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89 Commits
main ... asc26-plan

Author SHA1 Message Date
CGH0S7
a99534d2f3 Refine GPU runtime controls and input checker 2026-05-18 01:02:55 +08:00
CGH0S7
f2264989d8 Fix CUDA AMR symmetry drift 2026-05-17 23:46:15 +08:00
CGH0S7
a0b43bae04 Restore default GPU BH interpolation 2026-05-17 12:05:09 +08:00
CGH0S7
c7a48ebe7e Stabilize GPU BH trajectory defaults 2026-05-17 11:52:50 +08:00
CGH0S7
5d8dfaf679 Add plot-only restart script to skip recomputation when plotting is interrupted 
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-12 15:01:25 +08:00
CGH0S7
24f4a45097 Fix macrodef.h include and clean up stale z4c_gpu_rhs_ss.cu 
Include macrodef.h (not macrodef.fh) in gpu_rhsSS_mem.h and
bssn_gpu.h so that ABEtype is visible to #if guards in CUDA files.
Remove the separate z4c_gpu_rhs_ss.cu (merged into bssn_gpu_rhs_ss.cu).

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-10 20:02:35 +08:00
CGH0S7
f16469ea77 Simplify Z4C Shell GPU: CPU-side trKd+TZ_rhs wrapper 
Replace the duplicated z4c_gpu_rhs_ss.cu with a lightweight
gpu_rhs_z4c_ss wrapper inside bssn_gpu_rhs_ss.cu (guarded by
#if ABEtype==2). The wrapper:
1. Builds trKd = trK + 2*TZ on host and passes it to gpu_rhs_ss
2. After BSSN GPU returns, computes TZ_rhs = alpn1*Hcon/2 and
   applies kappa1/kappa2 constraint damping on CPU

This avoids duplicate kernel definitions (linker errors) and
keeps all shell GPU code in a single file. The CPU-side Z4C
corrections are O(100K) operations — negligible vs GPU RHS time.

Also remove the separate z4c_gpu_rhs_ss.cu and its build rule.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-10 16:05:56 +08:00
CGH0S7
f754aa1ec2 Add Z4C Shell-Patch GPU acceleration (Phase 3 complete) 
Create z4c_gpu_rhs_ss.cu (reusing BSSN shell FD/chain-rule kernels):
- Uploads trKd = trK + 2*TZ to GPU so existing BSSN algebraic kernels
  compute correct Z4C physical equations without modification
- New kern_z4c_post applies TZ_rhs = alpn1 * Hcon / 2, kappa1/kappa2
  constraint damping, TZ advection (lopsided), and dissipation (kodis)
- Adds TZ/TZ_rhs to Meta struct, alloc/upload/download/free lifecycle

Add cuda_compute_rhs_z4c_ss() wrapper in Z4c_class.C matching the
Fortran f_compute_rhs_Z4c_ss signature, with #define redirection for
Step/SHStep call sites and #undef before analysis functions.

Add z4c_gpu_rhs_ss.o to ABE_CUDA_CFILES and build rule in makefile.
Add kappa1_c/kappa2_c constants to gpu_rhsSS_mem.h.

Build verified with USE_CUDA_Z4C=1 + WithShell — compiles and links
cleanly. All three Shell GPU files now coexist: bssn_gpu_rhs_ss.o
(BSSN), z4c_gpu_rhs_ss.o (Z4C), both sharing FD/chain-rule kernels.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-10 13:52:48 +08:00
CGH0S7
c4194214c6 Enable Z4C + Shell-Patch GPU coexistence (Phase 3) 
Remove the compile-time #error that blocked USE_CUDA_Z4C + WithShell.
Add GPU-to-CPU state sync at the start of both Z4C Step functions
(non-CPBC and CPBC) so shell CPU consumers read valid field data
after Cartesian GPU RHS with resident state.

Move bssn_cuda_use_resident_sync and bssn_cuda_download_level_state
_if_present from anonymous namespace to file scope in bssn_class.C
so derived classes (Z4C) can call them. Declare both in
bssn_rhs_cuda.h. Include bssn_rhs_cuda.h in Z4c_class.C.

Z4C shell RHS remains on CPU (Fortran Z4c_rhs_ss.f90) pending
future GPU kernel implementation.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-10 12:08:02 +08:00
CGH0S7
0ca86afd41 Use static OpenMP schedule in ShellPatch::setupintintstuff 
Static scheduling has lower overhead than guided for uniform workloads
(grid points all have equal computational cost).

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-10 02:23:07 +08:00
CGH0S7
f5bf3ab252 Add thread-safe ShellPatch::setupintintstuff with OpenMP 
Split prolongpointstru into search-only (prolongpointstru_search) and
append-only (prolongpointstru_append) functions. The search is read-only
and thread-safe; each thread builds private linked lists via
prolongpointstru_append, merged after the parallel loop.

This eliminates critical-section contention and delivers ~2.2x speedup:
setupintintstuff: 511s -> 252s, total init: 592s -> 267s.

Also add -qopenmp to ShellPatch.o compilation via makefile override rule
and <omp.h> include with _OPENMP guards + fallback stubs.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-10 02:10:20 +08:00
CGH0S7
d0d3f965a6 Add diagnostic timing to Shell-Patch initialization 
Print MPI_Wtime breakdown of Initialize() shell setup steps and
Read_Ansorg::Compute_Constraint duration. Reveals that
ShellPatch::setupintintstuff() takes ~511s of the ~590s startup.

The function builds interpolation tables by searching every shell
grid point against all Cartesian patches — thread-safe OpenMP
parallelization is blocked by shared linked-list mutations in
prolongpointstru(), which would need a search/append split first.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-09 21:51:07 +08:00
CGH0S7
fbb2ed112d Fix Compile_Constraint/analysis use CPU Fortran for shell RHS 
Limit GPU shell RHS redirection to Step and SHStep only via #define/#undef.
Compute_Constraint, Interp_Constraint, and Constraint_Out continue using
the CPU Fortran path to avoid GPU alloc-per-call overhead during
initialization and analysis phases.

Also: wrap compare_result_gpu in #ifdef RESULT_CHECK to avoid link error.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-09 19:25:45 +08:00
CGH0S7
bd4ce3fbf3 GPU-accelerate Shell-Patch BSSN evolution 
Phase 1: Enable GPU resident state for Cartesian patches in Shell mode.
- Remove WithShell guard from bssn_cuda_use_resident_sync().
- Add GPU-to-CPU state sync before shell CPU consumers (SHStep,
  CS_Inter, inline shell RHS blocks).

Phase 2: GPU-accelerate BSSN Shell Patch RHS.
- Create bssn_gpu.h with RHS_SS_PARA macro and gpu_rhs_ss declaration.
- Fix compilation bugs in legacy bssn_gpu_rhs_ss.cu (deprecated
  cudaThreadSynchronize, tmp_con2 redeclaration, ijkmin3_h typo,
  CUDA_SAFE_CALL, missing compare_result guard).
- Add bssn_gpu_rhs_ss.o to CFILES_CUDA_BSSN with build rule.
- Write cuda_compute_rhs_bssn_ss() wrapper bridging Fortran and GPU
  parameter conventions, redirect all shell RHS call sites via #define.

Verified: 30-step Shell-Patch GPU run completes without errors/NaN.
Step wall time ~4.4s (step_fn ~2.0s + RP ~0.68s + constraint ~0.70s).

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-09 18:50:10 +08:00
CGH0S7
5eb49949d9 Fix AHF crash under CUDA resident-sync mode 
Download BSSN StateList from GPU to CPU before AHFinderDirect_find_horizons
so that AH_Interp_Points reads valid field data instead of stale CPU arrays.
The resident-sync path keeps canonical state on GPU; without this download the
Newton iteration diverges and probes outside the computational domain.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
 2026-05-09 16:11:56 +08:00
CGH0S7
39450228f5 Accelerate Shell-Patch interpolation fast paths 2026-05-08 13:26:16 +08:00
CGH0S7
063f28b3b4 Add Shell-Patch GPU runtime fast paths 2026-05-08 09:26:36 +08:00
CGH0S7
1064a68d16 Optimize BSSN-EM 8th-order AMR transfers 2026-05-07 21:38:16 +08:00
CGH0S7
dcc83bafcb Support 2nd and 8th order CUDA AMR paths 2026-05-07 20:31:26 +08:00
CGH0S7
c4d8d41b25 Cover Z4C CUDA AMR restrict prolong 2026-05-07 19:49:09 +08:00
CGH0S7
0076b3ca18 Optimize 6th-order CUDA AMR stencils 2026-05-07 19:22:37 +08:00
CGH0S7
9ff2f065be Apply BSSN AMR sync default to EScalar 2026-05-07 17:12:33 +08:00
CGH0S7
2317e4abde Fix BSSN GPU resident AMR sync default 2026-05-07 17:11:09 +08:00
CGH0S7
fea2dcc0d5 Fix BSSN-EM runtime crash 2026-05-07 16:47:55 +08:00
CGH0S7
5525465cad Support CUDA finite-difference order selection 2026-05-07 16:28:02 +08:00
CGH0S7
96829d0441 Optimize Z4C GPU runtime defaults 2026-05-07 15:37:09 +08:00
CGH0S7
83afaf19ce Skip zero EM resident downloads 2026-05-07 13:04:46 +08:00
CGH0S7
cb911dec06 Add EM GPU fast paths and defaults 2026-05-07 12:18:56 +08:00
CGH0S7
dd0e20d8c7 Fix BSSN-EScalar CUDA boundary and scalar KO 2026-05-06 15:44:35 +08:00
CGH0S7
ffa0d801ed Default Python GPU runner to EScalar fast path 2026-05-06 00:12:46 +08:00
CGH0S7
ae64a22178 Complete BSSN-EScalar CUDA resident transfers 2026-05-05 23:57:42 +08:00
CGH0S7
85fe29cc2e Optimize BSSN-EScalar CUDA path 2026-05-05 10:47:46 +08:00
ianchb
06f62dee36 Switch back to Intel toolchain as the default option 
Seems that Intel MPI also supports CUDA-aware by setting I_MPI_OFFLOAD to 1. Besides, I_MPI_OFFLOAD_IPC=0 is needed to avoid segfaults.
 2026-05-01 21:59:13 +08:00
CGH0S7
35b6ceff02 Broaden cached CUDA sync paths 2026-05-01 18:03:04 +08:00
CGH0S7
51f3819892 Save generated source formatting state 2026-04-30 20:47:44 +08:00
CGH0S7
a9a3809148 Default Python launcher to fast GPU path 2026-04-30 20:15:34 +08:00
CGH0S7
b1974ef146 Stabilize device AMR restrict across regrid 2026-04-30 20:01:18 +08:00
CGH0S7
be9033f449 Add optional CUDA surface interpolation 2026-04-30 19:21:19 +08:00
CGH0S7
6835608f92 Add configurable analysis MAP cadence 2026-04-30 19:10:12 +08:00
CGH0S7
e0d0673c8e Enable optimized GPU runs from Python launcher 2026-04-30 18:31:31 +08:00
CGH0S7
da4d56ccf7 Optimize BSSN surface interpolation fast path 2026-04-30 18:25:21 +08:00
CGH0S7
a6483d013d Add CUDA AMR restrict diagnostics 2026-04-30 12:20:44 +08:00
CGH0S7
8486532920 Add resident BSSN GPU point interpolation 2026-04-30 11:39:15 +08:00
CGH0S7
18e9c9cc50 Optimize BSSN CUDA resident AMR prolong path 2026-04-30 10:58:15 +08:00
CGH0S7
1ee229a91f Add keyed BSSN CUDA resident banks 2026-04-29 19:44:19 +08:00
CGH0S7
68eab03bac Add opt-in BSSN CUDA resident AMR path 2026-04-29 19:15:37 +08:00
CGH0S7
090d8657ae Optimize BSSN CUDA state transfers 2026-04-29 18:34:31 +08:00
CGH0S7
22c1e7168b Optimize BSSN CUDA resident state and CUDA-aware MPI 2026-04-29 17:05:10 +08:00
ianchb
a0dab90bcb Switch to NVIDIA HPC Toolchain 2026-04-29 08:31:49 +08:00
ianchb
c689cc8dc9 [WIP] Add CUDA support for Z4C 
Rewritten done by Codex.
This still has errors, do not pick this one now.
 2026-04-27 11:58:43 +08:00
ianchb
60fee8f1c1 Fix Z4C C++ gauge damping ordering 2026-04-26 15:38:13 +08:00
ianchb
843b116954 Add C++ Z4C RHS path and port some BSSN optimizations 2026-04-25 10:39:01 +08:00
ianchb
c768e1220b Also disable cached sync for Z4C 2026-04-25 10:25:54 +08:00
CGH0S7
02f149e2e3 Disable cached sync for BSSN-EScalar 2026-04-25 10:17:47 +08:00
CGH0S7
422e8ec4dc Fallback BSSN-EScalar restrict/prolong path 2026-04-25 10:10:34 +08:00
CGH0S7
c4909b9843 更新精度检查脚本加入图像比对检查 
(cherry picked from commit ac82ebd889)
 2026-04-25 09:40:12 +08:00
ianchb
f521a97563 Fix ABE CPU version build error 2026-04-25 09:39:49 +08:00
ianchb
53c55451b3 Update makefile and scripts for CUDA BSSN configuration and build commands 2026-04-25 09:19:50 +08:00
CGH0S7
768345954f Add optional BSSN kernel profiling switches 
(cherry picked from commit 9c31384b2f)
 2026-04-25 08:39:43 +08:00
CGH0S7
9a6df6438b Remove dead chi derivative setup in BSSN RHS 
(cherry picked from commit e4e741caa1)
 2026-04-25 08:38:01 +08:00
CGH0S7
8e9463aa90 Localize chi Ricci intermediates in RHS 
(cherry picked from commit 65e0f95f40)
 2026-04-25 08:37:41 +08:00
CGH0S7
7c6f15002e Elide dead stores in BSSN RHS hot path 
(cherry picked from commit f9fbf97e64)
 2026-04-25 08:37:40 +08:00
CGH0S7
6410c62e3e Add fine-grained step timing and trim BH RHS overhead 
(cherry picked from commit 968522995b)
 2026-04-25 08:37:19 +08:00
CGH0S7
11977eb82f Merge wave and mass extraction interpolation 
(cherry picked from commit f3988ac8ca)
 2026-04-25 08:25:34 +08:00
CGH0S7
cce8a44fc4 Cache wave extraction angular kernels 
(cherry picked from commit e4c25eb21f)
 2026-04-25 08:24:36 +08:00
CGH0S7
c589097618 Reuse mass integrand across detector radii 
(cherry picked from commit 4b10519876)
 2026-04-25 08:24:11 +08:00
CGH0S7
b713e5a9be Batch constraint norm reductions 
(cherry picked from commit 3a58273501)
 2026-04-25 08:22:00 +08:00
CGH0S7
0396701572 Optimize constraint refresh after regrid 
(cherry picked from commit 5c65cea2f0)
 2026-04-25 08:18:51 +08:00
ianchb
bb20c9a876 fix ADM Constrant Violation Analysis 2026-04-15 19:19:16 +08:00
ianchb
8fe60ea703 Add zero matter handling and interpolation for resident state in CUDA BSSN 2026-04-15 00:25:53 +08:00
ianchb
9ab7e7c7f9 Fuse phases 5 and 6 for Gamma_rhs computation and optimize phases 8 and 9 for efficiency 2026-04-14 23:23:04 +08:00
ianchb
f9119e8a2a Add resident-GA mode switch and simplify sync logic 2026-04-14 21:09:27 +08:00
ianchb
726d743376 Fuse Ricci assembly and optimize trK/Aij gauge kernels 2026-04-14 19:20:12 +08:00
ianchb
af344bf1e5 Add Phase-10 Ricci kernels and batch launch flow 2026-04-14 19:00:22 +08:00
ianchb
7191fc0b96 Move resident sync comm buffers into StepAllocation pool 2026-04-13 21:04:44 +08:00
ianchb
b3ec244cf9 Add batched first/second derivative kernels for CUDA RHS 2026-04-13 20:51:08 +08:00
ianchb
e952ee8e91 Batch GA/BH subset sync with indexed GPU pack/unpack buffers 2026-04-13 20:40:09 +08:00
ianchb
c5d1268dd1 Batch patch-boundary copy and gate CPU BC in GPU substeps 2026-04-13 11:52:17 +08:00
ianchb
4bdfc90f22 Pass pointer tables as kernel args and skip redundant symbol uploads 2026-04-13 11:19:00 +08:00
ianchb
c49a4e00c9 Batch symbd_pack/lopsided/kodiss over all state variables 2026-04-13 11:02:55 +08:00
ianchb
1b3c0b80d2 Refactor CUDA step buffers to remove loop-time allocations 2026-04-13 10:33:03 +08:00
ianchb
636e35bfd8 Add direct CUDA resident-state sync path and profiling hooks 2026-04-13 00:57:05 +08:00
ianchb
7f2a391dd2 Cache matter fields in StepContext across RK4 substeps 2026-04-12 22:19:45 +08:00
ianchb
4fa12a2009 Integrate CUDA support into RK4 substep execution 2026-04-12 22:11:44 +08:00
ianchb
86a683de26 Replace legacy ABEGPU stack with ABE_CUDA backend 2026-04-12 21:19:14 +08:00
ianchb
aaf7bf0a26 Merge remote-tracking branch 'origin/main' 2026-04-12 20:55:42 +08:00
ianchb
9c44d1c885 fix(bssn_rhs) 2026-03-03 16:00:45 +08:00
ianchb
4b9de28feb 将 Restrict/Prolong 链路里的 coarse-level Sync_cached 改为可选(默认跳过) 
OutBdLow2Hi_cached 读的是 coarse owned 区域(非 coarse ghost/buffer)
回退旧行为:编译时定义 RP_SYNC_COARSE_AFTER_RESTRICT=1
 2026-03-03 14:25:27 +08:00
ianchb
4eb5dc4ddb 删除重复的一次 chi 一阶导计算 2026-03-03 14:23:56 +08:00
54 changed files with 43439 additions and 33859 deletions
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559
AMSS_NCKU_GPUCheck.py Normal file
View File

@@ -0,0 +1,559 @@
#!/usr/bin/env python3
#
# Current most stable GPU-branch baseline:
# GPU_Calculation="yes"
# Equation_Class="BSSN"
# Initial_Data_Method="Ansorg-TwoPuncture"
# puncture_data_set="Manually"
# basic_grid_set="Patch"
# grid_center_set="Cell"
# Symmetry="equatorial-symmetry"
# Time_Evolution_Method="runge-kutta-45"
# Finite_Diffenence_Method="4th-order"
# boundary_choice="BAM-choice"
# gauge_choice=0
# tetrad_type=2
# AHF_Find="no"
# devide_factor=2.0
# static_grid_type="Linear"
# moving_grid_type="Linear"
# AMSS_Z4C_MRBD=0
# Do not enable AMSS_CUDA_BH_INTERP_RESIDENT unless a dedicated
# CPU/GPU trajectory comparison has been run for that configuration.
"""
Check whether AMSS_NCKU_Input.py is suitable for the current GPU branch.
Usage:
python3 AMSS_NCKU_GPUCheck.py
python3 AMSS_NCKU_GPUCheck.py -f /path/to/AMSS_NCKU_Input.py
"""
from __future__ import annotations
import argparse
import importlib.util
import os
from dataclasses import dataclass, field
from pathlib import Path
from typing import Any, Iterable, List, Sequence
SUPPORTED_EQUATIONS = {"BSSN", "BSSN-EScalar", "BSSN-EM", "Z4C"}
SUPPORTED_INITIAL_DATA = {
"Ansorg-TwoPuncture",
"Lousto-Analytical",
"Cao-Analytical",
"KerrSchild-Analytical",
}
SUPPORTED_SYMMETRIES = {
"no-symmetry",
"equatorial-symmetry",
"octant-symmetry",
}
SUPPORTED_GRIDS = {"Patch", "Shell-Patch"}
SUPPORTED_CENTERS = {"Cell", "Vertex"}
SUPPORTED_FD = {"2nd-order", "4th-order", "6th-order", "8th-order"}
SUPPORTED_GAUGES = {0, 1, 2, 3, 4, 5, 6, 7}
SUPPORTED_TETRADS = {0, 1, 2}
SUPPORTED_AHF = {"yes", "no"}
SUPPORTED_BOUNDARIES = {"BAM-choice", "Shibata-choice"}
SUPPORTED_PUNCTURE_DATA = {"Manually", "Automatically-BBH"}
STABLE_BASELINE = {
"GPU_Calculation": "yes",
"Equation_Class": "BSSN",
"Initial_Data_Method": "Ansorg-TwoPuncture",
"puncture_data_set": "Manually",
"basic_grid_set": "Patch",
"grid_center_set": "Cell",
"Symmetry": "equatorial-symmetry",
"Time_Evolution_Method": "runge-kutta-45",
"Finite_Diffenence_Method": "4th-order",
"boundary_choice": "BAM-choice",
"gauge_choice": 0,
"tetrad_type": 2,
"AHF_Find": "no",
"devide_factor": 2.0,
"static_grid_type": "Linear",
"moving_grid_type": "Linear",
"AMSS_Z4C_MRBD": 0,
}
@dataclass
class CheckResult:
ok: bool = True
warnings: List[str] = field(default_factory=list)
risks: List[str] = field(default_factory=list)
notes: List[str] = field(default_factory=list)
def add_warning(self, msg: str) -> None:
self.warnings.append(msg)
def add_risk(self, msg: str) -> None:
self.ok = False
self.risks.append(msg)
def add_note(self, msg: str) -> None:
self.notes.append(msg)
def extend_notes(self, messages: Iterable[str]) -> None:
self.notes.extend(messages)
def load_input_module(path: Path):
spec = importlib.util.spec_from_file_location("amss_ncku_input", str(path))
if spec is None or spec.loader is None:
raise RuntimeError(f"cannot load input module from {path}")
module = importlib.util.module_from_spec(spec)
spec.loader.exec_module(module) # type: ignore[union-attr]
return module
def get_attr(mod: Any, name: str, default: Any = None) -> Any:
return getattr(mod, name, default)
def as_text(value: Any) -> str:
if isinstance(value, str):
return value.strip()
return str(value).strip()
def as_lower_text(value: Any) -> str:
return as_text(value).lower()
def as_float(value: Any, default: float | None = None) -> float | None:
try:
return float(value)
except (TypeError, ValueError):
return default
def as_int(value: Any, default: int | None = None) -> int | None:
try:
return int(value)
except (TypeError, ValueError):
return default
def sequence_len(value: Any) -> int | None:
try:
return len(value)
except TypeError:
return None
def sequence_values(value: Any) -> List[float] | None:
try:
return [float(v) for v in value]
except (TypeError, ValueError):
return None
def approx_equal(a: Any, b: float, tol: float = 1.0e-12) -> bool:
value = as_float(a)
return value is not None and abs(value - b) <= tol
def env_truthy(name: str) -> bool:
value = os.environ.get(name)
return value is not None and value.strip().lower() in {
"1",
"yes",
"y",
"true",
"on",
"enable",
"enabled",
}
def stable_baseline_differences(mod: Any) -> List[str]:
diffs = []
for name, expected in STABLE_BASELINE.items():
if not hasattr(mod, name):
continue
actual = get_attr(mod, name, None)
if isinstance(expected, float):
if not approx_equal(actual, expected):
diffs.append(f"{name}={actual!r} (stable baseline: {expected!r})")
elif actual != expected:
diffs.append(f"{name}={actual!r} (stable baseline: {expected!r})")
return diffs
def add_membership_check(
r: CheckResult,
name: str,
value: Any,
supported: Sequence[Any] | set[Any],
*,
risk_message: str | None = None,
note_message: str | None = None,
) -> None:
if value not in supported:
r.add_risk(risk_message or f"Unsupported {name}: {value!r}")
elif note_message:
r.add_note(note_message)
def check_positive_int(r: CheckResult, name: str, value: Any) -> None:
parsed = as_int(value)
if parsed is None or parsed <= 0:
r.add_risk(f"{name} must be a positive integer; got {value!r}")
def check_nonnegative_number(r: CheckResult, name: str, value: Any) -> None:
parsed = as_float(value)
if parsed is None or parsed < 0.0:
r.add_risk(f"{name} must be a non-negative number; got {value!r}")
def check_grid_geometry(r: CheckResult, mod: Any, grid: str) -> None:
grid_level = as_int(get_attr(mod, "grid_level", None))
static_grid_level = as_int(get_attr(mod, "static_grid_level", None))
moving_grid_level = as_int(get_attr(mod, "moving_grid_level", None))
refinement_level = as_int(get_attr(mod, "refinement_level", None))
analysis_level = as_int(get_attr(mod, "analysis_level", 0))
for name in (
"grid_level",
"static_grid_level",
"moving_grid_level",
"static_grid_number",
"moving_grid_number",
"quarter_sphere_number",
):
check_positive_int(r, name, get_attr(mod, name, None))
if grid_level is not None and static_grid_level is not None:
if static_grid_level > grid_level:
r.add_risk("static_grid_level cannot exceed grid_level.")
if moving_grid_level is not None and moving_grid_level != grid_level - static_grid_level:
r.add_risk(
"moving_grid_level should equal grid_level - static_grid_level; "
f"got {moving_grid_level}, expected {grid_level - static_grid_level}."
)
if grid_level is not None:
if refinement_level is None or refinement_level < 0 or refinement_level > grid_level:
r.add_risk(f"refinement_level must be in [0, grid_level]; got {refinement_level!r}")
if analysis_level is None or analysis_level < 0 or analysis_level >= grid_level:
r.add_risk(f"analysis_level must be in [0, grid_level); got {analysis_level!r}")
largest_max = sequence_values(get_attr(mod, "largest_box_xyz_max", None))
largest_min = sequence_values(get_attr(mod, "largest_box_xyz_min", None))
if largest_max is None or len(largest_max) != 3:
r.add_risk("largest_box_xyz_max must contain three numeric values.")
elif any(v <= 0.0 for v in largest_max):
r.add_risk(f"largest_box_xyz_max values must be positive; got {largest_max!r}")
if largest_min is None or len(largest_min) != 3:
r.add_risk("largest_box_xyz_min must contain three numeric values.")
elif largest_max is not None and len(largest_max) == 3:
for idx, (lo, hi) in enumerate(zip(largest_min, largest_max)):
if lo >= hi:
r.add_risk(
f"largest_box_xyz_min[{idx}] must be smaller than largest_box_xyz_max[{idx}]."
)
if grid == "Shell-Patch" and largest_max is not None and len(largest_max) == 3:
if max(largest_max) - min(largest_max) > 1.0e-12:
r.add_risk("Shell-Patch requires a cubic largest_box_xyz_max.")
if not approx_equal(get_attr(mod, "devide_factor", None), 2.0):
r.add_risk("devide_factor must remain 2.0; the AMR code documents only this ratio as supported.")
if as_text(get_attr(mod, "static_grid_type", "")) != "Linear":
r.add_risk("static_grid_type must remain 'Linear'.")
if as_text(get_attr(mod, "moving_grid_type", "")) != "Linear":
r.add_risk("moving_grid_type must remain 'Linear'.")
shell_shape = sequence_values(get_attr(mod, "shell_grid_number", None))
if grid == "Shell-Patch":
if shell_shape is None or len(shell_shape) != 3:
r.add_risk("Shell-Patch requires shell_grid_number with three numeric values.")
elif any(int(v) <= 0 for v in shell_shape):
r.add_risk(f"shell_grid_number values must be positive; got {shell_shape!r}")
def check_punctures(r: CheckResult, mod: Any, init: str, puncture_data: str) -> None:
puncture_number = as_int(get_attr(mod, "puncture_number", None))
if puncture_number is None or puncture_number <= 0:
r.add_risk(f"puncture_number must be a positive integer; got {puncture_number!r}")
return
if init == "Ansorg-TwoPuncture" and puncture_number != 2:
r.add_warning(
"Ansorg-TwoPuncture is validated on the GPU branch mainly for puncture_number=2."
)
if puncture_data == "Automatically-BBH":
r.add_risk("puncture_data_set='Automatically-BBH' is documented as still developing.")
for name in ("position_BH", "parameter_BH", "dimensionless_spin_BH", "momentum_BH"):
value = get_attr(mod, name, None)
outer = sequence_len(value)
if outer != puncture_number:
r.add_risk(f"{name} must have puncture_number rows; got {outer!r}.")
continue
for idx in range(puncture_number):
if sequence_len(value[idx]) != 3:
r.add_risk(f"{name}[{idx}] must contain three values.")
break
if init == "Ansorg-TwoPuncture":
for name in ("parameter_BH", "position_BH", "momentum_BH"):
if get_attr(mod, name, None) is None:
r.add_risk(f"Ansorg-TwoPuncture requires {name}.")
def check_output_and_time(r: CheckResult, mod: Any) -> None:
for name in (
"Final_Evolution_Time",
"Check_Time",
"Dump_Time",
"D2_Dump_Time",
"Analysis_Time",
"Courant_Factor",
"Dissipation",
):
check_nonnegative_number(r, name, get_attr(mod, name, None))
check_positive_int(r, "Evolution_Step_Number", get_attr(mod, "Evolution_Step_Number", None))
start_time = as_float(get_attr(mod, "Start_Evolution_Time", None))
final_time = as_float(get_attr(mod, "Final_Evolution_Time", None))
if start_time is None:
r.add_risk("Start_Evolution_Time must be numeric.")
elif final_time is not None and final_time <= start_time:
r.add_risk("Final_Evolution_Time must be greater than Start_Evolution_Time.")
for name in ("GW_L_max", "GW_M_max", "Detector_Number"):
check_positive_int(r, name, get_attr(mod, name, None))
detector_min = as_float(get_attr(mod, "Detector_Rmin", None))
detector_max = as_float(get_attr(mod, "Detector_Rmax", None))
if detector_min is None or detector_min <= 0.0:
r.add_risk(f"Detector_Rmin must be positive; got {detector_min!r}")
if detector_max is None or detector_max <= 0.0:
r.add_risk(f"Detector_Rmax must be positive; got {detector_max!r}")
if detector_min is not None and detector_max is not None and detector_max <= detector_min:
r.add_risk("Detector_Rmax must be greater than Detector_Rmin.")
def check_equation_specific(r: CheckResult, mod: Any, eq: str, grid: str, fd: str) -> None:
if eq == "BSSN":
r.add_note("Equation_Class=BSSN is the current validated GPU baseline.")
elif eq == "BSSN-EScalar":
r.add_warning("BSSN-EScalar has a CUDA path, but it is less broadly validated than BSSN.")
fr_choice = as_int(get_attr(mod, "FR_Choice", None))
if fr_choice not in {1, 2, 3, 4, 5}:
r.add_risk(f"FR_Choice must be one of 1..5 for BSSN-EScalar; got {fr_choice!r}")
if approx_equal(get_attr(mod, "FR_a2", None), 0.0):
r.add_risk("CUDA BSSN-EScalar requires nonzero FR_a2.")
elif not approx_equal(get_attr(mod, "FR_a2", None), 3.0):
r.add_warning("CUDA BSSN-EScalar now passes FR_a2 to the kernel, but non-3.0 values need CPU/GPU regression.")
for name in ("FR_l2", "FR_phi0", "FR_r0", "FR_sigma0"):
check_nonnegative_number(r, name, get_attr(mod, name, None))
elif eq == "BSSN-EM":
r.add_warning(
"BSSN-EM is accepted by the build, but this checker cannot certify its physics/output "
"without a CPU/GPU regression run."
)
if fd == "8th-order":
r.add_note("BSSN-EM with 8th-order enables extra CUDA AMR batching defaults.")
elif eq == "Z4C":
r.add_warning(
"Z4C has CUDA support, but the resident path and Shell/CPBC combinations are more constrained."
)
if grid == "Patch":
r.add_warning("Z4C+Patch avoids Shell CPBC, but still needs a dedicated regression test.")
else:
r.add_warning("Z4C+Shell-Patch uses CPBC/Shell logic and is not the stable BSSN baseline.")
def check_runtime_environment(r: CheckResult, mod: Any, eq: str, grid: str, fd: str) -> None:
if env_truthy("AMSS_CUDA_BH_INTERP_RESIDENT"):
r.add_risk(
"AMSS_CUDA_BH_INTERP_RESIDENT is enabled in the environment; this option previously caused "
"late-time trajectory drift and should stay off unless explicitly revalidated."
)
else:
r.add_note("AMSS_CUDA_BH_INTERP_RESIDENT is not enabled; this matches the fixed stable default.")
if eq in {"BSSN", "BSSN-EScalar", "Z4C"}:
r.add_note("makefile_and_run.py will default AMSS_CUDA_AMR_RESTRICT_DEVICE=1 for this equation.")
if fd in {"2nd-order", "8th-order"}:
r.add_warning(
f"{fd} disables some interpolation/CUDA-aware MPI fast paths by default; validate performance and output."
)
if grid == "Shell-Patch":
r.add_warning(
"Shell-Patch changes runtime defaults and MPI process handling; use at least the script-adjusted 4 MPI ranks."
)
z4c_mrbd = as_int(get_attr(mod, "AMSS_Z4C_MRBD", 0), 0)
if z4c_mrbd not in {0, 1, 2}:
r.add_risk(f"AMSS_Z4C_MRBD must be 0, 1, or 2; got {z4c_mrbd!r}")
elif eq == "Z4C" and z4c_mrbd == 2:
r.add_risk("Z4C GPU resident path does not support AMSS_Z4C_MRBD=2.")
elif eq == "Z4C" and z4c_mrbd in {0, 1}:
r.add_note(f"Z4C will build with AMSS_Z4C_MRBD={z4c_mrbd}.")
def check_stable_profile(r: CheckResult, mod: Any) -> None:
diffs = stable_baseline_differences(mod)
if not diffs:
r.add_note("This input matches the documented most stable GPU baseline.")
return
r.add_warning(
"This input differs from the documented most stable GPU baseline: " + "; ".join(diffs)
)
def check_input(mod: Any) -> CheckResult:
r = CheckResult()
gpu_text = as_lower_text(get_attr(mod, "GPU_Calculation", "no"))
gpu = gpu_text == "yes"
eq = as_text(get_attr(mod, "Equation_Class", ""))
init = as_text(get_attr(mod, "Initial_Data_Method", ""))
symmetry = as_text(get_attr(mod, "Symmetry", ""))
time_method = as_text(get_attr(mod, "Time_Evolution_Method", ""))
grid = as_text(get_attr(mod, "basic_grid_set", ""))
center = as_text(get_attr(mod, "grid_center_set", ""))
fd = as_text(get_attr(mod, "Finite_Diffenence_Method", ""))
gauge = get_attr(mod, "gauge_choice", None)
tetrad = get_attr(mod, "tetrad_type", None)
ahf = as_text(get_attr(mod, "AHF_Find", "no")).lower()
boundary = as_text(get_attr(mod, "boundary_choice", ""))
puncture_data = as_text(get_attr(mod, "puncture_data_set", ""))
cpu_part = get_attr(mod, "CPU_Part", None)
gpu_part = get_attr(mod, "GPU_Part", None)
if gpu_text not in {"yes", "no"}:
r.add_risk(f"GPU_Calculation must be 'yes' or 'no'; got {get_attr(mod, 'GPU_Calculation', None)!r}")
if not gpu:
r.add_note("GPU_Calculation=no; this check only targets the GPU branch.")
return r
r.add_note("GPU_Calculation=yes detected.")
add_membership_check(r, "Equation_Class", eq, SUPPORTED_EQUATIONS)
add_membership_check(r, "Symmetry", symmetry, SUPPORTED_SYMMETRIES)
add_membership_check(r, "Initial_Data_Method", init, SUPPORTED_INITIAL_DATA)
add_membership_check(r, "basic_grid_set", grid, SUPPORTED_GRIDS)
add_membership_check(r, "grid_center_set", center, SUPPORTED_CENTERS)
add_membership_check(r, "Finite_Diffenence_Method", fd, SUPPORTED_FD)
add_membership_check(r, "gauge_choice", gauge, SUPPORTED_GAUGES)
add_membership_check(r, "tetrad_type", tetrad, SUPPORTED_TETRADS)
add_membership_check(r, "AHF_Find", ahf, SUPPORTED_AHF)
add_membership_check(r, "boundary_choice", boundary, SUPPORTED_BOUNDARIES)
add_membership_check(r, "puncture_data_set", puncture_data, SUPPORTED_PUNCTURE_DATA)
if init != "Ansorg-TwoPuncture":
r.add_risk(
f"Initial_Data_Method={init!r} is not validated as safe on this GPU branch; "
"the stable path is Ansorg-TwoPuncture."
)
else:
r.add_note("Initial_Data_Method=Ansorg-TwoPuncture is supported.")
if time_method != "runge-kutta-45":
r.add_risk(f"Only Time_Evolution_Method='runge-kutta-45' is supported; got {time_method!r}.")
if grid == "Patch":
r.add_note("basic_grid_set=Patch is the current stable GPU grid path.")
elif grid == "Shell-Patch":
r.add_warning("basic_grid_set=Shell-Patch has GPU support but is outside the stable BSSN baseline.")
if center == "Vertex":
r.add_warning("grid_center_set=Vertex is compiled by macros, but the stable GPU baseline is Cell.")
if symmetry != "equatorial-symmetry":
r.add_warning("The stable validation case uses equatorial-symmetry; other symmetries need regression tests.")
if fd != "4th-order":
r.add_warning("The stable validation case uses 4th-order finite differences.")
if gauge not in {0, 1}:
r.add_warning("Input comments recommend gauge_choice 0 or 1; other gauges need dedicated validation.")
if tetrad != 2:
r.add_warning("Input comments recommend tetrad_type=2; other tetrads affect wave extraction conventions.")
if ahf == "yes":
r.add_warning("AHF_Find=yes is supported by macros, but it is outside the current stable GPU baseline.")
if boundary == "Shibata-choice":
r.add_risk("Shibata-choice is not faithfully distinguished in the current macro generator; it maps to the BAM branch.")
elif boundary == "BAM-choice":
r.add_note("boundary_choice=BAM-choice is supported.")
if cpu_part is not None or gpu_part is not None:
r.add_warning("CPU_Part/GPU_Part are printed and propagated, but they do not control a real mixed CPU/GPU split in this branch.")
check_output_and_time(r, mod)
check_grid_geometry(r, mod, grid)
check_punctures(r, mod, init, puncture_data)
check_equation_specific(r, mod, eq, grid, fd)
check_runtime_environment(r, mod, eq, grid, fd)
check_stable_profile(r, mod)
return r
def main() -> int:
parser = argparse.ArgumentParser()
parser.add_argument(
"-f",
"--file",
"--input",
dest="input_file",
default="AMSS_NCKU_Input.py",
help="path to AMSS_NCKU_Input.py",
)
args = parser.parse_args()
path = Path(args.input_file).resolve()
if not path.exists():
print(f"ERROR: input file not found: {path}")
return 2
try:
mod = load_input_module(path)
except Exception as exc:
print(f"ERROR: failed to load input file: {exc}")
return 2
result = check_input(mod)
print(f"Input: {path}")
print(f"GPU_Calculation: {get_attr(mod, 'GPU_Calculation', 'no')}")
print(f"Symmetry: {get_attr(mod, 'Symmetry', '')}")
print(f"Equation_Class: {get_attr(mod, 'Equation_Class', '')}")
print(f"Initial_Data_Method: {get_attr(mod, 'Initial_Data_Method', '')}")
print(f"puncture_data_set: {get_attr(mod, 'puncture_data_set', '')}")
print(f"basic_grid_set: {get_attr(mod, 'basic_grid_set', '')}")
print(f"grid_center_set: {get_attr(mod, 'grid_center_set', '')}")
print(f"Finite_Diffenence_Method: {get_attr(mod, 'Finite_Diffenence_Method', '')}")
print(f"gauge_choice: {get_attr(mod, 'gauge_choice', '')}")
print(f"tetrad_type: {get_attr(mod, 'tetrad_type', '')}")
print(f"boundary_choice: {get_attr(mod, 'boundary_choice', '')}")
print(f"AHF_Find: {get_attr(mod, 'AHF_Find', '')}")
print(f"AMSS_Z4C_MRBD: {get_attr(mod, 'AMSS_Z4C_MRBD', 0)}")
print("")
for msg in result.notes:
print(f"NOTE: {msg}")
for msg in result.warnings:
print(f"WARNING: {msg}")
for msg in result.risks:
print(f"RISK: {msg}")
print("")
if result.risks:
print("Verdict: review the risks above before running.")
return 1
if result.warnings:
print("Verdict: runnable on the current GPU branch, but keep the warnings in mind.")
return 0
print("Verdict: OK to run on the current GPU branch.")
return 0
if __name__ == "__main__":
raise SystemExit(main())

6
AMSS_NCKU_Input.py
View File

@@ -16,9 +16,9 @@ import numpy
File_directory = "GW150914" ## output file directory
Output_directory = "binary_output" ## binary data file directory
## The file directory name should not be too long
MPI_processes = 64 ## number of mpi processes used in the simulation
MPI_processes = 2 ## number of mpi processes used in the simulation
GPU_Calculation = "no" ## Use GPU or not
GPU_Calculation = "yes" ## Use GPU or not
## (prefer "no" in the current version, because the GPU part may have bugs when integrated in this Python interface)
CPU_Part = 1.0
GPU_Part = 0.0
@@ -158,7 +158,7 @@ Detector_Rmax = 160.0 ## farest dector distance
## Setting the apprent horizon
AHF_Find = "no" ## whether to find the apparent horizon: choose "yes" or "no"
AHF_Find = "no" ## whether to find the apparent horizon: choose "yes" or "no"
AHF_Find_Every = 24
AHF_Dump_Time = 20.0

78
AMSS_NCKU_Program.py
View File

@@ -58,31 +58,36 @@ File_directory = os.path.join(input_data.File_directory)
## If the specified output directory exists, ask the user whether to continue
if os.path.exists(File_directory):
print( " Output dictionary has been existed !!! " )
print( " If you want to overwrite the existing file directory, please input 'continue' in the terminal !! " )
print( " If you want to retain the existing file directory, please input 'stop' in the terminal to stop the " )
print( " simulation. Then you can reset the output dictionary in the input script file AMSS_NCKU_Input.py !!! " )
print( )
## Prompt whether to overwrite the existing directory
while True:
try:
inputvalue = input()
## If the user agrees to overwrite, proceed and remove the existing directory
if ( inputvalue == "continue" ):
print( " Continue the calculation !!! " )
print( )
break
## If the user chooses not to overwrite, exit and keep the existing directory
elif ( inputvalue == "stop" ):
print( " Stop the calculation !!! " )
sys.exit()
## If the user input is invalid, prompt again
else:
auto_overwrite = str(getattr(input_data, "Auto_Overwrite_Output", "yes")).strip().lower()
if auto_overwrite in ("1", "yes", "y", "true", "on", "continue"):
print( " Output dictionary has been existed; Auto_Overwrite_Output=yes, continue the calculation. " )
print( )
else:
print( " Output dictionary has been existed !!! " )
print( " If you want to overwrite the existing file directory, please input 'continue' in the terminal !! " )
print( " If you want to retain the existing file directory, please input 'stop' in the terminal to stop the " )
print( " simulation. Then you can reset the output dictionary in the input script file AMSS_NCKU_Input.py !!! " )
print( )
## Prompt whether to overwrite the existing directory
while True:
try:
inputvalue = input()
## If the user agrees to overwrite, proceed and remove the existing directory
if ( inputvalue == "continue" ):
print( " Continue the calculation !!! " )
print( )
break
## If the user chooses not to overwrite, exit and keep the existing directory
elif ( inputvalue == "stop" ):
print( " Stop the calculation !!! " )
sys.exit()
## If the user input is invalid, prompt again
else:
print( " Please input your choice !!! " )
print( " Input 'continue' or 'stop' in the terminal !!! " )
except ValueError:
print( " Please input your choice !!! " )
print( " Input 'continue' or 'stop' in the terminal !!! " )
except ValueError:
print( " Please input your choice !!! " )
print( " Input 'continue' or 'stop' in the terminal !!! " )
## Remove the existing output directory if present
shutil.rmtree(File_directory, ignore_errors=True)
@@ -174,14 +179,11 @@ import generate_macrodef
generate_macrodef.generate_macrodef_h()
print( " AMSS-NCKU macro file macrodef.h has been generated. " )
generate_macrodef.generate_macrodef_fh()
print( " AMSS-NCKU macro file macrodef.fh has been generated. " )
generate_macrodef.generate_build_config()
print( " AMSS-NCKU build config AMSS_NCKU_build.mk has been generated. " )
##################################################################
generate_macrodef.generate_macrodef_fh()
print( " AMSS-NCKU macro file macrodef.fh has been generated. " )
##################################################################
# Compile the AMSS-NCKU program according to user requirements
@@ -220,13 +222,11 @@ shutil.copytree(AMSS_NCKU_source_path, AMSS_NCKU_source_copy)
# Copy the generated macro files into the AMSS_NCKU source folder
macrodef_h_path = os.path.join(File_directory, "macrodef.h")
macrodef_fh_path = os.path.join(File_directory, "macrodef.fh")
build_config_path = os.path.join(File_directory, "AMSS_NCKU_build.mk")
shutil.copy2(macrodef_h_path, AMSS_NCKU_source_copy)
shutil.copy2(macrodef_fh_path, AMSS_NCKU_source_copy)
shutil.copy2(build_config_path, AMSS_NCKU_source_copy)
macrodef_h_path = os.path.join(File_directory, "macrodef.h")
macrodef_fh_path = os.path.join(File_directory, "macrodef.fh")
shutil.copy2(macrodef_h_path, AMSS_NCKU_source_copy)
shutil.copy2(macrodef_fh_path, AMSS_NCKU_source_copy)
# Notes on copying files:
# shutil.copy2 preserves file metadata such as modification time.
@@ -263,7 +263,7 @@ print()
if (input_data.GPU_Calculation == "no"):
ABE_file = os.path.join(AMSS_NCKU_source_copy, "ABE")
elif (input_data.GPU_Calculation == "yes"):
ABE_file = os.path.join(AMSS_NCKU_source_copy, "ABEGPU")
ABE_file = os.path.join(AMSS_NCKU_source_copy, "ABE_CUDA")
if not os.path.exists( ABE_file ):
print( )

26
AMSS_NCKU_source/ABE.C
View File

@@ -198,16 +198,16 @@ int main(int argc, char *argv[])
if (myrank == 0)
{
string out_dir;
char filename[50];
map<string, string>::iterator iter;
iter = parameters::str_par.find("output dir");
if (iter != parameters::str_par.end())
{
out_dir = iter->second;
}
sprintf(filename, "%s/setting.par", out_dir.c_str());
ofstream setfile;
setfile.open(filename, ios::trunc);
string filename;
map<string, string>::iterator iter;
iter = parameters::str_par.find("output dir");
if (iter != parameters::str_par.end())
{
out_dir = iter->second;
}
filename = out_dir + "/setting.par";
ofstream setfile;
setfile.open(filename.c_str(), ios::trunc);
if (!setfile.good())
{
@@ -484,7 +484,11 @@ int main(int argc, char *argv[])
cout << endl;
}
delete ADM;
// Let the process teardown reclaim the simulation object. Some derived
// equation classes keep MPI/CUDA-backed state whose destructor ordering
// is fragile at program shutdown.
if (getenv("AMSS_DELETE_ADM_ON_EXIT"))
delete ADM;
//=======================caculation done=============================================================

125
AMSS_NCKU_source/Block.C
View File

@@ -6,14 +6,68 @@
#include <cstdio>
#include <string>
#include <cmath>
#include <new>
using namespace std;
#include "Block.h"
#include "misc.h"
Block::Block(int DIM, int *shapei, double *bboxi, int ranki, int ingfsi, int fngfsi, int levi, const int cgpui) : rank(ranki), ingfs(ingfsi), fngfs(fngfsi), lev(levi), cgpu(cgpui)
{
#include <new>
using namespace std;
#include "Block.h"
#include "misc.h"
#if USE_CUDA_BSSN || USE_CUDA_Z4C
#include <cuda_runtime_api.h>
#endif
namespace {
bool cuda_pin_gridfuncs_enabled()
{
static int enabled = -1;
if (enabled < 0)
{
const char *env = getenv("AMSS_CUDA_PIN_GRIDFUNCS");
enabled = (env && atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}
double *alloc_gridfunc(size_t count, unsigned char &pinned)
{
pinned = 0;
#if USE_CUDA_BSSN || USE_CUDA_Z4C
if (cuda_pin_gridfuncs_enabled())
{
double *ptr = 0;
cudaError_t err = cudaMallocHost((void **)&ptr, count * sizeof(double));
if (err == cudaSuccess)
{
pinned = 1;
return ptr;
}
cudaGetLastError();
}
#endif
return (double *)malloc(sizeof(double) * count);
}
void free_gridfunc(double *ptr, unsigned char pinned)
{
if (!ptr)
return;
#if USE_CUDA_BSSN || USE_CUDA_Z4C
if (pinned)
{
cudaFreeHost(ptr);
return;
}
#else
(void)pinned;
#endif
free(ptr);
}
}
Block::Block(int DIM, int *shapei, double *bboxi, int ranki, int ingfsi, int fngfsi, int levi, const int cgpui) : rank(ranki), lev(levi), cgpu(cgpui), ingfs(ingfsi), fngfs(fngfsi), igfs(0), fgfs(0), fgfs_pinned(0)
{
for (int i = 0; i < dim; i++)
X[i] = 0;
@@ -68,14 +122,15 @@ Block::Block(int DIM, int *shapei, double *bboxi, int ranki, int ingfsi, int fng
#endif
}
int nn = shape[0] * shape[1] * shape[2];
fgfs = new double *[fngfs];
for (int i = 0; i < fngfs; i++)
{
fgfs[i] = (double *)malloc(sizeof(double) * nn);
if (!(fgfs[i]))
{
cout << "on node#" << rank << ", out of memory when constructing Block." << endl;
int nn = shape[0] * shape[1] * shape[2];
fgfs = new double *[fngfs];
fgfs_pinned = new unsigned char[fngfs];
for (int i = 0; i < fngfs; i++)
{
fgfs[i] = alloc_gridfunc((size_t)nn, fgfs_pinned[i]);
if (!(fgfs[i]))
{
cout << "on node#" << rank << ", out of memory when constructing Block." << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
memset(fgfs[i], 0, sizeof(double) * nn);
@@ -103,17 +158,19 @@ Block::~Block()
{
for (int i = 0; i < dim; i++)
delete[] X[i];
for (int i = 0; i < ingfs; i++)
free(igfs[i]);
delete[] igfs;
for (int i = 0; i < fngfs; i++)
free(fgfs[i]);
delete[] fgfs;
X[0] = X[1] = X[2] = 0;
igfs = 0;
fgfs = 0;
}
}
for (int i = 0; i < ingfs; i++)
free(igfs[i]);
delete[] igfs;
for (int i = 0; i < fngfs; i++)
free_gridfunc(fgfs[i], fgfs_pinned ? fgfs_pinned[i] : 0);
delete[] fgfs;
delete[] fgfs_pinned;
X[0] = X[1] = X[2] = 0;
igfs = 0;
fgfs = 0;
fgfs_pinned = 0;
}
}
void Block::checkBlock()
{
int myrank;
@@ -184,12 +241,14 @@ void Block::swapList(MyList<var> *VarList1, MyList<var> *VarList2, int myrank)
if (rank == myrank)
{
MyList<var> *varl1 = VarList1, *varl2 = VarList2;
while (varl1 && varl2)
{
misc::swap<double *>(fgfs[varl1->data->sgfn], fgfs[varl2->data->sgfn]);
varl1 = varl1->next;
varl2 = varl2->next;
}
while (varl1 && varl2)
{
misc::swap<double *>(fgfs[varl1->data->sgfn], fgfs[varl2->data->sgfn]);
if (fgfs_pinned)
misc::swap<unsigned char>(fgfs_pinned[varl1->data->sgfn], fgfs_pinned[varl2->data->sgfn]);
varl1 = varl1->next;
varl2 = varl2->next;
}
if (varl1 || varl2)
{
cout << "error in Block::swaplist, var lists does not match." << endl;

13
AMSS_NCKU_source/Block.h
View File

@@ -13,14 +13,15 @@ public:
int shape[dim];
double bbox[2 * dim];
double *X[dim];
int rank; // where the real data locate in
int lev, cgpu;
int ingfs, fngfs;
int *(*igfs);
double *(*fgfs);
int rank; // where the real data locate in
int lev, cgpu;
int ingfs, fngfs;
int *(*igfs);
double *(*fgfs);
unsigned char *fgfs_pinned;
public:
Block() {};
Block() : rank(0), lev(0), cgpu(0), ingfs(0), fngfs(0), igfs(0), fgfs(0), fgfs_pinned(0) {};
Block(int DIM, int *shapei, double *bboxi, int ranki, int ingfsi, int fngfs, int levi, const int cgpui = 0);
~Block();

735
AMSS_NCKU_source/MPatch.C
View File

@@ -11,12 +11,15 @@
using namespace std;
#include "misc.h"
#include "MPatch.h"
#include "Parallel.h"
#include "fmisc.h"
#ifdef INTERP_LB_PROFILE
#include "interp_lb_profile.h"
#endif
#include "MPatch.h"
#include "Parallel.h"
#include "fmisc.h"
#if USE_CUDA_BSSN
#include "bssn_rhs_cuda.h"
#endif
#ifdef INTERP_LB_PROFILE
#include "interp_lb_profile.h"
#endif
namespace
{
@@ -154,8 +157,8 @@ void build_block_bin_index(Patch *patch, const double *DH, BlockBinIndex &index)
index.valid = true;
}
int find_block_index_for_point(const BlockBinIndex &index, const double *pox, const double *DH)
{
int find_block_index_for_point(const BlockBinIndex &index, const double *pox, const double *DH)
{
if (!index.valid)
return -1;
@@ -175,10 +178,448 @@ int find_block_index_for_point(const BlockBinIndex &index, const double *pox, co
for (size_t bi = 0; bi < index.views.size(); bi++)
if (point_in_block_view(index.views[bi], pox, DH))
return int(bi);
return -1;
}
} // namespace
return -1;
}
inline int fortran_idint_local(double x)
{
return int(x);
}
bool interp_fast_enabled()
{
static int enabled = -1;
if (enabled < 0)
{
const char *env = getenv("AMSS_INTERP_FAST");
enabled = (!env || atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}
bool interp_gpu_enabled()
{
static int enabled = -1;
if (enabled < 0)
{
const char *env = getenv("AMSS_INTERP_GPU");
enabled = (env && atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}
bool interp_fast_compare_enabled()
{
static int enabled = -1;
if (enabled < 0)
{
const char *env = getenv("AMSS_INTERP_FAST_COMPARE");
enabled = (env && atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}
double interp_fast_compare_tol()
{
static double tol = -1.0;
if (tol < 0.0)
{
const char *env = getenv("AMSS_INTERP_FAST_COMPARE_TOL");
tol = (env && atof(env) > 0.0) ? atof(env) : 1.0e-11;
}
return tol;
}
long long interp_fast_compare_limit()
{
static long long limit = -1;
if (limit < 0)
{
const char *env = getenv("AMSS_INTERP_FAST_COMPARE_LIMIT");
limit = (env && atoll(env) > 0) ? atoll(env) : 4096;
}
return limit;
}
struct FastInterpStencil
{
int cxB[dim];
double cx[dim];
double wx[8];
double wy[8];
double wz[8];
int nsamples;
int loc[512];
unsigned char sign_mask[512];
double weight[512];
};
inline void lagrange_unit_weights(double x, int ordn, double *w)
{
for (int i = 0; i < ordn; i++)
{
double num = 1.0;
double den = 1.0;
for (int j = 0; j < ordn; j++)
{
if (j == i)
continue;
num *= (x - double(j));
den *= double(i - j);
}
w[i] = num / den;
}
}
inline void z_unit_weights(double x, int ordn, double *w)
{
if (ordn == 6)
{
static const double c_uniform[6] = {-1.0, 5.0, -10.0, 10.0, -5.0, 1.0};
for (int i = 0; i < 6; i++)
{
if (x == double(i))
{
for (int j = 0; j < 6; j++)
w[j] = (j == i) ? 1.0 : 0.0;
return;
}
}
double den = 0.0;
for (int i = 0; i < 6; i++)
{
w[i] = c_uniform[i] / (x - double(i));
den += w[i];
}
for (int i = 0; i < 6; i++)
w[i] /= den;
return;
}
lagrange_unit_weights(x, ordn, w);
}
inline bool fast_interp_map_index(int idx, int extent, int d,
int &mapped, unsigned char &mask)
{
if (idx > 0)
mapped = idx;
else
{
mask |= (unsigned char)(1u << d);
#ifdef Vertex
#ifdef Cell
#error Both Cell and Vertex are defined
#endif
mapped = 2 - idx;
#else
#ifdef Cell
mapped = 1 - idx;
#else
#error Not define Vertex nor Cell
#endif
#endif
}
return mapped >= 1 && mapped <= extent;
}
bool prepare_fast_interp_stencil(Block *BP, const double *pox, int ordn,
int Symmetry, FastInterpStencil &st)
{
if (!BP || ordn <= 0 || ordn > 8)
return false;
st.nsamples = 0;
const int NO_SYMM = 0;
const int OCTANT = 2;
int cmin[dim], cmax[dim], cxT[dim];
for (int d = 0; d < dim; d++)
{
const double *X = BP->X[d];
const double dX = X[1] - X[0];
const int cxI = fortran_idint_local((pox[d] - X[0]) / dX + 0.4) + 1;
st.cxB[d] = cxI - ordn / 2 + 1;
cxT[d] = st.cxB[d] + ordn - 1;
cmin[d] = 1;
cmax[d] = BP->shape[d];
#ifdef Vertex
#ifdef Cell
#error Both Cell and Vertex are defined
#endif
if (Symmetry == OCTANT && d < 2 && fabs(X[0]) < dX)
cmin[d] = -ordn / 2 + 2;
if (Symmetry != NO_SYMM && d == 2 && fabs(X[0]) < dX)
cmin[d] = -ordn / 2 + 2;
#else
#ifdef Cell
if (Symmetry == OCTANT && d < 2 && fabs(X[0]) < dX)
cmin[d] = -ordn / 2 + 1;
if (Symmetry != NO_SYMM && d == 2 && fabs(X[0]) < dX)
cmin[d] = -ordn / 2 + 1;
#else
#error Not define Vertex nor Cell
#endif
#endif
if (st.cxB[d] < cmin[d])
{
st.cxB[d] = cmin[d];
cxT[d] = st.cxB[d] + ordn - 1;
}
if (cxT[d] > cmax[d])
{
cxT[d] = cmax[d];
st.cxB[d] = cxT[d] + 1 - ordn;
}
if (st.cxB[d] > 0)
st.cx[d] = (pox[d] - X[st.cxB[d] - 1]) / dX;
else
{
#ifdef Vertex
#ifdef Cell
#error Both Cell and Vertex are defined
#endif
st.cx[d] = (pox[d] + X[1 - st.cxB[d]]) / dX;
#else
#ifdef Cell
st.cx[d] = (pox[d] + X[-st.cxB[d]]) / dX;
#else
#error Not define Vertex nor Cell
#endif
#endif
}
}
lagrange_unit_weights(st.cx[0], ordn, st.wx);
lagrange_unit_weights(st.cx[1], ordn, st.wy);
z_unit_weights(st.cx[2], ordn, st.wz);
for (int kk = 0; kk < ordn; kk++)
{
for (int jj = 0; jj < ordn; jj++)
{
for (int ii = 0; ii < ordn; ii++)
{
unsigned char mask = 0;
int ix, iy, iz;
if (!fast_interp_map_index(st.cxB[0] + ii, BP->shape[0], 0, ix, mask) ||
!fast_interp_map_index(st.cxB[1] + jj, BP->shape[1], 1, iy, mask) ||
!fast_interp_map_index(st.cxB[2] + kk, BP->shape[2], 2, iz, mask))
return false;
const int s = st.nsamples++;
st.loc[s] = (ix - 1) + (iy - 1) * BP->shape[0] +
(iz - 1) * BP->shape[0] * BP->shape[1];
st.sign_mask[s] = mask;
st.weight[s] = st.wx[ii] * st.wy[jj] * st.wz[kk];
}
}
}
return true;
}
bool interpolate_var_list_with_stencil(Block *BP, MyList<var> *VarList,
int num_var, const double *pox,
int ordn, int Symmetry,
const FastInterpStencil &st,
double *out)
{
if (num_var <= 0 || num_var > 128)
return false;
double *data_ptrs[128];
double *soa_ptrs[128];
var *vars[128];
MyList<var> *varl = VarList;
int k = 0;
while (varl)
{
if (k >= num_var)
return false;
vars[k] = varl->data;
data_ptrs[k] = BP->fgfs[vars[k]->sgfn];
soa_ptrs[k] = vars[k]->SoA;
out[k] = 0.0;
varl = varl->next;
k++;
}
if (k != num_var)
return false;
for (int s = 0; s < st.nsamples; s++)
{
const int loc = st.loc[s];
const double w = st.weight[s];
const unsigned char mask = st.sign_mask[s];
if (mask == 0)
{
for (int v = 0; v < num_var; v++)
out[v] += w * data_ptrs[v][loc];
}
else
{
for (int v = 0; v < num_var; v++)
{
const double *SoA = soa_ptrs[v];
double sgn = 1.0;
if (mask & 1u)
sgn *= SoA[0];
if (mask & 2u)
sgn *= SoA[1];
if (mask & 4u)
sgn *= SoA[2];
out[v] += w * sgn * data_ptrs[v][loc];
}
}
}
if (interp_fast_compare_enabled())
{
static int report_count = 0;
static long long compare_calls = 0;
if (compare_calls++ >= interp_fast_compare_limit())
return true;
const double tol = interp_fast_compare_tol();
varl = VarList;
k = 0;
while (varl)
{
var *vp = vars[k];
double ref = 0.0;
double x = pox[0], y = pox[1], z = pox[2];
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2],
BP->fgfs[vp->sgfn], ref,
x, y, z, ordn, vp->SoA, Symmetry);
const double diff = fabs(ref - out[k]);
const double scale = 1.0 + fabs(ref);
if (diff > tol * scale && report_count < 32)
{
int rank = 0;
MPI_Comm_rank(MPI_COMM_WORLD, &rank);
fprintf(stderr,
"[AMSS-INTERP-CMP][rank %d] var=%s diff=%.17e ref=%.17e fast=%.17e p=(%.17e,%.17e,%.17e)\n",
rank, vp->name, diff, ref, out[k], pox[0], pox[1], pox[2]);
report_count++;
}
varl = varl->next;
k++;
}
}
return true;
}
bool interpolate_var_list_fast(Block *BP, MyList<var> *VarList, int num_var,
const double *pox, int ordn, int Symmetry,
double *out)
{
if (!interp_fast_enabled())
return false;
FastInterpStencil st;
if (!prepare_fast_interp_stencil(BP, pox, ordn, Symmetry, st))
return false;
return interpolate_var_list_with_stencil(BP, VarList, num_var, pox,
ordn, Symmetry, st, out);
}
struct CachedInterpPoint
{
Block *bp;
int owner_rank;
FastInterpStencil stencil;
};
struct SurfaceInterpCache
{
Patch *patch;
int NN;
int symmetry;
double key[9];
vector<CachedInterpPoint> points;
SurfaceInterpCache() : patch(0), NN(0), symmetry(-1) {}
};
bool surface_cache_key_matches(const SurfaceInterpCache &cache, Patch *patch,
int NN, double **XX, int Symmetry)
{
if (cache.patch != patch || cache.NN != NN || cache.symmetry != Symmetry ||
int(cache.points.size()) != NN || NN <= 0)
return false;
const int mid = NN / 2;
const int last = NN - 1;
const int ids[3] = {0, mid, last};
int p = 0;
for (int q = 0; q < 3; q++)
for (int d = 0; d < dim; d++)
if (cache.key[p++] != XX[d][ids[q]])
return false;
return true;
}
SurfaceInterpCache *find_surface_cache(Patch *patch, int NN, double **XX,
int Symmetry)
{
static vector<SurfaceInterpCache> caches;
for (size_t i = 0; i < caches.size(); i++)
if (surface_cache_key_matches(caches[i], patch, NN, XX, Symmetry))
return &caches[i];
if (caches.size() >= 24)
caches.erase(caches.begin());
caches.push_back(SurfaceInterpCache());
return &caches.back();
}
bool build_surface_cache(SurfaceInterpCache &cache, Patch *patch, int NN,
double **XX, int Symmetry, const double *DH,
const BlockBinIndex &block_index, int ordn)
{
int myrank = 0;
MPI_Comm_rank(MPI_COMM_WORLD, &myrank);
cache.patch = patch;
cache.NN = NN;
cache.symmetry = Symmetry;
cache.points.clear();
cache.points.resize(NN);
const int mid = NN / 2;
const int last = NN - 1;
const int ids[3] = {0, mid, last};
int p = 0;
for (int q = 0; q < 3; q++)
for (int d = 0; d < dim; d++)
cache.key[p++] = XX[d][ids[q]];
for (int j = 0; j < NN; j++)
{
double pox[dim];
for (int d = 0; d < dim; d++)
pox[d] = XX[d][j];
const int block_i = find_block_index_for_point(block_index, pox, DH);
if (block_i < 0)
{
cache.points[j].bp = 0;
cache.points[j].owner_rank = -1;
continue;
}
Block *BP = block_index.views[block_i].bp;
cache.points[j].bp = BP;
cache.points[j].owner_rank = BP->rank;
cache.points[j].stencil.nsamples = 0;
if (BP->rank == myrank)
{
if (!prepare_fast_interp_stencil(BP, pox, ordn, Symmetry,
cache.points[j].stencil))
return false;
}
}
return true;
}
} // namespace
Patch::Patch(int DIM, int *shapei, double *bboxi, int levi, bool buflog, int Symmetry) : lev(levi)
{
@@ -561,22 +1002,26 @@ void Patch::Interp_Points(MyList<var> *VarList,
if (block_i >= 0)
{
Block *BP = block_index.views[block_i].bp;
owner_rank[j] = BP->rank;
if (myrank == BP->rank)
{
//---> interpolation
varl = VarList;
int k = 0;
while (varl) // run along variables
{
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2], BP->fgfs[varl->data->sgfn], Shellf[j * num_var + k],
pox[0], pox[1], pox[2], ordn, varl->data->SoA, Symmetry);
varl = varl->next;
k++;
}
}
}
}
owner_rank[j] = BP->rank;
if (myrank == BP->rank)
{
//---> interpolation
if (!interpolate_var_list_fast(BP, VarList, num_var, pox, ordn,
Symmetry, Shellf + j * num_var))
{
varl = VarList;
int k = 0;
while (varl) // run along variables
{
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2], BP->fgfs[varl->data->sgfn], Shellf[j * num_var + k],
pox[0], pox[1], pox[2], ordn, varl->data->SoA, Symmetry);
varl = varl->next;
k++;
}
}
}
}
}
// Replace MPI_Allreduce with per-owner MPI_Bcast:
// Group consecutive points by owner rank and broadcast each group.
@@ -659,10 +1104,8 @@ void Patch::Interp_Points(MyList<var> *VarList,
varl = varl->next;
}
memset(Shellf, 0, sizeof(double) * NN * num_var);
// owner_rank[j] records which MPI rank owns point j
int *owner_rank;
// owner_rank[j] records which MPI rank owns point j
int *owner_rank;
owner_rank = new int[NN];
for (int j = 0; j < NN; j++)
owner_rank[j] = -1;
@@ -670,12 +1113,117 @@ void Patch::Interp_Points(MyList<var> *VarList,
double DH[dim];
for (int i = 0; i < dim; i++)
DH[i] = getdX(i);
BlockBinIndex block_index;
build_block_bin_index(this, DH, block_index);
// --- Interpolation phase (identical to original) ---
for (int j = 0; j < NN; j++)
{
BlockBinIndex block_index;
build_block_bin_index(this, DH, block_index);
SurfaceInterpCache *surface_cache = 0;
bool use_surface_cache = false;
if (interp_fast_enabled())
{
surface_cache = find_surface_cache(this, NN, XX, Symmetry);
use_surface_cache = surface_cache_key_matches(*surface_cache, this, NN, XX, Symmetry);
if (!use_surface_cache)
use_surface_cache = build_surface_cache(*surface_cache, this, NN, XX,
Symmetry, DH, block_index, ordn);
}
// --- Interpolation phase (identical to original) ---
#if USE_CUDA_BSSN
const bool use_gpu_interp = interp_gpu_enabled() && use_surface_cache && num_var == 2 &&
VarList && VarList->next && !VarList->next->next;
#else
const bool use_gpu_interp = false;
#endif
if (use_gpu_interp)
{
#if USE_CUDA_BSSN
vector<vector<int> > local_points(block_index.views.size());
for (int j = 0; j < NN; j++)
{
for (int i = 0; i < dim; i++)
{
if (myrank == 0 && (XX[i][j] < bbox[i] + lli[i] * DH[i] || XX[i][j] > bbox[dim + i] - uui[i] * DH[i]))
{
cout << "Patch::Interp_Points: point (";
for (int k = 0; k < dim; k++)
{
cout << XX[k][j];
if (k < dim - 1)
cout << ",";
else
cout << ") is out of current Patch." << endl;
}
MPI_Abort(MPI_COMM_WORLD, 1);
}
}
CachedInterpPoint &cp = surface_cache->points[j];
Block *BP = cp.bp;
owner_rank[j] = cp.owner_rank;
if (BP && myrank == BP->rank)
{
for (size_t bi = 0; bi < block_index.views.size(); bi++)
{
if (block_index.views[bi].bp == BP)
{
local_points[bi].push_back(j);
break;
}
}
}
}
var *v0 = VarList->data;
var *v1 = VarList->next->data;
double soa6[6] = {
v0->SoA[0], v0->SoA[1], v0->SoA[2],
v1->SoA[0], v1->SoA[1], v1->SoA[2]};
for (size_t bi = 0; bi < local_points.size(); bi++)
{
const int count = int(local_points[bi].size());
if (count <= 0)
continue;
Block *BP = block_index.views[bi].bp;
vector<double> px(count), py(count), pz(count), out(2 * count);
for (int q = 0; q < count; q++)
{
const int j = local_points[bi][q];
px[q] = XX[0][j];
py[q] = XX[1][j];
pz[q] = XX[2][j];
}
const double dx = BP->X[0][1] - BP->X[0][0];
const double dy = BP->X[1][1] - BP->X[1][0];
const double dz = BP->X[2][1] - BP->X[2][0];
const int ok = bssn_cuda_interp_host_two_fields(
BP, BP->shape,
BP->fgfs[v0->sgfn], BP->fgfs[v1->sgfn],
BP->X[0][0], BP->X[1][0], BP->X[2][0],
dx, dy, dz,
&px[0], &py[0], &pz[0], count,
ordn, Symmetry, soa6, &out[0]);
if (ok != 0)
{
if (myrank == 0)
cout << "Patch::Interp_Points: CUDA two-field interpolation failed" << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
for (int q = 0; q < count; q++)
{
const int j = local_points[bi][q];
Shellf[j * num_var] = out[2 * q];
Shellf[j * num_var + 1] = out[2 * q + 1];
}
}
#endif
}
else
{
for (int j = 0; j < NN; j++)
{
double pox[dim];
for (int i = 0; i < dim; i++)
{
@@ -692,28 +1240,59 @@ void Patch::Interp_Points(MyList<var> *VarList,
cout << ") is out of current Patch." << endl;
}
MPI_Abort(MPI_COMM_WORLD, 1);
}
}
const int block_i = find_block_index_for_point(block_index, pox, DH);
if (block_i >= 0)
{
Block *BP = block_index.views[block_i].bp;
owner_rank[j] = BP->rank;
if (myrank == BP->rank)
{
varl = VarList;
int k = 0;
while (varl)
{
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2], BP->fgfs[varl->data->sgfn], Shellf[j * num_var + k],
pox[0], pox[1], pox[2], ordn, varl->data->SoA, Symmetry);
varl = varl->next;
k++;
}
}
}
}
}
}
if (use_surface_cache)
{
CachedInterpPoint &cp = surface_cache->points[j];
Block *BP = cp.bp;
owner_rank[j] = cp.owner_rank;
if (BP && myrank == BP->rank)
{
if (!interpolate_var_list_with_stencil(BP, VarList, num_var, pox,
ordn, Symmetry, cp.stencil,
Shellf + j * num_var))
{
MyList<var> *varl_fallback = VarList;
int k = 0;
while (varl_fallback)
{
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2], BP->fgfs[varl_fallback->data->sgfn], Shellf[j * num_var + k],
pox[0], pox[1], pox[2], ordn, varl_fallback->data->SoA, Symmetry);
varl_fallback = varl_fallback->next;
k++;
}
}
}
}
else
{
const int block_i = find_block_index_for_point(block_index, pox, DH);
if (block_i >= 0)
{
Block *BP = block_index.views[block_i].bp;
owner_rank[j] = BP->rank;
if (myrank == BP->rank)
{
if (!interpolate_var_list_fast(BP, VarList, num_var, pox, ordn,
Symmetry, Shellf + j * num_var))
{
MyList<var> *varl_fallback = VarList;
int k = 0;
while (varl_fallback)
{
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2], BP->fgfs[varl_fallback->data->sgfn], Shellf[j * num_var + k],
pox[0], pox[1], pox[2], ordn, varl_fallback->data->SoA, Symmetry);
varl_fallback = varl_fallback->next;
k++;
}
}
}
}
}
}
}
#ifdef INTERP_LB_PROFILE
double t_interp_end = MPI_Wtime();
@@ -965,22 +1544,26 @@ void Patch::Interp_Points(MyList<var> *VarList,
if (block_i >= 0)
{
Block *BP = block_index.views[block_i].bp;
owner_rank[j] = BP->rank;
if (myrank == BP->rank)
{
//---> interpolation
varl = VarList;
int k = 0;
while (varl) // run along variables
{
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2], BP->fgfs[varl->data->sgfn], Shellf[j * num_var + k],
pox[0], pox[1], pox[2], ordn, varl->data->SoA, Symmetry);
varl = varl->next;
k++;
}
}
}
}
owner_rank[j] = BP->rank;
if (myrank == BP->rank)
{
//---> interpolation
if (!interpolate_var_list_fast(BP, VarList, num_var, pox, ordn,
Symmetry, Shellf + j * num_var))
{
varl = VarList;
int k = 0;
while (varl) // run along variables
{
f_global_interp(BP->shape, BP->X[0], BP->X[1], BP->X[2], BP->fgfs[varl->data->sgfn], Shellf[j * num_var + k],
pox[0], pox[1], pox[2], ordn, varl->data->SoA, Symmetry);
varl = varl->next;
k++;
}
}
}
}
}
// Collect unique global owner ranks and translate to local ranks in Comm_here
// Then broadcast each owner's points via MPI_Bcast on Comm_here

16260
AMSS_NCKU_source/Parallel.C
View File

File diff suppressed because it is too large Load Diff

36
AMSS_NCKU_source/Parallel.h
View File

@@ -104,6 +104,14 @@ namespace Parallel
double **recv_bufs;
int *send_buf_caps;
int *recv_buf_caps;
unsigned char *send_buf_pinned;
unsigned char *recv_buf_pinned;
unsigned char *send_buf_is_dev;
unsigned char *recv_buf_is_dev;
int *send_buf_caps_dev;
int *recv_buf_caps_dev;
double **send_bufs_dev;
double **recv_bufs_dev;
MPI_Request *reqs;
MPI_Status *stats;
int max_reqs;
@@ -111,12 +119,14 @@ namespace Parallel
int *tc_req_node;
int *tc_req_is_recv;
int *tc_completed;
bool cuda_aware_mode;
SyncCache();
void invalidate();
void destroy();
};
void Sync_cached(MyList<Patch> *PatL, MyList<var> *VarList, int Symmetry, SyncCache &cache);
void Sync_ensure_cache(MyList<Patch> *PatL, int Symmetry, SyncCache &cache);
void transfer_cached(MyList<gridseg> **src, MyList<gridseg> **dst,
MyList<var> *VarList1, MyList<var> *VarList2,
int Symmetry, SyncCache &cache);
@@ -179,13 +189,13 @@ namespace Parallel
MyList<Parallel::gridseg> *clone_gsl(MyList<Parallel::gridseg> *p, bool first_only);
MyList<Parallel::gridseg> *build_bulk_gsl(Patch *Pat); // similar to build_owned_gsl0 but does not care rank issue
MyList<Parallel::gridseg> *build_bulk_gsl(Block *bp, Patch *Pat);
void build_PhysBD_gstl(Patch *Pat, MyList<Parallel::gridseg> *srci, MyList<Parallel::gridseg> *dsti,
MyList<Parallel::gridseg> **out_src, MyList<Parallel::gridseg> **out_dst);
void PeriodicBD(Patch *Pat, MyList<var> *VarList, int Symmetry);
double L2Norm(Patch *Pat, var *vf);
void L2Norm7(Patch *Pat, var **vf, double *norms);
void checkgsl(MyList<Parallel::gridseg> *pp, bool first_only);
void checkvarl(MyList<var> *pp, bool first_only);
void build_PhysBD_gstl(Patch *Pat, MyList<Parallel::gridseg> *srci, MyList<Parallel::gridseg> *dsti,
MyList<Parallel::gridseg> **out_src, MyList<Parallel::gridseg> **out_dst);
void PeriodicBD(Patch *Pat, MyList<var> *VarList, int Symmetry);
double L2Norm(Patch *Pat, var *vf);
void L2Norm7(Patch *Pat, var **vf, double *norms);
void checkgsl(MyList<Parallel::gridseg> *pp, bool first_only);
void checkvarl(MyList<var> *pp, bool first_only);
MyList<Parallel::gridseg> *divide_gsl(MyList<Parallel::gridseg> *p, Patch *Pat);
MyList<Parallel::gridseg> *divide_gs(MyList<Parallel::gridseg> *p, Patch *Pat);
void prepare_inter_time_level(Patch *Pat,
@@ -217,12 +227,12 @@ namespace Parallel
void aligncheck(double *bbox0, double *bboxl, int lev, double *DH0, int *shape);
bool point_locat_gsl(double *pox, MyList<Parallel::gridseg> *gsl);
void checkpatchlist(MyList<Patch> *PatL, bool buflog);
double L2Norm(Patch *Pat, var *vf, MPI_Comm Comm_here);
void L2Norm7(Patch *Pat, var **vf, double *norms, MPI_Comm Comm_here);
bool PatList_Interp_Points(MyList<Patch> *PatL, MyList<var> *VarList,
int NN, double **XX,
double *Shellf, int Symmetry, MPI_Comm Comm_here);
double L2Norm(Patch *Pat, var *vf, MPI_Comm Comm_here);
void L2Norm7(Patch *Pat, var **vf, double *norms, MPI_Comm Comm_here);
bool PatList_Interp_Points(MyList<Patch> *PatL, MyList<var> *VarList,
int NN, double **XX,
double *Shellf, int Symmetry, MPI_Comm Comm_here);
#if (PSTR == 1 || PSTR == 2 || PSTR == 3)
MyList<Block> *distribute(MyList<Patch> *PatchLIST, int cpusize, int ingfsi, int fngfsi,
bool periodic, int start_rank, int end_rank, int nodes = 0);

4
AMSS_NCKU_source/ShellPatch.C
View File

@@ -59,7 +59,7 @@ bool shell_fast_interp_enabled()
if (enabled < 0)
{
const char *env = getenv("AMSS_SHELL_FAST_INTERP");
enabled = (!env || atoi(env) != 0) ? 1 : 0;
enabled = (env && atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}
@@ -70,7 +70,7 @@ bool shell_parallel_interp_enabled()
if (enabled < 0)
{
const char *env = getenv("AMSS_SHELL_PARALLEL_INTERP");
enabled = (!env || atoi(env) != 0) ? 1 : 0;
enabled = (env && atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}

696
AMSS_NCKU_source/Z4c_class.C
View File

@@ -3,6 +3,7 @@
#include <sstream>
#include <cstdio>
#include <map>
#include <string>
using namespace std;
#else
#include <stdio.h>
@@ -28,6 +29,20 @@ using namespace std;
#include "kodiss.h"
#include "parameters.h"
#ifndef USE_CUDA_Z4C
#define USE_CUDA_Z4C 0
#endif
#if USE_CUDA_Z4C && (ABEtype == 2)
#include "z4c_rhs_cuda.h"
#endif
#if USE_CUDA_BSSN
#include "bssn_rhs_cuda.h"
#ifdef WithShell
#include "bssn_gpu.h"
#endif
#endif
#ifdef With_AHF
#include "derivatives.h"
#include "myglobal.h"
@@ -37,6 +52,81 @@ using namespace std;
// Define Z4c_class
#if USE_CUDA_Z4C && (ABEtype == 2) && defined(WithShell)
// GPU-accelerated Z4C shell RHS: same parameter signature as f_compute_rhs_Z4c_ss.
// Internally calls gpu_rhs_z4c_ss which modifies trK→trKd before upload,
// runs BSSN algebraic kernels, then applies Z4C post-processing (TZ_rhs, damping).
extern "C" {
static int cuda_compute_rhs_z4c_ss(
int *ex, double &T, double *crho, double *sigma, double *R,
double *X, double *Y, double *Z,
double *drhodx, double *drhody, double *drhodz,
double *dsigmadx, double *dsigmady, double *dsigmadz,
double *dRdx, double *dRdy, double *dRdz,
double *drhodxx, double *drhodxy, double *drhodxz, double *drhodyy, double *drhodyz, double *drhodzz,
double *dsigmadxx, double *dsigmadxy, double *dsigmadxz, double *dsigmadyy, double *dsigmadyz, double *dsigmadzz,
double *dRdxx, double *dRdxy, double *dRdxz, double *dRdyy, double *dRdyz, double *dRdzz,
double *chi, double *trK,
double *gxx, double *gxy, double *gxz, double *gyy, double *gyz, double *gzz,
double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz,
double *Gamx, double *Gamy, double *Gamz,
double *Lap, double *betax, double *betay, double *betaz,
double *dtSfx, double *dtSfy, double *dtSfz,
double *TZ,
double *chi_rhs, double *trK_rhs,
double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs,
double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs,
double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs,
double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs,
double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs,
double *TZ_rhs,
double *rho_mat, double *Sx, double *Sy, double *Sz,
double *Sxx, double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz,
double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz,
double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz,
double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz,
double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz,
double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res,
double *Gmx_Res, double *Gmy_Res, double *Gmz_Res,
int &Symmetry, int &Lev, double &eps, int &sst, int &co)
{
return gpu_rhs_z4c_ss(0, 0, // calledby=ABE_main, mpi_rank=device_0
ex, T, crho, sigma, R, X, Y, Z,
drhodx, drhody, drhodz,
dsigmadx, dsigmady, dsigmadz,
dRdx, dRdy, dRdz,
drhodxx, drhodxy, drhodxz, drhodyy, drhodyz, drhodzz,
dsigmadxx, dsigmadxy, dsigmadxz, dsigmadyy, dsigmadyz, dsigmadzz,
dRdxx, dRdxy, dRdxz, dRdyy, dRdyz, dRdzz,
chi, trK,
gxx, gxy, gxz, gyy, gyz, gzz,
Axx, Axy, Axz, Ayy, Ayz, Azz,
Gamx, Gamy, Gamz,
Lap, betax, betay, betaz,
dtSfx, dtSfy, dtSfz,
TZ,
chi_rhs, trK_rhs,
gxx_rhs, gxy_rhs, gxz_rhs, gyy_rhs, gyz_rhs, gzz_rhs,
Axx_rhs, Axy_rhs, Axz_rhs, Ayy_rhs, Ayz_rhs, Azz_rhs,
Gamx_rhs, Gamy_rhs, Gamz_rhs,
Lap_rhs, betax_rhs, betay_rhs, betaz_rhs,
dtSfx_rhs, dtSfy_rhs, dtSfz_rhs,
TZ_rhs,
rho_mat, Sx, Sy, Sz,
Sxx, Sxy, Sxz, Syy, Syz, Szz,
Gamxxx, Gamxxy, Gamxxz, Gamxyy, Gamxyz, Gamxzz,
Gamyxx, Gamyxy, Gamyxz, Gamyyy, Gamyyz, Gamyzz,
Gamzxx, Gamzxy, Gamzxz, Gamzyy, Gamzyz, Gamzzz,
Rxx, Rxy, Rxz, Ryy, Ryz, Rzz,
ham_Res, movx_Res, movy_Res, movz_Res,
Gmx_Res, Gmy_Res, Gmz_Res,
Symmetry, Lev, eps, sst, co);
}
}
// Redirect all Z4C shell RHS calls in Step/SHStep to GPU
#define f_compute_rhs_Z4c_ss cuda_compute_rhs_z4c_ss
#endif
// This class inherits some members and methods from the parent `bssn_class` and modifies others.
// The modified members and methods are defined below (and in the header Z4c_class.h).
// The remaining members/methods are inherited from `bssn_class` (declared in bssn_class.h).
@@ -132,6 +222,13 @@ void Z4c_class::Initialize()
PhysTime = StartTime;
Setup_Black_Hole_position();
}
sync_cache_pre = new Parallel::SyncCache[GH->levels];
sync_cache_cor = new Parallel::SyncCache[GH->levels];
sync_cache_rp_coarse = new Parallel::SyncCache[GH->levels];
sync_cache_rp_fine = new Parallel::SyncCache[GH->levels];
sync_cache_restrict = new Parallel::SyncCache[GH->levels];
sync_cache_outbd = new Parallel::SyncCache[GH->levels];
}
//================================================================================================
@@ -165,13 +262,581 @@ Z4c_class::~Z4c_class()
//================================================================================================
#define MRBD 0 // 0: fix BD for meshrefinement level; 1: sommerfeld_bam for them; 2: sommerfeld_yo for them
#ifndef AMSS_Z4C_MRBD
#define AMSS_Z4C_MRBD 0
#endif
#define MRBD AMSS_Z4C_MRBD // 0: fix BD for meshrefinement level; 1: sommerfeld_bam for them; 2: sommerfeld_yo for them
#ifndef CPBC
// for sommerfeld boundary
#if USE_CUDA_Z4C && (ABEtype == 2)
#if (MRBD == 2)
#error "USE_CUDA_Z4C resident path does not support MRBD == 2"
#endif
namespace {
static const int k_z4c_cuda_bh_state_indices[3] = {18, 19, 20};
bool fill_z4c_cuda_views(Block *cg, MyList<var> *vars,
double **host_views,
double *propspeeds = 0,
double *soa_flat = 0)
{
int idx = 0;
while (vars && idx < Z4C_CUDA_STATE_COUNT)
{
host_views[idx] = cg->fgfs[vars->data->sgfn];
if (propspeeds)
propspeeds[idx] = vars->data->propspeed;
if (soa_flat)
{
soa_flat[3 * idx + 0] = vars->data->SoA[0];
soa_flat[3 * idx + 1] = vars->data->SoA[1];
soa_flat[3 * idx + 2] = vars->data->SoA[2];
}
vars = vars->next;
++idx;
}
return idx == Z4C_CUDA_STATE_COUNT && vars == 0;
}
void z4c_cuda_download_level_state(MyList<Patch> *PatL, MyList<var> *vars, int myrank, bool release_ctx)
{
MyList<Patch> *Pp = PatL;
while (Pp)
{
MyList<Block> *BP = Pp->data->blb;
while (BP)
{
Block *cg = BP->data;
if (myrank == cg->rank && z4c_cuda_has_resident_state(cg))
{
double *state_out[Z4C_CUDA_STATE_COUNT];
if (!fill_z4c_cuda_views(cg, vars, state_out))
{
cout << "CUDA Z4C state list mismatch on resident state download" << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
if (z4c_cuda_download_resident_state(cg, cg->shape, state_out))
{
cout << "CUDA Z4C resident state download failed" << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
if (release_ctx)
z4c_cuda_release_step_ctx(cg);
}
if (BP == Pp->data->ble)
break;
BP = BP->next;
}
Pp = Pp->next;
}
}
bool z4c_cuda_patch_contains_point(Patch *patch, const double *point)
{
if (!patch)
return false;
for (int d = 0; d < dim; d++)
{
const double h = patch->getdX(d);
const double lo = patch->bbox[d] + patch->lli[d] * h;
const double hi = patch->bbox[dim + d] - patch->uui[d] * h;
if (point[d] < lo || point[d] > hi)
return false;
}
return true;
}
bool z4c_cuda_point_in_block(Patch *patch, Block *block,
const double *point, const double *DH)
{
if (!patch || !block)
return false;
for (int d = 0; d < dim; d++)
{
double llb;
double uub;
#ifdef Vertex
#ifdef Cell
#error Both Cell and Vertex are defined
#endif
llb = (feq(block->bbox[d], patch->bbox[d], DH[d] / 2))
? block->bbox[d] + patch->lli[d] * DH[d]
: block->bbox[d] + (ghost_width - 0.5) * DH[d];
uub = (feq(block->bbox[dim + d], patch->bbox[dim + d], DH[d] / 2))
? block->bbox[dim + d] - patch->uui[d] * DH[d]
: block->bbox[dim + d] - (ghost_width - 0.5) * DH[d];
#else
#ifdef Cell
llb = (feq(block->bbox[d], patch->bbox[d], DH[d] / 2))
? block->bbox[d] + patch->lli[d] * DH[d]
: block->bbox[d] + ghost_width * DH[d];
uub = (feq(block->bbox[dim + d], patch->bbox[dim + d], DH[d] / 2))
? block->bbox[dim + d] - patch->uui[d] * DH[d]
: block->bbox[dim + d] - ghost_width * DH[d];
#else
#error Not define Vertex nor Cell
#endif
#endif
if (point[d] - llb < -DH[d] / 2 || point[d] - uub > DH[d] / 2)
return false;
}
return true;
}
int z4c_cuda_interp_tile_start(const double *coords, int n, double x, double dx, int ordn)
{
if (!coords || n <= ordn)
return 0;
int cxi = int((x - coords[0]) / dx + 0.4) + 1;
int start = cxi - ordn / 2;
if (start < 0)
start = 0;
const int max_start = n - ordn;
if (start > max_start)
start = max_start;
return start;
}
bool z4c_cuda_interp_bh_point_resident(MyList<Patch> *PatL,
int myrank,
const double *point,
var *forx, var *fory, var *forz,
int Symmetry,
double *shellf)
{
const int ordn = 2 * ghost_width;
int owner_rank = -1;
shellf[0] = shellf[1] = shellf[2] = 0.0;
MyList<Patch> *PL = PatL;
while (PL)
{
Patch *patch = PL->data;
if (!z4c_cuda_patch_contains_point(patch, point))
{
PL = PL->next;
continue;
}
double DH[dim];
for (int d = 0; d < dim; d++)
DH[d] = patch->getdX(d);
MyList<Block> *BP = patch->blb;
while (BP)
{
Block *block = BP->data;
if (z4c_cuda_point_in_block(patch, block, point, DH))
{
owner_rank = block->rank;
if (myrank == owner_rank)
{
int interp_ordn = ordn;
int interp_sym = Symmetry;
double x = point[0];
double y = point[1];
double z = point[2];
if (z4c_cuda_has_resident_state(block) &&
block->shape[0] >= ordn && block->shape[1] >= ordn && block->shape[2] >= ordn)
{
const int sx = ordn;
const int sy = ordn;
const int sz = ordn;
const int region_all = sx * sy * sz;
const int i0 = z4c_cuda_interp_tile_start(block->X[0], block->shape[0], x, DH[0], ordn);
const int j0 = z4c_cuda_interp_tile_start(block->X[1], block->shape[1], y, DH[1], ordn);
const int k0 = z4c_cuda_interp_tile_start(block->X[2], block->shape[2], z, DH[2], ordn);
double *packed_fields = new double[3 * region_all];
var *vars[3] = {forx, fory, forz};
for (int f = 0; f < 3; f++)
{
if (z4c_cuda_pack_state_region_to_host_buffer(block,
k_z4c_cuda_bh_state_indices[f],
packed_fields + f * region_all,
block->shape,
i0, j0, k0,
sx, sy, sz) != 0)
{
delete[] packed_fields;
cout << "CUDA Z4C BH tile download failed" << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
int tile_shape[3] = {sx, sy, sz};
f_global_interp(tile_shape,
block->X[0] + i0,
block->X[1] + j0,
block->X[2] + k0,
packed_fields + f * region_all,
shellf[f],
x, y, z,
interp_ordn,
vars[f]->SoA,
interp_sym);
}
delete[] packed_fields;
}
else
{
f_global_interp(block->shape, block->X[0], block->X[1], block->X[2],
block->fgfs[forx->sgfn], shellf[0],
x, y, z, interp_ordn, forx->SoA, interp_sym);
f_global_interp(block->shape, block->X[0], block->X[1], block->X[2],
block->fgfs[fory->sgfn], shellf[1],
x, y, z, interp_ordn, fory->SoA, interp_sym);
f_global_interp(block->shape, block->X[0], block->X[1], block->X[2],
block->fgfs[forz->sgfn], shellf[2],
x, y, z, interp_ordn, forz->SoA, interp_sym);
}
}
break;
}
if (BP == patch->ble)
break;
BP = BP->next;
}
if (owner_rank >= 0)
break;
PL = PL->next;
}
if (owner_rank < 0)
return false;
MPI_Bcast(shellf, 3, MPI_DOUBLE, owner_rank, MPI_COMM_WORLD);
return true;
}
bool z4c_cuda_compute_porg_rhs_resident(cgh *GH,
int ilev,
int myrank,
int BH_num,
double **BH_PS,
double **BH_RHS,
var *forx, var *fory, var *forz,
int Symmetry)
{
for (int n = 0; n < BH_num; n++)
{
double shellf[3] = {0.0, 0.0, 0.0};
int lev = ilev;
while (lev >= 0 &&
!z4c_cuda_interp_bh_point_resident(GH->PatL[lev], myrank, BH_PS[n],
forx, fory, forz, Symmetry, shellf))
{
--lev;
}
if (lev < 0)
return false;
BH_RHS[n][0] = -shellf[0];
BH_RHS[n][1] = -shellf[1];
BH_RHS[n][2] = -shellf[2];
}
return true;
}
bool z4c_cuda_resident_step_enabled()
{
static int enabled = -1;
if (enabled < 0)
{
const char *env = getenv("AMSS_Z4C_CUDA_RESIDENT");
enabled = (env && atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}
} // namespace
#endif
void Z4c_class::Step(int lev, int YN)
{
#if USE_CUDA_Z4C && (ABEtype == 2)
double dT_lev = dT * pow(0.5, Mymax(lev, trfls));
#ifdef With_AHF
AH_Step_Find(lev, dT_lev);
#endif
bool BB = fgt(PhysTime, StartTime, dT_lev / 2);
double ndeps = numepss;
if (lev < GH->movls)
ndeps = numepsb;
double TRK4 = PhysTime;
int iter_count = 0;
int pre = 0, cor = 1;
int ERROR = 0;
#ifdef WithShell
if (bssn_cuda_use_resident_sync(lev))
{
for (int dl = 0; dl < GH->levels; dl++)
bssn_cuda_download_level_state_if_present(GH->PatL[dl], StateList, myrank);
}
#endif
MyList<Patch> *Pp = GH->PatL[lev];
while (Pp)
{
MyList<Block> *BP = Pp->data->blb;
while (BP)
{
Block *cg = BP->data;
if (myrank == cg->rank)
{
double *state_in[Z4C_CUDA_STATE_COUNT];
double *state_out[Z4C_CUDA_STATE_COUNT];
double propspeed[Z4C_CUDA_STATE_COUNT];
double soa_flat[3 * Z4C_CUDA_STATE_COUNT];
if (!fill_z4c_cuda_views(cg, StateList, state_in, propspeed, soa_flat) ||
!fill_z4c_cuda_views(cg, SynchList_pre, state_out))
{
cout << "CUDA Z4C state list mismatch on predictor step" << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
int apply_bam_bc = 0;
#if (MRBD == 0)
#if (SommerType == 0)
apply_bam_bc = (lev == 0) ? 1 : 0;
#endif
#elif (MRBD == 1)
apply_bam_bc = 1;
#endif
int keep_resident_state = z4c_cuda_resident_step_enabled() ? 1 : 0;
int apply_enforce_ga = 0;
#if (AGM == 0)
apply_enforce_ga = 1;
#endif
if (z4c_cuda_rk4_substep(cg,
cg->shape, cg->X[0], cg->X[1], cg->X[2],
state_in, state_out,
propspeed, soa_flat, Pp->data->bbox,
dT_lev, TRK4, iter_count, apply_bam_bc,
Symmetry, lev, ndeps, pre,
keep_resident_state, apply_enforce_ga, chitiny))
{
cout << "CUDA Z4C predictor substep failed in domain: ("
<< cg->bbox[0] << ":" << cg->bbox[3] << ","
<< cg->bbox[1] << ":" << cg->bbox[4] << ","
<< cg->bbox[2] << ":" << cg->bbox[5] << ")" << endl;
ERROR = 1;
}
}
if (BP == Pp->data->ble)
break;
BP = BP->next;
}
Pp = Pp->next;
}
{
int erh = ERROR;
MPI_Allreduce(&erh, &ERROR, 1, MPI_INT, MPI_SUM, MPI_COMM_WORLD);
}
if (ERROR)
{
if (myrank == 0 && ErrorMonitor->outfile)
ErrorMonitor->outfile << "CUDA Z4C failed in predictor at t = " << PhysTime
<< ", lev = " << lev << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
Parallel::Sync_cached(GH->PatL[lev], SynchList_pre, Symmetry, sync_cache_pre[lev]);
if (BH_num > 0 && lev == GH->levels - 1)
{
compute_Porg_rhs(Porg0, Porg_rhs, Sfx0, Sfy0, Sfz0, lev);
for (int ithBH = 0; ithBH < BH_num; ithBH++)
{
f_rungekutta4_scalar(dT_lev, Porg0[ithBH][0], Porg[ithBH][0], Porg_rhs[ithBH][0], iter_count);
f_rungekutta4_scalar(dT_lev, Porg0[ithBH][1], Porg[ithBH][1], Porg_rhs[ithBH][1], iter_count);
f_rungekutta4_scalar(dT_lev, Porg0[ithBH][2], Porg[ithBH][2], Porg_rhs[ithBH][2], iter_count);
if (Symmetry > 0)
Porg[ithBH][2] = fabs(Porg[ithBH][2]);
if (Symmetry == 2)
{
Porg[ithBH][0] = fabs(Porg[ithBH][0]);
Porg[ithBH][1] = fabs(Porg[ithBH][1]);
}
}
}
if ((lev == a_lev) && (LastAnas + dT_lev >= AnasTime))
z4c_cuda_download_level_state(GH->PatL[lev], SynchList_pre, myrank, false);
if (lev == a_lev)
AnalysisStuff(lev, dT_lev);
for (iter_count = 1; iter_count < 4; iter_count++)
{
if (iter_count == 1 || iter_count == 3)
TRK4 += dT_lev / 2;
Pp = GH->PatL[lev];
while (Pp)
{
MyList<Block> *BP = Pp->data->blb;
while (BP)
{
Block *cg = BP->data;
if (myrank == cg->rank)
{
double *state_in[Z4C_CUDA_STATE_COUNT];
double *state_out[Z4C_CUDA_STATE_COUNT];
double propspeed[Z4C_CUDA_STATE_COUNT];
double soa_flat[3 * Z4C_CUDA_STATE_COUNT];
if (!fill_z4c_cuda_views(cg, SynchList_pre, state_in, propspeed, soa_flat) ||
!fill_z4c_cuda_views(cg, SynchList_cor, state_out))
{
cout << "CUDA Z4C state list mismatch on corrector step" << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
int apply_bam_bc = 0;
#if (MRBD == 0)
#if (SommerType == 0)
apply_bam_bc = (lev == 0) ? 1 : 0;
#endif
#elif (MRBD == 1)
apply_bam_bc = 1;
#endif
int keep_resident_state = z4c_cuda_resident_step_enabled() ? 1 : 0;
int apply_enforce_ga = 0;
#if (AGM == 0)
apply_enforce_ga = 1;
#elif (AGM == 1)
apply_enforce_ga = (iter_count == 3) ? 1 : 0;
#endif
if (z4c_cuda_rk4_substep(cg,
cg->shape, cg->X[0], cg->X[1], cg->X[2],
state_in, state_out,
propspeed, soa_flat, Pp->data->bbox,
dT_lev, TRK4, iter_count, apply_bam_bc,
Symmetry, lev, ndeps, cor,
keep_resident_state, apply_enforce_ga, chitiny))
{
cout << "CUDA Z4C corrector substep failed in domain: ("
<< cg->bbox[0] << ":" << cg->bbox[3] << ","
<< cg->bbox[1] << ":" << cg->bbox[4] << ","
<< cg->bbox[2] << ":" << cg->bbox[5] << ")" << endl;
ERROR = 1;
}
}
if (BP == Pp->data->ble)
break;
BP = BP->next;
}
Pp = Pp->next;
}
{
int erh = ERROR;
MPI_Allreduce(&erh, &ERROR, 1, MPI_INT, MPI_SUM, MPI_COMM_WORLD);
}
if (ERROR)
{
if (myrank == 0 && ErrorMonitor->outfile)
ErrorMonitor->outfile << "CUDA Z4C failed in RK4 substep#" << iter_count
<< " at t = " << PhysTime
<< ", lev = " << lev << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
Parallel::Sync_cached(GH->PatL[lev], SynchList_cor, Symmetry, sync_cache_cor[lev]);
if (BH_num > 0 && lev == GH->levels - 1)
{
if (z4c_cuda_resident_step_enabled())
{
if (!z4c_cuda_compute_porg_rhs_resident(GH, lev, myrank, BH_num,
Porg, Porg1,
Sfx, Sfy, Sfz, Symmetry))
{
if (myrank == 0 && ErrorMonitor->outfile)
ErrorMonitor->outfile << "CUDA Z4C failed to interpolate black-hole shift at t = "
<< PhysTime << endl;
MPI_Abort(MPI_COMM_WORLD, 1);
}
}
else
{
compute_Porg_rhs(Porg, Porg1, Sfx, Sfy, Sfz, lev);
}
for (int ithBH = 0; ithBH < BH_num; ithBH++)
{
f_rungekutta4_scalar(dT_lev, Porg0[ithBH][0], Porg1[ithBH][0], Porg_rhs[ithBH][0], iter_count);
f_rungekutta4_scalar(dT_lev, Porg0[ithBH][1], Porg1[ithBH][1], Porg_rhs[ithBH][1], iter_count);
f_rungekutta4_scalar(dT_lev, Porg0[ithBH][2], Porg1[ithBH][2], Porg_rhs[ithBH][2], iter_count);
if (Symmetry > 0)
Porg1[ithBH][2] = fabs(Porg1[ithBH][2]);
if (Symmetry == 2)
{
Porg1[ithBH][0] = fabs(Porg1[ithBH][0]);
Porg1[ithBH][1] = fabs(Porg1[ithBH][1]);
}
}
}
if (iter_count < 3)
{
Pp = GH->PatL[lev];
while (Pp)
{
MyList<Block> *BP = Pp->data->blb;
while (BP)
{
Block *cg = BP->data;
cg->swapList(SynchList_pre, SynchList_cor, myrank);
if (BP == Pp->data->ble)
break;
BP = BP->next;
}
Pp = Pp->next;
}
if (BH_num > 0 && lev == GH->levels - 1)
{
for (int ithBH = 0; ithBH < BH_num; ithBH++)
{
Porg[ithBH][0] = Porg1[ithBH][0];
Porg[ithBH][1] = Porg1[ithBH][1];
Porg[ithBH][2] = Porg1[ithBH][2];
}
}
}
}
z4c_cuda_download_level_state(GH->PatL[lev], SynchList_cor, myrank, false);
#if (RPS == 0)
RestrictProlong(lev, YN, BB);
#endif
Pp = GH->PatL[lev];
while (Pp)
{
MyList<Block> *BP = Pp->data->blb;
while (BP)
{
Block *cg = BP->data;
cg->swapList(StateList, SynchList_cor, myrank);
cg->swapList(OldStateList, SynchList_cor, myrank);
if (BP == Pp->data->ble)
break;
BP = BP->next;
}
Pp = Pp->next;
}
if (BH_num > 0 && lev == GH->levels - 1)
{
for (int ithBH = 0; ithBH < BH_num; ithBH++)
{
Porg0[ithBH][0] = Porg1[ithBH][0];
Porg0[ithBH][1] = Porg1[ithBH][1];
Porg0[ithBH][2] = Porg1[ithBH][2];
}
}
#else
double dT_lev = dT * pow(0.5, Mymax(lev, trfls));
#ifdef With_AHF
AH_Step_Find(lev, dT_lev);
@@ -339,6 +1004,13 @@ void Z4c_class::Step(int lev, int YN)
}
#ifdef WithShell
#if USE_CUDA_Z4C
if (bssn_cuda_use_resident_sync(lev))
{
for (int dl = 0; dl < GH->levels; dl++)
bssn_cuda_download_level_state_if_present(GH->PatL[dl], StateList, myrank);
}
#endif
// evolve Shell Patches
if (lev == 0)
{
@@ -1042,9 +1714,11 @@ void Z4c_class::Step(int lev, int YN)
Porg0[ithBH][2] = Porg1[ithBH][2];
}
}
#endif
}
#else
// for constraint preserving boundary (CPBC)
// Note: CPBC path uses CPU Fortran RHS; GPU resident sync is a no-op here.
#ifndef WithShell
#error "CPBC only supports Shell"
#endif
@@ -1074,6 +1748,14 @@ void Z4c_class::Step(int lev, int YN)
int pre = 0, cor = 1;
int ERROR = 0;
#if USE_CUDA_Z4C && defined(WithShell)
if (bssn_cuda_use_resident_sync(lev))
{
for (int dl = 0; dl < GH->levels; dl++)
bssn_cuda_download_level_state_if_present(GH->PatL[dl], StateList, myrank);
}
#endif
MyList<ss_patch> *sPp;
// Predictor
MyList<Patch> *Pp = GH->PatL[lev];
@@ -2404,6 +3086,11 @@ void Z4c_class::Check_extrop()
//================================================================================================
#if USE_CUDA_Z4C && (ABEtype == 2) && defined(WithShell)
#undef f_compute_rhs_Z4c_ss
#define f_compute_rhs_Z4c_ss compute_rhs_z4c_ss_
#endif
// this member function is used to compute and output constraint violation
//================================================================================================
@@ -2679,11 +3366,12 @@ void Z4c_class::Interp_Constraint()
}
ofstream outfile;
char filename[50];
sprintf(filename, "%s/interp_constraint_%05d.dat", ErrorMonitor->out_dir.c_str(), int(PhysTime / dT + 0.5));
char suffix[64];
sprintf(suffix, "/interp_constraint_%05d.dat", int(PhysTime / dT + 0.5));
string filename = ErrorMonitor->out_dir + suffix;
// 0.5 for round off
outfile.open(filename);
outfile.open(filename.c_str());
outfile << "# corrdinate, H_Res, Px_Res, Py_Res, Pz_Res, Gx_Res, Gy_Res, Gz_Res, ...." << endl;
for (int i = 0; i < n; i++)
{

1034
AMSS_NCKU_source/bssnEM_class.C
View File

File diff suppressed because it is too large Load Diff

1158
AMSS_NCKU_source/bssnEScalar_class.C
View File

File diff suppressed because it is too large Load Diff

2
AMSS_NCKU_source/bssnEScalar_class.h
View File

@@ -51,7 +51,7 @@ public:
void Compute_Psi4(int lev);
void Step(int lev, int YN);
void AnalysisStuff_EScalar(int lev, double dT_lev);
void Interp_Constraint(bool infg);
void Interp_Constraint();
void Constraint_Out();
protected:

17681
AMSS_NCKU_source/bssn_class.C
View File

File diff suppressed because it is too large Load Diff

48
AMSS_NCKU_source/bssn_class.h
View File

@@ -31,19 +31,11 @@ using namespace std;
#include "surface_integral.h"
#include "checkpoint.h"
extern void setpbh(int iBHN, double **iPBH, double *iMass, int rBHN);
#ifndef BSSN_USE_TRANSFER_CACHE
#define BSSN_USE_TRANSFER_CACHE 1
#endif
#ifndef BSSN_USE_ESCALAR_C_KERNEL
#define BSSN_USE_ESCALAR_C_KERNEL 1
#endif
class bssn_class
{
public:
extern void setpbh(int iBHN, double **iPBH, double *iMass, int rBHN);
class bssn_class
{
public:
int ngfs;
int nprocs, myrank;
cgh *GH;
@@ -56,6 +48,7 @@ public:
double StartTime, TotalTime;
double AnasTime, DumpTime, d2DumpTime, CheckTime;
double LastAnas, LastConsOut;
bool cuda_level0_constraint_cache_valid;
int *ConstraintRefreshLevels;
double Courant;
double numepss, numepsb, numepsh;
@@ -151,7 +144,7 @@ public:
bssn_class(double Couranti, double StartTimei, double TotalTimei, double DumpTimei, double d2DumpTimei, double CheckTimei, double AnasTimei,
int Symmetryi, int checkruni, char *checkfilenamei, double numepssi, double numepsbi, double numepshi,
int a_levi, int maxli, int decni, double maxrexi, double drexi);
~bssn_class();
virtual ~bssn_class();
void Evolve(int Steps);
void RecursiveStep(int lev);
@@ -175,25 +168,14 @@ public:
void Setup_KerrSchild();
void Enforce_algcon(int lev, int fg);
void testRestrict();
void testOutBd();
bool check_Stdin_Abort();
bool use_transfer_cache() const;
void setup_transfer_caches();
void invalidate_transfer_caches();
void destroy_transfer_caches();
void sync_predictor_start(int lev, MyList<var> *VarList, Parallel::AsyncSyncState &async_state);
void sync_predictor_finish(int lev, Parallel::AsyncSyncState &async_state, MyList<var> *VarList);
void sync_corrector_start(int lev, MyList<var> *VarList, Parallel::AsyncSyncState &async_state);
void sync_corrector_finish(int lev, Parallel::AsyncSyncState &async_state, MyList<var> *VarList);
void sync_evolution(int lev, MyList<var> *VarList, Parallel::SyncCache *cache_array = 0);
void restrict_evolution(int lev, MyList<var> *src_var_list, MyList<var> *dst_var_list);
void outbdlow2hi_evolution(int lev, MyList<var> *src_var_list, MyList<var> *dst_var_list);
virtual void Setup_Initial_Data_Cao();
virtual void Setup_Initial_Data_Lousto();
virtual void Initialize();
void testRestrict();
void testOutBd();
bool check_Stdin_Abort();
virtual void Setup_Initial_Data_Cao();
virtual void Setup_Initial_Data_Lousto();
virtual void Initialize();
virtual void Read_Ansorg();
virtual void Read_Pablo() {};
virtual void Compute_Psi4(int lev);

323
AMSS_NCKU_source/bssn_em_rhs_c.C
View File

@@ -1,323 +0,0 @@
#include "macrodef.h"
#include "bssn_rhs.h"
#include "share_func.h"
#include "tool.h"
#include <cstddef>
/*
* C 版 BSSN-EM RHS kernel — replaces empart.f90 + bssn_rhs.f90 for BSSN+Maxwell.
*
* Computes:
* 1. All metric and EM field derivatives
* 2. Physical metric, Christoffel-like terms
* 3. EM field RHS (E, B, Kpsi, Kphi)
* 4. Stress-energy tensor (rho, Si, Sij)
* 5. Calls f_compute_rhs_bssn (C BSSN RHS) with stress-energy
* 6. Advection + KO dissipation for EM fields
* 7. NaN check
*/
int f_compute_rhs_bssn_em_c(int *ex, double &T,
double *X, double *Y, double *Z,
double *chi, double *trK,
double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz,
double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz,
double *Gamx, double *Gamy, double *Gamz,
double *Lap, double *betax, double *betay, double *betaz,
double *dtSfx, double *dtSfy, double *dtSfz,
double *Ex, double *Ey, double *Ez,
double *Bx, double *By, double *Bz,
double *Kpsi, double *Kphi,
double *Jx, double *Jy, double *Jz, double *qchar,
double *chi_rhs, double *trK_rhs,
double *gxx_rhs, double *gxy_rhs, double *gxz_rhs,
double *gyy_rhs, double *gyz_rhs, double *gzz_rhs,
double *Axx_rhs, double *Axy_rhs, double *Axz_rhs,
double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs,
double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs,
double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs,
double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs,
double *Ex_rhs, double *Ey_rhs, double *Ez_rhs,
double *Bx_rhs, double *By_rhs, double *Bz_rhs,
double *Kpsi_rhs, double *Kphi_rhs,
double *rho, double *Sx, double *Sy, double *Sz,
double *Sxx, double *Sxy, double *Sxz,
double *Syy, double *Syz, double *Szz,
double *Gamxxx, double *Gamxxy, double *Gamxxz,
double *Gamxyy, double *Gamxyz, double *Gamxzz,
double *Gamyxx, double *Gamyxy, double *Gamyxz,
double *Gamyyy, double *Gamyyz, double *Gamyzz,
double *Gamzxx, double *Gamzxy, double *Gamzxz,
double *Gamzyy, double *Gamzyz, double *Gamzzz,
double *Rxx, double *Rxy, double *Rxz,
double *Ryy, double *Ryz, double *Rzz,
double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res,
double *Gmx_Res, double *Gmy_Res, double *Gmz_Res,
int &Symmetry, int &Lev, double &eps, int &co)
{
(void)T;
int gont = 0;
const int nx = ex[0], ny = ex[1], nz = ex[2];
const int all = nx * ny * nz;
const size_t n = (size_t)all;
const double ZEO = 0.0, ONE = 1.0, TWO = 2.0, FOUR = 4.0, EIT = 8.0;
const double HALF = 0.5, THR = 3.0, F3o2 = 1.5, PI = 3.14159265358979323846;
const double SYM = 1.0, ANTI = -1.0;
const double kappa = 1.0;
const double SSS[3]={SYM,SYM,SYM}, AAS[3]={ANTI,ANTI,SYM};
const double ASA[3]={ANTI,SYM,ANTI}, SAA[3]={SYM,ANTI,ANTI};
const double ASS[3]={ANTI,SYM,SYM}, SAS[3]={SYM,ANTI,SYM};
const double SSA[3]={SYM,SYM,ANTI};
/* ---- allocate temporary arrays ---- */
double *chix = (double*)malloc(n*sizeof(double));
double *chiy = (double*)malloc(n*sizeof(double));
double *chiz = (double*)malloc(n*sizeof(double));
double *Exx=(double*)malloc(n*sizeof(double)),*Exy=(double*)malloc(n*sizeof(double)),*Exz=(double*)malloc(n*sizeof(double));
double *Eyx=(double*)malloc(n*sizeof(double)),*Eyy=(double*)malloc(n*sizeof(double)),*Eyz=(double*)malloc(n*sizeof(double));
double *Ezx=(double*)malloc(n*sizeof(double)),*Ezy=(double*)malloc(n*sizeof(double)),*Ezz=(double*)malloc(n*sizeof(double));
double *Bxx=(double*)malloc(n*sizeof(double)),*Bxy=(double*)malloc(n*sizeof(double)),*Bxz=(double*)malloc(n*sizeof(double));
double *Byx=(double*)malloc(n*sizeof(double)),*Byy=(double*)malloc(n*sizeof(double)),*Byz=(double*)malloc(n*sizeof(double));
double *Bzx=(double*)malloc(n*sizeof(double)),*Bzy=(double*)malloc(n*sizeof(double)),*Bzz=(double*)malloc(n*sizeof(double));
double *Kpsix=(double*)malloc(n*sizeof(double)),*Kpsiy=(double*)malloc(n*sizeof(double)),*Kpsiz=(double*)malloc(n*sizeof(double));
double *Kphix=(double*)malloc(n*sizeof(double)),*Kphiy=(double*)malloc(n*sizeof(double)),*Kphiz=(double*)malloc(n*sizeof(double));
double *Lapx=(double*)malloc(n*sizeof(double)),*Lapy=(double*)malloc(n*sizeof(double)),*Lapz=(double*)malloc(n*sizeof(double));
double *betaxx=(double*)malloc(n*sizeof(double)),*betaxy=(double*)malloc(n*sizeof(double)),*betaxz=(double*)malloc(n*sizeof(double));
double *betayx=(double*)malloc(n*sizeof(double)),*betayy=(double*)malloc(n*sizeof(double)),*betayz=(double*)malloc(n*sizeof(double));
double *betazx=(double*)malloc(n*sizeof(double)),*betazy=(double*)malloc(n*sizeof(double)),*betazz=(double*)malloc(n*sizeof(double));
double *gxxx=(double*)malloc(n*sizeof(double)),*gxxy=(double*)malloc(n*sizeof(double)),*gxxz=(double*)malloc(n*sizeof(double));
double *gxyx=(double*)malloc(n*sizeof(double)),*gxyy=(double*)malloc(n*sizeof(double)),*gxyz=(double*)malloc(n*sizeof(double));
double *gxzx=(double*)malloc(n*sizeof(double)),*gxzy=(double*)malloc(n*sizeof(double)),*gxzz=(double*)malloc(n*sizeof(double));
double *gyyx=(double*)malloc(n*sizeof(double)),*gyyy=(double*)malloc(n*sizeof(double)),*gyyz=(double*)malloc(n*sizeof(double));
double *gyzx=(double*)malloc(n*sizeof(double)),*gyzy=(double*)malloc(n*sizeof(double)),*gyzz=(double*)malloc(n*sizeof(double));
double *gzzx=(double*)malloc(n*sizeof(double)),*gzzy=(double*)malloc(n*sizeof(double)),*gzzz=(double*)malloc(n*sizeof(double));
double *gupxx=(double*)malloc(n*sizeof(double)),*gupxy=(double*)malloc(n*sizeof(double)),*gupxz=(double*)malloc(n*sizeof(double));
double *gupyy=(double*)malloc(n*sizeof(double)),*gupyz=(double*)malloc(n*sizeof(double)),*gupzz=(double*)malloc(n*sizeof(double));
if (!chix||!chiy||!chiz||!Exx||!Exy||!Exz||!Eyx||!Eyy||!Eyz||!Ezx||!Ezy||!Ezz||
!Bxx||!Bxy||!Bxz||!Byx||!Byy||!Byz||!Bzx||!Bzy||!Bzz||
!Kpsix||!Kpsiy||!Kpsiz||!Kphix||!Kphiy||!Kphiz||
!Lapx||!Lapy||!Lapz||
!betaxx||!betaxy||!betaxz||!betayx||!betayy||!betayz||!betazx||!betazy||!betazz||
!gxxx||!gxxy||!gxxz||!gxyx||!gxyy||!gxyz||!gxzx||!gxzy||!gxzz||
!gyyx||!gyyy||!gyyz||!gyzx||!gyzy||!gyzz||!gzzx||!gzzy||!gzzz||
!gupxx||!gupxy||!gupxz||!gupyy||!gupyz||!gupzz) {
gont = 1;
}
/* ==== 1. Compute all derivatives ==== */
if (!gont) {
/* metric derivatives */
fderivs(ex, Lap, Lapx, Lapy, Lapz, X, Y, Z, SYM, SYM, SYM, Symmetry, Lev);
fderivs(ex, betax, betaxx, betaxy, betaxz, X, Y, Z, ANTI, SYM, SYM, Symmetry, Lev);
fderivs(ex, betay, betayx, betayy, betayz, X, Y, Z, SYM, ANTI, SYM, Symmetry, Lev);
fderivs(ex, betaz, betazx, betazy, betazz, X, Y, Z, SYM, SYM, ANTI, Symmetry, Lev);
fderivs(ex, chi, chix, chiy, chiz, X, Y, Z, SYM, SYM, SYM, Symmetry, Lev);
fderivs(ex, dxx, gxxx, gxxy, gxxz, X, Y, Z, SYM, SYM, SYM, Symmetry, Lev);
fderivs(ex, gxy, gxyx, gxyy, gxyz, X, Y, Z, ANTI, ANTI, SYM, Symmetry, Lev);
fderivs(ex, gxz, gxzx, gxzy, gxzz, X, Y, Z, ANTI, SYM, ANTI, Symmetry, Lev);
fderivs(ex, dyy, gyyx, gyyy, gyyz, X, Y, Z, SYM, SYM, SYM, Symmetry, Lev);
fderivs(ex, gyz, gyzx, gyzy, gyzz, X, Y, Z, SYM, ANTI, ANTI, Symmetry, Lev);
fderivs(ex, dzz, gzzx, gzzy, gzzz, X, Y, Z, SYM, SYM, SYM, Symmetry, Lev);
/* EM field derivatives */
fderivs(ex, Kpsi, Kpsix, Kpsiy, Kpsiz, X, Y, Z, SYM, SYM, SYM, Symmetry, Lev);
fderivs(ex, Kphi, Kphix, Kphiy, Kphiz, X, Y, Z, SYM, SYM, SYM, Symmetry, Lev);
fderivs(ex, Ex, Exx, Exy, Exz, X, Y, Z, ANTI, SYM, SYM, Symmetry, Lev);
fderivs(ex, Ey, Eyx, Eyy, Eyz, X, Y, Z, SYM, ANTI, SYM, Symmetry, Lev);
fderivs(ex, Ez, Ezx, Ezy, Ezz, X, Y, Z, SYM, SYM, ANTI, Symmetry, Lev);
fderivs(ex, Bx, Bxx, Bxy, Bxz, X, Y, Z, SYM, ANTI, ANTI, Symmetry, Lev);
fderivs(ex, By, Byx, Byy, Byz, X, Y, Z, ANTI, SYM, ANTI, Symmetry, Lev);
fderivs(ex, Bz, Bzx, Bzy, Bzz, X, Y, Z, ANTI, ANTI, SYM, Symmetry, Lev);
/* ==== 2. Compute EM RHS and stress-energy ==== */
const double F1o4PI = ONE / (FOUR * PI);
for (size_t i = 0; i < n; ++i) {
const double alpn1 = Lap[i] + ONE;
const double chin1 = chi[i] + ONE;
const double chi3o2 = sqrt(chin1) * chin1; // chi^{3/2}
const double ichi = ONE / chin1;
/* physical metric */
const double pgxx = (dxx[i] + ONE) * ichi;
const double pgyy = (dyy[i] + ONE) * ichi;
const double pgzz = (dzz[i] + ONE) * ichi;
const double pgxy = gxy[i] * ichi;
const double pgxz = gxz[i] * ichi;
const double pgyz = gyz[i] * ichi;
/* inverse physical metric */
const double det = pgxx * pgyy * pgzz + pgxy * pgyz * pgxz + pgxz * pgxy * pgyz
- pgxz * pgyy * pgxz - pgxy * pgxy * pgzz - pgxx * pgyz * pgyz;
const double idet = ONE / det;
const double upxx = (pgyy * pgzz - pgyz * pgyz) * idet;
const double upxy = -(pgxy * pgzz - pgyz * pgxz) * idet;
const double upxz = (pgxy * pgyz - pgyy * pgxz) * idet;
const double upyy = (pgxx * pgzz - pgxz * pgxz) * idet;
const double upyz = -(pgxx * pgyz - pgxy * pgxz) * idet;
const double upzz = (pgxx * pgyy - pgxy * pgxy) * idet;
gupxx[i]=upxx; gupxy[i]=upxy; gupxz[i]=upxz;
gupyy[i]=upyy; gupyz[i]=upyz; gupzz[i]=upzz;
/* E-field RHS */
/* curl(B) part: epsilon^{ijk} ∂_j (alpha * B_k) in coordinate basis */
/* Using lower-index B fields: B_i_lower = pg_{ij} * B^j */
const double BxL = pgxx*Bx[i] + pgxy*By[i] + pgxz*Bz[i];
const double ByL = pgxy*Bx[i] + pgyy*By[i] + pgyz*Bz[i];
const double BzL = pgxz*Bx[i] + pgyz*By[i] + pgzz*Bz[i];
/* Physical metric derivatives (chain rule from conformal) */
const double pgxx_x = (gxxx[i] - pgxx*chix[i]) * ichi;
/* const double pgxx_y = (gxxy[i] - pgxx*chiy[i]) * ichi; */
const double pgxy_x = (gxyx[i] - pgxy*chix[i]) * ichi;
const double pgxy_y = (gxyy[i] - pgxy*chiy[i]) * ichi;
const double pgxz_x = (gxzx[i] - pgxz*chix[i]) * ichi;
const double pgxz_z = (gxzz[i] - pgxz*chiz[i]) * ichi;
const double pgyy_y = (gyyy[i] - pgyy*chiy[i]) * ichi;
const double pgyz_y = (gyzy[i] - pgyz*chiy[i]) * ichi;
const double pgyz_z = (gyzz[i] - pgyz*chiz[i]) * ichi;
const double pgzz_z = (gzzz[i] - pgzz*chiz[i]) * ichi;
/* Curl_x(B) = ∂_y (alpha*BzL) - ∂_z (alpha*ByL) */
const double aBx = alpn1*BxL, aBy = alpn1*ByL, aBz = alpn1*BzL;
const double curlBx = (aBz*Lapy[i] + alpn1*(pgxz*Bxy[i]+pgyz*Byy[i]+pgzz*Bzy[i]) + alpn1*(Bx[i]*gxzy[i]+By[i]*gyzy[i]+Bz[i]*gzzy[i]))
- (aBy*Lapz[i] + alpn1*(pgxy*Bxz[i]+pgyy*Byz[i]+pgyz*Bzz[i]) + alpn1*(Bx[i]*gxyz[i]+By[i]*gyyz[i]+Bz[i]*gyzz[i]));
double curlBy = (aBx*Lapz[i] + alpn1*(pgxx*Bxz[i]+pgxy*Byz[i]+pgxz*Bzz[i]) + alpn1*(Bx[i]*gxxz[i]+By[i]*gxyz[i]+Bz[i]*gxzz[i]))
- (aBz*Lapx[i] + alpn1*(pgxz*Bxx[i]+pgyz*Byx[i]+pgzz*Bzx[i]) + alpn1*(Bx[i]*gxzx[i]+By[i]*gyzx[i]+Bz[i]*gzzx[i]));
double curlBz = (aBy*Lapx[i] + alpn1*(pgxy*Bxx[i]+pgyy*Byx[i]+pgyz*Bzx[i]) + alpn1*(Bx[i]*gxyx[i]+By[i]*gyyx[i]+Bz[i]*gyzx[i]))
- (aBx*Lapy[i] + alpn1*(pgxx*Bxy[i]+pgxy*Byy[i]+pgxz*Bzy[i]) + alpn1*(Bx[i]*gxxy[i]+By[i]*gxyy[i]+Bz[i]*gxzy[i]));
/* Advection part: -beta^j * ∂_j E^i */
const double advEx = Ex[i]*betaxx[i] + Ey[i]*betaxy[i] + Ez[i]*betaxz[i];
const double advEy = Ex[i]*betayx[i] + Ey[i]*betayy[i] + Ez[i]*betayz[i];
const double advEz = Ex[i]*betazx[i] + Ey[i]*betazy[i] + Ez[i]*betazz[i];
/* grad(Kpsi) contracted with inverse metric */
const double gupKx = upxx*Kpsix[i] + upxy*Kpsiy[i] + upxz*Kpsiz[i];
const double gupKy = upxy*Kpsix[i] + upyy*Kpsiy[i] + upyz*Kpsiz[i];
const double gupKz = upxz*Kpsix[i] + upyz*Kpsiy[i] + upzz*Kpsiz[i];
Ex_rhs[i] = alpn1*trK[i]*Ex[i] - advEx - FOUR*PI*alpn1*Jx[i] - alpn1*gupKx + chi3o2*curlBx;
Ey_rhs[i] = alpn1*trK[i]*Ey[i] - advEy - FOUR*PI*alpn1*Jy[i] - alpn1*gupKy + chi3o2*curlBy;
Ez_rhs[i] = alpn1*trK[i]*Ez[i] - advEz - FOUR*PI*alpn1*Jz[i] - alpn1*gupKz + chi3o2*curlBz;
/* B-field RHS: similar but with -chi^{3/2} * curl(E) and grad(Kphi) */
const double ExL = pgxx*Ex[i] + pgxy*Ey[i] + pgxz*Ez[i];
const double EyL = pgxy*Ex[i] + pgyy*Ey[i] + pgyz*Ez[i];
const double EzL = pgxz*Ex[i] + pgyz*Ey[i] + pgzz*Ez[i];
const double aEx = alpn1*ExL, aEy = alpn1*EyL, aEz = alpn1*EzL;
const double curlEx = (aEz*Lapy[i] + alpn1*(pgxz*Exy[i]+pgyz*Eyy[i]+pgzz*Ezy[i]) + alpn1*(Ex[i]*gxzy[i]+Ey[i]*gyzy[i]+Ez[i]*gzzy[i]))
- (aEy*Lapz[i] + alpn1*(pgxy*Exz[i]+pgyy*Eyz[i]+pgyz*Ezz[i]) + alpn1*(Ex[i]*gxyz[i]+Ey[i]*gyyz[i]+Ez[i]*gyzz[i]));
double curlEy = (aEx*Lapz[i] + alpn1*(pgxx*Exz[i]+pgxy*Eyz[i]+pgxz*Ezz[i]) + alpn1*(Ex[i]*gxxz[i]+Ey[i]*gxyz[i]+Ez[i]*gxzz[i]))
- (aEz*Lapx[i] + alpn1*(pgxz*Exx[i]+pgyz*Eyx[i]+pgzz*Ezx[i]) + alpn1*(Ex[i]*gxzx[i]+Ey[i]*gyzx[i]+Ez[i]*gzzx[i]));
double curlEz = (aEy*Lapx[i] + alpn1*(pgxy*Exx[i]+pgyy*Eyx[i]+pgyz*Ezx[i]) + alpn1*(Ex[i]*gxyx[i]+Ey[i]*gyyx[i]+Ez[i]*gyzx[i]))
- (aEx*Lapy[i] + alpn1*(pgxx*Exy[i]+pgxy*Eyy[i]+pgxz*Ezy[i]) + alpn1*(Ex[i]*gxxy[i]+Ey[i]*gxyy[i]+Ez[i]*gxzy[i]));
const double advBx = Bx[i]*betaxx[i] + By[i]*betaxy[i] + Bz[i]*betaxz[i];
const double advBy = Bx[i]*betayx[i] + By[i]*betayy[i] + Bz[i]*betayz[i];
const double advBz = Bx[i]*betazx[i] + By[i]*betazy[i] + Bz[i]*betazz[i];
const double gupKphix = upxx*Kphix[i] + upxy*Kphiy[i] + upxz*Kphiz[i];
const double gupKphiy = upxy*Kphix[i] + upyy*Kphiy[i] + upyz*Kphiz[i];
const double gupKphiz = upxz*Kphix[i] + upyz*Kphiy[i] + upzz*Kphiz[i];
Bx_rhs[i] = alpn1*trK[i]*Bx[i] - advBx - alpn1*gupKphix - chi3o2*curlEx;
By_rhs[i] = alpn1*trK[i]*By[i] - advBy - alpn1*gupKphiy - chi3o2*curlEy;
Bz_rhs[i] = alpn1*trK[i]*Bz[i] - advBz - alpn1*gupKphiz - chi3o2*curlEz;
/* Scalar potential RHS */
const double divE = Exx[i] + Eyy[i] + Ezz[i];
const double divB = Bxx[i] + Byy[i] + Bzz[i];
const double chiCont = F3o2 * ichi * (chix[i]*Ex[i] + chiy[i]*Ey[i] + chiz[i]*Ez[i]);
Kpsi_rhs[i] = FOUR*PI*alpn1*qchar[i] - alpn1*kappa*Kpsi[i] - alpn1*(divE - chiCont);
Kphi_rhs[i] = -alpn1*kappa*Kphi[i] - alpn1*(divB - F3o2*ichi*(chix[i]*Bx[i] + chiy[i]*By[i] + chiz[i]*Bz[i]));
/* Stress-energy tensor */
const double E2 = pgxx*Ex[i]*Ex[i] + pgyy*Ey[i]*Ey[i] + pgzz*Ez[i]*Ez[i]
+ TWO*(pgxy*Ex[i]*Ey[i] + pgxz*Ex[i]*Ez[i] + pgyz*Ey[i]*Ez[i]);
const double B2 = pgxx*Bx[i]*Bx[i] + pgyy*By[i]*By[i] + pgzz*Bz[i]*Bz[i]
+ TWO*(pgxy*Bx[i]*By[i] + pgxz*Bx[i]*Bz[i] + pgyz*By[i]*Bz[i]);
rho[i] = (E2 + B2) / (EIT * PI);
const double ichi3o2 = ONE / chi3o2;
Sx[i] = (Ey[i]*Bz[i] - Ez[i]*By[i]) * F1o4PI * ichi3o2;
Sy[i] = (Ez[i]*Bx[i] - Ex[i]*Bz[i]) * F1o4PI * ichi3o2;
Sz[i] = (Ex[i]*By[i] - Ey[i]*Bx[i]) * F1o4PI * ichi3o2;
const double lExi = pgxx*Ex[i] + pgxy*Ey[i] + pgxz*Ez[i];
const double lEyi = pgxy*Ex[i] + pgyy*Ey[i] + pgyz*Ez[i];
const double lEzi = pgxz*Ex[i] + pgyz*Ey[i] + pgzz*Ez[i];
const double lBxi = pgxx*Bx[i] + pgxy*By[i] + pgxz*Bz[i];
const double lByi = pgxy*Bx[i] + pgyy*By[i] + pgyz*Bz[i];
const double lBzi = pgxz*Bx[i] + pgyz*By[i] + pgzz*Bz[i];
Sxx[i] = rho[i]*pgxx - (lExi*lExi + lBxi*lBxi) * F1o4PI;
Sxy[i] = rho[i]*pgxy - (lExi*lEyi + lBxi*lByi) * F1o4PI;
Sxz[i] = rho[i]*pgxz - (lExi*lEzi + lBxi*lBzi) * F1o4PI;
Syy[i] = rho[i]*pgyy - (lEyi*lEyi + lByi*lByi) * F1o4PI;
Syz[i] = rho[i]*pgyz - (lEyi*lEzi + lByi*lBzi) * F1o4PI;
Szz[i] = rho[i]*pgzz - (lEzi*lEzi + lBzi*lBzi) * F1o4PI;
}
/* ==== 3. Call BSSN RHS with EM stress-energy ==== */
gont = f_compute_rhs_bssn(ex, T, X, Y, Z,
chi, trK, dxx, gxy, gxz, dyy, gyz, dzz,
Axx, Axy, Axz, Ayy, Ayz, Azz,
Gamx, Gamy, Gamz, Lap, betax, betay, betaz, dtSfx, dtSfy, dtSfz,
chi_rhs, trK_rhs,
gxx_rhs, gxy_rhs, gxz_rhs, gyy_rhs, gyz_rhs, gzz_rhs,
Axx_rhs, Axy_rhs, Axz_rhs, Ayy_rhs, Ayz_rhs, Azz_rhs,
Gamx_rhs, Gamy_rhs, Gamz_rhs, Lap_rhs, betax_rhs, betay_rhs, betaz_rhs,
dtSfx_rhs, dtSfy_rhs, dtSfz_rhs,
rho, Sx, Sy, Sz, Sxx, Sxy, Sxz, Syy, Syz, Szz,
Gamxxx, Gamxxy, Gamxxz, Gamxyy, Gamxyz, Gamxzz,
Gamyxx, Gamyxy, Gamyxz, Gamyyy, Gamyyz, Gamyzz,
Gamzxx, Gamzxy, Gamzxz, Gamzyy, Gamzyz, Gamzzz,
Rxx, Rxy, Rxz, Ryy, Ryz, Rzz,
ham_Res, movx_Res, movy_Res, movz_Res,
Gmx_Res, Gmy_Res, Gmz_Res,
Symmetry, Lev, eps, co);
if (!gont) {
/* ==== 4. Advection terms for EM fields ==== */
lopsided(ex, X, Y, Z, Kpsi, Kpsi_rhs, betax, betay, betaz, Symmetry, SSS);
lopsided(ex, X, Y, Z, Kphi, Kphi_rhs, betax, betay, betaz, Symmetry, SSS);
lopsided(ex, X, Y, Z, Ex, Ex_rhs, betax, betay, betaz, Symmetry, ASS);
lopsided(ex, X, Y, Z, Ey, Ey_rhs, betax, betay, betaz, Symmetry, SAS);
lopsided(ex, X, Y, Z, Ez, Ez_rhs, betax, betay, betaz, Symmetry, SSA);
lopsided(ex, X, Y, Z, Bx, Bx_rhs, betax, betay, betaz, Symmetry, SAA);
lopsided(ex, X, Y, Z, By, By_rhs, betax, betay, betaz, Symmetry, ASA);
lopsided(ex, X, Y, Z, Bz, Bz_rhs, betax, betay, betaz, Symmetry, AAS);
/* ==== 5. KO dissipation for EM fields ==== */
if (eps > ZEO) {
kodis(ex, X, Y, Z, Kpsi, Kpsi_rhs, SSS, Symmetry, eps);
kodis(ex, X, Y, Z, Kphi, Kphi_rhs, SSS, Symmetry, eps);
kodis(ex, X, Y, Z, Ex, Ex_rhs, ASS, Symmetry, eps);
kodis(ex, X, Y, Z, Ey, Ey_rhs, SAS, Symmetry, eps);
kodis(ex, X, Y, Z, Ez, Ez_rhs, SSA, Symmetry, eps);
kodis(ex, X, Y, Z, Bx, Bx_rhs, SAA, Symmetry, eps);
kodis(ex, X, Y, Z, By, By_rhs, ASA, Symmetry, eps);
kodis(ex, X, Y, Z, Bz, Bz_rhs, AAS, Symmetry, eps);
}
/* ==== 6. NaN check ==== */
for (int i = 0; i < all; ++i) {
if (!isfinite(Ex_rhs[i]+Ey_rhs[i]+Ez_rhs[i]+Bx_rhs[i]+By_rhs[i]+Bz_rhs[i]+Kpsi_rhs[i]+Kphi_rhs[i])) {
gont = 1; break;
}
}
} /* inner if (!gont) */
} /* outer if (!gont) */
free(chix);free(chiy);free(chiz);
free(Exx);free(Exy);free(Exz);free(Eyx);free(Eyy);free(Eyz);free(Ezx);free(Ezy);free(Ezz);
free(Bxx);free(Bxy);free(Bxz);free(Byx);free(Byy);free(Byz);free(Bzx);free(Bzy);free(Bzz);
free(Kpsix);free(Kpsiy);free(Kpsiz);
free(Kphix);free(Kphiy);free(Kphiz);
free(Lapx);free(Lapy);free(Lapz);
free(betaxx);free(betaxy);free(betaxz);free(betayx);free(betayy);free(betayz);free(betazx);free(betazy);free(betazz);
free(gxxx);free(gxxy);free(gxxz);free(gxyx);free(gxyy);free(gxyz);free(gxzx);free(gxzy);free(gxzz);
free(gyyx);free(gyyy);free(gyyz);free(gyzx);free(gyzy);free(gyzz);free(gzzx);free(gzzy);free(gzzz);
free(gupxx);free(gupxy);free(gupxz);free(gupyy);free(gupyz);free(gupzz);
return gont;
}

169
AMSS_NCKU_source/bssn_escalar_rhs_c.C
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@@ -1,169 +0,0 @@
#include "macrodef.h"
#include "bssn_rhs.h"
#include "share_func.h"
#include "tool.h"
#include <vector>
namespace
{
// Reuse the temporary workspace across block calls to avoid repeated heap churn
// in the EScalar wrapper. MPI ranks execute this path sequentially, so a single
// process-local buffer is sufficient here.
std::vector<double> g_escalar_tmp_store;
}
#ifdef fortran1
#define f_frpotential frpotential
#endif
#ifdef fortran2
#define f_frpotential FRPOTENTIAL
#endif
#ifdef fortran3
#define f_frpotential frpotential_
#endif
extern "C"
{
void f_frpotential(int *, double *, double *, double *);
}
int f_compute_rhs_bssn_escalar_c(int *ex, double &T,
double *X, double *Y, double *Z,
double *chi, double *trK,
double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz,
double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz,
double *Gamx, double *Gamy, double *Gamz,
double *Lap, double *betax, double *betay, double *betaz,
double *dtSfx, double *dtSfy, double *dtSfz,
double *Sphi, double *Spi,
double *chi_rhs, double *trK_rhs,
double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs,
double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs,
double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs,
double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs,
double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs,
double *Sphi_rhs, double *Spi_rhs,
double *rho, double *Sx, double *Sy, double *Sz,
double *Sxx, double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz,
double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz,
double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz,
double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz,
double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz,
double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res,
double *Gmx_Res, double *Gmy_Res, double *Gmz_Res,
int &Symmetry, int &Lev, double &eps, int &co)
{
const int nx = ex[0], ny = ex[1], nz = ex[2];
const int all = nx * ny * nz;
const size_t workspace_size = size_t(all) * 17;
if (g_escalar_tmp_store.size() < workspace_size)
g_escalar_tmp_store.resize(workspace_size);
double *tmp_ptr = g_escalar_tmp_store.data();
auto alloc_tmp = [&](int n = 1) -> double *
{
double *ptr = tmp_ptr;
tmp_ptr += size_t(all) * n;
return ptr;
};
double *chix = alloc_tmp(), *chiy = alloc_tmp(), *chiz = alloc_tmp();
double *Kx = alloc_tmp(), *Ky = alloc_tmp(), *Kz = alloc_tmp();
double *fxx = alloc_tmp(), *fxy = alloc_tmp(), *fxz = alloc_tmp();
double *fyy = alloc_tmp(), *fyz = alloc_tmp(), *fzz = alloc_tmp();
double *Lapx = alloc_tmp(), *Lapy = alloc_tmp(), *Lapz = alloc_tmp();
double *V = alloc_tmp(), *dVdSphi = alloc_tmp();
const double ZEO = 0.0, ONE = 1.0, TWO = 2.0, HALF = 0.5;
const double SSS[3] = {1.0, 1.0, 1.0};
fderivs(ex, chi, chix, chiy, chiz, X, Y, Z, 1.0, 1.0, 1.0, Symmetry, Lev);
fderivs(ex, Lap, Lapx, Lapy, Lapz, X, Y, Z, 1.0, 1.0, 1.0, Symmetry, Lev);
fderivs(ex, Sphi, Kx, Ky, Kz, X, Y, Z, 1.0, 1.0, 1.0, Symmetry, Lev);
fdderivs(ex, Sphi, fxx, fxy, fxz, fyy, fyz, fzz, X, Y, Z, 1.0, 1.0, 1.0, Symmetry, Lev);
f_frpotential(ex, Sphi, V, dVdSphi);
for (int i = 0; i < all; ++i)
{
const double alpn1 = Lap[i] + ONE;
const double chin1 = chi[i] + ONE;
const double gxx = dxx[i] + ONE;
const double gyy = dyy[i] + ONE;
const double gzz = dzz[i] + ONE;
const double det = gxx * gyy * gzz + gxy[i] * gyz[i] * gxz[i] + gxz[i] * gxy[i] * gyz[i]
- gxz[i] * gyy * gxz[i] - gxy[i] * gxy[i] * gzz - gxx * gyz[i] * gyz[i];
const double gupxx = (gyy * gzz - gyz[i] * gyz[i]) / det;
const double gupxy = -(gxy[i] * gzz - gyz[i] * gxz[i]) / det;
const double gupxz = (gxy[i] * gyz[i] - gyy * gxz[i]) / det;
const double gupyy = (gxx * gzz - gxz[i] * gxz[i]) / det;
const double gupyz = -(gxx * gyz[i] - gxy[i] * gxz[i]) / det;
const double gupzz = (gxx * gyy - gxy[i] * gxy[i]) / det;
Sphi_rhs[i] = alpn1 * Spi[i];
Spi_rhs[i] = gupxx * fxx[i] + gupyy * fyy[i] + gupzz * fzz[i]
+ TWO * (gupxy * fxy[i] + gupxz * fxz[i] + gupyz * fyz[i])
- ((Gamx[i] + (gupxx * chix[i] + gupxy * chiy[i] + gupxz * chiz[i]) / TWO / chin1) * Kx[i]
+ (Gamy[i] + (gupxy * chix[i] + gupyy * chiy[i] + gupyz * chiz[i]) / TWO / chin1) * Ky[i]
+ (Gamz[i] + (gupxz * chix[i] + gupyz * chiy[i] + gupzz * chiz[i]) / TWO / chin1) * Kz[i]);
Spi_rhs[i] = Spi_rhs[i] * alpn1
+ gupxx * Lapx[i] * Kx[i] + gupxy * Lapx[i] * Ky[i] + gupxz * Lapx[i] * Kz[i]
+ gupxy * Lapy[i] * Kx[i] + gupyy * Lapy[i] * Ky[i] + gupyz * Lapy[i] * Kz[i]
+ gupxz * Lapz[i] * Kx[i] + gupyz * Lapz[i] * Ky[i] + gupzz * Lapz[i] * Kz[i];
Spi_rhs[i] = Spi_rhs[i] * chin1 + alpn1 * (trK[i] * Spi[i] - dVdSphi[i]);
rho[i] = chin1 * ((gupxx * Kx[i] * Kx[i] + gupyy * Ky[i] * Ky[i] + gupzz * Kz[i] * Kz[i]) * HALF
+ gupxy * Kx[i] * Ky[i] + gupxz * Kx[i] * Kz[i] + gupyz * Ky[i] * Kz[i])
+ Spi[i] * Spi[i] * HALF + V[i];
Sx[i] = -Spi[i] * Kx[i];
Sy[i] = -Spi[i] * Ky[i];
Sz[i] = -Spi[i] * Kz[i];
const double pressure = (rho[i] - Spi[i] * Spi[i]) / chin1;
Sxx[i] = Kx[i] * Kx[i] - pressure * gxx;
Sxy[i] = Kx[i] * Ky[i] - pressure * gxy[i];
Sxz[i] = Kx[i] * Kz[i] - pressure * gxz[i];
Syy[i] = Ky[i] * Ky[i] - pressure * gyy;
Syz[i] = Ky[i] * Kz[i] - pressure * gyz[i];
Szz[i] = Kz[i] * Kz[i] - pressure * gzz;
}
if (f_compute_rhs_bssn(ex, T, X, Y, Z,
chi, trK,
dxx, gxy, gxz, dyy, gyz, dzz,
Axx, Axy, Axz, Ayy, Ayz, Azz,
Gamx, Gamy, Gamz,
Lap, betax, betay, betaz,
dtSfx, dtSfy, dtSfz,
chi_rhs, trK_rhs,
gxx_rhs, gxy_rhs, gxz_rhs, gyy_rhs, gyz_rhs, gzz_rhs,
Axx_rhs, Axy_rhs, Axz_rhs, Ayy_rhs, Ayz_rhs, Azz_rhs,
Gamx_rhs, Gamy_rhs, Gamz_rhs,
Lap_rhs, betax_rhs, betay_rhs, betaz_rhs,
dtSfx_rhs, dtSfy_rhs, dtSfz_rhs,
rho, Sx, Sy, Sz,
Sxx, Sxy, Sxz, Syy, Syz, Szz,
Gamxxx, Gamxxy, Gamxxz, Gamxyy, Gamxyz, Gamxzz,
Gamyxx, Gamyxy, Gamyxz, Gamyyy, Gamyyz, Gamyzz,
Gamzxx, Gamzxy, Gamzxz, Gamzyy, Gamzyz, Gamzzz,
Rxx, Rxy, Rxz, Ryy, Ryz, Rzz,
ham_Res, movx_Res, movy_Res, movz_Res,
Gmx_Res, Gmy_Res, Gmz_Res,
Symmetry, Lev, eps, co))
return 1;
lopsided_kodis(ex, X, Y, Z, Sphi, Sphi_rhs, betax, betay, betaz, Symmetry, SSS, eps);
lopsided_kodis(ex, X, Y, Z, Spi, Spi_rhs, betax, betay, betaz, Symmetry, SSS, eps);
for (int i = 0; i < all; ++i)
{
if (Sphi_rhs[i] != Sphi_rhs[i] || Spi_rhs[i] != Spi_rhs[i] || rho[i] != rho[i])
return 1;
}
return 0;
}

2908
AMSS_NCKU_source/bssn_gpu.cu
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129
AMSS_NCKU_source/bssn_gpu.h
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@@ -1,73 +1,56 @@
#ifndef BSSN_GPU_H_
#define BSSN_GPU_H_
#include "bssn_macro.h"
#include "macrodef.fh"
#define DEVICE_ID 0
// #define DEVICE_ID_BY_MPI_RANK
#define GRID_DIM 256
#define BLOCK_DIM 128
#define _FH2_(i, j, k) fh[(i) + (j) * _1D_SIZE[2] + (k) * _2D_SIZE[2]]
#define _FH3_(i, j, k) fh[(i) + (j) * _1D_SIZE[3] + (k) * _2D_SIZE[3]]
#define pow2(x) ((x) * (x))
#define TimeBetween(a, b) ((b.tv_sec - a.tv_sec) + (b.tv_usec - a.tv_usec) / 1000000.0f)
#define M_ metac.
#define Mh_ meta->
#define Ms_ metassc.
#define Msh_ metass->
// #define TIMING
#define RHS_SS_PARA int calledby, int mpi_rank, int *ex, double &T, double *crho, double *sigma, double *R, double *X, double *Y, double *Z, double *drhodx, double *drhody, double *drhodz, double *dsigmadx, double *dsigmady, double *dsigmadz, double *dRdx, double *dRdy, double *dRdz, double *drhodxx, double *drhodxy, double *drhodxz, double *drhodyy, double *drhodyz, double *drhodzz, double *dsigmadxx, double *dsigmadxy, double *dsigmadxz, double *dsigmadyy, double *dsigmadyz, double *dsigmadzz, double *dRdxx, double *dRdxy, double *dRdxz, double *dRdyy, double *dRdyz, double *dRdzz, double *chi, double *trK, double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz, double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz, double *Gamx, double *Gamy, double *Gamz, double *Lap, double *betax, double *betay, double *betaz, double *dtSfx, double *dtSfy, double *dtSfz, double *chi_rhs, double *trK_rhs, double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs, double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs, double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs, double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs, double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs, double *rho, double *Sx, double *Sy, double *Sz, double *Sxx, double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz, double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz, double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz, double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz, double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz, double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res, double *Gmx_Res, double *Gmy_Res, double *Gmz_Res, int &Symmetry, int &Lev, double &eps, int &sst, int &co
/** main function */
int gpu_rhs(int calledby, int mpi_rank, int *ex, double &T,
double *X, double *Y, double *Z,
double *chi, double *trK,
double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz,
double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz,
double *Gamx, double *Gamy, double *Gamz,
double *Lap, double *betax, double *betay, double *betaz,
double *dtSfx, double *dtSfy, double *dtSfz,
double *chi_rhs, double *trK_rhs,
double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs,
double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs,
double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs,
double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs,
double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs,
double *rho, double *Sx, double *Sy, double *Sz, double *Sxx,
double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz,
double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz,
double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz,
double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz,
double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz,
double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res,
double *Gmx_Res, double *Gmy_Res, double *Gmz_Res,
int &Symmetry, int &Lev, double &eps, int &co);
int gpu_rhs_ss(RHS_SS_PARA);
/** Init GPU side data in GPUMeta. */
// void init_fluid_meta_gpu(GPUMeta *gpu_meta);
#endif
#ifndef BSSN_GPU_H_
#define BSSN_GPU_H_
#include "bssn_macro.h"
#include "macrodef.h"
#define DEVICE_ID 0
// #define DEVICE_ID_BY_MPI_RANK
#define GRID_DIM 256
#define BLOCK_DIM 128
#define _FH2_(i, j, k) fh[(i) + (j) * _1D_SIZE[2] + (k) * _2D_SIZE[2]]
#define _FH3_(i, j, k) fh[(i) + (j) * _1D_SIZE[3] + (k) * _2D_SIZE[3]]
#define pow2(x) ((x) * (x))
#define TimeBetween(a, b) ((b.tv_sec - a.tv_sec) + (b.tv_usec - a.tv_usec) / 1000000.0f)
#define M_ metac.
#define Mh_ meta->
#define Ms_ metassc.
#define Msh_ metass->
// #define TIMING
#define RHS_SS_PARA int calledby, int mpi_rank, int *ex, double &T, double *crho, double *sigma, double *R, double *X, double *Y, double *Z, double *drhodx, double *drhody, double *drhodz, double *dsigmadx, double *dsigmady, double *dsigmadz, double *dRdx, double *dRdy, double *dRdz, double *drhodxx, double *drhodxy, double *drhodxz, double *drhodyy, double *drhodyz, double *drhodzz, double *dsigmadxx, double *dsigmadxy, double *dsigmadxz, double *dsigmadyy, double *dsigmadyz, double *dsigmadzz, double *dRdxx, double *dRdxy, double *dRdxz, double *dRdyy, double *dRdyz, double *dRdzz, double *chi, double *trK, double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz, double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz, double *Gamx, double *Gamy, double *Gamz, double *Lap, double *betax, double *betay, double *betaz, double *dtSfx, double *dtSfy, double *dtSfz, double *chi_rhs, double *trK_rhs, double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs, double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs, double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs, double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs, double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs, double *rho, double *Sx, double *Sy, double *Sz, double *Sxx, double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz, double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz, double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz, double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz, double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz, double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res, double *Gmx_Res, double *Gmy_Res, double *Gmz_Res, int &Symmetry, int &Lev, double &eps, int &sst, int &co
/** main function */
int gpu_rhs(int calledby, int mpi_rank, int *ex, double &T,
double *X, double *Y, double *Z,
double *chi, double *trK,
double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz,
double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz,
double *Gamx, double *Gamy, double *Gamz,
double *Lap, double *betax, double *betay, double *betaz,
double *dtSfx, double *dtSfy, double *dtSfz,
double *chi_rhs, double *trK_rhs,
double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs,
double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs,
double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs,
double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs,
double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs,
double *rho, double *Sx, double *Sy, double *Sz, double *Sxx,
double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz,
double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz,
double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz,
double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz,
double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz,
double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res,
double *Gmx_Res, double *Gmy_Res, double *Gmz_Res,
int &Symmetry, int &Lev, double &eps, int &co);
int gpu_rhs_ss(RHS_SS_PARA);
#define Z4C_SS_PARA int calledby, int mpi_rank, int *ex, double &T, double *crho, double *sigma, double *R, double *X, double *Y, double *Z, double *drhodx, double *drhody, double *drhodz, double *dsigmadx, double *dsigmady, double *dsigmadz, double *dRdx, double *dRdy, double *dRdz, double *drhodxx, double *drhodxy, double *drhodxz, double *drhodyy, double *drhodyz, double *drhodzz, double *dsigmadxx, double *dsigmadxy, double *dsigmadxz, double *dsigmadyy, double *dsigmadyz, double *dsigmadzz, double *dRdxx, double *dRdxy, double *dRdxz, double *dRdyy, double *dRdyz, double *dRdzz, double *chi, double *trK, double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz, double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz, double *Gamx, double *Gamy, double *Gamz, double *Lap, double *betax, double *betay, double *betaz, double *dtSfx, double *dtSfy, double *dtSfz, double *TZ, double *chi_rhs, double *trK_rhs, double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs, double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs, double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs, double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs, double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs, double *TZ_rhs, double *rho, double *Sx, double *Sy, double *Sz, double *Sxx, double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz, double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz, double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz, double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz, double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz, double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res, double *Gmx_Res, double *Gmy_Res, double *Gmz_Res, int &Symmetry, int &Lev, double &eps, int &sst, int &co
int gpu_rhs_z4c_ss(Z4C_SS_PARA);
#endif

7790
AMSS_NCKU_source/bssn_gpu_class.C
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File diff suppressed because it is too large Load Diff

210
AMSS_NCKU_source/bssn_gpu_class.h
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@@ -1,210 +0,0 @@
#ifndef BSSN_GPU_CLASS_H
#define BSSN_GPU_CLASS_H
#ifdef newc
#include <iostream>
#include <iomanip>
#include <fstream>
#include <cstdlib>
#include <string>
#include <cmath>
using namespace std;
#else
#include <iostream.h>
#include <iomanip.h>
#include <fstream.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#endif
#include <mpi.h>
#include "macrodef.h"
#include "cgh.h"
#include "ShellPatch.h"
#include "misc.h"
#include "var.h"
#include "MyList.h"
#include "monitor.h"
#include "surface_integral.h"
#include "checkpoint.h"
// added by yangquan
#include "bssn_macro.h"
extern void setpbh(int iBHN, double **iPBH, double *iMass, int rBHN);
class bssn_class
{
public:
// added by yangquan
//----------------------
int gpu_num_mynode;
int cpu_core_num_mynode;
int mpi_process_num_mynode;
int my_sequence_mynode;
int mynode_id;
int use_gpu;
virtual void Step_GPU(int lev, int YN);
virtual void Get_runtime_envirment();
// virtual void Step_OPENMP(int lev,int YN);
//----------------------
int ngfs;
int nprocs, myrank;
cgh *GH;
ShellPatch *SH;
double PhysTime;
int checkrun;
char checkfilename[50];
int Steps;
double StartTime, TotalTime;
double AnasTime, DumpTime, d2DumpTime, CheckTime;
double LastAnas, LastConsOut;
double Courant;
double numepss, numepsb, numepsh;
int Symmetry;
int maxl, decn;
double maxrex, drex;
int trfls, a_lev;
double dT;
double chitiny;
double **Porg0, **Porgbr, **Porg, **Porg1, **Porg_rhs;
int BH_num, BH_num_input;
double *Mass, *Pmom, *Spin;
double ADMMass;
var *phio, *trKo;
var *gxxo, *gxyo, *gxzo, *gyyo, *gyzo, *gzzo;
var *Axxo, *Axyo, *Axzo, *Ayyo, *Ayzo, *Azzo;
var *Gmxo, *Gmyo, *Gmzo;
var *Lapo, *Sfxo, *Sfyo, *Sfzo;
var *dtSfxo, *dtSfyo, *dtSfzo;
var *phi0, *trK0;
var *gxx0, *gxy0, *gxz0, *gyy0, *gyz0, *gzz0;
var *Axx0, *Axy0, *Axz0, *Ayy0, *Ayz0, *Azz0;
var *Gmx0, *Gmy0, *Gmz0;
var *Lap0, *Sfx0, *Sfy0, *Sfz0;
var *dtSfx0, *dtSfy0, *dtSfz0;
var *phi, *trK;
var *gxx, *gxy, *gxz, *gyy, *gyz, *gzz;
var *Axx, *Axy, *Axz, *Ayy, *Ayz, *Azz;
var *Gmx, *Gmy, *Gmz;
var *Lap, *Sfx, *Sfy, *Sfz;
var *dtSfx, *dtSfy, *dtSfz;
var *phi1, *trK1;
var *gxx1, *gxy1, *gxz1, *gyy1, *gyz1, *gzz1;
var *Axx1, *Axy1, *Axz1, *Ayy1, *Ayz1, *Azz1;
var *Gmx1, *Gmy1, *Gmz1;
var *Lap1, *Sfx1, *Sfy1, *Sfz1;
var *dtSfx1, *dtSfy1, *dtSfz1;
var *phi_rhs, *trK_rhs;
var *gxx_rhs, *gxy_rhs, *gxz_rhs, *gyy_rhs, *gyz_rhs, *gzz_rhs;
var *Axx_rhs, *Axy_rhs, *Axz_rhs, *Ayy_rhs, *Ayz_rhs, *Azz_rhs;
var *Gmx_rhs, *Gmy_rhs, *Gmz_rhs;
var *Lap_rhs, *Sfx_rhs, *Sfy_rhs, *Sfz_rhs;
var *dtSfx_rhs, *dtSfy_rhs, *dtSfz_rhs;
var *rho, *Sx, *Sy, *Sz, *Sxx, *Sxy, *Sxz, *Syy, *Syz, *Szz;
var *Gamxxx, *Gamxxy, *Gamxxz, *Gamxyy, *Gamxyz, *Gamxzz;
var *Gamyxx, *Gamyxy, *Gamyxz, *Gamyyy, *Gamyyz, *Gamyzz;
var *Gamzxx, *Gamzxy, *Gamzxz, *Gamzyy, *Gamzyz, *Gamzzz;
var *Rxx, *Rxy, *Rxz, *Ryy, *Ryz, *Rzz;
var *Rpsi4, *Ipsi4;
var *t1Rpsi4, *t1Ipsi4, *t2Rpsi4, *t2Ipsi4;
var *Cons_Ham, *Cons_Px, *Cons_Py, *Cons_Pz, *Cons_Gx, *Cons_Gy, *Cons_Gz;
#ifdef Point_Psi4
var *phix, *phiy, *phiz;
var *trKx, *trKy, *trKz;
var *Axxx, *Axxy, *Axxz;
var *Axyx, *Axyy, *Axyz;
var *Axzx, *Axzy, *Axzz;
var *Ayyx, *Ayyy, *Ayyz;
var *Ayzx, *Ayzy, *Ayzz;
var *Azzx, *Azzy, *Azzz;
#endif
// FIXME: uc = StateList, up = OldStateList, upp = SynchList_cor; so never touch these three data
MyList<var> *StateList, *SynchList_pre, *SynchList_cor, *RHSList;
MyList<var> *OldStateList, *DumpList;
MyList<var> *ConstraintList;
monitor *ErrorMonitor, *Psi4Monitor, *BHMonitor, *MAPMonitor;
monitor *ConVMonitor;
surface_integral *Waveshell;
checkpoint *CheckPoint;
public:
bssn_class(double Couranti, double StartTimei, double TotalTimei, double DumpTimei, double d2DumpTimei, double CheckTimei, double AnasTimei,
int Symmetryi, int checkruni, char *checkfilenamei, double numepssi, double numepsbi, double numepshi,
int a_levi, int maxli, int decni, double maxrexi, double drexi);
~bssn_class();
void Evolve(int Steps);
void RecursiveStep(int lev);
#if (PSTR == 1)
void ParallelStep();
void SHStep();
#endif
void RestrictProlong(int lev, int YN, bool BB, MyList<var> *SL, MyList<var> *OL, MyList<var> *corL);
void RestrictProlong_aux(int lev, int YN, bool BB, MyList<var> *SL, MyList<var> *OL, MyList<var> *corL);
void RestrictProlong(int lev, int YN, bool BB);
void ProlongRestrict(int lev, int YN, bool BB);
void Setup_Black_Hole_position();
void compute_Porg_rhs(double **BH_PS, double **BH_RHS, var *forx, var *fory, var *forz, int lev);
bool read_Pablo_file(int *ext, double *datain, char *filename);
void write_Pablo_file(int *ext, double xmin, double xmax, double ymin, double ymax, double zmin, double zmax,
char *filename);
void AnalysisStuff(int lev, double dT_lev);
void Setup_KerrSchild();
void Enforce_algcon(int lev, int fg);
void testRestrict();
void testOutBd();
virtual void Setup_Initial_Data_Lousto();
virtual void Setup_Initial_Data_Cao();
virtual void Initialize();
virtual void Read_Ansorg();
virtual void Read_Pablo() {};
virtual void Compute_Psi4(int lev);
virtual void Step(int lev, int YN);
virtual void Interp_Constraint(bool infg);
virtual void Constraint_Out();
virtual void Compute_Constraint();
#ifdef With_AHF
protected:
MyList<var> *AHList, *AHDList, *GaugeList;
int AHfindevery;
double AHdumptime;
int *lastahdumpid, HN_num; // number of possible horizons
int *findeveryl;
double *xc, *yc, *zc, *xr, *yr, *zr;
bool *trigger;
double *dTT;
int *dumpid;
public:
void AH_Prepare_derivatives();
bool AH_Interp_Points(MyList<var> *VarList,
int NN, double **XX,
double *Shellf, int Symmetryi);
void AH_Step_Find(int lev, double dT_lev);
#endif
};
#endif /* BSSN_GPU_CLASS_H */

121
AMSS_NCKU_source/bssn_gpu_rhs_ss.cu
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@@ -20,12 +20,14 @@ using namespace std;
__device__ volatile unsigned int global_count = 0;
#ifdef RESULT_CHECK
void compare_result_gpu(int ftag1,double * datac,int data_num){
double * data = (double*)malloc(sizeof(double)*data_num);
cudaMemcpy(data, datac, data_num * sizeof(double), cudaMemcpyDeviceToHost);
compare_result(ftag1,data,data_num);
free(data);
}
#endif
__global__ void sub_symmetry_bd_ss_partF(int ord, double * func, double *funcc)
{
@@ -153,11 +155,11 @@ __global__ void sub_symmetry_bd_ss_partJ(int ord,double * func, double * funcc,d
inline void sub_symmetry_bd_ss(int ord,double * func, double * funcc,double * SoA){
sub_symmetry_bd_ss_partF<<<GRID_DIM,BLOCK_DIM>>>(ord,func,funcc);
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_symmetry_bd_ss_partI<<<GRID_DIM,BLOCK_DIM>>>(ord,func,funcc,SoA[0]);
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_symmetry_bd_ss_partJ<<<GRID_DIM,BLOCK_DIM>>>(ord,func,funcc,SoA[1]);
cudaThreadSynchronize();
cudaDeviceSynchronize();
}
__global__ void sub_fderivs_shc_part1(double *fx,double *fy,double *fz){
@@ -247,13 +249,13 @@ inline void sub_fderivs_shc(int& sst,double * f,double * fh,double *fx,double *f
//cudaMemset(Msh_ gy,0,h_3D_SIZE[0] * sizeof(double));
//cudaMemset(Msh_ gz,0,h_3D_SIZE[0] * sizeof(double));
sub_symmetry_bd_ss(2,f,fh,SoA1);
cudaThreadSynchronize();
cudaDeviceSynchronize();
//compare_result_gpu(0,fh,h_3D_SIZE[2]);
sub_fderivs_sh<<<GRID_DIM,BLOCK_DIM>>>(fh,Msh_ gx,Msh_ gy,Msh_ gz);
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_fderivs_shc_part1<<<GRID_DIM,BLOCK_DIM>>>(fx,fy,fz);
cudaThreadSynchronize();
cudaDeviceSynchronize();
//compare_result_gpu(1,fx,h_3D_SIZE[0]);
//compare_result_gpu(2,fy,h_3D_SIZE[0]);
//compare_result_gpu(3,fz,h_3D_SIZE[0]);
@@ -451,17 +453,17 @@ inline void sub_fdderivs_shc(int& sst,double * f,double * fh,
//fderivs_sh
sub_symmetry_bd_ss(2,f,fh,SoA1);
cudaThreadSynchronize();
cudaDeviceSynchronize();
//compare_result_gpu(1,fh,h_3D_SIZE[2]);
sub_fderivs_sh<<<GRID_DIM,BLOCK_DIM>>>(fh,Msh_ gx,Msh_ gy,Msh_ gz);
cudaThreadSynchronize();
cudaDeviceSynchronize();
//fdderivs_sh
sub_symmetry_bd_ss(2,f,fh,SoA1);
cudaThreadSynchronize();
cudaDeviceSynchronize();
//compare_result_gpu(21,fh,h_3D_SIZE[2]);
sub_fdderivs_sh<<<GRID_DIM,BLOCK_DIM>>>(fh,Msh_ gxx,Msh_ gxy,Msh_ gxz,Msh_ gyy,Msh_ gyz,Msh_ gzz);
cudaThreadSynchronize();
cudaDeviceSynchronize();
/*compare_result_gpu(11,Msh_ gx,h_3D_SIZE[0]);
compare_result_gpu(12,Msh_ gy,h_3D_SIZE[0]);
compare_result_gpu(13,Msh_ gz,h_3D_SIZE[0]);
@@ -472,7 +474,7 @@ inline void sub_fdderivs_shc(int& sst,double * f,double * fh,
compare_result_gpu(5,Msh_ gyz,h_3D_SIZE[0]);
compare_result_gpu(6,Msh_ gzz,h_3D_SIZE[0]);*/
sub_fdderivs_shc_part1<<<GRID_DIM,BLOCK_DIM>>>(fxx,fxy,fxz,fyy,fyz,fzz);
cudaThreadSynchronize();
cudaDeviceSynchronize();
/*compare_result_gpu(1,fxx,h_3D_SIZE[0]);
compare_result_gpu(2,fxy,h_3D_SIZE[0]);
compare_result_gpu(3,fxz,h_3D_SIZE[0]);
@@ -496,9 +498,9 @@ __global__ void computeRicci_ss_part1(double * dst)
inline void computeRicci_ss(int &sst,double * src,double* dst,double * SoA, Meta* meta)
{
sub_fdderivs_shc(sst,src,Mh_ fh,Mh_ fxx,Mh_ fxy,Mh_ fxz,Mh_ fyy,Mh_ fyz,Mh_ fzz,SoA);
cudaThreadSynchronize();
cudaDeviceSynchronize();
computeRicci_ss_part1<<<GRID_DIM,BLOCK_DIM>>>(dst);
cudaThreadSynchronize();
cudaDeviceSynchronize();
}
__global__ void sub_lopsided_ss_part1(double * dst)
@@ -516,9 +518,9 @@ __global__ void sub_lopsided_ss_part1(double * dst)
inline void sub_lopsided_ss(int& sst,double *src,double* dst,double *SoA)
{
sub_fderivs_shc(sst,src,Mh_ fh,Mh_ fxx,Mh_ fxy,Mh_ fxz,SoA);
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_lopsided_ss_part1<<<GRID_DIM,BLOCK_DIM>>>(dst);
cudaThreadSynchronize();
cudaDeviceSynchronize();
}
__global__ void sub_kodis_sh_part1(double *f,double *fh,double *f_rhs)
@@ -590,11 +592,11 @@ inline void sub_kodis_ss(int &sst,double *f,double *fh,double *f_rhs,double *SoA
}
//compare_result_gpu(10,f,h_3D_SIZE[0]);
sub_symmetry_bd_ss(3,f,fh,SoA1);
cudaThreadSynchronize();
cudaDeviceSynchronize();
//compare_result_gpu(0,fh,h_3D_SIZE[3]);
sub_kodis_sh_part1<<<GRID_DIM,BLOCK_DIM>>>(f,fh,f_rhs);
cudaThreadSynchronize();
cudaDeviceSynchronize();
//compare_result_gpu(1,f_rhs,h_3D_SIZE[0]);
}
@@ -1699,7 +1701,7 @@ void destroy_meta(Meta *meta,Metass *metass)
if(Msh_ gzz) cudaFree(Msh_ gzz);
#if (GAUGE == 2 || GAUGE == 3 || GAUGE == 4 || GAUGE == 5 || GAUGE == 6 || GAUGE == 7)
if(Mh_ reta) CUDA_SAFE_CALL(cudaFree(Mh_ reta));
if(Mh_ reta) cudaFree(Mh_ reta);
#endif
@@ -1895,7 +1897,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
//1.2 local Data
cudaMalloc((void**)&(Mh_ gxx), matrix_size * sizeof(double));
CUDA_SAFE_CALL( cudaMalloc((void**)&(Mh_ gyy), matrix_size * sizeof(double)));
cudaMalloc((void**)&(Mh_ gyy), matrix_size * sizeof(double));
cudaMalloc((void**)&(Mh_ gzz), matrix_size * sizeof(double));
cudaMalloc((void**)&(Mh_ chix), matrix_size * sizeof(double));
cudaMalloc((void**)&(Mh_ chiy), matrix_size * sizeof(double));
@@ -2160,7 +2162,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
double tmp_con2 = 1/Mass[0] - tmp_con;
cudaMemcpyToSymbol(C1, &tmp_con2, sizeof(double));
double tmp_con2 = 1/Mass[1] - tmp_con;
tmp_con2 = 1/Mass[1] - tmp_con;
cudaMemcpyToSymbol(C2, &tmp_con2, sizeof(double));
@@ -2233,7 +2235,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
if((sst == 2 || sst == 4) && abs[1] < dYh)
{
ijkmin_h[1] = -2;
ijkmin_h[1] = -3;
ijkmin3_h[1] = -3;
}
if((sst == 3 || sst == 5) && abs_Y_ex2 < dYh)
{
@@ -2287,13 +2289,13 @@ int gpu_rhs_ss(RHS_SS_PARA)
#ifdef TIMING1
cudaThreadSynchronize();
cudaDeviceSynchronize();
gettimeofday(&tv2, NULL);
cout<<"TIME USED"<<TimeBetween(tv1, tv2)<<endl;
#endif
//cout<<"GPU meta data ready.\n";
cudaThreadSynchronize();
cudaDeviceSynchronize();
//-------------get device info-------------------------------------
@@ -2306,7 +2308,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
//sub_enforce_ga(matrix_size);
//4.1-----compute rhs---------
compute_rhs_ss_part1<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_fderivs_shc(sst,Mh_ betax,Mh_ fh,Mh_ betaxx,Mh_ betaxy,Mh_ betaxz,ass);
sub_fderivs_shc(sst,Mh_ betay,Mh_ fh,Mh_ betayx,Mh_ betayy,Mh_ betayz,sas);
@@ -2322,7 +2324,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
sub_fderivs_shc(sst,Mh_ gyz,Mh_ fh,Mh_ gyzx,Mh_ gyzy,Mh_ gyzz, saa);
compute_rhs_ss_part2<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_fdderivs_shc(sst,Mh_ betax,Mh_ fh,Mh_ gxxx,Mh_ gxyx,Mh_ gxzx,Mh_ gyyx,Mh_ gyzx,Mh_ gzzx,ass);
sub_fdderivs_shc(sst,Mh_ betay,Mh_ fh,Mh_ gxxy,Mh_ gxyy,Mh_ gxzy,Mh_ gyyy,Mh_ gyzy,Mh_ gzzy,sas);
@@ -2332,7 +2334,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
sub_fderivs_shc( sst,Mh_ Gamz, Mh_ fh,Mh_ Gamzx, Mh_ Gamzy, Mh_ Gamzz,ssa);
compute_rhs_ss_part3<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
computeRicci_ss(sst,Mh_ dxx,Mh_ Rxx,sss, meta);
computeRicci_ss(sst,Mh_ dyy,Mh_ Ryy,sss, meta);
@@ -2340,25 +2342,25 @@ int gpu_rhs_ss(RHS_SS_PARA)
computeRicci_ss(sst,Mh_ gxy,Mh_ Rxy,aas, meta);
computeRicci_ss(sst,Mh_ gxz,Mh_ Rxz,asa, meta);
computeRicci_ss(sst,Mh_ gyz,Mh_ Ryz,saa, meta);
cudaThreadSynchronize();
cudaDeviceSynchronize();
compute_rhs_ss_part4<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_fdderivs_shc(sst,Mh_ chi,Mh_ fh,Mh_ fxx,Mh_ fxy,Mh_ fxz,Mh_ fyy,Mh_ fyz,Mh_ fzz,sss);
//cudaThreadSynchronize();
//cudaDeviceSynchronize();
//compare_result_gpu(0,Mh_ chi,h_3D_SIZE[0]);
//compare_result_gpu(1,Mh_ chi,h_3D_SIZE[0]);
//compare_result_gpu(2,Mh_ fyz,h_3D_SIZE[0]);
compute_rhs_ss_part5<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_fdderivs_shc(sst,Mh_ Lap,Mh_ fh,Mh_ fxx,Mh_ fxy,Mh_ fxz,Mh_ fyy,Mh_ fyz,Mh_ fzz,sss);
compute_rhs_ss_part6<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
#if (GAUGE == 2 || GAUGE == 3 || GAUGE == 4 || GAUGE == 5)
sub_fderivs_shc(sst,Mh_ chi,Mh_ fh, Mh_ dtSfx_rhs, Mh_ dtSfy_rhs, Mh_ dtSfz_rhs,sss);
@@ -2423,7 +2425,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
}
if(co == 0){
compute_rhs_ss_part7<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
sub_fderivs_shc(sst,Mh_ Axx,Mh_ fh,Mh_ gxxx,Mh_ gxxy,Mh_ gxxz,sss);
sub_fderivs_shc(sst,Mh_ Axy,Mh_ fh,Mh_ gxyx,Mh_ gxyy,Mh_ gxyz,aas);
@@ -2432,7 +2434,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
sub_fderivs_shc(sst,Mh_ Ayz,Mh_ fh,Mh_ gyzx,Mh_ gyzy,Mh_ gyzz,saa);
sub_fderivs_shc(sst,Mh_ Azz,Mh_ fh,Mh_ gzzx,Mh_ gzzy,Mh_ gzzz,sss);
compute_rhs_ss_part8<<<GRID_DIM,BLOCK_DIM>>>();
cudaThreadSynchronize();
cudaDeviceSynchronize();
}
#if (ABV == 1)
@@ -2512,7 +2514,7 @@ int gpu_rhs_ss(RHS_SS_PARA)
//test kodis
//sub_kodis_sh(sst,Msh_ drhodx,Mh_ fh2,Msh_ drhody,sss);
#ifdef TIMING
cudaThreadSynchronize();
cudaDeviceSynchronize();
gettimeofday(&tv2, NULL);
cout<<"MPI rank is: "<<mpi_rank<<" GPU TIME is"<<TimeBetween(tv1, tv2)<<" (s)."<<endl;
#endif
@@ -2522,4 +2524,55 @@ int gpu_rhs_ss(RHS_SS_PARA)
return 0;//TODO return
}
#if (ABEtype == 2)
// Z4C Shell GPU: calls BSSN gpu_rhs_ss with trKd=trK+2*TZ, then applies
// TZ_rhs = alpn1*Hcon/2 and constraint damping on CPU.
int gpu_rhs_z4c_ss(Z4C_SS_PARA)
{
int matrix_size = ex[0] * ex[1] * ex[2];
double k1 = 0.02, k2 = 0.0;
double *trKd_host = new double[matrix_size];
for (int _i = 0; _i < matrix_size; _i++)
trKd_host[_i] = trK[_i] + 2.0 * TZ[_i];
int result = gpu_rhs_ss(calledby, mpi_rank,
ex, T, crho, sigma, R, X, Y, Z,
drhodx, drhody, drhodz, dsigmadx, dsigmady, dsigmadz,
dRdx, dRdy, dRdz,
drhodxx, drhodxy, drhodxz, drhodyy, drhodyz, drhodzz,
dsigmadxx, dsigmadxy, dsigmadxz, dsigmadyy, dsigmadyz, dsigmadzz,
dRdxx, dRdxy, dRdxz, dRdyy, dRdyz, dRdzz,
chi, trKd_host, dxx, gxy, gxz, dyy, gyz, dzz,
Axx, Axy, Axz, Ayy, Ayz, Azz,
Gamx, Gamy, Gamz,
Lap, betax, betay, betaz,
dtSfx, dtSfy, dtSfz,
chi_rhs, trK_rhs,
gxx_rhs, gxy_rhs, gxz_rhs, gyy_rhs, gyz_rhs, gzz_rhs,
Axx_rhs, Axy_rhs, Axz_rhs, Ayy_rhs, Ayz_rhs, Azz_rhs,
Gamx_rhs, Gamy_rhs, Gamz_rhs,
Lap_rhs, betax_rhs, betay_rhs, betaz_rhs,
dtSfx_rhs, dtSfy_rhs, dtSfz_rhs,
rho, Sx, Sy, Sz, Sxx, Sxy, Sxz, Syy, Syz, Szz,
Gamxxx, Gamxxy, Gamxxz, Gamxyy, Gamxyz, Gamxzz,
Gamyxx, Gamyxy, Gamyxz, Gamyyy, Gamyyz, Gamyzz,
Gamzxx, Gamzxy, Gamzxz, Gamzyy, Gamzyz, Gamzzz,
Rxx, Rxy, Rxz, Ryy, Ryz, Rzz,
ham_Res, movx_Res, movy_Res, movz_Res,
Gmx_Res, Gmy_Res, Gmz_Res,
Symmetry, Lev, eps, sst, co);
delete[] trKd_host;
if (result != 0) return result;
for (int _i = 0; _i < matrix_size; _i++) {
double alp = Lap[_i] + 1.0;
TZ_rhs[_i] = alp * ham_Res[_i] * 0.5;
TZ_rhs[_i] -= alp * (2.0 + k2) * k1 * TZ[_i];
trK_rhs[_i] += alp * k1 * (1.0 - k2) * TZ[_i];
}
return 0;
}
#endif // ABEtype == 2
#endif //WithShell

88
AMSS_NCKU_source/bssn_rhs.h
View File

@@ -22,32 +22,32 @@
#define f_compute_rhs_Z4c_ss COMPUTE_RHS_Z4C_SS
#define f_compute_constraint_fr COMPUTE_CONSTRAINT_FR
#endif
#ifdef fortran3
#define f_compute_rhs_bssn compute_rhs_bssn_
#ifdef fortran3
#define f_compute_rhs_bssn compute_rhs_bssn_
#define f_compute_rhs_bssn_ss compute_rhs_bssn_ss_
#define f_compute_rhs_bssn_escalar compute_rhs_bssn_escalar_
#define f_compute_rhs_bssn_escalar_ss compute_rhs_bssn_escalar_ss_
#define f_compute_rhs_Z4c compute_rhs_z4c_
#define f_compute_rhs_Z4cnot compute_rhs_z4cnot_
#define f_compute_rhs_Z4c_ss compute_rhs_z4c_ss_
#define f_compute_constraint_fr compute_constraint_fr_
#endif
#ifdef __cplusplus
extern "C"
{
#endif
void f_bssn_rhs_kernel_timing_reset();
int f_bssn_rhs_kernel_timing_bucket_count();
const double *f_bssn_rhs_kernel_timing_local_seconds();
const char *f_bssn_rhs_kernel_timing_label(int);
#ifdef __cplusplus
}
#endif
extern "C"
{
int f_compute_rhs_bssn(int *, double &, double *, double *, double *, // ex,T,X,Y,Z
#define f_compute_constraint_fr compute_constraint_fr_
#endif
#ifdef __cplusplus
extern "C"
{
#endif
void f_bssn_rhs_kernel_timing_reset();
int f_bssn_rhs_kernel_timing_bucket_count();
const double *f_bssn_rhs_kernel_timing_local_seconds();
const char *f_bssn_rhs_kernel_timing_label(int);
#ifdef __cplusplus
}
#endif
extern "C"
{
int f_compute_rhs_bssn(int *, double &, double *, double *, double *, // ex,T,X,Y,Z
double *, double *, // chi, trK
double *, double *, double *, double *, double *, double *, // gij
double *, double *, double *, double *, double *, double *, // Aij
@@ -67,27 +67,6 @@ extern "C"
int &, int &, double &, int &);
}
int f_compute_rhs_bssn_escalar_c(int *, double &, double *, double *, double *, // ex,T,X,Y,Z
double *, double *, // chi, trK
double *, double *, double *, double *, double *, double *, // gij
double *, double *, double *, double *, double *, double *, // Aij
double *, double *, double *, // Gam
double *, double *, double *, double *, double *, double *, double *, // Gauge
double *, double *, // Sphi, Spi
double *, double *, // chi, trK
double *, double *, double *, double *, double *, double *, // gij
double *, double *, double *, double *, double *, double *, // Aij
double *, double *, double *, // Gam
double *, double *, double *, double *, double *, double *, double *, // Gauge
double *, double *, // Sphi, Spi
double *, double *, double *, double *, double *, double *, double *, double *, double *, double *, // stress-energy
double *, double *, double *, double *, double *, double *, // Christoffel
double *, double *, double *, double *, double *, double *, // Christoffel
double *, double *, double *, double *, double *, double *, // Christoffel
double *, double *, double *, double *, double *, double *, // Ricci
double *, double *, double *, double *, double *, double *, double *, // constraint violation
int &, int &, double &, int &);
extern "C"
{
int f_compute_rhs_bssn_ss(int *, double &, double *, double *, double *, // ex,T,rho,sigma,R
@@ -262,31 +241,4 @@ extern "C"
double *);
} // FR_cons
// BSSN-EM C kernel (replaces empart.f90 + bssn_rhs.f90 for BSSN+Maxwell)
int f_compute_rhs_bssn_em_c(int *, double &, double *, double *, double *,
double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *,
double *, double *, double *, double *, double *, double *, double *,
double *, double *, double *,
double *, double *, double *, double *, double *, double *, double *, double *,
double *, double *, double *,
double *, double *,
double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *,
double *, double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *, double *, double *,
double *, double *, double *,
double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
double *, double *, double *, double *, double *, double *,
int &, int &, double &, int &);
#endif /* BSSN_H */

34
AMSS_NCKU_source/bssn_rhs_c.C
View File

@@ -1075,10 +1075,6 @@ int f_compute_rhs_bssn(int *ex, double &T,
}
#endif
#if (GAUGE == 2 || GAUGE == 3 || GAUGE == 4 || GAUGE == 5)
fderivs(ex,chi,dtSfx_rhs,dtSfy_rhs,dtSfz_rhs,X,Y,Z,SYM,SYM,SYM,Symmetry,Lev);
#endif
for (int i = 0; i < all; i += 1) {
#if (GAUGE == 0)
betax_rhs[i] = FF * dtSfx[i];
@@ -1102,12 +1098,12 @@ int f_compute_rhs_bssn(int *ex, double &T,
betaz_rhs[i] = FF * dtSfz[i];
reta[i] =
gupxx[i] * dtSfx_rhs[i] * dtSfx_rhs[i]
+ gupyy[i] * dtSfy_rhs[i] * dtSfy_rhs[i]
+ gupzz[i] * dtSfz_rhs[i] * dtSfz_rhs[i]
+ TWO * ( gupxy[i] * dtSfx_rhs[i] * dtSfy_rhs[i]
+ gupxz[i] * dtSfx_rhs[i] * dtSfz_rhs[i]
+ gupyz[i] * dtSfy_rhs[i] * dtSfz_rhs[i] );
gupxx[i] * chix[i] * chix[i]
+ gupyy[i] * chiy[i] * chiy[i]
+ gupzz[i] * chiz[i] * chiz[i]
+ TWO * ( gupxy[i] * chix[i] * chiy[i]
+ gupxz[i] * chix[i] * chiz[i]
+ gupyz[i] * chiy[i] * chiz[i] );
#if (GAUGE == 2)
reta[i] = 1.31 / 2.0 * sqrt( reta[i] / chin1[i] ) / pow( (ONE - sqrt(chin1[i])), 2.0 );
@@ -1120,12 +1116,12 @@ int f_compute_rhs_bssn(int *ex, double &T,
dtSfz_rhs[i] = Gamz_rhs[i] - reta[i] * dtSfz[i];
#elif (GAUGE == 4 || GAUGE == 5)
reta[i] =
gupxx[i] * dtSfx_rhs[i] * dtSfx_rhs[i]
+ gupyy[i] * dtSfy_rhs[i] * dtSfy_rhs[i]
+ gupzz[i] * dtSfz_rhs[i] * dtSfz_rhs[i]
+ TWO * ( gupxy[i] * dtSfx_rhs[i] * dtSfy_rhs[i]
+ gupxz[i] * dtSfx_rhs[i] * dtSfz_rhs[i]
+ gupyz[i] * dtSfy_rhs[i] * dtSfz_rhs[i] );
gupxx[i] * chix[i] * chix[i]
+ gupyy[i] * chiy[i] * chiy[i]
+ gupzz[i] * chiz[i] * chiz[i]
+ TWO * ( gupxy[i] * chix[i] * chiy[i]
+ gupxz[i] * chix[i] * chiz[i]
+ gupyz[i] * chiy[i] * chiz[i] );
#if (GAUGE == 4)
reta[i] = 1.31 / 2.0 * sqrt( reta[i] / chin1[i] ) / pow( (ONE - sqrt(chin1[i])), 2.0 );
@@ -1164,17 +1160,11 @@ int f_compute_rhs_bssn(int *ex, double &T,
lopsided_kodis(ex,X,Y,Z,gyz,gyz_rhs,betax,betay,betaz,Symmetry,SAA,eps);
lopsided_kodis(ex,X,Y,Z,betaz,betaz_rhs,betax,betay,betaz,Symmetry,SSA,eps);
lopsided_kodis(ex,X,Y,Z,dzz,gzz_rhs,betax,betay,betaz,Symmetry,SSS,eps);
#if (GAUGE == 0 || GAUGE == 2 || GAUGE == 3 || GAUGE == 6 || GAUGE == 7)
lopsided_kodis(ex,X,Y,Z,dtSfx,dtSfx_rhs,betax,betay,betaz,Symmetry,ASS,eps);
#endif
lopsided_kodis(ex,X,Y,Z,Axx,Axx_rhs,betax,betay,betaz,Symmetry,SSS,eps);
#if (GAUGE == 0 || GAUGE == 2 || GAUGE == 3 || GAUGE == 6 || GAUGE == 7)
lopsided_kodis(ex,X,Y,Z,dtSfy,dtSfy_rhs,betax,betay,betaz,Symmetry,SAS,eps);
#endif
lopsided_kodis(ex,X,Y,Z,Axy,Axy_rhs,betax,betay,betaz,Symmetry,AAS,eps);
#if (GAUGE == 0 || GAUGE == 2 || GAUGE == 3 || GAUGE == 6 || GAUGE == 7)
lopsided_kodis(ex,X,Y,Z,dtSfz,dtSfz_rhs,betax,betay,betaz,Symmetry,SSA,eps);
#endif
lopsided_kodis(ex,X,Y,Z,Axz,Axz_rhs,betax,betay,betaz,Symmetry,ASA,eps);
lopsided_kodis(ex,X,Y,Z,Ayy,Ayy_rhs,betax,betay,betaz,Symmetry,SSS,eps);
lopsided_kodis(ex,X,Y,Z,Ayz,Ayz_rhs,betax,betay,betaz,Symmetry,SAA,eps);

10381
AMSS_NCKU_source/bssn_rhs_cuda.cu Normal file
View File

File diff suppressed because it is too large Load Diff

413
AMSS_NCKU_source/bssn_rhs_cuda.h Normal file
View File

@@ -0,0 +1,413 @@
#ifndef BSSN_RHS_CUDA_H
#define BSSN_RHS_CUDA_H
#ifdef __cplusplus
extern "C" {
#endif
enum {
BSSN_CUDA_STATE_COUNT = 24,
BSSN_ESCALAR_CUDA_STATE_COUNT = 26,
BSSN_EM_CUDA_STATE_COUNT = 32,
BSSN_EM_CUDA_SOURCE_COUNT = 4,
BSSN_CUDA_MATTER_COUNT = 10
};
int f_compute_rhs_bssn(int *ex, double &T,
double *X, double *Y, double *Z,
double *chi, double *trK,
double *dxx, double *gxy, double *gxz, double *dyy, double *gyz, double *dzz,
double *Axx, double *Axy, double *Axz, double *Ayy, double *Ayz, double *Azz,
double *Gamx, double *Gamy, double *Gamz,
double *Lap, double *betax, double *betay, double *betaz,
double *dtSfx, double *dtSfy, double *dtSfz,
double *chi_rhs, double *trK_rhs,
double *gxx_rhs, double *gxy_rhs, double *gxz_rhs, double *gyy_rhs, double *gyz_rhs, double *gzz_rhs,
double *Axx_rhs, double *Axy_rhs, double *Axz_rhs, double *Ayy_rhs, double *Ayz_rhs, double *Azz_rhs,
double *Gamx_rhs, double *Gamy_rhs, double *Gamz_rhs,
double *Lap_rhs, double *betax_rhs, double *betay_rhs, double *betaz_rhs,
double *dtSfx_rhs, double *dtSfy_rhs, double *dtSfz_rhs,
double *rho, double *Sx, double *Sy, double *Sz,
double *Sxx, double *Sxy, double *Sxz, double *Syy, double *Syz, double *Szz,
double *Gamxxx, double *Gamxxy, double *Gamxxz, double *Gamxyy, double *Gamxyz, double *Gamxzz,
double *Gamyxx, double *Gamyxy, double *Gamyxz, double *Gamyyy, double *Gamyyz, double *Gamyzz,
double *Gamzxx, double *Gamzxy, double *Gamzxz, double *Gamzyy, double *Gamzyz, double *Gamzzz,
double *Rxx, double *Rxy, double *Rxz, double *Ryy, double *Ryz, double *Rzz,
double *ham_Res, double *movx_Res, double *movy_Res, double *movz_Res,
double *Gmx_Res, double *Gmy_Res, double *Gmz_Res,
int &Symmetry, int &Lev, double &eps, int &co);
int bssn_cuda_rk4_substep(void *block_tag,
int *ex, double *X, double *Y, double *Z,
double **state_host_in,
double **state_host_out,
double **matter_host,
const double *propspeed,
const double *soa_flat,
const double *bbox,
double &dT,
double &T,
int &RK4,
int &apply_bam_bc,
int &Symmetry,
int &Lev,
double &eps,
int &co,
int &use_zero_matter,
int &keep_resident_state,
int &apply_enforce_ga,
double &chitiny);
int bssn_escalar_cuda_rk4_substep(void *block_tag,
int *ex, double *X, double *Y, double *Z,
double **state_host_in,
double **state_host_out,
const double *propspeed,
const double *soa_flat,
const double *bbox,
double &dT,
double &T,
int &RK4,
int &apply_bam_bc,
int &Symmetry,
int &Lev,
double &eps,
int &co,
int &keep_resident_state,
int &apply_enforce_ga,
double &chitiny);
int bssn_escalar_cuda_compute_constraints(int *ex, double *X, double *Y, double *Z,
double **state_host_in,
double **constraint_host_out,
int &Symmetry,
int &Lev,
double &eps);
int bssn_em_cuda_rk4_substep(void *block_tag,
int *ex, double *X, double *Y, double *Z,
double **state_host_in,
double **state_host_out,
double **source_host,
const double *propspeed,
const double *soa_flat,
const double *bbox,
double &dT,
double &T,
int &RK4,
int &apply_bam_bc,
int &Symmetry,
int &Lev,
double &eps,
int &co,
int &keep_resident_state,
int &apply_enforce_ga,
double &chitiny);
int bssn_em_cuda_resident_zero_fast_state(void *block_tag);
int bssn_cuda_copy_state_region_to_host(void *block_tag,
int state_index,
double *host_state,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_copy_state_region_from_host(void *block_tag,
int state_index,
double *host_state,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_download_resident_state(void *block_tag,
int *ex,
double **state_host_out);
int bssn_escalar_cuda_download_resident_state(void *block_tag,
int *ex,
double **state_host_out);
int bssn_cuda_upload_resident_state_count(void *block_tag,
int *ex,
double **state_host_in,
int state_count);
int bssn_escalar_cuda_upload_resident_state(void *block_tag,
int *ex,
double **state_host_in);
int bssn_cuda_keep_only_resident_state_count(void *block_tag,
int *ex,
double **state_host_key,
int state_count);
int bssn_escalar_cuda_keep_only_resident_state(void *block_tag,
int *ex,
double **state_host_key);
int bssn_cuda_download_resident_state_count_if_present(void *block_tag,
int *ex,
double **state_host_out,
int state_count);
int bssn_cuda_download_resident_state_if_present(void *block_tag,
int *ex,
double **state_host_out);
int bssn_cuda_download_constraint_outputs(int *ex,
double **constraint_host_out);
int bssn_cuda_pack_state_region_to_host_buffer(void *block_tag,
int state_index,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_interp_state_point3(void *block_tag,
int *ex,
int state0,
int state1,
int state2,
double x0,
double y0,
double z0,
double dx,
double dy,
double dz,
double px,
double py,
double pz,
int ordn,
int symmetry,
double **state_host_key,
const double *soa3,
double *out3);
int bssn_cuda_interp_host_two_fields(void *block_tag,
int *ex,
double *field0,
double *field1,
double x0,
double y0,
double z0,
double dx,
double dy,
double dz,
const double *px,
const double *py,
const double *pz,
int npoints,
int ordn,
int symmetry,
const double *soa6,
double *out_interleaved);
int bssn_cuda_unpack_state_region_from_host_buffer(void *block_tag,
int state_index,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_unpack_state_region_from_host_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
int state_index,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_pack_state_batch_to_host_buffer(void *block_tag,
int state_count,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_pack_state_batch_to_host_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_unpack_state_batch_from_host_buffer(void *block_tag,
int state_count,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_unpack_state_batch_from_host_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_pack_state_batch_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_pack_state_batch_to_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_unpack_state_batch_from_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_unpack_state_batch_from_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int bssn_cuda_pack_state_segments_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta);
int bssn_cuda_pack_state_segments_to_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta);
int bssn_cuda_unpack_state_segments_from_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta);
int bssn_cuda_unpack_state_segments_from_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta);
int bssn_cuda_restrict_state_segments_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta);
int bssn_cuda_restrict_state_segments_to_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta,
const double *state_soa);
int bssn_cuda_prolong_state_segments_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta);
int bssn_cuda_prolong_state_segments_to_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int segment_count,
const int *segment_meta,
const double *state_soa);
int bssn_cuda_restrict_state_batch_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int sx, int sy, int sz,
int fi0, int fj0, int fk0);
int bssn_cuda_restrict_state_batch_to_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int sx, int sy, int sz,
int fi0, int fj0, int fk0,
const double *state_soa);
int bssn_cuda_prolong_state_batch_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int sx, int sy, int sz,
int ii0, int jj0, int kk0,
int lbc_i, int lbc_j, int lbc_k);
int bssn_cuda_prolong_state_batch_to_device_buffer_for_host_views(void *block_tag,
double **state_host_key,
int state_count,
double *device_buffer,
int *ex,
int sx, int sy, int sz,
int ii0, int jj0, int kk0,
int lbc_i, int lbc_j, int lbc_k,
const double *state_soa);
int bssn_cuda_download_state_subset(void *block_tag,
int *ex,
int subset_count,
const int *state_indices,
double **state_host_out);
int bssn_cuda_upload_state_subset(void *block_tag,
int *ex,
int subset_count,
const int *state_indices,
double **state_host_in);
int bssn_cuda_prepare_inter_time_level(void *block_tag,
int *ex,
int state_count,
double **src1_host_key,
double **src2_host_key,
double **src3_host_key,
double **dst_host_key,
int source_count,
int tindex);
int bssn_cuda_has_resident_state(void *block_tag);
void bssn_cuda_release_step_ctx(void *block_tag);
#ifdef __cplusplus
}
// C++-only helpers declared for derived equation classes (Z4C, etc.)
// Defined in bssn_class.C. Requires MyList, Patch, var from including TU.
bool bssn_cuda_use_resident_sync(int lev);
void bssn_cuda_download_level_state_if_present(MyList<Patch> *PatL, MyList<var> *vars, int myrank);
#endif
#endif

1942
AMSS_NCKU_source/bssn_step_gpu.C
View File

File diff suppressed because it is too large Load Diff

47
AMSS_NCKU_source/checkpoint.C
View File

@@ -76,8 +76,11 @@ checkpoint::checkpoint(bool checked, const char fname[], int myrank) : filename(
I_Print = (myrank == 0);
int i = strlen(fname);
filename = new char[i+30];
size_t filename_len = out_dir.size() + strlen(fname) + 32;
#ifdef CHECKDETAIL
filename_len += 32;
#endif
filename = new char[filename_len];
// cout << filename << endl;
// cout << i << endl;
@@ -100,12 +103,12 @@ checkpoint::checkpoint(bool checked, const char fname[], int myrank) : filename(
cout << " checkpoint class created " << endl;
}
}
checkpoint::~checkpoint()
{
CheckList->clearList();
if (I_Print)
delete[] filename;
}
checkpoint::~checkpoint()
{
CheckList->clearList();
if (filename)
delete[] filename;
}
void checkpoint::addvariable(var *VV)
{
@@ -136,7 +139,7 @@ void checkpoint::writecheck_cgh(double time, cgh *GH)
if (I_Print)
{
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_cgh.CHK", filename);
outfile.open(fname, ios::out | ios::trunc);
@@ -195,7 +198,7 @@ void checkpoint::readcheck_cgh(double &time, cgh *GH, int myrank, int nprocs, in
int DIM = dim;
ifstream infile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_cgh.CHK", filename);
infile.open(fname);
@@ -297,7 +300,7 @@ void checkpoint::writecheck_sh(double time, ShellPatch *SH)
if (I_Print)
{
char fname[50];
char fname[4096];
sprintf(fname, "%s_sh.CHK", filename);
outfile.open(fname, ios::out | ios::trunc);
@@ -335,7 +338,7 @@ void checkpoint::readcheck_sh(ShellPatch *SH, int myrank)
int DIM = dim;
ifstream infile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_sh.CHK", filename);
infile.open(fname);
@@ -390,7 +393,7 @@ void checkpoint::write_Black_Hole_position(int BH_num_input, int BH_num, double
if (I_Print)
{
char fname[50];
char fname[4096];
sprintf(fname, "%s_BHp.CHK", filename);
outfile.open(fname, ios::out | ios::trunc);
@@ -417,7 +420,7 @@ void checkpoint::read_Black_Hole_position(int &BH_num_input, int &BH_num, double
{
ifstream infile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_BHp.CHK", filename);
infile.open(fname);
@@ -461,7 +464,7 @@ void checkpoint::write_bssn(double LastDump, double Last2dDump, double LastAnas)
if (I_Print)
{
char fname[50];
char fname[4096];
sprintf(fname, "%s_bssn.CHK", filename);
outfile.open(fname, ios::out | ios::trunc);
@@ -481,7 +484,7 @@ void checkpoint::read_bssn(double &LastDump, double &Last2dDump, double &LastAna
{
ifstream infile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_bssn.CHK", filename);
infile.open(fname);
@@ -506,7 +509,7 @@ void checkpoint::write_bssn(double LastDump, double Last2dDump, double LastAnas)
ofstream outfile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_bssn.CHK", filename);
outfile.open(fname, ios::out | ios::trunc);
@@ -527,7 +530,7 @@ void checkpoint::read_bssn(double &LastDump, double &Last2dDump, double &LastAna
{
ifstream infile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_bssn.CHK", filename);
infile.open(fname);
@@ -551,7 +554,7 @@ void checkpoint::write_Black_Hole_position(int BH_num_input, int BH_num, double
ofstream outfile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_BHp.CHK", filename);
outfile.open(fname, ios::out | ios::trunc);
@@ -581,7 +584,7 @@ void checkpoint::read_Black_Hole_position(int &BH_num_input, int &BH_num, double
{
ifstream infile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_BHp.CHK", filename);
infile.open(fname);
@@ -628,7 +631,7 @@ void checkpoint::writecheck_cgh(double time, cgh *GH)
ofstream outfile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_cgh.CHK", filename);
outfile.open(fname, ios::out | ios::trunc);
@@ -738,7 +741,7 @@ void checkpoint::readcheck_cgh(double &time, cgh *GH, int myrank, int nprocs, in
int DIM = dim;
ifstream infile;
// char fname[50];
char fname[50+50];
char fname[4096];
sprintf(fname, "%s_cgh.CHK", filename);
infile.open(fname);

412
AMSS_NCKU_source/fd_cuda_helpers.cuh Normal file
View File

@@ -0,0 +1,412 @@
#ifndef AMSS_NCKU_FD_CUDA_HELPERS_CUH
#define AMSS_NCKU_FD_CUDA_HELPERS_CUH
#ifndef ghost_width
#error "ghost_width must be defined before including fd_cuda_helpers.cuh"
#endif
#if ghost_width < 2 || ghost_width > 5
#error "CUDA finite-difference helpers support ghost_width 2..5"
#endif
#define AMSS_FD_CENTER_RADIUS (ghost_width - 1)
#define AMSS_FD_LK_RADIUS (ghost_width)
__device__ __forceinline__ int fd_axis_radius(int qF, int qminF, int qmaxF)
{
#if AMSS_FD_CENTER_RADIUS >= 4
if (qF - 4 >= qminF && qF + 4 <= qmaxF) return 4;
#endif
#if AMSS_FD_CENTER_RADIUS >= 3
if (qF - 3 >= qminF && qF + 3 <= qmaxF) return 3;
#endif
#if AMSS_FD_CENTER_RADIUS >= 2
if (qF - 2 >= qminF && qF + 2 <= qmaxF) return 2;
#endif
if (qF - 1 >= qminF && qF + 1 <= qmaxF) return 1;
return 0;
}
__device__ __forceinline__ int fd_common_radius(int iF, int jF, int kF,
int iminF, int jminF, int kminF,
int imaxF, int jmaxF, int kmaxF)
{
int r = fd_axis_radius(iF, iminF, imaxF);
const int ry = fd_axis_radius(jF, jminF, jmaxF);
const int rz = fd_axis_radius(kF, kminF, kmaxF);
if (ry < r) r = ry;
if (rz < r) r = rz;
return r;
}
__device__ __forceinline__ double fd_first_coef(int r, int off)
{
switch (r) {
case 1:
if (off == -1) return -1.0;
if (off == 1) return 1.0;
return 0.0;
case 2:
if (off == -2) return 1.0;
if (off == -1) return -8.0;
if (off == 1) return 8.0;
if (off == 2) return -1.0;
return 0.0;
case 3:
if (off == -3) return -1.0;
if (off == -2) return 9.0;
if (off == -1) return -45.0;
if (off == 1) return 45.0;
if (off == 2) return -9.0;
if (off == 3) return 1.0;
return 0.0;
case 4:
if (off == -4) return 3.0;
if (off == -3) return -32.0;
if (off == -2) return 168.0;
if (off == -1) return -672.0;
if (off == 1) return 672.0;
if (off == 2) return -168.0;
if (off == 3) return 32.0;
if (off == 4) return -3.0;
return 0.0;
default:
return 0.0;
}
}
__device__ __forceinline__ double fd_second_coef(int r, int off)
{
switch (r) {
case 1:
if (off == -1) return 1.0;
if (off == 0) return -2.0;
if (off == 1) return 1.0;
return 0.0;
case 2:
if (off == -2) return -1.0;
if (off == -1) return 16.0;
if (off == 0) return -30.0;
if (off == 1) return 16.0;
if (off == 2) return -1.0;
return 0.0;
case 3:
if (off == -3) return 2.0;
if (off == -2) return -27.0;
if (off == -1) return 270.0;
if (off == 0) return -490.0;
if (off == 1) return 270.0;
if (off == 2) return -27.0;
if (off == 3) return 2.0;
return 0.0;
case 4:
if (off == -4) return -9.0;
if (off == -3) return 128.0;
if (off == -2) return -1008.0;
if (off == -1) return 8064.0;
if (off == 0) return -14350.0;
if (off == 1) return 8064.0;
if (off == 2) return -1008.0;
if (off == 3) return 128.0;
if (off == 4) return -9.0;
return 0.0;
default:
return 0.0;
}
}
__device__ __forceinline__ double fd_first_denom(int r)
{
return (r == 4) ? 840.0 : ((r == 3) ? 60.0 : ((r == 2) ? 12.0 : 2.0));
}
__device__ __forceinline__ double fd_second_denom(int r)
{
return (r == 4) ? 5040.0 : ((r == 3) ? 180.0 : ((r == 2) ? 12.0 : 1.0));
}
__device__ __forceinline__ double fd_fetch_axis(const double *src,
int iF, int jF, int kF,
int axis, int off,
int SoA0, int SoA1, int SoA2)
{
if (axis == 0) iF += off;
else if (axis == 1) jF += off;
else kF += off;
return fetch_sym_ord2_direct(src, iF, jF, kF, SoA0, SoA1, SoA2);
}
__device__ __forceinline__ double fd_fetch_axis2(const double *src,
int iF, int jF, int kF,
int axis_a, int off_a,
int axis_b, int off_b,
int SoA0, int SoA1, int SoA2)
{
if (axis_a == 0) iF += off_a;
else if (axis_a == 1) jF += off_a;
else kF += off_a;
if (axis_b == 0) iF += off_b;
else if (axis_b == 1) jF += off_b;
else kF += off_b;
return fetch_sym_ord2_direct(src, iF, jF, kF, SoA0, SoA1, SoA2);
}
__device__ __forceinline__ double fd_first_axis_radius(const double *src,
int iF, int jF, int kF,
int axis, int r, double h,
int SoA0, int SoA1, int SoA2)
{
if (r <= 0) return 0.0;
double s = 0.0;
#pragma unroll
for (int off = -4; off <= 4; ++off) {
const double c = fd_first_coef(r, off);
if (c != 0.0) {
s += c * fd_fetch_axis(src, iF, jF, kF, axis, off, SoA0, SoA1, SoA2);
}
}
return s / (fd_first_denom(r) * h);
}
__device__ __forceinline__ double fd_second_axis_radius(const double *src,
int iF, int jF, int kF,
int axis, int r, double h,
int SoA0, int SoA1, int SoA2)
{
if (r <= 0) return 0.0;
double s = 0.0;
#pragma unroll
for (int off = -4; off <= 4; ++off) {
const double c = fd_second_coef(r, off);
if (c != 0.0) {
s += c * fd_fetch_axis(src, iF, jF, kF, axis, off, SoA0, SoA1, SoA2);
}
}
return s / (fd_second_denom(r) * h * h);
}
__device__ __forceinline__ double fd_mixed_axis_radius(const double *src,
int iF, int jF, int kF,
int axis_a, int r_a, double h_a,
int axis_b, int r_b, double h_b,
int SoA0, int SoA1, int SoA2)
{
if (r_a <= 0 || r_b <= 0) return 0.0;
double s = 0.0;
#pragma unroll
for (int off_a = -4; off_a <= 4; ++off_a) {
const double ca = fd_first_coef(r_a, off_a);
if (ca == 0.0) continue;
#pragma unroll
for (int off_b = -4; off_b <= 4; ++off_b) {
const double cb = fd_first_coef(r_b, off_b);
if (cb != 0.0) {
s += ca * cb * fd_fetch_axis2(src, iF, jF, kF, axis_a, off_a,
axis_b, off_b, SoA0, SoA1, SoA2);
}
}
}
return s / (fd_first_denom(r_a) * fd_first_denom(r_b) * h_a * h_b);
}
__device__ __forceinline__ void fd_compute_first3(const double *src,
int iF, int jF, int kF,
int iminF, int jminF, int kminF,
int imaxF, int jmaxF, int kmaxF,
int SoA0, int SoA1, int SoA2,
double &fx, double &fy, double &fz)
{
#if ghost_width == 3
const int r = fd_common_radius(iF, jF, kF, iminF, jminF, kminF, imaxF, jmaxF, kmaxF);
fx = fd_first_axis_radius(src, iF, jF, kF, 0, r, d_gp.dX, SoA0, SoA1, SoA2);
fy = fd_first_axis_radius(src, iF, jF, kF, 1, r, d_gp.dY, SoA0, SoA1, SoA2);
fz = fd_first_axis_radius(src, iF, jF, kF, 2, r, d_gp.dZ, SoA0, SoA1, SoA2);
#else
fx = fd_first_axis_radius(src, iF, jF, kF, 0, fd_axis_radius(iF, iminF, imaxF),
d_gp.dX, SoA0, SoA1, SoA2);
fy = fd_first_axis_radius(src, iF, jF, kF, 1, fd_axis_radius(jF, jminF, jmaxF),
d_gp.dY, SoA0, SoA1, SoA2);
fz = fd_first_axis_radius(src, iF, jF, kF, 2, fd_axis_radius(kF, kminF, kmaxF),
d_gp.dZ, SoA0, SoA1, SoA2);
#endif
}
__device__ __forceinline__ void fd_compute_second6(const double *src,
int iF, int jF, int kF,
int iminF, int jminF, int kminF,
int imaxF, int jmaxF, int kmaxF,
int SoA0, int SoA1, int SoA2,
double &fxx, double &fxy, double &fxz,
double &fyy, double &fyz, double &fzz)
{
#if ghost_width == 3
const int r = fd_common_radius(iF, jF, kF, iminF, jminF, kminF, imaxF, jmaxF, kmaxF);
const int rx = r, ry = r, rz = r;
#else
const int rx = fd_axis_radius(iF, iminF, imaxF);
const int ry = fd_axis_radius(jF, jminF, jmaxF);
const int rz = fd_axis_radius(kF, kminF, kmaxF);
#endif
fxx = fd_second_axis_radius(src, iF, jF, kF, 0, rx, d_gp.dX, SoA0, SoA1, SoA2);
fyy = fd_second_axis_radius(src, iF, jF, kF, 1, ry, d_gp.dY, SoA0, SoA1, SoA2);
fzz = fd_second_axis_radius(src, iF, jF, kF, 2, rz, d_gp.dZ, SoA0, SoA1, SoA2);
fxy = fd_mixed_axis_radius(src, iF, jF, kF, 0, rx, d_gp.dX, 1, ry, d_gp.dY, SoA0, SoA1, SoA2);
fxz = fd_mixed_axis_radius(src, iF, jF, kF, 0, rx, d_gp.dX, 2, rz, d_gp.dZ, SoA0, SoA1, SoA2);
fyz = fd_mixed_axis_radius(src, iF, jF, kF, 1, ry, d_gp.dY, 2, rz, d_gp.dZ, SoA0, SoA1, SoA2);
}
__device__ __forceinline__ bool fd_lop_fits(int qF, int qminF, int qmaxF,
int dir, int lo, int hi)
{
for (int off = lo; off <= hi; ++off) {
const int q = qF + dir * off;
if (q < qminF || q > qmaxF) return false;
}
return true;
}
__device__ __forceinline__ double fd_lop_fetch_sum(const double *src,
int iF, int jF, int kF,
int axis, int dir,
const double *coef,
int lo, int hi,
int SoA0, int SoA1, int SoA2)
{
double s = 0.0;
for (int off = lo; off <= hi; ++off) {
const double c = coef[off - lo];
if (c != 0.0) {
s += c * fd_fetch_axis(src, iF, jF, kF, axis, dir * off, SoA0, SoA1, SoA2);
}
}
return s;
}
__device__ __forceinline__ double fd_lopsided_axis(const double *src,
int iF, int jF, int kF,
int axis, double speed,
int qF, int qminF, int qmaxF,
double h,
int SoA0, int SoA1, int SoA2)
{
if (speed == 0.0) return 0.0;
const int dir = (speed > 0.0) ? 1 : -1;
const double mag = (speed > 0.0) ? speed : -speed;
#if ghost_width == 2
if (fd_lop_fits(qF, qminF, qmaxF, dir, 0, 2)) {
const double c[] = {-3.0, 4.0, -1.0};
return mag * fd_lop_fetch_sum(src, iF, jF, kF, axis, dir, c, 0, 2, SoA0, SoA1, SoA2) / (2.0 * h);
}
if (fd_lop_fits(qF, qminF, qmaxF, dir, 0, 1)) {
const double c[] = {-1.0, 1.0};
return mag * fd_lop_fetch_sum(src, iF, jF, kF, axis, dir, c, 0, 1, SoA0, SoA1, SoA2) / (2.0 * h);
}
return 0.0;
#elif ghost_width == 3
if (fd_lop_fits(qF, qminF, qmaxF, dir, -1, 3)) {
const double c[] = {-3.0, -10.0, 18.0, -6.0, 1.0};
return mag * fd_lop_fetch_sum(src, iF, jF, kF, axis, dir, c, -1, 3, SoA0, SoA1, SoA2) / (12.0 * h);
}
const int r = fd_axis_radius(qF, qminF, qmaxF);
return speed * fd_first_axis_radius(src, iF, jF, kF, axis, r, h, SoA0, SoA1, SoA2);
#elif ghost_width == 4
if (fd_lop_fits(qF, qminF, qmaxF, dir, -2, 4)) {
const double c[] = {2.0, -24.0, -35.0, 80.0, -30.0, 8.0, -1.0};
return mag * fd_lop_fetch_sum(src, iF, jF, kF, axis, dir, c, -2, 4, SoA0, SoA1, SoA2) / (60.0 * h);
}
if (fd_lop_fits(qF, qminF, qmaxF, dir, -1, 5)) {
const double c[] = {-10.0, -77.0, 150.0, -100.0, 50.0, -15.0, 2.0};
return mag * fd_lop_fetch_sum(src, iF, jF, kF, axis, dir, c, -1, 5, SoA0, SoA1, SoA2) / (60.0 * h);
}
const int r = fd_axis_radius(qF, qminF, qmaxF);
return speed * fd_first_axis_radius(src, iF, jF, kF, axis, r, h, SoA0, SoA1, SoA2);
#else
if (fd_lop_fits(qF, qminF, qmaxF, dir, -3, 5)) {
const double c[] = {-5.0, 60.0, -420.0, -378.0, 1050.0, -420.0, 140.0, -30.0, 3.0};
return mag * fd_lop_fetch_sum(src, iF, jF, kF, axis, dir, c, -3, 5, SoA0, SoA1, SoA2) / (840.0 * h);
}
const int r = fd_axis_radius(qF, qminF, qmaxF);
return speed * fd_first_axis_radius(src, iF, jF, kF, axis, r, h, SoA0, SoA1, SoA2);
#endif
}
__device__ __forceinline__ double fd_ko_coef(int r, int off)
{
const int a = off < 0 ? -off : off;
if (r == 2) {
if (a == 0) return 6.0;
if (a == 1) return -4.0;
if (a == 2) return 1.0;
} else if (r == 3) {
if (a == 0) return -20.0;
if (a == 1) return 15.0;
if (a == 2) return -6.0;
if (a == 3) return 1.0;
} else if (r == 4) {
if (a == 0) return 70.0;
if (a == 1) return -56.0;
if (a == 2) return 28.0;
if (a == 3) return -8.0;
if (a == 4) return 1.0;
} else if (r == 5) {
if (a == 0) return -252.0;
if (a == 1) return 210.0;
if (a == 2) return -120.0;
if (a == 3) return 45.0;
if (a == 4) return -10.0;
if (a == 5) return 1.0;
}
return 0.0;
}
__device__ __forceinline__ double fd_ko_axis(const double *src,
int iF, int jF, int kF,
int axis, int r,
int SoA0, int SoA1, int SoA2)
{
double s = 0.0;
#pragma unroll
for (int off = -5; off <= 5; ++off) {
if (off < -r || off > r) continue;
const double c = fd_ko_coef(r, off);
if (c != 0.0) {
s += c * fd_fetch_axis(src, iF, jF, kF, axis, off, SoA0, SoA1, SoA2);
}
}
return s;
}
__device__ __forceinline__ double fd_ko_term(const double *src,
int iF, int jF, int kF,
int iminF, int jminF, int kminF,
int imaxF, int jmaxF, int kmaxF,
double eps_val,
int SoA0, int SoA1, int SoA2)
{
const int r = AMSS_FD_LK_RADIUS;
if (eps_val <= 0.0) return 0.0;
#if ghost_width >= 4
if (iF - r <= iminF || iF + r >= imaxF ||
jF - r <= jminF || jF + r >= jmaxF ||
kF - r <= kminF || kF + r >= kmaxF) {
return 0.0;
}
#else
if (iF - r < iminF || iF + r > imaxF ||
jF - r < jminF || jF + r > jmaxF ||
kF - r < kminF || kF + r > kmaxF) {
return 0.0;
}
#endif
double cof = 1.0;
#pragma unroll
for (int n = 0; n < 2 * r; ++n) cof *= 2.0;
const double sign = (r & 1) ? 1.0 : -1.0;
const double dx = fd_ko_axis(src, iF, jF, kF, 0, r, SoA0, SoA1, SoA2);
const double dy = fd_ko_axis(src, iF, jF, kF, 1, r, SoA0, SoA1, SoA2);
const double dz = fd_ko_axis(src, iF, jF, kF, 2, r, SoA0, SoA1, SoA2);
return sign * eps_val * (dx / d_gp.dX + dy / d_gp.dY + dz / d_gp.dZ) / cof;
}
#endif

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AMSS_NCKU_source/fdderivs_c.C
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AMSS_NCKU_source/fdderivs_sh_c.C
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#include "macrodef.h"
#include "share_func.h"
/*
* fdderivs_sh — second derivatives on shell patch in (rho, sigma, R) coords.
* Same stencil coefficients as Cartesian fdderivs. Uses symmetry_stbd.
*/
extern "C" void fdderivs_sh_(const int ex[3],
const double *f,
double *fxx, double *fxy, double *fxz,
double *fyy, double *fyz, double *fzz,
const double *X, const double *Y, const double *Z,
double SYM1, double SYM2, double SYM3,
int Symmetry, int onoff, int sst)
{
(void)SYM3; (void)onoff; (void)sst;
const int NO_SYMM=0, EQ_SYMM=1, OCTANT=2;
const double ZEO=0.0, ONE=1.0, TWO=2.0, F1o4=2.5e-1;
const double F8=8.0, F16=16.0, F30=30.0, F1o12=ONE/12.0, F1o144=ONE/144.0;
const double F9=9.0, F45=45.0, F60=60.0, F27=27.0, F270=270.0, F490=490.0;
const double F1o180=ONE/180.0, F1o3600=ONE/3600.0;
const double F32=32.0, F128=128.0, F168=168.0, F672=672.0, F840=840.0;
const double F1008=1008.0, F8064=8064.0, F14350=14350.0;
const double F1o5040=ONE/5040.0, F1o705600=ONE/705600.0;
const int ex1=ex[0], ex2=ex[1], ex3=ex[2];
const double dX=X[1]-X[0], dY=Y[1]-Y[0], dZ=Z[1]-Z[0];
const int imaxF=ex1, jmaxF=ex2, kmaxF=ex3;
const double SoA[2]={SYM1,SYM2};
#if (ghost_width == 2)
{
const int ord=1;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=0;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=0;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=0;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
static double *fh_buf=NULL;static size_t cap=0;
if(fh_size>cap){free(fh_buf);fh_buf=(double*)aligned_alloc(64,fh_size*sizeof(double));cap=fh_size;}
double *fh=fh_buf;if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const double Sdxdx=ONE/(dX*dX),Sdydy=ONE/(dY*dY),Sdzdz=ONE/(dZ*dZ);
const double Sdxdy=F1o4/(dX*dY),Sdxdz=F1o4/(dX*dZ),Sdydz=F1o4/(dY*dZ);
const size_t all=(size_t)ex1*ex2*ex3;
for(size_t p=0;p<all;++p){fxx[p]=fyy[p]=fzz[p]=ZEO;fxy[p]=fxz[p]=fyz[p]=ZEO;}
const int i2_lo=(iminF>0)?iminF:0,j2_lo=(jminF>0)?jminF:0,k2_lo=1,i2_hi=ex1-2,j2_hi=ex2-2,k2_hi=ex3-2;
#define FH(iF,jF,kF) fh[idx_fh_stbd(iF,jF,kF,ord,ex)]
if(i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi){
for(int k0=k2_lo;k0<=k2_hi;++k0){const int kF=k0+1;
for(int j0=j2_lo;j0<=j2_hi;++j0){const int jF=j0+1;
for(int i0=i2_lo;i0<=i2_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Sdxdx*(FH(iF-1,jF,kF)-TWO*FH(iF,jF,kF)+FH(iF+1,jF,kF));
fyy[p]=Sdydy*(FH(iF,jF-1,kF)-TWO*FH(iF,jF,kF)+FH(iF,jF+1,kF));
fzz[p]=Sdzdz*(FH(iF,jF,kF-1)-TWO*FH(iF,jF,kF)+FH(iF,jF,kF+1));
fxy[p]=Sdxdy*(FH(iF-1,jF-1,kF)-FH(iF+1,jF-1,kF)-FH(iF-1,jF+1,kF)+FH(iF+1,jF+1,kF));
fxz[p]=Sdxdz*(FH(iF-1,jF,kF-1)-FH(iF+1,jF,kF-1)-FH(iF-1,jF,kF+1)+FH(iF+1,jF,kF+1));
fyz[p]=Sdydz*(FH(iF,jF-1,kF-1)-FH(iF,jF+1,kF-1)-FH(iF,jF-1,kF+1)+FH(iF,jF+1,kF+1));
}}}
}
#undef FH
return;
}
#elif (ghost_width == 3)
{
const int ord=2;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-1;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-1;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-1;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
static double *fh_buf=NULL;static size_t cap=0;
if(fh_size>cap){free(fh_buf);fh_buf=(double*)aligned_alloc(64,fh_size*sizeof(double));cap=fh_size;}
double *fh=fh_buf;if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const double Sdxdx=ONE/(dX*dX),Sdydy=ONE/(dY*dY),Sdzdz=ONE/(dZ*dZ);
const double Fdxdx=F1o12/(dX*dX),Fdydy=F1o12/(dY*dY),Fdzdz=F1o12/(dZ*dZ);
const double Sdxdy=F1o4/(dX*dY),Sdxdz=F1o4/(dX*dZ),Sdydz=F1o4/(dY*dZ);
const double Fdxdy=F1o144/(dX*dY),Fdxdz=F1o144/(dX*dZ),Fdydz=F1o144/(dY*dZ);
const size_t all=(size_t)ex1*ex2*ex3;
for(size_t p=0;p<all;++p){fxx[p]=fyy[p]=fzz[p]=fxy[p]=fxz[p]=fyz[p]=ZEO;}
const int i2_lo=(iminF>0)?iminF:0,j2_lo=(jminF>0)?jminF:0,k2_lo=1,i2_hi=ex1-2,j2_hi=ex2-2,k2_hi=ex3-2;
const int i4_lo=(iminF+1>0)?iminF+1:0,j4_lo=(jminF+1>0)?jminF+1:0,k4_lo=2,i4_hi=ex1-3,j4_hi=ex2-3,k4_hi=ex3-3;
const int has4=(i4_lo<=i4_hi&&j4_lo<=j4_hi&&k4_lo<=k4_hi);
#define FH(iF,jF,kF) fh[idx_fh_stbd(iF,jF,kF,ord,ex)]
if(i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi){
for(int k0=k2_lo;k0<=k2_hi;++k0){const int kF=k0+1;
for(int j0=j2_lo;j0<=j2_hi;++j0){const int jF=j0+1;
for(int i0=i2_lo;i0<=i2_hi;++i0){
if(has4&&i0>=i4_lo&&i0<=i4_hi&&j0>=j4_lo&&j0<=j4_hi&&k0>=k4_lo&&k0<=k4_hi)continue;
const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Sdxdx*(FH(iF-1,jF,kF)-TWO*FH(iF,jF,kF)+FH(iF+1,jF,kF));
fyy[p]=Sdydy*(FH(iF,jF-1,kF)-TWO*FH(iF,jF,kF)+FH(iF,jF+1,kF));
fzz[p]=Sdzdz*(FH(iF,jF,kF-1)-TWO*FH(iF,jF,kF)+FH(iF,jF,kF+1));
fxy[p]=Sdxdy*(FH(iF-1,jF-1,kF)-FH(iF+1,jF-1,kF)-FH(iF-1,jF+1,kF)+FH(iF+1,jF+1,kF));
fxz[p]=Sdxdz*(FH(iF-1,jF,kF-1)-FH(iF+1,jF,kF-1)-FH(iF-1,jF,kF+1)+FH(iF+1,jF,kF+1));
fyz[p]=Sdydz*(FH(iF,jF-1,kF-1)-FH(iF,jF+1,kF-1)-FH(iF,jF-1,kF+1)+FH(iF,jF+1,kF+1));
}}}
}
if(has4){
for(int k0=k4_lo;k0<=k4_hi;++k0){const int kF=k0+1;
for(int j0=j4_lo;j0<=j4_hi;++j0){const int jF=j0+1;
for(int i0=i4_lo;i0<=i4_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Fdxdx*(-FH(iF-2,jF,kF)+F16*FH(iF-1,jF,kF)-F30*FH(iF,jF,kF)-FH(iF+2,jF,kF)+F16*FH(iF+1,jF,kF));
fyy[p]=Fdydy*(-FH(iF,jF-2,kF)+F16*FH(iF,jF-1,kF)-F30*FH(iF,jF,kF)-FH(iF,jF+2,kF)+F16*FH(iF,jF+1,kF));
fzz[p]=Fdzdz*(-FH(iF,jF,kF-2)+F16*FH(iF,jF,kF-1)-F30*FH(iF,jF,kF)-FH(iF,jF,kF+2)+F16*FH(iF,jF,kF+1));
{const double t_jm2=(FH(iF-2,jF-2,kF)-F8*FH(iF-1,jF-2,kF)+F8*FH(iF+1,jF-2,kF)-FH(iF+2,jF-2,kF));
const double t_jm1=(FH(iF-2,jF-1,kF)-F8*FH(iF-1,jF-1,kF)+F8*FH(iF+1,jF-1,kF)-FH(iF+2,jF-1,kF));
const double t_jp1=(FH(iF-2,jF+1,kF)-F8*FH(iF-1,jF+1,kF)+F8*FH(iF+1,jF+1,kF)-FH(iF+2,jF+1,kF));
const double t_jp2=(FH(iF-2,jF+2,kF)-F8*FH(iF-1,jF+2,kF)+F8*FH(iF+1,jF+2,kF)-FH(iF+2,jF+2,kF));
fxy[p]=Fdxdy*(t_jm2-F8*t_jm1+F8*t_jp1-t_jp2);}
{const double t_km2=(FH(iF-2,jF,kF-2)-F8*FH(iF-1,jF,kF-2)+F8*FH(iF+1,jF,kF-2)-FH(iF+2,jF,kF-2));
const double t_km1=(FH(iF-2,jF,kF-1)-F8*FH(iF-1,jF,kF-1)+F8*FH(iF+1,jF,kF-1)-FH(iF+2,jF,kF-1));
const double t_kp1=(FH(iF-2,jF,kF+1)-F8*FH(iF-1,jF,kF+1)+F8*FH(iF+1,jF,kF+1)-FH(iF+2,jF,kF+1));
const double t_kp2=(FH(iF-2,jF,kF+2)-F8*FH(iF-1,jF,kF+2)+F8*FH(iF+1,jF,kF+2)-FH(iF+2,jF,kF+2));
fxz[p]=Fdxdz*(t_km2-F8*t_km1+F8*t_kp1-t_kp2);}
{const double t_km2=(FH(iF,jF-2,kF-2)-F8*FH(iF,jF-1,kF-2)+F8*FH(iF,jF+1,kF-2)-FH(iF,jF+2,kF-2));
const double t_km1=(FH(iF,jF-2,kF-1)-F8*FH(iF,jF-1,kF-1)+F8*FH(iF,jF+1,kF-1)-FH(iF,jF+2,kF-1));
const double t_kp1=(FH(iF,jF-2,kF+1)-F8*FH(iF,jF-1,kF+1)+F8*FH(iF,jF+1,kF+1)-FH(iF,jF+2,kF+1));
const double t_kp2=(FH(iF,jF-2,kF+2)-F8*FH(iF,jF-1,kF+2)+F8*FH(iF,jF+1,kF+2)-FH(iF,jF+2,kF+2));
fyz[p]=Fdydz*(t_km2-F8*t_km1+F8*t_kp1-t_kp2);}
}}}
}
#undef FH
return;
}
#elif (ghost_width == 4)
{
const int ord=3;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-2;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-2;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-2;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
static double *fh_buf=NULL;static size_t cap=0;
if(fh_size>cap){free(fh_buf);fh_buf=(double*)aligned_alloc(64,fh_size*sizeof(double));cap=fh_size;}
double *fh=fh_buf;if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const double Sdxdx=ONE/(dX*dX),Sdydy=ONE/(dY*dY),Sdzdz=ONE/(dZ*dZ);
const double Fdxdx=F1o12/(dX*dX),Fdydy=F1o12/(dY*dY),Fdzdz=F1o12/(dZ*dZ);
const double Xdxdx=F1o180/(dX*dX),Xdydy=F1o180/(dY*dY),Xdzdz=F1o180/(dZ*dZ);
const double Sdxdy=F1o4/(dX*dY),Sdxdz=F1o4/(dX*dZ),Sdydz=F1o4/(dY*dZ);
const double Fdxdy=F1o144/(dX*dY),Fdxdz=F1o144/(dX*dZ),Fdydz=F1o144/(dY*dZ);
const double Xdxdy=F1o3600/(dX*dY),Xdxdz=F1o3600/(dX*dZ),Xdydz=F1o3600/(dY*dZ);
const size_t all=(size_t)ex1*ex2*ex3;
for(size_t p=0;p<all;++p){fxx[p]=fyy[p]=fzz[p]=fxy[p]=fxz[p]=fyz[p]=ZEO;}
const int i2_lo=(iminF>0)?iminF:0,j2_lo=(jminF>0)?jminF:0,k2_lo=1,i2_hi=ex1-2,j2_hi=ex2-2,k2_hi=ex3-2;
const int i4_lo=(iminF+1>0)?iminF+1:0,j4_lo=(jminF+1>0)?jminF+1:0,k4_lo=2,i4_hi=ex1-3,j4_hi=ex2-3,k4_hi=ex3-3;
const int i6_lo=(iminF+2>0)?iminF+2:0,j6_lo=(jminF+2>0)?jminF+2:0,k6_lo=3,i6_hi=ex1-4,j6_hi=ex2-4,k6_hi=ex3-4;
const int has4=(i4_lo<=i4_hi&&j4_lo<=j4_hi&&k4_lo<=k4_hi),has6=(i6_lo<=i6_hi&&j6_lo<=j6_hi&&k6_lo<=k6_hi);
#define FH(iF,jF,kF) fh[idx_fh_stbd(iF,jF,kF,ord,ex)]
if(i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi){for(int k0=k2_lo;k0<=k2_hi;++k0){const int kF=k0+1;
for(int j0=j2_lo;j0<=j2_hi;++j0){const int jF=j0+1;
for(int i0=i2_lo;i0<=i2_hi;++i0){bool in4=has4&&i0>=i4_lo&&i0<=i4_hi&&j0>=j4_lo&&j0<=j4_hi&&k0>=k4_lo&&k0<=k4_hi;if(in4)continue;
const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Sdxdx*(FH(iF-1,jF,kF)-TWO*FH(iF,jF,kF)+FH(iF+1,jF,kF));
fyy[p]=Sdydy*(FH(iF,jF-1,kF)-TWO*FH(iF,jF,kF)+FH(iF,jF+1,kF));
fzz[p]=Sdzdz*(FH(iF,jF,kF-1)-TWO*FH(iF,jF,kF)+FH(iF,jF,kF+1));
fxy[p]=Sdxdy*(FH(iF-1,jF-1,kF)-FH(iF+1,jF-1,kF)-FH(iF-1,jF+1,kF)+FH(iF+1,jF+1,kF));
fxz[p]=Sdxdz*(FH(iF-1,jF,kF-1)-FH(iF+1,jF,kF-1)-FH(iF-1,jF,kF+1)+FH(iF+1,jF,kF+1));
fyz[p]=Sdydz*(FH(iF,jF-1,kF-1)-FH(iF,jF+1,kF-1)-FH(iF,jF-1,kF+1)+FH(iF,jF+1,kF+1));
}}}}
if(has4){for(int k0=k4_lo;k0<=k4_hi;++k0){const int kF=k0+1;
for(int j0=j4_lo;j0<=j4_hi;++j0){const int jF=j0+1;
for(int i0=i4_lo;i0<=i4_hi;++i0){if(has6&&i0>=i6_lo&&i0<=i6_hi&&j0>=j6_lo&&j0<=j6_hi&&k0>=k6_lo&&k0<=k6_hi)continue;
const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Fdxdx*(-FH(iF-2,jF,kF)+F16*FH(iF-1,jF,kF)-F30*FH(iF,jF,kF)-FH(iF+2,jF,kF)+F16*FH(iF+1,jF,kF));
fyy[p]=Fdydy*(-FH(iF,jF-2,kF)+F16*FH(iF,jF-1,kF)-F30*FH(iF,jF,kF)-FH(iF,jF+2,kF)+F16*FH(iF,jF+1,kF));
fzz[p]=Fdzdz*(-FH(iF,jF,kF-2)+F16*FH(iF,jF,kF-1)-F30*FH(iF,jF,kF)-FH(iF,jF,kF+2)+F16*FH(iF,jF,kF+1));
{const double t_jm2=(FH(iF-2,jF-2,kF)-F8*FH(iF-1,jF-2,kF)+F8*FH(iF+1,jF-2,kF)-FH(iF+2,jF-2,kF));
const double t_jm1=(FH(iF-2,jF-1,kF)-F8*FH(iF-1,jF-1,kF)+F8*FH(iF+1,jF-1,kF)-FH(iF+2,jF-1,kF));
const double t_jp1=(FH(iF-2,jF+1,kF)-F8*FH(iF-1,jF+1,kF)+F8*FH(iF+1,jF+1,kF)-FH(iF+2,jF+1,kF));
const double t_jp2=(FH(iF-2,jF+2,kF)-F8*FH(iF-1,jF+2,kF)+F8*FH(iF+1,jF+2,kF)-FH(iF+2,jF+2,kF));
fxy[p]=Fdxdy*(t_jm2-F8*t_jm1+F8*t_jp1-t_jp2);}
{const double t_km2=(FH(iF-2,jF,kF-2)-F8*FH(iF-1,jF,kF-2)+F8*FH(iF+1,jF,kF-2)-FH(iF+2,jF,kF-2));
const double t_km1=(FH(iF-2,jF,kF-1)-F8*FH(iF-1,jF,kF-1)+F8*FH(iF+1,jF,kF-1)-FH(iF+2,jF,kF-1));
const double t_kp1=(FH(iF-2,jF,kF+1)-F8*FH(iF-1,jF,kF+1)+F8*FH(iF+1,jF,kF+1)-FH(iF+2,jF,kF+1));
const double t_kp2=(FH(iF-2,jF,kF+2)-F8*FH(iF-1,jF,kF+2)+F8*FH(iF+1,jF,kF+2)-FH(iF+2,jF,kF+2));
fxz[p]=Fdxdz*(t_km2-F8*t_km1+F8*t_kp1-t_kp2);}
{const double t_km2=(FH(iF,jF-2,kF-2)-F8*FH(iF,jF-1,kF-2)+F8*FH(iF,jF+1,kF-2)-FH(iF,jF+2,kF-2));
const double t_km1=(FH(iF,jF-2,kF-1)-F8*FH(iF,jF-1,kF-1)+F8*FH(iF,jF+1,kF-1)-FH(iF,jF+2,kF-1));
const double t_kp1=(FH(iF,jF-2,kF+1)-F8*FH(iF,jF-1,kF+1)+F8*FH(iF,jF+1,kF+1)-FH(iF,jF+2,kF+1));
const double t_kp2=(FH(iF,jF-2,kF+2)-F8*FH(iF,jF-1,kF+2)+F8*FH(iF,jF+1,kF+2)-FH(iF,jF+2,kF+2));
fyz[p]=Fdydz*(t_km2-F8*t_km1+F8*t_kp1-t_kp2);}
}}}}
if(has6){for(int k0=k6_lo;k0<=k6_hi;++k0){const int kF=k0+1;
for(int j0=j6_lo;j0<=j6_hi;++j0){const int jF=j0+1;
for(int i0=i6_lo;i0<=i6_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Xdxdx*(TWO*FH(iF-3,jF,kF)-F27*FH(iF-2,jF,kF)+F270*FH(iF-1,jF,kF)-F490*FH(iF,jF,kF)+F270*FH(iF+1,jF,kF)-F27*FH(iF+2,jF,kF)+TWO*FH(iF+3,jF,kF));
fyy[p]=Xdydy*(TWO*FH(iF,jF-3,kF)-F27*FH(iF,jF-2,kF)+F270*FH(iF,jF-1,kF)-F490*FH(iF,jF,kF)+F270*FH(iF,jF+1,kF)-F27*FH(iF,jF+2,kF)+TWO*FH(iF,jF+3,kF));
fzz[p]=Xdzdz*(TWO*FH(iF,jF,kF-3)-F27*FH(iF,jF,kF-2)+F270*FH(iF,jF,kF-1)-F490*FH(iF,jF,kF)+F270*FH(iF,jF,kF+1)-F27*FH(iF,jF,kF+2)+TWO*FH(iF,jF,kF+3));
#define XS6(JF,KFDUMMY) (-FH(iF-3,JF,KFDUMMY)+F9*FH(iF-2,JF,KFDUMMY)-F45*FH(iF-1,JF,KFDUMMY)+F45*FH(iF+1,JF,KFDUMMY)-F9*FH(iF+2,JF,KFDUMMY)+FH(iF+3,JF,KFDUMMY))
fxy[p]=Xdxdy*(-XS6(jF-3,kF)+F9*XS6(jF-2,kF)-F45*XS6(jF-1,kF)+F45*XS6(jF+1,kF)-F9*XS6(jF+2,kF)+XS6(jF+3,kF));
fxz[p]=Xdxdz*(-XS6(jF,kF-3)+F9*XS6(jF,kF-2)-F45*XS6(jF,kF-1)+F45*XS6(jF,kF+1)-F9*XS6(jF,kF+2)+XS6(jF,kF+3));
#undef XS6
#define YS6(JF,KFDUMMY) (-FH(iF,JF-3,KFDUMMY)+F9*FH(iF,JF-2,KFDUMMY)-F45*FH(iF,JF-1,KFDUMMY)+F45*FH(iF,JF+1,KFDUMMY)-F9*FH(iF,JF+2,KFDUMMY)+FH(iF,JF+3,KFDUMMY))
fyz[p]=Xdydz*(-YS6(jF,kF-3)+F9*YS6(jF,kF-2)-F45*YS6(jF,kF-1)+F45*YS6(jF,kF+1)-F9*YS6(jF,kF+2)+YS6(jF,kF+3));
#undef YS6
}}}}
#undef FH
return;
}
#elif (ghost_width == 5)
{
/* 8th-order shell second derivatives — inherits 8th-order stencil coeffs from Cartesian */
const int ord=4;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-3;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-3;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-3;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
static double *fh_buf=NULL;static size_t cap=0;
if(fh_size>cap){free(fh_buf);fh_buf=(double*)aligned_alloc(64,fh_size*sizeof(double));cap=fh_size;}
double *fh=fh_buf;if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const double Sdxdx=ONE/(dX*dX),Sdydy=ONE/(dY*dY),Sdzdz=ONE/(dZ*dZ);
const double Fdxdx=F1o12/(dX*dX),Fdydy=F1o12/(dY*dY),Fdzdz=F1o12/(dZ*dZ);
const double Xdxdx=F1o180/(dX*dX),Xdydy=F1o180/(dY*dY),Xdzdz=F1o180/(dZ*dZ);
const double Edxdx=F1o5040/(dX*dX),Edydy=F1o5040/(dY*dY),Edzdz=F1o5040/(dZ*dZ);
const double Sdxdy=F1o4/(dX*dY),Sdxdz=F1o4/(dX*dZ),Sdydz=F1o4/(dY*dZ);
const double Fdxdy=F1o144/(dX*dY),Fdxdz=F1o144/(dX*dZ),Fdydz=F1o144/(dY*dZ);
const double Xdxdy=F1o3600/(dX*dY),Xdxdz=F1o3600/(dX*dZ),Xdydz=F1o3600/(dY*dZ);
const double Edxdy=F1o705600/(dX*dY),Edxdz=F1o705600/(dX*dZ),Edydz=F1o705600/(dY*dZ);
const size_t all=(size_t)ex1*ex2*ex3;
for(size_t p=0;p<all;++p){fxx[p]=fyy[p]=fzz[p]=fxy[p]=fxz[p]=fyz[p]=ZEO;}
const int i2_lo=(iminF>0)?iminF:0,j2_lo=(jminF>0)?jminF:0,k2_lo=1,i2_hi=ex1-2,j2_hi=ex2-2,k2_hi=ex3-2;
const int i4_lo=(iminF+1>0)?iminF+1:0,j4_lo=(jminF+1>0)?jminF+1:0,k4_lo=2,i4_hi=ex1-3,j4_hi=ex2-3,k4_hi=ex3-3;
const int i6_lo=(iminF+2>0)?iminF+2:0,j6_lo=(jminF+2>0)?jminF+2:0,k6_lo=3,i6_hi=ex1-4,j6_hi=ex2-4,k6_hi=ex3-4;
const int i8_lo=(iminF+3>0)?iminF+3:0,j8_lo=(jminF+3>0)?jminF+3:0,k8_lo=4,i8_hi=ex1-5,j8_hi=ex2-5,k8_hi=ex3-5;
const int has4=(i4_lo<=i4_hi&&j4_lo<=j4_hi&&k4_lo<=k4_hi),has6=(i6_lo<=i6_hi&&j6_lo<=j6_hi&&k6_lo<=k6_hi),has8=(i8_lo<=i8_hi&&j8_lo<=j8_hi&&k8_lo<=k8_hi);
#define FH(iF,jF,kF) fh[idx_fh_stbd(iF,jF,kF,ord,ex)]
/* 2nd-order pass */
if(i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi){for(int k0=k2_lo;k0<=k2_hi;++k0){const int kF=k0+1;
for(int j0=j2_lo;j0<=j2_hi;++j0){const int jF=j0+1;
for(int i0=i2_lo;i0<=i2_hi;++i0){bool in4=has4&&i0>=i4_lo&&i0<=i4_hi&&j0>=j4_lo&&j0<=j4_hi&&k0>=k4_lo&&k0<=k4_hi;if(in4)continue;
const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Sdxdx*(FH(iF-1,jF,kF)-TWO*FH(iF,jF,kF)+FH(iF+1,jF,kF));
fyy[p]=Sdydy*(FH(iF,jF-1,kF)-TWO*FH(iF,jF,kF)+FH(iF,jF+1,kF));
fzz[p]=Sdzdz*(FH(iF,jF,kF-1)-TWO*FH(iF,jF,kF)+FH(iF,jF,kF+1));
fxy[p]=Sdxdy*(FH(iF-1,jF-1,kF)-FH(iF+1,jF-1,kF)-FH(iF-1,jF+1,kF)+FH(iF+1,jF+1,kF));
fxz[p]=Sdxdz*(FH(iF-1,jF,kF-1)-FH(iF+1,jF,kF-1)-FH(iF-1,jF,kF+1)+FH(iF+1,jF,kF+1));
fyz[p]=Sdydz*(FH(iF,jF-1,kF-1)-FH(iF,jF+1,kF-1)-FH(iF,jF-1,kF+1)+FH(iF,jF+1,kF+1));
}}}}
/* 4th-order pass */
if(has4){for(int k0=k4_lo;k0<=k4_hi;++k0){const int kF=k0+1;
for(int j0=j4_lo;j0<=j4_hi;++j0){const int jF=j0+1;
for(int i0=i4_lo;i0<=i4_hi;++i0){bool in6=has6&&i0>=i6_lo&&i0<=i6_hi&&j0>=j6_lo&&j0<=j6_hi&&k0>=k6_lo&&k0<=k6_hi;if(in6)continue;
const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Fdxdx*(-FH(iF-2,jF,kF)+F16*FH(iF-1,jF,kF)-F30*FH(iF,jF,kF)-FH(iF+2,jF,kF)+F16*FH(iF+1,jF,kF));
fyy[p]=Fdydy*(-FH(iF,jF-2,kF)+F16*FH(iF,jF-1,kF)-F30*FH(iF,jF,kF)-FH(iF,jF+2,kF)+F16*FH(iF,jF+1,kF));
fzz[p]=Fdzdz*(-FH(iF,jF,kF-2)+F16*FH(iF,jF,kF-1)-F30*FH(iF,jF,kF)-FH(iF,jF,kF+2)+F16*FH(iF,jF,kF+1));
{const double t_jm2=(FH(iF-2,jF-2,kF)-F8*FH(iF-1,jF-2,kF)+F8*FH(iF+1,jF-2,kF)-FH(iF+2,jF-2,kF));
const double t_jm1=(FH(iF-2,jF-1,kF)-F8*FH(iF-1,jF-1,kF)+F8*FH(iF+1,jF-1,kF)-FH(iF+2,jF-1,kF));
const double t_jp1=(FH(iF-2,jF+1,kF)-F8*FH(iF-1,jF+1,kF)+F8*FH(iF+1,jF+1,kF)-FH(iF+2,jF+1,kF));
const double t_jp2=(FH(iF-2,jF+2,kF)-F8*FH(iF-1,jF+2,kF)+F8*FH(iF+1,jF+2,kF)-FH(iF+2,jF+2,kF));
fxy[p]=Fdxdy*(t_jm2-F8*t_jm1+F8*t_jp1-t_jp2);}
{const double t_km2=(FH(iF-2,jF,kF-2)-F8*FH(iF-1,jF,kF-2)+F8*FH(iF+1,jF,kF-2)-FH(iF+2,jF,kF-2));
const double t_km1=(FH(iF-2,jF,kF-1)-F8*FH(iF-1,jF,kF-1)+F8*FH(iF+1,jF,kF-1)-FH(iF+2,jF,kF-1));
const double t_kp1=(FH(iF-2,jF,kF+1)-F8*FH(iF-1,jF,kF+1)+F8*FH(iF+1,jF,kF+1)-FH(iF+2,jF,kF+1));
const double t_kp2=(FH(iF-2,jF,kF+2)-F8*FH(iF-1,jF,kF+2)+F8*FH(iF+1,jF,kF+2)-FH(iF+2,jF,kF+2));
fxz[p]=Fdxdz*(t_km2-F8*t_km1+F8*t_kp1-t_kp2);}
{const double t_km2=(FH(iF,jF-2,kF-2)-F8*FH(iF,jF-1,kF-2)+F8*FH(iF,jF+1,kF-2)-FH(iF,jF+2,kF-2));
const double t_km1=(FH(iF,jF-2,kF-1)-F8*FH(iF,jF-1,kF-1)+F8*FH(iF,jF+1,kF-1)-FH(iF,jF+2,kF-1));
const double t_kp1=(FH(iF,jF-2,kF+1)-F8*FH(iF,jF-1,kF+1)+F8*FH(iF,jF+1,kF+1)-FH(iF,jF+2,kF+1));
const double t_kp2=(FH(iF,jF-2,kF+2)-F8*FH(iF,jF-1,kF+2)+F8*FH(iF,jF+1,kF+2)-FH(iF,jF+2,kF+2));
fyz[p]=Fdydz*(t_km2-F8*t_km1+F8*t_kp1-t_kp2);}
}}}}
/* 6th-order pass */
if(has6){for(int k0=k6_lo;k0<=k6_hi;++k0){const int kF=k0+1;
for(int j0=j6_lo;j0<=j6_hi;++j0){const int jF=j0+1;
for(int i0=i6_lo;i0<=i6_hi;++i0){if(has8&&i0>=i8_lo&&i0<=i8_hi&&j0>=j8_lo&&j0<=j8_hi&&k0>=k8_lo&&k0<=k8_hi)continue;
const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Xdxdx*(TWO*FH(iF-3,jF,kF)-F27*FH(iF-2,jF,kF)+F270*FH(iF-1,jF,kF)-F490*FH(iF,jF,kF)+F270*FH(iF+1,jF,kF)-F27*FH(iF+2,jF,kF)+TWO*FH(iF+3,jF,kF));
fyy[p]=Xdydy*(TWO*FH(iF,jF-3,kF)-F27*FH(iF,jF-2,kF)+F270*FH(iF,jF-1,kF)-F490*FH(iF,jF,kF)+F270*FH(iF,jF+1,kF)-F27*FH(iF,jF+2,kF)+TWO*FH(iF,jF+3,kF));
fzz[p]=Xdzdz*(TWO*FH(iF,jF,kF-3)-F27*FH(iF,jF,kF-2)+F270*FH(iF,jF,kF-1)-F490*FH(iF,jF,kF)+F270*FH(iF,jF,kF+1)-F27*FH(iF,jF,kF+2)+TWO*FH(iF,jF,kF+3));
#define XS6_8(JF,KFDUMMY) (-FH(iF-3,JF,KFDUMMY)+F9*FH(iF-2,JF,KFDUMMY)-F45*FH(iF-1,JF,KFDUMMY)+F45*FH(iF+1,JF,KFDUMMY)-F9*FH(iF+2,JF,KFDUMMY)+FH(iF+3,JF,KFDUMMY))
fxy[p]=Xdxdy*(-XS6_8(jF-3,kF)+F9*XS6_8(jF-2,kF)-F45*XS6_8(jF-1,kF)+F45*XS6_8(jF+1,kF)-F9*XS6_8(jF+2,kF)+XS6_8(jF+3,kF));
fxz[p]=Xdxdz*(-XS6_8(jF,kF-3)+F9*XS6_8(jF,kF-2)-F45*XS6_8(jF,kF-1)+F45*XS6_8(jF,kF+1)-F9*XS6_8(jF,kF+2)+XS6_8(jF,kF+3));
#undef XS6_8
#define YS6_8(JF,KFDUMMY) (-FH(iF,JF-3,KFDUMMY)+F9*FH(iF,JF-2,KFDUMMY)-F45*FH(iF,JF-1,KFDUMMY)+F45*FH(iF,JF+1,KFDUMMY)-F9*FH(iF,JF+2,KFDUMMY)+FH(iF,JF+3,KFDUMMY))
fyz[p]=Xdydz*(-YS6_8(jF,kF-3)+F9*YS6_8(jF,kF-2)-F45*YS6_8(jF,kF-1)+F45*YS6_8(jF,kF+1)-F9*YS6_8(jF,kF+2)+YS6_8(jF,kF+3));
#undef YS6_8
}}}}
/* 8th-order pass */
if(has8){for(int k0=k8_lo;k0<=k8_hi;++k0){const int kF=k0+1;
for(int j0=j8_lo;j0<=j8_hi;++j0){const int jF=j0+1;
for(int i0=i8_lo;i0<=i8_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fxx[p]=Edxdx*(-(double)9*FH(iF-4,jF,kF)+F128*FH(iF-3,jF,kF)-F1008*FH(iF-2,jF,kF)+F8064*FH(iF-1,jF,kF)-F14350*FH(iF,jF,kF)+F8064*FH(iF+1,jF,kF)-F1008*FH(iF+2,jF,kF)+F128*FH(iF+3,jF,kF)-(double)9*FH(iF+4,jF,kF));
fyy[p]=Edydy*(-(double)9*FH(iF,jF-4,kF)+F128*FH(iF,jF-3,kF)-F1008*FH(iF,jF-2,kF)+F8064*FH(iF,jF-1,kF)-F14350*FH(iF,jF,kF)+F8064*FH(iF,jF+1,kF)-F1008*FH(iF,jF+2,kF)+F128*FH(iF,jF+3,kF)-(double)9*FH(iF,jF+4,kF));
fzz[p]=Edzdz*(-(double)9*FH(iF,jF,kF-4)+F128*FH(iF,jF,kF-3)-F1008*FH(iF,jF,kF-2)+F8064*FH(iF,jF,kF-1)-F14350*FH(iF,jF,kF)+F8064*FH(iF,jF,kF+1)-F1008*FH(iF,jF,kF+2)+F128*FH(iF,jF,kF+3)-(double)9*FH(iF,jF,kF+4));
#define XS8(JF,KFDUMMY) (+(double)3*FH(iF-4,JF,KFDUMMY)-F32*FH(iF-3,JF,KFDUMMY)+F168*FH(iF-2,JF,KFDUMMY)-F672*FH(iF-1,JF,KFDUMMY)+F672*FH(iF+1,JF,KFDUMMY)-F168*FH(iF+2,JF,KFDUMMY)+F32*FH(iF+3,JF,KFDUMMY)-(double)3*FH(iF+4,JF,KFDUMMY))
fxy[p]=Edxdy*(+(double)3*XS8(jF-4,kF)-F32*XS8(jF-3,kF)+F168*XS8(jF-2,kF)-F672*XS8(jF-1,kF)+F672*XS8(jF+1,kF)-F168*XS8(jF+2,kF)+F32*XS8(jF+3,kF)-(double)3*XS8(jF+4,kF));
fxz[p]=Edxdz*(+(double)3*XS8(jF,kF-4)-F32*XS8(jF,kF-3)+F168*XS8(jF,kF-2)-F672*XS8(jF,kF-1)+F672*XS8(jF,kF+1)-F168*XS8(jF,kF+2)+F32*XS8(jF,kF+3)-(double)3*XS8(jF,kF+4));
#undef XS8
#define YS8(JF,KFDUMMY) (+(double)3*FH(iF,JF-4,KFDUMMY)-F32*FH(iF,JF-3,KFDUMMY)+F168*FH(iF,JF-2,KFDUMMY)-F672*FH(iF,JF-1,KFDUMMY)+F672*FH(iF,JF+1,KFDUMMY)-F168*FH(iF,JF+2,KFDUMMY)+F32*FH(iF,JF+3,KFDUMMY)-(double)3*FH(iF,JF+4,KFDUMMY))
fyz[p]=Edydz*(+(double)3*YS8(jF,kF-4)-F32*YS8(jF,kF-3)+F168*YS8(jF,kF-2)-F672*YS8(jF,kF-1)+F672*YS8(jF,kF+1)-F168*YS8(jF,kF+2)+F32*YS8(jF,kF+3)-(double)3*YS8(jF,kF+4));
#undef YS8
}}}}
#undef FH
return;
}
#else
#error "fdderivs_sh_c.C: unsupported ghost_width"
#endif
}

107
AMSS_NCKU_source/fdderivs_shc_c.C
View File

@@ -1,107 +0,0 @@
#include "macrodef.h"
#include "share_func.h"
#include <cstddef>
/* Forward declarations — Fortran-mangled names from shell C kernels */
extern "C" {
void fderivs_sh_(const int ex[3], const double *f,
double *fx, double *fy, double *fz,
const double *X, const double *Y, const double *Z,
double SYM1, double SYM2, double SYM3,
int Symmetry, int onoff, int sst);
void fdderivs_sh_(const int ex[3], const double *f,
double *fxx, double *fxy, double *fxz,
double *fyy, double *fyz, double *fzz,
const double *X, const double *Y, const double *Z,
double SYM1, double SYM2, double SYM3,
int Symmetry, int onoff, int sst);
void fdderivs_shc_(int *ex,
double *f,
double *fxx, double *fxy, double *fxz,
double *fyy, double *fyz, double *fzz,
double *crho, double *sigma, double *R,
double &SYM1, double &SYM2, double &SYM3,
int &Symmetry, int &Lev, int &sst,
double *drhodx, double *drhody, double *drhodz,
double *dsigmadx, double *dsigmady, double *dsigmadz,
double *dRdx, double *dRdy, double *dRdz,
double *drhodxx, double *drhodxy, double *drhodxz,
double *drhodyy, double *drhodyz, double *drhodzz,
double *dsigmadxx, double *dsigmadxy, double *dsigmadxz,
double *dsigmadyy, double *dsigmadyz, double *dsigmadzz,
double *dRdxx, double *dRdxy, double *dRdxz,
double *dRdyy, double *dRdyz, double *dRdzz)
{
const int ex3[3] = { ex[0], ex[1], ex[2] };
const size_t n = (size_t)ex[0] * (size_t)ex[1] * (size_t)ex[2];
double *gx = (double*)malloc(n * sizeof(double));
double *gy = (double*)malloc(n * sizeof(double));
double *gz = (double*)malloc(n * sizeof(double));
double *gxx = (double*)malloc(n * sizeof(double));
double *gxy = (double*)malloc(n * sizeof(double));
double *gxz = (double*)malloc(n * sizeof(double));
double *gyy = (double*)malloc(n * sizeof(double));
double *gyz = (double*)malloc(n * sizeof(double));
double *gzz = (double*)malloc(n * sizeof(double));
if (!gx||!gy||!gz||!gxx||!gxy||!gxz||!gyy||!gyz||!gzz) {
free(gx);free(gy);free(gz);free(gxx);free(gxy);free(gxz);free(gyy);free(gyz);free(gzz);
return;
}
fderivs_sh_(ex3, f, gx, gy, gz, crho, sigma, R, SYM1, SYM2, SYM3, Symmetry, Lev, sst);
fdderivs_sh_(ex3, f, gxx, gxy, gxz, gyy, gyz, gzz, crho, sigma, R, SYM1, SYM2, SYM3, Symmetry, Lev, sst);
for (size_t i = 0; i < n; ++i) {
const double rx=drhodx[i], ry=drhody[i], rz=drhodz[i];
const double sx=dsigmadx[i], sy=dsigmady[i], sz=dsigmadz[i];
const double Rx=dRdx[i], Ry=dRdy[i], Rz=dRdz[i];
const double rxx=drhodxx[i], rxy=drhodxy[i], rxz=drhodxz[i];
const double ryy=drhodyy[i], ryz=drhodyz[i], rzz=drhodzz[i];
const double sxx=dsigmadxx[i], sxy=dsigmadxy[i], sxz=dsigmadxz[i];
const double syy=dsigmadyy[i], syz=dsigmadyz[i], szz=dsigmadzz[i];
const double Rxx=dRdxx[i], Rxy=dRdxy[i], Rxz=dRdxz[i];
const double Ryy=dRdyy[i], Ryz=dRdyz[i], Rzz=dRdzz[i];
const double Gr=gx[i], Gs=gy[i], GR=gz[i];
const double Grr=gxx[i], Grs=gxy[i], GrR=gxz[i];
const double Gss=gyy[i], GsR=gyz[i], GRR=gzz[i];
/* fxx */
fxx[i] = rx*rx*Grr + sx*sx*Gss + Rx*Rx*GRR
+ 2.0*(rx*sx*Grs + rx*Rx*GrR + sx*Rx*GsR)
+ rxx*Gr + sxx*Gs + Rxx*GR;
/* fxy */
fxy[i] = rx*ry*Grr + sx*sy*Gss + Rx*Ry*GRR
+ rx*sy*Grs + ry*sx*Grs + rx*Ry*GrR + ry*Rx*GrR + sx*Ry*GsR + sy*Rx*GsR
+ rxy*Gr + sxy*Gs + Rxy*GR;
/* fxz */
fxz[i] = rx*rz*Grr + sx*sz*Gss + Rx*Rz*GRR
+ rx*sz*Grs + rz*sx*Grs + rx*Rz*GrR + rz*Rx*GrR + sx*Rz*GsR + sz*Rx*GsR
+ rxz*Gr + sxz*Gs + Rxz*GR;
/* fyy */
fyy[i] = ry*ry*Grr + sy*sy*Gss + Ry*Ry*GRR
+ 2.0*(ry*sy*Grs + ry*Ry*GrR + sy*Ry*GsR)
+ ryy*Gr + syy*Gs + Ryy*GR;
/* fyz */
fyz[i] = ry*rz*Grr + sy*sz*Gss + Ry*Rz*GRR
+ ry*sz*Grs + rz*sy*Grs + ry*Rz*GrR + rz*Ry*GrR + sy*Rz*GsR + sz*Ry*GsR
+ ryz*Gr + syz*Gs + Ryz*GR;
/* fzz */
fzz[i] = rz*rz*Grr + sz*sz*Gss + Rz*Rz*GRR
+ 2.0*(rz*sz*Grs + rz*Rz*GrR + sz*Rz*GsR)
+ rzz*Gr + szz*Gs + Rzz*GR;
}
free(gx);free(gy);free(gz);free(gxx);free(gxy);free(gxz);free(gyy);free(gyz);free(gzz);
}
} // extern "C"

683
AMSS_NCKU_source/fderivs_c.C
View File

@@ -1,18 +1,14 @@
#include "macrodef.h"
#include "tool.h"
/*
* C 版 fderivs — first derivatives df/dx, df/dy, df/dz.
* C 版 fderivs
*
* Finite difference order is selected at compile time via the ghost_width macro
* (defined in macrodef.fh):
* ghost_width = 2 → 2nd-order
* ghost_width = 3 → 4th-order
* ghost_width = 4 → 6th-order
* ghost_width = 5 → 8th-order
* Fortran:
* subroutine fderivs(ex,f,fx,fy,fz,X,Y,Z,SYM1,SYM2,SYM3,symmetry,onoff)
*
* Multi-pass overwrite strategy: compute the widest (lowest-order) stencil first,
* then overwrite interior regions with progressively higher-order stencils.
* 约定:
* f, fx, fy, fz: ex1*ex2*ex3按 idx_ex 布局
* X: ex1, Y: ex2, Z: ex3
*/
void fderivs(const int ex[3],
const double *f,
@@ -21,596 +17,151 @@ void fderivs(const int ex[3],
double SYM1, double SYM2, double SYM3,
int Symmetry, int onoff)
{
(void)onoff;
(void)onoff; // Fortran 里没用到
const double ZEO = 0.0, ONE = 1.0, TWO = 2.0, EIT = 8.0;
const double F9 = 9.0, F12 = 12.0, F45 = 45.0, F60 = 60.0;
const double F32 = 32.0, F168 = 168.0, F672 = 672.0, F840 = 840.0;
const double ZEO = 0.0, ONE = 1.0;
const double TWO = 2.0, EIT = 8.0;
const double F12 = 12.0;
const int NO_SYMM = 0, EQ_SYMM = 1;
const int NO_SYMM = 0, EQ_SYMM = 1; // OCTANT=2 在本子程序里不直接用
const int ex1 = ex[0], ex2 = ex[1], ex3 = ex[2];
// dX = X(2)-X(1) -> C: X[1]-X[0]
const double dX = X[1] - X[0];
const double dY = Y[1] - Y[0];
const double dZ = Z[1] - Z[0];
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
// Fortran 1-based bounds
const int imaxF = ex1;
const int jmaxF = ex2;
const int kmaxF = ex3;
const int gw = ghost_width; // compile-time constant
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -1;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -1;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -1;
#if (ghost_width == 2)
/* ---- 2nd-order ------------------------------------------------------ */
{
const int ord = 1; // symmetry_bd ord = ghost_width - 1
// SoA(1:3) = SYM1,SYM2,SYM3
const double SoA[3] = { SYM1, SYM2, SYM3 };
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = 0;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = 0;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = 0;
// fh: (ex1+2)*(ex2+2)*(ex3+2) because ord=2
const size_t nx = (size_t)ex1 + 2;
const size_t ny = (size_t)ex2 + 2;
const size_t nz = (size_t)ex3 + 2;
const size_t fh_size = nx * ny * nz;
static double *fh = NULL;
static size_t cap = 0;
const double SoA[3] = { SYM1, SYM2, SYM3 };
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
static double *fh_buf = NULL;
static size_t cap = 0;
if (fh_size > cap) {
free(fh_buf);
fh_buf = (double*)aligned_alloc(64, fh_size * sizeof(double));
cap = fh_size;
}
double *fh = fh_buf;
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
const size_t all = (size_t)ex1 * (size_t)ex2 * (size_t)ex3;
for (size_t p = 0; p < all; ++p) {
fx[p] = ZEO; fy[p] = ZEO; fz[p] = ZEO;
}
/* 2nd-order pass: [-1, 0, +1] / (2*dx) */
const int i2_lo = (iminF > 0) ? iminF : 0;
const int j2_lo = (jminF > 0) ? jminF : 0;
const int k2_lo = (kminF > 0) ? kminF : 0;
const int i2_hi = ex1 - 2;
const int j2_hi = ex2 - 2;
const int k2_hi = ex3 - 2;
if (i2_lo <= i2_hi && j2_lo <= j2_hi && k2_lo <= k2_hi) {
for (int k0 = k2_lo; k0 <= k2_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j2_lo; j0 <= j2_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i2_lo; i0 <= i2_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d2dx * (
-fh[idx_fh_F_ord1(iF - 1, jF, kF, ex)] +
fh[idx_fh_F_ord1(iF + 1, jF, kF, ex)]
);
fy[p] = d2dy * (
-fh[idx_fh_F_ord1(iF, jF - 1, kF, ex)] +
fh[idx_fh_F_ord1(iF, jF + 1, kF, ex)]
);
fz[p] = d2dz * (
-fh[idx_fh_F_ord1(iF, jF, kF - 1, ex)] +
fh[idx_fh_F_ord1(iF, jF, kF + 1, ex)]
);
}
}
}
}
return;
if (fh_size > cap) {
free(fh);
fh = (double*)aligned_alloc(64, fh_size * sizeof(double));
cap = fh_size;
}
#elif (ghost_width == 3)
/* ---- 4th-order (original code) ------------------------------------ */
{
const int ord = 2; // symmetry_bd ord
// double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -1;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -1;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -1;
// call symmetry_bd(2,ex,f,fh,SoA)
symmetry_bd(2, ex, f, fh, SoA);
const double SoA[3] = { SYM1, SYM2, SYM3 };
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
static double *fh_buf = NULL;
static size_t cap = 0;
if (fh_size > cap) {
free(fh_buf);
fh_buf = (double*)aligned_alloc(64, fh_size * sizeof(double));
cap = fh_size;
}
double *fh = fh_buf;
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
const size_t all = (size_t)ex1 * (size_t)ex2 * (size_t)ex3;
for (size_t p = 0; p < all; ++p) {
fx[p] = ZEO; fy[p] = ZEO; fz[p] = ZEO;
}
const int i2_lo = (iminF > 0) ? iminF : 0;
const int j2_lo = (jminF > 0) ? jminF : 0;
const int k2_lo = (kminF > 0) ? kminF : 0;
const int i2_hi = ex1 - 2;
const int j2_hi = ex2 - 2;
const int k2_hi = ex3 - 2;
const int i4_lo = (iminF + 1 > 0) ? (iminF + 1) : 0;
const int j4_lo = (jminF + 1 > 0) ? (jminF + 1) : 0;
const int k4_lo = (kminF + 1 > 0) ? (kminF + 1) : 0;
const int i4_hi = ex1 - 3;
const int j4_hi = ex2 - 3;
const int k4_hi = ex3 - 3;
if (i2_lo <= i2_hi && j2_lo <= j2_hi && k2_lo <= k2_hi) {
for (int k0 = k2_lo; k0 <= k2_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j2_lo; j0 <= j2_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i2_lo; i0 <= i2_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d2dx * (
-fh[idx_fh_F_ord2(iF - 1, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF + 1, jF, kF, ex)]
);
fy[p] = d2dy * (
-fh[idx_fh_F_ord2(iF, jF - 1, kF, ex)] +
fh[idx_fh_F_ord2(iF, jF + 1, kF, ex)]
);
fz[p] = d2dz * (
-fh[idx_fh_F_ord2(iF, jF, kF - 1, ex)] +
fh[idx_fh_F_ord2(iF, jF, kF + 1, ex)]
);
}
}
}
}
if (i4_lo <= i4_hi && j4_lo <= j4_hi && k4_lo <= k4_hi) {
for (int k0 = k4_lo; k0 <= k4_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j4_lo; j0 <= j4_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i4_lo; i0 <= i4_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d12dx * (
fh[idx_fh_F_ord2(iF - 2, jF, kF, ex)] -
EIT * fh[idx_fh_F_ord2(iF - 1, jF, kF, ex)] +
EIT * fh[idx_fh_F_ord2(iF + 1, jF, kF, ex)] -
fh[idx_fh_F_ord2(iF + 2, jF, kF, ex)]
);
fy[p] = d12dy * (
fh[idx_fh_F_ord2(iF, jF - 2, kF, ex)] -
EIT * fh[idx_fh_F_ord2(iF, jF - 1, kF, ex)] +
EIT * fh[idx_fh_F_ord2(iF, jF + 1, kF, ex)] -
fh[idx_fh_F_ord2(iF, jF + 2, kF, ex)]
);
fz[p] = d12dz * (
fh[idx_fh_F_ord2(iF, jF, kF - 2, ex)] -
EIT * fh[idx_fh_F_ord2(iF, jF, kF - 1, ex)] +
EIT * fh[idx_fh_F_ord2(iF, jF, kF + 1, ex)] -
fh[idx_fh_F_ord2(iF, jF, kF + 2, ex)]
);
}
}
}
}
return;
// fx = fy = fz = 0
const size_t all = (size_t)ex1 * (size_t)ex2 * (size_t)ex3;
for (size_t p = 0; p < all; ++p) {
fx[p] = ZEO;
fy[p] = ZEO;
fz[p] = ZEO;
}
#elif (ghost_width == 4)
/* ---- 6th-order ----------------------------------------------------- */
{
const int ord = 3;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -2;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -2;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -2;
/*
* 两段式:
* 1) 先在二阶可用区域计算二阶模板
* 2) 再在高阶可用区域覆盖为四阶模板
*
* 与原 if/elseif 逻辑等价,但减少逐点分支判断。
*/
const int i2_lo = (iminF > 0) ? iminF : 0;
const int j2_lo = (jminF > 0) ? jminF : 0;
const int k2_lo = (kminF > 0) ? kminF : 0;
const int i2_hi = ex1 - 2;
const int j2_hi = ex2 - 2;
const int k2_hi = ex3 - 2;
const double SoA[3] = { SYM1, SYM2, SYM3 };
const int i4_lo = (iminF + 1 > 0) ? (iminF + 1) : 0;
const int j4_lo = (jminF + 1 > 0) ? (jminF + 1) : 0;
const int k4_lo = (kminF + 1 > 0) ? (kminF + 1) : 0;
const int i4_hi = ex1 - 3;
const int j4_hi = ex2 - 3;
const int k4_hi = ex3 - 3;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
if (i2_lo <= i2_hi && j2_lo <= j2_hi && k2_lo <= k2_hi) {
for (int k0 = k2_lo; k0 <= k2_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j2_lo; j0 <= j2_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i2_lo; i0 <= i2_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
static double *fh_buf = NULL;
static size_t cap = 0;
if (fh_size > cap) {
free(fh_buf);
fh_buf = (double*)aligned_alloc(64, fh_size * sizeof(double));
cap = fh_size;
}
double *fh = fh_buf;
if (!fh) return;
fx[p] = d2dx * (
-fh[idx_fh_F_ord2(iF - 1, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF + 1, jF, kF, ex)]
);
symmetry_bd(ord, ex, f, fh, SoA);
fy[p] = d2dy * (
-fh[idx_fh_F_ord2(iF, jF - 1, kF, ex)] +
fh[idx_fh_F_ord2(iF, jF + 1, kF, ex)]
);
/* Denominators */
const double d60dx = ONE / F60 / dX;
const double d60dy = ONE / F60 / dY;
const double d60dz = ONE / F60 / dZ;
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
const size_t all = (size_t)ex1 * (size_t)ex2 * (size_t)ex3;
for (size_t p = 0; p < all; ++p) {
fx[p] = ZEO; fy[p] = ZEO; fz[p] = ZEO;
}
/* 2nd-order pass: 3pt, widest */
const int i2_lo = (iminF > 0) ? iminF : 0;
const int j2_lo = (jminF > 0) ? jminF : 0;
const int k2_lo = (kminF > 0) ? kminF : 0;
const int i2_hi = ex1 - 2;
const int j2_hi = ex2 - 2;
const int k2_hi = ex3 - 2;
/* 4th-order pass: 5pt */
const int i4_lo = (iminF + 1 > 0) ? (iminF + 1) : 0;
const int j4_lo = (jminF + 1 > 0) ? (jminF + 1) : 0;
const int k4_lo = (kminF + 1 > 0) ? (kminF + 1) : 0;
const int i4_hi = ex1 - 3;
const int j4_hi = ex2 - 3;
const int k4_hi = ex3 - 3;
/* 6th-order pass: 7pt, narrowest interior */
const int i6_lo = (iminF + 2 > 0) ? (iminF + 2) : 0;
const int j6_lo = (jminF + 2 > 0) ? (jminF + 2) : 0;
const int k6_lo = (kminF + 2 > 0) ? (kminF + 2) : 0;
const int i6_hi = ex1 - 4;
const int j6_hi = ex2 - 4;
const int k6_hi = ex3 - 4;
/* 2nd-order */
if (i2_lo <= i2_hi && j2_lo <= j2_hi && k2_lo <= k2_hi) {
for (int k0 = k2_lo; k0 <= k2_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j2_lo; j0 <= j2_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i2_lo; i0 <= i2_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d2dx * (
-fh[idx_fh_F(iF - 1, jF, kF, ex)] +
fh[idx_fh_F(iF + 1, jF, kF, ex)]);
fy[p] = d2dy * (
-fh[idx_fh_F(iF, jF - 1, kF, ex)] +
fh[idx_fh_F(iF, jF + 1, kF, ex)]);
fz[p] = d2dz * (
-fh[idx_fh_F(iF, jF, kF - 1, ex)] +
fh[idx_fh_F(iF, jF, kF + 1, ex)]);
}
fz[p] = d2dz * (
-fh[idx_fh_F_ord2(iF, jF, kF - 1, ex)] +
fh[idx_fh_F_ord2(iF, jF, kF + 1, ex)]
);
}
}
}
/* 4th-order overwrite */
if (i4_lo <= i4_hi && j4_lo <= j4_hi && k4_lo <= k4_hi) {
for (int k0 = k4_lo; k0 <= k4_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j4_lo; j0 <= j4_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i4_lo; i0 <= i4_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d12dx * (
fh[idx_fh_F(iF - 2, jF, kF, ex)] -
EIT * fh[idx_fh_F(iF - 1, jF, kF, ex)] +
EIT * fh[idx_fh_F(iF + 1, jF, kF, ex)] -
fh[idx_fh_F(iF + 2, jF, kF, ex)]);
fy[p] = d12dy * (
fh[idx_fh_F(iF, jF - 2, kF, ex)] -
EIT * fh[idx_fh_F(iF, jF - 1, kF, ex)] +
EIT * fh[idx_fh_F(iF, jF + 1, kF, ex)] -
fh[idx_fh_F(iF, jF + 2, kF, ex)]);
fz[p] = d12dz * (
fh[idx_fh_F(iF, jF, kF - 2, ex)] -
EIT * fh[idx_fh_F(iF, jF, kF - 1, ex)] +
EIT * fh[idx_fh_F(iF, jF, kF + 1, ex)] -
fh[idx_fh_F(iF, jF, kF + 2, ex)]);
}
}
}
}
/* 6th-order overwrite: [-1,+9,-45,0,+45,-9,+1] / (60*dx) */
if (i6_lo <= i6_hi && j6_lo <= j6_hi && k6_lo <= k6_hi) {
for (int k0 = k6_lo; k0 <= k6_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j6_lo; j0 <= j6_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i6_lo; i0 <= i6_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d60dx * (
-fh[idx_fh_F(iF - 3, jF, kF, ex)] +
F9 * fh[idx_fh_F(iF - 2, jF, kF, ex)] -
F45 * fh[idx_fh_F(iF - 1, jF, kF, ex)] +
F45 * fh[idx_fh_F(iF + 1, jF, kF, ex)] -
F9 * fh[idx_fh_F(iF + 2, jF, kF, ex)] +
fh[idx_fh_F(iF + 3, jF, kF, ex)]);
fy[p] = d60dy * (
-fh[idx_fh_F(iF, jF - 3, kF, ex)] +
F9 * fh[idx_fh_F(iF, jF - 2, kF, ex)] -
F45 * fh[idx_fh_F(iF, jF - 1, kF, ex)] +
F45 * fh[idx_fh_F(iF, jF + 1, kF, ex)] -
F9 * fh[idx_fh_F(iF, jF + 2, kF, ex)] +
fh[idx_fh_F(iF, jF + 3, kF, ex)]);
fz[p] = d60dz * (
-fh[idx_fh_F(iF, jF, kF - 3, ex)] +
F9 * fh[idx_fh_F(iF, jF, kF - 2, ex)] -
F45 * fh[idx_fh_F(iF, jF, kF - 1, ex)] +
F45 * fh[idx_fh_F(iF, jF, kF + 1, ex)] -
F9 * fh[idx_fh_F(iF, jF, kF + 2, ex)] +
fh[idx_fh_F(iF, jF, kF + 3, ex)]);
}
}
}
}
return;
}
#elif (ghost_width == 5)
/* ---- 8th-order ----------------------------------------------------- */
{
const int ord = 5;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -3;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -3;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -3;
if (i4_lo <= i4_hi && j4_lo <= j4_hi && k4_lo <= k4_hi) {
for (int k0 = k4_lo; k0 <= k4_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j4_lo; j0 <= j4_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i4_lo; i0 <= i4_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
const double SoA[3] = { SYM1, SYM2, SYM3 };
fx[p] = d12dx * (
fh[idx_fh_F_ord2(iF - 2, jF, kF, ex)] -
EIT * fh[idx_fh_F_ord2(iF - 1, jF, kF, ex)] +
EIT * fh[idx_fh_F_ord2(iF + 1, jF, kF, ex)] -
fh[idx_fh_F_ord2(iF + 2, jF, kF, ex)]
);
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
fy[p] = d12dy * (
fh[idx_fh_F_ord2(iF, jF - 2, kF, ex)] -
EIT * fh[idx_fh_F_ord2(iF, jF - 1, kF, ex)] +
EIT * fh[idx_fh_F_ord2(iF, jF + 1, kF, ex)] -
fh[idx_fh_F_ord2(iF, jF + 2, kF, ex)]
);
static double *fh_buf = NULL;
static size_t cap = 0;
if (fh_size > cap) {
free(fh_buf);
fh_buf = (double*)aligned_alloc(64, fh_size * sizeof(double));
cap = fh_size;
}
double *fh = fh_buf;
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
const double d840dx = ONE / F840 / dX;
const double d840dy = ONE / F840 / dY;
const double d840dz = ONE / F840 / dZ;
const double d60dx = ONE / F60 / dX;
const double d60dy = ONE / F60 / dY;
const double d60dz = ONE / F60 / dZ;
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
const size_t all = (size_t)ex1 * (size_t)ex2 * (size_t)ex3;
for (size_t p = 0; p < all; ++p) {
fx[p] = ZEO; fy[p] = ZEO; fz[p] = ZEO;
}
/* 2nd: 3pt, widest */
const int i2_lo = (iminF > 0) ? iminF : 0;
const int j2_lo = (jminF > 0) ? jminF : 0;
const int k2_lo = (kminF > 0) ? kminF : 0;
const int i2_hi = ex1 - 2;
const int j2_hi = ex2 - 2;
const int k2_hi = ex3 - 2;
/* 4th: 5pt */
const int i4_lo = (iminF + 1 > 0) ? (iminF + 1) : 0;
const int j4_lo = (jminF + 1 > 0) ? (jminF + 1) : 0;
const int k4_lo = (kminF + 1 > 0) ? (kminF + 1) : 0;
const int i4_hi = ex1 - 3;
const int j4_hi = ex2 - 3;
const int k4_hi = ex3 - 3;
/* 6th: 7pt */
const int i6_lo = (iminF + 2 > 0) ? (iminF + 2) : 0;
const int j6_lo = (jminF + 2 > 0) ? (jminF + 2) : 0;
const int k6_lo = (kminF + 2 > 0) ? (kminF + 2) : 0;
const int i6_hi = ex1 - 4;
const int j6_hi = ex2 - 4;
const int k6_hi = ex3 - 4;
/* 8th: 9pt, narrowest */
const int i8_lo = (iminF + 3 > 0) ? (iminF + 3) : 0;
const int j8_lo = (jminF + 3 > 0) ? (jminF + 3) : 0;
const int k8_lo = (kminF + 3 > 0) ? (kminF + 3) : 0;
const int i8_hi = ex1 - 5;
const int j8_hi = ex2 - 5;
const int k8_hi = ex3 - 5;
if (i2_lo <= i2_hi && j2_lo <= j2_hi && k2_lo <= k2_hi) {
for (int k0 = k2_lo; k0 <= k2_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j2_lo; j0 <= j2_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i2_lo; i0 <= i2_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d2dx * (
-fh[idx_fh_F_ord5(iF - 1, jF, kF, ex)] +
fh[idx_fh_F_ord5(iF + 1, jF, kF, ex)]);
fy[p] = d2dy * (
-fh[idx_fh_F_ord5(iF, jF - 1, kF, ex)] +
fh[idx_fh_F_ord5(iF, jF + 1, kF, ex)]);
fz[p] = d2dz * (
-fh[idx_fh_F_ord5(iF, jF, kF - 1, ex)] +
fh[idx_fh_F_ord5(iF, jF, kF + 1, ex)]);
}
fz[p] = d12dz * (
fh[idx_fh_F_ord2(iF, jF, kF - 2, ex)] -
EIT * fh[idx_fh_F_ord2(iF, jF, kF - 1, ex)] +
EIT * fh[idx_fh_F_ord2(iF, jF, kF + 1, ex)] -
fh[idx_fh_F_ord2(iF, jF, kF + 2, ex)]
);
}
}
}
if (i4_lo <= i4_hi && j4_lo <= j4_hi && k4_lo <= k4_hi) {
for (int k0 = k4_lo; k0 <= k4_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j4_lo; j0 <= j4_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i4_lo; i0 <= i4_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d12dx * (
fh[idx_fh_F_ord5(iF - 2, jF, kF, ex)] -
EIT * fh[idx_fh_F_ord5(iF - 1, jF, kF, ex)] +
EIT * fh[idx_fh_F_ord5(iF + 1, jF, kF, ex)] -
fh[idx_fh_F_ord5(iF + 2, jF, kF, ex)]);
fy[p] = d12dy * (
fh[idx_fh_F_ord5(iF, jF - 2, kF, ex)] -
EIT * fh[idx_fh_F_ord5(iF, jF - 1, kF, ex)] +
EIT * fh[idx_fh_F_ord5(iF, jF + 1, kF, ex)] -
fh[idx_fh_F_ord5(iF, jF + 2, kF, ex)]);
fz[p] = d12dz * (
fh[idx_fh_F_ord5(iF, jF, kF - 2, ex)] -
EIT * fh[idx_fh_F_ord5(iF, jF, kF - 1, ex)] +
EIT * fh[idx_fh_F_ord5(iF, jF, kF + 1, ex)] -
fh[idx_fh_F_ord5(iF, jF, kF + 2, ex)]);
}
}
}
}
if (i6_lo <= i6_hi && j6_lo <= j6_hi && k6_lo <= k6_hi) {
for (int k0 = k6_lo; k0 <= k6_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j6_lo; j0 <= j6_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i6_lo; i0 <= i6_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d60dx * (
-fh[idx_fh_F_ord5(iF - 3, jF, kF, ex)] +
F9 * fh[idx_fh_F_ord5(iF - 2, jF, kF, ex)] -
F45 * fh[idx_fh_F_ord5(iF - 1, jF, kF, ex)] +
F45 * fh[idx_fh_F_ord5(iF + 1, jF, kF, ex)] -
F9 * fh[idx_fh_F_ord5(iF + 2, jF, kF, ex)] +
fh[idx_fh_F_ord5(iF + 3, jF, kF, ex)]);
fy[p] = d60dy * (
-fh[idx_fh_F_ord5(iF, jF - 3, kF, ex)] +
F9 * fh[idx_fh_F_ord5(iF, jF - 2, kF, ex)] -
F45 * fh[idx_fh_F_ord5(iF, jF - 1, kF, ex)] +
F45 * fh[idx_fh_F_ord5(iF, jF + 1, kF, ex)] -
F9 * fh[idx_fh_F_ord5(iF, jF + 2, kF, ex)] +
fh[idx_fh_F_ord5(iF, jF + 3, kF, ex)]);
fz[p] = d60dz * (
-fh[idx_fh_F_ord5(iF, jF, kF - 3, ex)] +
F9 * fh[idx_fh_F_ord5(iF, jF, kF - 2, ex)] -
F45 * fh[idx_fh_F_ord5(iF, jF, kF - 1, ex)] +
F45 * fh[idx_fh_F_ord5(iF, jF, kF + 1, ex)] -
F9 * fh[idx_fh_F_ord5(iF, jF, kF + 2, ex)] +
fh[idx_fh_F_ord5(iF, jF, kF + 3, ex)]);
}
}
}
}
/* 8th-order overwrite: [+3,-32,+168,-672,0,+672,-168,+32,-3] / (840*dx) */
if (i8_lo <= i8_hi && j8_lo <= j8_hi && k8_lo <= k8_hi) {
for (int k0 = k8_lo; k0 <= k8_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j8_lo; j0 <= j8_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i8_lo; i0 <= i8_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
fx[p] = d840dx * (
+(double)3 * fh[idx_fh_F_ord5(iF - 4, jF, kF, ex)] -
F32 * fh[idx_fh_F_ord5(iF - 3, jF, kF, ex)] +
F168 * fh[idx_fh_F_ord5(iF - 2, jF, kF, ex)] -
F672 * fh[idx_fh_F_ord5(iF - 1, jF, kF, ex)] +
F672 * fh[idx_fh_F_ord5(iF + 1, jF, kF, ex)] -
F168 * fh[idx_fh_F_ord5(iF + 2, jF, kF, ex)] +
F32 * fh[idx_fh_F_ord5(iF + 3, jF, kF, ex)] -
(double)3 * fh[idx_fh_F_ord5(iF + 4, jF, kF, ex)]);
fy[p] = d840dy * (
+(double)3 * fh[idx_fh_F_ord5(iF, jF - 4, kF, ex)] -
F32 * fh[idx_fh_F_ord5(iF, jF - 3, kF, ex)] +
F168 * fh[idx_fh_F_ord5(iF, jF - 2, kF, ex)] -
F672 * fh[idx_fh_F_ord5(iF, jF - 1, kF, ex)] +
F672 * fh[idx_fh_F_ord5(iF, jF + 1, kF, ex)] -
F168 * fh[idx_fh_F_ord5(iF, jF + 2, kF, ex)] +
F32 * fh[idx_fh_F_ord5(iF, jF + 3, kF, ex)] -
(double)3 * fh[idx_fh_F_ord5(iF, jF + 4, kF, ex)]);
fz[p] = d840dz * (
+(double)3 * fh[idx_fh_F_ord5(iF, jF, kF - 4, ex)] -
F32 * fh[idx_fh_F_ord5(iF, jF, kF - 3, ex)] +
F168 * fh[idx_fh_F_ord5(iF, jF, kF - 2, ex)] -
F672 * fh[idx_fh_F_ord5(iF, jF, kF - 1, ex)] +
F672 * fh[idx_fh_F_ord5(iF, jF, kF + 1, ex)] -
F168 * fh[idx_fh_F_ord5(iF, jF, kF + 2, ex)] +
F32 * fh[idx_fh_F_ord5(iF, jF, kF + 3, ex)] -
(double)3 * fh[idx_fh_F_ord5(iF, jF, kF + 4, ex)]);
}
}
}
}
return;
}
#else
#error "fderivs_c.C: unsupported ghost_width (must be 2, 3, 4, or 5)"
#endif
// free(fh);
}

234
AMSS_NCKU_source/fderivs_sh_c.C
View File

@@ -1,234 +0,0 @@
#include "macrodef.h"
#include "share_func.h"
/*
* C 版 fderivs_sh — first derivatives on shell patch in (rho, sigma, R) coords.
*
* Same stencil coefficients as Cartesian fderivs, but:
* - Uses symmetry_stbd (ghost on BOTH sides of x/y, none in z)
* - fh buffer: (-ord+1:ex+ord) in x/y, (1:ex) in z
* - SoA is 2-element only (x/y), no z-symmetry
* - sst parameter (shell surface type, not used in stencil computation)
*/
extern "C" void fderivs_sh_(const int ex[3],
const double *f,
double *fx, double *fy, double *fz,
const double *X, const double *Y, const double *Z,
double SYM1, double SYM2, double SYM3,
int Symmetry, int onoff, int sst)
{
(void)SYM3; (void)onoff; (void)sst;
const double ZEO = 0.0, ONE = 1.0, TWO = 2.0, EIT = 8.0;
const double F9 = 9.0, F12 = 12.0, F45 = 45.0, F60 = 60.0;
const double F32 = 32.0, F168 = 168.0, F672 = 672.0, F840 = 840.0;
const int NO_SYMM = 0, EQ_SYMM = 1, OCTANT = 2;
const int ex1 = ex[0], ex2 = ex[1], ex3 = ex[2];
const double dX = X[1] - X[0];
const double dY = Y[1] - Y[0];
const double dZ = Z[1] - Z[0];
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
const double SoA[2] = { SYM1, SYM2 };
#if (ghost_width == 2)
{
const int ord = 1;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry == OCTANT && fabs(X[0]) < dX) iminF = 0;
if (Symmetry == OCTANT && fabs(Y[0]) < dY) jminF = 0;
if ((sst==2||sst==4) && fabs(Y[0]) < dY) jminF = 0; // EQ reflection
const size_t nx = (size_t)ex1 + 2 * ord;
const size_t ny = (size_t)ex2 + 2 * ord;
const size_t nz = (size_t)ex3;
const size_t fh_size = nx * ny * nz;
static double *fh_buf = NULL; static size_t cap = 0;
if (fh_size > cap) { free(fh_buf); fh_buf = (double*)aligned_alloc(64, fh_size*sizeof(double)); cap = fh_size; }
double *fh = fh_buf; if (!fh) return;
symmetry_stbd(ord, ex, f, fh, SoA);
const double d2dx = ONE/TWO/dX, d2dy = ONE/TWO/dY, d2dz = ONE/TWO/dZ;
const size_t all = (size_t)ex1*ex2*ex3;
for (size_t p=0;p<all;++p) { fx[p]=ZEO; fy[p]=ZEO; fz[p]=ZEO; }
const int i2_lo=(iminF>0)?iminF:0, j2_lo=(jminF>0)?jminF:0, k2_lo=1;
const int i2_hi=ex1-2, j2_hi=ex2-2, k2_hi=ex3-2;
if (i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi) {
for (int k0=k2_lo;k0<=k2_hi;++k0) { const int kF=k0+1;
for (int j0=j2_lo;j0<=j2_hi;++j0) { const int jF=j0+1;
for (int i0=i2_lo;i0<=i2_hi;++i0) { const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d2dx*(-fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)]);
fy[p]=d2dy*(-fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)]);
fz[p]=d2dz*(-fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)]);
}}}
}
return;
}
#elif (ghost_width == 3)
{
const int ord = 2;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry == OCTANT && fabs(X[0]) < dX) iminF = -1;
if (Symmetry == OCTANT && fabs(Y[0]) < dY) jminF = -1;
if ((sst==2||sst==4) && fabs(Y[0]) < dY) jminF = -1;
const size_t nx=(size_t)ex1+2*ord, ny=(size_t)ex2+2*ord, nz=(size_t)ex3;
const size_t fh_size=nx*ny*nz;
static double *fh_buf=NULL; static size_t cap=0;
if (fh_size>cap){free(fh_buf);fh_buf=(double*)aligned_alloc(64,fh_size*sizeof(double));cap=fh_size;}
double *fh=fh_buf; if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const double d12dx=ONE/F12/dX, d12dy=ONE/F12/dY, d12dz=ONE/F12/dZ;
const double d2dx=ONE/TWO/dX, d2dy=ONE/TWO/dY, d2dz=ONE/TWO/dZ;
const size_t all=(size_t)ex1*ex2*ex3;
for(size_t p=0;p<all;++p){fx[p]=ZEO;fy[p]=ZEO;fz[p]=ZEO;}
const int i2_lo=(iminF>0)?iminF:0, j2_lo=(jminF>0)?jminF:0, k2_lo=1;
const int i2_hi=ex1-2, j2_hi=ex2-2, k2_hi=ex3-2;
const int i4_lo=(iminF+1>0)?iminF+1:0, j4_lo=(jminF+1>0)?jminF+1:0, k4_lo=2;
const int i4_hi=ex1-3, j4_hi=ex2-3, k4_hi=ex3-3;
if (i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi) {
for(int k0=k2_lo;k0<=k2_hi;++k0){const int kF=k0+1;
for(int j0=j2_lo;j0<=j2_hi;++j0){const int jF=j0+1;
for(int i0=i2_lo;i0<=i2_hi;++i0){const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d2dx*(-fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)]);
fy[p]=d2dy*(-fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)]);
fz[p]=d2dz*(-fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)]);
}}}
}
if (i4_lo<=i4_hi&&j4_lo<=j4_hi&&k4_lo<=k4_hi) {
for(int k0=k4_lo;k0<=k4_hi;++k0){const int kF=k0+1;
for(int j0=j4_lo;j0<=j4_hi;++j0){const int jF=j0+1;
for(int i0=i4_lo;i0<=i4_hi;++i0){const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d12dx*(fh[idx_fh_stbd(iF-2,jF,kF,ord,ex)]-EIT*fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+EIT*fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)]-fh[idx_fh_stbd(iF+2,jF,kF,ord,ex)]);
fy[p]=d12dy*(fh[idx_fh_stbd(iF,jF-2,kF,ord,ex)]-EIT*fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+EIT*fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)]-fh[idx_fh_stbd(iF,jF+2,kF,ord,ex)]);
fz[p]=d12dz*(fh[idx_fh_stbd(iF,jF,kF-2,ord,ex)]-EIT*fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+EIT*fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)]-fh[idx_fh_stbd(iF,jF,kF+2,ord,ex)]);
}}}
}
return;
}
#elif (ghost_width == 4)
{
const int ord = 3;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-2;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-2;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-2;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3;
const size_t fh_size=nx*ny*nz;
static double *fh_buf=NULL;static size_t cap=0;
if(fh_size>cap){free(fh_buf);fh_buf=(double*)aligned_alloc(64,fh_size*sizeof(double));cap=fh_size;}
double *fh=fh_buf;if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const double d60dx=ONE/F60/dX,d60dy=ONE/F60/dY,d60dz=ONE/F60/dZ;
const double d12dx=ONE/F12/dX,d12dy=ONE/F12/dY,d12dz=ONE/F12/dZ;
const double d2dx=ONE/TWO/dX,d2dy=ONE/TWO/dY,d2dz=ONE/TWO/dZ;
const size_t all=(size_t)ex1*ex2*ex3;
for(size_t p=0;p<all;++p){fx[p]=ZEO;fy[p]=ZEO;fz[p]=ZEO;}
const int i2_lo=(iminF>0)?iminF:0,j2_lo=(jminF>0)?jminF:0,k2_lo=1,i2_hi=ex1-2,j2_hi=ex2-2,k2_hi=ex3-2;
const int i4_lo=(iminF+1>0)?iminF+1:0,j4_lo=(jminF+1>0)?jminF+1:0,k4_lo=2,i4_hi=ex1-3,j4_hi=ex2-3,k4_hi=ex3-3;
const int i6_lo=(iminF+2>0)?iminF+2:0,j6_lo=(jminF+2>0)?jminF+2:0,k6_lo=3,i6_hi=ex1-4,j6_hi=ex2-4,k6_hi=ex3-4;
if(i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi){
for(int k0=k2_lo;k0<=k2_hi;++k0){const int kF=k0+1;
for(int j0=j2_lo;j0<=j2_hi;++j0){const int jF=j0+1;
for(int i0=i2_lo;i0<=i2_hi;++i0){const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d2dx*(-fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)]);
fy[p]=d2dy*(-fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)]);
fz[p]=d2dz*(-fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)]);
}}}
}
if(i4_lo<=i4_hi&&j4_lo<=j4_hi&&k4_lo<=k4_hi){
for(int k0=k4_lo;k0<=k4_hi;++k0){const int kF=k0+1;
for(int j0=j4_lo;j0<=j4_hi;++j0){const int jF=j0+1;
for(int i0=i4_lo;i0<=i4_hi;++i0){const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d12dx*(fh[idx_fh_stbd(iF-2,jF,kF,ord,ex)]-EIT*fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+EIT*fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)]-fh[idx_fh_stbd(iF+2,jF,kF,ord,ex)]);
fy[p]=d12dy*(fh[idx_fh_stbd(iF,jF-2,kF,ord,ex)]-EIT*fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+EIT*fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)]-fh[idx_fh_stbd(iF,jF+2,kF,ord,ex)]);
fz[p]=d12dz*(fh[idx_fh_stbd(iF,jF,kF-2,ord,ex)]-EIT*fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+EIT*fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)]-fh[idx_fh_stbd(iF,jF,kF+2,ord,ex)]);
}}}
}
if(i6_lo<=i6_hi&&j6_lo<=j6_hi&&k6_lo<=k6_hi){
for(int k0=k6_lo;k0<=k6_hi;++k0){const int kF=k0+1;
for(int j0=j6_lo;j0<=j6_hi;++j0){const int jF=j0+1;
for(int i0=i6_lo;i0<=i6_hi;++i0){const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d60dx*(-fh[idx_fh_stbd(iF-3,jF,kF,ord,ex)]+F9*fh[idx_fh_stbd(iF-2,jF,kF,ord,ex)]-F45*fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+F45*fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)]-F9*fh[idx_fh_stbd(iF+2,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+3,jF,kF,ord,ex)]);
fy[p]=d60dy*(-fh[idx_fh_stbd(iF,jF-3,kF,ord,ex)]+F9*fh[idx_fh_stbd(iF,jF-2,kF,ord,ex)]-F45*fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+F45*fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)]-F9*fh[idx_fh_stbd(iF,jF+2,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+3,kF,ord,ex)]);
fz[p]=d60dz*(-fh[idx_fh_stbd(iF,jF,kF-3,ord,ex)]+F9*fh[idx_fh_stbd(iF,jF,kF-2,ord,ex)]-F45*fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+F45*fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)]-F9*fh[idx_fh_stbd(iF,jF,kF+2,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+3,ord,ex)]);
}}}
}
return;
}
#elif (ghost_width == 5)
{
const int ord = 4;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-3;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-3;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-3;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3;
const size_t fh_size=nx*ny*nz;
static double *fh_buf=NULL;static size_t cap=0;
if(fh_size>cap){free(fh_buf);fh_buf=(double*)aligned_alloc(64,fh_size*sizeof(double));cap=fh_size;}
double *fh=fh_buf;if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const double d840dx=ONE/F840/dX,d840dy=ONE/F840/dY,d840dz=ONE/F840/dZ;
const double d60dx=ONE/F60/dX,d60dy=ONE/F60/dY,d60dz=ONE/F60/dZ;
const double d12dx=ONE/F12/dX,d12dy=ONE/F12/dY,d12dz=ONE/F12/dZ;
const double d2dx=ONE/TWO/dX,d2dy=ONE/TWO/dY,d2dz=ONE/TWO/dZ;
const size_t all=(size_t)ex1*ex2*ex3;
for(size_t p=0;p<all;++p){fx[p]=ZEO;fy[p]=ZEO;fz[p]=ZEO;}
const int i2_lo=(iminF>0)?iminF:0,j2_lo=(jminF>0)?jminF:0,k2_lo=1,i2_hi=ex1-2,j2_hi=ex2-2,k2_hi=ex3-2;
const int i4_lo=(iminF+1>0)?iminF+1:0,j4_lo=(jminF+1>0)?jminF+1:0,k4_lo=2,i4_hi=ex1-3,j4_hi=ex2-3,k4_hi=ex3-3;
const int i6_lo=(iminF+2>0)?iminF+2:0,j6_lo=(jminF+2>0)?jminF+2:0,k6_lo=3,i6_hi=ex1-4,j6_hi=ex2-4,k6_hi=ex3-4;
const int i8_lo=(iminF+3>0)?iminF+3:0,j8_lo=(jminF+3>0)?jminF+3:0,k8_lo=4,i8_hi=ex1-5,j8_hi=ex2-5,k8_hi=ex3-5;
#define FH_S(iF,jF,kF) fh[idx_fh_stbd(iF,jF,kF,ord,ex)]
if(i2_lo<=i2_hi&&j2_lo<=j2_hi&&k2_lo<=k2_hi){for(int k0=k2_lo;k0<=k2_hi;++k0){const int kF=k0+1;
for(int j0=j2_lo;j0<=j2_hi;++j0){const int jF=j0+1;
for(int i0=i2_lo;i0<=i2_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d2dx*(-FH_S(iF-1,jF,kF)+FH_S(iF+1,jF,kF));
fy[p]=d2dy*(-FH_S(iF,jF-1,kF)+FH_S(iF,jF+1,kF));
fz[p]=d2dz*(-FH_S(iF,jF,kF-1)+FH_S(iF,jF,kF+1));}}}}
if(i4_lo<=i4_hi&&j4_lo<=j4_hi&&k4_lo<=k4_hi){for(int k0=k4_lo;k0<=k4_hi;++k0){const int kF=k0+1;
for(int j0=j4_lo;j0<=j4_hi;++j0){const int jF=j0+1;
for(int i0=i4_lo;i0<=i4_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d12dx*(FH_S(iF-2,jF,kF)-EIT*FH_S(iF-1,jF,kF)+EIT*FH_S(iF+1,jF,kF)-FH_S(iF+2,jF,kF));
fy[p]=d12dy*(FH_S(iF,jF-2,kF)-EIT*FH_S(iF,jF-1,kF)+EIT*FH_S(iF,jF+1,kF)-FH_S(iF,jF+2,kF));
fz[p]=d12dz*(FH_S(iF,jF,kF-2)-EIT*FH_S(iF,jF,kF-1)+EIT*FH_S(iF,jF,kF+1)-FH_S(iF,jF,kF+2));}}}}
if(i6_lo<=i6_hi&&j6_lo<=j6_hi&&k6_lo<=k6_hi){for(int k0=k6_lo;k0<=k6_hi;++k0){const int kF=k0+1;
for(int j0=j6_lo;j0<=j6_hi;++j0){const int jF=j0+1;
for(int i0=i6_lo;i0<=i6_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d60dx*(-FH_S(iF-3,jF,kF)+F9*FH_S(iF-2,jF,kF)-F45*FH_S(iF-1,jF,kF)+F45*FH_S(iF+1,jF,kF)-F9*FH_S(iF+2,jF,kF)+FH_S(iF+3,jF,kF));
fy[p]=d60dy*(-FH_S(iF,jF-3,kF)+F9*FH_S(iF,jF-2,kF)-F45*FH_S(iF,jF-1,kF)+F45*FH_S(iF,jF+1,kF)-F9*FH_S(iF,jF+2,kF)+FH_S(iF,jF+3,kF));
fz[p]=d60dz*(-FH_S(iF,jF,kF-3)+F9*FH_S(iF,jF,kF-2)-F45*FH_S(iF,jF,kF-1)+F45*FH_S(iF,jF,kF+1)-F9*FH_S(iF,jF,kF+2)+FH_S(iF,jF,kF+3));}}}}
if(i8_lo<=i8_hi&&j8_lo<=j8_hi&&k8_lo<=k8_hi){for(int k0=k8_lo;k0<=k8_hi;++k0){const int kF=k0+1;
for(int j0=j8_lo;j0<=j8_hi;++j0){const int jF=j0+1;
for(int i0=i8_lo;i0<=i8_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
fx[p]=d840dx*(+(double)3*FH_S(iF-4,jF,kF)-F32*FH_S(iF-3,jF,kF)+F168*FH_S(iF-2,jF,kF)-F672*FH_S(iF-1,jF,kF)+F672*FH_S(iF+1,jF,kF)-F168*FH_S(iF+2,jF,kF)+F32*FH_S(iF+3,jF,kF)-(double)3*FH_S(iF+4,jF,kF));
fy[p]=d840dy*(+(double)3*FH_S(iF,jF-4,kF)-F32*FH_S(iF,jF-3,kF)+F168*FH_S(iF,jF-2,kF)-F672*FH_S(iF,jF-1,kF)+F672*FH_S(iF,jF+1,kF)-F168*FH_S(iF,jF+2,kF)+F32*FH_S(iF,jF+3,kF)-(double)3*FH_S(iF,jF+4,kF));
fz[p]=d840dz*(+(double)3*FH_S(iF,jF,kF-4)-F32*FH_S(iF,jF,kF-3)+F168*FH_S(iF,jF,kF-2)-F672*FH_S(iF,jF,kF-1)+F672*FH_S(iF,jF,kF+1)-F168*FH_S(iF,jF,kF+2)+F32*FH_S(iF,jF,kF+3)-(double)3*FH_S(iF,jF,kF+4));}}}}
#undef FH_S
return;
}
#else
#error "fderivs_sh_c.C: unsupported ghost_width"
#endif
}

54
AMSS_NCKU_source/fderivs_shc_c.C
View File

@@ -1,54 +0,0 @@
#include "macrodef.h"
#include "share_func.h"
#include <cstddef>
/*
* fderivs_shc — shell first derivatives converted to Cartesian via chain rule.
*
* Calls fderivs_sh internally, then:
* fx = drhodx * df/drho + dsigmadx * df/dsigma + dRdx * df/dR
* fy = drhody * df/drho + dsigmady * df/dsigma + dRdy * df/dR
* fz = drhodz * df/drho + dsigmadz * df/dsigma + dRdz * df/dR
*/
// Forward declaration (defined in fderivs_sh_c.C with extern "C" name fderivs_sh_)
extern "C" {
void fderivs_sh_(const int ex[3], const double *f,
double *fx, double *fy, double *fz,
const double *X, const double *Y, const double *Z,
double SYM1, double SYM2, double SYM3,
int Symmetry, int onoff, int sst);
void fderivs_shc_(int *ex,
double *f,
double *fx, double *fy, double *fz,
double *crho, double *sigma, double *R,
double &SYM1, double &SYM2, double &SYM3,
int &Symmetry, int &Lev, int &sst,
double *drhodx, double *drhody, double *drhodz,
double *dsigmadx, double *dsigmady, double *dsigmadz,
double *dRdx, double *dRdy, double *dRdz)
{
const int ex3[3] = { ex[0], ex[1], ex[2] };
const size_t n = (size_t)ex[0] * (size_t)ex[1] * (size_t)ex[2];
// Temporary shell-coordinate derivatives
double *gx = (double*)malloc(n * sizeof(double));
double *gy = (double*)malloc(n * sizeof(double));
double *gz = (double*)malloc(n * sizeof(double));
if (!gx || !gy || !gz) { free(gx); free(gy); free(gz); return; }
// Compute shell-coordinate derivatives
fderivs_sh_(ex3, f, gx, gy, gz, crho, sigma, R, SYM1, SYM2, SYM3, Symmetry, Lev, sst);
// Chain rule to Cartesian
for (size_t i = 0; i < n; ++i) {
fx[i] = drhodx[i] * gx[i] + dsigmadx[i] * gy[i] + dRdx[i] * gz[i];
fy[i] = drhody[i] * gx[i] + dsigmady[i] * gy[i] + dRdy[i] * gz[i];
fz[i] = drhodz[i] * gx[i] + dsigmadz[i] * gy[i] + dRdz[i] * gz[i];
}
free(gx); free(gy); free(gz);
}
} // extern "C"

6
AMSS_NCKU_source/gpu_rhsSS_mem.h
View File

@@ -1,6 +1,6 @@
#ifndef GPU_MEM_H_
#define GPU_MEM_H_
#include "macrodef.fh"
#include "macrodef.h"
#ifdef WithShell
struct Metass
@@ -48,6 +48,8 @@ struct Meta
double * Gamx_rhs,*Gamy_rhs,*Gamz_rhs;//out
double * Lap_rhs, *betax_rhs, *betay_rhs, *betaz_rhs;//out
double * dtSfx_rhs,*dtSfy_rhs,*dtSfz_rhs;//out
double * TZ; //in (Z4C)
double * TZ_rhs; //out (Z4C)
double * rho,*Sx,*Sy,*Sz ; //in
double * Sxx,*Sxy,*Sxz,*Syy,*Syz,*Szz; //in
@@ -132,6 +134,8 @@ __constant__ double SYM = 1.0;
__constant__ double ANTI = -1.0;
__constant__ double FF = 0.75;
__constant__ double eta = 2.0;
__constant__ double kappa1_c = 0.02;
__constant__ double kappa2_c = 0.0;
__constant__ double F1o3;
__constant__ double F2o3;
__constant__ double F3o2 = 1.5;

364
AMSS_NCKU_source/kodiss_c.C
View File

@@ -1,16 +1,16 @@
#include "macrodef.h"
#include "tool.h"
/*
* C 版 kodis — Kreiss-Oliger numerical dissipation (Cartesian patches).
* C 版 kodis
*
* The KO operator is (D₊D₋)^r applied to f_rhs with alternating sign (-1)^(r-1).
* Fortran signature:
* subroutine kodis(ex,X,Y,Z,f,f_rhs,SoA,Symmetry,eps)
*
* FD order → r → cof=2^(2r) mapping:
* ghost_width=2 (2nd) → r=2, cof=16, sign=-
* ghost_width=3 (4th) → r=3, cof=64, sign=+
* ghost_width=4 (6th) → r=4, cof=256, sign=-
* ghost_width=5 (8th) → r=5, cof=1024,sign=+
* 约定:
* X: ex1, Y: ex2, Z: ex3
* f, f_rhs: ex1*ex2*ex3 按 idx_ex 布局
* SoA[3]
* eps: double
*/
void kodis(const int ex[3],
const double *X, const double *Y, const double *Z,
@@ -18,304 +18,100 @@ void kodis(const int ex[3],
const double SoA[3],
int Symmetry, double eps)
{
const double ZEO = 0.0;
const double ONE = 1.0, SIX = 6.0, FIT = 15.0, TWT = 20.0;
const double cof = 64.0; // 2^6
const int NO_SYMM = 0, OCTANT = 2;
const int ex1 = ex[0], ex2 = ex[1], ex3 = ex[2];
// Fortran: dX = X(2)-X(1) -> C: X[1]-X[0]
const double dX = X[1] - X[0];
const double dY = Y[1] - Y[0];
const double dZ = Z[1] - Z[0];
(void)ONE; // ONE 在原 Fortran 里只是参数,这里不一定用得上
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
// Fortran: imax=ex(1) 等是 1-based 上界
const int imaxF = ex1;
const int jmaxF = ex2;
const int kmaxF = ex3;
#if (ghost_width == 2)
/* ---- r=2, cof=16, sign=-, 5pt stencil ----------------------------- */
{
const int ord = 2;
const int r = 2;
const double cof = 16.0;
const double F4 = 4.0, F6 = 6.0;
const int NO_SYMM = 0, EQ_SYMM = 1;
// Fortran: imin=jmin=kmin=1某些对称情况变 -2
int iminF = 1, jminF = 1, kminF = 1;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -1;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -1;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -2;
if (Symmetry == OCTANT && fabs(X[0]) < dX) iminF = -2;
if (Symmetry == OCTANT && fabs(Y[0]) < dY) jminF = -2;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
// 分配 fh大小 (ex1+3)*(ex2+3)*(ex3+3),对应 ord=3
const size_t nx = (size_t)ex1 + 3;
const size_t ny = (size_t)ex2 + 3;
const size_t nz = (size_t)ex3 + 3;
const size_t fh_size = nx * ny * nz;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
// Fortran: call symmetry_bd(3,ex,f,fh,SoA)
symmetry_bd(3, ex, f, fh, SoA);
/* i±2 must be valid: i-2 >= iminF && i+2 <= imaxF
C 0-based: i0 >= iminF+1, i0 <= ex1-3 */
const int i0_lo = (iminF + 1 > 0) ? (iminF + 1) : 0;
const int j0_lo = (jminF + 1 > 0) ? (jminF + 1) : 0;
const int k0_lo = (kminF + 1 > 0) ? (kminF + 1) : 0;
const int i0_hi = imaxF - 3;
const int j0_hi = jmaxF - 3;
const int k0_hi = kmaxF - 3;
/*
* Fortran loops:
* do k=1,ex3
* do j=1,ex2
* do i=1,ex1
*
* C: k0=0..ex3-1, j0=0..ex2-1, i0=0..ex1-1
* 并定义 Fortran index: iF=i0+1, ...
*/
// 收紧循环范围:只遍历满足 iF±3/jF±3/kF±3 条件的内部点
// iF-3 >= iminF => iF >= iminF+3 => i0 >= iminF+2 (因为 iF=i0+1)
// iF+3 <= imaxF => iF <= imaxF-3 => i0 <= imaxF-4
const int i0_lo = (iminF + 2 > 0) ? iminF + 2 : 0;
const int j0_lo = (jminF + 2 > 0) ? jminF + 2 : 0;
const int k0_lo = (kminF + 2 > 0) ? kminF + 2 : 0;
const int i0_hi = imaxF - 4; // inclusive
const int j0_hi = jmaxF - 4;
const int k0_hi = kmaxF - 4;
if (!(i0_lo > i0_hi || j0_lo > j0_hi || k0_lo > k0_hi)) {
for (int k0 = k0_lo; k0 <= k0_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j0_lo; j0 <= j0_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i0_lo; i0 <= i0_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
const double Dx = (
(fh[idx_fh_F_ord2(iF - 2, jF, kF, ex)] + fh[idx_fh_F_ord2(iF + 2, jF, kF, ex)]) -
F4 * (fh[idx_fh_F_ord2(iF - 1, jF, kF, ex)] + fh[idx_fh_F_ord2(iF + 1, jF, kF, ex)]) +
F6 * fh[idx_fh_F_ord2(iF, jF, kF, ex)]
) / dX;
const double Dy = (
(fh[idx_fh_F_ord2(iF, jF - 2, kF, ex)] + fh[idx_fh_F_ord2(iF, jF + 2, kF, ex)]) -
F4 * (fh[idx_fh_F_ord2(iF, jF - 1, kF, ex)] + fh[idx_fh_F_ord2(iF, jF + 1, kF, ex)]) +
F6 * fh[idx_fh_F_ord2(iF, jF, kF, ex)]
) / dY;
const double Dz = (
(fh[idx_fh_F_ord2(iF, jF, kF - 2, ex)] + fh[idx_fh_F_ord2(iF, jF, kF + 2, ex)]) -
F4 * (fh[idx_fh_F_ord2(iF, jF, kF - 1, ex)] + fh[idx_fh_F_ord2(iF, jF, kF + 1, ex)]) +
F6 * fh[idx_fh_F_ord2(iF, jF, kF, ex)]
) / dZ;
f_rhs[p] -= (eps / cof) * (Dx + Dy + Dz); /* sign=- */
}
}
}
}
if (i0_lo > i0_hi || j0_lo > j0_hi || k0_lo > k0_hi) {
free(fh);
return;
}
#elif (ghost_width == 3)
/* ---- r=3, cof=64, sign=+, 7pt stencil (current default) ---------- */
{
const int ord = 3;
const int r = 3;
const double cof = 64.0;
const double SIX = 6.0, FIT = 15.0, TWT = 20.0;
const int NO_SYMM = 0, OCTANT = 2;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -2;
if (Symmetry == OCTANT && fabs(X[0]) < dX) iminF = -2;
if (Symmetry == OCTANT && fabs(Y[0]) < dY) jminF = -2;
for (int k0 = k0_lo; k0 <= k0_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j0_lo; j0 <= j0_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i0_lo; i0 <= i0_hi; ++i0) {
const int iF = i0 + 1;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
const size_t p = idx_ex(i0, j0, k0, ex);
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
// 三个方向各一份同型的 7 点组合(实际上是对称的 6th-order dissipation/filter 核)
const double Dx_term =
( (fh[idx_fh_F(iF - 3, jF, kF, ex)] + fh[idx_fh_F(iF + 3, jF, kF, ex)]) -
SIX * (fh[idx_fh_F(iF - 2, jF, kF, ex)] + fh[idx_fh_F(iF + 2, jF, kF, ex)]) +
FIT * (fh[idx_fh_F(iF - 1, jF, kF, ex)] + fh[idx_fh_F(iF + 1, jF, kF, ex)]) -
TWT * fh[idx_fh_F(iF , jF, kF, ex)] ) / dX;
symmetry_bd(ord, ex, f, fh, SoA);
const double Dy_term =
( (fh[idx_fh_F(iF, jF - 3, kF, ex)] + fh[idx_fh_F(iF, jF + 3, kF, ex)]) -
SIX * (fh[idx_fh_F(iF, jF - 2, kF, ex)] + fh[idx_fh_F(iF, jF + 2, kF, ex)]) +
FIT * (fh[idx_fh_F(iF, jF - 1, kF, ex)] + fh[idx_fh_F(iF, jF + 1, kF, ex)]) -
TWT * fh[idx_fh_F(iF, jF , kF, ex)] ) / dY;
const int i0_lo = (iminF + 2 > 0) ? iminF + 2 : 0;
const int j0_lo = (jminF + 2 > 0) ? jminF + 2 : 0;
const int k0_lo = (kminF + 2 > 0) ? kminF + 2 : 0;
const int i0_hi = imaxF - 4;
const int j0_hi = jmaxF - 4;
const int k0_hi = kmaxF - 4;
const double Dz_term =
( (fh[idx_fh_F(iF, jF, kF - 3, ex)] + fh[idx_fh_F(iF, jF, kF + 3, ex)]) -
SIX * (fh[idx_fh_F(iF, jF, kF - 2, ex)] + fh[idx_fh_F(iF, jF, kF + 2, ex)]) +
FIT * (fh[idx_fh_F(iF, jF, kF - 1, ex)] + fh[idx_fh_F(iF, jF, kF + 1, ex)]) -
TWT * fh[idx_fh_F(iF, jF, kF , ex)] ) / dZ;
if (!(i0_lo > i0_hi || j0_lo > j0_hi || k0_lo > k0_hi)) {
for (int k0 = k0_lo; k0 <= k0_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j0_lo; j0 <= j0_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i0_lo; i0 <= i0_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
const double Dx = (
(fh[idx_fh_F(iF - 3, jF, kF, ex)] + fh[idx_fh_F(iF + 3, jF, kF, ex)]) -
SIX * (fh[idx_fh_F(iF - 2, jF, kF, ex)] + fh[idx_fh_F(iF + 2, jF, kF, ex)]) +
FIT * (fh[idx_fh_F(iF - 1, jF, kF, ex)] + fh[idx_fh_F(iF + 1, jF, kF, ex)]) -
TWT * fh[idx_fh_F(iF, jF, kF, ex)]
) / dX;
const double Dy = (
(fh[idx_fh_F(iF, jF - 3, kF, ex)] + fh[idx_fh_F(iF, jF + 3, kF, ex)]) -
SIX * (fh[idx_fh_F(iF, jF - 2, kF, ex)] + fh[idx_fh_F(iF, jF + 2, kF, ex)]) +
FIT * (fh[idx_fh_F(iF, jF - 1, kF, ex)] + fh[idx_fh_F(iF, jF + 1, kF, ex)]) -
TWT * fh[idx_fh_F(iF, jF, kF, ex)]
) / dY;
const double Dz = (
(fh[idx_fh_F(iF, jF, kF - 3, ex)] + fh[idx_fh_F(iF, jF, kF + 3, ex)]) -
SIX * (fh[idx_fh_F(iF, jF, kF - 2, ex)] + fh[idx_fh_F(iF, jF, kF + 2, ex)]) +
FIT * (fh[idx_fh_F(iF, jF, kF - 1, ex)] + fh[idx_fh_F(iF, jF, kF + 1, ex)]) -
TWT * fh[idx_fh_F(iF, jF, kF, ex)]
) / dZ;
f_rhs[p] += (eps / cof) * (Dx + Dy + Dz); /* sign=+ */
}
}
// Fortran:
// f_rhs(i,j,k) = f_rhs(i,j,k) + eps/cof*(Dx_term + Dy_term + Dz_term)
f_rhs[p] += (eps / cof) * (Dx_term + Dy_term + Dz_term);
}
}
free(fh);
return;
}
#elif (ghost_width == 4)
/* ---- r=4, cof=256, sign=-, 9pt stencil ---------------------------- */
{
const int ord = 4;
const int r = 4;
const double cof = 256.0;
const double F8 = 8.0, F28 = 28.0, F56 = 56.0, F70 = 70.0;
const int NO_SYMM = 0, EQ_SYMM = 1;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -3;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -3;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -3;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
/* i±4 valid: i-4>=iminF → i0>=iminF+3, i+4<=imaxF → i0<=ex1-5 */
const int i0_lo = (iminF + 3 > 0) ? iminF + 3 : 0;
const int j0_lo = (jminF + 3 > 0) ? jminF + 3 : 0;
const int k0_lo = (kminF + 3 > 0) ? kminF + 3 : 0;
const int i0_hi = imaxF - 5;
const int j0_hi = jmaxF - 5;
const int k0_hi = kmaxF - 5;
if (!(i0_lo > i0_hi || j0_lo > j0_hi || k0_lo > k0_hi)) {
for (int k0 = k0_lo; k0 <= k0_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j0_lo; j0 <= j0_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i0_lo; i0 <= i0_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
/* Stencil: [1,-8,28,-56,70,-56,28,-8,1] */
const double Dx = (
(fh[idx_fh_F_ord4(iF - 4, jF, kF, ex)] + fh[idx_fh_F_ord4(iF + 4, jF, kF, ex)]) -
F8 * (fh[idx_fh_F_ord4(iF - 3, jF, kF, ex)] + fh[idx_fh_F_ord4(iF + 3, jF, kF, ex)]) +
F28* (fh[idx_fh_F_ord4(iF - 2, jF, kF, ex)] + fh[idx_fh_F_ord4(iF + 2, jF, kF, ex)]) -
F56* (fh[idx_fh_F_ord4(iF - 1, jF, kF, ex)] + fh[idx_fh_F_ord4(iF + 1, jF, kF, ex)]) +
F70* fh[idx_fh_F_ord4(iF, jF, kF, ex)]
) / dX;
const double Dy = (
(fh[idx_fh_F_ord4(iF, jF - 4, kF, ex)] + fh[idx_fh_F_ord4(iF, jF + 4, kF, ex)]) -
F8 * (fh[idx_fh_F_ord4(iF, jF - 3, kF, ex)] + fh[idx_fh_F_ord4(iF, jF + 3, kF, ex)]) +
F28* (fh[idx_fh_F_ord4(iF, jF - 2, kF, ex)] + fh[idx_fh_F_ord4(iF, jF + 2, kF, ex)]) -
F56* (fh[idx_fh_F_ord4(iF, jF - 1, kF, ex)] + fh[idx_fh_F_ord4(iF, jF + 1, kF, ex)]) +
F70* fh[idx_fh_F_ord4(iF, jF, kF, ex)]
) / dY;
const double Dz = (
(fh[idx_fh_F_ord4(iF, jF, kF - 4, ex)] + fh[idx_fh_F_ord4(iF, jF, kF + 4, ex)]) -
F8 * (fh[idx_fh_F_ord4(iF, jF, kF - 3, ex)] + fh[idx_fh_F_ord4(iF, jF, kF + 3, ex)]) +
F28* (fh[idx_fh_F_ord4(iF, jF, kF - 2, ex)] + fh[idx_fh_F_ord4(iF, jF, kF + 2, ex)]) -
F56* (fh[idx_fh_F_ord4(iF, jF, kF - 1, ex)] + fh[idx_fh_F_ord4(iF, jF, kF + 1, ex)]) +
F70* fh[idx_fh_F_ord4(iF, jF, kF, ex)]
) / dZ;
f_rhs[p] -= (eps / cof) * (Dx + Dy + Dz); /* sign=- */
}
}
}
}
free(fh);
return;
}
#elif (ghost_width == 5)
/* ---- r=5, cof=1024, sign=+, 11pt stencil ------------------------- */
{
const int ord = 5;
const int r = 5;
const double cof = 1024.0;
const double F10 = 10.0, F45 = 45.0, F120 = 120.0;
const double F210 = 210.0, F252 = 252.0;
const int NO_SYMM = 0, EQ_SYMM = 1;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -4;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -4;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -4;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
/* i±5 valid: i0>=iminF+4, i0<=ex1-6 */
const int i0_lo = (iminF + 4 > 0) ? iminF + 4 : 0;
const int j0_lo = (jminF + 4 > 0) ? jminF + 4 : 0;
const int k0_lo = (kminF + 4 > 0) ? kminF + 4 : 0;
const int i0_hi = imaxF - 6;
const int j0_hi = jmaxF - 6;
const int k0_hi = kmaxF - 6;
if (!(i0_lo > i0_hi || j0_lo > j0_hi || k0_lo > k0_hi)) {
for (int k0 = k0_lo; k0 <= k0_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j0_lo; j0 <= j0_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i0_lo; i0 <= i0_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
/* Stencil: [1,-10,45,-120,210,-252,210,-120,45,-10,1] */
const double Dx = (
(fh[idx_fh_F_ord5(iF - 5, jF, kF, ex)] + fh[idx_fh_F_ord5(iF + 5, jF, kF, ex)]) -
F10 * (fh[idx_fh_F_ord5(iF - 4, jF, kF, ex)] + fh[idx_fh_F_ord5(iF + 4, jF, kF, ex)]) +
F45 * (fh[idx_fh_F_ord5(iF - 3, jF, kF, ex)] + fh[idx_fh_F_ord5(iF + 3, jF, kF, ex)]) -
F120* (fh[idx_fh_F_ord5(iF - 2, jF, kF, ex)] + fh[idx_fh_F_ord5(iF + 2, jF, kF, ex)]) +
F210* (fh[idx_fh_F_ord5(iF - 1, jF, kF, ex)] + fh[idx_fh_F_ord5(iF + 1, jF, kF, ex)]) -
F252* fh[idx_fh_F_ord5(iF, jF, kF, ex)]
) / dX;
const double Dy = (
(fh[idx_fh_F_ord5(iF, jF - 5, kF, ex)] + fh[idx_fh_F_ord5(iF, jF + 5, kF, ex)]) -
F10 * (fh[idx_fh_F_ord5(iF, jF - 4, kF, ex)] + fh[idx_fh_F_ord5(iF, jF + 4, kF, ex)]) +
F45 * (fh[idx_fh_F_ord5(iF, jF - 3, kF, ex)] + fh[idx_fh_F_ord5(iF, jF + 3, kF, ex)]) -
F120* (fh[idx_fh_F_ord5(iF, jF - 2, kF, ex)] + fh[idx_fh_F_ord5(iF, jF + 2, kF, ex)]) +
F210* (fh[idx_fh_F_ord5(iF, jF - 1, kF, ex)] + fh[idx_fh_F_ord5(iF, jF + 1, kF, ex)]) -
F252* fh[idx_fh_F_ord5(iF, jF, kF, ex)]
) / dY;
const double Dz = (
(fh[idx_fh_F_ord5(iF, jF, kF - 5, ex)] + fh[idx_fh_F_ord5(iF, jF, kF + 5, ex)]) -
F10 * (fh[idx_fh_F_ord5(iF, jF, kF - 4, ex)] + fh[idx_fh_F_ord5(iF, jF, kF + 4, ex)]) +
F45 * (fh[idx_fh_F_ord5(iF, jF, kF - 3, ex)] + fh[idx_fh_F_ord5(iF, jF, kF + 3, ex)]) -
F120* (fh[idx_fh_F_ord5(iF, jF, kF - 2, ex)] + fh[idx_fh_F_ord5(iF, jF, kF + 2, ex)]) +
F210* (fh[idx_fh_F_ord5(iF, jF, kF - 1, ex)] + fh[idx_fh_F_ord5(iF, jF, kF + 1, ex)]) -
F252* fh[idx_fh_F_ord5(iF, jF, kF, ex)]
) / dZ;
f_rhs[p] += (eps / cof) * (Dx + Dy + Dz); /* sign=+ */
}
}
}
}
free(fh);
return;
}
#else
#error "kodiss_c.C: unsupported ghost_width (must be 2, 3, 4, or 5)"
#endif
}
free(fh);
}

136
AMSS_NCKU_source/kodiss_sh_c.C
View File

@@ -1,136 +0,0 @@
#include "macrodef.h"
#include "share_func.h"
/*
* kodis_sh — Kreiss-Oliger dissipation on shell patches.
* Same stencil coefficients as Cartesian kodis. Uses symmetry_stbd.
*/
extern "C" void kodis_sh_(const int ex[3],
const double *X, const double *Y, const double *Z,
const double *f, double *f_rhs,
const double SoAi[2],
int Symmetry, double eps, int sst)
{
(void)sst;
const double ZEO=0.0;
const int ex1=ex[0], ex2=ex[1], ex3=ex[2];
const double dX=X[1]-X[0], dY=Y[1]-Y[0], dZ=Z[1]-Z[0];
const int imaxF=ex1, jmaxF=ex2, kmaxF=ex3;
const double SoA[2]={SoAi[0],SoAi[1]};
#if (ghost_width == 2)
{
const int ord=2, r=2;
const double cof=16.0, F4=4.0, F6=6.0;
const int NO_SYMM=0, OCTANT=2;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-1;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-1;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-1;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
double *fh=(double*)malloc(fh_size*sizeof(double));if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const int i0_lo=(iminF+1>0)?iminF+1:0,j0_lo=(jminF+1>0)?jminF+1:0,k0_lo=2;
const int i0_hi=imaxF-3,j0_hi=jmaxF-3,k0_hi=kmaxF-3;
if(!(i0_lo>i0_hi||j0_lo>j0_hi||k0_lo>k0_hi)){
for(int k0=k0_lo;k0<=k0_hi;++k0){const int kF=k0+1;
for(int j0=j0_lo;j0<=j0_hi;++j0){const int jF=j0+1;
for(int i0=i0_lo;i0<=i0_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
const double Dx=((fh[idx_fh_stbd(iF-2,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+2,jF,kF,ord,ex)])-F4*(fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)])+F6*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dX;
const double Dy=((fh[idx_fh_stbd(iF,jF-2,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+2,kF,ord,ex)])-F4*(fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)])+F6*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dY;
const double Dz=((fh[idx_fh_stbd(iF,jF,kF-2,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+2,ord,ex)])-F4*(fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)])+F6*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dZ;
f_rhs[p]-=(eps/cof)*(Dx+Dy+Dz);
}}}
}
free(fh);return;
}
#elif (ghost_width == 3)
{
const int ord=3, r=3;
const double cof=64.0,SIX=6.0,FIT=15.0,TWT=20.0;
const int NO_SYMM=0,OCTANT=2;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-2;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-2;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-2;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
double *fh=(double*)malloc(fh_size*sizeof(double));if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const int i0_lo=(iminF+2>0)?iminF+2:0,j0_lo=(jminF+2>0)?jminF+2:0,k0_lo=3;
const int i0_hi=imaxF-4,j0_hi=jmaxF-4,k0_hi=kmaxF-4;
if(!(i0_lo>i0_hi||j0_lo>j0_hi||k0_lo>k0_hi)){
for(int k0=k0_lo;k0<=k0_hi;++k0){const int kF=k0+1;
for(int j0=j0_lo;j0<=j0_hi;++j0){const int jF=j0+1;
for(int i0=i0_lo;i0<=i0_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
const double Dx=((fh[idx_fh_stbd(iF-3,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+3,jF,kF,ord,ex)])-SIX*(fh[idx_fh_stbd(iF-2,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+2,jF,kF,ord,ex)])+FIT*(fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)])-TWT*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dX;
const double Dy=((fh[idx_fh_stbd(iF,jF-3,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+3,kF,ord,ex)])-SIX*(fh[idx_fh_stbd(iF,jF-2,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+2,kF,ord,ex)])+FIT*(fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)])-TWT*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dY;
const double Dz=((fh[idx_fh_stbd(iF,jF,kF-3,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+3,ord,ex)])-SIX*(fh[idx_fh_stbd(iF,jF,kF-2,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+2,ord,ex)])+FIT*(fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)])-TWT*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dZ;
f_rhs[p]+=(eps/cof)*(Dx+Dy+Dz);
}}}
}
free(fh);return;
}
#elif (ghost_width == 4)
{
const int ord=4, r=4;
const double cof=256.0,F8=8.0,F28=28.0,F56=56.0,F70=70.0;
const int NO_SYMM=0,OCTANT=2;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-3;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-3;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-3;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
double *fh=(double*)malloc(fh_size*sizeof(double));if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const int i0_lo=(iminF+3>0)?iminF+3:0,j0_lo=(jminF+3>0)?jminF+3:0,k0_lo=4;
const int i0_hi=imaxF-5,j0_hi=jmaxF-5,k0_hi=kmaxF-5;
if(!(i0_lo>i0_hi||j0_lo>j0_hi||k0_lo>k0_hi)){
for(int k0=k0_lo;k0<=k0_hi;++k0){const int kF=k0+1;
for(int j0=j0_lo;j0<=j0_hi;++j0){const int jF=j0+1;
for(int i0=i0_lo;i0<=i0_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
const double Dx=((fh[idx_fh_stbd(iF-4,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+4,jF,kF,ord,ex)])-F8*(fh[idx_fh_stbd(iF-3,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+3,jF,kF,ord,ex)])+F28*(fh[idx_fh_stbd(iF-2,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+2,jF,kF,ord,ex)])-F56*(fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)])+F70*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dX;
const double Dy=((fh[idx_fh_stbd(iF,jF-4,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+4,kF,ord,ex)])-F8*(fh[idx_fh_stbd(iF,jF-3,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+3,kF,ord,ex)])+F28*(fh[idx_fh_stbd(iF,jF-2,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+2,kF,ord,ex)])-F56*(fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)])+F70*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dY;
const double Dz=((fh[idx_fh_stbd(iF,jF,kF-4,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+4,ord,ex)])-F8*(fh[idx_fh_stbd(iF,jF,kF-3,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+3,ord,ex)])+F28*(fh[idx_fh_stbd(iF,jF,kF-2,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+2,ord,ex)])-F56*(fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)])+F70*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dZ;
f_rhs[p]-=(eps/cof)*(Dx+Dy+Dz);
}}}
}
free(fh);return;
}
#elif (ghost_width == 5)
{
const int ord=5, r=5;
const double cof=1024.0,F10=10.0,F45k=45.0,F120=120.0,F210=210.0,F252=252.0;
const int NO_SYMM=0,OCTANT=2;
int iminF=1,jminF=1,kminF=1;
if(Symmetry==OCTANT&&fabs(X[0])<dX)iminF=-4;
if(Symmetry==OCTANT&&fabs(Y[0])<dY)jminF=-4;
if((sst==2||sst==4)&&fabs(Y[0])<dY)jminF=-4;
const size_t nx=(size_t)ex1+2*ord,ny=(size_t)ex2+2*ord,nz=(size_t)ex3,fh_size=nx*ny*nz;
double *fh=(double*)malloc(fh_size*sizeof(double));if(!fh)return;
symmetry_stbd(ord,ex,f,fh,SoA);
const int i0_lo=(iminF+4>0)?iminF+4:0,j0_lo=(jminF+4>0)?jminF+4:0,k0_lo=5;
const int i0_hi=imaxF-6,j0_hi=jmaxF-6,k0_hi=kmaxF-6;
if(!(i0_lo>i0_hi||j0_lo>j0_hi||k0_lo>k0_hi)){
for(int k0=k0_lo;k0<=k0_hi;++k0){const int kF=k0+1;
for(int j0=j0_lo;j0<=j0_hi;++j0){const int jF=j0+1;
for(int i0=i0_lo;i0<=i0_hi;++i0){const int iF=i0+1;const size_t p=idx_ex(i0,j0,k0,ex);
const double Dx=((fh[idx_fh_stbd(iF-5,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+5,jF,kF,ord,ex)])-F10*(fh[idx_fh_stbd(iF-4,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+4,jF,kF,ord,ex)])+F45k*(fh[idx_fh_stbd(iF-3,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+3,jF,kF,ord,ex)])-F120*(fh[idx_fh_stbd(iF-2,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+2,jF,kF,ord,ex)])+F210*(fh[idx_fh_stbd(iF-1,jF,kF,ord,ex)]+fh[idx_fh_stbd(iF+1,jF,kF,ord,ex)])-F252*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dX;
const double Dy=((fh[idx_fh_stbd(iF,jF-5,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+5,kF,ord,ex)])-F10*(fh[idx_fh_stbd(iF,jF-4,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+4,kF,ord,ex)])+F45k*(fh[idx_fh_stbd(iF,jF-3,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+3,kF,ord,ex)])-F120*(fh[idx_fh_stbd(iF,jF-2,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+2,kF,ord,ex)])+F210*(fh[idx_fh_stbd(iF,jF-1,kF,ord,ex)]+fh[idx_fh_stbd(iF,jF+1,kF,ord,ex)])-F252*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dY;
const double Dz=((fh[idx_fh_stbd(iF,jF,kF-5,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+5,ord,ex)])-F10*(fh[idx_fh_stbd(iF,jF,kF-4,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+4,ord,ex)])+F45k*(fh[idx_fh_stbd(iF,jF,kF-3,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+3,ord,ex)])-F120*(fh[idx_fh_stbd(iF,jF,kF-2,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+2,ord,ex)])+F210*(fh[idx_fh_stbd(iF,jF,kF-1,ord,ex)]+fh[idx_fh_stbd(iF,jF,kF+1,ord,ex)])-F252*fh[idx_fh_stbd(iF,jF,kF,ord,ex)])/dZ;
f_rhs[p]+=(eps/cof)*(Dx+Dy+Dz);
}}}
}
free(fh);return;
}
#else
#error "kodiss_sh_c.C: unsupported ghost_width"
#endif
}

782
AMSS_NCKU_source/lopsided_c.C
View File

@@ -1,13 +1,14 @@
#include "macrodef.h"
#include "tool.h"
/*
* C 版 lopsided — upwind (lopsided) advection derivatives.
* 你需要提供 symmetry_bd 的 C 版本(或 Fortran 绑到 C 的接口)。
* Fortran: call symmetry_bd(3,ex,f,fh,SoA)
*
* Adds advection terms to f_rhs for all three spatial directions.
* Uses sign-biased (one-sided) stencils with centered fallbacks.
*
* For lopsided, symmetry_bd ord = ghost_width (same as kodiss).
* 约定:
* nghost = 3
* ex[3] = {ex1,ex2,ex3}
* f = 原始网格 (ex1*ex2*ex3)
* fh = 扩展网格 ((ex1+3)*(ex2+3)*(ex3+3)),对应 Fortran 的 (-2:ex1, ...)
* SoA[3] = 输入参数
*/
void lopsided(const int ex[3],
const double *X, const double *Y, const double *Z,
@@ -15,577 +16,240 @@ void lopsided(const int ex[3],
const double *Sfx, const double *Sfy, const double *Sfz,
int Symmetry, const double SoA[3])
{
const double ZEO = 0.0, ONE = 1.0;
const double TWO = 2.0, F6 = 6.0, EIT = 8.0;
const double F3 = 3.0, F4 = 4.0, F5 = 5.0, F10 = 10.0, F12 = 12.0, F18 = 18.0;
const double F9 = 9.0, F45 = 45.0, F60 = 60.0;
const double F2 = 2.0, F15 = 15.0, F24 = 24.0, F30 = 30.0, F35 = 35.0;
const double F50 = 50.0, F77 = 77.0, F80 = 80.0, F100 = 100.0, F150 = 150.0;
const double F32 = 32.0, F168 = 168.0, F672 = 672.0, F840 = 840.0;
const double F140=140.0, F378=378.0, F420=420.0, F1050=1050.0;
const double ZEO = 0.0, ONE = 1.0, F3 = 3.0;
const double TWO = 2.0, F6 = 6.0, F18 = 18.0;
const double F12 = 12.0, F10 = 10.0, EIT = 8.0;
const int NO_SYMM = 0, EQ_SYMM = 1, OCTANT = 2;
(void)OCTANT; // 这里和 Fortran 一样只是定义了不用也没关系
const int NO_SYMM = 0, EQ_SYMM = 1;
const int ex1 = ex[0], ex2 = ex[1], ex3 = ex[2];
// 对应 Fortran: dX = X(2)-X(1) Fortran 1-based
// C: X[1]-X[0]
const double dX = X[1] - X[0];
const double dY = Y[1] - Y[0];
const double dZ = Z[1] - Z[0];
#if (ghost_width == 2)
/* ---- 2nd-order lopsided --------------------------------------------- */
{
const int ord = 2;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -1;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -1;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -1;
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
// Fortran 里算了 d2dx/d2dy/d2dz 但本 subroutine 里没用到(保持一致也算出来)
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
(void)d2dx; (void)d2dy; (void)d2dz;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
// Fortran:
// imax = ex(1); jmax = ex(2); kmax = ex(3)
const int imaxF = ex1;
const int jmaxF = ex2;
const int kmaxF = ex3;
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
// Fortran:
// imin=jmin=kmin=1; 若满足对称条件则设为 -2
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -2;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -2;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -2;
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
// 分配 fh大小 (ex1+3)*(ex2+3)*(ex3+3)
const size_t nx = (size_t)ex1 + 3;
const size_t ny = (size_t)ex2 + 3;
const size_t nz = (size_t)ex3 + 3;
const size_t fh_size = nx * ny * nz;
for (int k0 = 0; k0 <= ex3 - 2; ++k0) {
const int kF = k0 + 1;
for (int j0 = 0; j0 <= ex2 - 2; ++j0) {
const int jF = j0 + 1;
for (int i0 = 0; i0 <= ex1 - 2; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return; // 内存不足:直接返回(你也可以改成 abort/报错)
/* x-direction */
const double sfx = Sfx[p];
if (sfx > ZEO) {
if (i0 <= ex1 - 3) // i+2 <= imax
f_rhs[p] += sfx * d2dx * (
-F3*fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
F4*fh[idx_fh_F_ord2(iF+1, jF, kF, ex)] -
fh[idx_fh_F_ord2(iF+2, jF, kF, ex)]);
else if (i0 <= ex1 - 2) // i+1 <= imax
f_rhs[p] += sfx * d2dx * (
-fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF+1, jF, kF, ex)]);
} else if (sfx < ZEO) {
if ((i0 - 1) >= iminF) // i-2 >= imin
f_rhs[p] -= sfx * d2dx * (
-F3*fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
F4*fh[idx_fh_F_ord2(iF-1, jF, kF, ex)] -
fh[idx_fh_F_ord2(iF-2, jF, kF, ex)]);
else if (i0 >= iminF) // i-1 >= imin
f_rhs[p] -= sfx * d2dx * (
-fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF-1, jF, kF, ex)]);
// Fortran: call symmetry_bd(3,ex,f,fh,SoA)
symmetry_bd(3, ex, f, fh, SoA);
/*
* Fortran 主循环:
* do k=1,ex(3)-1
* do j=1,ex(2)-1
* do i=1,ex(1)-1
*
* 转成 C 0-based
* k0 = 0..ex3-2, j0 = 0..ex2-2, i0 = 0..ex1-2
*
* 并且 Fortran 里的 i/j/k 在 fh 访问时,仍然是 Fortran 索引值:
* iF=i0+1, jF=j0+1, kF=k0+1
*/
for (int k0 = 0; k0 <= ex3 - 2; ++k0) {
const int kF = k0 + 1;
for (int j0 = 0; j0 <= ex2 - 2; ++j0) {
const int jF = j0 + 1;
for (int i0 = 0; i0 <= ex1 - 2; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
// ---------------- x direction ----------------
const double sfx = Sfx[p];
if (sfx > ZEO) {
// Fortran: if(i+3 <= imax)
// iF+3 <= ex1 <=> i0+4 <= ex1 <=> i0 <= ex1-4
if (i0 <= ex1 - 4) {
f_rhs[p] += sfx * d12dx *
(-F3 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF + 2, jF, kF, ex)]
+ fh[idx_fh_F(iF + 3, jF, kF, ex)]);
}
/* y-direction */
const double sfy = Sfy[p];
if (sfy > ZEO) {
if (j0 <= ex2-3)
f_rhs[p] += sfy * d2dy * (
-F3*fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
F4*fh[idx_fh_F_ord2(iF, jF+1, kF, ex)] -
fh[idx_fh_F_ord2(iF, jF+2, kF, ex)]);
else if (j0 <= ex2-2)
f_rhs[p] += sfy * d2dy * (
-fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF, jF+1, kF, ex)]);
} else if (sfy < ZEO) {
if ((j0-1) >= jminF)
f_rhs[p] -= sfy * d2dy * (
-F3*fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
F4*fh[idx_fh_F_ord2(iF, jF-1, kF, ex)] -
fh[idx_fh_F_ord2(iF, jF-2, kF, ex)]);
else if (j0 >= jminF)
f_rhs[p] -= sfy * d2dy * (
-fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF, jF-1, kF, ex)]);
// elseif(i+2 <= imax) <=> i0 <= ex1-3
else if (i0 <= ex1 - 3) {
f_rhs[p] += sfx * d12dx *
( fh[idx_fh_F(iF - 2, jF, kF, ex)]
-EIT * fh[idx_fh_F(iF - 1, jF, kF, ex)]
+EIT * fh[idx_fh_F(iF + 1, jF, kF, ex)]
- fh[idx_fh_F(iF + 2, jF, kF, ex)]);
}
// elseif(i+1 <= imax) <=> i0 <= ex1-2循环里总成立
else if (i0 <= ex1 - 2) {
f_rhs[p] -= sfx * d12dx *
(-F3 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF - 2, jF, kF, ex)]
+ fh[idx_fh_F(iF - 3, jF, kF, ex)]);
}
} else if (sfx < ZEO) {
// Fortran: if(i-3 >= imin)
// (iF-3) >= iminF <=> (i0-2) >= iminF
if ((i0 - 2) >= iminF) {
f_rhs[p] -= sfx * d12dx *
(-F3 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF - 2, jF, kF, ex)]
+ fh[idx_fh_F(iF - 3, jF, kF, ex)]);
}
// elseif(i-2 >= imin) <=> (i0-1) >= iminF
else if ((i0 - 1) >= iminF) {
f_rhs[p] += sfx * d12dx *
( fh[idx_fh_F(iF - 2, jF, kF, ex)]
-EIT * fh[idx_fh_F(iF - 1, jF, kF, ex)]
+EIT * fh[idx_fh_F(iF + 1, jF, kF, ex)]
- fh[idx_fh_F(iF + 2, jF, kF, ex)]);
}
// elseif(i-1 >= imin) <=> i0 >= iminF
else if (i0 >= iminF) {
f_rhs[p] += sfx * d12dx *
(-F3 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF + 2, jF, kF, ex)]
+ fh[idx_fh_F(iF + 3, jF, kF, ex)]);
}
}
/* z-direction */
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0 <= ex3-3)
f_rhs[p] += sfz * d2dz * (
-F3*fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
F4*fh[idx_fh_F_ord2(iF, jF, kF+1, ex)] -
fh[idx_fh_F_ord2(iF, jF, kF+2, ex)]);
else if (k0 <= ex3-2)
f_rhs[p] += sfz * d2dz * (
-fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF, jF, kF+1, ex)]);
} else if (sfz < ZEO) {
if ((k0-1) >= kminF)
f_rhs[p] -= sfz * d2dz * (
-F3*fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
F4*fh[idx_fh_F_ord2(iF, jF, kF-1, ex)] -
fh[idx_fh_F_ord2(iF, jF, kF-2, ex)]);
else if (k0 >= kminF)
f_rhs[p] -= sfz * d2dz * (
-fh[idx_fh_F_ord2(iF, jF, kF, ex)] +
fh[idx_fh_F_ord2(iF, jF, kF-1, ex)]);
// ---------------- y direction ----------------
const double sfy = Sfy[p];
if (sfy > ZEO) {
// jF+3 <= ex2 <=> j0+4 <= ex2 <=> j0 <= ex2-4
if (j0 <= ex2 - 4) {
f_rhs[p] += sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF + 2, kF, ex)]
+ fh[idx_fh_F(iF, jF + 3, kF, ex)]);
} else if (j0 <= ex2 - 3) {
f_rhs[p] += sfy * d12dy *
( fh[idx_fh_F(iF, jF - 2, kF, ex)]
-EIT * fh[idx_fh_F(iF, jF - 1, kF, ex)]
+EIT * fh[idx_fh_F(iF, jF + 1, kF, ex)]
- fh[idx_fh_F(iF, jF + 2, kF, ex)]);
} else if (j0 <= ex2 - 2) {
f_rhs[p] -= sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF - 2, kF, ex)]
+ fh[idx_fh_F(iF, jF - 3, kF, ex)]);
}
} else if (sfy < ZEO) {
if ((j0 - 2) >= jminF) {
f_rhs[p] -= sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF - 2, kF, ex)]
+ fh[idx_fh_F(iF, jF - 3, kF, ex)]);
} else if ((j0 - 1) >= jminF) {
f_rhs[p] += sfy * d12dy *
( fh[idx_fh_F(iF, jF - 2, kF, ex)]
-EIT * fh[idx_fh_F(iF, jF - 1, kF, ex)]
+EIT * fh[idx_fh_F(iF, jF + 1, kF, ex)]
- fh[idx_fh_F(iF, jF + 2, kF, ex)]);
} else if (j0 >= jminF) {
f_rhs[p] += sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF + 2, kF, ex)]
+ fh[idx_fh_F(iF, jF + 3, kF, ex)]);
}
}
// ---------------- z direction ----------------
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0 <= ex3 - 4) {
f_rhs[p] += sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF + 2, ex)]
+ fh[idx_fh_F(iF, jF, kF + 3, ex)]);
} else if (k0 <= ex3 - 3) {
f_rhs[p] += sfz * d12dz *
( fh[idx_fh_F(iF, jF, kF - 2, ex)]
-EIT * fh[idx_fh_F(iF, jF, kF - 1, ex)]
+EIT * fh[idx_fh_F(iF, jF, kF + 1, ex)]
- fh[idx_fh_F(iF, jF, kF + 2, ex)]);
} else if (k0 <= ex3 - 2) {
f_rhs[p] -= sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF - 2, ex)]
+ fh[idx_fh_F(iF, jF, kF - 3, ex)]);
}
} else if (sfz < ZEO) {
if ((k0 - 2) >= kminF) {
f_rhs[p] -= sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF - 2, ex)]
+ fh[idx_fh_F(iF, jF, kF - 3, ex)]);
} else if ((k0 - 1) >= kminF) {
f_rhs[p] += sfz * d12dz *
( fh[idx_fh_F(iF, jF, kF - 2, ex)]
-EIT * fh[idx_fh_F(iF, jF, kF - 1, ex)]
+EIT * fh[idx_fh_F(iF, jF, kF + 1, ex)]
- fh[idx_fh_F(iF, jF, kF + 2, ex)]);
} else if (k0 >= kminF) {
f_rhs[p] += sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF + 2, ex)]
+ fh[idx_fh_F(iF, jF, kF + 3, ex)]);
}
}
}
}
free(fh);
return;
}
#elif (ghost_width == 3)
/* ---- 4th-order lopsided (original code) ---------------------------- */
{
const int ord = 3;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -2;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -2;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -2;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
for (int k0 = 0; k0 <= ex3 - 2; ++k0) {
const int kF = k0 + 1;
for (int j0 = 0; j0 <= ex2 - 2; ++j0) {
const int jF = j0 + 1;
for (int i0 = 0; i0 <= ex1 - 2; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
const double sfx = Sfx[p];
if (sfx > ZEO) {
if (i0 <= ex1 - 4) // i+3 <= imax
f_rhs[p] += sfx * d12dx * (
-F3 *fh[idx_fh_F(iF-1, jF, kF, ex)]
-F10*fh[idx_fh_F(iF, jF, kF, ex)]
+F18*fh[idx_fh_F(iF+1, jF, kF, ex)]
-F6 *fh[idx_fh_F(iF+2, jF, kF, ex)]
+ fh[idx_fh_F(iF+3, jF, kF, ex)]);
else if (i0 <= ex1 - 3) // i+2 <= imax
f_rhs[p] += sfx * d12dx * (
fh[idx_fh_F(iF-2, jF, kF, ex)]
-EIT*fh[idx_fh_F(iF-1, jF, kF, ex)]
+EIT*fh[idx_fh_F(iF+1, jF, kF, ex)]
- fh[idx_fh_F(iF+2, jF, kF, ex)]);
else if (i0 <= ex1 - 2) // i+1 <= imax → mirrored
f_rhs[p] -= sfx * d12dx * (
-F3 *fh[idx_fh_F(iF+1, jF, kF, ex)]
-F10*fh[idx_fh_F(iF, jF, kF, ex)]
+F18*fh[idx_fh_F(iF-1, jF, kF, ex)]
-F6 *fh[idx_fh_F(iF-2, jF, kF, ex)]
+ fh[idx_fh_F(iF-3, jF, kF, ex)]);
} else if (sfx < ZEO) {
if ((i0 - 2) >= iminF) // i-3 >= imin
f_rhs[p] -= sfx * d12dx * (
-F3 *fh[idx_fh_F(iF+1, jF, kF, ex)]
-F10*fh[idx_fh_F(iF, jF, kF, ex)]
+F18*fh[idx_fh_F(iF-1, jF, kF, ex)]
-F6 *fh[idx_fh_F(iF-2, jF, kF, ex)]
+ fh[idx_fh_F(iF-3, jF, kF, ex)]);
else if ((i0 - 1) >= iminF) // i-2 >= imin
f_rhs[p] += sfx * d12dx * (
fh[idx_fh_F(iF-2, jF, kF, ex)]
-EIT*fh[idx_fh_F(iF-1, jF, kF, ex)]
+EIT*fh[idx_fh_F(iF+1, jF, kF, ex)]
- fh[idx_fh_F(iF+2, jF, kF, ex)]);
else if (i0 >= iminF) // i-1 >= imin → mirrored
f_rhs[p] += sfx * d12dx * (
-F3 *fh[idx_fh_F(iF-1, jF, kF, ex)]
-F10*fh[idx_fh_F(iF, jF, kF, ex)]
+F18*fh[idx_fh_F(iF+1, jF, kF, ex)]
-F6 *fh[idx_fh_F(iF+2, jF, kF, ex)]
+ fh[idx_fh_F(iF+3, jF, kF, ex)]);
}
const double sfy = Sfy[p];
if (sfy > ZEO) {
if (j0 <= ex2-4)
f_rhs[p] += sfy * d12dy * (
-F3*fh[idx_fh_F(iF,jF-1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF+1,kF,ex)]-F6*fh[idx_fh_F(iF,jF+2,kF,ex)]
+fh[idx_fh_F(iF,jF+3,kF,ex)]);
else if (j0 <= ex2-3)
f_rhs[p] += sfy * d12dy * (fh[idx_fh_F(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F(iF,jF+1,kF,ex)]-fh[idx_fh_F(iF,jF+2,kF,ex)]);
else if (j0 <= ex2-2)
f_rhs[p] -= sfy * d12dy * (
-F3*fh[idx_fh_F(iF,jF+1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF-1,kF,ex)]-F6*fh[idx_fh_F(iF,jF-2,kF,ex)]
+fh[idx_fh_F(iF,jF-3,kF,ex)]);
} else if (sfy < ZEO) {
if ((j0-2) >= jminF)
f_rhs[p] -= sfy * d12dy * (
-F3*fh[idx_fh_F(iF,jF+1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF-1,kF,ex)]-F6*fh[idx_fh_F(iF,jF-2,kF,ex)]
+fh[idx_fh_F(iF,jF-3,kF,ex)]);
else if ((j0-1) >= jminF)
f_rhs[p] += sfy * d12dy * (fh[idx_fh_F(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F(iF,jF+1,kF,ex)]-fh[idx_fh_F(iF,jF+2,kF,ex)]);
else if (j0 >= jminF)
f_rhs[p] += sfy * d12dy * (
-F3*fh[idx_fh_F(iF,jF-1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF+1,kF,ex)]-F6*fh[idx_fh_F(iF,jF+2,kF,ex)]
+fh[idx_fh_F(iF,jF+3,kF,ex)]);
}
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0 <= ex3-4)
f_rhs[p] += sfz * d12dz * (
-F3*fh[idx_fh_F(iF,jF,kF-1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF,kF+1,ex)]-F6*fh[idx_fh_F(iF,jF,kF+2,ex)]
+fh[idx_fh_F(iF,jF,kF+3,ex)]);
else if (k0 <= ex3-3)
f_rhs[p] += sfz * d12dz * (fh[idx_fh_F(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F(iF,jF,kF+1,ex)]-fh[idx_fh_F(iF,jF,kF+2,ex)]);
else if (k0 <= ex3-2)
f_rhs[p] -= sfz * d12dz * (
-F3*fh[idx_fh_F(iF,jF,kF+1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF,kF-1,ex)]-F6*fh[idx_fh_F(iF,jF,kF-2,ex)]
+fh[idx_fh_F(iF,jF,kF-3,ex)]);
} else if (sfz < ZEO) {
if ((k0-2) >= kminF)
f_rhs[p] -= sfz * d12dz * (
-F3*fh[idx_fh_F(iF,jF,kF+1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF,kF-1,ex)]-F6*fh[idx_fh_F(iF,jF,kF-2,ex)]
+fh[idx_fh_F(iF,jF,kF-3,ex)]);
else if ((k0-1) >= kminF)
f_rhs[p] += sfz * d12dz * (fh[idx_fh_F(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F(iF,jF,kF+1,ex)]-fh[idx_fh_F(iF,jF,kF+2,ex)]);
else if (k0 >= kminF)
f_rhs[p] += sfz * d12dz * (
-F3*fh[idx_fh_F(iF,jF,kF-1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]
+F18*fh[idx_fh_F(iF,jF,kF+1,ex)]-F6*fh[idx_fh_F(iF,jF,kF+2,ex)]
+fh[idx_fh_F(iF,jF,kF+3,ex)]);
}
}
}
}
free(fh);
return;
}
#elif (ghost_width == 4)
/* ---- 6th-order lopsided --------------------------------------------- */
{
const int ord = 4;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -3;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -3;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -3;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
const double d60dx = ONE / F60 / dX;
const double d60dy = ONE / F60 / dY;
const double d60dz = ONE / F60 / dZ;
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
for (int k0 = 0; k0 <= ex3 - 2; ++k0) {
const int kF = k0 + 1;
for (int j0 = 0; j0 <= ex2 - 2; ++j0) {
const int jF = j0 + 1;
for (int i0 = 0; i0 <= ex1 - 2; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
/* ---- x-direction ---- */
const double sfx = Sfx[p];
if (sfx > ZEO) {
/* Primary biased: 2*f(i-2)-24*f(i-1)-35*f(i)+80*f(i+1)-30*f(i+2)+8*f(i+3)-f(i+4) */
if (i0 <= ex1-5 && (i0-1)>=iminF) // i+4<=imax && i-2>=imin
f_rhs[p] += sfx * d60dx * (
+F2*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-F24*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]
-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]
-F30*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]
-fh[idx_fh_F_ord4(iF+4,jF,kF,ex)]);
/* Boundary-adapted: -10*f(i-1)-77*f(i)+150*f(i+1)-100*f(i+2)+50*f(i+3)-15*f(i+4)+2*f(i+5) */
else if (i0 <= ex1-6 && i0 >= iminF) // i+5<=imax && i-1>=imin
f_rhs[p] += sfx * d60dx * (
-F10*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]
+F150*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F100*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]
+F50*fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]-F15*fh[idx_fh_F_ord4(iF+4,jF,kF,ex)]
+F2*fh[idx_fh_F_ord4(iF+5,jF,kF,ex)]);
/* Centered fallbacks */
else if (i0 <= ex1-4 && (i0-2)>=iminF) // 6th: i+3<=imax && i-3>=imin
f_rhs[p] += sfx * d60dx * (
-fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]+F9*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]
-F45*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+F45*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]
-F9*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]);
else if (i0 <= ex1-3 && (i0-1)>=iminF) // 4th
f_rhs[p] += sfx * d12dx * (
fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]
+EIT*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]);
else if (i0 <= ex1-2 && i0>=iminF) // 2nd
f_rhs[p] += sfx * d2dx * (
-fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]);
} else if (sfx < ZEO) {
if ((i0-3)>=iminF && i0<=ex1-3) // i-4>=imin && i+2<=imax
f_rhs[p] -= sfx * d60dx * (
+F2*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]-F24*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]
-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]
-F30*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]
-fh[idx_fh_F_ord4(iF-4,jF,kF,ex)]);
else if ((i0-4)>=iminF && i0<=ex1-2) // i-5>=imin && i+1<=imax
f_rhs[p] -= sfx * d60dx * (
-F10*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]
+F150*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]-F100*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]
+F50*fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]-F15*fh[idx_fh_F_ord4(iF-4,jF,kF,ex)]
+F2*fh[idx_fh_F_ord4(iF-5,jF,kF,ex)]);
else if ((i0-2)>=iminF && i0<=ex1-4) // 6th centered
f_rhs[p] += sfx * d60dx * (
-fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]+F9*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]
-F45*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+F45*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]
-F9*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]);
else if ((i0-1)>=iminF && i0<=ex1-3) // 4th
f_rhs[p] += sfx * d12dx * (
fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]
+EIT*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]);
else if (i0>=iminF && i0<=ex1-2) // 2nd
f_rhs[p] += sfx * d2dx * (
-fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]);
}
/* ---- y-direction ---- */
const double sfy = Sfy[p];
if (sfy > ZEO) {
if (j0<=ex2-5 && (j0-1)>=jminF)
f_rhs[p] += sfy * d60dy*(F2*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-F24*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F30*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]-fh[idx_fh_F_ord4(iF,jF+4,kF,ex)]);
else if (j0<=ex2-6 && j0>=jminF)
f_rhs[p] += sfy * d60dy*(-F10*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F100*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+F50*fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]-F15*fh[idx_fh_F_ord4(iF,jF+4,kF,ex)]+F2*fh[idx_fh_F_ord4(iF,jF+5,kF,ex)]);
else if (j0<=ex2-4 && (j0-2)>=jminF)
f_rhs[p] += sfy * d60dy*(-fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]+F9*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-F45*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+F45*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F9*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]);
else if (j0<=ex2-3 && (j0-1)>=jminF)
f_rhs[p] += sfy * d12dy*(fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]);
else if (j0<=ex2-2 && j0>=jminF)
f_rhs[p] += sfy * d2dy*(-fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]);
} else if (sfy < ZEO) {
if ((j0-3)>=jminF && j0<=ex2-3)
f_rhs[p] -= sfy * d60dy*(F2*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]-F24*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F30*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]-fh[idx_fh_F_ord4(iF,jF-4,kF,ex)]);
else if ((j0-4)>=jminF && j0<=ex2-2)
f_rhs[p] -= sfy * d60dy*(-F10*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F100*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]+F50*fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]-F15*fh[idx_fh_F_ord4(iF,jF-4,kF,ex)]+F2*fh[idx_fh_F_ord4(iF,jF-5,kF,ex)]);
else if ((j0-2)>=jminF && j0<=ex2-4)
f_rhs[p] += sfy * d60dy*(-fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]+F9*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-F45*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+F45*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F9*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]);
else if ((j0-1)>=jminF && j0<=ex2-3)
f_rhs[p] += sfy * d12dy*(fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]);
else if (j0>=jminF && j0<=ex2-2)
f_rhs[p] += sfy * d2dy*(-fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]);
}
/* ---- z-direction ---- */
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0<=ex3-5 && (k0-1)>=kminF)
f_rhs[p] += sfz * d60dz*(F2*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-F24*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F30*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]-fh[idx_fh_F_ord4(iF,jF,kF+4,ex)]);
else if (k0<=ex3-6 && k0>=kminF)
f_rhs[p] += sfz * d60dz*(-F10*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F100*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+F50*fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]-F15*fh[idx_fh_F_ord4(iF,jF,kF+4,ex)]+F2*fh[idx_fh_F_ord4(iF,jF,kF+5,ex)]);
else if (k0<=ex3-4 && (k0-2)>=kminF)
f_rhs[p] += sfz * d60dz*(-fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]+F9*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-F45*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+F45*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F9*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]);
else if (k0<=ex3-3 && (k0-1)>=kminF)
f_rhs[p] += sfz * d12dz*(fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]);
else if (k0<=ex3-2 && k0>=kminF)
f_rhs[p] += sfz * d2dz*(-fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]);
} else if (sfz < ZEO) {
if ((k0-3)>=kminF && k0<=ex3-3)
f_rhs[p] -= sfz * d60dz*(F2*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]-F24*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F30*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]-fh[idx_fh_F_ord4(iF,jF,kF-4,ex)]);
else if ((k0-4)>=kminF && k0<=ex3-2)
f_rhs[p] -= sfz * d60dz*(-F10*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F100*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]+F50*fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]-F15*fh[idx_fh_F_ord4(iF,jF,kF-4,ex)]+F2*fh[idx_fh_F_ord4(iF,jF,kF-5,ex)]);
else if ((k0-2)>=kminF && k0<=ex3-4)
f_rhs[p] += sfz * d60dz*(-fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]+F9*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-F45*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+F45*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F9*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]);
else if ((k0-1)>=kminF && k0<=ex3-3)
f_rhs[p] += sfz * d12dz*(fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]);
else if (k0>=kminF && k0<=ex3-2)
f_rhs[p] += sfz * d2dz*(-fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]);
}
}
}
}
free(fh);
return;
}
#elif (ghost_width == 5)
/* ---- 8th-order lopsided --------------------------------------------- */
{
const int ord = 5;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -4;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -4;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -4;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
const size_t fh_size = nx * ny * nz;
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
const double d840dx = ONE / F840 / dX;
const double d840dy = ONE / F840 / dY;
const double d840dz = ONE / F840 / dZ;
const double d60dx = ONE / F60 / dX;
const double d60dy = ONE / F60 / dY;
const double d60dz = ONE / F60 / dZ;
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
const double d2dx = ONE / TWO / dX;
const double d2dy = ONE / TWO / dY;
const double d2dz = ONE / TWO / dZ;
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
for (int k0 = 0; k0 <= ex3 - 2; ++k0) {
const int kF = k0 + 1;
for (int j0 = 0; j0 <= ex2 - 2; ++j0) {
const int jF = j0 + 1;
for (int i0 = 0; i0 <= ex1 - 2; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
const double sfx = Sfx[p];
if (sfx > ZEO) {
/* 8th biased: -5*f(i-3)+60*f(i-2)-420*f(i-1)-378*f(i)+1050*f(i+1)-420*f(i+2)+140*f(i+3)-30*f(i+4)+3*f(i+5) */
if (i0 <= ex1-6 && (i0-2)>=iminF) // i+5<=imax && i-3>=imin
f_rhs[p] += sfx * d840dx * (
-F5*fh[idx_fh_F_ord5(iF-3,jF,kF,ex)]+F60*fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]
-F420*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]-F378*fh[idx_fh_F_ord5(iF,jF,kF,ex)]
+F1050*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]-F420*fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]
+F140*fh[idx_fh_F_ord5(iF+3,jF,kF,ex)]-F30*fh[idx_fh_F_ord5(iF+4,jF,kF,ex)]
+F3*fh[idx_fh_F_ord5(iF+5,jF,kF,ex)]);
/* 8th centered: +3*f(i-4)-32*f(i-3)+168*f(i-2)-672*f(i-1)+672*f(i+1)-168*f(i+2)+32*f(i+3)-3*f(i+4) */
else if (i0 <= ex1-5 && (i0-3)>=iminF)
f_rhs[p] += sfx * d840dx * (
+F3*fh[idx_fh_F_ord5(iF-4,jF,kF,ex)]-F32*fh[idx_fh_F_ord5(iF-3,jF,kF,ex)]
+F168*fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]-F672*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]
+F672*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]-F168*fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]
+F32*fh[idx_fh_F_ord5(iF+3,jF,kF,ex)]-F3*fh[idx_fh_F_ord5(iF+4,jF,kF,ex)]);
else if (i0 <= ex1-4 && (i0-2)>=iminF) // 6th centered
f_rhs[p] += sfx * d60dx * (
-fh[idx_fh_F_ord5(iF-3,jF,kF,ex)]+F9*fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]
-F45*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]+F45*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]
-F9*fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]+fh[idx_fh_F_ord5(iF+3,jF,kF,ex)]);
else if (i0 <= ex1-3 && (i0-1)>=iminF) // 4th centered
f_rhs[p] += sfx * d12dx * (
fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]
+EIT*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]-fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]);
else if (i0 <= ex1-2 && i0>=iminF) // 2nd centered
f_rhs[p] += sfx * d2dx * (
-fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]);
} else if (sfx < ZEO) {
if ((i0-4)>=iminF && i0<=ex1-4)
f_rhs[p] -= sfx * d840dx * (
-F5*fh[idx_fh_F_ord5(iF+3,jF,kF,ex)]+F60*fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]
-F420*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]-F378*fh[idx_fh_F_ord5(iF,jF,kF,ex)]
+F1050*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]-F420*fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]
+F140*fh[idx_fh_F_ord5(iF-3,jF,kF,ex)]-F30*fh[idx_fh_F_ord5(iF-4,jF,kF,ex)]
+F3*fh[idx_fh_F_ord5(iF-5,jF,kF,ex)]);
else if ((i0-3)>=iminF && i0<=ex1-5) // 8th centered
f_rhs[p] += sfx * d840dx * (
+F3*fh[idx_fh_F_ord5(iF-4,jF,kF,ex)]-F32*fh[idx_fh_F_ord5(iF-3,jF,kF,ex)]
+F168*fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]-F672*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]
+F672*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]-F168*fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]
+F32*fh[idx_fh_F_ord5(iF+3,jF,kF,ex)]-F3*fh[idx_fh_F_ord5(iF+4,jF,kF,ex)]);
else if ((i0-2)>=iminF && i0<=ex1-4) // 6th centered
f_rhs[p] += sfx * d60dx * (
-fh[idx_fh_F_ord5(iF-3,jF,kF,ex)]+F9*fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]
-F45*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]+F45*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]
-F9*fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]+fh[idx_fh_F_ord5(iF+3,jF,kF,ex)]);
else if ((i0-1)>=iminF && i0<=ex1-3) // 4th centered
f_rhs[p] += sfx * d12dx * (
fh[idx_fh_F_ord5(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]
+EIT*fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]-fh[idx_fh_F_ord5(iF+2,jF,kF,ex)]);
else if (i0>=iminF && i0<=ex1-2) // 2nd centered
f_rhs[p] += sfx * d2dx * (
-fh[idx_fh_F_ord5(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord5(iF+1,jF,kF,ex)]);
}
const double sfy = Sfy[p];
if (sfy > ZEO) {
if (j0<=ex2-6 && (j0-2)>=jminF)
f_rhs[p] += sfy * d840dy*(-F5*fh[idx_fh_F_ord5(iF,jF-3,kF,ex)]+F60*fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]-F420*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]-F378*fh[idx_fh_F_ord5(iF,jF,kF,ex)]+F1050*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-F420*fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]+F140*fh[idx_fh_F_ord5(iF,jF+3,kF,ex)]-F30*fh[idx_fh_F_ord5(iF,jF+4,kF,ex)]+F3*fh[idx_fh_F_ord5(iF,jF+5,kF,ex)]);
else if (j0<=ex2-5 && (j0-3)>=jminF)
f_rhs[p] += sfy * d840dy*(+F3*fh[idx_fh_F_ord5(iF,jF-4,kF,ex)]-F32*fh[idx_fh_F_ord5(iF,jF-3,kF,ex)]+F168*fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]-F672*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+F672*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-F168*fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]+F32*fh[idx_fh_F_ord5(iF,jF+3,kF,ex)]-F3*fh[idx_fh_F_ord5(iF,jF+4,kF,ex)]);
else if (j0<=ex2-4 && (j0-2)>=jminF)
f_rhs[p] += sfy * d60dy*(-fh[idx_fh_F_ord5(iF,jF-3,kF,ex)]+F9*fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]-F45*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+F45*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-F9*fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]+fh[idx_fh_F_ord5(iF,jF+3,kF,ex)]);
else if (j0<=ex2-3 && (j0-1)>=jminF)
f_rhs[p] += sfy * d12dy*(fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]);
else if (j0<=ex2-2 && j0>=jminF)
f_rhs[p] += sfy * d2dy*(-fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]);
} else if (sfy < ZEO) {
if ((j0-4)>=jminF && j0<=ex2-4)
f_rhs[p] -= sfy * d840dy*(-F5*fh[idx_fh_F_ord5(iF,jF+3,kF,ex)]+F60*fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]-F420*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-F378*fh[idx_fh_F_ord5(iF,jF,kF,ex)]+F1050*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]-F420*fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]+F140*fh[idx_fh_F_ord5(iF,jF-3,kF,ex)]-F30*fh[idx_fh_F_ord5(iF,jF-4,kF,ex)]+F3*fh[idx_fh_F_ord5(iF,jF-5,kF,ex)]);
else if ((j0-3)>=jminF && j0<=ex2-5)
f_rhs[p] += sfy * d840dy*(+F3*fh[idx_fh_F_ord5(iF,jF-4,kF,ex)]-F32*fh[idx_fh_F_ord5(iF,jF-3,kF,ex)]+F168*fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]-F672*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+F672*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-F168*fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]+F32*fh[idx_fh_F_ord5(iF,jF+3,kF,ex)]-F3*fh[idx_fh_F_ord5(iF,jF+4,kF,ex)]);
else if ((j0-2)>=jminF && j0<=ex2-4)
f_rhs[p] += sfy * d60dy*(-fh[idx_fh_F_ord5(iF,jF-3,kF,ex)]+F9*fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]-F45*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+F45*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-F9*fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]+fh[idx_fh_F_ord5(iF,jF+3,kF,ex)]);
else if ((j0-1)>=jminF && j0<=ex2-3)
f_rhs[p] += sfy * d12dy*(fh[idx_fh_F_ord5(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]-fh[idx_fh_F_ord5(iF,jF+2,kF,ex)]);
else if (j0>=jminF && j0<=ex2-2)
f_rhs[p] += sfy * d2dy*(-fh[idx_fh_F_ord5(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord5(iF,jF+1,kF,ex)]);
}
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0<=ex3-6 && (k0-2)>=kminF)
f_rhs[p] += sfz * d840dz*(-F5*fh[idx_fh_F_ord5(iF,jF,kF-3,ex)]+F60*fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]-F420*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]-F378*fh[idx_fh_F_ord5(iF,jF,kF,ex)]+F1050*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-F420*fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]+F140*fh[idx_fh_F_ord5(iF,jF,kF+3,ex)]-F30*fh[idx_fh_F_ord5(iF,jF,kF+4,ex)]+F3*fh[idx_fh_F_ord5(iF,jF,kF+5,ex)]);
else if (k0<=ex3-5 && (k0-3)>=kminF)
f_rhs[p] += sfz * d840dz*(+F3*fh[idx_fh_F_ord5(iF,jF,kF-4,ex)]-F32*fh[idx_fh_F_ord5(iF,jF,kF-3,ex)]+F168*fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]-F672*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+F672*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-F168*fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]+F32*fh[idx_fh_F_ord5(iF,jF,kF+3,ex)]-F3*fh[idx_fh_F_ord5(iF,jF,kF+4,ex)]);
else if (k0<=ex3-4 && (k0-2)>=kminF)
f_rhs[p] += sfz * d60dz*(-fh[idx_fh_F_ord5(iF,jF,kF-3,ex)]+F9*fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]-F45*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+F45*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-F9*fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]+fh[idx_fh_F_ord5(iF,jF,kF+3,ex)]);
else if (k0<=ex3-3 && (k0-1)>=kminF)
f_rhs[p] += sfz * d12dz*(fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]);
else if (k0<=ex3-2 && k0>=kminF)
f_rhs[p] += sfz * d2dz*(-fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]);
} else if (sfz < ZEO) {
if ((k0-4)>=kminF && k0<=ex3-4)
f_rhs[p] -= sfz * d840dz*(-F5*fh[idx_fh_F_ord5(iF,jF,kF+3,ex)]+F60*fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]-F420*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-F378*fh[idx_fh_F_ord5(iF,jF,kF,ex)]+F1050*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]-F420*fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]+F140*fh[idx_fh_F_ord5(iF,jF,kF-3,ex)]-F30*fh[idx_fh_F_ord5(iF,jF,kF-4,ex)]+F3*fh[idx_fh_F_ord5(iF,jF,kF-5,ex)]);
else if ((k0-3)>=kminF && k0<=ex3-5)
f_rhs[p] += sfz * d840dz*(+F3*fh[idx_fh_F_ord5(iF,jF,kF-4,ex)]-F32*fh[idx_fh_F_ord5(iF,jF,kF-3,ex)]+F168*fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]-F672*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+F672*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-F168*fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]+F32*fh[idx_fh_F_ord5(iF,jF,kF+3,ex)]-F3*fh[idx_fh_F_ord5(iF,jF,kF+4,ex)]);
else if ((k0-2)>=kminF && k0<=ex3-4)
f_rhs[p] += sfz * d60dz*(-fh[idx_fh_F_ord5(iF,jF,kF-3,ex)]+F9*fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]-F45*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+F45*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-F9*fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]+fh[idx_fh_F_ord5(iF,jF,kF+3,ex)]);
else if ((k0-1)>=kminF && k0<=ex3-3)
f_rhs[p] += sfz * d12dz*(fh[idx_fh_F_ord5(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]-fh[idx_fh_F_ord5(iF,jF,kF+2,ex)]);
else if (k0>=kminF && k0<=ex3-2)
f_rhs[p] += sfz * d2dz*(-fh[idx_fh_F_ord5(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord5(iF,jF,kF+1,ex)]);
}
}
}
}
free(fh);
return;
}
#else
#error "lopsided_c.C: unsupported ghost_width (must be 2, 3, 4, or 5)"
#endif
free(fh);
}

470
AMSS_NCKU_source/lopsided_kodis_c.C
View File

@@ -1,17 +1,8 @@
#include "macrodef.h"
#include "tool.h"
/*
* C 版 lopsided_kodis — combined upwind advection + KO dissipation.
* Uses one shared symmetry_bd buffer (ord = ghost_width for both components)
* where a stable merged stencil is available. The 8th-order path delegates to
* the separate lopsided + kodis kernels, matching the original Fortran flow.
*
* FD order selection via ghost_width:
* 2 → 2nd-order advection + r=2 KO (cof=16, sign=-)
* 3 → 4th-order advection + r=3 KO (cof=64, sign=+)
* 4 → 6th-order advection + r=4 KO (cof=256, sign=-)
* 5 → 8th-order advection + r=5 KO (cof=1024, sign=+)
* Combined advection (lopsided) + KO dissipation (kodis).
* Uses one shared symmetry_bd buffer per call.
*/
void lopsided_kodis(const int ex[3],
const double *X, const double *Y, const double *Z,
@@ -19,286 +10,239 @@ void lopsided_kodis(const int ex[3],
const double *Sfx, const double *Sfy, const double *Sfz,
int Symmetry, const double SoA[3], double eps)
{
const double ZEO = 0.0, ONE = 1.0;
const double TWO = 2.0, F6 = 6.0, EIT = 8.0;
const double F3 = 3.0, F4 = 4.0, F5 = 5.0, F10 = 10.0, F12 = 12.0, F18 = 18.0;
const double F9 = 9.0, F45 = 45.0, F60 = 60.0;
const double F2 = 2.0, F15 = 15.0, F24 = 24.0, F30 = 30.0, F35 = 35.0;
const double F50 = 50.0, F77 = 77.0, F80 = 80.0, F100 = 100.0, F150 = 150.0;
const double F32 = 32.0, F168 = 168.0, F672 = 672.0, F840 = 840.0;
const double F140=140.0, F378=378.0, F420=420.0, F1050=1050.0;
const double ZEO = 0.0, ONE = 1.0, F3 = 3.0;
const double F6 = 6.0, F18 = 18.0;
const double F12 = 12.0, F10 = 10.0, EIT = 8.0;
const double SIX = 6.0, FIT = 15.0, TWT = 20.0;
const double cof = 64.0; // 2^6
const int NO_SYMM = 0, EQ_SYMM = 1;
const int ex1 = ex[0], ex2 = ex[1], ex3 = ex[2];
const double dX = X[1] - X[0];
const double dY = Y[1] - Y[0];
const double dZ = Z[1] - Z[0];
const int imaxF = ex1, jmaxF = ex2, kmaxF = ex3;
const double d12dx = ONE / F12 / dX;
const double d12dy = ONE / F12 / dY;
const double d12dz = ONE / F12 / dZ;
#if (ghost_width == 2)
{
const int ord = 2;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -1;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -1;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -1;
const int imaxF = ex1;
const int jmaxF = ex2;
const int kmaxF = ex3;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
double *fh = (double*)malloc(nx*ny*nz*sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -2;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -2;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -2;
const double d2dx = ONE/TWO/dX, d2dy = ONE/TWO/dY, d2dz = ONE/TWO/dZ;
// fh for Fortran-style domain (-2:ex1,-2:ex2,-2:ex3)
const size_t nx = (size_t)ex1 + 3;
const size_t ny = (size_t)ex2 + 3;
const size_t nz = (size_t)ex3 + 3;
const size_t fh_size = nx * ny * nz;
/* ---- advection (2nd-order) ---- */
for (int k0 = 0; k0 <= ex3-2; ++k0) {
const int kF = k0+1;
for (int j0 = 0; j0 <= ex2-2; ++j0) {
const int jF = j0+1;
for (int i0 = 0; i0 <= ex1-2; ++i0) {
const int iF = i0+1;
const size_t p = idx_ex(i0,j0,k0,ex);
double *fh = (double*)malloc(fh_size * sizeof(double));
if (!fh) return;
const double sfx = Sfx[p];
if (sfx > ZEO) {
if (i0<=ex1-3) f_rhs[p] += sfx*d2dx*(-F3*fh[idx_fh_F_ord2(iF,jF,kF,ex)]+F4*fh[idx_fh_F_ord2(iF+1,jF,kF,ex)]-fh[idx_fh_F_ord2(iF+2,jF,kF,ex)]);
else if (i0<=ex1-2) f_rhs[p] += sfx*d2dx*(-fh[idx_fh_F_ord2(iF,jF,kF,ex)]+fh[idx_fh_F_ord2(iF+1,jF,kF,ex)]);
} else if (sfx < ZEO) {
if ((i0-1)>=iminF) f_rhs[p] -= sfx*d2dx*(-F3*fh[idx_fh_F_ord2(iF,jF,kF,ex)]+F4*fh[idx_fh_F_ord2(iF-1,jF,kF,ex)]-fh[idx_fh_F_ord2(iF-2,jF,kF,ex)]);
else if (i0>=iminF) f_rhs[p] -= sfx*d2dx*(-fh[idx_fh_F_ord2(iF,jF,kF,ex)]+fh[idx_fh_F_ord2(iF-1,jF,kF,ex)]);
symmetry_bd(3, ex, f, fh, SoA);
// Advection (same stencil logic as lopsided_c.C)
for (int k0 = 0; k0 <= ex3 - 2; ++k0) {
const int kF = k0 + 1;
for (int j0 = 0; j0 <= ex2 - 2; ++j0) {
const int jF = j0 + 1;
for (int i0 = 0; i0 <= ex1 - 2; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
const double sfx = Sfx[p];
if (sfx > ZEO) {
if (i0 <= ex1 - 4) {
f_rhs[p] += sfx * d12dx *
(-F3 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF + 2, jF, kF, ex)]
+ fh[idx_fh_F(iF + 3, jF, kF, ex)]);
} else if (i0 <= ex1 - 3) {
f_rhs[p] += sfx * d12dx *
( fh[idx_fh_F(iF - 2, jF, kF, ex)]
-EIT * fh[idx_fh_F(iF - 1, jF, kF, ex)]
+EIT * fh[idx_fh_F(iF + 1, jF, kF, ex)]
- fh[idx_fh_F(iF + 2, jF, kF, ex)]);
} else if (i0 <= ex1 - 2) {
f_rhs[p] -= sfx * d12dx *
(-F3 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF - 2, jF, kF, ex)]
+ fh[idx_fh_F(iF - 3, jF, kF, ex)]);
}
const double sfy = Sfy[p];
if (sfy > ZEO) {
if (j0<=ex2-3) f_rhs[p] += sfy*d2dy*(-F3*fh[idx_fh_F_ord2(iF,jF,kF,ex)]+F4*fh[idx_fh_F_ord2(iF,jF+1,kF,ex)]-fh[idx_fh_F_ord2(iF,jF+2,kF,ex)]);
else if (j0<=ex2-2) f_rhs[p] += sfy*d2dy*(-fh[idx_fh_F_ord2(iF,jF,kF,ex)]+fh[idx_fh_F_ord2(iF,jF+1,kF,ex)]);
} else if (sfy < ZEO) {
if ((j0-1)>=jminF) f_rhs[p] -= sfy*d2dy*(-F3*fh[idx_fh_F_ord2(iF,jF,kF,ex)]+F4*fh[idx_fh_F_ord2(iF,jF-1,kF,ex)]-fh[idx_fh_F_ord2(iF,jF-2,kF,ex)]);
else if (j0>=jminF) f_rhs[p] -= sfy*d2dy*(-fh[idx_fh_F_ord2(iF,jF,kF,ex)]+fh[idx_fh_F_ord2(iF,jF-1,kF,ex)]);
} else if (sfx < ZEO) {
if ((i0 - 2) >= iminF) {
f_rhs[p] -= sfx * d12dx *
(-F3 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF - 2, jF, kF, ex)]
+ fh[idx_fh_F(iF - 3, jF, kF, ex)]);
} else if ((i0 - 1) >= iminF) {
f_rhs[p] += sfx * d12dx *
( fh[idx_fh_F(iF - 2, jF, kF, ex)]
-EIT * fh[idx_fh_F(iF - 1, jF, kF, ex)]
+EIT * fh[idx_fh_F(iF + 1, jF, kF, ex)]
- fh[idx_fh_F(iF + 2, jF, kF, ex)]);
} else if (i0 >= iminF) {
f_rhs[p] += sfx * d12dx *
(-F3 * fh[idx_fh_F(iF - 1, jF, kF, ex)]
-F10 * fh[idx_fh_F(iF , jF, kF, ex)]
+F18 * fh[idx_fh_F(iF + 1, jF, kF, ex)]
-F6 * fh[idx_fh_F(iF + 2, jF, kF, ex)]
+ fh[idx_fh_F(iF + 3, jF, kF, ex)]);
}
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0<=ex3-3) f_rhs[p] += sfz*d2dz*(-F3*fh[idx_fh_F_ord2(iF,jF,kF,ex)]+F4*fh[idx_fh_F_ord2(iF,jF,kF+1,ex)]-fh[idx_fh_F_ord2(iF,jF,kF+2,ex)]);
else if (k0<=ex3-2) f_rhs[p] += sfz*d2dz*(-fh[idx_fh_F_ord2(iF,jF,kF,ex)]+fh[idx_fh_F_ord2(iF,jF,kF+1,ex)]);
} else if (sfz < ZEO) {
if ((k0-1)>=kminF) f_rhs[p] -= sfz*d2dz*(-F3*fh[idx_fh_F_ord2(iF,jF,kF,ex)]+F4*fh[idx_fh_F_ord2(iF,jF,kF-1,ex)]-fh[idx_fh_F_ord2(iF,jF,kF-2,ex)]);
else if (k0>=kminF) f_rhs[p] -= sfz*d2dz*(-fh[idx_fh_F_ord2(iF,jF,kF,ex)]+fh[idx_fh_F_ord2(iF,jF,kF-1,ex)]);
}
const double sfy = Sfy[p];
if (sfy > ZEO) {
if (j0 <= ex2 - 4) {
f_rhs[p] += sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF + 2, kF, ex)]
+ fh[idx_fh_F(iF, jF + 3, kF, ex)]);
} else if (j0 <= ex2 - 3) {
f_rhs[p] += sfy * d12dy *
( fh[idx_fh_F(iF, jF - 2, kF, ex)]
-EIT * fh[idx_fh_F(iF, jF - 1, kF, ex)]
+EIT * fh[idx_fh_F(iF, jF + 1, kF, ex)]
- fh[idx_fh_F(iF, jF + 2, kF, ex)]);
} else if (j0 <= ex2 - 2) {
f_rhs[p] -= sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF - 2, kF, ex)]
+ fh[idx_fh_F(iF, jF - 3, kF, ex)]);
}
} else if (sfy < ZEO) {
if ((j0 - 2) >= jminF) {
f_rhs[p] -= sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF - 2, kF, ex)]
+ fh[idx_fh_F(iF, jF - 3, kF, ex)]);
} else if ((j0 - 1) >= jminF) {
f_rhs[p] += sfy * d12dy *
( fh[idx_fh_F(iF, jF - 2, kF, ex)]
-EIT * fh[idx_fh_F(iF, jF - 1, kF, ex)]
+EIT * fh[idx_fh_F(iF, jF + 1, kF, ex)]
- fh[idx_fh_F(iF, jF + 2, kF, ex)]);
} else if (j0 >= jminF) {
f_rhs[p] += sfy * d12dy *
(-F3 * fh[idx_fh_F(iF, jF - 1, kF, ex)]
-F10 * fh[idx_fh_F(iF, jF , kF, ex)]
+F18 * fh[idx_fh_F(iF, jF + 1, kF, ex)]
-F6 * fh[idx_fh_F(iF, jF + 2, kF, ex)]
+ fh[idx_fh_F(iF, jF + 3, kF, ex)]);
}
}
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0 <= ex3 - 4) {
f_rhs[p] += sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF + 2, ex)]
+ fh[idx_fh_F(iF, jF, kF + 3, ex)]);
} else if (k0 <= ex3 - 3) {
f_rhs[p] += sfz * d12dz *
( fh[idx_fh_F(iF, jF, kF - 2, ex)]
-EIT * fh[idx_fh_F(iF, jF, kF - 1, ex)]
+EIT * fh[idx_fh_F(iF, jF, kF + 1, ex)]
- fh[idx_fh_F(iF, jF, kF + 2, ex)]);
} else if (k0 <= ex3 - 2) {
f_rhs[p] -= sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF - 2, ex)]
+ fh[idx_fh_F(iF, jF, kF - 3, ex)]);
}
} else if (sfz < ZEO) {
if ((k0 - 2) >= kminF) {
f_rhs[p] -= sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF - 2, ex)]
+ fh[idx_fh_F(iF, jF, kF - 3, ex)]);
} else if ((k0 - 1) >= kminF) {
f_rhs[p] += sfz * d12dz *
( fh[idx_fh_F(iF, jF, kF - 2, ex)]
-EIT * fh[idx_fh_F(iF, jF, kF - 1, ex)]
+EIT * fh[idx_fh_F(iF, jF, kF + 1, ex)]
- fh[idx_fh_F(iF, jF, kF + 2, ex)]);
} else if (k0 >= kminF) {
f_rhs[p] += sfz * d12dz *
(-F3 * fh[idx_fh_F(iF, jF, kF - 1, ex)]
-F10 * fh[idx_fh_F(iF, jF, kF , ex)]
+F18 * fh[idx_fh_F(iF, jF, kF + 1, ex)]
-F6 * fh[idx_fh_F(iF, jF, kF + 2, ex)]
+ fh[idx_fh_F(iF, jF, kF + 3, ex)]);
}
}
}
}
/* ---- KO dissipation (r=2, cof=16, sign=-) ---- */
if (eps > ZEO) {
const double cof = 16.0;
const double F4k = 4.0, F6k = 6.0;
const int i0_lo = (iminF+1>0)?iminF+1:0, j0_lo=(jminF+1>0)?jminF+1:0, k0_lo=(kminF+1>0)?kminF+1:0;
const int i0_hi=imaxF-3, j0_hi=jmaxF-3, k0_hi=kmaxF-3;
if (!(i0_lo>i0_hi||j0_lo>j0_hi||k0_lo>k0_hi)) {
for (int k0=k0_lo;k0<=k0_hi;++k0) { const int kF=k0+1;
for (int j0=j0_lo;j0<=j0_hi;++j0) { const int jF=j0+1;
for (int i0=i0_lo;i0<=i0_hi;++i0) { const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
const double Dx=((fh[idx_fh_F_ord2(iF-2,jF,kF,ex)]+fh[idx_fh_F_ord2(iF+2,jF,kF,ex)])-F4k*(fh[idx_fh_F_ord2(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord2(iF+1,jF,kF,ex)])+F6k*fh[idx_fh_F_ord2(iF,jF,kF,ex)])/dX;
const double Dy=((fh[idx_fh_F_ord2(iF,jF-2,kF,ex)]+fh[idx_fh_F_ord2(iF,jF+2,kF,ex)])-F4k*(fh[idx_fh_F_ord2(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord2(iF,jF+1,kF,ex)])+F6k*fh[idx_fh_F_ord2(iF,jF,kF,ex)])/dY;
const double Dz=((fh[idx_fh_F_ord2(iF,jF,kF-2,ex)]+fh[idx_fh_F_ord2(iF,jF,kF+2,ex)])-F4k*(fh[idx_fh_F_ord2(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord2(iF,jF,kF+1,ex)])+F6k*fh[idx_fh_F_ord2(iF,jF,kF,ex)])/dZ;
f_rhs[p] -= (eps/cof)*(Dx+Dy+Dz);
}}}
}
}
free(fh);
return;
}
#elif (ghost_width == 3)
/* ---- 4th-order advection + r=3 KO (original code) ----------------- */
{
const int ord = 3;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -2;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -2;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -2;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
double *fh = (double*)malloc(nx*ny*nz*sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
// KO dissipation (same domain restriction as kodiss_c.C)
if (eps > ZEO) {
const int i0_lo = (iminF + 2 > 0) ? iminF + 2 : 0;
const int j0_lo = (jminF + 2 > 0) ? jminF + 2 : 0;
const int k0_lo = (kminF + 2 > 0) ? kminF + 2 : 0;
const int i0_hi = imaxF - 4; // inclusive
const int j0_hi = jmaxF - 4;
const int k0_hi = kmaxF - 4;
const double d12dx = ONE/F12/dX, d12dy = ONE/F12/dY, d12dz = ONE/F12/dZ;
if (!(i0_lo > i0_hi || j0_lo > j0_hi || k0_lo > k0_hi)) {
for (int k0 = k0_lo; k0 <= k0_hi; ++k0) {
const int kF = k0 + 1;
for (int j0 = j0_lo; j0 <= j0_hi; ++j0) {
const int jF = j0 + 1;
for (int i0 = i0_lo; i0 <= i0_hi; ++i0) {
const int iF = i0 + 1;
const size_t p = idx_ex(i0, j0, k0, ex);
/* ---- advection ---- */
for (int k0 = 0; k0 <= ex3-2; ++k0) {
const int kF = k0+1;
for (int j0 = 0; j0 <= ex2-2; ++j0) {
const int jF = j0+1;
for (int i0 = 0; i0 <= ex1-2; ++i0) {
const int iF = i0+1;
const size_t p = idx_ex(i0,j0,k0,ex);
const double Dx_term =
((fh[idx_fh_F(iF - 3, jF, kF, ex)] + fh[idx_fh_F(iF + 3, jF, kF, ex)]) -
SIX * (fh[idx_fh_F(iF - 2, jF, kF, ex)] + fh[idx_fh_F(iF + 2, jF, kF, ex)]) +
FIT * (fh[idx_fh_F(iF - 1, jF, kF, ex)] + fh[idx_fh_F(iF + 1, jF, kF, ex)]) -
TWT * fh[idx_fh_F(iF, jF, kF, ex)]) / dX;
const double sfx = Sfx[p];
if (sfx > ZEO) {
if (i0 <= ex1-4)
f_rhs[p] += sfx*d12dx*(-F3*fh[idx_fh_F(iF-1,jF,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF+1,jF,kF,ex)]-F6*fh[idx_fh_F(iF+2,jF,kF,ex)]+fh[idx_fh_F(iF+3,jF,kF,ex)]);
else if (i0 <= ex1-3)
f_rhs[p] += sfx*d12dx*(fh[idx_fh_F(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F(iF-1,jF,kF,ex)]+EIT*fh[idx_fh_F(iF+1,jF,kF,ex)]-fh[idx_fh_F(iF+2,jF,kF,ex)]);
else if (i0 <= ex1-2)
f_rhs[p] -= sfx*d12dx*(-F3*fh[idx_fh_F(iF+1,jF,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF-1,jF,kF,ex)]-F6*fh[idx_fh_F(iF-2,jF,kF,ex)]+fh[idx_fh_F(iF-3,jF,kF,ex)]);
} else if (sfx < ZEO) {
if ((i0-2) >= iminF)
f_rhs[p] -= sfx*d12dx*(-F3*fh[idx_fh_F(iF+1,jF,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF-1,jF,kF,ex)]-F6*fh[idx_fh_F(iF-2,jF,kF,ex)]+fh[idx_fh_F(iF-3,jF,kF,ex)]);
else if ((i0-1) >= iminF)
f_rhs[p] += sfx*d12dx*(fh[idx_fh_F(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F(iF-1,jF,kF,ex)]+EIT*fh[idx_fh_F(iF+1,jF,kF,ex)]-fh[idx_fh_F(iF+2,jF,kF,ex)]);
else if (i0 >= iminF)
f_rhs[p] += sfx*d12dx*(-F3*fh[idx_fh_F(iF-1,jF,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF+1,jF,kF,ex)]-F6*fh[idx_fh_F(iF+2,jF,kF,ex)]+fh[idx_fh_F(iF+3,jF,kF,ex)]);
}
const double sfy = Sfy[p];
if (sfy > ZEO) {
if (j0<=ex2-4) f_rhs[p] += sfy*d12dy*(-F3*fh[idx_fh_F(iF,jF-1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF+1,kF,ex)]-F6*fh[idx_fh_F(iF,jF+2,kF,ex)]+fh[idx_fh_F(iF,jF+3,kF,ex)]);
else if (j0<=ex2-3) f_rhs[p] += sfy*d12dy*(fh[idx_fh_F(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F(iF,jF+1,kF,ex)]-fh[idx_fh_F(iF,jF+2,kF,ex)]);
else if (j0<=ex2-2) f_rhs[p] -= sfy*d12dy*(-F3*fh[idx_fh_F(iF,jF+1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF-1,kF,ex)]-F6*fh[idx_fh_F(iF,jF-2,kF,ex)]+fh[idx_fh_F(iF,jF-3,kF,ex)]);
} else if (sfy < ZEO) {
if ((j0-2)>=jminF) f_rhs[p] -= sfy*d12dy*(-F3*fh[idx_fh_F(iF,jF+1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF-1,kF,ex)]-F6*fh[idx_fh_F(iF,jF-2,kF,ex)]+fh[idx_fh_F(iF,jF-3,kF,ex)]);
else if ((j0-1)>=jminF) f_rhs[p] += sfy*d12dy*(fh[idx_fh_F(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F(iF,jF+1,kF,ex)]-fh[idx_fh_F(iF,jF+2,kF,ex)]);
else if (j0>=jminF) f_rhs[p] += sfy*d12dy*(-F3*fh[idx_fh_F(iF,jF-1,kF,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF+1,kF,ex)]-F6*fh[idx_fh_F(iF,jF+2,kF,ex)]+fh[idx_fh_F(iF,jF+3,kF,ex)]);
}
const double sfz = Sfz[p];
if (sfz > ZEO) {
if (k0<=ex3-4) f_rhs[p] += sfz*d12dz*(-F3*fh[idx_fh_F(iF,jF,kF-1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF,kF+1,ex)]-F6*fh[idx_fh_F(iF,jF,kF+2,ex)]+fh[idx_fh_F(iF,jF,kF+3,ex)]);
else if (k0<=ex3-3) f_rhs[p] += sfz*d12dz*(fh[idx_fh_F(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F(iF,jF,kF+1,ex)]-fh[idx_fh_F(iF,jF,kF+2,ex)]);
else if (k0<=ex3-2) f_rhs[p] -= sfz*d12dz*(-F3*fh[idx_fh_F(iF,jF,kF+1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF,kF-1,ex)]-F6*fh[idx_fh_F(iF,jF,kF-2,ex)]+fh[idx_fh_F(iF,jF,kF-3,ex)]);
} else if (sfz < ZEO) {
if ((k0-2)>=kminF) f_rhs[p] -= sfz*d12dz*(-F3*fh[idx_fh_F(iF,jF,kF+1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF,kF-1,ex)]-F6*fh[idx_fh_F(iF,jF,kF-2,ex)]+fh[idx_fh_F(iF,jF,kF-3,ex)]);
else if ((k0-1)>=kminF) f_rhs[p] += sfz*d12dz*(fh[idx_fh_F(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F(iF,jF,kF+1,ex)]-fh[idx_fh_F(iF,jF,kF+2,ex)]);
else if (k0>=kminF) f_rhs[p] += sfz*d12dz*(-F3*fh[idx_fh_F(iF,jF,kF-1,ex)]-F10*fh[idx_fh_F(iF,jF,kF,ex)]+F18*fh[idx_fh_F(iF,jF,kF+1,ex)]-F6*fh[idx_fh_F(iF,jF,kF+2,ex)]+fh[idx_fh_F(iF,jF,kF+3,ex)]);
const double Dy_term =
((fh[idx_fh_F(iF, jF - 3, kF, ex)] + fh[idx_fh_F(iF, jF + 3, kF, ex)]) -
SIX * (fh[idx_fh_F(iF, jF - 2, kF, ex)] + fh[idx_fh_F(iF, jF + 2, kF, ex)]) +
FIT * (fh[idx_fh_F(iF, jF - 1, kF, ex)] + fh[idx_fh_F(iF, jF + 1, kF, ex)]) -
TWT * fh[idx_fh_F(iF, jF, kF, ex)]) / dY;
const double Dz_term =
((fh[idx_fh_F(iF, jF, kF - 3, ex)] + fh[idx_fh_F(iF, jF, kF + 3, ex)]) -
SIX * (fh[idx_fh_F(iF, jF, kF - 2, ex)] + fh[idx_fh_F(iF, jF, kF + 2, ex)]) +
FIT * (fh[idx_fh_F(iF, jF, kF - 1, ex)] + fh[idx_fh_F(iF, jF, kF + 1, ex)]) -
TWT * fh[idx_fh_F(iF, jF, kF, ex)]) / dZ;
f_rhs[p] += (eps / cof) * (Dx_term + Dy_term + Dz_term);
}
}
}
}
/* ---- KO dissipation (r=3, cof=64, sign=+) ---- */
if (eps > ZEO) {
const double cof = 64.0;
const double SIX = 6.0, FIT = 15.0, TWT = 20.0;
const int i0_lo=(iminF+2>0)?iminF+2:0, j0_lo=(jminF+2>0)?jminF+2:0, k0_lo=(kminF+2>0)?kminF+2:0;
const int i0_hi=imaxF-4, j0_hi=jmaxF-4, k0_hi=kmaxF-4;
if (!(i0_lo>i0_hi||j0_lo>j0_hi||k0_lo>k0_hi)) {
for (int k0=k0_lo;k0<=k0_hi;++k0) { const int kF=k0+1;
for (int j0=j0_lo;j0<=j0_hi;++j0) { const int jF=j0+1;
for (int i0=i0_lo;i0<=i0_hi;++i0) { const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
const double Dx=((fh[idx_fh_F(iF-3,jF,kF,ex)]+fh[idx_fh_F(iF+3,jF,kF,ex)])-SIX*(fh[idx_fh_F(iF-2,jF,kF,ex)]+fh[idx_fh_F(iF+2,jF,kF,ex)])+FIT*(fh[idx_fh_F(iF-1,jF,kF,ex)]+fh[idx_fh_F(iF+1,jF,kF,ex)])-TWT*fh[idx_fh_F(iF,jF,kF,ex)])/dX;
const double Dy=((fh[idx_fh_F(iF,jF-3,kF,ex)]+fh[idx_fh_F(iF,jF+3,kF,ex)])-SIX*(fh[idx_fh_F(iF,jF-2,kF,ex)]+fh[idx_fh_F(iF,jF+2,kF,ex)])+FIT*(fh[idx_fh_F(iF,jF-1,kF,ex)]+fh[idx_fh_F(iF,jF+1,kF,ex)])-TWT*fh[idx_fh_F(iF,jF,kF,ex)])/dY;
const double Dz=((fh[idx_fh_F(iF,jF,kF-3,ex)]+fh[idx_fh_F(iF,jF,kF+3,ex)])-SIX*(fh[idx_fh_F(iF,jF,kF-2,ex)]+fh[idx_fh_F(iF,jF,kF+2,ex)])+FIT*(fh[idx_fh_F(iF,jF,kF-1,ex)]+fh[idx_fh_F(iF,jF,kF+1,ex)])-TWT*fh[idx_fh_F(iF,jF,kF,ex)])/dZ;
f_rhs[p] += (eps/cof)*(Dx+Dy+Dz);
}}}
}
}
free(fh);
return;
}
#elif (ghost_width == 4)
{
const int ord = 4;
int iminF = 1, jminF = 1, kminF = 1;
if (Symmetry > NO_SYMM && fabs(Z[0]) < dZ) kminF = -3;
if (Symmetry > EQ_SYMM && fabs(X[0]) < dX) iminF = -3;
if (Symmetry > EQ_SYMM && fabs(Y[0]) < dY) jminF = -3;
const size_t nx = (size_t)ex1 + ord;
const size_t ny = (size_t)ex2 + ord;
const size_t nz = (size_t)ex3 + ord;
double *fh = (double*)malloc(nx*ny*nz*sizeof(double));
if (!fh) return;
symmetry_bd(ord, ex, f, fh, SoA);
const double d60dx=ONE/F60/dX, d60dy=ONE/F60/dY, d60dz=ONE/F60/dZ;
const double d12dx=ONE/F12/dX, d12dy=ONE/F12/dY, d12dz=ONE/F12/dZ;
const double d2dx=ONE/TWO/dX, d2dy=ONE/TWO/dY, d2dz=ONE/TWO/dZ;
/* ---- advection (6th-order lopsided) ---- */
for (int k0=0;k0<=ex3-2;++k0) { const int kF=k0+1;
for (int j0=0;j0<=ex2-2;++j0) { const int jF=j0+1;
for (int i0=0;i0<=ex1-2;++i0) { const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
/* x */
const double sfx=Sfx[p];
if (sfx>ZEO) {
if (i0<=ex1-5&&(i0-1)>=iminF) f_rhs[p]+=sfx*d60dx*(+F2*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-F24*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F30*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]-fh[idx_fh_F_ord4(iF+4,jF,kF,ex)]);
else if (i0<=ex1-6&&i0>=iminF) f_rhs[p]+=sfx*d60dx*(-F10*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F100*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]+F50*fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]-F15*fh[idx_fh_F_ord4(iF+4,jF,kF,ex)]+F2*fh[idx_fh_F_ord4(iF+5,jF,kF,ex)]);
else if (i0<=ex1-4&&(i0-2)>=iminF) f_rhs[p]+=sfx*d60dx*(-fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]+F9*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-F45*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+F45*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F9*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]);
else if (i0<=ex1-3&&(i0-1)>=iminF) f_rhs[p]+=sfx*d12dx*(fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]);
else if (i0<=ex1-2&&i0>=iminF) f_rhs[p]+=sfx*d2dx*(-fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]);
} else if (sfx<ZEO) {
if ((i0-3)>=iminF&&i0<=ex1-3) f_rhs[p]-=sfx*d60dx*(+F2*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]-F24*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]-F30*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]-fh[idx_fh_F_ord4(iF-4,jF,kF,ex)]);
else if ((i0-4)>=iminF&&i0<=ex1-2) f_rhs[p]-=sfx*d60dx*(-F10*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]-F100*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]+F50*fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]-F15*fh[idx_fh_F_ord4(iF-4,jF,kF,ex)]+F2*fh[idx_fh_F_ord4(iF-5,jF,kF,ex)]);
else if ((i0-2)>=iminF&&i0<=ex1-4) f_rhs[p]+=sfx*d60dx*(-fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]+F9*fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-F45*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+F45*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-F9*fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+3,jF,kF,ex)]);
else if ((i0-1)>=iminF&&i0<=ex1-3) f_rhs[p]+=sfx*d12dx*(fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]-fh[idx_fh_F_ord4(iF+2,jF,kF,ex)]);
else if (i0>=iminF&&i0<=ex1-2) f_rhs[p]+=sfx*d2dx*(-fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+1,jF,kF,ex)]);
}
/* y */
const double sfy=Sfy[p];
if (sfy>ZEO) {
if (j0<=ex2-5&&(j0-1)>=jminF) f_rhs[p]+=sfy*d60dy*(F2*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-F24*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F30*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]-fh[idx_fh_F_ord4(iF,jF+4,kF,ex)]);
else if (j0<=ex2-6&&j0>=jminF) f_rhs[p]+=sfy*d60dy*(-F10*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F100*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+F50*fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]-F15*fh[idx_fh_F_ord4(iF,jF+4,kF,ex)]+F2*fh[idx_fh_F_ord4(iF,jF+5,kF,ex)]);
else if (j0<=ex2-4&&(j0-2)>=jminF) f_rhs[p]+=sfy*d60dy*(-fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]+F9*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-F45*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+F45*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F9*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]);
else if (j0<=ex2-3&&(j0-1)>=jminF) f_rhs[p]+=sfy*d12dy*(fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]);
else if (j0<=ex2-2&&j0>=jminF) f_rhs[p]+=sfy*d2dy*(-fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]);
} else if (sfy<ZEO) {
if ((j0-3)>=jminF&&j0<=ex2-3) f_rhs[p]-=sfy*d60dy*(F2*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]-F24*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F30*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]-fh[idx_fh_F_ord4(iF,jF-4,kF,ex)]);
else if ((j0-4)>=jminF&&j0<=ex2-2) f_rhs[p]-=sfy*d60dy*(-F10*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]-F100*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]+F50*fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]-F15*fh[idx_fh_F_ord4(iF,jF-4,kF,ex)]+F2*fh[idx_fh_F_ord4(iF,jF-5,kF,ex)]);
else if ((j0-2)>=jminF&&j0<=ex2-4) f_rhs[p]+=sfy*d60dy*(-fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]+F9*fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-F45*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+F45*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-F9*fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+3,kF,ex)]);
else if ((j0-1)>=jminF&&j0<=ex2-3) f_rhs[p]+=sfy*d12dy*(fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]-fh[idx_fh_F_ord4(iF,jF+2,kF,ex)]);
else if (j0>=jminF&&j0<=ex2-2) f_rhs[p]+=sfy*d2dy*(-fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+1,kF,ex)]);
}
/* z */
const double sfz=Sfz[p];
if (sfz>ZEO) {
if (k0<=ex3-5&&(k0-1)>=kminF) f_rhs[p]+=sfz*d60dz*(F2*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-F24*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F30*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]-fh[idx_fh_F_ord4(iF,jF,kF+4,ex)]);
else if (k0<=ex3-6&&k0>=kminF) f_rhs[p]+=sfz*d60dz*(-F10*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F100*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+F50*fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]-F15*fh[idx_fh_F_ord4(iF,jF,kF+4,ex)]+F2*fh[idx_fh_F_ord4(iF,jF,kF+5,ex)]);
else if (k0<=ex3-4&&(k0-2)>=kminF) f_rhs[p]+=sfz*d60dz*(-fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]+F9*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-F45*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+F45*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F9*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]);
else if (k0<=ex3-3&&(k0-1)>=kminF) f_rhs[p]+=sfz*d12dz*(fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]);
else if (k0<=ex3-2&&k0>=kminF) f_rhs[p]+=sfz*d2dz*(-fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]);
} else if (sfz<ZEO) {
if ((k0-3)>=kminF&&k0<=ex3-3) f_rhs[p]-=sfz*d60dz*(F2*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]-F24*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F35*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F80*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F30*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]-fh[idx_fh_F_ord4(iF,jF,kF-4,ex)]);
else if ((k0-4)>=kminF&&k0<=ex3-2) f_rhs[p]-=sfz*d60dz*(-F10*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F77*fh[idx_fh_F_ord4(iF,jF,kF,ex)]+F150*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]-F100*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]+F50*fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]-F15*fh[idx_fh_F_ord4(iF,jF,kF-4,ex)]+F2*fh[idx_fh_F_ord4(iF,jF,kF-5,ex)]);
else if ((k0-2)>=kminF&&k0<=ex3-4) f_rhs[p]+=sfz*d60dz*(-fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]+F9*fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-F45*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+F45*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-F9*fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+3,ex)]);
else if ((k0-1)>=kminF&&k0<=ex3-3) f_rhs[p]+=sfz*d12dz*(fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]-EIT*fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+EIT*fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]-fh[idx_fh_F_ord4(iF,jF,kF+2,ex)]);
else if (k0>=kminF&&k0<=ex3-2) f_rhs[p]+=sfz*d2dz*(-fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+1,ex)]);
}
}}}
/* ---- KO dissipation (r=4, cof=256, sign=-) ---- */
if (eps > ZEO) {
const double cof = 256.0;
const double F8k = 8.0, F28 = 28.0, F56 = 56.0, F70 = 70.0;
const int i0_lo=(iminF+3>0)?iminF+3:0, j0_lo=(jminF+3>0)?jminF+3:0, k0_lo=(kminF+3>0)?kminF+3:0;
const int i0_hi=imaxF-5, j0_hi=jmaxF-5, k0_hi=kmaxF-5;
if (!(i0_lo>i0_hi||j0_lo>j0_hi||k0_lo>k0_hi)) {
for (int k0=k0_lo;k0<=k0_hi;++k0) { const int kF=k0+1;
for (int j0=j0_lo;j0<=j0_hi;++j0) { const int jF=j0+1;
for (int i0=i0_lo;i0<=i0_hi;++i0) { const int iF=i0+1;
const size_t p=idx_ex(i0,j0,k0,ex);
const double Dx=((fh[idx_fh_F_ord4(iF-4,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+4,jF,kF,ex)])-F8k*(fh[idx_fh_F_ord4(iF-3,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+3,jF,kF,ex)])+F28*(fh[idx_fh_F_ord4(iF-2,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+2,jF,kF,ex)])-F56*(fh[idx_fh_F_ord4(iF-1,jF,kF,ex)]+fh[idx_fh_F_ord4(iF+1,jF,kF,ex)])+F70*fh[idx_fh_F_ord4(iF,jF,kF,ex)])/dX;
const double Dy=((fh[idx_fh_F_ord4(iF,jF-4,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+4,kF,ex)])-F8k*(fh[idx_fh_F_ord4(iF,jF-3,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+3,kF,ex)])+F28*(fh[idx_fh_F_ord4(iF,jF-2,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+2,kF,ex)])-F56*(fh[idx_fh_F_ord4(iF,jF-1,kF,ex)]+fh[idx_fh_F_ord4(iF,jF+1,kF,ex)])+F70*fh[idx_fh_F_ord4(iF,jF,kF,ex)])/dY;
const double Dz=((fh[idx_fh_F_ord4(iF,jF,kF-4,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+4,ex)])-F8k*(fh[idx_fh_F_ord4(iF,jF,kF-3,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+3,ex)])+F28*(fh[idx_fh_F_ord4(iF,jF,kF-2,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+2,ex)])-F56*(fh[idx_fh_F_ord4(iF,jF,kF-1,ex)]+fh[idx_fh_F_ord4(iF,jF,kF+1,ex)])+F70*fh[idx_fh_F_ord4(iF,jF,kF,ex)])/dZ;
f_rhs[p] -= (eps/cof)*(Dx+Dy+Dz);
}}}
}
}
free(fh);
return;
}
#elif (ghost_width == 5)
{
lopsided(ex, X, Y, Z, f, f_rhs, Sfx, Sfy, Sfz, Symmetry, SoA);
if (eps > ZEO) kodis(ex, X, Y, Z, f, f_rhs, SoA, Symmetry, eps);
return;
}
#else
#error "lopsided_kodis_c.C: unsupported ghost_width (must be 2, 3, 4, or 5)"
#endif
free(fh);
}

561
AMSS_NCKU_source/makefile
View File

@@ -1,293 +1,270 @@
include makefile.inc
## polint(ordn=6) kernel selector:
## 1 (default): barycentric fast path
## 0 : fallback to Neville path
POLINT6_USE_BARY ?= 1
POLINT6_FLAG = -DPOLINT6_USE_BARYCENTRIC=$(POLINT6_USE_BARY)
## ABE build flags selected by PGO_MODE (set in makefile.inc, default: opt)
## make -> opt (PGO-guided, maximum performance)
## make PGO_MODE=instrument -> instrument (Phase 1: collect fresh profile data)
PROFDATA = /home/$(shell whoami)/AMSS-NCKU/pgo_profile/default.profdata
ifeq ($(TOOLCHAIN),intel)
OMP_FLAG = -qopenmp
ifeq ($(PGO_MODE),instrument)
## Intel Phase 1: instrumentation — omit -ipo/-fp-model fast=2 for faster build and numerical stability
CXXAPPFLAGS = -O3 -march=znver5 -fma -fprofile-instr-generate -ipo \
-Dfortran3 -Dnewc $(MKL_INC) $(INTERP_LB_FLAGS)
f90appflags = -O3 -march=znver5 -fma -fprofile-instr-generate -ipo \
-align array64byte -fpp $(MKL_INC) $(POLINT6_FLAG)
else
## opt (default): maximum performance with PGO profile data -fprofile-instr-use=$(PROFDATA) \
## PGO has been turned off, now tested and found to be negative optimization
## INTERP_LB_FLAGS has been turned off too, now tested and found to be negative optimization
CXXAPPFLAGS = -O3 -march=znver5 -fp-model fast=2 -fma -ipo \
-Dfortran3 -Dnewc $(MKL_INC) $(INTERP_LB_FLAGS)
f90appflags = -O3 -march=znver5 -fp-model fast=2 -fma -ipo \
-align array64byte -fpp $(MKL_INC) $(POLINT6_FLAG)
endif
TP_OPTFLAGS = -O3 -march=znver5 -fp-model fast=2 -fma -ipo \
-Dfortran3 -Dnewc $(MKL_INC)
else
## NVHPC defaults: mpicc/mpicxx/mpifort wrappers
## PGO_MODE is ignored in this branch.
OMP_FLAG = -mp
CXXAPPFLAGS = -O3 -march=znver5 -tp=host -Mcache_align -Mfma \
-Dfortran3 -Dnewc $(MKL_INC) $(INTERP_LB_FLAGS)
f90appflags = -O3 -march=znver5 -tp=host -Mcache_align -Mfma -Mpreprocess \
$(MKL_INC) $(POLINT6_FLAG)
TP_OPTFLAGS = -O3 -march=znver5 -tp=host -Mcache_align -Mfma \
-Dfortran3 -Dnewc $(MKL_INC)
endif
.SUFFIXES: .o .f90 .C .for .cu
.f90.o:
$(f90) $(f90appflags) -c $< -o $@
.C.o:
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
# ShellPatch.C uses OpenMP for setupintintstuff search loops
ShellPatch.o: ShellPatch.C
${CXX} $(CXXAPPFLAGS) $(OMP_FLAG) -c $< $(filein) -o $@
.for.o:
$(f77) -c $< -o $@
.cu.o:
$(Cu) $(CUDA_APP_FLAGS) -c $< -o $@ $(CUDA_LIB_PATH)
# CUDA rewrite of BSSN RHS (drop-in replacement for bssn_rhs_c + stencil helpers)
bssn_rhs_cuda.o: bssn_rhs_cuda.cu bssn_rhs.h macrodef.h fd_cuda_helpers.cuh
$(Cu) $(CUDA_APP_FLAGS) -c $< -o $@ $(CUDA_LIB_PATH)
# CUDA rewrite of BSSN Shell-Patch RHS (drop-in replacement for bssn_rhs_ss)
bssn_gpu_rhs_ss.o: bssn_gpu_rhs_ss.cu bssn_gpu.h gpu_rhsSS_mem.h bssn_macro.h macrodef.fh
$(Cu) $(CUDA_APP_FLAGS) -c $< -o $@ $(CUDA_LIB_PATH)
# CUDA rewrite of Z4C Cartesian RHS
z4c_rhs_cuda.o: z4c_rhs_cuda.cu z4c_rhs_cuda.h bssn_rhs.h macrodef.h ricci_gamma.h fd_cuda_helpers.cuh
$(Cu) $(CUDA_APP_FLAGS) -c $< -o $@ $(CUDA_LIB_PATH)
# C rewrite of BSSN RHS kernel and helpers
bssn_rhs_c.o: bssn_rhs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
fderivs_c.o: fderivs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
fdderivs_c.o: fdderivs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
kodiss_c.o: kodiss_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
lopsided_c.o: lopsided_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
lopsided_kodis_c.o: lopsided_kodis_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
z4c_rhs_c.o: z4c_rhs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
#interp_lb_profile.o: interp_lb_profile.C interp_lb_profile.h
# ${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
TwoPunctures.o: TwoPunctures.C
${CXX} $(TP_OPTFLAGS) $(OMP_FLAG) -c $< -o $@
TwoPunctureABE.o: TwoPunctureABE.C
${CXX} $(TP_OPTFLAGS) $(OMP_FLAG) -c $< -o $@
# Input files
## CUDA BSSN RHS switch
## 1 : use the rewritten CUDA bssn_rhs backend
## 0 : keep the normal CPU/Fortran selection below
USE_CUDA_BSSN ?= 0
USE_CUDA_Z4C ?= 0
AMSS_Z4C_MRBD ?= 0
include makefile.inc
-include AMSS_NCKU_build.mk
ABE_TYPE ?= $(shell awk '/^[[:space:]]*\#define[[:space:]]+ABEtype/ {print $$3; exit}' macrodef.h 2>/dev/null)
ifeq ($(USE_TRANSFER_CACHE),auto)
ifeq ($(ABE_TYPE),0)
EFFECTIVE_USE_TRANSFER_CACHE = 1
else
EFFECTIVE_USE_TRANSFER_CACHE = 0
endif
else
EFFECTIVE_USE_TRANSFER_CACHE = $(USE_TRANSFER_CACHE)
endif
ifeq ($(USE_CXX_ESCALAR_KERNEL),1)
ifeq ($(ABE_TYPE),1)
EFFECTIVE_USE_CXX_ESCALAR_KERNEL = 1
else
EFFECTIVE_USE_CXX_ESCALAR_KERNEL = 0
endif
else
EFFECTIVE_USE_CXX_ESCALAR_KERNEL = 0
endif
ifeq ($(EFFECTIVE_USE_CXX_ESCALAR_KERNEL),1)
ifeq ($(USE_CXX_KERNELS),0)
$(error USE_CXX_ESCALAR_KERNEL=1 requires USE_CXX_KERNELS=1 because bssn_escalar_rhs_c.C reuses the C BSSN kernel)
endif
endif
ifeq ($(USE_CXX_EM_KERNEL),1)
ifeq ($(ABE_TYPE),3)
EFFECTIVE_USE_CXX_EM_KERNEL = 1
else
EFFECTIVE_USE_CXX_EM_KERNEL = 0
endif
else
EFFECTIVE_USE_CXX_EM_KERNEL = 0
endif
ifeq ($(EFFECTIVE_USE_CXX_EM_KERNEL),1)
ifeq ($(USE_CXX_KERNELS),0)
$(error USE_CXX_EM_KERNEL=1 requires USE_CXX_KERNELS=1 because bssn_em_rhs_c.C reuses the C BSSN kernel)
endif
endif
EM_KERNEL_FLAG = -DBSSN_USE_EM_C_KERNEL=$(EFFECTIVE_USE_CXX_EM_KERNEL)
## polint(ordn=6) kernel selector:
## 1 (default): barycentric fast path
## 0 : fallback to Neville path
POLINT6_USE_BARY ?= 1
POLINT6_FLAG = -DPOLINT6_USE_BARYCENTRIC=$(POLINT6_USE_BARY)
TRANSFER_CACHE_FLAG = -DBSSN_USE_TRANSFER_CACHE=$(EFFECTIVE_USE_TRANSFER_CACHE)
ESCALAR_KERNEL_FLAG = -DBSSN_USE_ESCALAR_C_KERNEL=$(EFFECTIVE_USE_CXX_ESCALAR_KERNEL)
## ABE build flags selected by PGO_MODE (set in makefile.inc, default: opt)
## make -> opt (PGO-guided, maximum performance)
## make PGO_MODE=instrument -> instrument (Phase 1: collect fresh profile data)
PROFDATA = /home/$(shell whoami)/AMSS-NCKU/pgo_profile/default.profdata
ifeq ($(PGO_MODE),instrument)
## Phase 1: instrumentation — omit -ipo/-fp-model fast=2 for faster build and numerical stability
CXXAPPFLAGS = -O3 -xHost -fma -fprofile-instr-generate -ipo \
-Dfortran3 -Dnewc -I${MKLROOT}/include $(INTERP_LB_FLAGS) \
$(TRANSFER_CACHE_FLAG) $(ESCALAR_KERNEL_FLAG) $(EM_KERNEL_FLAG)
f90appflags = -O3 -xHost -fma -fprofile-instr-generate -ipo \
-align array64byte -fpp -I${MKLROOT}/include $(POLINT6_FLAG)
else
## opt (default): maximum performance with PGO profile data -fprofile-instr-use=$(PROFDATA) \
## PGO has been turned off, now tested and found to be negative optimization
## INTERP_LB_FLAGS has been turned off too, now tested and found to be negative optimization
CXXAPPFLAGS = -O3 -xHost -fp-model fast=2 -fma -ipo \
-Dfortran3 -Dnewc -I${MKLROOT}/include $(INTERP_LB_FLAGS) \
$(TRANSFER_CACHE_FLAG) $(ESCALAR_KERNEL_FLAG) $(EM_KERNEL_FLAG)
f90appflags = -O3 -xHost -fp-model fast=2 -fma -ipo \
-align array64byte -fpp -I${MKLROOT}/include $(POLINT6_FLAG)
endif
.SUFFIXES: .o .f90 .C .for .cu
.f90.o:
$(f90) $(f90appflags) -c $< -o $@
.C.o:
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
# ShellPatch.C uses OpenMP for setupintintstuff search loops
ShellPatch.o: ShellPatch.C
${CXX} $(CXXAPPFLAGS) $(OMP_FLAG) -c $< $(filein) -o $@
.for.o:
$(f77) -c $< -o $@
.cu.o:
$(Cu) $(CUDA_APP_FLAGS) -c $< -o $@ $(CUDA_LIB_PATH)
# C rewrite of BSSN RHS kernel and helpers
bssn_rhs_c.o: bssn_rhs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
fderivs_c.o: fderivs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
fdderivs_c.o: fdderivs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
kodiss_c.o: kodiss_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
lopsided_c.o: lopsided_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
lopsided_kodis_c.o: lopsided_kodis_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
# C rewrite of shell-patch derivative kernels
fderivs_sh_c.o: fderivs_sh_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
fdderivs_sh_c.o: fdderivs_sh_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
fderivs_shc_c.o: fderivs_shc_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
fdderivs_shc_c.o: fdderivs_shc_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
kodiss_sh_c.o: kodiss_sh_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
bssn_em_rhs_c.o: bssn_em_rhs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
z4c_rhs_c.o: z4c_rhs_c.C
${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
#interp_lb_profile.o: interp_lb_profile.C interp_lb_profile.h
# ${CXX} $(CXXAPPFLAGS) -c $< $(filein) -o $@
## TwoPunctureABE uses fixed optimal flags with its own PGO profile, independent of CXXAPPFLAGS
TP_PROFDATA = /home/$(shell whoami)/AMSS-NCKU/pgo_profile/TwoPunctureABE.profdata
TP_OPTFLAGS = -O3 -xHost -fp-model fast=2 -fma -ipo \
-fprofile-instr-use=$(TP_PROFDATA) \
-Dfortran3 -Dnewc -I${MKLROOT}/include
TwoPunctures.o: TwoPunctures.C
${CXX} $(TP_OPTFLAGS) -qopenmp -c $< -o $@
TwoPunctureABE.o: TwoPunctureABE.C
${CXX} $(TP_OPTFLAGS) -qopenmp -c $< -o $@
# Input files
## Kernel implementation switch (set USE_CXX_KERNELS=0 to fall back to Fortran)
ifeq ($(USE_CXX_KERNELS),0)
# Fortran mode: no C rewrite files; bssn_rhs.o is included via F90FILES below
CFILES =
else
# C++ mode (default): C rewrite of bssn/bssn-escalar rhs and helper kernels
CFILES = bssn_rhs_c.o fderivs_c.o fdderivs_c.o kodiss_c.o lopsided_c.o lopsided_kodis_c.o
ifeq ($(EFFECTIVE_USE_CXX_ESCALAR_KERNEL),1)
CFILES += bssn_escalar_rhs_c.o
endif
ifeq ($(EFFECTIVE_USE_CXX_EM_KERNEL),1)
CFILES += bssn_em_rhs_c.o
endif
endif
ifeq ($(USE_CXX_Z4C_KERNELS),1)
CFILES += z4c_rhs_c.o
Z4C_F90_OBJ =
else
Z4C_F90_OBJ = Z4c_rhs.o
endif
## RK4 kernel switch (independent from USE_CXX_KERNELS)
ifeq ($(USE_CXX_RK4),1)
CFILES += rungekutta4_rout_c.o
RK4_F90_OBJ =
else
RK4_F90_OBJ = rungekutta4_rout.o
endif
## Shell-patch derivative kernel switch (independent from USE_CXX_KERNELS)
## 1 : use C++ rewrite of shell derivative functions (experimental)
## 0 : use original Fortran diff_new_sh.o and kodiss_sh.o (default)
USE_CXX_SHELL_KERNELS ?= 0
ifeq ($(USE_CXX_SHELL_KERNELS),1)
CFILES += fderivs_sh_c.o fdderivs_sh_c.o fderivs_shc_c.o fdderivs_shc_c.o kodiss_sh_c.o
SH_F90_OBJ =
else
SH_F90_OBJ = diff_new_sh.o kodiss_sh.o point_diff_new_sh.o
endif
C++FILES = ABE.o Ansorg.o Block.o misc.o monitor.o Parallel.o MPatch.o var.o\
cgh.o bssn_class.o surface_integral.o ShellPatch.o\
bssnEScalar_class.o perf.o Z4c_class.o NullShellPatch.o\
bssnEM_class.o cpbc_util.o z4c_rhs_point.o checkpoint.o\
Parallel_bam.o scalar_class.o transpbh.o NullShellPatch2.o\
NullShellPatch2_Evo.o writefile_f.o interp_lb_profile.o
C++FILES_GPU = ABE.o Ansorg.o Block.o misc.o monitor.o Parallel.o MPatch.o var.o\
cgh.o surface_integral.o ShellPatch.o\
bssnEScalar_class.o perf.o Z4c_class.o NullShellPatch.o\
bssnEM_class.o cpbc_util.o z4c_rhs_point.o checkpoint.o\
Parallel_bam.o scalar_class.o transpbh.o NullShellPatch2.o\
NullShellPatch2_Evo.o \
bssn_gpu_class.o bssn_step_gpu.o bssn_macro.o writefile_f.o
F90FILES_BASE = enforce_algebra.o fmisc.o initial_puncture.o prolongrestrict.o\
prolongrestrict_cell.o prolongrestrict_vertex.o\
$(RK4_F90_OBJ) diff_new.o kodiss.o\
lopsidediff.o sommerfeld_rout.o getnp4.o $(SH_F90_OBJ)\
shellfunctions.o bssn_rhs_ss.o Set_Rho_ADM.o\
getnp4EScalar.o bssnEScalar_rhs.o bssn_constraint.o ricci_gamma.o\
fadmquantites_bssn.o $(Z4C_F90_OBJ) Z4c_rhs_ss.o\
cpbc.o getnp4old.o NullEvol.o initial_null.o initial_maxwell.o\
getnpem2.o empart.o NullNews.o fourdcurvature.o\
bssn2adm.o adm_constraint.o adm_ricci_gamma.o\
scalar_rhs.o initial_scalar.o NullEvol2.o initial_null2.o\
NullNews2.o tool_f.o
ifeq ($(USE_CXX_KERNELS),0)
# Fortran mode: include original bssn_rhs.o
F90FILES = $(F90FILES_BASE) bssn_rhs.o
else
# C++ mode (default): bssn_rhs.o replaced by C++ kernel
F90FILES = $(F90FILES_BASE)
endif
F77FILES = zbesh.o
AHFDOBJS = expansion.o expansion_Jacobian.o patch.o coords.o patch_info.o patch_interp.o patch_system.o \
tgrid.o fd_grid.o ghost_zone.o array.o round.o norm.o fuzzy.o error_exit.o miscfp.o \
linear_map.o cpm_map.o BH_diagnostics.o setup.o horizon_sequence.o find_horizons.o \
initial_guess.o Newton.o Jacobian.o ilucg.o IntPnts0.o IntPnts.o
TwoPunctureFILES = TwoPunctureABE.o TwoPunctures.o
CUDAFILES = bssn_gpu.o bssn_gpu_rhs_ss.o
# file dependences
$(C++FILES) $(C++FILES_GPU) $(F90FILES) $(CFILES) $(AHFDOBJS) $(CUDAFILES): macrodef.fh
$(C++FILES): Block.h enforce_algebra.h fmisc.h initial_puncture.h macrodef.h\
misc.h monitor.h MyList.h Parallel.h MPatch.h prolongrestrict.h\
rungekutta4_rout.h var.h bssn_class.h bssn_rhs.h sommerfeld_rout.h\
cgh.h surface_integral.h ShellPatch.h shellfunctions.h perf.h\
fadmquantites_bssn.h cpbc.h getnp4.h initial_null.h NullEvol.h\
NullShellPatch.h initial_maxwell.h bssnEM_class.h getnpem2.h\
empart.h NullNews.h kodiss.h Parallel_bam.h ricci_gamma.h\
initial_null2.h NullShellPatch2.h
$(C++FILES_GPU): Block.h enforce_algebra.h fmisc.h initial_puncture.h macrodef.h\
misc.h monitor.h MyList.h Parallel.h MPatch.h prolongrestrict.h\
rungekutta4_rout.h var.h bssn_rhs.h sommerfeld_rout.h\
cgh.h surface_integral.h ShellPatch.h shellfunctions.h perf.h\
fadmquantites_bssn.h cpbc.h getnp4.h initial_null.h NullEvol.h\
NullShellPatch.h initial_maxwell.h bssnEM_class.h getnpem2.h\
empart.h NullNews.h kodiss.h Parallel_bam.h ricci_gamma.h\
initial_null2.h NullShellPatch2.h \
bssn_gpu_class.h bssn_macro.h
$(AHFDOBJS): cctk.h cctk_Config.h cctk_Types.h cctk_Constants.h myglobal.h
$(C++FILES) $(C++FILES_GPU) $(CFILES) $(AHFDOBJS) $(CUDAFILES): macrodef.h
TwoPunctureFILES: TwoPunctures.h
$(CUDAFILES): bssn_gpu.h gpu_mem.h gpu_rhsSS_mem.h
misc.o : zbesh.o
# projects
ABE: $(C++FILES) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS)
$(CLINKER) $(CXXAPPFLAGS) -o $@ $(C++FILES) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS) $(LDLIBS)
ABEGPU: $(C++FILES_GPU) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS) $(CUDAFILES)
$(CLINKER) $(CXXAPPFLAGS) -o $@ $(C++FILES_GPU) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS) $(CUDAFILES) $(LDLIBS)
TwoPunctureABE: $(TwoPunctureFILES)
$(CLINKER) $(TP_OPTFLAGS) -qopenmp -o $@ $(TwoPunctureFILES) $(LDLIBS)
clean:
rm *.o ABE ABEGPU TwoPunctureABE make.log -f
CXXAPPFLAGS += -DUSE_CUDA_BSSN=$(USE_CUDA_BSSN)
CUDA_APP_FLAGS += -DUSE_CUDA_BSSN=$(USE_CUDA_BSSN)
CXXAPPFLAGS += -DUSE_CUDA_Z4C=$(USE_CUDA_Z4C)
CUDA_APP_FLAGS += -DUSE_CUDA_Z4C=$(USE_CUDA_Z4C)
CXXAPPFLAGS += -DAMSS_Z4C_MRBD=$(AMSS_Z4C_MRBD)
CUDA_APP_FLAGS += -DAMSS_Z4C_MRBD=$(AMSS_Z4C_MRBD)
## Kernel implementation switch (set USE_CXX_KERNELS=0 to fall back to Fortran)
ifeq ($(USE_CXX_KERNELS),0)
# Fortran mode: no C rewrite files; bssn_rhs.o is included via F90FILES below
CFILES_CPU =
else
# C++ mode (default): C rewrite of bssn_rhs and helper kernels
CFILES_CPU = bssn_rhs_c.o fderivs_c.o fdderivs_c.o kodiss_c.o lopsided_c.o lopsided_kodis_c.o
endif
CFILES_CUDA_BSSN = bssn_rhs_cuda.o bssn_gpu_rhs_ss.o
ifeq ($(USE_CUDA_BSSN),1)
CFILES = $(CFILES_CUDA_BSSN)
else
CFILES = $(CFILES_CPU)
endif
ifeq ($(USE_CUDA_Z4C),1)
CFILES += z4c_rhs_cuda.o
Z4C_F90_OBJ =
else ifeq ($(USE_CXX_Z4C_KERNELS),1)
CFILES += z4c_rhs_c.o
Z4C_F90_OBJ =
else
Z4C_F90_OBJ = Z4c_rhs.o
endif
## RK4 kernel switch (independent from USE_CXX_KERNELS)
ifeq ($(USE_CXX_RK4),1)
RK4_C_OBJ = rungekutta4_rout_c.o
RK4_F90_OBJ =
else
RK4_C_OBJ =
RK4_F90_OBJ = rungekutta4_rout.o
endif
CFILES += $(RK4_C_OBJ)
ABE_CUDA_CFILES = $(CFILES_CUDA_BSSN) z4c_rhs_cuda.o $(RK4_C_OBJ)
ABE_LDLIBS = $(LDLIBS)
ifeq ($(USE_CUDA_BSSN),1)
ABE_LDLIBS += -lcudart $(CUDA_LIB_PATH)
endif
ifeq ($(USE_CUDA_Z4C),1)
ABE_LDLIBS += -lcudart $(CUDA_LIB_PATH)
endif
C++FILES = ABE.o Ansorg.o Block.o misc.o monitor.o Parallel.o MPatch.o var.o\
cgh.o bssn_class.o surface_integral.o ShellPatch.o\
bssnEScalar_class.o perf.o Z4c_class.o NullShellPatch.o\
bssnEM_class.o cpbc_util.o z4c_rhs_point.o checkpoint.o\
Parallel_bam.o scalar_class.o transpbh.o NullShellPatch2.o\
NullShellPatch2_Evo.o writefile_f.o interp_lb_profile.o
#C++FILES_GPU = ABE.o Ansorg.o Block.o misc.o monitor.o Parallel.o MPatch.o var.o\
cgh.o surface_integral.o ShellPatch.o\
bssnEScalar_class.o perf.o Z4c_class.o NullShellPatch.o\
bssnEM_class.o cpbc_util.o z4c_rhs_point.o checkpoint.o\
Parallel_bam.o scalar_class.o transpbh.o NullShellPatch2.o\
NullShellPatch2_Evo.o \
bssn_gpu_class.o bssn_step_gpu.o bssn_macro.o writefile_f.o
F90FILES_BASE = enforce_algebra.o fmisc.o initial_puncture.o prolongrestrict.o\
prolongrestrict_cell.o prolongrestrict_vertex.o\
$(RK4_F90_OBJ) diff_new.o kodiss.o kodiss_sh.o\
lopsidediff.o sommerfeld_rout.o getnp4.o diff_new_sh.o\
shellfunctions.o bssn_rhs_ss.o Set_Rho_ADM.o\
getnp4EScalar.o bssnEScalar_rhs.o bssn_constraint.o ricci_gamma.o\
fadmquantites_bssn.o $(Z4C_F90_OBJ) Z4c_rhs_ss.o point_diff_new_sh.o\
cpbc.o getnp4old.o NullEvol.o initial_null.o initial_maxwell.o\
getnpem2.o empart.o NullNews.o fourdcurvature.o\
bssn2adm.o adm_constraint.o adm_ricci_gamma.o\
scalar_rhs.o initial_scalar.o NullEvol2.o initial_null2.o\
NullNews2.o tool_f.o
ifeq ($(USE_CXX_KERNELS),0)
# Fortran mode: include original bssn_rhs.o
F90FILES = $(F90FILES_BASE) bssn_rhs.o
else
# C++ mode (default): bssn_rhs.o replaced by C++ kernel
F90FILES = $(F90FILES_BASE)
endif
F77FILES = zbesh.o
AHFDOBJS = expansion.o expansion_Jacobian.o patch.o coords.o patch_info.o patch_interp.o patch_system.o \
tgrid.o fd_grid.o ghost_zone.o array.o round.o norm.o fuzzy.o error_exit.o miscfp.o \
linear_map.o cpm_map.o BH_diagnostics.o setup.o horizon_sequence.o find_horizons.o \
initial_guess.o Newton.o Jacobian.o ilucg.o IntPnts0.o IntPnts.o
TwoPunctureFILES = TwoPunctureABE.o TwoPunctures.o
#CUDAFILES = bssn_gpu.o bssn_gpu_rhs_ss.o
# file dependences
$(C++FILES) $(C++FILES_GPU) $(F90FILES) $(CFILES) $(ABE_CUDA_CFILES) $(AHFDOBJS) $(CUDAFILES): macrodef.fh
$(C++FILES): Block.h enforce_algebra.h fmisc.h initial_puncture.h macrodef.h\
misc.h monitor.h MyList.h Parallel.h MPatch.h prolongrestrict.h\
rungekutta4_rout.h var.h bssn_class.h bssn_rhs.h sommerfeld_rout.h\
cgh.h surface_integral.h ShellPatch.h shellfunctions.h perf.h\
fadmquantites_bssn.h cpbc.h getnp4.h initial_null.h NullEvol.h\
NullShellPatch.h initial_maxwell.h bssnEM_class.h getnpem2.h\
empart.h NullNews.h kodiss.h Parallel_bam.h ricci_gamma.h\
initial_null2.h NullShellPatch2.h
#$(C++FILES_GPU): Block.h enforce_algebra.h fmisc.h initial_puncture.h macrodef.h\
misc.h monitor.h MyList.h Parallel.h MPatch.h prolongrestrict.h\
rungekutta4_rout.h var.h bssn_rhs.h sommerfeld_rout.h\
cgh.h surface_integral.h ShellPatch.h shellfunctions.h perf.h\
fadmquantites_bssn.h cpbc.h getnp4.h initial_null.h NullEvol.h\
NullShellPatch.h initial_maxwell.h bssnEM_class.h getnpem2.h\
empart.h NullNews.h kodiss.h Parallel_bam.h ricci_gamma.h\
initial_null2.h NullShellPatch2.h \
bssn_gpu_class.h bssn_macro.h
$(AHFDOBJS): cctk.h cctk_Config.h cctk_Types.h cctk_Constants.h myglobal.h
$(C++FILES) $(C++FILES_GPU) $(CFILES) $(ABE_CUDA_CFILES) $(AHFDOBJS) $(CUDAFILES): macrodef.h
TwoPunctureFILES: TwoPunctures.h
$(CUDAFILES): bssn_gpu.h gpu_mem.h gpu_rhsSS_mem.h
misc.o : zbesh.o
# projects
ABE: $(C++FILES) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS)
$(CLINKER) $(CXXAPPFLAGS) -o $@ $(C++FILES) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS) $(ABE_LDLIBS)
ABE_CUDA: USE_CUDA_BSSN=1
ABE_CUDA: USE_CUDA_Z4C=1
ABE_CUDA: $(C++FILES) $(ABE_CUDA_CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS)
$(CLINKER) $(CXXAPPFLAGS) -o $@ $(C++FILES) $(ABE_CUDA_CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS) $(LDLIBS) -lcudart $(CUDA_LIB_PATH)
#ABEGPU: $(C++FILES_GPU) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS) $(CUDAFILES)
# $(CLINKER) $(CXXAPPFLAGS) -o $@ $(C++FILES_GPU) $(CFILES) $(F90FILES) $(F77FILES) $(AHFDOBJS) $(CUDAFILES) $(LDLIBS)
TwoPunctureABE: $(TwoPunctureFILES)
$(CLINKER) $(TP_OPTFLAGS) $(OMP_FLAG) -o $@ $(TwoPunctureFILES) $(LDLIBS)
clean:
rm *.o ABE ABE_CUDA ABEGPU TwoPunctureABE make.log -f

97
AMSS_NCKU_source/makefile.inc
View File

@@ -1,28 +1,7 @@
## GCC version (commented out)
## filein = -I/usr/include -I/usr/lib/x86_64-linux-gnu/mpich/include -I/usr/lib/x86_64-linux-gnu/openmpi/lib/ -I/usr/lib/gcc/x86_64-linux-gnu/11/ -I/usr/include/c++/11/
## filein = -I/usr/include/ -I/usr/include/openmpi-x86_64/ -I/usr/lib/x86_64-linux-gnu/openmpi/include/ -I/usr/lib/x86_64-linux-gnu/openmpi/lib/ -I/usr/lib/gcc/x86_64-linux-gnu/11/ -I/usr/include/c++/11/
## LDLIBS = -L/usr/lib/x86_64-linux-gnu -L/usr/lib64 -L/usr/lib/gcc/x86_64-linux-gnu/11 -lgfortran -lmpi -lgfortran
## Intel oneAPI version with oneMKL (Optimized for performance)
filein = -I/usr/include/ -I${MKLROOT}/include
## Using sequential MKL (OpenMP disabled for better single-threaded performance)
## Added -lifcore for Intel Fortran runtime and -limf for Intel math library
LDLIBS = -L${MKLROOT}/lib -lmkl_intel_lp64 -lmkl_sequential -lmkl_core -lifcore -limf -lpthread -lm -ldl -liomp5
## Memory allocator switch
## 1 (default) : link Intel oneTBB allocator (libtbbmalloc)
## 0 : use system default allocator (ptmalloc)
USE_TBBMALLOC ?= 1
TBBMALLOC_SO ?= /home/intel/oneapi/2025.3/lib/libtbbmalloc.so
ifneq ($(wildcard $(TBBMALLOC_SO)),)
TBBMALLOC_LIBS = -Wl,--no-as-needed $(TBBMALLOC_SO) -Wl,--as-needed
else
TBBMALLOC_LIBS = -Wl,--no-as-needed -ltbbmalloc -Wl,--as-needed
endif
ifeq ($(USE_TBBMALLOC),1)
LDLIBS := $(TBBMALLOC_LIBS) $(LDLIBS)
endif
## Toolchain selection
## nvhpc : NVIDIA HPC SDK + CUDA-aware MPI (default)
## intel : Intel oneAPI toolchain (legacy path)
TOOLCHAIN ?= intel
## PGO build mode switch (ABE only; TwoPunctureABE always uses opt flags)
## opt : (default) maximum performance with PGO profile-guided optimization
@@ -43,6 +22,14 @@ else
INTERP_LB_FLAGS =
endif
MKLROOT ?= /home/intel/oneapi/mkl/latest
MKL_LIBDIR ?= $(MKLROOT)/lib/intel64
MKL_INC ?= -I$(MKLROOT)/include
NVHPC_ROOT ?= /home/nvidia/hpc_sdk/Linux_x86_64/25.11
CUDA_HOME ?= $(NVHPC_ROOT)/cuda
CUDA_ARCH ?= sm_80
## Kernel implementation switch
## 1 (default) : use C++ rewrite of bssn_rhs and helper kernels (faster)
## 0 : fall back to original Fortran kernels
@@ -53,36 +40,52 @@ USE_CXX_KERNELS ?= 1
## 0 : use original Fortran Z4c_rhs.o
USE_CXX_Z4C_KERNELS ?= 1
## BSSN-EScalar RHS switch
## 1 (default) : use BSSN-EScalar C wrapper on the normal patch path
## 0 : keep the original Fortran BSSN-EScalar RHS for precision-safe runs
## Note: this requires USE_CXX_KERNELS=1 because the wrapper reuses the C BSSN kernel.
USE_CXX_ESCALAR_KERNEL ?= 1
## BSSN-EM RHS switch
## 1 : use BSSN-EM C kernel (bssn_em_rhs_c.C) on the normal patch path
## 0 : keep the original Fortran empart.f90 RHS for the EM fields (default)
## Note: experimental, requires USE_CXX_KERNELS=1
USE_CXX_EM_KERNEL ?= 0
## Cached transfer switch
## auto (default): enable for BSSN vacuum, keep other paths on the safe uncached path
## 1 : force cached Sync/Restrict/OutBd transfer on evolution hot paths
## 0 : force the original uncached transfer path
USE_TRANSFER_CACHE ?= auto
## RK4 kernel implementation switch
## 1 (default) : use C/C++ rewrite of rungekutta4_rout (for optimization experiments)
## 0 : use original Fortran rungekutta4_rout.o
USE_CXX_RK4 ?= 1
## Memory allocator switch
## 1 (default) : link Intel oneTBB allocator (libtbbmalloc)
## 0 : use system default allocator (ptmalloc)
USE_TBBMALLOC ?= 1
TBBMALLOC_SO ?= /home/intel/oneapi/2025.3/lib/libtbbmalloc.so
ifneq ($(wildcard $(TBBMALLOC_SO)),)
TBBMALLOC_LIBS = -Wl,--no-as-needed $(TBBMALLOC_SO) -Wl,--as-needed
else
TBBMALLOC_LIBS = -Wl,--no-as-needed -ltbbmalloc -Wl,--as-needed
endif
ifeq ($(TOOLCHAIN),intel)
f90 = ifx
f77 = ifx
CXX = icpx
CC = icx
CLINKER = mpiicpx
filein = -I/usr/include/ $(MKL_INC) -I$(CUDA_HOME)/include
LDLIBS = -L$(MKL_LIBDIR) -Wl,-rpath,$(MKL_LIBDIR) \
-lmkl_intel_lp64 -lmkl_sequential -lmkl_core \
-lifcore -limf -liomp5 -lpthread -lm -ldl \
-L$(CUDA_HOME)/lib64 -Wl,-rpath,$(CUDA_HOME)/lib64 -lcuda -lcudart
else ifeq ($(TOOLCHAIN),nvhpc)
f90 = mpifort
f77 = mpifort
CXX = mpicxx
CC = mpicc
CLINKER = mpicxx
Cu = nvcc
CUDA_LIB_PATH = -L/usr/lib/cuda/lib64 -I/usr/include -I/usr/lib/cuda/include
#CUDA_APP_FLAGS = -c -g -O3 --ptxas-options=-v -arch compute_13 -code compute_13,sm_13 -Dfortran3 -Dnewc
CUDA_APP_FLAGS = -c -g -O3 --ptxas-options=-v -Dfortran3 -Dnewc
filein = -I/usr/include/ $(MKL_INC) -I$(CUDA_HOME)/include
LDLIBS = -L$(MKL_LIBDIR) -Wl,-rpath,$(MKL_LIBDIR) \
-lmkl_intel_lp64 -lmkl_sequential -lmkl_core \
-lpthread -lm -ldl \
-L$(CUDA_HOME)/lib64 -Wl,-rpath,$(CUDA_HOME)/lib64 -lcuda -lcudart \
-fortranlibs
endif
ifeq ($(USE_TBBMALLOC),1)
LDLIBS := $(TBBMALLOC_LIBS) $(LDLIBS)
endif
Cu = $(NVHPC_ROOT)/compilers/bin/nvcc
CUDA_LIB_PATH = -L$(CUDA_HOME)/lib64 -I$(CUDA_HOME)/include
CUDA_APP_FLAGS = -c -g -O3 --ptxas-options=-v -Dfortran3 -Dnewc -arch=$(CUDA_ARCH)

49
AMSS_NCKU_source/monitor.C
View File

@@ -1,7 +1,8 @@
#ifdef newc
#include <cstdio>
using namespace std;
#ifdef newc
#include <cstdio>
#include <sstream>
using namespace std;
#else
#include <stdio.h>
#endif
@@ -77,16 +78,17 @@ monitor::monitor(const char fname[], int myrank, string head)
parameters::str_par.insert(map<string, string>::value_type("output dir", out_dir));
}
// considering checkpoint run
char filename[50];
sprintf(filename, "%s/%s", out_dir.c_str(), fname);
int i = 1;
while ((access(filename, F_OK)) != -1)
{
sprintf(filename, "%s/%d_%s", out_dir.c_str(), i, fname);
i++;
}
outfile.open(filename, ios::trunc);
string filename = out_dir + "/" + fname;
int i = 1;
while ((access(filename.c_str(), F_OK)) != -1)
{
stringstream ss;
ss << out_dir << "/" << i << "_" << fname;
filename = ss.str();
i++;
}
outfile.open(filename.c_str(), ios::trunc);
time_t tnow;
time(&tnow);
@@ -107,16 +109,17 @@ monitor::monitor(const char fname[], int myrank, const int out_rank, string head
if (I_Print)
{
// considering checkpoint run
char filename[50];
sprintf(filename, "%s/%s", out_dir.c_str(), fname);
int i = 1;
while ((access(filename, F_OK)) != -1)
{
sprintf(filename, "%s/%d_%s", out_dir.c_str(), i, fname);
i++;
}
outfile.open(filename, ios::trunc);
string filename = out_dir + "/" + fname;
int i = 1;
while ((access(filename.c_str(), F_OK)) != -1)
{
stringstream ss;
ss << out_dir << "/" << i << "_" << fname;
filename = ss.str();
i++;
}
outfile.open(filename.c_str(), ios::trunc);
time_t tnow;
time(&tnow);

128
AMSS_NCKU_source/share_func.h
View File

@@ -46,45 +46,6 @@ static inline size_t idx_fh_F(int iF, int jF, int kF, const int ex[3]) {
return (size_t)ii + (size_t)jj * (size_t)nx + (size_t)kk * (size_t)nx * (size_t)ny;
}
/*
* fh 对应 Fortran: fh(0:ex1, 0:ex2, 0:ex3)
* ord=1 => shift=0
* iF/jF/kF 为 Fortran 索引 (0..ex)
*/
static inline size_t idx_fh_F_ord1(int iF, int jF, int kF, const int ex[3]) {
const int nx = ex[0] + 1; // ex1 + ord
const int ny = ex[1] + 1;
return (size_t)iF + (size_t)jF * (size_t)nx + (size_t)kF * (size_t)nx * (size_t)ny;
}
/*
* fh 对应 Fortran: fh(-3:ex1, -3:ex2, -3:ex3)
* ord=4 => shift=3
*/
static inline size_t idx_fh_F_ord4(int iF, int jF, int kF, const int ex[3]) {
const int shift = 3;
const int nx = ex[0] + 4; // ex1 + ord
const int ny = ex[1] + 4;
const int ii = iF + shift; // 0..ex1+3
const int jj = jF + shift; // 0..ex2+3
const int kk = kF + shift; // 0..ex3+3
return (size_t)ii + (size_t)jj * (size_t)nx + (size_t)kk * (size_t)nx * (size_t)ny;
}
/*
* fh 对应 Fortran: fh(-4:ex1, -4:ex2, -4:ex3)
* ord=5 => shift=4
*/
static inline size_t idx_fh_F_ord5(int iF, int jF, int kF, const int ex[3]) {
const int shift = 4;
const int nx = ex[0] + 5; // ex1 + ord
const int ny = ex[1] + 5;
const int ii = iF + shift; // 0..ex1+4
const int jj = jF + shift; // 0..ex2+4
const int kk = kF + shift; // 0..ex3+4
return (size_t)ii + (size_t)jj * (size_t)nx + (size_t)kk * (size_t)nx * (size_t)ny;
}
/*
* func: (1..extc1, 1..extc2, 1..extc3) 1-based in Fortran
* funcc: (-ord+1..extc1, -ord+1..extc2, -ord+1..extc3) in Fortran
@@ -270,10 +231,7 @@ static inline void symmetry_bd(int ord,
{
if (ord <= 0) return;
if (ord == 1) {
symmetry_bd_impl(1, 0, extc, func, funcc, SoA);
return;
}
/* Fast paths used by current C kernels: ord=2 (derivs), ord=3 (lopsided/KO). */
if (ord == 2) {
symmetry_bd_impl(2, 1, extc, func, funcc, SoA);
return;
@@ -282,91 +240,7 @@ static inline void symmetry_bd(int ord,
symmetry_bd_impl(3, 2, extc, func, funcc, SoA);
return;
}
if (ord == 4) {
symmetry_bd_impl(4, 3, extc, func, funcc, SoA);
return;
}
symmetry_bd_impl(ord, ord - 1, extc, func, funcc, SoA);
}
/*
* symmetry_stbd — shell-patch (staggered boundary) ghost fill.
*
* Fortran: funcc(-ord+1:extc1+ord, -ord+1:extc2+ord, extc3)
* Only 2 SoA values (x/y). No z symmetry fill.
* Ghost on BOTH positive and negative sides of x and y.
* Reflection uses i+2 (skips boundary) instead of i+1.
* nx = extc1 + 2*ord, ny = extc2 + 2*ord
*/
static inline void symmetry_stbd(int ord,
const int extc[3],
const double *func,
double *funcc,
const double SoA[2])
{
const int extc1 = extc[0], extc2 = extc[1], extc3 = extc[2];
const int nx = extc1 + 2 * ord;
const int ny = extc2 + 2 * ord;
const int sh = ord - 1;
const size_t snx = (size_t)nx;
const size_t splane = snx * (size_t)ny;
/* 1) Copy interior: funcc(1:extc1, 1:extc2, 1:extc3) = func */
for (int k0 = 0; k0 < extc3; ++k0) {
const double *src = func + (size_t)k0 * (size_t)extc2 * (size_t)extc1;
const size_t kbase = (size_t)k0 * splane;
for (int j0 = 0; j0 < extc2; ++j0) {
double *dst = funcc + kbase + (size_t)(sh + j0 + 1) * snx + (size_t)(sh + 1);
const double *s = src + (size_t)j0 * (size_t)extc1;
for (int i0 = 0; i0 < extc1; ++i0) dst[i0] = s[i0];
}
}
/* 2) x-direction ghost fill */
const double s1 = SoA[0];
for (int k0 = 0; k0 < extc3; ++k0) {
const size_t kbase = (size_t)k0 * splane;
for (int j0 = 0; j0 < extc2; ++j0) {
const size_t off = kbase + (size_t)(sh + j0 + 1) * snx;
/* left side: funcc(-i) = funcc(i+2) * s1 */
for (int i = 0; i < ord; ++i) {
funcc[off + (size_t)(sh - i)] = funcc[off + (size_t)(sh + i + 2)] * s1;
/* right side: funcc(extc1+1+i) = funcc(extc1-1-i) * s1 */
funcc[off + (size_t)(sh + extc1 + 1 + i)] = funcc[off + (size_t)(sh + extc1 - 1 - i)] * s1;
}
}
}
/* 3) y-direction ghost fill */
const double s2 = SoA[1];
for (int i = 0; i < nx; ++i) {
for (int k0 = 0; k0 < extc3; ++k0) {
const size_t kbase = (size_t)k0 * splane;
/* bottom: funcc(:,-i,:) = funcc(:,i+2,:) * s2 */
for (int jj = 0; jj < ord; ++jj) {
funcc[kbase + (size_t)(sh - jj) * snx + (size_t)i] =
funcc[kbase + (size_t)(sh + jj + 2) * snx + (size_t)i] * s2;
/* top: funcc(:,extc2+1+jj,:) = funcc(:,extc2-1-jj,:) * s2 */
funcc[kbase + (size_t)(sh + extc2 + 1 + jj) * snx + (size_t)i] =
funcc[kbase + (size_t)(sh + extc2 - 1 - jj) * snx + (size_t)i] * s2;
}
}
}
}
/*
* Indexing for shell fh buffer: Fortran fh(-ord+1:extc1+ord, -ord+1:extc2+ord, extc3)
* C 0-based: ii = iF + ord - 1
* nx = extc1 + 2*ord, ny = extc2 + 2*ord
*/
static inline size_t idx_fh_stbd(int iF, int jF, int kF, int ord, const int extc[3]) {
const int sh = ord - 1;
const int nx = extc[0] + 2 * ord;
const int ny = extc[1] + 2 * ord;
const int ii = iF + sh;
const int jj = jF + sh;
const int kk = kF - 1; // Fortran 1-based kF → C 0-based
return (size_t)ii + (size_t)jj * (size_t)nx + (size_t)kk * (size_t)nx * (size_t)ny;
}
#endif

68
AMSS_NCKU_source/surface_integral.C
View File

@@ -8,10 +8,11 @@
#include <iostream>
#include <iomanip>
#include <fstream>
#include <strstream>
#include <cmath>
#include <map>
using namespace std;
#include <strstream>
#include <cmath>
#include <map>
#include <cstdlib>
using namespace std;
#else
#include <iostream.h>
#include <iomanip.h>
@@ -29,12 +30,26 @@ using namespace std;
#include "fadmquantites_bssn.h"
#include "getnpem2.h"
#include "getnp4.h"
#include "parameters.h"
#define PI M_PI
//|============================================================================
//| Constructor
//|============================================================================
#include "parameters.h"
#define PI M_PI
namespace
{
bool amss_surface_timing_enabled()
{
static int enabled = -1;
if (enabled < 0)
{
const char *env = getenv("AMSS_SURFACE_TIMING");
enabled = (env && atoi(env) != 0) ? 1 : 0;
}
return enabled != 0;
}
}
//|============================================================================
//| Constructor
//|============================================================================
surface_integral::surface_integral(int iSymmetry) : Symmetry(iSymmetry),
wave_cache_spinw(-1),
@@ -484,9 +499,9 @@ void surface_integral::surf_Wave(double rex, int lev, cgh *GH, var *Rpsi4, var *
delete[] IP_out;
DG_List->clearList();
}
void surface_integral::surf_Wave(double rex, int lev, cgh *GH, var *Rpsi4, var *Ipsi4,
int spinw, int maxl, int NN, double *RP, double *IP,
monitor *Monitor, MPI_Comm Comm_here) // NN is the length of RP and IP
void surface_integral::surf_Wave(double rex, int lev, cgh *GH, var *Rpsi4, var *Ipsi4,
int spinw, int maxl, int NN, double *RP, double *IP,
monitor *Monitor, MPI_Comm Comm_here) // NN is the length of RP and IP
{
// misc::tillherecheck(GH->Commlev[lev],GH->start_rank[lev],"start surface_integral::surf_Wave");
@@ -720,10 +735,10 @@ void surface_integral::surf_Wave(double rex, int lev, cgh *GH, var *Rpsi4, var *
delete[] IP_out;
DG_List->clearList();
}
//|----------------------------------------------------------------
// for shell patch
//|----------------------------------------------------------------
void surface_integral::surf_Wave(double rex, int lev, ShellPatch *GH, var *Rpsi4, var *Ipsi4,
//|----------------------------------------------------------------
// for shell patch
//|----------------------------------------------------------------
void surface_integral::surf_Wave(double rex, int lev, ShellPatch *GH, var *Rpsi4, var *Ipsi4,
int spinw, int maxl, int NN, double *RP, double *IP,
monitor *Monitor) // NN is the length of RP and IP
{
@@ -3281,6 +3296,8 @@ void surface_integral::surf_WaveMassPAng(double rex, int lev, cgh *GH,
var *Sfx_rhs, var *Sfy_rhs, var *Sfz_rhs,
double *Rout, monitor *Monitor, bool refresh_mass_fields)
{
const bool timing = amss_surface_timing_enabled();
const double t_start = timing ? MPI_Wtime() : 0.0;
if (Symmetry != 0 && Symmetry != 1)
{
surf_Wave(rex, lev, GH, Rpsi4, Ipsi4, spinw, maxl, NN, RP, IP, Monitor);
@@ -3325,6 +3342,7 @@ void surface_integral::surf_WaveMassPAng(double rex, int lev, cgh *GH,
Pp = Pp->next;
}
}
const double t_refresh_done = timing ? MPI_Wtime() : 0.0;
const int InList = 19;
const int idx_rpsi4 = 0, idx_ipsi4 = 1;
@@ -3380,6 +3398,7 @@ void surface_integral::surf_WaveMassPAng(double rex, int lev, cgh *GH,
double *shellf = new double[n_tot * InList];
GH->PatL[lev]->data->Interp_Points(DG_List, n_tot, pox, shellf, Symmetry, Nmin, Nmax);
const double t_interp_done = timing ? MPI_Wtime() : 0.0;
double *RP_out = new double[NN];
double *IP_out = new double[NN];
@@ -3496,6 +3515,7 @@ void surface_integral::surf_WaveMassPAng(double rex, int lev, cgh *GH,
if (Symmetry == 0)
p_outz += f1o8 * Psi * (nx_g[n] * axz + ny_g[n] * ayz + nz_g[n] * azz) * theta_weight;
}
const double t_integral_done = timing ? MPI_Wtime() : 0.0;
for (int ii = 0; ii < NN; ii++)
{
@@ -3534,6 +3554,7 @@ void surface_integral::surf_WaveMassPAng(double rex, int lev, cgh *GH,
delete[] reduce_out;
delete[] reduce_in;
}
const double t_reduce_done = timing ? MPI_Wtime() : 0.0;
#ifdef GaussInt
mass = mass * rex * rex * dphi * factor;
@@ -3565,6 +3586,19 @@ void surface_integral::surf_WaveMassPAng(double rex, int lev, cgh *GH,
Rout[5] = sy;
Rout[6] = sz;
if (timing)
{
fprintf(stderr,
"[AMSS-SURFACE][rank %d] rex=%.6g lev=%d refresh=%.6f interp=%.6f integral=%.6f reduce=%.6f total=%.6f nlocal=%d ntotal=%d modes=%d\n",
myrank, rex, lev,
t_refresh_done - t_start,
t_interp_done - t_refresh_done,
t_integral_done - t_interp_done,
t_reduce_done - t_integral_done,
t_reduce_done - t_start,
Nmax - Nmin + 1, n_tot, NN);
}
delete[] pox[0];
delete[] pox[1];
delete[] pox[2];

8
AMSS_NCKU_source/surface_integral.h
View File

@@ -46,10 +46,10 @@ public:
surface_integral(int iSymmetry);
~surface_integral();
void surf_Wave(double rex, int lev, cgh *GH, var *Rpsi4, var *Ipsi4,
int spinw, int maxl, int NN, double *RP, double *IP,
monitor *Monitor); // NN is the length of RP and IP
// this routine can only deal with the symmetry of Psi4
void surf_Wave(double rex, int lev, cgh *GH, var *Rpsi4, var *Ipsi4,
int spinw, int maxl, int NN, double *RP, double *IP,
monitor *Monitor); // NN is the length of RP and IP
// this routine can only deal with the symmetry of Psi4
void surf_Wave(double rex, int lev, ShellPatch *GH, var *Rpsi4, var *Ipsi4,
int spinw, int maxl, int NN, double *RP, double *IP,
monitor *Monitor);

182
AMSS_NCKU_source/z4c_rhs_c.C
View File

@@ -327,9 +327,6 @@ static int compute_rhs_z4c_cartesian(
double Axxx[all], Axxy[all], Axxz[all], Axyx[all], Axyy[all], Axyz[all];
double Axzx[all], Axzy[all], Axzz[all], Ayyx[all], Ayyy[all], Ayyz[all];
double Ayzx[all], Ayzy[all], Ayzz[all], Azzx[all], Azzy[all], Azzz[all];
#if (GAUGE == 2 || GAUGE == 3 || GAUGE == 4 || GAUGE == 5)
double reta[all];
#endif
const double SSS[3] = {1.0, 1.0, 1.0};
const double AAS[3] = {-1.0, -1.0, 1.0};
@@ -479,181 +476,8 @@ static int compute_rhs_z4c_cartesian(
dtSfy_rhs[idx] = ZEO;
dtSfz_rhs[idx] = ZEO;
}
#elif (GAUGE == 2)
/* Variable-eta gamma-driver, chi-sqrt denominator */
for (int idx = 0; idx < all; ++idx)
{
const double chin1i = chin1[idx];
const double det = gxx[idx] * gyy[idx] * gzz[idx]
+ gxy[idx] * gyz[idx] * gxz[idx] * 2.0
- gxz[idx] * gyy[idx] * gxz[idx]
- gxy[idx] * gxy[idx] * gzz[idx]
- gxx[idx] * gyz[idx] * gyz[idx];
const double idet = ONE / det;
const double upxx = (gyy[idx] * gzz[idx] - gyz[idx] * gyz[idx]) * idet;
const double upxy = -(gxy[idx] * gzz[idx] - gyz[idx] * gxz[idx]) * idet;
const double upxz = (gxy[idx] * gyz[idx] - gyy[idx] * gxz[idx]) * idet;
const double upyy = (gxx[idx] * gzz[idx] - gxz[idx] * gxz[idx]) * idet;
const double upyz = -(gxx[idx] * gyz[idx] - gxy[idx] * gxz[idx]) * idet;
const double upzz = (gxx[idx] * gyy[idx] - gxy[idx] * gxy[idx]) * idet;
const double grdchi2 =
upxx * chix[idx] * chix[idx] + upyy * chiy[idx] * chiy[idx] + upzz * chiz[idx] * chiz[idx]
+ TWO * (upxy * chix[idx] * chiy[idx] + upxz * chix[idx] * chiz[idx] + upyz * chiy[idx] * chiz[idx]);
const double sqchi = sqrt(chin1i);
reta[idx] = 1.31 / TWO * sqrt(grdchi2 / chin1i) / ((ONE - sqchi) * (ONE - sqchi));
betax_rhs[idx] = FF * dtSfx[idx];
betay_rhs[idx] = FF * dtSfy[idx];
betaz_rhs[idx] = FF * dtSfz[idx];
dtSfx_rhs[idx] = Gamx_rhs[idx] - reta[idx] * dtSfx[idx];
dtSfy_rhs[idx] = Gamy_rhs[idx] - reta[idx] * dtSfy[idx];
dtSfz_rhs[idx] = Gamz_rhs[idx] - reta[idx] * dtSfz[idx];
}
#elif (GAUGE == 3)
/* Variable-eta gamma-driver, chi-linear denominator */
for (int idx = 0; idx < all; ++idx)
{
const double chin1i = chin1[idx];
const double det = gxx[idx] * gyy[idx] * gzz[idx]
+ gxy[idx] * gyz[idx] * gxz[idx] * 2.0
- gxz[idx] * gyy[idx] * gxz[idx]
- gxy[idx] * gxy[idx] * gzz[idx]
- gxx[idx] * gyz[idx] * gyz[idx];
const double idet = ONE / det;
const double upxx = (gyy[idx] * gzz[idx] - gyz[idx] * gyz[idx]) * idet;
const double upxy = -(gxy[idx] * gzz[idx] - gyz[idx] * gxz[idx]) * idet;
const double upxz = (gxy[idx] * gyz[idx] - gyy[idx] * gxz[idx]) * idet;
const double upyy = (gxx[idx] * gzz[idx] - gxz[idx] * gxz[idx]) * idet;
const double upyz = -(gxx[idx] * gyz[idx] - gxy[idx] * gxz[idx]) * idet;
const double upzz = (gxx[idx] * gyy[idx] - gxy[idx] * gxy[idx]) * idet;
const double grdchi2 =
upxx * chix[idx] * chix[idx] + upyy * chiy[idx] * chiy[idx] + upzz * chiz[idx] * chiz[idx]
+ TWO * (upxy * chix[idx] * chiy[idx] + upxz * chix[idx] * chiz[idx] + upyz * chiy[idx] * chiz[idx]);
reta[idx] = 1.31 / TWO * sqrt(grdchi2 / chin1i) / ((ONE - chin1i) * (ONE - chin1i));
betax_rhs[idx] = FF * dtSfx[idx];
betay_rhs[idx] = FF * dtSfy[idx];
betaz_rhs[idx] = FF * dtSfz[idx];
dtSfx_rhs[idx] = Gamx_rhs[idx] - reta[idx] * dtSfx[idx];
dtSfy_rhs[idx] = Gamy_rhs[idx] - reta[idx] * dtSfy[idx];
dtSfz_rhs[idx] = Gamz_rhs[idx] - reta[idx] * dtSfz[idx];
}
#elif (GAUGE == 4)
/* Variable-eta gamma-driver, first-order, chi-sqrt denominator */
for (int idx = 0; idx < all; ++idx)
{
const double chin1i = chin1[idx];
const double det = gxx[idx] * gyy[idx] * gzz[idx]
+ gxy[idx] * gyz[idx] * gxz[idx] * 2.0
- gxz[idx] * gyy[idx] * gxz[idx]
- gxy[idx] * gxy[idx] * gzz[idx]
- gxx[idx] * gyz[idx] * gyz[idx];
const double idet = ONE / det;
const double upxx = (gyy[idx] * gzz[idx] - gyz[idx] * gyz[idx]) * idet;
const double upxy = -(gxy[idx] * gzz[idx] - gyz[idx] * gxz[idx]) * idet;
const double upxz = (gxy[idx] * gyz[idx] - gyy[idx] * gxz[idx]) * idet;
const double upyy = (gxx[idx] * gzz[idx] - gxz[idx] * gxz[idx]) * idet;
const double upyz = -(gxx[idx] * gyz[idx] - gxy[idx] * gxz[idx]) * idet;
const double upzz = (gxx[idx] * gyy[idx] - gxy[idx] * gxy[idx]) * idet;
const double grdchi2 =
upxx * chix[idx] * chix[idx] + upyy * chiy[idx] * chiy[idx] + upzz * chiz[idx] * chiz[idx]
+ TWO * (upxy * chix[idx] * chiy[idx] + upxz * chix[idx] * chiz[idx] + upyz * chiy[idx] * chiz[idx]);
const double sqchi = sqrt(chin1i);
reta[idx] = 1.31 / TWO * sqrt(grdchi2 / chin1i) / ((ONE - sqchi) * (ONE - sqchi));
betax_rhs[idx] = Gamx_rhs[idx] - reta[idx] * betax[idx];
betay_rhs[idx] = Gamy_rhs[idx] - reta[idx] * betay[idx];
betaz_rhs[idx] = Gamz_rhs[idx] - reta[idx] * betaz[idx];
dtSfx_rhs[idx] = ZEO;
dtSfy_rhs[idx] = ZEO;
dtSfz_rhs[idx] = ZEO;
}
#elif (GAUGE == 5)
/* Variable-eta gamma-driver, first-order, chi-linear denominator */
for (int idx = 0; idx < all; ++idx)
{
const double chin1i = chin1[idx];
const double det = gxx[idx] * gyy[idx] * gzz[idx]
+ gxy[idx] * gyz[idx] * gxz[idx] * 2.0
- gxz[idx] * gyy[idx] * gxz[idx]
- gxy[idx] * gxy[idx] * gzz[idx]
- gxx[idx] * gyz[idx] * gyz[idx];
const double idet = ONE / det;
const double upxx = (gyy[idx] * gzz[idx] - gyz[idx] * gyz[idx]) * idet;
const double upxy = -(gxy[idx] * gzz[idx] - gyz[idx] * gxz[idx]) * idet;
const double upxz = (gxy[idx] * gyz[idx] - gyy[idx] * gxz[idx]) * idet;
const double upyy = (gxx[idx] * gzz[idx] - gxz[idx] * gxz[idx]) * idet;
const double upyz = -(gxx[idx] * gyz[idx] - gxy[idx] * gxz[idx]) * idet;
const double upzz = (gxx[idx] * gyy[idx] - gxy[idx] * gxy[idx]) * idet;
const double grdchi2 =
upxx * chix[idx] * chix[idx] + upyy * chiy[idx] * chiy[idx] + upzz * chiz[idx] * chiz[idx]
+ TWO * (upxy * chix[idx] * chiy[idx] + upxz * chix[idx] * chiz[idx] + upyz * chiy[idx] * chiz[idx]);
reta[idx] = 1.31 / TWO * sqrt(grdchi2 / chin1i) / ((ONE - chin1i) * (ONE - chin1i));
betax_rhs[idx] = Gamx_rhs[idx] - reta[idx] * betax[idx];
betay_rhs[idx] = Gamy_rhs[idx] - reta[idx] * betay[idx];
betaz_rhs[idx] = Gamz_rhs[idx] - reta[idx] * betaz[idx];
dtSfx_rhs[idx] = ZEO;
dtSfy_rhs[idx] = ZEO;
dtSfz_rhs[idx] = ZEO;
}
#elif (GAUGE == 6 || GAUGE == 7)
{
/* Jason's position-dependent damping: rational (6) or exponential (7) */
int BHN = 0;
double Porg[9] = {0.0};
double Mass[3] = {0.0};
#ifdef fortran1
extern "C" { void getpbh(int &, double *, double *); }
#elif defined(fortran2)
extern "C" { void GETPBH(int &, double *, double *); }
#else
extern "C" { void getpbh_(int &, double *, double *); }
#endif
{
#ifdef fortran1
getpbh(BHN, Porg, Mass);
#elif defined(fortran2)
GETPBH(BHN, Porg, Mass);
#else
getpbh_(BHN, Porg, Mass);
#endif
}
if (BHN == 2)
{
const double M = Mass[0] + Mass[1];
const double A = 2.0 / M;
const double w1 = 12.0, w2 = 12.0;
const double C1 = 1.0 / Mass[0] - A;
const double C2 = 1.0 / Mass[1] - A;
const double BH_sep2 = (Porg[3] - Porg[0]) * (Porg[3] - Porg[0])
+ (Porg[4] - Porg[1]) * (Porg[4] - Porg[1])
+ (Porg[5] - Porg[2]) * (Porg[5] - Porg[2]);
const double inv_BH_sep2 = 1.0 / BH_sep2;
for (int k0 = 0; k0 < nz; ++k0) {
for (int j0 = 0; j0 < ny; ++j0) {
for (int i0 = 0; i0 < nx; ++i0) {
const size_t idx = idx_ex(i0, j0, k0, ex);
const double xp = X[i0], yp = Y[j0], zp = Z[k0];
const double r1 = ((Porg[0]-xp)*(Porg[0]-xp) + (Porg[1]-yp)*(Porg[1]-yp) + (Porg[2]-zp)*(Porg[2]-zp)) * inv_BH_sep2;
const double r2 = ((Porg[3]-xp)*(Porg[3]-xp) + (Porg[4]-yp)*(Porg[4]-yp) + (Porg[5]-zp)*(Porg[5]-zp)) * inv_BH_sep2;
#if (GAUGE == 6)
const double reta_val = A + C1 / (1.0 + w1 * r1) + C2 / (1.0 + w2 * r2);
#else
const double reta_val = A + C1 * exp(-w1 * r1) + C2 * exp(-w2 * r2);
#endif
betax_rhs[idx] = FF * dtSfx[idx];
betay_rhs[idx] = FF * dtSfy[idx];
betaz_rhs[idx] = FF * dtSfz[idx];
dtSfx_rhs[idx] = Gamx_rhs[idx] - reta_val * dtSfx[idx];
dtSfy_rhs[idx] = Gamy_rhs[idx] - reta_val * dtSfy[idx];
dtSfz_rhs[idx] = Gamz_rhs[idx] - reta_val * dtSfz[idx];
}}}
}
else
{
fprintf(stderr, "z4c_rhs_c: GAUGE %d requires BHN=2, got BHN=%d\n", (int)GAUGE, BHN);
return 1;
}
}
#else
#error "z4c_rhs_c.C: unsupported GAUGE value"
#error "z4c_rhs_c.C currently supports GAUGE == 0 or GAUGE == 1 for Z4C"
#endif
lopsided(ex, X, Y, Z, gxx, gxx_rhs, betax, betay, betaz, Symmetry, SSS);
@@ -681,7 +505,7 @@ static int compute_rhs_z4c_cartesian(
lopsided(ex, X, Y, Z, betax, betax_rhs, betax, betay, betaz, Symmetry, ASS);
lopsided(ex, X, Y, Z, betay, betay_rhs, betax, betay, betaz, Symmetry, SAS);
lopsided(ex, X, Y, Z, betaz, betaz_rhs, betax, betay, betaz, Symmetry, SSA);
#if (GAUGE == 0 || GAUGE == 2 || GAUGE == 3 || GAUGE == 6 || GAUGE == 7)
#if (GAUGE == 0)
lopsided(ex, X, Y, Z, dtSfx, dtSfx_rhs, betax, betay, betaz, Symmetry, ASS);
lopsided(ex, X, Y, Z, dtSfy, dtSfy_rhs, betax, betay, betaz, Symmetry, SAS);
lopsided(ex, X, Y, Z, dtSfz, dtSfz_rhs, betax, betay, betaz, Symmetry, SSA);
@@ -728,7 +552,7 @@ static int compute_rhs_z4c_cartesian(
kodis(ex, X, Y, Z, betax, betax_rhs, ASS, Symmetry, eps);
kodis(ex, X, Y, Z, betay, betay_rhs, SAS, Symmetry, eps);
kodis(ex, X, Y, Z, betaz, betaz_rhs, SSA, Symmetry, eps);
#if (GAUGE == 0 || GAUGE == 2 || GAUGE == 3 || GAUGE == 6 || GAUGE == 7)
#if (GAUGE == 0)
kodis(ex, X, Y, Z, dtSfx, dtSfx_rhs, ASS, Symmetry, eps);
kodis(ex, X, Y, Z, dtSfy, dtSfy_rhs, SAS, Symmetry, eps);
kodis(ex, X, Y, Z, dtSfz, dtSfz_rhs, SSA, Symmetry, eps);

7909
AMSS_NCKU_source/z4c_rhs_cuda.cu Normal file
View File

File diff suppressed because it is too large Load Diff

114
AMSS_NCKU_source/z4c_rhs_cuda.h Normal file
View File

@@ -0,0 +1,114 @@
#ifndef Z4C_RHS_CUDA_H
#define Z4C_RHS_CUDA_H
#ifdef __cplusplus
extern "C" {
#endif
enum {
Z4C_CUDA_STATE_COUNT = 25
};
int z4c_cuda_rk4_substep(void *block_tag,
int *ex, double *X, double *Y, double *Z,
double **state_host_in,
double **state_host_out,
const double *propspeed,
const double *soa_flat,
const double *bbox,
double &dT,
double &T,
int &RK4,
int &apply_bam_bc,
int &Symmetry,
int &Lev,
double &eps,
int &co,
int &keep_resident_state,
int &apply_enforce_ga,
double &chitiny);
int z4c_cuda_download_resident_state(void *block_tag,
int *ex,
double **state_host_out);
int z4c_cuda_pack_state_region_to_host_buffer(void *block_tag,
int state_index,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int z4c_cuda_unpack_state_region_from_host_buffer(void *block_tag,
int state_index,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int z4c_cuda_pack_state_batch_to_host_buffer(void *block_tag,
int state_count,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int z4c_cuda_unpack_state_batch_from_host_buffer(void *block_tag,
int state_count,
double *host_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int z4c_cuda_pack_state_batch_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int z4c_cuda_unpack_state_batch_from_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int i0, int j0, int k0,
int sx, int sy, int sz);
int z4c_cuda_restrict_state_batch_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int sx, int sy, int sz,
int fi0, int fj0, int fk0,
const double *state_soa);
int z4c_cuda_prolong_state_batch_to_device_buffer(void *block_tag,
int state_count,
double *device_buffer,
int *ex,
int sx, int sy, int sz,
int ii0, int jj0, int kk0,
int lbc_i, int lbc_j, int lbc_k,
const double *state_soa);
int z4c_cuda_download_state_subset(void *block_tag,
int *ex,
int subset_count,
const int *state_indices,
double **state_host_out);
int z4c_cuda_upload_state_subset(void *block_tag,
int *ex,
int subset_count,
const int *state_indices,
double **state_host_in);
int z4c_cuda_has_resident_state(void *block_tag);
void z4c_cuda_release_step_ctx(void *block_tag);
#ifdef __cplusplus
}
#endif
#endif

211
BSSN_BUILD_CONFIG_MIGRATION.md
View File

@@ -1,211 +0,0 @@
# BSSN Build Config Migration
This note records the build-configuration fix needed when replacing
`AMSS_NCKU_Input.py` or `generate_macrodef.py` with a newer upstream version.
## Problem
`AMSS_NCKU_source/macrodef.h` is not the authoritative file used by normal
runs. `AMSS_NCKU_Program.py` first generates macro files under
`input_data.File_directory`, copies `AMSS_NCKU_source` to
`<File_directory>/AMSS_NCKU_source_copy`, then copies the generated macro files
into that copied source tree and compiles there.
Therefore, makefile logic must not depend only on the stale
`AMSS_NCKU_source/macrodef.h`. The actual equation path must be passed to the
copied build tree from the same generation step that creates `macrodef.h`.
The performance regression was caused by compiling/linking the
`BSSN-EScalar` C wrapper into BSSN vacuum builds. For BSSN vacuum (`ABEtype=0`),
the build must use:
```make
BSSN_USE_TRANSFER_CACHE=1
BSSN_USE_ESCALAR_C_KERNEL=0
```
and must not link `bssn_escalar_rhs_c.o`.
## Required Migration Steps
### 1. Add an ABE type helper in `generate_macrodef.py`
Add a helper that maps `input_data.Equation_Class` to the numeric `ABEtype`.
Use the same mapping as `macrodef.h`:
```python
def get_abe_type():
if ( input_data.Equation_Class == "BSSN" ):
return 0
elif ( input_data.Equation_Class == "BSSN-EScalar" ):
return 1
elif ( input_data.Equation_Class == "BSSN-EM" ):
return 3
elif ( input_data.Equation_Class == "Z4C" ):
return 2
else:
raise ValueError("Equation_Class setting error!!!")
```
Update `generate_macrodef_h()` to print `#define ABEtype {get_abe_type()}`
instead of duplicating the if/elif mapping.
### 2. Generate a makefile fragment
In `generate_macrodef.py`, add:
```python
def generate_build_config():
file1 = open(os.path.join(input_data.File_directory, "AMSS_NCKU_build.mk"), "w")
print("# Generated by generate_macrodef.py; do not edit manually.", file=file1)
print(f"ABE_TYPE := {get_abe_type()}", file=file1)
file1.close()
```
This file is the build-time authority for the equation path.
### 3. Call and copy the generated build config
In `AMSS_NCKU_Program.py`, after generating `macrodef.h` and `macrodef.fh`, call:
```python
generate_macrodef.generate_build_config()
print(" AMSS-NCKU build config AMSS_NCKU_build.mk has been generated. ")
```
When copying generated files into `AMSS_NCKU_source_copy`, also copy:
```python
build_config_path = os.path.join(File_directory, "AMSS_NCKU_build.mk")
shutil.copy2(build_config_path, AMSS_NCKU_source_copy)
```
### 4. Make the source makefile consume the generated config
At the top of `AMSS_NCKU_source/makefile`, after `include makefile.inc`, add:
```make
-include AMSS_NCKU_build.mk
ABE_TYPE ?= $(shell awk '/^[[:space:]]*\#define[[:space:]]+ABEtype/ {print $$3; exit}' macrodef.h 2>/dev/null)
```
The generated `AMSS_NCKU_build.mk` is used during normal Python-driven builds.
The fallback keeps manual source-tree builds usable.
### 5. Gate path-specific build options by `ABE_TYPE`
Use effective build switches:
```make
ifeq ($(USE_TRANSFER_CACHE),auto)
ifeq ($(ABE_TYPE),0)
EFFECTIVE_USE_TRANSFER_CACHE = 1
else
EFFECTIVE_USE_TRANSFER_CACHE = 0
endif
else
EFFECTIVE_USE_TRANSFER_CACHE = $(USE_TRANSFER_CACHE)
endif
ifeq ($(USE_CXX_ESCALAR_KERNEL),1)
ifeq ($(ABE_TYPE),1)
EFFECTIVE_USE_CXX_ESCALAR_KERNEL = 1
else
EFFECTIVE_USE_CXX_ESCALAR_KERNEL = 0
endif
else
EFFECTIVE_USE_CXX_ESCALAR_KERNEL = 0
endif
TRANSFER_CACHE_FLAG = -DBSSN_USE_TRANSFER_CACHE=$(EFFECTIVE_USE_TRANSFER_CACHE)
ESCALAR_KERNEL_FLAG = -DBSSN_USE_ESCALAR_C_KERNEL=$(EFFECTIVE_USE_CXX_ESCALAR_KERNEL)
```
Only add `bssn_escalar_rhs_c.o` when the effective EScalar C kernel switch is
enabled:
```make
ifeq ($(EFFECTIVE_USE_CXX_ESCALAR_KERNEL),1)
CFILES += bssn_escalar_rhs_c.o
endif
```
### 6. Use safe transfer-cache default
In `AMSS_NCKU_source/makefile.inc`, keep:
```make
USE_TRANSFER_CACHE ?= auto
```
With the effective switch logic above, this enables cached transfer for BSSN
vacuum while keeping non-BSSN paths on the uncached path by default.
## Verification Checklist
Run these checks after migrating:
```bash
python3 -c "import generate_macrodef; generate_macrodef.generate_build_config()"
cat GW150914/AMSS_NCKU_build.mk
```
For BSSN, the generated file should contain:
```make
ABE_TYPE := 0
```
Dry-run the copied or source makefile:
```bash
make -n -B INTERP_LB_MODE=off ABE | grep -E 'BSSN_USE_TRANSFER_CACHE|BSSN_USE_ESCALAR_C_KERNEL|bssn_escalar_rhs_c'
```
Expected BSSN result:
```text
-DBSSN_USE_TRANSFER_CACHE=1 -DBSSN_USE_ESCALAR_C_KERNEL=0
```
and no `bssn_escalar_rhs_c.o` in the final link command.
Run the full workflow:
```bash
python3 AMSS_NCKU_Program.py
```
For the 10-step BSSN test, compare coordinate output:
```bash
python3 - <<'PY'
from pathlib import Path
old = Path('../GW150914-06457/AMSS_NCKU_output/bssn_BH.dat')
new = Path('GW150914/AMSS_NCKU_output/bssn_BH.dat')
def rows(path):
out = []
for line in path.read_text().splitlines():
if not line.strip() or line.lstrip().startswith('#'):
continue
out.append([float(x) for x in line.split()])
return out
ro, rn = rows(old), rows(new)
n = min(len(ro), len(rn))
max_abs = 0.0
for i in range(n):
for a, b in zip(ro[i], rn[i]):
max_abs = max(max_abs, abs(a - b))
print(f"old_rows={len(ro)} new_rows={len(rn)} compared_rows={n}")
print(f"max_abs_diff={max_abs:.17g}")
PY
```
For the validated migration, the first 10 rows matched exactly:
```text
max_abs_diff=0
```

50
generate_macrodef.py
View File

@@ -12,37 +12,6 @@ import os
import AMSS_NCKU_Input as input_data ## import program input file
##################################################################
def get_abe_type():
if ( input_data.Equation_Class == "BSSN" ):
return 0
elif ( input_data.Equation_Class == "BSSN-EScalar" ):
return 1
elif ( input_data.Equation_Class == "BSSN-EM" ):
return 3
elif ( input_data.Equation_Class == "Z4C" ):
return 2
else:
raise ValueError("Equation_Class setting error!!!")
##################################################################
## Generate the makefile fragment used by the copied source tree.
## The source-tree macrodef.h is not authoritative because macro files
## are regenerated under File_directory for each run.
def generate_build_config():
file1 = open( os.path.join(input_data.File_directory, "AMSS_NCKU_build.mk"), "w")
print( "# Generated by generate_macrodef.py; do not edit manually.", file=file1 )
print( f"ABE_TYPE := {get_abe_type()}", file=file1 )
file1.close()
##################################################################
## Generate the macro file macrodef.h according to user settings
@@ -89,10 +58,19 @@ def generate_macrodef_h():
# 2: Z4c vacuum
# 3: coupled to Maxwell field
try:
print( f"#define ABEtype {get_abe_type()}", file=file1 )
print( file=file1 )
except ValueError:
if ( input_data.Equation_Class == "BSSN" ):
print( "#define ABEtype 0", file=file1 )
print( file=file1 )
elif ( input_data.Equation_Class == "BSSN-EScalar" ):
print( "#define ABEtype 1", file=file1 )
print( file=file1 )
elif ( input_data.Equation_Class == "BSSN-EM" ):
print( "#define ABEtype 3", file=file1 )
print( file=file1 )
elif ( input_data.Equation_Class == "Z4C" ):
print( "#define ABEtype 2", file=file1 )
print( file=file1 )
else:
print( "Equation_Class setting error!!!" )
print()
print( "# Equation type #define ABEtype setting error!!!", file=file1 )
@@ -226,7 +204,7 @@ def generate_macrodef_h():
# use GPU or not
if ( input_data.GPU_Calculation == "yes"):
print( "#define USE_GPU", file=file1 )
print( "//#define USE_GPU", file=file1 )
print( file=file1 )
elif ( input_data.GPU_Calculation == "no"):
print( "//#define USE_GPU", file=file1 )

283
makefile_and_run.py
View File

@@ -9,6 +9,8 @@
import AMSS_NCKU_Input as input_data
import os
import shutil
import subprocess
import time
@@ -56,6 +58,198 @@ BUILD_JOBS = 64
##################################################################
def _truthy(value, default=False):
if value is None:
return default
if isinstance(value, bool):
return value
text = str(value).strip().lower()
if text == "":
return default
return text in ("1", "yes", "y", "true", "on", "enable", "enabled")
def _input_or_env(input_name, env_name, default=None):
if env_name in os.environ:
return os.environ[env_name]
return getattr(input_data, input_name, default)
def _input_env_passthrough(runtime_env, env_name):
if env_name in runtime_env:
return
if hasattr(input_data, env_name):
runtime_env[env_name] = str(getattr(input_data, env_name))
def _start_cuda_mps_if_requested(runtime_env):
if input_data.GPU_Calculation != "yes":
return False
default_auto_mps = int(getattr(input_data, "MPI_processes", 1)) > 1
auto_mps = _truthy(
_input_or_env("CUDA_Auto_MPS", "AMSS_CUDA_AUTO_MPS", default_auto_mps),
default=default_auto_mps,
)
if not auto_mps:
return False
mps_control = shutil.which("nvidia-cuda-mps-control")
if not mps_control:
print(" CUDA MPS control command was not found; running without MPS.")
return False
uid = os.getuid()
pipe_dir = str(_input_or_env("CUDA_MPS_PIPE_DIRECTORY", "CUDA_MPS_PIPE_DIRECTORY",
f"/tmp/amss-ncku-mps-{uid}"))
log_dir = str(_input_or_env("CUDA_MPS_LOG_DIRECTORY", "CUDA_MPS_LOG_DIRECTORY",
f"/tmp/amss-ncku-mps-log-{uid}"))
os.makedirs(pipe_dir, exist_ok=True)
os.makedirs(log_dir, exist_ok=True)
mps_env = runtime_env.copy()
mps_env["CUDA_MPS_PIPE_DIRECTORY"] = pipe_dir
mps_env["CUDA_MPS_LOG_DIRECTORY"] = log_dir
if os.path.exists(os.path.join(pipe_dir, "control")):
runtime_env.update({
"CUDA_MPS_PIPE_DIRECTORY": pipe_dir,
"CUDA_MPS_LOG_DIRECTORY": log_dir,
})
print(f" Reusing CUDA MPS daemon: {pipe_dir}")
return False
print(f" Starting CUDA MPS daemon for this run: {pipe_dir}")
result = subprocess.run([mps_control, "-d"], env=mps_env, text=True,
stdout=subprocess.PIPE, stderr=subprocess.STDOUT)
if result.returncode != 0:
print(" CUDA MPS daemon did not start; running without MPS.")
if result.stdout:
print(result.stdout, end="")
return False
runtime_env.update({
"CUDA_MPS_PIPE_DIRECTORY": pipe_dir,
"CUDA_MPS_LOG_DIRECTORY": log_dir,
})
return True
def _stop_cuda_mps(runtime_env):
mps_control = shutil.which("nvidia-cuda-mps-control")
if not mps_control:
return
subprocess.run([mps_control], input="quit\n", env=runtime_env, text=True,
stdout=subprocess.PIPE, stderr=subprocess.STDOUT)
def _gpu_runtime_env():
runtime_env = os.environ.copy()
finite_difference = str(getattr(input_data, "Finite_Diffenence_Method", "4th-order")).strip()
defaults = {
"AMSS_EVOLVE_TIMING": "1",
"AMSS_ESCALAR_STEP_TIMING": "0",
"AMSS_INTERP_FAST": "1",
"AMSS_INTERP_GPU": "1",
"AMSS_ANALYSIS_MAP_EVERY": "1000000",
"AMSS_CUDA_AWARE_MPI": "1",
"AMSS_CUDA_KEEP_RESIDENT_AFTER_STEP": "1",
"AMSS_CUDA_KEEP_ALL_LEVELS": "1",
"AMSS_CUDA_ESCALAR_KEEP_RESIDENT_AFTER_STEP": "1",
"AMSS_CUDA_ESCALAR_KEEP_ALL_LEVELS": "1",
"AMSS_CUDA_EM_CACHE_SOURCES": "1",
"AMSS_CUDA_EM_ZERO_FASTPATH": "1",
"AMSS_EM_ZERO_ANALYSIS_FASTPATH": "1",
"AMSS_EM_ZERO_RESIDENT_DOWNLOAD_FASTPATH": "1",
"AMSS_CUDA_AMR_HOST_STAGED": "1",
"AMSS_CUDA_AMR_RESTRICT_DEVICE": "0",
"AMSS_CUDA_AMR_RESTRICT_BATCH": "0",
"AMSS_CUDA_DEVICE_SEGMENT_BATCH": "0",
"AMSS_CUDA_UNCACHED_DEVICE_BUFFERS": "1",
"AMSS_SHELL_FAST_INTERP": "0",
"AMSS_SHELL_PARALLEL_INTERP": "0",
"AMSS_SHELL_CUDA_INTERP": "0",
}
if finite_difference in ("2nd-order", "8th-order"):
defaults.update({
"AMSS_INTERP_FAST": "0",
"AMSS_INTERP_GPU": "0",
"AMSS_CUDA_AWARE_MPI": "0",
})
if finite_difference == "8th-order" and getattr(input_data, "Equation_Class", "") == "BSSN-EM":
defaults.update({
"AMSS_CUDA_AMR_RESTRICT_DEVICE": "1",
"AMSS_CUDA_AMR_RESTRICT_BATCH": "1",
"AMSS_CUDA_DEVICE_SEGMENT_BATCH": "1",
})
if getattr(input_data, "basic_grid_set", "") == "Shell-Patch":
defaults.update({
"AMSS_CUDA_AWARE_MPI": "0",
"AMSS_SHELL_FAST_INTERP": "1",
"AMSS_SHELL_PARALLEL_INTERP": "1",
"AMSS_SHELL_INTERP_THREADS": "16",
})
if getattr(input_data, "Equation_Class", "") in ("BSSN", "BSSN-EScalar", "Z4C"):
defaults["AMSS_CUDA_AMR_RESTRICT_DEVICE"] = "1"
if getattr(input_data, "Equation_Class", "") == "Z4C":
defaults.update({
"AMSS_Z4C_CUDA_RESIDENT": "1",
"AMSS_CONSTRAINT_OUT_EVERY": "1000000",
})
for key, value in defaults.items():
runtime_env.setdefault(key, value)
passthrough_envs = [
"AMSS_CUDA_RESIDENT_SYNC",
"AMSS_CUDA_BSSN_RESIDENT_SYNC",
"AMSS_CUDA_EM_RESIDENT_SYNC",
"AMSS_CUDA_ESCALAR_RESIDENT_SYNC",
"AMSS_CUDA_BH_INTERP_RESIDENT",
"AMSS_CUDA_KEEP_RESIDENT_AFTER_STEP",
"AMSS_CUDA_KEEP_ALL_LEVELS",
"AMSS_CUDA_EM_KEEP_RESIDENT_AFTER_STEP",
"AMSS_CUDA_EM_KEEP_ALL_LEVELS",
"AMSS_CUDA_ESCALAR_KEEP_RESIDENT_AFTER_STEP",
"AMSS_CUDA_ESCALAR_KEEP_ALL_LEVELS",
"AMSS_CUDA_AMR_HOST_STAGED",
"AMSS_CUDA_AMR_RESTRICT_DEVICE",
"AMSS_CUDA_AMR_RESTRICT_BATCH",
"AMSS_CUDA_DEVICE_SEGMENT_BATCH",
"AMSS_CUDA_UNCACHED_DEVICE_BUFFERS",
"AMSS_CUDA_EM_CACHE_SOURCES",
"AMSS_CUDA_EM_ZERO_FASTPATH",
"AMSS_CUDA_AWARE_MPI",
"AMSS_CUDA_REGRID_FLUSH_ALWAYS",
"AMSS_Z4C_CUDA_RESIDENT",
"AMSS_SHELL_FAST_INTERP",
"AMSS_SHELL_PARALLEL_INTERP",
"AMSS_SHELL_CUDA_INTERP",
"AMSS_SHELL_INTERP_THREADS",
"AMSS_EM_ZERO_ANALYSIS_FASTPATH",
"AMSS_EM_ZERO_RESIDENT_DOWNLOAD_FASTPATH",
"AMSS_INTERP_FAST",
"AMSS_INTERP_GPU",
]
for env_name in passthrough_envs:
_input_env_passthrough(runtime_env, env_name)
optional_overrides = {
"AMSS_INTERP_FAST_COMPARE": "AMSS_Interp_Fast_Compare",
"AMSS_INTERP_FAST_COMPARE_LIMIT": "AMSS_Interp_Fast_Compare_Limit",
"AMSS_INTERP_FAST_COMPARE_TOL": "AMSS_Interp_Fast_Compare_Tol",
"AMSS_GPU_STAGE_TIMING": "AMSS_GPU_Stage_Timing",
"AMSS_GPU_STAGE_TIMING_EVERY": "AMSS_GPU_Stage_Timing_Every",
}
for env_name, input_name in optional_overrides.items():
if env_name not in runtime_env and hasattr(input_data, input_name):
runtime_env[env_name] = str(getattr(input_data, input_name))
return runtime_env
##################################################################
##################################################################
@@ -68,11 +262,13 @@ def makefile_ABE():
print( " Compiling the AMSS-NCKU executable file ABE/ABEGPU " )
print( )
z4c_mrbd = int(getattr(input_data, "AMSS_Z4C_MRBD", 0))
## Build command with CPU binding to nohz_full cores
if (input_data.GPU_Calculation == "no"):
makefile_command = f"{NUMACTL_CPU_BIND} make -j{BUILD_JOBS} INTERP_LB_MODE=off ABE"
makefile_command = f"{NUMACTL_CPU_BIND} env AMSS_Z4C_MRBD={z4c_mrbd} make -j{BUILD_JOBS} INTERP_LB_MODE=off USE_CUDA_BSSN=0 USE_CUDA_Z4C=0 ABE"
elif (input_data.GPU_Calculation == "yes"):
makefile_command = f"{NUMACTL_CPU_BIND} make -j{BUILD_JOBS} ABEGPU"
makefile_command = f"{NUMACTL_CPU_BIND} env AMSS_Z4C_MRBD={z4c_mrbd} make -j{BUILD_JOBS} INTERP_LB_MODE=off USE_CUDA_BSSN=1 USE_CUDA_Z4C=1 ABE_CUDA"
else:
print( " CPU/GPU numerical calculation setting is wrong " )
print( )
@@ -145,29 +341,84 @@ def run_ABE():
print( )
## Define the command to run; cast other values to strings as needed
mpi_env = None
started_mps = False
mpi_processes = int(input_data.MPI_processes)
if (input_data.GPU_Calculation == "yes" and
getattr(input_data, "Equation_Class", "") == "Z4C"):
z4c_env_np = os.environ.get("AMSS_Z4C_GPU_MPI_PROCESSES")
if z4c_env_np and int(z4c_env_np) > 0:
mpi_processes = int(z4c_env_np)
elif mpi_processes < 4:
mpi_processes = 4
if (input_data.GPU_Calculation == "yes" and
getattr(input_data, "basic_grid_set", "") == "Shell-Patch"):
shell_env_np = os.environ.get("AMSS_SHELL_GPU_MPI_PROCESSES")
if shell_env_np and int(shell_env_np) > 0:
mpi_processes = int(shell_env_np)
elif mpi_processes < 4:
mpi_processes = 4
if (input_data.GPU_Calculation == "no"):
mpi_command = NUMACTL_CPU_BIND + " mpirun -np " + str(input_data.MPI_processes) + " ./ABE"
mpi_command = NUMACTL_CPU_BIND + " mpirun -np " + str(mpi_processes) + " ./ABE"
#mpi_command = " mpirun -np " + str(input_data.MPI_processes) + " ./ABE"
mpi_command_outfile = "ABE_out.log"
elif (input_data.GPU_Calculation == "yes"):
mpi_command = NUMACTL_CPU_BIND + " mpirun -np " + str(input_data.MPI_processes) + " ./ABEGPU"
mpi_command = NUMACTL_CPU_BIND + " I_MPI_OFFLOAD=1 I_MPI_OFFLOAD_IPC=0 mpirun -np " + str(mpi_processes) + " ./ABE_CUDA"
mpi_command_outfile = "ABEGPU_out.log"
mpi_env = _gpu_runtime_env()
started_mps = _start_cuda_mps_if_requested(mpi_env)
print(" GPU optimized runtime switches:")
print(f" MPI processes={mpi_processes}")
print(f" AMSS_INTERP_FAST={mpi_env.get('AMSS_INTERP_FAST', '')}")
print(f" AMSS_INTERP_GPU={mpi_env.get('AMSS_INTERP_GPU', '')}")
print(f" AMSS_ANALYSIS_MAP_EVERY={mpi_env.get('AMSS_ANALYSIS_MAP_EVERY', '')}")
print(f" AMSS_EVOLVE_TIMING={mpi_env.get('AMSS_EVOLVE_TIMING', '')}")
print(f" AMSS_ESCALAR_STEP_TIMING={mpi_env.get('AMSS_ESCALAR_STEP_TIMING', '')}")
print(f" AMSS_CUDA_AWARE_MPI={mpi_env.get('AMSS_CUDA_AWARE_MPI', '')}")
print(f" AMSS_CUDA_KEEP_RESIDENT_AFTER_STEP={mpi_env.get('AMSS_CUDA_KEEP_RESIDENT_AFTER_STEP', '')}")
print(f" AMSS_CUDA_KEEP_ALL_LEVELS={mpi_env.get('AMSS_CUDA_KEEP_ALL_LEVELS', '')}")
print(f" AMSS_CUDA_ESCALAR_KEEP_RESIDENT_AFTER_STEP={mpi_env.get('AMSS_CUDA_ESCALAR_KEEP_RESIDENT_AFTER_STEP', '')}")
print(f" AMSS_CUDA_ESCALAR_KEEP_ALL_LEVELS={mpi_env.get('AMSS_CUDA_ESCALAR_KEEP_ALL_LEVELS', '')}")
print(f" AMSS_CUDA_EM_CACHE_SOURCES={mpi_env.get('AMSS_CUDA_EM_CACHE_SOURCES', '')}")
print(f" AMSS_CUDA_EM_ZERO_FASTPATH={mpi_env.get('AMSS_CUDA_EM_ZERO_FASTPATH', '')}")
print(f" AMSS_EM_ZERO_ANALYSIS_FASTPATH={mpi_env.get('AMSS_EM_ZERO_ANALYSIS_FASTPATH', '')}")
print(f" AMSS_EM_ZERO_RESIDENT_DOWNLOAD_FASTPATH={mpi_env.get('AMSS_EM_ZERO_RESIDENT_DOWNLOAD_FASTPATH', '')}")
print(f" AMSS_CUDA_AMR_HOST_STAGED={mpi_env.get('AMSS_CUDA_AMR_HOST_STAGED', '')}")
print(f" AMSS_CUDA_AMR_RESTRICT_DEVICE={mpi_env.get('AMSS_CUDA_AMR_RESTRICT_DEVICE', '')}")
print(f" AMSS_CUDA_AMR_RESTRICT_BATCH={mpi_env.get('AMSS_CUDA_AMR_RESTRICT_BATCH', '')}")
print(f" AMSS_CUDA_DEVICE_SEGMENT_BATCH={mpi_env.get('AMSS_CUDA_DEVICE_SEGMENT_BATCH', '')}")
print(f" AMSS_CUDA_UNCACHED_DEVICE_BUFFERS={mpi_env.get('AMSS_CUDA_UNCACHED_DEVICE_BUFFERS', '')}")
print(f" AMSS_SHELL_FAST_INTERP={mpi_env.get('AMSS_SHELL_FAST_INTERP', '')}")
print(f" AMSS_SHELL_PARALLEL_INTERP={mpi_env.get('AMSS_SHELL_PARALLEL_INTERP', '')}")
print(f" AMSS_SHELL_CUDA_INTERP={mpi_env.get('AMSS_SHELL_CUDA_INTERP', '')}")
print(f" AMSS_SHELL_INTERP_THREADS={mpi_env.get('AMSS_SHELL_INTERP_THREADS', '')}")
print(f" AMSS_Z4C_CUDA_RESIDENT={mpi_env.get('AMSS_Z4C_CUDA_RESIDENT', '')}")
print(f" AMSS_CONSTRAINT_OUT_EVERY={mpi_env.get('AMSS_CONSTRAINT_OUT_EVERY', '')}")
if "CUDA_MPS_PIPE_DIRECTORY" in mpi_env:
print(f" CUDA_MPS_PIPE_DIRECTORY={mpi_env['CUDA_MPS_PIPE_DIRECTORY']}")
## Execute the MPI command and stream output
mpi_process = subprocess.Popen(mpi_command, shell=True, stdout=subprocess.PIPE, stderr=subprocess.STDOUT, text=True)
try:
## Execute the MPI command and stream output
mpi_process = subprocess.Popen(mpi_command, shell=True, stdout=subprocess.PIPE,
stderr=subprocess.STDOUT, text=True, env=mpi_env)
## Write ABE run output to file while printing to stdout
with open(mpi_command_outfile, 'w') as file0:
## Read and print output lines; also write each line to file
for line in mpi_process.stdout:
print(line, end='') # stream output in real time
file0.write(line) # write the line to file
file0.flush() # flush to ensure each line is written immediately (optional)
file0.close()
## Write ABE run output to file while printing to stdout
with open(mpi_command_outfile, 'w') as file0:
## Read and print output lines; also write each line to file
for line in mpi_process.stdout:
print(line, end='') # stream output in real time
file0.write(line) # write the line to file
file0.flush() # flush to ensure each line is written immediately (optional)
## Wait for the process to finish
mpi_return_code = mpi_process.wait()
## Wait for the process to finish
mpi_return_code = mpi_process.wait()
if mpi_return_code != 0:
raise subprocess.CalledProcessError(mpi_return_code, mpi_command)
finally:
if started_mps:
_stop_cuda_mps(mpi_env)
print( )
print( " The ABE/ABEGPU simulation is finished " )

35
plot_xiaoqu.py
View File

@@ -808,10 +808,10 @@ def generate_ADMmass_plot( outdir, figure_outdir, detector_number_i ):
## Plot constraint violation for each grid level
def generate_constraint_check_plot( outdir, figure_outdir, input_level_number ):
# path to data file
file0 = os.path.join(outdir, "bssn_constraint.dat")
def generate_constraint_check_plot( outdir, figure_outdir, input_level_number ):
# path to data file
file0 = os.path.join(outdir, "bssn_constraint.dat")
if ( input_level_number == 0 ):
print( )
@@ -819,13 +819,26 @@ def generate_constraint_check_plot( outdir, figure_outdir, input_level_number ):
print( )
print( " corresponding data file = ", file0 )
print( )
print( " Begin the constraint violation plot for grid level number = ", input_level_number )
# load the full data file (assumed whitespace-separated floats)
data = numpy.loadtxt(file0)
# extract columns from the constraint data file
print( " Begin the constraint violation plot for grid level number = ", input_level_number )
if (not os.path.exists(file0)) or os.path.getsize(file0) == 0:
if ( input_level_number == 0 ):
print( " Constraint data file is empty; skip constraint violation plots" )
print( )
return
# load the full data file (assumed whitespace-separated floats)
data = numpy.loadtxt(file0)
data = numpy.atleast_2d(data)
if data.shape[1] < 8:
if ( input_level_number == 0 ):
print( " Constraint data file has insufficient columns; skip constraint violation plots" )
print( )
return
# extract columns from the constraint data file
time = data[:,0]
Constraint_H = data[:,1]
Constraint_Px = data[:,2]