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kernels/tests/regression/sgemm_tcore/sgemm_impl.hpp
Hansung Kim b44b202a21 sgemm_impl: Rename to wmma
2024-08-18 16:21:22 -07:00

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#ifndef _SGEMM_IMPL_H_
#define _SGEMM_IMPL_H_
#include <vx_intrinsics.h>
#include <vx_spawn.h>
#include "include/gemmini.h"
#include "gemmini_mmio.h"
#define FP_SIZE 32
// "fake" fp16 type that only has the correct data width.
using float16_t = uint16_t;
#if (FP_SIZE == 32)
using float_type = float;
#elif (FP_SIZE == 16)
using float_type = float16_t;
#endif
// Constraints on parameters:
// * Memory:
// (BM + BN) * BK * sizeof(T) <= sharedmem size.
// BM * BK == BN * BK >= threadblock size >= NT * CORES_PER_CLUSTER
// When larger, the kernel runs a sequential loop to read into sharedmem;
// but smaller case is not handled.
// * Compute:
// ( M* N) / (TM*TN) == grid size >= NC*NW*NT
// (BM*BN) / (TM*TN) == threadblock size < NT * NW * CORES_PER_CLUSTER
// (BM*BN) / (TM*TN) == threadblock size >= NT * CORES_PER_CLUSTER
// * Combining BM * BK >= (BM*BN) / (TM*TN) == threadblock yields
// BM <= BK*TM*TN
#define BM 64
#define BN 64
#if (FP_SIZE == 32)
#define BK 64
#elif (FP_SIZE == 16)
#define BK 128
#else
#error "unsupported FP_SIZE"
#endif
#define WM 16
#define WN 8
#define TCM 8
#define TCN 8
#if (FP_SIZE == 32)
#define TCK 8
#elif (FP_SIZE == 16)
#define TCK 16
#else
#error "unsupported FP_SIZE"
#endif
#define WMITER (WM / TCM)
#define WNITER (WN / TCN)
#define ELEM_PER_THREAD (WM * WN / NUM_THREADS)
// FIXME: NUM_THREADS and NUM_WARPS hardcoded
#if ((BM * BN / ELEM_PER_THREAD) > (CORES_PER_CLUSTER * 8 * 8))
#error "threadblock size too big for cluster"
#endif
// number of loop around the inner 0..TCK..BK loop to simulate perfect-DRAM
// scenario
#define BK_LOOP 1
// Whether to transpose smem A tile at GMEM->SMEM (produce), or SMEM->RF
// (consume). This is because the tensor core expects the A tile to be stored
// in column-major order in SMEM, whereas it will be ultimately stored in
// row-major in the RF.
//
// For correctness, only one of either should be 1. E.g., PRODUCE 1 CONSUME 0
// generates the NN kernel where both A and B are stored row-major in GMEM.
// To model the case where the A matrix is already stored column-major in GMEM,
// set both to 0.
#define TRANSPOSE_AT_PRODUCE 0
#define TRANSPOSE_AT_CONSUME 0
// GMEM_COALESCED: When TRANSPOSE_AT_PRODUCE == 1 (i.e. transpose at
// GMEM->SMEM), determines whether we do bank-conflict-free accesses for
// 1: GMEM loads of A matrix, or
// 0: SMEM stores of A matrix.
//
// Usually, GMEM_COALESCED==1 yields better performance since the memory
// behavior of GMEM is more sensitive to bank conflicts.
#define GMEM_COALESCED_A 1
#define GEMMINI_DMA 0
#if SMEM_SIZE == 0x4000
#define SMEM_ADDR_Q0 ((float * const) 0xff000000)
#define SMEM_ADDR_Q1 ((float * const) 0xff001000)
#define SMEM_ADDR_Q2 ((float * const) 0xff002000)
#define SMEM_ADDR_Q3 ((float * const) 0xff003000)
#define SPAD_ADDR_Q0 0x0
#define SPAD_ADDR_Q1 0x80
#define SPAD_ADDR_Q2 0x100
#define SPAD_ADDR_Q3 0x180
#define BOUND_INST 0x400040004ULL
#elif SMEM_SIZE == 0x10000
#define SMEM_ADDR_Q0 ((float * const) 0xff000000)
#define SMEM_ADDR_Q1 ((float * const) 0xff004000)
#define SMEM_ADDR_Q2 ((float * const) 0xff008000)
#define SMEM_ADDR_Q3 ((float * const) 0xff00c000)
#define SPAD_ADDR_Q0 0x0
#define SPAD_ADDR_Q1 0x200
#define SPAD_ADDR_Q2 0x400
#define SPAD_ADDR_Q3 0x600
#define BOUND_INST 0x800080008ULL
#else
#error Unsupported smem size
#endif
inline constexpr void map_operand_32lanes(const int tid, int &row, int &col) {
const int tg = tid / 4;
// A (row major)
// Figure 7(a) in paper
// row 0~ 3: threadgroups 0 and 2
// row 4~ 7: threadgroups 4 and 6
// row 8~11: threadgroups 1 and 3
// row 12~15: threadgroups 5 and 7
row = tid % 4;
row += (tg * 8) % 16;
row += (tg / 4) * 4;
// B (column major)
// NOTE: Matrix B mapping in Figure 7(a) is incorrect; below is the
// corrected mapping:
// col 0~ 3: threadgroups 0 and 1
// col 4~ 7: threadgroups 4 and 5
// col 8~11: threadgroups 2 and 3
// col 12~15: threadgroups 6 and 7
col = tid % 4;
col += ((tg % 4) / 2) * 8;
col += (tg / 4) * 4;
}
inline constexpr void map_operand_8lanes(const int tid, int &row, int &col) {
const int tg = tid / 4;
// A (row major)
// row 0~ 3: threadgroup 0
// row 4~ 7: threadgroup 1
row = tid % 4;
row += tg * 4;
// B (column major)
// col 0~ 3: threadgroup 0
// col 4~ 7: threadgroup 1
col = tid % 4;
col += tg * 4;
}
inline constexpr void map_operand(const int tid, int &row, int &col) {
if constexpr (NUM_THREADS == 32) {
map_operand_32lanes(tid, row, col);
} else if constexpr (NUM_THREADS == 8) {
map_operand_8lanes(tid, row, col);
} else {
// FIXME: not allowed
}
}
inline constexpr void map_c_32lanes(const int tid, int &row, int &col) {
const int tg = tid / 4;
// C
// Figure 7(b), left
col = ((tg % 4) / 2) * 8;
row = (tg * 8) % 16;
row += (tg / 4) * 4;
// Figure 7(b), right
row += (tid % 4) % 2;
col += ((tid % 4) / 2) * 2;
}
inline constexpr void map_c_8lanes(const int tid, int &row, int &col) {
const int tg = tid / 4;
// C
col = 0;
row = tg * 4;
// Figure 7(b), right
row += (tid % 4) % 2;
col += ((tid % 4) / 2) * 2;
}
inline constexpr void map_c(const int tid, int &row, int &col) {
if constexpr (NUM_THREADS == 32) {
map_c_32lanes(tid, row, col);
} else if constexpr (NUM_THREADS == 8) {
map_c_8lanes(tid, row, col);
} else {
// FIXME: not allowed
}
}
#define RISCV_CUSTOM3 0x7B
inline void vx_wmma(const int dest_reg) {
if (dest_reg == 0) {
asm volatile (".insn r %0, 0, 0, x0, x0, x0" :: "i"(RISCV_CUSTOM3));
} else {
asm volatile (".insn r %0, 0, 0, x1, x0, x0" :: "i"(RISCV_CUSTOM3));
}
}
// `local_k` is assumed to be multiple of TCK
template <typename T>
inline void wmma_load_a(volatile const T *smem_A, const int local_k,
const int warp_row, const int wm_iter,
const int thread_in_warp) {
asm volatile ("wmma_load_a_start_%=:" :: );
const int tid = thread_in_warp;
const int tg = tid / 4;
// @perf: this is duplicately computed in wmma_load_a and wmma_load_b
int row = 0;
int col = 0;
map_operand(tid, row, col);
// In fp16 mode, bit-pack two fp16 elements into each fp32 element, and do
// data movement at the fp32 granularity. Assuming that the matrix is stored
// row-major in GMEM, the packed fp16 pairs belong to the same row,
// neighboring columns; therefore, it essentially becomes equivalent to
// moving a fp32 matrix whose column dimensions (dim_k/BK/k) are compressed
// by a factor of two.
constexpr int packed_factor = (std::is_same_v<T, float16_t> ? 2 : 1);
constexpr int BK_adjusted = BK / packed_factor;
const int local_k_adjusted = local_k / packed_factor;
if constexpr (TRANSPOSE_AT_CONSUME) {
// A is stored K-major in smem
constexpr int smem_A_rows = BM;
constexpr int smem_A_cols = BK_adjusted;
// int A_offset = (WM * warp_row + TCM * wm_iter + row) * smem_A_cols;
// f8-f15 stores a single row of A
const volatile uint8_t *smem_addr;
smem_addr = reinterpret_cast<const volatile uint8_t *>(
&reinterpret_cast<const volatile float *>(
smem_A)[(WM * warp_row + TCM * wm_iter + row) * smem_A_cols +
local_k /* FIXME: adjust for fp16? */]);
// step to the next column
// @perf: bank conflicts; threads read from different rows
asm volatile("flw f0, %0(%1)" ::"i"(0 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f1, %0(%1)" ::"i"(1 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f2, %0(%1)" ::"i"(2 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f3, %0(%1)" ::"i"(3 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f4, %0(%1)" ::"i"(4 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f5, %0(%1)" ::"i"(5 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f6, %0(%1)" ::"i"(6 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f7, %0(%1)" ::"i"(7 * sizeof(float)), "r"(smem_addr));
} else {
// A is stored M-major in smem
constexpr int smem_AS_rows = BK_adjusted;
constexpr int smem_AS_cols = BM;
const volatile uint8_t *smem_addr;
smem_addr = reinterpret_cast<const volatile uint8_t *>(
&reinterpret_cast<const volatile float *>(
smem_A)[((local_k_adjusted + 0) * smem_AS_cols) +
(WM * warp_row + TCM * wm_iter) + row]);
// f8-f15 stores a single row of A
// threads read from different columns; no bank conflicts
asm volatile("flw f0, %0(%1)" :: "i"(smem_AS_cols * 0 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f1, %0(%1)" :: "i"(smem_AS_cols * 1 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f2, %0(%1)" :: "i"(smem_AS_cols * 2 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f3, %0(%1)" :: "i"(smem_AS_cols * 3 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f4, %0(%1)" :: "i"(smem_AS_cols * 4 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f5, %0(%1)" :: "i"(smem_AS_cols * 5 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f6, %0(%1)" :: "i"(smem_AS_cols * 6 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f7, %0(%1)" :: "i"(smem_AS_cols * 7 * sizeof(float)), "r"(smem_addr));
}
asm volatile ("wmma_load_a_finish_%=:" :: );
}
// `local_k` is assumed to be multiple of TCK
template <typename T>
inline void wmma_load_b(const volatile T *smem_B, const int local_k,
const int warp_col, const int wn_iter,
const int thread_in_warp) {
asm volatile ("wmma_load_b_start_%=:" :: );
const int tid = thread_in_warp;
const int tg = tid / 4;
int row = 0;
int col = 0;
map_operand(tid, row, col);
// see comment in wmma_load_a
constexpr int packed_factor = (std::is_same_v<T, float16_t> ? 2 : 1);
constexpr int BK_adjusted = BN / packed_factor;
constexpr int BN_adjusted = BN / packed_factor;
const int local_k_adjusted = local_k / packed_factor;
// B is stored N-major in smem
constexpr int smem_B_rows = BK_adjusted;
constexpr int smem_B_cols = BN;
const volatile uint8_t *smem_addr;
smem_addr = reinterpret_cast<const volatile uint8_t *>(
&reinterpret_cast<const volatile float *>(
smem_B)[((local_k_adjusted + 0) * smem_B_cols) +
(WN * warp_col + TCN * wn_iter) + col]);
// f8-f15 stores a single column of B
// threads read from different columns; no bank conflicts
asm volatile("flw f8, %0(%1)" :: "i"(smem_B_cols * 0 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f9, %0(%1)" :: "i"(smem_B_cols * 1 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f10, %0(%1)" :: "i"(smem_B_cols * 2 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f11, %0(%1)" :: "i"(smem_B_cols * 3 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f12, %0(%1)" :: "i"(smem_B_cols * 4 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f13, %0(%1)" :: "i"(smem_B_cols * 5 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f14, %0(%1)" :: "i"(smem_B_cols * 6 * sizeof(float)), "r"(smem_addr));
asm volatile("flw f15, %0(%1)" :: "i"(smem_B_cols * 7 * sizeof(float)), "r"(smem_addr));
asm volatile ("wmma_load_b_finish_%=:" :: );
}
inline void initialize_C(const int dest_reg) {
// initialize C to zeros
if (dest_reg == 0) {
asm volatile("fmv.w.x f16, x0");
asm volatile("fmv.w.x f17, x0");
asm volatile("fmv.w.x f18, x0");
asm volatile("fmv.w.x f19, x0");
asm volatile("fmv.w.x f20, x0");
asm volatile("fmv.w.x f21, x0");
asm volatile("fmv.w.x f22, x0");
asm volatile("fmv.w.x f23, x0");
} else {
asm volatile("fmv.w.x f24, x0");
asm volatile("fmv.w.x f25, x0");
asm volatile("fmv.w.x f26, x0");
asm volatile("fmv.w.x f27, x0");
asm volatile("fmv.w.x f28, x0");
asm volatile("fmv.w.x f29, x0");
asm volatile("fmv.w.x f30, x0");
asm volatile("fmv.w.x f31, x0");
}
}
__attribute__((always_inline)) inline void
wmma_store(const int thread_in_warp, const int warp_col, const int warp_row,
const int wn_iter, const int wm_iter, const int dim_n,
float *write_addr) {
asm volatile ("wmma_store_start_%=:" :: );
int tid = thread_in_warp;
// these are [0, TCM/TCN)
int tid_row = 0;
int tid_col = 0;
map_c(tid, tid_row, tid_col);
int local_row = (WM * warp_row + TCM * wm_iter) + tid_row;
int local_col = (WN * warp_col + TCN * wn_iter) + tid_col;
// @perf: this likely causes a lot of gmem bank conflicts
if (wm_iter == 0) {
volatile uint8_t *addr = reinterpret_cast<volatile uint8_t *>(
&write_addr[dim_n * (local_row + 0) + (local_col + 0)]);
volatile uint8_t *addr_tworow = addr + (2 * dim_n) * sizeof(float);
asm volatile("fsw f16, %0(%1)" ::"i"(0 * sizeof(float)), "r"(addr));
asm volatile("fsw f17, %0(%1)" ::"i"(1 * sizeof(float)), "r"(addr));
asm volatile("fsw f18, %0(%1)" ::"i"(0 * sizeof(float)), "r"(addr_tworow));
asm volatile("fsw f19, %0(%1)" ::"i"(1 * sizeof(float)), "r"(addr_tworow));
asm volatile("fsw f20, %0(%1)" ::"i"(4 * sizeof(float)), "r"(addr));
asm volatile("fsw f21, %0(%1)" ::"i"(5 * sizeof(float)), "r"(addr));
asm volatile("fsw f22, %0(%1)" ::"i"(4 * sizeof(float)), "r"(addr_tworow));
asm volatile("fsw f23, %0(%1)" ::"i"(5 * sizeof(float)), "r"(addr_tworow));
} else {
volatile uint8_t *addr = reinterpret_cast<volatile uint8_t *>(
&write_addr[dim_n * (local_row + 0) + (local_col + 0)]);
volatile uint8_t *addr_tworow = addr + (2 * dim_n) * sizeof(float);
asm volatile("fsw f24, %0(%1)" ::"i"(0 * sizeof(float)), "r"(addr));
asm volatile("fsw f25, %0(%1)" ::"i"(1 * sizeof(float)), "r"(addr));
asm volatile("fsw f26, %0(%1)" ::"i"(0 * sizeof(float)), "r"(addr_tworow));
asm volatile("fsw f27, %0(%1)" ::"i"(1 * sizeof(float)), "r"(addr_tworow));
asm volatile("fsw f28, %0(%1)" ::"i"(4 * sizeof(float)), "r"(addr));
asm volatile("fsw f29, %0(%1)" ::"i"(5 * sizeof(float)), "r"(addr));
asm volatile("fsw f30, %0(%1)" ::"i"(4 * sizeof(float)), "r"(addr_tworow));
asm volatile("fsw f31, %0(%1)" ::"i"(5 * sizeof(float)), "r"(addr_tworow));
}
asm volatile ("wmma_store_finish_%=:" :: );
}
inline void threadblock_barrier(const uint32_t barrier_id, const uint32_t count) {
vx_fence();
vx_barrier(barrier_id, count);
}
// TODO: reduce args by passing leading A/B dimensions
template <typename T>
__attribute__((always_inline))
inline void global_dmem_load(const uint32_t dim_m, const uint32_t dim_n, const uint32_t dim_k,
const uint32_t k, const T *A, const T *B,
volatile T *local_a, volatile T *local_b,
const uint32_t tid_in_threadblock,
const uint32_t threadblock_id_x,
const uint32_t threadblock_id_y) {
asm volatile ("global_dmem_load_start_%=:" :: );
// In fp16 mode, bit-pack two fp16 elements into each fp32 element, and do
// data movement at the fp32 granularity. Assuming that the matrix is stored
// row-major in GMEM, the packed fp16 pairs belong to the same row,
// neighboring columns; therefore, it essentially becomes equivalent to
// moving a fp32 matrix whose column dimensions (dim_k/BK/k) are compressed
// by a factor of two.
constexpr uint32_t packed_factor = (std::is_same_v<T, float16_t> ? 2 : 1);
constexpr uint32_t BK_adjusted = BK / packed_factor;
const uint32_t dim_k_adjusted = dim_k / packed_factor;
constexpr uint32_t BN_adjusted = BN / packed_factor;
const uint32_t dim_n_adjusted = dim_n / packed_factor;
const uint32_t k_adjusted = k / packed_factor;
const uint32_t local_a_row = tid_in_threadblock / BK_adjusted;
const uint32_t local_a_col = tid_in_threadblock % BK_adjusted;
const uint32_t local_as_row = tid_in_threadblock / BM;
const uint32_t local_as_col = tid_in_threadblock % BM;
const uint32_t local_b_row = tid_in_threadblock / BN_adjusted;
const uint32_t local_b_col = tid_in_threadblock % BN_adjusted;
// FIXME: need fix for fp16?
constexpr uint32_t threads_per_threadblock = (BM * BN) / ELEM_PER_THREAD;
// Data move from GMEM to SMEM
//
// Make sure global offset values for A and B are contiguous between
// neighboring threads to ensure GMEM coalescing.
//
// TODO: Sharedmem swizzling is important here
// move A
if constexpr (!TRANSPOSE_AT_PRODUCE) {
// A is stored M-major in GMEM;
// no transpose at GMEM->SMEM movement
const uint32_t block_m = threadblock_id_y;
const uint32_t global_a_row = k_adjusted + local_as_row;
const uint32_t global_a_col = BM * block_m + local_as_col;
// number of rows a full TB can read at a time
constexpr uint32_t row_stride_as = threads_per_threadblock / BM;
const float *global_a = reinterpret_cast<const float *>(A) +
dim_m * global_a_row + global_a_col;
volatile float *local_a_tmp = reinterpret_cast<volatile float *>(local_a) +
BM * local_as_row + local_as_col;
#pragma GCC unroll 1
for (uint32_t local_row_offset = 0; local_row_offset < BK_adjusted;
local_row_offset += row_stride_as) {
// TODO: the code GCC generates for below seems fine atm, but unroll to
// assembly to be absolutely sure
*local_a_tmp = *global_a;
global_a += dim_m * row_stride_as;
local_a_tmp += BM * row_stride_as;
}
} else {
if constexpr (!GMEM_COALESCED_A) {
// !GMEM_COALESCED_A: threads do uncoalesced read from neighboring row in
// GMEM, writes to neighboring cols in SMEM
constexpr uint32_t row_stride_as = threads_per_threadblock / BM;
const uint32_t global_a_row = BM * threadblock_id_y + local_as_col;
const float *global_a =
reinterpret_cast<float *>(A) + dim_k_adjusted * global_a_row + (k_adjusted + local_as_row);
volatile float *local_a_tmp =
reinterpret_cast<float *>(local_a) + BM * local_as_row + local_as_col;
static_assert(
row_stride_as * 8 <= BK_adjusted,
"manual loop unrolling condition not met; consider increasing BK");
static_assert(
(BK_adjusted % (row_stride_as * 8)) == 0,
"manual loop unrolling condition not met; BK should be power-of-two");
#pragma GCC unroll 1
for (uint32_t local_row_offset = 0; local_row_offset < BK_adjusted;
local_row_offset += row_stride_as * 8) {
// @perf: bank conflicts here
// const uint32_t global_a_offset =
// dim_k_adjusted * (global_a_row) + (k + local_as_row + local_row_offset);
// local_a[BM * (local_as_row + local_row_offset) + local_as_col] =
// A[global_a_offset];
// *local_a_tmp = *global_a;
asm volatile ("flw ft0, (%0)" :: "r"(global_a));
global_a += row_stride_as;
asm volatile ("flw ft1, (%0)" :: "r"(global_a));
global_a += row_stride_as;
asm volatile ("flw ft2, (%0)" :: "r"(global_a));
global_a += row_stride_as;
asm volatile ("flw ft3, (%0)" :: "r"(global_a));
global_a += row_stride_as;
asm volatile ("flw ft4, (%0)" :: "r"(global_a));
global_a += row_stride_as;
asm volatile ("flw ft5, (%0)" :: "r"(global_a));
global_a += row_stride_as;
asm volatile ("flw ft6, (%0)" :: "r"(global_a));
global_a += row_stride_as;
asm volatile ("flw ft7, (%0)" :: "r"(global_a));
global_a += row_stride_as;
// NOTE: stride is fixed to word size , i.e. sizeof(float) = 4,
// regardless of fp16 or fp32. Since Vortex core does not support fp16,
// load things at word granularity and reinterpret bits inside the
// tensor core.
asm volatile ("fsw ft0, %0(%1)" :: "i"(BM * row_stride_as * 0 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft1, %0(%1)" :: "i"(BM * row_stride_as * 1 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft2, %0(%1)" :: "i"(BM * row_stride_as * 2 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft3, %0(%1)" :: "i"(BM * row_stride_as * 3 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft4, %0(%1)" :: "i"(BM * row_stride_as * 4 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft5, %0(%1)" :: "i"(BM * row_stride_as * 5 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft6, %0(%1)" :: "i"(BM * row_stride_as * 6 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft7, %0(%1)" :: "i"(BM * row_stride_as * 7 * sizeof(float)), "r"(local_a_tmp));
local_a_tmp += BM * row_stride_as * 8;
}
} else {
constexpr uint32_t row_stride_a = threads_per_threadblock / BK_adjusted;
const uint32_t global_a_row = BM * threadblock_id_y + local_a_row;
const float *global_a = reinterpret_cast<const float *>(A) +
dim_k_adjusted * global_a_row +
(k_adjusted + local_a_col);
// NOTE that SMEM writes are transposed
volatile float *local_a_tmp =
reinterpret_cast<volatile float *>(local_a) + BM * local_a_col +
local_a_row;
static_assert(
row_stride_a * 8 <= BM,
"manual loop unrolling condition not met; consider increasing BM");
static_assert(
(BM % (row_stride_a * 8)) == 0,
"manual loop unrolling condition not met; BM should be power-of-two");
#pragma GCC unroll 1
for (uint32_t local_row_offset = 0; local_row_offset < BM;
local_row_offset += row_stride_a * 8) {
// const uint32_t global_a_offset =
// dim_k_adjusted * (global_a_row + local_row_offset) + (k + local_a_col);
// NOTE that SMEM writes are transposed
// local_a[BM * (local_a_col) + local_a_row + local_row_offset] =
// A[global_a_offset];
asm volatile ("flw ft0, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
asm volatile ("flw ft1, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
asm volatile ("flw ft2, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
asm volatile ("flw ft3, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
asm volatile ("flw ft4, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
asm volatile ("flw ft5, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
asm volatile ("flw ft6, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
asm volatile ("flw ft7, (%0)" :: "r"(global_a));
global_a += dim_k_adjusted * row_stride_a;
// stride along columns
asm volatile ("fsw ft0, %0(%1)" :: "i"(row_stride_a * 0 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft1, %0(%1)" :: "i"(row_stride_a * 1 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft2, %0(%1)" :: "i"(row_stride_a * 2 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft3, %0(%1)" :: "i"(row_stride_a * 3 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft4, %0(%1)" :: "i"(row_stride_a * 4 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft5, %0(%1)" :: "i"(row_stride_a * 5 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft6, %0(%1)" :: "i"(row_stride_a * 6 * sizeof(float)), "r"(local_a_tmp));
asm volatile ("fsw ft7, %0(%1)" :: "i"(row_stride_a * 7 * sizeof(float)), "r"(local_a_tmp));
local_a_tmp += row_stride_a * 8;
}
}
} // end move A
// move B
constexpr uint32_t row_stride_b = threads_per_threadblock / BN_adjusted;
const uint32_t global_b_col = BN_adjusted * threadblock_id_x + local_b_col;
// NOTE: not k_adjusted here; k is along the row dimension which is not
// compressed for fp16
const float *global_b = reinterpret_cast<const float *>(B) +
dim_n_adjusted * (k + local_b_row) + global_b_col;
volatile float *local_b_tmp = reinterpret_cast<volatile float *>(local_b) +
BN_adjusted * local_b_row + local_b_col;
static_assert(
row_stride_b * 8 <= BK_adjusted,
"manual loop unrolling condition not met; consider increasing BK");
static_assert(
(BK_adjusted % (row_stride_b * 8)) == 0,
"manual loop unrolling condition not met; BK should be power-of-two");
#pragma GCC unroll 1
for (uint32_t load_offset = 0; load_offset < BK;
load_offset += row_stride_b * 8) {
// equivalent code:
//
// *local_b_tmp = *global_b;
// global_b += dim_n * row_stride_b;
// local_b_tmp += BN * row_stride_b;
asm volatile ("flw ft0, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("flw ft1, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("flw ft2, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("flw ft3, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("flw ft4, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("flw ft5, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("flw ft6, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("flw ft7, (%0)" :: "r"(global_b));
global_b += dim_n_adjusted * row_stride_b;
asm volatile ("fsw ft0, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 0 * sizeof(float)), "r"(local_b_tmp));
asm volatile ("fsw ft1, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 1 * sizeof(float)), "r"(local_b_tmp));
local_b_tmp += BN_adjusted * row_stride_b * 2;
asm volatile ("fsw ft2, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 0 * sizeof(float)), "r"(local_b_tmp));
asm volatile ("fsw ft3, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 1 * sizeof(float)), "r"(local_b_tmp));
local_b_tmp += BN_adjusted * row_stride_b * 2;
asm volatile ("fsw ft4, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 0 * sizeof(float)), "r"(local_b_tmp));
asm volatile ("fsw ft5, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 1 * sizeof(float)), "r"(local_b_tmp));
local_b_tmp += BN_adjusted * row_stride_b * 2;
asm volatile ("fsw ft6, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 0 * sizeof(float)), "r"(local_b_tmp));
asm volatile ("fsw ft7, %0(%1)" :: "i"(BN_adjusted * row_stride_b * 1 * sizeof(float)), "r"(local_b_tmp));
local_b_tmp += BN_adjusted * row_stride_b * 2;
}
asm volatile ("global_dmem_load_finish_%=:" :: );
}
// Do a single tile*tile matrix multiplication using the matrix data stored in
// SMEM. Useful in fused kernels where GEMMs are done at a per-tile scope.
template <typename T,
bool write_to_smem = false // if true, write result tile to SMEM at a
// given address
>
__attribute__((always_inline)) inline void
thread_block_gemm_single_tile(const T *local_a, const T *local_b, T *local_c,
const uint32_t tid_in_threadblock,
const uint32_t threads_per_threadblock) {
// no double-buffering
// FIXME: duplicated from thread_block_gemm
const uint32_t threads_per_warpgroup = threads_per_threadblock;
const uint32_t warp_id_in_warpgroup = tid_in_threadblock / NUM_THREADS;
const uint32_t warp_row = warp_id_in_warpgroup / (BN / WN);
const uint32_t warp_col = warp_id_in_warpgroup % (BN / WN);
const uint32_t tid_in_warp = tid_in_threadblock % NUM_THREADS;
#pragma GCC unroll 1
for (int i = 0; i < BK_LOOP; i++) {
#pragma GCC unroll 4
for (uint32_t local_k = 0; local_k < BK; local_k += TCK) {
#pragma GCC unroll 2
for (int wn_iter = 0; wn_iter < WNITER; wn_iter++) {
// SMEM -> RF
wmma_load_b<T>(local_b, local_k, warp_col, wn_iter, tid_in_warp);
#pragma GCC unroll 2
for (int wm_iter = 0; wm_iter < WMITER; wm_iter++) {
// SMEM -> RF
wmma_load_a<T>(local_a, local_k, warp_row, wm_iter, tid_in_warp);
// perform mma
vx_wmma(wm_iter);
}
}
}
}
if constexpr (GEMMINI_DMA) {
// Call gemmini fence at the end of the loop to overlap dma & wmma.
// Usually, by this time, dma has finished the copy so that this
// becomes a no-op.
if (tid_in_threadblock == 0) {
gemmini_fence();
}
}
if constexpr (write_to_smem) {
#pragma GCC unroll
for (int wm_iter = 0; wm_iter < WMITER; wm_iter++) {
#pragma GCC unroll
for (int wn_iter = 0; wn_iter < WNITER; wn_iter++) {
wmma_store(tid_in_warp, warp_col, warp_row, wn_iter, wm_iter, BN,
local_c);
}
}
}
}
template <typename T, bool write_to_gmem = true,
// by default, A/B tiles are placed at the start of the smem
uint32_t smem_a_offset = 0, // byte offset of A tile in shared
// memory
uint32_t smem_a_dbuf_offset = 0, // byte offset of A
// double-buffer tile in shared
// memory
uint32_t smem_b_offset = sizeof(float) * BM *
BK, // byte offset of B tile
// in shared memory
uint32_t smem_b_dbuf_offset = sizeof(float) * BM *
BK // byte offset of B double-buffer
// tile in shared memory
>
inline void thread_block_gemm(const T *A, const T *B, float *C,
const uint32_t dim_m, const uint32_t dim_n,
const uint32_t dim_k,
const uint32_t tid_in_threadblock,
const uint32_t threads_per_threadblock,
const uint32_t threadblocks_per_cluster,
const uint32_t threadblock_id_in_cluster,
uint8_t *sharedmem_per_threadblock) {
const uint32_t local_a_row = tid_in_threadblock / BK;
const uint32_t local_a_col = tid_in_threadblock % BK;
const uint32_t local_as_row = tid_in_threadblock / BM;
const uint32_t local_as_col = tid_in_threadblock % BM;
const uint32_t local_b_row = tid_in_threadblock / BN;
const uint32_t local_b_col = tid_in_threadblock % BN;
// no double-buffering
const uint32_t threads_per_warpgroup = threads_per_threadblock;
const uint32_t warp_id_in_warpgroup = tid_in_threadblock / NUM_THREADS;
const uint32_t warp_row = warp_id_in_warpgroup / (BN / WN);
const uint32_t warp_col = warp_id_in_warpgroup % (BN / WN);
const uint32_t tid_in_warp = tid_in_threadblock % NUM_THREADS;
const uint32_t warps_per_threadblock_per_core =
NUM_WARPS / threads_per_threadblock;
volatile T *local_a =
reinterpret_cast<T *>(sharedmem_per_threadblock + smem_a_offset);
volatile T *local_a_buf =
reinterpret_cast<T *>(sharedmem_per_threadblock + smem_a_dbuf_offset);
volatile T *local_b =
reinterpret_cast<T *>(sharedmem_per_threadblock + smem_b_offset);
volatile T *local_b_buf =
reinterpret_cast<T *>(sharedmem_per_threadblock + smem_b_dbuf_offset);
constexpr uint32_t skips =
loop_matmul_skips(/*skip_lda=*/0, /*skip_ldb=*/0, /*skip_ldd=*/1,
/*skip_ex=*/1, /*skip_stc=*/1);
#if (GEMMINI_DMA == 1)
if (tid_in_threadblock == 0) {
gemmini_extended_config_ex(WEIGHT_STATIONARY, 0, 0, 1, 0, 0);
// gemmini_extended_config_ex(dataflow, act & 3, 0, 1, a_transpose,
// b_transpose);
gemmini_extended3_config_ld(dim_k * sizeof(elem_t), MVIN_SCALE_IDENTITY,
false, 0);
gemmini_extended3_config_ld(dim_n * sizeof(elem_t), MVIN_SCALE_IDENTITY,
false, 1);
gemmini_extended_config_st(dim_n * sizeof(elem_t), 0, MVIN_SCALE_IDENTITY);
gemmini_fence();
}
#endif
// divide rows (M) by the number of threadblocks
const uint32_t dim_m_range = (dim_m / threadblocks_per_cluster);
const uint32_t dim_m_start = dim_m_range * threadblock_id_in_cluster;
const uint32_t block_m_start = dim_m_start / BM;
const uint32_t block_m_end = (dim_m_start + dim_m_range) / BM;
#pragma GCC unroll 1
for (uint32_t block_m = block_m_start; block_m < block_m_end; block_m++) {
#pragma GCC unroll 1
for (uint32_t block_n = 0; (block_n * BN) < dim_n; block_n++) {
// clear out C
initialize_C(0);
initialize_C(1);
if constexpr (GEMMINI_DMA) {
// pipeline initiation
if (tid_in_threadblock == 0) {
// configure dma gmem address to load from
// FIXME: block_k is wrong
ROCC_INSTRUCTION_RS1_RS2(
XCUSTOM_ACC,
(uint64_t)(A + block_m * BM * dim_k + /*block_k:*/0 * BK),
(uint64_t)(B + /*block_k:*/0 * BK * dim_n + block_n * BN),
k_LOOP_WS_CONFIG_ADDRS_AB)
// GEMMINI_CISC(8) does k_LOOP_WS_CONFIG_STRIDES_AB
GEMMINI_CISC_CMD_R((dim_n << 16) | (dim_k << 8) | 8);
gemmini_fence();
GEMMINI_CISC_CMD_I(10);
gemmini_fence();
#if 0
// sp_tiled_matmul_full_spad_ws includes CONFIG_BOUNDS
// FIXME: block_k is 0 for two times
sp_tiled_matmul_full_spad_ws(
#if 1
SPAD_ADDR_Q0, SPAD_ADDR_Q1,
#else
(/*block_k:*/ 0 & 1) ? SPAD_ADDR_Q2 : SPAD_ADDR_Q0,
(/*block_k:*/ 0 & 1) ? SPAD_ADDR_Q3 : SPAD_ADDR_Q1,
#endif
/*spad_D=*/0, /*spad_C=*/SPAD_ADDR_Q3,
/*I=*/BM / DIM, /*J=*/BN / DIM, /*K=*/BK / DIM, /*pad_I=*/0,
/*pad_J=*/0, /*pad_K=*/0,
/*a_transpose=*/0, /*b_transpose=*/0, /*full_C=*/0, /*low_D=*/0,
/*acc=*/0, /*act=*/NO_ACTIVATION, /*skips=*/skips)
gemmini_fence();
#endif
}
threadblock_barrier(threadblock_id_in_cluster,
warps_per_threadblock_per_core);
}
#pragma GCC unroll 1
for (uint32_t block_k = 0; (block_k * BK) < dim_k; block_k++) {
// producer code: GMEM->SMEM memory movement
// ---------------------------------------------------------------------
//
// this is either done using DMA or SIMT cores depending on GEMMINI_DMA
#if (GEMMINI_DMA == 1)
if ((tid_in_threadblock == 0) && ((block_k * BK) != (dim_k - BK))) {
// configure dma gmem address to load from
// FIXME: block_k is wrong
ROCC_INSTRUCTION_RS1_RS2(
XCUSTOM_ACC,
(uint64_t)(A + block_m * BM * dim_k + (block_k + 1/*runahead*/) * BK),
(uint64_t)(B + (block_k + 1/*runahead*/) * BK * dim_n + block_n * BN),
k_LOOP_WS_CONFIG_ADDRS_AB)
// GEMMINI_CISC(8) does k_LOOP_WS_CONFIG_STRIDES_AB
GEMMINI_CISC_CMD_R((dim_n << 16) | (dim_k << 8) | 8);
// gemmini_fence();
// block_k is even: opcode 11 (write to local_a_buf)
// block_k is odd: opcode 10 (write to local_a)
const uint32_t opcode = 11 - (block_k & 1);
GEMMINI_CISC_CMD_R(opcode);
// // TODO: branch is probably slow
// if (block_k & 1) {
// GEMMINI_CISC_CMD_I(12);
// } else { // block_k == 0 is here
// GEMMINI_CISC_CMD_I(13);
// }
// configure loop iteration bounds
// FIXME: shouldn't be necessary
// ROCC_INSTRUCTION_RS1_RS2(XCUSTOM_ACC, 0, BOUND_INST,
// k_LOOP_WS_CONFIG_BOUNDS) ROCC_INSTRUCTION_RS1_RS2(XCUSTOM_ACC,
// SPAD_ADDR_Q0, SPAD_ADDR_Q1, k_LOOP_WS_CONFIG_SPAD_AB)
// ROCC_INSTRUCTION_RS1_RS2(
// XCUSTOM_ACC,
// ((uint64_t)(/*a_spad_id:*/ 0) << 18) |
// ((uint64_t)(/*b_spad_id:*/ 0) << 16) |
// ((uint64_t)(/*act:0*/ 0) << 8) | ((/*low_D:*/ 0) << 2) |
// ((/*full_C:*/ 0) << 1) | (/*ex_accumulate:*/ 0),
// ((uint64_t)(/*C_spad_addr:*/ A) << 32) | 0x200U | (skips) |
// ((/*is_resadd*/ 0) << 2) | ((/*B_transpose:*/ 0) << 1) |
// (/*A_transpose:*/ 1),
// k_LOOP_WS)
// gemmini_fence();
#if 0
uint32_t spad_a_produce;
uint32_t spad_b_produce;
const uint32_t mask_odd = (block_k & 1) << 31 >> 31;
const uint32_t mask_even = ((block_k & 1) ^ 1) << 31 >> 31;
spad_a_produce =
((mask_odd & (SPAD_ADDR_Q0)) | (mask_even & (SPAD_ADDR_Q2)));
spad_b_produce =
((mask_odd & (SPAD_ADDR_Q1)) | (mask_even & (SPAD_ADDR_Q3)));
// sp_tiled_matmul_full_spad_ws includes CONFIG_BOUNDS
// FIXME: block_k is 0 for two times
sp_tiled_matmul_full_spad_ws(
spad_a_produce,
spad_b_produce,
/*spad_D=*/0, /*spad_C=*/SPAD_ADDR_Q1,
/*I=*/BM / DIM, /*J=*/BN / DIM, /*K=*/BK / DIM, /*pad_I=*/0,
/*pad_J=*/0, /*pad_K=*/0,
/*a_transpose=*/0, /*b_transpose=*/0, /*full_C=*/0, /*low_D=*/0,
/*acc=*/0, /*act=*/NO_ACTIVATION, /*skips=*/skips)
#endif
}
#else
global_dmem_load<T>(dim_m, dim_n, dim_k, block_k * BK, A, B, local_a,
local_b, tid_in_threadblock, block_n, block_m);
threadblock_barrier(threadblock_id_in_cluster,
warps_per_threadblock_per_core);
#endif
// consumer code: SMEM->RF and compute
// ----------------------------------------------------------------------
// @perf: this loop spills to stack a lot because of all the flws in
const volatile T *local_a_consume;
const volatile T *local_b_consume;
if constexpr (GEMMINI_DMA) {
// local_a_consume = (k_index % 2) ? local_a_buf : local_a;
// local_b_consume = (k_index % 2) ? local_b_buf : local_b;
// FIXME: swap multiply with bitshifts
// const uint32_t mask_odd = (block_k & 1) << 31 >> 31;
// const uint32_t mask_even = ((block_k & 1) ^ 1) << 31 >> 31;
// local_a_consume = reinterpret_cast<volatile T *>(
// (mask_odd & reinterpret_cast<uintmax_t>(local_a_buf)) |
// (mask_even & reinterpret_cast<uintmax_t>(local_a)));
// local_b_consume = reinterpret_cast<volatile T *>(
// (mask_odd & reinterpret_cast<uintmax_t>(local_b_buf)) |
// (mask_even & reinterpret_cast<uintmax_t>(local_b)));
local_a_consume = local_a + (block_k & 1) * (BM * BK);
local_b_consume = local_b + (block_k & 1) * (BK * BN);
} else {
// no double-buffering without DMA
local_a_consume = local_a;
local_b_consume = local_b;
}
thread_block_gemm_single_tile(
local_a_consume, local_b_consume,
static_cast<volatile T *>(nullptr) /*ignore*/, tid_in_threadblock,
threads_per_threadblock);
if constexpr (GEMMINI_DMA) {
// Call gemmini fence at the end of the loop to overlap dma & wmma.
// Usually, by this time, dma has finished the copy so that this
// becomes a no-op.
if (tid_in_threadblock == 0) {
gemmini_fence();
}
}
threadblock_barrier(threadblock_id_in_cluster,
warps_per_threadblock_per_core);
}
if constexpr (write_to_gmem) {
#pragma GCC unroll
for (int wm_iter = 0; wm_iter < WMITER; wm_iter++) {
#pragma GCC unroll
for (int wn_iter = 0; wn_iter < WNITER; wn_iter++) {
float *global_offset_C = C + (BM * block_m) * dim_n + BN * block_n;
wmma_store(tid_in_warp, warp_col, warp_row, wn_iter, wm_iter, dim_n,
global_offset_C);
}
}
}
}
}
}
#endif
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