sgemm_wg: Implement multiple C per thread with sliding A/B blocks

tests/regression/sgemm_wg/kernel.cpp

@@ -3,7 +3,10 @@
 #include <vx_spawn.h>
 #include "common.h"
 
-inline void thread_block_gemm(kernel_arg_t *__UNIFORM__ arg,
+#define MAX_TM 4
+
+void thread_block_gemm(kernel_arg_t *__UNIFORM__ arg,
+                              const uint32_t tid_in_threadblock,
                               const uint32_t tid_in_threadblock_x,
                               const uint32_t tid_in_threadblock_y,
                               const uint32_t threadblock_dim_x,
@@ -12,83 +15,103 @@ inline void thread_block_gemm(kernel_arg_t *__UNIFORM__ arg,
                               const uint32_t threadblock_id_y,
                               const uint32_t threadblock_id_in_core,
                               float *sharedmem_per_threadblock) {
-  const float *global_a = (const float *)arg->addr_a;
-  const float *global_b = (const float *)arg->addr_b;
-  float *global_c = (float *)arg->addr_c;
+  const float *A = (const float *)arg->addr_a;
+  const float *B = (const float *)arg->addr_b;
+  float *C = (float *)arg->addr_c;
 
-  // assumes NT == NW == matrix_dim
   const uint32_t dim_m = arg->dim_m;
   const uint32_t dim_n = arg->dim_n;
   const uint32_t dim_k = arg->dim_k;
 
-  // FIXME: assumes local block size is square shape
-  const uint32_t local_row = tid_in_threadblock_y;
-  const uint32_t local_col = tid_in_threadblock_x;
-  const uint32_t global_row = threadblock_id_y * threadblock_dim_y + local_row;
-  const uint32_t global_col = threadblock_id_x * threadblock_dim_x + local_col;
+  // FIXME: Output block size is assumed to be square, i.e. BM == BN
+  // const uint32_t BM = threadblock_dim_y;
+  // const uint32_t BN = threadblock_dim_y;
+  // const uint32_t BK = threadblock_dim_x;
+  constexpr uint32_t BM = 8;
+  constexpr uint32_t BN = 8;
+  constexpr uint32_t BK = 4;
+  constexpr uint32_t TM = 2;
+
+  const uint32_t local_a_row = tid_in_threadblock / BK;
+  const uint32_t local_a_col = tid_in_threadblock % BK;
+  const uint32_t local_b_row = tid_in_threadblock / BN;
+  const uint32_t local_b_col = tid_in_threadblock % BN;
+  const uint32_t global_a_row = BM * threadblock_id_y + local_a_row;
+  const uint32_t global_b_col = BN * threadblock_id_x + local_b_col;
+
+  A += dim_k * BM * threadblock_id_y;
+  B += BN * threadblock_id_x;
+  C += dim_n * BM * threadblock_id_y + BN * threadblock_id_x;
 
   // each thread generates one output element
-  float reg_c = 0.0f;
+  float reg_c[MAX_TM] = { 0.0f };
 
-  for (uint32_t k = 0; k < dim_k; k += threadblock_dim_x) {
+  for (uint32_t k = 0; k < dim_k; k += BK) {
     float *local_a = sharedmem_per_threadblock;
     size_t local_a_elems = threadblock_dim_x * threadblock_dim_y;
     float *local_b = sharedmem_per_threadblock + local_a_elems;
 
-    uint32_t offset_global_a = dim_k * global_row + (k + local_col);
-    uint32_t offset_global_b = dim_n * (local_row + k) + global_col;
-    // FIXME: threadblocks size must be BM*BN, not BM*BK or BN*BK. This means
-    // there is a mismatch between the number of elements in the A/B tile and
-    // the C tile.  This is handled by each thread computing multiple result
-    // elements.
-    //
-    // local_a: threadblock_dim_y rows, threadblock_dim_x cols
-    // local_b: threadblock_dim_x rows, threadblock_dim_y cols
-    // threadblock_dim_x == block_k, threadblock_dim_y == block_m == block_n
-    local_a[threadblock_dim_x * local_row + local_col] = global_a[offset_global_a];
-    local_b[threadblock_dim_y * local_col + local_row] = global_b[offset_global_b];
+    // NOTE: local_b is transposed to column-major to facilitate better memory
+    // access.
+    local_a[BK * local_a_row + local_a_col] = A[dim_k * local_a_row + local_a_col];
+    local_b[BN * local_b_row + local_b_col] = B[dim_n * local_b_row + local_b_col];
+
+    // Advance A and B block
+    A += BK;
+    B += dim_n * BK;
 
     vx_barrier(threadblock_id_in_core, threadblock_dim_y);
     vx_fence();
 
-    for (uint32_t local_k = 0; local_k < threadblock_dim_x; local_k++) {
-      reg_c += local_a[threadblock_dim_x * local_row + local_k] *
-               local_b[threadblock_dim_y * local_col + local_k];
+    for (uint32_t local_k = 0; local_k < BK; local_k++) {
+      // Compute multiple result elements (TM) per thread
+      const float local_b_tmp = local_b[BN * local_k + local_b_col];
+#pragma GCC unroll 1
+      for (uint32_t result_idx = 0; result_idx < TM; result_idx++) {
+        reg_c[result_idx] +=
+            local_a[BK * (TM * local_b_row + result_idx) + local_k] *
+            local_b_tmp;
+      }
     }
 
     vx_barrier(threadblock_id_in_core, threadblock_dim_y);
     vx_fence();
   }
 
-  global_c[dim_n * global_row + global_col] = reg_c;
+#pragma GCC unroll 1
+  for (uint32_t result_idx = 0; result_idx < TM; result_idx++) {
+    C[dim_n * (TM * local_b_row + result_idx) + local_b_col] = reg_c[result_idx];
+  }
 }
 
 void kernel_body(int task_id, kernel_arg_t* __UNIFORM__ arg) {
   // @perf: All threads are running these compute whose result is mostly same
   // across the threadblock
 
-  const uint32_t dim_n = arg->dim_n;
-  int tid_x = task_id % dim_n;
-  int tid_y = task_id / dim_n;
-
-  const uint32_t threadblocks_per_core = 2;
+  const uint32_t threadblocks_per_core = 1;
   const uint32_t threadblock_dim_x = vx_num_threads();
   const uint32_t threadblock_dim_y = vx_num_warps() / threadblocks_per_core;
   const uint32_t threads_per_threadblock = threadblock_dim_x * threadblock_dim_y;
   const int threadblock_id = task_id / threads_per_threadblock;
   const int threadblock_id_in_core = threadblock_id % threadblocks_per_core;
 
-  const uint32_t dim_n_in_blocks = dim_n / threadblock_dim_x;
-  const int threadblock_id_x = threadblock_id % dim_n_in_blocks;
-  const int threadblock_id_y = threadblock_id / dim_n_in_blocks;
-
+  const int tid_in_threadblock = task_id % threads_per_threadblock;
   const int tid_in_threadblock_x = vx_thread_id();
   const int tid_in_threadblock_y = vx_warp_id() % threadblock_dim_y;
 
+  const uint32_t dim_m = arg->dim_m;
+  const uint32_t dim_n = arg->dim_n;
+  const uint32_t BN = 8;
+  const uint32_t dim_n_in_blocks = dim_n / BN;
+  const int threadblock_id_x = threadblock_id % dim_n_in_blocks;
+  const int threadblock_id_y = threadblock_id / dim_n_in_blocks;
+  // const int threadblock_id_x = dim_n / threadblock_dim_x;
+  // const int threadblock_id_y = dim_m / threadblock_dim_y / 1;
+
   float *sharedmem_per_threadblock =
       (float *)DEV_SMEM_START_ADDR +
-      (2 * threadblock_dim_x * threadblock_dim_y) * threadblock_id_in_core;
-  thread_block_gemm(arg, tid_in_threadblock_x, tid_in_threadblock_y,
+      (2 * threads_per_threadblock) * threadblock_id_in_core;
+  thread_block_gemm(arg, tid_in_threadblock, tid_in_threadblock_x, tid_in_threadblock_y,
                     threadblock_dim_x, threadblock_dim_y, threadblock_id_x,
                     threadblock_id_y, threadblock_id_in_core,
                     sharedmem_per_threadblock);
@@ -96,7 +119,7 @@ void kernel_body(int task_id, kernel_arg_t* __UNIFORM__ arg) {
 
 int main() {
   kernel_arg_t *arg = (kernel_arg_t *)KERNEL_ARG_DEV_MEM_ADDR;
-  const uint32_t grid_size = arg->dim_m * arg->dim_n;
+  const uint32_t grid_size = arg->dim_m * arg->dim_n / 2;
   vx_spawn_tasks(grid_size, (vx_spawn_tasks_cb)kernel_body, arg);
   return 0;
 }