sgemm_tcore: Remove BM_d/BN_d

tests/regression/sgemm_tcore/kernel.cpp

@@ -339,9 +339,6 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
                  volatile float *local_b, const uint32_t tid_in_threadblock,
                  const uint32_t threadblock_id_x,
                  const uint32_t threadblock_id_y) {
-  constexpr uint32_t BM_d = BM;
-  constexpr uint32_t BN_d = BN;
-
   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;
@@ -359,14 +356,16 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
   //
   // TODO: Sharedmem swizzling is important here
   if constexpr (!TRANSPOSE_AS) {
-    const uint32_t global_a_row = BM_d * threadblock_id_y + local_a_row;
+    // FIXME: !TRANSPOSE_AS code is old
+
+    const uint32_t global_a_row = BM * threadblock_id_y + local_a_row;
     // number of rows a full TB can read at a time
     constexpr uint32_t row_stride_a = threads_in_warpgroup / BK;
     const float *global_a = A + dim_k * global_a_row + (k + local_a_col);
     volatile float *local_a_tmp = local_a + BK * local_a_row + local_a_col;
 
 #pragma GCC unroll 2
-    for (uint32_t local_row_offset = 0; local_row_offset < BM_d;
+    for (uint32_t local_row_offset = 0; local_row_offset < BM;
          local_row_offset += row_stride_a) {
       // const uint32_t global_a_offset =
       //     dim_k * (global_a_row + local_row_offset) + (k + local_a_col);
@@ -379,13 +378,13 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
     }
   } else {
     if constexpr (!GMEM_COALESCED_A) {
-      constexpr uint32_t row_stride_as = threads_in_warpgroup / BM_d;
-      const uint32_t global_a_row = BM_d * threadblock_id_y + local_as_col;
+      constexpr uint32_t row_stride_as = threads_in_warpgroup / BM;
+      const uint32_t global_a_row = BM * threadblock_id_y + local_as_col;
       const float *global_a = A + dim_k * global_a_row + (k + local_as_row);
       // FIXME experimenting with global coalescing
-      // const uint32_t global_a_row = BM_d * threadblock_id_y + local_as_row;
+      // const uint32_t global_a_row = BM * threadblock_id_y + local_as_row;
       // const float *global_a = A + dim_k * global_a_row + (k + local_as_col);
-      volatile float *local_a_tmp = local_a + BM_d * local_as_row + local_as_col;
+      volatile float *local_a_tmp = local_a + BM * local_as_row + local_as_col;
 
       static_assert(
           row_stride_as * 8 <= BK,
@@ -403,7 +402,7 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
         // FIXME experimenting with global coalescing
         // const uint32_t global_a_offset =
         //     dim_k * (global_a_row + local_row_offset) + (k + local_as_col);
-        // local_a[BM_d * (local_as_row + local_row_offset) + local_as_col] =
+        // local_a[BM * (local_as_row + local_row_offset) + local_as_col] =
         //     A[global_a_offset];
 
         // *local_a_tmp = *global_a;
@@ -436,25 +435,25 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
       }
     } else {
       constexpr uint32_t row_stride_a = threads_in_warpgroup / BK;
-      const uint32_t global_a_row = BM_d * threadblock_id_y + local_a_row;
+      const uint32_t global_a_row = BM * threadblock_id_y + local_a_row;
       const float *global_a = A + dim_k * global_a_row + (k + local_a_col);
       // NOTE that SMEM writes are transposed
-      volatile float *local_a_tmp = local_a + BM_d * local_a_col + local_a_row;
+      volatile float *local_a_tmp = local_a + BM * local_a_col + local_a_row;
 
       static_assert(
-          row_stride_a * 8 <= BM_d,
+          row_stride_a * 8 <= BM,
           "manual loop unrolling condition not met; consider increasing BM");
       static_assert(
-          (BM_d % (row_stride_a * 8)) == 0,
+          (BM % (row_stride_a * 8)) == 0,
           "manual loop unrolling condition not met; BM should be power-of-two");
 
 #pragma GCC unroll 4
-      for (uint32_t local_row_offset = 0; local_row_offset < BM_d;
+      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 * (global_a_row + local_row_offset) + (k + local_a_col);
         // NOTE that SMEM writes are transposed
-        // local_a[BM_d * (local_a_col) + local_a_row + local_row_offset] =
+        // local_a[BM * (local_a_col) + local_a_row + local_row_offset] =
         //     A[global_a_offset];
 
         asm volatile ("flw ft0, (%0)"   :: "r"(global_a));
@@ -488,10 +487,10 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
     }
   }
 
-  constexpr uint32_t row_stride_b = threads_in_warpgroup / BN_d;
-  const uint32_t global_b_col = BN_d * threadblock_id_x + local_b_col;
+  constexpr uint32_t row_stride_b = threads_in_warpgroup / BN;
+  const uint32_t global_b_col = BN * threadblock_id_x + local_b_col;
   const float *global_b = B + dim_n * (k + local_b_row) + global_b_col;
-  volatile float *local_b_tmp = local_b + BN_d * local_b_row + local_b_col;
+  volatile float *local_b_tmp = local_b + BN * local_b_row + local_b_col;
 
   static_assert(
       row_stride_b * 8 <= BK,
@@ -505,13 +504,13 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
        load_offset += row_stride_b * 8) {
     // const uint32_t global_b_offset =
     //     dim_n * (k + local_b_row + load_offset) + global_b_col;
-    // local_b[BN_d * (local_b_row + load_offset) + local_b_col] =
+    // local_b[BN * (local_b_row + load_offset) + local_b_col] =
     //     B[global_b_offset];
 
     // *local_b_tmp = *global_b;
 
     // global_b += dim_n * row_stride_b;
-    // local_b_tmp += BN_d * row_stride_b;
+    // local_b_tmp += BN * row_stride_b;
 
     asm volatile ("flw ft0, (%0)"   :: "r"(global_b));
     global_b += dim_n * row_stride_b;
@@ -530,15 +529,15 @@ global_dmem_load(const uint32_t dim_n, const uint32_t dim_k, const uint32_t k,
     asm volatile ("flw ft7, (%0)"   :: "r"(global_b));
     global_b += dim_n * row_stride_b;
 
-    asm volatile ("fsw ft0, %0(%1)" :: "i"(BN_d * row_stride_b * 0 * sizeof(float)), "r"(local_b_tmp));
-    asm volatile ("fsw ft1, %0(%1)" :: "i"(BN_d * row_stride_b * 1 * sizeof(float)), "r"(local_b_tmp));
-    asm volatile ("fsw ft2, %0(%1)" :: "i"(BN_d * row_stride_b * 2 * sizeof(float)), "r"(local_b_tmp));
-    asm volatile ("fsw ft3, %0(%1)" :: "i"(BN_d * row_stride_b * 3 * sizeof(float)), "r"(local_b_tmp));
-    asm volatile ("fsw ft4, %0(%1)" :: "i"(BN_d * row_stride_b * 4 * sizeof(float)), "r"(local_b_tmp));
-    asm volatile ("fsw ft5, %0(%1)" :: "i"(BN_d * row_stride_b * 5 * sizeof(float)), "r"(local_b_tmp));
-    asm volatile ("fsw ft6, %0(%1)" :: "i"(BN_d * row_stride_b * 6 * sizeof(float)), "r"(local_b_tmp));
-    asm volatile ("fsw ft7, %0(%1)" :: "i"(BN_d * row_stride_b * 7 * sizeof(float)), "r"(local_b_tmp));
-    local_b_tmp += BN_d * row_stride_b * 8;
+    asm volatile ("fsw ft0, %0(%1)" :: "i"(BN * row_stride_b * 0 * sizeof(float)), "r"(local_b_tmp));
+    asm volatile ("fsw ft1, %0(%1)" :: "i"(BN * row_stride_b * 1 * sizeof(float)), "r"(local_b_tmp));
+    asm volatile ("fsw ft2, %0(%1)" :: "i"(BN * row_stride_b * 2 * sizeof(float)), "r"(local_b_tmp));
+    asm volatile ("fsw ft3, %0(%1)" :: "i"(BN * row_stride_b * 3 * sizeof(float)), "r"(local_b_tmp));
+    asm volatile ("fsw ft4, %0(%1)" :: "i"(BN * row_stride_b * 4 * sizeof(float)), "r"(local_b_tmp));
+    asm volatile ("fsw ft5, %0(%1)" :: "i"(BN * row_stride_b * 5 * sizeof(float)), "r"(local_b_tmp));
+    asm volatile ("fsw ft6, %0(%1)" :: "i"(BN * row_stride_b * 6 * sizeof(float)), "r"(local_b_tmp));
+    asm volatile ("fsw ft7, %0(%1)" :: "i"(BN * row_stride_b * 7 * sizeof(float)), "r"(local_b_tmp));
+    local_b_tmp += BN * row_stride_b * 8;
   }
 }