make non dma gemmini use 64x64 tile size

tests/regression/sgemm_gemmini/kernel.cpp

@@ -6,25 +6,25 @@
 #include "include/gemmini.h"
 #include "gemmini_mmio.h"
 
-#define TILE_M 32
-#define TILE_N 32
-#define TILE_K 32
-#define TILE_MN 1024
-#define TILE_MK 1024
-#define TILE_NK 1024
+#define TILE_M 64
+#define TILE_N 64
+#define TILE_K 64
+#define TILE_MN 4096
+#define TILE_MK 4096
+#define TILE_NK 4096
 
 #define NUM_CLUSTERS 1
-#define NUM_THREADS_IN_CLUSTER 128
+#define NUM_THREADS_IN_CLUSTER 256
 
 #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 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 0x80
-#define SPAD_ADDR_Q2 0x100
-#define SPAD_ADDR_Q3 0x180
-#define SPAD_ADDR_Q4 0x200
+#define SPAD_ADDR_Q1 0x200
+#define SPAD_ADDR_Q2 0x400
+#define SPAD_ADDR_Q3 0x600
+#define SPAD_ADDR_Q4 0x800
 
 #define HARDCODE
 #define REGBLOCK
@@ -61,7 +61,6 @@ inline void threadblock_barrier(unsigned int barrier_id, unsigned int count) {
 void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
                                  const uint32_t threadblock_id,
                                  const uint32_t tid_in_threadblock) {
-  __asm__("matmul_start:");
   const float * const A = (const float * const) arg->addr_a;
   const float * const B = (const float * const) arg->addr_b;
   float * const C = (float * const) arg->addr_c;
@@ -71,7 +70,9 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
     // gemmini_extended_config_ex(dataflow, act & 3, 0, 1, a_transpose, b_transpose);
 
     // gemmini_extended_config_st(stride_C * sizeof_C, act & 3, scale);
+    #ifndef POWER
     PRINTF("start\n");
+    #endif
   }
 
   vx_fence();
@@ -121,9 +122,7 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
   for (uint32_t tile_i = num_tile_rows_per_tb * threadblock_id;
                 tile_i < num_tile_rows_per_tb * (threadblock_id + 1);
                 tile_i += 1) {
-    __asm__("i_loop:");
     for (int tile_j = 0; tile_j < num_tiles_n; tile_j += 1) {
-      __asm__("j_loop:");
       float * const smem_c_tile_start = SMEM_ADDR_Q1;
       #ifdef OFFLOAD_ACCUMULATE
       float * const smem_acc_tile_start = SMEM_ADDR_Q0 + HW_TID();
@@ -131,15 +130,14 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
       float * const smem_acc_tile_start = SMEM_ADDR_Q2 + hw_tid;
       #endif
 
-      __asm__("k_loop:");
       for (int tile_k = 0; tile_k < num_tiles_k; tile_k += 1) {
         // TODO: double buffer
         rd_cycles(marker1);
 
         #ifdef HARDCODE
-          #if (TILE_MK / NUM_THREADS / NUM_WARPS / CORES_PER_CLUSTER) != 8
-            #error CANNOT UNROLL
-          #endif
+          // #if (TILE_MK / NUM_THREADS / NUM_WARPS / CORES_PER_CLUSTER) != 8
+          //   #error CANNOT UNROLL
+          // #endif
 
         constexpr uint32_t every_iter = j1_stride;
         const uint32_t every_2iters_a = i1_stride * dim_k;
@@ -228,6 +226,42 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
           smem_b_tile_start[5 * num_threads_in_cluster] = v1;
           smem_b_tile_start[6 * num_threads_in_cluster] = v2;
           smem_b_tile_start[7 * num_threads_in_cluster] = v3;
+
+          v0 = dram_a_tile_start[every_iter * 0 + every_2iters_a * 4];
+          v1 = dram_a_tile_start[every_iter * 1 + every_2iters_a * 4];
+          v2 = dram_a_tile_start[every_iter * 0 + every_2iters_a * 5];
+          v3 = dram_a_tile_start[every_iter * 1 + every_2iters_a * 5];
+          smem_a_tile_start[8  * num_threads_in_cluster] = v0;
+          smem_a_tile_start[9  * num_threads_in_cluster] = v1;
+          smem_a_tile_start[10 * num_threads_in_cluster] = v2;
+          smem_a_tile_start[11 * num_threads_in_cluster] = v3;
+
+          v0 = dram_b_tile_start[every_iter * 0 + every_2iters_b * 4];
+          v1 = dram_b_tile_start[every_iter * 1 + every_2iters_b * 4];
+          v2 = dram_b_tile_start[every_iter * 0 + every_2iters_b * 5];
+          v3 = dram_b_tile_start[every_iter * 1 + every_2iters_b * 5];
+          smem_b_tile_start[8  * num_threads_in_cluster] = v0;
+          smem_b_tile_start[9  * num_threads_in_cluster] = v1;
+          smem_b_tile_start[10 * num_threads_in_cluster] = v2;
+          smem_b_tile_start[11 * num_threads_in_cluster] = v3;
+
+          v0 = dram_a_tile_start[every_iter * 0 + every_2iters_a * 6];
+          v1 = dram_a_tile_start[every_iter * 1 + every_2iters_a * 6];
+          v2 = dram_a_tile_start[every_iter * 0 + every_2iters_a * 7];
+          v3 = dram_a_tile_start[every_iter * 1 + every_2iters_a * 7];
+          smem_a_tile_start[12 * num_threads_in_cluster] = v0;
+          smem_a_tile_start[13 * num_threads_in_cluster] = v1;
+          smem_a_tile_start[14 * num_threads_in_cluster] = v2;
+          smem_a_tile_start[15 * num_threads_in_cluster] = v3;
+
+          v0 = dram_b_tile_start[every_iter * 0 + every_2iters_b * 6];
+          v1 = dram_b_tile_start[every_iter * 1 + every_2iters_b * 6];
+          v2 = dram_b_tile_start[every_iter * 0 + every_2iters_b * 7];
+          v3 = dram_b_tile_start[every_iter * 1 + every_2iters_b * 7];
+          smem_b_tile_start[12 * num_threads_in_cluster] = v0;
+          smem_b_tile_start[13 * num_threads_in_cluster] = v1;
+          smem_b_tile_start[14 * num_threads_in_cluster] = v2;
+          smem_b_tile_start[15 * num_threads_in_cluster] = v3;
         #endif
         }
         #else
@@ -398,34 +432,29 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
       #ifdef OFFLOAD_ACCUMULATE
       threadblock_barrier(/*barrier_id=*/0, /*count=*/NUM_WARPS);
       rd_cycles(marker6);
-      __asm__("mvout_spad_ser:");
       // mvout to scratchpad for activation
       if (HW_TID() == 0) {
-        __asm__("mvout_spad:");
 //        #ifdef DBUF
 //        gemmini_fence();
 //        #endif
       #ifdef CISC
         GEMMINI_CISC_CMD_I(9);
       #else
-        ROCC_INSTRUCTION_RS1_RS2(XCUSTOM_ACC, 0, (4ULL << 32) | (4ULL << 16) | 4ULL, k_LOOP_WS_CONFIG_BOUNDS)
+        ROCC_INSTRUCTION_RS1_RS2(XCUSTOM_ACC, 0, (((uint64_t) TILE_M / DIM) << 32) |
+          (((uint64_t) TILE_K / DIM) << 16) | ((uint64_t) TILE_N / DIM), k_LOOP_WS_CONFIG_BOUNDS)
         ROCC_INSTRUCTION_RS1_RS2(XCUSTOM_ACC, 0, 0x278U, k_LOOP_WS)
       #endif
-        __asm__("mvout_spad_fence:");
         gemmini_fence();
       }
-      __asm__("mvout_spad_bar:");
       threadblock_barrier(/*barrier_id=*/0, /*count=*/NUM_WARPS);
-      __asm__("end_mvout_spad:");
       #endif
       rd_cycles(marker7);
 
       // move out to dram
-      __asm__("mvout_dram:");
       #ifdef HARDCODE
-      #if (TILE_MN / NUM_THREADS / NUM_WARPS / CORES_PER_CLUSTER) != 8
-        #error CANNOT UNROLL
-      #endif
+      // #if (TILE_MN / NUM_THREADS / NUM_WARPS / CORES_PER_CLUSTER) != 8
+      //   #error CANNOT UNROLL
+      // #endif
       constexpr uint32_t every_iter = j1_stride;
       const uint32_t every_2iters = i1_stride * dim_n;
       const uint32_t runtime_const = i0 * dim_n + j1_idx + j0;
@@ -468,6 +497,24 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
       dram_c_tile_start[every_iter * 1 + every_2iters * 2] = v1;
       dram_c_tile_start[every_iter * 0 + every_2iters * 3] = v2;
       dram_c_tile_start[every_iter * 1 + every_2iters * 3] = v3;
+
+      v0 = smem_acc_tile_start[8  * num_threads_in_cluster];
+      v1 = smem_acc_tile_start[9  * num_threads_in_cluster];
+      v2 = smem_acc_tile_start[10 * num_threads_in_cluster];
+      v3 = smem_acc_tile_start[11 * num_threads_in_cluster];
+      dram_c_tile_start[every_iter * 0 + every_2iters * 4] = v0;
+      dram_c_tile_start[every_iter * 1 + every_2iters * 4] = v1;
+      dram_c_tile_start[every_iter * 0 + every_2iters * 5] = v2;
+      dram_c_tile_start[every_iter * 1 + every_2iters * 5] = v3;
+
+      v0 = smem_acc_tile_start[12 * num_threads_in_cluster];
+      v1 = smem_acc_tile_start[13 * num_threads_in_cluster];
+      v2 = smem_acc_tile_start[14 * num_threads_in_cluster];
+      v3 = smem_acc_tile_start[15 * num_threads_in_cluster];
+      dram_c_tile_start[every_iter * 0 + every_2iters * 6] = v0;
+      dram_c_tile_start[every_iter * 1 + every_2iters * 6] = v1;
+      dram_c_tile_start[every_iter * 0 + every_2iters * 7] = v2;
+      dram_c_tile_start[every_iter * 1 + every_2iters * 7] = v3;
       #else
       dram_c_tile_start[every_iter * 0 + every_2iters * 0] = \
         smem_acc_tile_start[0 * num_threads_in_cluster];
@@ -496,7 +543,6 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
           *(SMEM_ADDR_Q2 + SMEM_MAT_OFFSET(elem_offset / TILE_N, elem_offset % TILE_N, TILE_N));
       }
       #endif
-      __asm__("end_mvout_dram:");
 
       // rd_cycles_force(marker8);
     }
@@ -507,7 +553,7 @@ void thread_block_matmul_gemmini(kernel_arg_t *__UNIFORM__ arg,
     rd_cycles_force(marker9);
     #ifdef POWER
     if (HW_TID() == 0) {
-        PRINTF("\nstart %d end %d\n", marker0, marker9);
+        PRINTF("%d\n", marker9 - marker0);
     }
     #else
     if (HW_TID() == 0) {