| import math |
| import torch |
| import time |
| from bitsandbytes.triton.triton_utils import is_triton_available |
|
|
| if not is_triton_available(): |
| def quantize_global_transpose(input): return None |
| def quantize_global(x: torch.Tensor): return None |
| else: |
|
|
| import triton |
| import triton.language as tl |
| from triton.ops.matmul_perf_model import early_config_prune, estimate_matmul_time |
|
|
| |
| @triton.autotune( |
| configs=[ |
| triton.Config({'BLOCK_SIZE': 1024,}, num_warps=4), |
| triton.Config({'BLOCK_SIZE': 2048,}, num_stages=1), |
| |
| ], |
| key=['n_elements'] |
| ) |
| @triton.jit |
| def _quantize_global( |
| x_ptr, |
| absmax_inv_ptr, |
| output_ptr, |
| n_elements, |
| BLOCK_SIZE: tl.constexpr, |
| ): |
| pid = tl.program_id(axis=0) |
| block_start = pid * BLOCK_SIZE |
| offsets = block_start + tl.arange(0, BLOCK_SIZE) |
| mask = offsets < n_elements |
| x = tl.load(x_ptr + offsets, mask=mask) |
| absmax_inv = tl.load(absmax_inv_ptr) |
| output = tl.libdevice.llrint(127. * (x * absmax_inv)) |
| tl.store(output_ptr + offsets, output, mask=mask) |
|
|
| def quantize_global(x: torch.Tensor): |
| absmax = x.abs().max().unsqueeze(0) |
| absmax_inv = 1./ absmax |
| output = torch.empty(*x.shape, device='cuda', dtype=torch.int8) |
| assert x.is_cuda and output.is_cuda |
| n_elements = output.numel() |
| grid = lambda meta: (triton.cdiv(n_elements, meta['BLOCK_SIZE']),) |
| _quantize_global[grid](x, absmax_inv, output, n_elements) |
| return output, absmax |
|
|
|
|
| |
| @triton.autotune( |
| configs=[ |
| triton.Config({'BLOCK_M': 128, 'BLOCK_N': 128, 'GROUP_M': 8}, num_warps=4), |
| triton.Config({'BLOCK_M': 128, 'BLOCK_N': 128, 'GROUP_M': 8}, num_warps=4), |
| |
| |
| ], |
| key=['M', 'N'] |
| ) |
| @triton.jit |
| def _quantize_global_transpose(A, absmax_inv_ptr, B, stride_am, stride_an, stride_bn, stride_bm, M, N, |
| BLOCK_M : tl.constexpr, |
| BLOCK_N : tl.constexpr, |
| GROUP_M : tl.constexpr): |
| pid = tl.program_id(0) |
| grid_m = (M + BLOCK_M - 1) // BLOCK_M |
| grid_n = (N + BLOCK_N - 1) // BLOCK_N |
| |
| width = GROUP_M * grid_n |
| group_id = pid // width |
| group_size = min(grid_m - group_id * GROUP_M, GROUP_M) |
| pid_m = group_id * GROUP_M + (pid % group_size) |
| pid_n = (pid % width) // group_size |
| |
| rm = pid_m * BLOCK_M + tl.arange(0, BLOCK_M) |
| rn = pid_n * BLOCK_N + tl.arange(0, BLOCK_N) |
| A = A + (rm[:, None] * stride_am + rn[None, :] * stride_an) |
| mask = (rm < M)[:, None] & (rn < N)[None, :] |
| a = tl.load(A, mask=mask) |
| absmax_inv = tl.load(absmax_inv_ptr) |
| |
| |
| rm = pid_m * BLOCK_M + tl.arange(0, BLOCK_M) |
| rn = pid_n * BLOCK_N + tl.arange(0, BLOCK_N) |
| B = B + (rm[:, None] * stride_bm + rn[None, :] * stride_bn) |
| mask = (rm < M)[:, None] & (rn < N)[None, :] |
|
|
| output = tl.libdevice.llrint(127. * (a * absmax_inv)) |
|
|
| tl.store(B, output, mask=mask) |
|
|
| def quantize_global_transpose(input): |
| absmax = input.abs().max().unsqueeze(0) |
| absmax_inv = 1./ absmax |
| M, N = input.shape |
| out = torch.empty(N, M, device='cuda', dtype=torch.int8) |
| |
| assert out.size(0) == N and out.size(1) == M |
| assert input.stride(0) == 1 or input.stride(1) == 1 |
| assert out.stride(0) == 1 or out.stride(1) == 1 |
| |
| grid = lambda META: (triton.cdiv(M, META['BLOCK_M']) * triton.cdiv(N, META['BLOCK_N']),) |
| _quantize_global_transpose[grid](input, absmax_inv, out, input.stride(0), input.stride(1), out.stride(0), out.stride(1), M, N) |
| return out, absmax |
|
|
|
|
