# Owner(s): ["module: inductor"] import functools import unittest from typing import Union import torch from torch import Tensor from torch._inductor import config, utils from torch._inductor.test_case import run_tests, TestCase from torch.testing._internal.common_cuda import ( PLATFORM_SUPPORTS_FP8, PLATFORM_SUPPORTS_MX_GEMM, ) from torch.testing._internal.common_quantized import ceil_div, to_blocked from torch.testing._internal.common_utils import ( instantiate_parametrized_tests, parametrize, ) from torch.testing._internal.inductor_utils import ( _quantize_rowwise, _quantize_tensorwise, _to_fp8_saturated, HAS_CPU, HAS_CUDA, ) from torch.utils._triton import has_triton_tma_device torch.set_float32_matmul_precision("high") f8_msg = "FP8 is only supported on H100+, SM 8.9 and MI300+ devices" def _fix_fp8_dtype_for_rocm( dtype: Union[torch.dtype, list[torch.dtype], tuple[torch.dtype]], device ) -> Union[torch.dtype, list[torch.dtype], tuple[torch.dtype]]: # This function is used to change FP8 data types # with MI300 supported FP8 types if device is GPU: # e4m3fn -> e4m3fnuz # e5m2 -> e5m2fnuz # Supports single, typle and list of dtypes # Keeps the same test name for CUDA and ROCm # Also it allows to enable FP8 inductor tests for CPU if ( torch.version.hip and ("cuda" in device) and ("gfx94" in torch.cuda.get_device_properties(0).gcnArchName.split(":")[0]) ): # MI300 uses different float8 dtypes if isinstance(dtype, tuple): return tuple(_fix_fp8_dtype_for_rocm(x, device) for x in dtype) if isinstance(dtype, list): return [_fix_fp8_dtype_for_rocm(x, device) for x in dtype] if dtype == torch.float8_e4m3fn: return torch.float8_e4m3fnuz elif dtype == torch.float8_e5m2: return torch.float8_e5m2fnuz return dtype @instantiate_parametrized_tests class TestFP8Types(TestCase): @parametrize("float8_dtype", (torch.float8_e4m3fn, torch.float8_e5m2)) @parametrize("device", ("cuda", "cpu")) def test_xblock_for_small_numel(self, float8_dtype: torch.dtype, device: str): """ TritonOverrides.to_dtype will set min_elem_per_thread to 2 or 4 depends on the variant of fp8 type. This cause triton_heuristics.triton_config pick a XBLOCK larger than numel and fail the config sanity check. We should not pick a XBLOCK larger than xnumel """ float8_dtype = _fix_fp8_dtype_for_rocm(float8_dtype, device=device) if device == "cuda" and not PLATFORM_SUPPORTS_FP8: raise unittest.SkipTest(f8_msg) def f(x): return x.to(dtype=float8_dtype) x = torch.randn(1, device=device) expected = f(x) actual = torch.compile(f)(x) torch.testing.assert_close(expected.half(), actual.half(), rtol=1e-2, atol=1e-2) @parametrize("dtype", (torch.float16, torch.bfloat16)) @parametrize("device", ("cuda", "cpu")) def test_eager_fallback(self, dtype: torch.dtype, device: torch.device): if device == "cuda" and not PLATFORM_SUPPORTS_FP8: raise unittest.SkipTest(f8_msg) weight_shape = (32, 16) e4m3_type = torch.float8_e4m3fn e4m3_type = _fix_fp8_dtype_for_rocm(e4m3_type, device=device) def fp8_matmul_unwrapped(x): a_scale = torch.Tensor([1.0]).to(device=device) b_scale = torch.Tensor([1.0]).to(device=device) output_scale = None input_bias = torch.rand(32, device=device, dtype=dtype) weight = torch.rand(*weight_shape, device=device, dtype=dtype).T.to( e4m3_type ) a_inverse_scale = 1 / a_scale b_inverse_scale = 1 / b_scale output = torch._scaled_mm( x, weight, bias=input_bias, out_dtype=dtype, scale_a=a_inverse_scale, scale_b=b_inverse_scale, scale_result=output_scale, ) return output compiled_fp8_matmul = torch.compile( fp8_matmul_unwrapped, backend="inductor", dynamic=True ) x_shape = (16, 16) x = torch.rand(*x_shape, device=device, dtype=dtype).to(e4m3_type) y_fp8 = compiled_fp8_matmul(x) # noqa: F841 x_shape = (15, 16) x = torch.rand(*x_shape, device=device, dtype=dtype).to(e4m3_type) y_fp8 = compiled_fp8_matmul(x) # noqa: F841 @parametrize("dtype", (torch.float16, torch.bfloat16, torch.float)) @parametrize("shape", ("15,3,13", "4,2048,4096")) @parametrize("dst_types", [(torch.float8_e4m3fn, torch.float8_e5m2)]) @parametrize("device", ("cuda", "cpu")) def test_valid_cast( self, dtype: torch.dtype, shape: str, dst_types: tuple, device: torch.device ): if device == "cuda" and not PLATFORM_SUPPORTS_FP8: raise unittest.SkipTest(f8_msg) dst_types = _fix_fp8_dtype_for_rocm(dst_types, device=device) e4m3, e5m2 = dst_types def fp8_cast(x): y0 = x.to(dtype=e4m3).to(dtype) y1 = x.to(dtype=e5m2).to(dtype) return y0, y1 compiled_fp8_cast = torch.compile(fp8_cast, backend="inductor", dynamic=True) shape = [int(dim) for dim in shape.split(",")] x = torch.rand(*shape, device=device, dtype=dtype) y0_fp8, y1_fp8 = compiled_fp8_cast(x) torch.testing.assert_close(y0_fp8, x, rtol=5e-1, atol=5e-1) torch.testing.assert_close(y1_fp8, x, rtol=5e-1, atol=5e-1) @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) def test_bad_cast(self): def fp8_cast(x, dtype): return x.to(dtype=dtype) compiled_fp8_cast = torch.compile(fp8_cast, backend="inductor", dynamic=True) x_shape = (16, 16, 16) with self.assertRaisesRegex( torch._dynamo.exc.BackendCompilerFailed, "Conversions between float8_e5m2 and float8_e4m3fn is not supported!", ): x = torch.rand(*x_shape, device="cuda").to(dtype=torch.float8_e4m3fn) compiled_fp8_cast(x, torch.float8_e5m2) with self.assertRaisesRegex( torch._dynamo.exc.BackendCompilerFailed, "Conversions between float8_e5m2 and float8_e4m3fn is not supported!", ): x = torch.rand(*x_shape, device="cuda").to(dtype=torch.float8_e5m2) compiled_fp8_cast(x, torch.float8_e4m3fn) @parametrize("src_dtype", (torch.float16, torch.bfloat16, torch.float)) @parametrize("dst_dtype", (torch.float8_e4m3fn, torch.float8_e5m2)) @parametrize("shape", ("16,16,16", "4,2048,4096")) @parametrize("device", ("cuda", "cpu")) def test_to_fp8_saturated( self, src_dtype: torch.dtype, dst_dtype: torch.dtype, shape: str, device: torch.device, ): if device == "cuda" and not PLATFORM_SUPPORTS_FP8: raise unittest.SkipTest(f8_msg) dst_dtype = _fix_fp8_dtype_for_rocm(dst_dtype, device=device) def fp8_saturated(x, dtype): return _to_fp8_saturated(x, dtype) compiled_fp8_cast = torch.compile( fp8_saturated, backend="inductor", dynamic=True ) shape = [int(dim) for dim in shape.split(",")] x = torch.rand(*shape, device=device, dtype=src_dtype) y_compiled = compiled_fp8_cast(x, dst_dtype) y = fp8_saturated(x, dst_dtype) torch.testing.assert_close(y_compiled.half(), y.half(), rtol=5e-1, atol=5e-1) @parametrize("float8_dtype", (torch.float8_e4m3fn, torch.float8_e5m2)) @parametrize("shape", ("1,1,15", "1,10,15", "1,10,512", "1,10,4096", "4,2048,4096")) @parametrize("device", ("cuda", "cpu")) def test_amax_fp8_quant( self, float8_dtype: torch.dtype, shape: str, device: torch.device ): float8_dtype = _fix_fp8_dtype_for_rocm(float8_dtype, device=device) if device == "cuda" and not PLATFORM_SUPPORTS_FP8: raise unittest.SkipTest( "FP8 is only supported on H100+ and sm_89 and MI300+ devices" ) shape = [int(dim) for dim in shape.split(",")] batch_size, sequence_length, hidden_size = shape def amax_fp8(x: Tensor, scale: Tensor): y = torch.amax(torch.abs(x)) y_scaled = y.to(dtype=torch.float) * scale bits_fp8 = _to_fp8_saturated(y_scaled, float8_dtype) return bits_fp8 compiled_amax_fp8_quant = torch.compile(amax_fp8, backend="inductor") x_shape = (batch_size, sequence_length, hidden_size) x = torch.rand(*x_shape, device=device, dtype=torch.half) scale = torch.tensor(0.2, device=device, dtype=torch.float) y_compiled = compiled_amax_fp8_quant(x, scale) y = amax_fp8(x, scale) torch.testing.assert_close(y_compiled.half(), y.half(), rtol=1e-2, atol=1e-2) @parametrize("float8_dtype", (torch.float8_e4m3fn, torch.float8_e5m2)) @parametrize("shape", ("1,1,15", "1,10,15", "1,10,512", "1,10,4096", "4,2048,4096")) @parametrize("device", ("cuda", "cpu")) def test_amax_along_with_fp8_quant( self, float8_dtype: torch.dtype, shape: str, device: torch.device ): if device == "cuda" and not PLATFORM_SUPPORTS_FP8: raise unittest.SkipTest(f8_msg) float8_dtype = _fix_fp8_dtype_for_rocm(float8_dtype, device=device) shape = [int(dim) for dim in shape.split(",")] batch_size, sequence_length, hidden_size = shape def amax_fp8(x: Tensor, scale: Tensor, amax_buffer: Tensor): amax_buffer.fill_(torch.amax(torch.abs(x))) x_scaled = x.to(dtype=torch.float) * scale bits_fp8 = _to_fp8_saturated(x_scaled, float8_dtype) return bits_fp8 compiled_amax_fp8_quant = torch.compile(amax_fp8, backend="inductor") x_shape = (batch_size, sequence_length, hidden_size) x = torch.rand(*x_shape, device=device, dtype=torch.half) scale = torch.tensor(1.0, device=device, dtype=torch.float) amax_buffer_compiled = torch.zeros((1), device=device, dtype=torch.half) y_compiled = compiled_amax_fp8_quant(x, scale, amax_buffer_compiled) amax_buffer = torch.zeros((1), device=device, dtype=torch.half) y = amax_fp8(x, scale, amax_buffer) torch.testing.assert_close(y_compiled.half(), y.half(), rtol=1e-1, atol=1e-1) torch.testing.assert_close( amax_buffer_compiled, amax_buffer, rtol=1e-2, atol=1e-2 ) @parametrize("float8_dtype", (torch.float8_e4m3fn, torch.float8_e5m2)) @parametrize("amax_keep_dim", (True, False)) @parametrize("shape", ("1,1,15", "1,10,15", "1,10,512", "1,10,4096", "4,2048,4096")) @parametrize("device", ("cuda", "cpu")) def test_layernorm_fp8_quant( self, float8_dtype: torch.dtype, amax_keep_dim: bool, shape: str, device: torch.device, ): if device == "cuda" and not PLATFORM_SUPPORTS_FP8: raise unittest.SkipTest( "FP8 is only supported on H100+ and sm_89 and MI300+ devices" ) float8_dtype = _fix_fp8_dtype_for_rocm(float8_dtype, device=device) shape = [int(dim) for dim in shape.split(",")] batch_size, sequence_length, hidden_size = shape def ln_fp8(x: Tensor, scale: Tensor, amax_buffer: Tensor): x = torch.nn.functional.layer_norm( x.to(dtype=torch.float), [hidden_size], weight=None, bias=None, eps=1e-05, ) amax_buffer.fill_( torch.amax(torch.abs(x), keepdim=amax_keep_dim).reshape(-1)[0] ) x_scaled = x * scale bits_fp8 = _to_fp8_saturated(x_scaled, float8_dtype) return bits_fp8 compiled_ln_fp8_quant = torch.compile(ln_fp8, backend="inductor") x_shape = (batch_size, sequence_length, hidden_size) x = torch.rand(*x_shape, device=device, dtype=torch.half) scale = torch.tensor(0.2, device=device, dtype=torch.float) amax_buffer_compiled = torch.zeros((1), device=device, dtype=torch.half) y_compiled = compiled_ln_fp8_quant(x, scale, amax_buffer_compiled) amax_buffer = torch.zeros((1), device=device, dtype=torch.half) y = ln_fp8(x, scale, amax_buffer) torch.testing.assert_close(y_compiled.half(), y.half(), rtol=1e-1, atol=1e-1) torch.testing.assert_close( amax_buffer_compiled, amax_buffer, rtol=1e-2, atol=1e-2 ) @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) @parametrize("float8_dtype", (torch.float8_e4m3fn, torch.float8_e5m2)) @parametrize("shape", ("4,2048,4096",)) @parametrize("keepdim", (False, True)) def test_layernorm_fp8_quant_benchmark( self, float8_dtype: torch.dtype, shape: str, keepdim: bool, ): float8_dtype = _fix_fp8_dtype_for_rocm(float8_dtype, device="cuda") shape = [int(dim) for dim in shape.split(",")] batch_size, sequence_length, hidden_size = shape def ln(x: Tensor): x = torch.nn.functional.layer_norm( x.to(dtype=torch.float), [hidden_size], weight=None, bias=None, eps=1e-05, ) return x def ln_fp8(x: Tensor, scale: Tensor, amax_buffer: Tensor): x = torch.nn.functional.layer_norm( x.to(dtype=torch.float), [hidden_size], weight=None, bias=None, eps=1e-05, ) amax = torch.amax(torch.abs(x), keepdim=keepdim) amax_buffer.view_as(amax).copy_(amax) x_scaled = x * scale bits_fp8 = _to_fp8_saturated(x_scaled, float8_dtype) return bits_fp8 compiled_ln_fp8_quant = torch.compile(ln_fp8, backend="inductor") x_shape = (batch_size, sequence_length, hidden_size) x = torch.rand(*x_shape, device="cuda", dtype=torch.half) scale = torch.tensor(0.2, device="cuda", dtype=torch.float) amax_buffer_compiled = torch.zeros((1), device="cuda", dtype=torch.half) amax_buffer = torch.zeros((1), device="cuda", dtype=torch.half) _ = compiled_ln_fp8_quant(x, scale, amax_buffer_compiled) compiled_latency = utils.do_bench_using_profiling( functools.partial(compiled_ln_fp8_quant, x, scale, amax_buffer_compiled) ) eager_latency = utils.do_bench_using_profiling( functools.partial(ln_fp8, x, scale, amax_buffer) ) compiled_ln = torch.compile(ln, backend="inductor") _ = compiled_ln(x) ln_latency = utils.do_bench_using_profiling(functools.partial(compiled_ln, x)) print( f"Config: {float8_dtype=}, {shape=}, {keepdim=}. " f"Benchmark results: Inductor: {compiled_latency}ms, Eager: {eager_latency}ms, " f"LN only Inductor: {ln_latency}ms." ) @instantiate_parametrized_tests class TestFP8Lowering(TestCase): @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) @parametrize("dtype", (torch.bfloat16, torch.float32)) @parametrize("shape", ("16,16,32", "16,32,32", "1024,1024,512")) @parametrize("has_bias", (False, True)) @parametrize("use_fast_accum", (False, True)) @parametrize( "persistent_matmul", [False, True] if has_triton_tma_device() else [False] ) def test_tensorwise_scaling( self, dtype: torch.dtype, shape: str, has_bias: bool, use_fast_accum: bool, persistent_matmul: bool, ): if dtype is torch.float32 and has_bias: self.skipTest("bias is not supported when output dtype is float32") device = "cuda" dtype_float8 = torch.float8_e4m3fn dtype_float8 = _fix_fp8_dtype_for_rocm(dtype_float8, device) shape = [int(dim) for dim in shape.split(",")] M, K, N = shape # Matmul Y = X [M, K] x W [N, K] # input and output dtypes of _scaled_mm do not need to be the same, but # typically in a model they are x = torch.randn(M, K, dtype=dtype, device=device) w = torch.randn(N, K, dtype=dtype, device=device) bias = None if has_bias: bias = torch.randn(N, device=device, dtype=torch.bfloat16) # quantize weight (prior to inference) w_fp8, w_inverse_scale = _quantize_tensorwise(w, dtype_float8) w_t_fp8 = w_fp8.t() # quantize input x x_fp8, x_inverse_scale = _quantize_tensorwise(x, dtype_float8) def linear(x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias): y = torch._scaled_mm( x_fp8, w_t_fp8, x_inverse_scale, w_inverse_scale, bias, out_dtype=dtype, use_fast_accum=use_fast_accum, ) return y y_eager = linear( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) with config.patch({"triton.enable_persistent_tma_matmul": persistent_matmul}): linear_compiled = torch.compile( linear, backend="inductor", mode="max-autotune" ) y_compiled = linear_compiled( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) self.assertEqual(y_eager.dtype, dtype) self.assertEqual(y_compiled.dtype, dtype) # depending on the kernel config (BLOCK_M size, etc) selected during Inductor # autotuning for the compiled case, the results can be different because of # the way blocks of results are accumulated (float addition not associative), so # setting a small absolute tolerance in these tests torch.testing.assert_close(y_eager, y_compiled, rtol=1e-2, atol=0.05) @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) @parametrize("shape", ("16,16,32", "16,32,32", "1024,1024,512")) @parametrize("has_bias", (False, True)) @parametrize("use_fast_accum", (False, True)) @parametrize( "persistent_matmul", [False, True] if has_triton_tma_device() else [False] ) def test_rowwise_scaling( self, shape: str, has_bias: bool, use_fast_accum: bool, persistent_matmul: bool ): # Only bf16 output type is supported for row-wise scaling, not fp32 dtype: torch.dtype = torch.bfloat16 device = "cuda" dtype_float8 = torch.float8_e4m3fn dtype_float8 = _fix_fp8_dtype_for_rocm(dtype_float8, device) shape = [int(dim) for dim in shape.split(",")] M, K, N = shape # Matmul Y = X [M, K] x W [N, K] x = torch.randn(M, K, dtype=dtype, device=device) w = torch.randn(N, K, dtype=dtype, device=device) bias = None if has_bias: bias = torch.randn(N, device=device, dtype=torch.bfloat16) # quantize weight (prior to inference) w_fp8, w_inverse_scale = _quantize_rowwise(w, dtype_float8) w_t_fp8 = w_fp8.t() w_inverse_scale = w_inverse_scale.t() # scale_b should be (1, N) # quantize input x x_fp8, x_inverse_scale = _quantize_rowwise(x, dtype_float8) def linear(x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias): y = torch._scaled_mm( x_fp8, w_t_fp8, x_inverse_scale, w_inverse_scale, bias, out_dtype=dtype, use_fast_accum=use_fast_accum, ) return y y_eager = linear( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) with config.patch({"triton.enable_persistent_tma_matmul": persistent_matmul}): linear_compiled = torch.compile( linear, backend="inductor", mode="max-autotune" ) y_compiled = linear_compiled( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) self.assertEqual(y_eager.dtype, dtype) self.assertEqual(y_compiled.dtype, dtype) torch.testing.assert_close(y_eager, y_compiled, rtol=1e-2, atol=0.05) @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) @parametrize("M", (1, 3, 33, 257, 1024)) @parametrize("K", (16, 32, 1024)) @parametrize("N", (16, 2048)) @parametrize( "persistent_matmul", [False, True] if has_triton_tma_device() else [False] ) def test_tensorwise_scaling_acceptable_input_dims( self, M: int, K: int, N: int, persistent_matmul: bool ): # alignment requirements: K and N divisible by 16 dtype: torch.dtype = torch.bfloat16 use_fast_accum = True device = "cuda" dtype_float8 = torch.float8_e4m3fn dtype_float8 = _fix_fp8_dtype_for_rocm(dtype_float8, device) x = torch.randn(M, K, dtype=dtype, device=device) w = torch.randn(N, K, dtype=dtype, device=device) bias = None w_fp8, w_inverse_scale = _quantize_tensorwise(w, dtype_float8) w_t_fp8 = w_fp8.t() x_fp8, x_inverse_scale = _quantize_tensorwise(x, dtype_float8) def linear(x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias): y = torch._scaled_mm( x_fp8, w_t_fp8, x_inverse_scale, w_inverse_scale, bias, out_dtype=dtype, use_fast_accum=use_fast_accum, ) return y y_eager = linear( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) with config.patch({"triton.enable_persistent_tma_matmul": persistent_matmul}): linear_compiled = torch.compile( linear, backend="inductor", mode="max-autotune" ) y_compiled = linear_compiled( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) self.assertEqual(y_eager.dtype, dtype) self.assertEqual(y_compiled.dtype, dtype) torch.testing.assert_close(y_eager, y_compiled, rtol=1e-2, atol=0.07) @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) @parametrize("M", (1, 3, 33, 257, 1024)) @parametrize("K", (16, 32, 1024)) @parametrize("N", (16, 2048)) @parametrize( "persistent_matmul", [False, True] if has_triton_tma_device() else [False] ) def test_rowwise_scaling_acceptable_input_dims( self, M: int, K: int, N: int, persistent_matmul: bool ): dtype: torch.dtype = torch.bfloat16 use_fast_accum = True device = "cuda" dtype_float8 = torch.float8_e4m3fn dtype_float8 = _fix_fp8_dtype_for_rocm(dtype_float8, device) x = torch.randn(M, K, dtype=dtype, device=device) w = torch.randn(N, K, dtype=dtype, device=device) bias = torch.randn(N, device=device, dtype=torch.bfloat16) w_fp8, w_inverse_scale = _quantize_rowwise(w, dtype_float8) w_t_fp8 = w_fp8.t() w_inverse_scale = w_inverse_scale.t() # scale_b should be (1, N) x_fp8, x_inverse_scale = _quantize_rowwise(x, dtype_float8) def linear(x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias): y = torch._scaled_mm( x_fp8, w_t_fp8, x_inverse_scale, w_inverse_scale, bias, out_dtype=dtype, use_fast_accum=use_fast_accum, ) return y y_eager = linear( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) with config.patch({"triton.enable_persistent_tma_matmul": persistent_matmul}): linear_compiled = torch.compile( linear, backend="inductor", mode="max-autotune" ) y_compiled = linear_compiled( x_fp8, x_inverse_scale, w_t_fp8, w_inverse_scale, bias, ) self.assertEqual(y_eager.dtype, dtype) self.assertEqual(y_compiled.dtype, dtype) torch.testing.assert_close(y_eager, y_compiled, rtol=1e-2, atol=0.07) @unittest.skipIf(not PLATFORM_SUPPORTS_MX_GEMM, "Not supported on non B200") def test_mx_fp8_max_autotune(self): M, K, N = 128, 32, 128 BLOCK_SIZE = 32 device = "cuda" dtype = torch.bfloat16 A_ref = torch.eye(M, device=device, dtype=torch.bfloat16) B_ref = torch.eye(N, device=device, dtype=torch.bfloat16) A = A_ref.to(torch.float8_e4m3fn) B = B_ref.to(torch.float8_e4m3fn) A_scale = torch.full( (M, ceil_div(K, BLOCK_SIZE)), 1.0, device=device, dtype=torch.float8_e8m0fnu ) B_scale = torch.full( (N, ceil_div(K, BLOCK_SIZE)), 1.0, device=device, dtype=torch.float8_e8m0fnu ) A_scale = to_blocked(A_scale) B_scale = to_blocked(B_scale) def linear(A, B, A_scale, B_scale): y = torch._scaled_mm( A, B.t(), A_scale, B_scale, out_dtype=torch.bfloat16, use_fast_accum=False, ) return y y_eager = linear(A, B, A_scale, B_scale) linear_compiled = torch.compile(linear, backend="inductor", mode="max-autotune") y_compiled = linear_compiled(A, B, A_scale, B_scale) self.assertEqual(y_eager.dtype, dtype) self.assertEqual(y_compiled.dtype, dtype) torch.testing.assert_close(y_eager, y_compiled, rtol=1e-2, atol=0.07) @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) def test_unacceptable_input_dims(self): # for compiled ops, type checking is in torch/_meta_registrations.py dtype: torch.dtype = torch.bfloat16 device = "cuda" dtype_float8 = torch.float8_e4m3fn dtype_float8 = _fix_fp8_dtype_for_rocm(dtype_float8, device) M, K, N = 64, 15, 2048 # K needs to be a multiple of 16 x = torch.randn(M, K, dtype=dtype, device=device) w = torch.randn(N, K, dtype=dtype, device=device) bias = torch.randn(N, device=device, dtype=torch.bfloat16) w_fp8, w_inverse_scale = _quantize_tensorwise(w, dtype_float8) w_t_fp8 = w_fp8.t() def linear(x, w_t_fp8, w_inverse_scale, bias): x_fp8, x_inverse_scale = _quantize_tensorwise(x, dtype_float8) y = torch._scaled_mm( x_fp8, w_t_fp8, x_inverse_scale, w_inverse_scale, bias, out_dtype=dtype, use_fast_accum=True, ) return y linear_compiled = torch.compile(linear, backend="inductor", mode="max-autotune") with self.assertRaises(torch._dynamo.exc.TorchRuntimeError) as cm: linear_compiled( x, w_t_fp8, w_inverse_scale, bias, ) self.assertTrue( f"Expected self.size(1) to be divisible by 16, but got self.size(1)={K}" in str(cm.exception) ) @unittest.skipIf(not PLATFORM_SUPPORTS_FP8, f8_msg) def test_unacceptable_scale_dims_rowwise_scaling(self): dtype: torch.dtype = torch.bfloat16 device = "cuda" dtype_float8 = torch.float8_e4m3fn dtype_float8 = _fix_fp8_dtype_for_rocm(dtype_float8, device) M, K, N = 233, 32, 128 x = torch.randn(M, K, dtype=dtype, device=device) w = torch.randn(N, K, dtype=dtype, device=device) bias = torch.randn(N, device=device, dtype=torch.bfloat16) w_fp8, w_inverse_scale = _quantize_rowwise(w, dtype_float8) w_t_fp8 = w_fp8.t() def linear(x, w_t_fp8, w_inverse_scale, bias): x_fp8, x_inverse_scale = _quantize_rowwise(x, dtype_float8) y = torch._scaled_mm( x_fp8, w_t_fp8, w_inverse_scale.t(), # testing with w and x scales switched x_inverse_scale, bias, out_dtype=dtype, use_fast_accum=True, ) return y linear_compiled = torch.compile(linear, backend="inductor", mode="max-autotune") with self.assertRaises(torch._dynamo.exc.TorchRuntimeError) as cm: linear_compiled( x, w_t_fp8, w_inverse_scale, bias, ) self.assertTrue("Invalid scaling configuration." in str(cm.exception)) if __name__ == "__main__": if HAS_CUDA or HAS_CPU: run_tests()