# Copyright (c) ModelScope Contributors. All rights reserved. import time import torch from transformers import TrainerControl, TrainerState from typing import TYPE_CHECKING from swift.utils import empty_cache, get_current_device, get_device_count, get_env_args, get_logger, synchronize from .base import TrainerCallback if TYPE_CHECKING: from swift.trainers import Trainer, TrainingArguments logger = get_logger() device_flops_map = { 'GB200': 2.5e15, 'B200': 2.25e15, 'MI300X': 1336e12, 'H100': 312e12, 'H800': 312e12, 'H200': 989e12, 'A100': 312e12, 'A800': 312e12, 'L40S': 362.05e12, 'L40': 181.05e12, 'A40': 149.7e12, 'L20': 119.5e12, 'H20': 148e12, '910B': 354e12, 'Ascend910': 354e12, 'RTX 3070 Ti': 21.75e12 } class PerfMetricsLogCallback(TrainerCallback): """An callback for perf metrics (MFU etc) log implementation""" def __init__(self, args: 'TrainingArguments', trainer: 'Trainer'): super().__init__(args, trainer) self.device_tflops = None self.elapsed = 0.0 self.step_start_time = None def on_init_end(self, args: 'TrainingArguments', state: TrainerState, control: TrainerControl, **kwargs): # Top priority. Specify by ENV tflops = get_env_args('DEVICE_TFLOPS', int, None) device_count = max(get_device_count(), 1) if tflops is not None: logger.info(f"Specify theoretical max TFLOPS through ENV 'DEVICE_TFLOPS'. [{tflops} TFLOPS]") else: # Run a estimating test. dtype = kwargs.get('model').dtype device = torch.device(get_current_device()) logger.info(f'Estimating device TFLOPS baseline. Device: [{device}] dtype: [{dtype}]') tflops = self._estimate_device_tflops_by_dtype(device, dtype) logger.info(f'Estimate test finished. [{tflops} TFLOPS] Device count: [{device_count}]') # TODO Collect comprehensive TFLOPS data. Then provide a fallback strategy based on lookup tables. self.device_tflops = tflops * device_count def on_step_begin(self, args: 'TrainingArguments', state: TrainerState, control: TrainerControl, **kwargs): self.step_start_time = time.time() def on_step_end(self, args: 'TrainingArguments', state: TrainerState, control: TrainerControl, **kwargs): self.elapsed += time.time() - self.step_start_time def on_log(self, args: 'TrainingArguments', state: TrainerState, control: TrainerControl, logs=None, **kwargs): total_flos = getattr(state, 'total_flos', 0) actual_flops = total_flos / self.elapsed theoretical_max_flops = self.device_tflops * 1e12 mfu = actual_flops / theoretical_max_flops logger.debug(f'Total_flos[{total_flos}] elapsed_time[{self.elapsed}]sec Average MFU[{mfu}]') logs['MFU'] = round(mfu, 6) @staticmethod def _estimate_device_tflops_by_dtype(device: torch.device, dtype: torch.dtype, repeats: int = 60, dim: int = 8192): # Set matrix dimension shape = (dim, dim) backend = device.type if backend == 'npu': import torch_npu # Initialize matrices a = torch.randn(*shape, device=device, dtype=dtype) b = torch.randn(*shape, device=device, dtype=dtype) # Warm-up for _ in range(5): c = torch.matmul(a, b) synchronize(device) # Run benchmark test start = time.time() for _ in range(repeats): c = torch.matmul(a, b) synchronize(device) end = time.time() total_time = end - start avg_time = total_time / repeats # Adjust repeat count and retest if test duration is too short if total_time < 3: repeats = int(6 / avg_time) start = time.time() for _ in range(repeats): c = torch.matmul(a, b) synchronize(device) end = time.time() total_time = end - start avg_time = total_time / repeats del a, b, c empty_cache() tflops = (2 * dim**3 / avg_time) / 1e12 logger.info(f'[Device {device}] Total time: {total_time:.4f}s, dtype: {dtype}, Perf: {tflops:.4f} TFLOPS') return tflops @staticmethod def _retrieve_flops_from_map(device): """Retrieve theoretical FLOPS from Map. """ device_name = device.get_device_name() flops = None for name, value in device_flops_map.items(): if name in device_name: flops = value break return flops