# The MIT License (MIT) # # Copyright (c) 2015-2025 Advanced Micro Devices, Inc. All rights reserved. # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the 'Software'), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED 'AS IS', WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN # THE SOFTWARE. from argparse import ArgumentParser from diffusers import EulerDiscreteScheduler from transformers import CLIPTokenizer from PIL import Image import migraphx as mgx import os import sys import torch import time from functools import wraps from hip import hip from collections import namedtuple HipEventPair = namedtuple('HipEventPair', ['start', 'end']) # measurement helper def measure(fn): @wraps(fn) def measure_ms(*args, **kwargs): start_time = time.perf_counter_ns() result = fn(*args, **kwargs) end_time = time.perf_counter_ns() print( f"Elapsed time for {fn.__name__}: {(end_time - start_time) * 1e-6:.4f} ms\n" ) return result return measure_ms def get_args(): parser = ArgumentParser() # Model compile parser.add_argument( "--onnx-model-path", type=str, default="models/sd21-onnx/", help="Path to onnx model files.", ) parser.add_argument( "--compiled-model-path", type=str, default=None, help= "Path to compiled mxr model files. If not set, it will be saved next to the onnx model.", ) parser.add_argument( "--fp16", choices=["all", "vae", "clip", "unet"], nargs="+", help="Quantize models with fp16 precision.", ) parser.add_argument( "--force-compile", action="store_true", default=False, help="Ignore existing .mxr files and override them", ) parser.add_argument( "--exhaustive-tune", action="store_true", default=False, help="Perform exhaustive tuning when compiling onnx models", ) # Runtime parser.add_argument( "-s", "--seed", type=int, default=42, help="Random seed", ) parser.add_argument( "-t", "--steps", type=int, default=20, help="Number of steps", ) parser.add_argument("-b", "--batch", type=int, default=1, help="Batch count or number of images to produce") parser.add_argument( "-p", "--prompt", type=str, required=True, help="Prompt", ) parser.add_argument( "-n", "--negative-prompt", type=str, default="", help="Negative prompt", ) parser.add_argument( "--scale", type=float, default=7.0, help="Guidance scale", ) parser.add_argument( "-o", "--output", type=str, default=None, help="Output name", ) return parser.parse_args() mgx_to_torch_dtype_dict = { "bool_type": torch.bool, "uint8_type": torch.uint8, "int8_type": torch.int8, "int16_type": torch.int16, "int32_type": torch.int32, "int64_type": torch.int64, "float_type": torch.float32, "double_type": torch.float64, "half_type": torch.float16, } torch_to_mgx_dtype_dict = { value: key for (key, value) in mgx_to_torch_dtype_dict.items() } def tensor_to_arg(tensor): return mgx.argument_from_pointer( mgx.shape( **{ "type": torch_to_mgx_dtype_dict[tensor.dtype], "lens": list(tensor.size()), "strides": list(tensor.stride()) }), tensor.data_ptr()) def tensors_to_args(tensors): return {name: tensor_to_arg(tensor) for name, tensor in tensors.items()} def get_output_name(idx): return f"main:#output_{idx}" def copy_tensor_sync(tensor, data): tensor.copy_(data) torch.cuda.synchronize() def run_model_sync(model, args): model.run(args) mgx.gpu_sync() def allocate_torch_tensors(model): input_shapes = model.get_parameter_shapes() data_mapping = { name: torch.zeros(shape.lens()).to( mgx_to_torch_dtype_dict[shape.type_string()]).to(device="cuda") if not shape.scalar() else torch.tensor(0).to( mgx_to_torch_dtype_dict[shape.type_string()]).to(device="cuda") for name, shape in input_shapes.items() } return data_mapping class StableDiffusionMGX(): def __init__(self, onnx_model_path, compiled_model_path, fp16, batch, force_compile, exhaustive_tune): model_id = "stabilityai/stable-diffusion-2-1" print(f"Using {model_id}") print("Creating EulerDiscreteScheduler scheduler") self.scheduler = EulerDiscreteScheduler.from_pretrained( model_id, subfolder="scheduler") print("Creating CLIPTokenizer tokenizer...") self.tokenizer = CLIPTokenizer.from_pretrained(model_id, subfolder="tokenizer") if fp16 is None: fp16 = [] elif "all" in fp16: fp16 = ["vae", "clip", "unet"] self.batch = batch print("Load models...") self.models = { "vae": StableDiffusionMGX.load_mgx_model( "vae_decoder", {"latent_sample": [self.batch, 4, 64, 64]}, onnx_model_path, compiled_model_path=compiled_model_path, use_fp16="vae" in fp16, force_compile=force_compile, exhaustive_tune=exhaustive_tune, offload_copy=False, batch=self.batch), "clip": StableDiffusionMGX.load_mgx_model( "text_encoder", {"input_ids": [2, 77]}, onnx_model_path, compiled_model_path=compiled_model_path, use_fp16="clip" in fp16, force_compile=force_compile, exhaustive_tune=exhaustive_tune, offload_copy=False), "unet": StableDiffusionMGX.load_mgx_model( "unet", { "sample": [2 * self.batch, 4, 64, 64], "encoder_hidden_states": [2 * self.batch, 77, 1024], "timestep": [], }, onnx_model_path, compiled_model_path=compiled_model_path, use_fp16="unet" in fp16, force_compile=force_compile, exhaustive_tune=exhaustive_tune, offload_copy=False, batch=self.batch) } self.tensors = { "clip": allocate_torch_tensors(self.models["clip"]), "unet": allocate_torch_tensors(self.models["unet"]), "vae": allocate_torch_tensors(self.models["vae"]), } self.model_args = { "clip": tensors_to_args(self.tensors['clip']), "unet": tensors_to_args(self.tensors['unet']), "vae": tensors_to_args(self.tensors['vae']), } self.events = { "warmup": HipEventPair(start=hip.hipEventCreate()[1], end=hip.hipEventCreate()[1]), "run": HipEventPair(start=hip.hipEventCreate()[1], end=hip.hipEventCreate()[1]), "clip": HipEventPair(start=hip.hipEventCreate()[1], end=hip.hipEventCreate()[1]), "denoise": HipEventPair(start=hip.hipEventCreate()[1], end=hip.hipEventCreate()[1]), "decode": HipEventPair(start=hip.hipEventCreate()[1], end=hip.hipEventCreate()[1]), } self.stream = hip.hipStreamCreate()[1] def cleanup(self): for event in self.events.values(): hip.hipEventDestroy(event.start) hip.hipEventDestroy(event.end) hip.hipStreamDestroy(self.stream) def profile_start(self, name): if name in self.events: hip.hipEventRecord(self.events[name].start, None) def profile_end(self, name): if name in self.events: hip.hipEventRecord(self.events[name].end, None) @measure @torch.no_grad() def run(self, prompt, negative_prompt, steps, seed, scale): torch.cuda.synchronize() self.profile_start("run") # need to set this for each run self.scheduler.set_timesteps(steps, device="cuda") print("Tokenizing prompts...") prompt_tokens = self.tokenize(prompt, negative_prompt) print("Creating text embeddings...") self.profile_start("clip") text_embeddings = self.get_embeddings(prompt_tokens) self.profile_end("clip") print( f"Creating random input data ({1}x{4}x{64}x{64}) (latents) with seed={seed}..." ) latents = torch.randn( (self.batch, 4, 64, 64), generator=torch.manual_seed(seed)).to(device="cuda") print("Apply initial noise sigma\n") latents = latents * self.scheduler.init_noise_sigma print("Running denoising loop...") self.profile_start("denoise") for step, t in enumerate(self.scheduler.timesteps): print(f"#{step}/{len(self.scheduler.timesteps)} step") latents = self.denoise_step(text_embeddings, latents, t, scale) self.profile_end("denoise") print("Scale denoised result...") latents = 1 / 0.18215 * latents self.profile_start("decode") print("Decode denoised result...") image = self.decode(latents) self.profile_end("decode") torch.cuda.synchronize() self.profile_end("run") return image def print_summary(self, denoise_steps): print('WARMUP\t{:>9.2f} ms'.format( hip.hipEventElapsedTime(self.events['warmup'].start, self.events['warmup'].end)[1])) print('CLIP\t{:>9.2f} ms'.format( hip.hipEventElapsedTime(self.events['clip'].start, self.events['clip'].end)[1])) print('UNetx{}\t{:>9.2f} ms'.format( str(denoise_steps), hip.hipEventElapsedTime(self.events['denoise'].start, self.events['denoise'].end)[1])) print('VAE-Dec\t{:>9.2f} ms'.format( hip.hipEventElapsedTime(self.events['decode'].start, self.events['decode'].end)[1])) print('RUN\t{:>9.2f} ms'.format( hip.hipEventElapsedTime(self.events['run'].start, self.events['run'].end)[1])) @staticmethod @measure def load_mgx_model(name, shapes, onnx_model_path, compiled_model_path=None, use_fp16=False, force_compile=False, exhaustive_tune=False, offload_copy=True, batch=1): print(f"Loading {name} model...") if compiled_model_path is None: compiled_model_path = onnx_model_path onnx_file = f"{onnx_model_path}/{name}/model.onnx" mxr_file = f"{compiled_model_path}/{name}/model_{'fp16' if use_fp16 else 'fp32'}_b{batch}_{'gpu' if not offload_copy else 'oc'}.mxr" if not force_compile and os.path.isfile(mxr_file): print(f"Found mxr, loading it from {mxr_file}") model = mgx.load(mxr_file, format="msgpack") elif os.path.isfile(onnx_file): print(f"No mxr found at {mxr_file}") print(f"Parsing from {onnx_file}") model = mgx.parse_onnx(onnx_file, map_input_dims=shapes) if use_fp16: mgx.quantize_fp16(model) model.compile(mgx.get_target("gpu"), exhaustive_tune=exhaustive_tune, offload_copy=offload_copy) print(f"Saving {name} model to {mxr_file}") os.makedirs(os.path.dirname(mxr_file), exist_ok=True) mgx.save(model, mxr_file, format="msgpack") else: print( f"No {name} model found at {onnx_file} or {mxr_file}. Please download it and re-try." ) sys.exit(1) return model @measure def tokenize(self, prompt, negative_prompt): return self.tokenizer([prompt, negative_prompt], padding="max_length", max_length=self.tokenizer.model_max_length, truncation=True, return_tensors="pt") @measure def get_embeddings(self, prompt_tokens): copy_tensor_sync(self.tensors["clip"]["input_ids"], prompt_tokens.input_ids.to(torch.int32)) run_model_sync(self.models["clip"], self.model_args["clip"]) text_embeds = self.tensors["clip"][get_output_name(0)] return torch.cat( [torch.cat([i] * self.batch) for i in text_embeds.split(1)]) @staticmethod def convert_to_rgb_image(image): image = (image / 2 + 0.5).clamp(0, 1) image = image.detach().cpu().permute(0, 2, 3, 1).numpy() images = (image * 255).round().astype("uint8") return [Image.fromarray(images[i]) for i in range(images.shape[0])] @staticmethod def save_image(pil_image, filename="output.png"): pil_image.save(filename) @measure def denoise_step(self, text_embeddings, latents, t, scale): latents_model_input = torch.cat([latents] * 2) latents_model_input = self.scheduler.scale_model_input( latents_model_input, t).to(torch.float32).to(device="cuda") timestep = t.to(torch.int64).to(device="cuda") copy_tensor_sync(self.tensors["unet"]["sample"], latents_model_input) copy_tensor_sync(self.tensors["unet"]["encoder_hidden_states"], text_embeddings) copy_tensor_sync(self.tensors["unet"]["timestep"], timestep) run_model_sync(self.models["unet"], self.model_args['unet']) noise_pred_text, noise_pred_uncond = torch.tensor_split( self.tensors["unet"][get_output_name(0)], 2) # perform guidance noise_pred = noise_pred_uncond + scale * (noise_pred_text - noise_pred_uncond) # compute the previous noisy sample x_t -> x_t-1 return self.scheduler.step(noise_pred, t, latents).prev_sample @measure def decode(self, latents): copy_tensor_sync(self.tensors["vae"]["latent_sample"], latents) run_model_sync(self.models["vae"], self.model_args["vae"]) return self.tensors["vae"][get_output_name(0)] @measure def warmup(self, num_runs): self.profile_start("warmup") copy_tensor_sync(self.tensors["clip"]["input_ids"], torch.ones((2, 77)).to(torch.int32)) copy_tensor_sync( self.tensors["unet"]["sample"], torch.randn((2 * self.batch, 4, 64, 64)).to(torch.float32)) copy_tensor_sync( self.tensors["unet"]["encoder_hidden_states"], torch.randn((2 * self.batch, 77, 1024)).to(torch.float32)) copy_tensor_sync(self.tensors["unet"]["timestep"], torch.tensor(0).to(torch.int64)) copy_tensor_sync( self.tensors["vae"]["latent_sample"], torch.randn((self.batch, 4, 64, 64)).to(torch.float32)) for _ in range(num_runs): run_model_sync(self.models["clip"], self.model_args["clip"]) run_model_sync(self.models["unet"], self.model_args["unet"]) run_model_sync(self.models["vae"], self.model_args["vae"]) self.profile_end("warmup") if __name__ == "__main__": args = get_args() sd = StableDiffusionMGX(args.onnx_model_path, args.compiled_model_path, args.fp16, args.batch, args.force_compile, args.exhaustive_tune) print("Warmup") sd.warmup(5) print("Run") result = sd.run(args.prompt, args.negative_prompt, args.steps, args.seed, args.scale) print("Summary") sd.print_summary(args.steps) print("Cleanup") sd.cleanup() print("Convert result to rgb image...") images = StableDiffusionMGX.convert_to_rgb_image(result) for i, image in enumerate(images): filename = f"{args.batch}_{args.output}" if args.output else f"output_s{args.seed}_t{args.steps}_{i}.png" StableDiffusionMGX.save_image(image, filename) print(f"Image saved to {filename}")