提交 40fa1b94 编写于 作者: C chenyuanzhao

feat(imperative): add more tools for megengine

上级 67e4e834
# MegEngine Tools
This directory contains executable python files.
Use these files in the following way (replace `xxx` to specific file name, like `network_visualize`):
MegEngine 相关的工具汇总。使用方法如下(可将 `xxx` 替换成任一脚本文件,如 `network_visualize`):
```
```bash
python -m megengine.tools.xxx
```
工具列表:
### accuracy_shake_var_tree
将精度抖动分析结果构造成树结构,方便锁定引起抖动的根节点,以及查找依赖关系。
输入: compare_binary_iodump 的输出存入到的一个文件
输出: 第一个出现结果不一致的输出结点
执行命令: accuracy_shake_var_tree 中定义了一些函数组件,可按需集成到实际代码中。下面有一个测试代码:
```python
import megengine.tools.accuracy_shake_var_tree as st
r = st.parse('diff.txt')
for key, value in r.items():
n = st.varNode.get_varNode(key)
n.show_src_info()
print("reference nodes:")
for i in n.get_reference_list():
print(i.id)
```
### benchmark_op
逐个运行 functional op(并不是所有的 functional op),对比 MegEngine 与 PyTorch 的性能,通过量化结果来指导如何进行下一步的优化。
输入: 无
输出: 打印一个列表,对比在小输入和大输入的情况下 MegEngine 和 Pytorch 执行一些 functional op 的速度对比
执行命令: `python3 -m megengine.tools.benchmark_op`
### compare_binary_iodump
分析同一模型在不同平台下给定相同输入之后的输出是否完全一致。
输入: 两个目录(假设分别为 expect/ 和 actual/),分别存有不同平台下运行的 tensor 结果
输出: 打印所有的输出 tensor 信息,如果某个 tensor 在两个平台上的值不一致,那么会打印出第一个不一致的值
执行命令: `python3 -m megengine.tools.compare_binary_iodump expect/ actual/`
### draw_graph
用来查看静态图的 op 序列,有助于理解 MegEngine 的静态图在动态图的基础上做了哪些优化。
输入: `megengine.core.tensor.megbrain_graph.Graph._to_json` 得出的静态图描述文件,为 json 格式
输出: 一个 dot 文件,可通过 dot 命令绘制出图片
执行命令:
```bash
python3 -m megengine.tools.draw_graph -i dump.json -o dump.dot
dot -Tpng dump.dot -o dump.png
```
### dump_with_testcase_mge
将待测数据提前注入模型文件,并在本地运行得到期望结果,可与实际运行的结果进行比对以检查是否出错。
输入: 一个 MegEngine 模型文件,可选一些 npy 文件作为模型输入(也可以随机生成输入,如下面的命令示例)
输出: 一个带输入的 MegEngine 模型文件
执行命令: `python3 -m megengine.tools.dump_with_testcase_mge model.mge -d "#rand(0,255,14,2)"`
### graph_info_analyze
将图和内存信息的 json 文件的文件夹 logs 转换为 TensorBoard 的输入文件夹 logs_p。以便 TensorBoard 对图结构以及内存信息进行可视化。
输入: 图和内存信息的 json 文件的文件夹
输出: TensorBoard 的输入文件夹
执行命令: `python3 -m megengine.tools.graph_info_analyze -i logs -o logs_p`
### load_network_and_run
python 版本的 load_and_run。
输入: MegEngine 的模型文件,可选一些 npy 文件作为模型输入
输出: 模型执行并打印一些测速信息
执行命令: `python3 -m megengine.tools.load_network_and_run model.mge --iter 10`
### network_visualize
1. 分析给定的 MegEngine 模型中参数量信息,包括 shape、dtype、mean、std 以及 size 占比等。
2. 分析给定的 MegEngine 模型中算子 FLOPs 计算量以及占比,还有算子的 inputs\outputs shape、感受野、stride 等。
输入: MegEngine 的模型文件
输出: 模型中的参数量信息或计算量信息
执行命令:
```bash
# 分析参数量
python3 -m megengine.tools.network_visualize model.mge --cal_params --logging_to_stdout
# 分析计算量
python3 -m megengine.tools.network_visualize model.mge --cal_flops --logging_to_stdout
```
### profile_analyze
对于 load_and_run --profile 运行模型生成的 profile.json 文件或者 trace 模式下开启 profiling 功能并通过 trace.get_profile() 得到的 json 文件进行分析,得到静态图中算子的时间和显存占比等信息,以表格形式呈现。
输入: load_and_run 生成的 profile 文件
输出: 一个按照参数在输入文件中筛选得出的数据表格
执行命令:
```bash
# 生成供分析的 json 文件
python3 -m megengine.tools.load_network_and_run model.mge --warm-up --iter 10 --profile profile.json
#分析耗时前 3 的单个算子
python3 -m megengine.tools.profile_analyze profile.json -t 3
#筛选用时超过 10us 的 conv 按 flops 排序
python3 -m megengine.tools.profile_analyze profile.json -t 3 --order-by +flops --min-time 1e-5 --type ConvolutionForward
```
### profiler
对给定的训练程序,记录训练过程并以通用格式存储,可在浏览器上可视化。
输入: 需要一个 MegEngine 的训练程序(称之为 train.py,其中包含一个典型的 MegEngine 训练过程)
输出: 一些记录 profile 过程的 json 文件,默认在 profile 子目录下,可用 https://ui.perfetto.dev/ 进行加载并且可视化
执行命令: `python3 -m megengine.tools.profiler train.py`
### svg_viewer
查看 MegEngine 生成的显存占用图,可以帮助用户了解显存使用情况.
输入: 显存占用的 svg 图片
输出: 网页展示的可视化
执行命令: `python3 -m megengine.tools.svg_viewer`
# -*- coding: utf-8 -*-
# MegEngine is Licensed under the Apache License, Version 2.0 (the "License")
#
# Copyright (c) 2014-2021 Megvii Inc. All rights reserved.
#
# Unless required by applicable law or agreed to in writing,
# software distributed under the License is distributed on an
# "AS IS" BASIS, WITHOUT ARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
import time
import numpy as np
import megengine as mge
import megengine.module as MM
import megengine.functional as MF
import torch
import torch.nn as nn
import torch.nn.functional as TF
from tabulate import tabulate
module_cache = {
"conv2d": (MM.Conv2d(32, 32, 3, 1, 0), nn.Conv2d(32, 32, 3, 1, 0).cuda()),
"dw_conv2d": (MM.Conv2d(32, 32, 3, 1, 0, groups=32), nn.Conv2d(32, 32, 3, 1, 0, groups=32).cuda()),
"conv3d": (MM.Conv3d(32, 32, 3, 1, 0), nn.Conv3d(32, 32, 3, 1, 0).cuda()),
"ConvTranspose2d": (MM.ConvTranspose2d(32, 32, 3, 1, 0), nn.ConvTranspose2d(32, 32, 3, 1, 0).cuda()),
"BatchNorm2d": (MM.BatchNorm2d(64), nn.BatchNorm2d(64).cuda()),
"Linear": (MM.Linear(1000, 1000), nn.Linear(1000, 1000).cuda()),
}
test_cases = [
# (mge op, torch op, small inps, large inps, unpack_inps, rep)
("adaptive_avg_pool2d", lambda x: MF.adaptive_avg_pool2d(x, (7,7)), lambda x: TF.adaptive_avg_pool2d(x, (7,7)), [(2, 32, 16, 16)], [(64, 512, 16, 16)], True, 1000),
("adaptive_max_pool2d", lambda x: MF.adaptive_max_pool2d(x, (7,7)), lambda x: TF.adaptive_max_pool2d(x, (7,7)), [(2, 32, 16, 16)], [(64, 512, 16, 16)], True, 1000),
("argsort", MF.argsort, torch.argsort, [(1000,)], [(1000, 1000),], True, 1000),
("avg_pool2d", lambda x: MF.avg_pool2d(x, 2), lambda x: TF.avg_pool2d(x, 2), [(2, 32, 16, 16)], [(64, 512, 16, 16)], True, 1000),
("broadcast", lambda x: MF.broadcast_to(x, (5,) + x.shape), lambda x: torch.broadcast_to(x, (5,)+x.shape), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("batchedmatmul", MF.matmul, torch.matmul, [(8, 64, 32), (8, 32, 64)], [(8, 2048, 512), (8, 512, 2048)], True, 1000),
("batchnrom2d", lambda x: module_cache["BatchNorm2d"][0](x), lambda x: module_cache["BatchNorm2d"][1](x), [(2, 64, 16, 16)], [(64, 64, 128, 128)], True, 1000),
("concat", MF.concat, torch.cat, [(20, 100), (50, 100), (30, 100)], [(64, 512, 16, 16), (64, 512, 16, 16), (64, 512, 16, 16)], False, 1000),
("conv2d", lambda x: module_cache["conv2d"][0](x), lambda x: module_cache["conv2d"][1](x), [(2, 32, 16, 16)], [(32, 32, 128, 128)], True, 1000),
("conv3d", lambda x: module_cache["conv3d"][0](x), lambda x: module_cache["conv3d"][1](x), [(2, 32, 8, 8, 8)], [(32, 32, 16, 16, 16)], True, 1000),
("convTranspose2d", lambda x: module_cache["ConvTranspose2d"][0](x), lambda x: module_cache["ConvTranspose2d"][1](x), [(2, 32, 16, 16)], [(32, 32, 128, 128)], True, 1000),
("dropout", lambda x: MF.dropout(x, 0.5), TF.dropout, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("dw_conv2d", lambda x: module_cache["dw_conv2d"][0](x), lambda x: module_cache["dw_conv2d"][1](x), [(2, 32, 16, 16)], [(32, 32, 128, 128)], True, 1000),
("elemwise.unary", MF.log, torch.log, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("elemwise.binary", MF.add, torch.add, [(100,100), (100,100)], [(64, 512, 16, 16), (64, 512, 16, 16)], True, 1000),
("expand_dims", lambda x: MF.expand_dims(x, 0), lambda x: torch.unsqueeze(x, 0), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("gelu", MF.gelu, TF.gelu, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("hswish", MF.hswish, TF.hardswish, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("hsigmoid", MF.hsigmoid, TF.hardsigmoid, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("isinf", MF.isinf, torch.isinf, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("indeixngMultiAxisVec", lambda x: x[[1,3,5], [1,3,5], [1,3,5], [1,3,5]], lambda x: x[[1,3,5], [1,3,5], [1,3,5], [1,3,5]], [(10,10,10,10)], [(64, 512, 16, 16)], True, 1000),
("logsigmoid", MF.logsigmoid, TF.logsigmoid, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("leaky_relu", lambda x: MF.leaky_relu(x, 0.5), lambda x: TF.leaky_relu(x, 0.5), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("linear", lambda x: module_cache["Linear"][0](x), lambda x: module_cache["Linear"][1](x), [(10, 1000)], [(64, 128, 1000)], True, 1000),
("matinv", MF.matinv, torch.inverse, [(10,10)], [(30, 30)], True, 1000),
("matmul", MF.matmul, torch.matmul, [(64,32), (32, 64)], [(2048, 1024), (1024, 2048)], True, 1000),
("max_pool2d", lambda x: MF.max_pool2d(x, 2), lambda x: TF.max_pool2d(x, 2), [(2, 32, 16, 16)], [(64, 512, 16, 16)], True, 1000),
("normal", lambda x: mge.random.normal(0,1, x.shape), lambda x: torch.randn(x.shape, device="cuda"), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("prelu", MF.prelu, TF.prelu, [(100,100), (1,)], [(64, 512, 16, 16), (1,)], True, 1000),
("reduce.max", lambda x: MF.max(x, 0), lambda x: torch.max(x, 0), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("reduce.mean", lambda x: MF.mean(x, 0), lambda x: torch.mean(x, 0), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("reduce.mean", lambda x: MF.mean(x, 0), lambda x: torch.mean(x, 0), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("relu", MF.relu, TF.relu, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("relu6", MF.relu6, TF.relu6, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("repeat", lambda x: MF.repeat(x, 5), lambda x: torch.repeat_interleave(x, 5), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("silu", MF.silu, TF.silu, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("split", lambda x: MF.split(x, 5), lambda x: torch.split(x, 5), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("sigmoid", MF.sigmoid, TF.sigmoid, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("softmax", lambda x: MF.softmax(x, axis=1), lambda x: TF.softmax(x, dim=1), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("softplus", MF.softplus, TF.softplus, [(100,100)], [(64, 512, 16, 16)], True, 1000),
("squeeze", lambda x: MF.squeeze(x, 0), lambda x: torch.squeeze(x, 0), [(1, 100,100)], [(1, 64, 512, 16, 16)], True, 1000),
("stack", MF.stack, torch.stack, [(100,100), (100,100)], [(64, 512, 16, 16), (64, 512, 16, 16)], False, 10000),
("subtensor", lambda x: x[0:20, 10:60], lambda x: x[0:20, 10:60], [(100,100)], [(64, 512, 16, 16)], True, 1000),
("topk", lambda x: MF.topk(x, 10), lambda x: torch.topk(x, 10), [(100,100)], [(1000, 1000)], True, 1000),
("tile", lambda x: MF.tile(x, (2,)*len(x.shape)), lambda x: torch.tile(x, (2,)*len(x.shape)), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("transpose", lambda x: MF.transpose(x, list(range(len(x.shape)))[::-1]), lambda x: torch.permute(x, list(range(len(x.shape)))[::-1]), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("where", lambda x: MF.where(x > 0.5, x, x), lambda x: torch.where(x > 0.5, x, x), [(100,100)], [(64, 512, 16, 16)], True, 1000),
("uniform", lambda x: mge.random.uniform(0,1, x.shape), lambda x: torch.rand(x.shape, device="cuda"), [(100,100)], [(64, 512, 16, 16)], True, 1000),
]
def perf_func(func, inps, reps, unpack_inps, is_mge):
if is_mge:
mge._full_sync()
tik = time.time()
for _ in range(reps):
if unpack_inps:
out = func(*inps)
else:
out = func(inps)
mge._full_sync()
else:
torch.cuda.synchronize()
with torch.no_grad():
tik = time.time()
for _ in range(reps):
if unpack_inps:
out = func(*inps)
else:
out = func(inps)
torch.cuda.synchronize()
return time.time() - tik
def get_avg_time(func, inps, reps, unpack_inps, is_mge):
# warm up
for _ in range(2):
t = perf_func(func, inps, reps, unpack_inps, is_mge)
times = []
for _ in range(5):
t = perf_func(func, inps, reps, unpack_inps, is_mge)
times.append(t)
return np.mean(times)
def get_perf_results(mge_func, torch_func, shapes, unpack_inps, reps):
inps = [
np.random.randn(*shape) for shape in shapes
]
inps_mge = [mge.tensor(inp, dtype="float32") for inp in inps]
avg_time_mge = get_avg_time(mge_func, inps_mge, reps, unpack_inps, True)
inps_torch = [torch.Tensor(inp).type(torch.float).cuda() for inp in inps]
avg_time_torch = get_avg_time(torch_func, inps_torch, reps, unpack_inps, False)
return avg_time_mge, avg_time_torch
if __name__ == "__main__":
header = ["opr_name", "time(mge/pytorch; small input)", "time(mge/pytorch; large input)"]
table = []
for case in test_cases:
assert len(case) == 7
name, mge_func, torch_func, small_shapes, large_shapes, unpack_inps, reps = case
data = []
data.append(name)
print("========== op: {}".format(name))
avg_time_mge, avg_time_torch = get_perf_results(mge_func, torch_func, small_shapes, unpack_inps, reps)
print("mge time: {}".format(avg_time_mge))
print("torch time: {}".format(avg_time_torch))
data.append("{:.2f}".format(avg_time_mge / avg_time_torch))
avg_time_mge, avg_time_torch = get_perf_results(mge_func, torch_func, large_shapes, unpack_inps, reps)
print("mge time: {}".format(avg_time_mge))
print("torch time: {}".format(avg_time_torch))
data.append("{:.2f}".format(avg_time_mge / avg_time_torch))
table.append(data)
print(tabulate(table, header, tablefmt="github"))
\ No newline at end of file
# -*- coding: utf-8 -*-
# MegEngine is Licensed under the Apache License, Version 2.0 (the "License")
#
# Copyright (c) 2014-2021 Megvii Inc. All rights reserved.
#
# Unless required by applicable law or agreed to in writing,
# software distributed under the License is distributed on an
# "AS IS" BASIS, WITHOUT ARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
import argparse
import os
import re
import struct
import cv2
import numpy as np
import megengine as mge
import megengine.core._imperative_rt as rt
import megengine.core.tensor.megbrain_graph as G
from megengine import tensor
from megengine.core.ops import builtin
from megengine.utils import comp_graph_tools as cgtools
logger = mge.get_logger(__name__)
def auto_reformat_image(args, path, data, dst_shape):
"""reformat image to target shape
:param data: image data as numpy array
:param dst_shape: target shape
"""
dim3_format = False # required input format does not contain batch
hwc_format = False # required input format is NHWC
if not dst_shape: # input tensor shape is not predefined
if len(data.shape) == 2:
chl = 1
h = data.shape[0]
w = data.shape[1]
else:
assert len(data.shape) == 3, "Input image must be of dimension 2 or 3"
h, w, chl = data.shape
dst_shape = (1, chl, h, w)
if len(dst_shape) == 3:
dst_shape = (1,) + dst_shape
dim3_format = True
assert len(dst_shape) == 4, "bad dst_shape: {}".format(dst_shape)
chl = dst_shape[1]
if chl in [1, 3]:
n, c, h, w = dst_shape
dst_shape = (n, h, w, c)
else:
chl = dst_shape[3]
assert chl in [1, 3], "can not infer input format from shape: {}".format(
dst_shape
)
hwc_format = True
# dst_shape has now been normalized to NHWC format
if args.resize_input:
h, w = dst_shape[1:3]
data = cv2.resize(data, (w, h))
logger.info("input {} resized to {}".format(path, data.shape))
if chl == 1:
data = cv2.cvtColor(data, cv2.COLOR_BGR2GRAY)
data = data[:, :, np.newaxis]
assert data.ndim == 3
data = data[np.newaxis]
# data normalized to NHWC format
if not hwc_format:
data = np.transpose(data, (0, 3, 1, 2))
if dim3_format:
data = np.squeeze(data, 0)
return data
def read_input_data(args, dst_shape, dtype, path, repeat):
def check_shape_equal(dst_shape, data_shape):
if len(dst_shape):
assert len(data_shape) == len(
dst_shape
), "input/data shapes mismatch: {} vs {}".format(dst_shape, data_shape)
if data_shape[1:] != dst_shape[1:]:
logger.warning(
"dst_shape is {}; data_shape is {}".format(dst_shape, data_shape)
)
if path.startswith("#"):
assert not args.resize_input
assert not args.input_transform
spec = path
m = re.match(r"^#rand\(([-0-9.]*)\s*,\s*([-0-9.]*)\s*(,[^\)]+)?\)$", spec)
assert m, "bad spec {}".format(spec)
rng_min = float(m.group(1))
rng_max = float(m.group(2))
if m.group(3):
shape_str = m.group(3)
try:
shape = shape_str[1:].split(",")
if shape[-1].strip() == "...":
shape = shape[:-1]
shape.extend(list(dst_shape[len(shape) :]))
data_shape = tuple(map(int, shape))
except ValueError as e:
raise ValueError("bad spec {}: {}".format(spec, e.args))
else:
data_shape = dst_shape
check_shape_equal(dst_shape, data_shape)
return np.random.uniform(rng_min, rng_max, data_shape).astype(dtype)
# try to load image
data = cv2.imread(path, cv2.IMREAD_COLOR)
if data is None:
assert not args.resize_input
data = np.load(path)
assert isinstance(data, np.ndarray)
else:
# load image succeeds, so we expect input format is image format
data = auto_reformat_image(args, path, data, dst_shape)
data = np.repeat(data, repeat, axis=0)
if repeat > 1:
logger.info(
"repeat input for {} times, data shape is {}".format(repeat, data.shape)
)
check_shape_equal(dst_shape, data.shape)
if args.input_transform:
data = eval(args.input_transform, {"data": data, "np": np})
return data
def gen_one_testcase(args, inputs, spec):
paths = spec.split(";")
if len(paths) != len(inputs):
if len(paths) == 1 and paths[0].startswith("#"):
paths = ["{}:{}".format(name, paths[0]) for name in inputs.keys()]
assert len(paths) == len(inputs), "required inputs: {}; data paths: {}".format(
inputs.keys(), paths
)
if len(paths) == 1 and ":" not in paths[0]:
paths[0] = next(iter(inputs.keys())) + ":" + paths[0]
ret = {}
for path in paths:
var, path = path.split(":")
if args.repeat:
repeat = args.repeat
else:
repeat = 1
ret[var] = read_input_data(
args, inputs[var].shape, inputs[var].dtype, path, repeat
)
return ret
def make_feeds(args):
ret = G.load_graph(args.input)
cg_rt, outputs = ret.graph, ret.output_vars_list
inputs = cgtools.get_dep_vars(outputs, "Host2DeviceCopy")
inputs = {i.name: i for i in inputs}
if not args.no_assert:
replace_varmap = {}
inp_map = {}
# replace var use InputNode
for name, var in inputs.items():
inp = G.InputNode(
device="xpux", dtype=var.dtype, shape=var.shape, graph=cg_rt
)
replace_varmap[var] = inp.outputs[0]
inp_map[name] = inp
new = cgtools.replace_vars(outputs, replace_varmap)
if isinstance(new, rt.VarNode):
new = list(new)
output_nodes = [G.OutputNode(var) for var in new]
func = cg_rt.compile([node.outputs[0] for node in output_nodes])
def make_dev_tensor(value, dtype=None, device=None):
return tensor(value, dtype=dtype, device=device)._dev_tensor()
def calculate(*args, **kwargs):
output_val = []
# set inputs value
for name, var in inputs.items():
val = kwargs.pop(name, None)
assert val is not None, "miss input name{}".format(name)
dev_tensor = make_dev_tensor(val, dtype=var.dtype, device="xpux")
inp_map[name].set_value(dev_tensor)
func.execute()
for res in output_nodes:
output_val.append(res.get_value().numpy())
return output_val
def expect_name(var):
return "{}:expect".format(var.name)
testcases = []
np.set_printoptions(precision=2, threshold=4, suppress=True)
data_list = []
for item in args.data:
if item.startswith("@"):
with open(item[1:], "r") as f:
data_list.extend([line.rstrip() for line in f if line.rstrip() != ""])
else:
data_list.append(item)
for inp_spec in data_list:
cur_testcase = gen_one_testcase(args, inputs, inp_spec)
assert len(cur_testcase) == len(
inputs
), "required inputs: {}; given data: {}".format(
inputs.keys(), cur_testcase.keys()
)
if not args.no_assert:
outputs_get = calculate(**cur_testcase)
for var, val in zip(outputs, outputs_get):
cur_testcase[expect_name(var)] = val
logger.info(
"generate test groundtruth: var={} shape={} range=({}, {})"
" mean={} var={}".format(
var, val.shape, val.min(), val.max(), np.mean(val), np.var(val)
)
)
testcases.append(cur_testcase)
logger.info(
"add testcase: \n {}".format(
"\n ".join(
"{}: shape={} dtype={} range=({:.2f},{:.2f}) "
"mean={:.2f} sd={:.2f}".format(
k, v.shape, v.dtype, v.min(), v.max(), np.mean(v), np.std(v)
)
for k, v in sorted(cur_testcase.items())
)
)
)
if not args.no_assert:
def expect_shp(var):
ret = var.shape
if ret:
return ret
return testcases[0][expect_name(var)].shape
def assert_equal(expect, real, **kwargs):
op = builtin.AssertEqual(**kwargs)
(res,) = G.apply_normal_varnode(op, expect, real)
return res
verbose = not args.silent
outputs_new = []
for i in outputs:
device = rt.CompNode("xpux")
dtype = i.dtype
name = expect_name(i)
shape = expect_shp(i)
# make expect output as one input of model.
expect_get = rt.make_h2d(cg_rt, device, dtype, shape, name)
# insert assert opr to check expect and real.
outputs_new.append(
assert_equal(
expect_get,
i,
verbose=verbose,
maxerr=args.maxerr,
)
)
inputs[expect_name(i)] = expect_get
outputs = outputs_new
return {"outputs": outputs, "testcases": testcases}
def optimize_for_inference(args, outputs):
args_list = [
"enable_io16xc32",
"enable_ioc16",
"enable_hwcd4",
"enable_nchw4",
"enable_nchw88",
"enable_nchw44",
"enable_nchw44_dot",
"enable_nchw32",
"enable_chwn4",
"enable_fuse_conv_bias_nonlinearity",
"enable_fuse_conv_bias_with_z",
"enable_fuse_preprocess",
]
kwargs = {}
for k in args_list:
if getattr(args, k):
kwargs[k] = True
if args.optimize_for_inference:
outputs = G.optimize_for_inference(outputs, **kwargs)
return outputs
def main():
parser = argparse.ArgumentParser(
description="Pack computing graph, input values and expected output "
"values into one file for checking correctness. README.md gives more "
"details on the usage",
formatter_class=argparse.ArgumentDefaultsHelpFormatter,
)
parser.add_argument("input", help="MegEngine dumped model file")
parser.add_argument("-o", "--output", help="output file", required=True)
parser.add_argument(
"-d",
"--data",
default=[],
action="append",
required=True,
help="Given input test data when input file is a network, "
"and current network output would be used as groundtruth. "
"The format is var0:file0;var1:file1... to specify data files for "
"input vars. It can also be #rand(min,max,shape...) for generating "
"random input data, for example, #rand(0,255), "
"#rand(0,255,1,3,224,224) or #rand(0, 255, 1, ...) where `...` means "
"the remaining part of the original shape. "
"If the shape is not specified, the shape of "
"corresponding input tensors in the network will be used. "
"If there is only one input var, its name can be omitted. "
"Each data file can either be an image which can be loaded by opencv, "
"or a pickled numpy.ndarray. "
"This option can be given multiple times to add multiple testcases. "
" *NOTE* "
"If you start the data with the letter @, the rest should be a "
"filename, and each line in the file should be a single datum in "
"the format described above. ",
)
parser.add_argument(
"--repeat",
type=int,
default=1,
help="Specify how many times the input image is repeated. "
"Useful when running benchmark for batch size other than one. "
"Have no effect on randomly generated input data.",
)
parser.add_argument(
"--silent",
action="store_true",
help="set verbose to False in asserti_equal opr",
)
parser.add_argument(
"--optimize-for-inference",
action="store_true",
help="enable optimization for inference",
)
parser.add_argument(
"--no-assert",
action="store_true",
help="do not insert assert_equal opr to check result; "
"this option is useful for benchmarking",
)
parser.add_argument(
"--maxerr",
type=float,
default=1e-4,
help="max error for assert_equal check during runtime",
)
parser.add_argument(
"--resize-input",
action="store_true",
help="resize input image to fit input var shape",
)
parser.add_argument(
"--input-transform",
help="a python expression to transform the input data. "
"Example: data / np.std(data)",
)
parser.add_argument(
"--discard-var-name",
action="store_true",
help="discard variable and param names in the " "generated output",
)
parser.add_argument(
"--output-strip-info", action="store_true", help="output code strip information"
)
parser.add_argument(
"--enable-io16xc32",
action="store_true",
help="transform the mode to float16 io float32 compute",
)
parser.add_argument(
"--enable-ioc16",
action="store_true",
help="transform the dtype of the model to float16 io " "and compute",
)
parser.add_argument(
"--enable-fuse-conv-bias-nonlinearity",
action="store_true",
help="fuse convolution bias and nonlinearity opr to a "
"conv_bias opr and compute",
)
parser.add_argument(
"--enable-hwcd4",
action="store_true",
help="transform the model format from NCHW to NHWCD4 "
"for inference; you may need to disable CUDA and set "
"MGB_USE_MEGDNN_DBG=2",
)
parser.add_argument(
"--enable-nchw4",
action="store_true",
help="transform the model format from NCHW to NCHW4 " "for inference",
)
parser.add_argument(
"--enable-nchw88",
action="store_true",
help="transform the model format from NCHW to NCHW88 " "for inference",
)
parser.add_argument(
"--enable-nchw44",
action="store_true",
help="transform the model format from NCHW to NCHW44 " "for inference",
)
parser.add_argument(
"--enable-nchw44-dot",
action="store_true",
help="transform the model format from NCHW to NCHW44_DOT "
"for optimizing armv8.2 dot in inference",
)
parser.add_argument(
"--enable-nchw32",
action="store_true",
help="transform the model format from NCHW4 to NCHW32 "
"for inference on nvidia TensoCore",
)
parser.add_argument(
"--enable-chwn4",
action="store_true",
help="transform the model format to CHWN4 "
"for inference, mainly used for nvidia tensorcore",
)
parser.add_argument(
"--enable-fuse-conv-bias-with-z",
action="store_true",
help="fuse conv_bias with z input for inference on "
"nvidia GPU (this optimization pass will result in mismatch "
"of the precision of output of training and inference)",
)
parser.add_argument(
"--enable-fuse-preprocess",
action="store_true",
help="fuse astype\pad_channel\dimshuffle and etc opr "
"from h2d opr",
)
args = parser.parse_args()
feeds = make_feeds(args)
assert isinstance(feeds, dict) and feeds["testcases"], "testcases can not be empty"
output_mgbvars = feeds["outputs"]
output_mgbvars = optimize_for_inference(args, output_mgbvars)
inputs = cgtools.get_dep_vars(output_mgbvars, "Host2DeviceCopy")
inputs = sorted((i.name, i.dtype) for i in inputs)
if args.discard_var_name:
sereg_kwargs = dict(keep_var_name=0, keep_param_name=False)
else:
sereg_kwargs = dict(keep_var_name=2, keep_param_name=True)
strip_info_file = args.output + ".json" if args.output_strip_info else None
with open(args.output, "wb") as fout:
fout.write(b"mgbtest0")
fout.write(struct.pack("I", len(feeds["testcases"])))
dump_content, stat = G.dump_graph(
output_mgbvars,
append_json=True,
strip_info_file=strip_info_file,
**sereg_kwargs,
)
fout.write(dump_content)
logger.info(
"graph dump sizes: tot_size={:.3f}KiB overhead={:.3f}KiB".format(
stat.tot_bytes / 1024, (stat.tot_bytes - stat.tensor_value_bytes) / 1024
)
)
def make_dev_tensor(value, dtype=None, device=None):
return tensor(value, dtype=dtype, device=device)._dev_tensor()
for testcase in feeds["testcases"]:
assert isinstance(testcase, dict)
cg = G.Graph()
output_mgbvars = []
for name, dtype in inputs:
output_mgbvars.append(
cg.make_const(
make_dev_tensor(testcase.pop(name), dtype=dtype, device="cpux")
)
)
assert not testcase, "extra inputs provided in testcase: {}".format(
testcase.keys()
)
with open(args.output, "ab") as fout:
dump_content, _ = G.dump_graph(
output_mgbvars, strip_info_file=strip_info_file, append_json=True
)
fout.write(dump_content)
if __name__ == "__main__":
main()
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