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# Ultralytics YOLOv5 🚀, AGPL-3.0 license
"""Common modules."""
import ast
import contextlib
import json
import math
import platform
import warnings
import zipfile
from collections import OrderedDict, namedtuple
from copy import copy
from pathlib import Path
from urllib.parse import urlparse
import cv2
import numpy as np
import pandas as pd
import requests
import torch
import torch.nn as nn
from PIL import Image
from torch.cuda import amp
# Import 'ultralytics' package or install if missing
try:
import ultralytics
assert hasattr(ultralytics, "__version__") # verify package is not directory
except (ImportError, AssertionError):
import os
os.system("pip install -U ultralytics")
import ultralytics
from ultralytics.utils.plotting import Annotator, colors, save_one_box
from utils import TryExcept
from utils.dataloaders import exif_transpose, letterbox
from utils.general import (
LOGGER,
ROOT,
Profile,
check_requirements,
check_suffix,
check_version,
colorstr,
increment_path,
is_jupyter,
make_divisible,
non_max_suppression,
scale_boxes,
xywh2xyxy,
xyxy2xywh,
yaml_load,
)
from utils.torch_utils import copy_attr, smart_inference_mode
def autopad(k, p=None, d=1):
"""
Pads kernel to 'same' output shape, adjusting for optional dilation; returns padding size.
`k`: kernel, `p`: padding, `d`: dilation.
"""
if d > 1:
k = d * (k - 1) + 1 if isinstance(k, int) else [d * (x - 1) + 1 for x in k] # actual kernel-size
if p is None:
p = k // 2 if isinstance(k, int) else [x // 2 for x in k] # auto-pad
return p
class Conv(nn.Module):
"""Applies a convolution, batch normalization, and activation function to an input tensor in a neural network."""
default_act = nn.SiLU() # default activation
def __init__(self, c1, c2, k=1, s=1, p=None, g=1, d=1, act=True):
"""Initializes a standard convolution layer with optional batch normalization and activation."""
super().__init__()
self.conv = nn.Conv2d(c1, c2, k, s, autopad(k, p, d), groups=g, dilation=d, bias=False)
self.bn = nn.BatchNorm2d(c2)
self.act = self.default_act if act is True else act if isinstance(act, nn.Module) else nn.Identity()
def forward(self, x):
"""Applies a convolution followed by batch normalization and an activation function to the input tensor `x`."""
return self.act(self.bn(self.conv(x)))
def forward_fuse(self, x):
"""Applies a fused convolution and activation function to the input tensor `x`."""
return self.act(self.conv(x))
class DWConv(Conv):
"""Implements a depth-wise convolution layer with optional activation for efficient spatial filtering."""
def __init__(self, c1, c2, k=1, s=1, d=1, act=True):
"""Initializes a depth-wise convolution layer with optional activation; args: input channels (c1), output
channels (c2), kernel size (k), stride (s), dilation (d), and activation flag (act).
"""
super().__init__(c1, c2, k, s, g=math.gcd(c1, c2), d=d, act=act)
class DWConvTranspose2d(nn.ConvTranspose2d):
"""A depth-wise transpose convolutional layer for upsampling in neural networks, particularly in YOLOv5 models."""
def __init__(self, c1, c2, k=1, s=1, p1=0, p2=0):
"""Initializes a depth-wise transpose convolutional layer for YOLOv5; args: input channels (c1), output channels
(c2), kernel size (k), stride (s), input padding (p1), output padding (p2).
"""
super().__init__(c1, c2, k, s, p1, p2, groups=math.gcd(c1, c2))
class TransformerLayer(nn.Module):
"""Transformer layer with multihead attention and linear layers, optimized by removing LayerNorm."""
def __init__(self, c, num_heads):
"""
Initializes a transformer layer, sans LayerNorm for performance, with multihead attention and linear layers.
See as described in https://arxiv.org/abs/2010.11929.
"""
super().__init__()
self.q = nn.Linear(c, c, bias=False)
self.k = nn.Linear(c, c, bias=False)
self.v = nn.Linear(c, c, bias=False)
self.ma = nn.MultiheadAttention(embed_dim=c, num_heads=num_heads)
self.fc1 = nn.Linear(c, c, bias=False)
self.fc2 = nn.Linear(c, c, bias=False)
def forward(self, x):
"""Performs forward pass using MultiheadAttention and two linear transformations with residual connections."""
x = self.ma(self.q(x), self.k(x), self.v(x))[0] + x
x = self.fc2(self.fc1(x)) + x
return x
class TransformerBlock(nn.Module):
"""A Transformer block for vision tasks with convolution, position embeddings, and Transformer layers."""
def __init__(self, c1, c2, num_heads, num_layers):
"""Initializes a Transformer block for vision tasks, adapting dimensions if necessary and stacking specified
layers.
"""
super().__init__()
self.conv = None
if c1 != c2:
self.conv = Conv(c1, c2)
self.linear = nn.Linear(c2, c2) # learnable position embedding
self.tr = nn.Sequential(*(TransformerLayer(c2, num_heads) for _ in range(num_layers)))
self.c2 = c2
def forward(self, x):
"""Processes input through an optional convolution, followed by Transformer layers and position embeddings for
object detection.
"""
if self.conv is not None:
x = self.conv(x)
b, _, w, h = x.shape
p = x.flatten(2).permute(2, 0, 1)
return self.tr(p + self.linear(p)).permute(1, 2, 0).reshape(b, self.c2, w, h)
class Bottleneck(nn.Module):
"""A bottleneck layer with optional shortcut and group convolution for efficient feature extraction."""
def __init__(self, c1, c2, shortcut=True, g=1, e=0.5):
"""Initializes a standard bottleneck layer with optional shortcut and group convolution, supporting channel
expansion.
"""
super().__init__()
c_ = int(c2 * e) # hidden channels
self.cv1 = Conv(c1, c_, 1, 1)
self.cv2 = Conv(c_, c2, 3, 1, g=g)
self.add = shortcut and c1 == c2
def forward(self, x):
"""Processes input through two convolutions, optionally adds shortcut if channel dimensions match; input is a
tensor.
"""
return x + self.cv2(self.cv1(x)) if self.add else self.cv2(self.cv1(x))
class BottleneckCSP(nn.Module):
"""CSP bottleneck layer for feature extraction with cross-stage partial connections and optional shortcuts."""
def __init__(self, c1, c2, n=1, shortcut=True, g=1, e=0.5):
"""Initializes CSP bottleneck with optional shortcuts; args: ch_in, ch_out, number of repeats, shortcut bool,
groups, expansion.
"""
super().__init__()
c_ = int(c2 * e) # hidden channels
self.cv1 = Conv(c1, c_, 1, 1)
self.cv2 = nn.Conv2d(c1, c_, 1, 1, bias=False)
self.cv3 = nn.Conv2d(c_, c_, 1, 1, bias=False)
self.cv4 = Conv(2 * c_, c2, 1, 1)
self.bn = nn.BatchNorm2d(2 * c_) # applied to cat(cv2, cv3)
self.act = nn.SiLU()
self.m = nn.Sequential(*(Bottleneck(c_, c_, shortcut, g, e=1.0) for _ in range(n)))
def forward(self, x):
"""Performs forward pass by applying layers, activation, and concatenation on input x, returning feature-
enhanced output.
"""
y1 = self.cv3(self.m(self.cv1(x)))
y2 = self.cv2(x)
return self.cv4(self.act(self.bn(torch.cat((y1, y2), 1))))
class CrossConv(nn.Module):
"""Implements a cross convolution layer with downsampling, expansion, and optional shortcut."""
def __init__(self, c1, c2, k=3, s=1, g=1, e=1.0, shortcut=False):
"""
Initializes CrossConv with downsampling, expanding, and optionally shortcutting; `c1` input, `c2` output
channels.
Inputs are ch_in, ch_out, kernel, stride, groups, expansion, shortcut.
"""
super().__init__()
c_ = int(c2 * e) # hidden channels
self.cv1 = Conv(c1, c_, (1, k), (1, s))
self.cv2 = Conv(c_, c2, (k, 1), (s, 1), g=g)
self.add = shortcut and c1 == c2
def forward(self, x):
"""Performs feature sampling, expanding, and applies shortcut if channels match; expects `x` input tensor."""
return x + self.cv2(self.cv1(x)) if self.add else self.cv2(self.cv1(x))
class C3(nn.Module):
"""Implements a CSP Bottleneck module with three convolutions for enhanced feature extraction in neural networks."""
def __init__(self, c1, c2, n=1, shortcut=True, g=1, e=0.5):
"""Initializes C3 module with options for channel count, bottleneck repetition, shortcut usage, group
convolutions, and expansion.
"""
super().__init__()
c_ = int(c2 * e) # hidden channels
self.cv1 = Conv(c1, c_, 1, 1)
self.cv2 = Conv(c1, c_, 1, 1)
self.cv3 = Conv(2 * c_, c2, 1) # optional act=FReLU(c2)
self.m = nn.Sequential(*(Bottleneck(c_, c_, shortcut, g, e=1.0) for _ in range(n)))
def forward(self, x):
"""Performs forward propagation using concatenated outputs from two convolutions and a Bottleneck sequence."""
return self.cv3(torch.cat((self.m(self.cv1(x)), self.cv2(x)), 1))
class C3x(C3):
"""Extends the C3 module with cross-convolutions for enhanced feature extraction in neural networks."""
def __init__(self, c1, c2, n=1, shortcut=True, g=1, e=0.5):
"""Initializes C3x module with cross-convolutions, extending C3 with customizable channel dimensions, groups,
and expansion.
"""
super().__init__(c1, c2, n, shortcut, g, e)
c_ = int(c2 * e)
self.m = nn.Sequential(*(CrossConv(c_, c_, 3, 1, g, 1.0, shortcut) for _ in range(n)))
class C3TR(C3):
"""C3 module with TransformerBlock for enhanced feature extraction in object detection models."""
def __init__(self, c1, c2, n=1, shortcut=True, g=1, e=0.5):
"""Initializes C3 module with TransformerBlock for enhanced feature extraction, accepts channel sizes, shortcut
config, group, and expansion.
"""
super().__init__(c1, c2, n, shortcut, g, e)
c_ = int(c2 * e)
self.m = TransformerBlock(c_, c_, 4, n)
class C3SPP(C3):
"""Extends the C3 module with an SPP layer for enhanced spatial feature extraction and customizable channels."""
def __init__(self, c1, c2, k=(5, 9, 13), n=1, shortcut=True, g=1, e=0.5):
"""Initializes a C3 module with SPP layer for advanced spatial feature extraction, given channel sizes, kernel
sizes, shortcut, group, and expansion ratio.
"""
super().__init__(c1, c2, n, shortcut, g, e)
c_ = int(c2 * e)
self.m = SPP(c_, c_, k)
class C3Ghost(C3):
"""Implements a C3 module with Ghost Bottlenecks for efficient feature extraction in YOLOv5."""
def __init__(self, c1, c2, n=1, shortcut=True, g=1, e=0.5):
"""Initializes YOLOv5's C3 module with Ghost Bottlenecks for efficient feature extraction."""
super().__init__(c1, c2, n, shortcut, g, e)
c_ = int(c2 * e) # hidden channels
self.m = nn.Sequential(*(GhostBottleneck(c_, c_) for _ in range(n)))
class SPP(nn.Module):
"""Implements Spatial Pyramid Pooling (SPP) for feature extraction, ref: https://arxiv.org/abs/1406.4729."""
def __init__(self, c1, c2, k=(5, 9, 13)):
"""Initializes SPP layer with Spatial Pyramid Pooling, ref: https://arxiv.org/abs/1406.4729, args: c1 (input channels), c2 (output channels), k (kernel sizes)."""
super().__init__()
c_ = c1 // 2 # hidden channels
self.cv1 = Conv(c1, c_, 1, 1)
self.cv2 = Conv(c_ * (len(k) + 1), c2, 1, 1)
self.m = nn.ModuleList([nn.MaxPool2d(kernel_size=x, stride=1, padding=x // 2) for x in k])
def forward(self, x):
"""Applies convolution and max pooling layers to the input tensor `x`, concatenates results, and returns output
tensor.
"""
x = self.cv1(x)
with warnings.catch_warnings():
warnings.simplefilter("ignore") # suppress torch 1.9.0 max_pool2d() warning
return self.cv2(torch.cat([x] + [m(x) for m in self.m], 1))
class SPPF(nn.Module):
"""Implements a fast Spatial Pyramid Pooling (SPPF) layer for efficient feature extraction in YOLOv5 models."""
def __init__(self, c1, c2, k=5):
"""
Initializes YOLOv5 SPPF layer with given channels and kernel size for YOLOv5 model, combining convolution and
max pooling.
Equivalent to SPP(k=(5, 9, 13)).
"""
super().__init__()
c_ = c1 // 2 # hidden channels
self.cv1 = Conv(c1, c_, 1, 1)
self.cv2 = Conv(c_ * 4, c2, 1, 1)
self.m = nn.MaxPool2d(kernel_size=k, stride=1, padding=k // 2)
def forward(self, x):
"""Processes input through a series of convolutions and max pooling operations for feature extraction."""
x = self.cv1(x)
with warnings.catch_warnings():
warnings.simplefilter("ignore") # suppress torch 1.9.0 max_pool2d() warning
y1 = self.m(x)
y2 = self.m(y1)
return self.cv2(torch.cat((x, y1, y2, self.m(y2)), 1))
class Focus(nn.Module):
"""Focuses spatial information into channel space using slicing and convolution for efficient feature extraction."""
def __init__(self, c1, c2, k=1, s=1, p=None, g=1, act=True):
"""Initializes Focus module to concentrate width-height info into channel space with configurable convolution
parameters.
"""
super().__init__()
self.conv = Conv(c1 * 4, c2, k, s, p, g, act=act)
# self.contract = Contract(gain=2)
def forward(self, x):
"""Processes input through Focus mechanism, reshaping (b,c,w,h) to (b,4c,w/2,h/2) then applies convolution."""
return self.conv(torch.cat((x[..., ::2, ::2], x[..., 1::2, ::2], x[..., ::2, 1::2], x[..., 1::2, 1::2]), 1))
# return self.conv(self.contract(x))
class GhostConv(nn.Module):
"""Implements Ghost Convolution for efficient feature extraction, see https://github.com/huawei-noah/ghostnet."""
def __init__(self, c1, c2, k=1, s=1, g=1, act=True):
"""Initializes GhostConv with in/out channels, kernel size, stride, groups, and activation; halves out channels
for efficiency.
"""
super().__init__()
c_ = c2 // 2 # hidden channels
self.cv1 = Conv(c1, c_, k, s, None, g, act=act)
self.cv2 = Conv(c_, c_, 5, 1, None, c_, act=act)
def forward(self, x):
"""Performs forward pass, concatenating outputs of two convolutions on input `x`: shape (B,C,H,W)."""
y = self.cv1(x)
return torch.cat((y, self.cv2(y)), 1)
class GhostBottleneck(nn.Module):
"""Efficient bottleneck layer using Ghost Convolutions, see https://github.com/huawei-noah/ghostnet."""
def __init__(self, c1, c2, k=3, s=1):
"""Initializes GhostBottleneck with ch_in `c1`, ch_out `c2`, kernel size `k`, stride `s`; see https://github.com/huawei-noah/ghostnet."""
super().__init__()
c_ = c2 // 2
self.conv = nn.Sequential(
GhostConv(c1, c_, 1, 1), # pw
DWConv(c_, c_, k, s, act=False) if s == 2 else nn.Identity(), # dw
GhostConv(c_, c2, 1, 1, act=False),
) # pw-linear
self.shortcut = (
nn.Sequential(DWConv(c1, c1, k, s, act=False), Conv(c1, c2, 1, 1, act=False)) if s == 2 else nn.Identity()
)
def forward(self, x):
"""Processes input through conv and shortcut layers, returning their summed output."""
return self.conv(x) + self.shortcut(x)
class Contract(nn.Module):
"""Contracts spatial dimensions into channel dimensions for efficient processing in neural networks."""
def __init__(self, gain=2):
"""Initializes a layer to contract spatial dimensions (width-height) into channels, e.g., input shape
(1,64,80,80) to (1,256,40,40).
"""
super().__init__()
self.gain = gain
def forward(self, x):
"""Processes input tensor to expand channel dimensions by contracting spatial dimensions, yielding output shape
`(b, c*s*s, h//s, w//s)`.
"""
b, c, h, w = x.size() # assert (h / s == 0) and (W / s == 0), 'Indivisible gain'
s = self.gain
x = x.view(b, c, h // s, s, w // s, s) # x(1,64,40,2,40,2)
x = x.permute(0, 3, 5, 1, 2, 4).contiguous() # x(1,2,2,64,40,40)
return x.view(b, c * s * s, h // s, w // s) # x(1,256,40,40)
class Expand(nn.Module):
"""Expands spatial dimensions by redistributing channels, e.g., from (1,64,80,80) to (1,16,160,160)."""
def __init__(self, gain=2):
"""
Initializes the Expand module to increase spatial dimensions by redistributing channels, with an optional gain
factor.
Example: x(1,64,80,80) to x(1,16,160,160).
"""
super().__init__()
self.gain = gain
def forward(self, x):
"""Processes input tensor x to expand spatial dimensions by redistributing channels, requiring C / gain^2 ==
0.
"""
b, c, h, w = x.size() # assert C / s ** 2 == 0, 'Indivisible gain'
s = self.gain
x = x.view(b, s, s, c // s**2, h, w) # x(1,2,2,16,80,80)
x = x.permute(0, 3, 4, 1, 5, 2).contiguous() # x(1,16,80,2,80,2)
return x.view(b, c // s**2, h * s, w * s) # x(1,16,160,160)
class Concat(nn.Module):
"""Concatenates tensors along a specified dimension for efficient tensor manipulation in neural networks."""
def __init__(self, dimension=1):
"""Initializes a Concat module to concatenate tensors along a specified dimension."""
super().__init__()
self.d = dimension
def forward(self, x):
"""Concatenates a list of tensors along a specified dimension; `x` is a list of tensors, `dimension` is an
int.
"""
return torch.cat(x, self.d)
class DetectMultiBackend(nn.Module):
"""YOLOv5 MultiBackend class for inference on various backends including PyTorch, ONNX, TensorRT, and more."""
def __init__(self, weights="yolov5s.pt", device=torch.device("cpu"), dnn=False, data=None, fp16=False, fuse=True):
"""Initializes DetectMultiBackend with support for various inference backends, including PyTorch and ONNX."""
# PyTorch: weights = *.pt
# TorchScript: *.torchscript
# ONNX Runtime: *.onnx
# ONNX OpenCV DNN: *.onnx --dnn
# OpenVINO: *_openvino_model
# CoreML: *.mlpackage
# TensorRT: *.engine
# TensorFlow SavedModel: *_saved_model
# TensorFlow GraphDef: *.pb
# TensorFlow Lite: *.tflite
# TensorFlow Edge TPU: *_edgetpu.tflite
# PaddlePaddle: *_paddle_model
from models.experimental import attempt_download, attempt_load # scoped to avoid circular import
super().__init__()
w = str(weights[0] if isinstance(weights, list) else weights)
pt, jit, onnx, xml, engine, coreml, saved_model, pb, tflite, edgetpu, tfjs, paddle, triton = self._model_type(w)
fp16 &= pt or jit or onnx or engine or triton # FP16
nhwc = coreml or saved_model or pb or tflite or edgetpu # BHWC formats (vs torch BCWH)
stride = 32 # default stride
cuda = torch.cuda.is_available() and device.type != "cpu" # use CUDA
if not (pt or triton):
w = attempt_download(w) # download if not local
if pt: # PyTorch
model = attempt_load(weights if isinstance(weights, list) else w, device=device, inplace=True, fuse=fuse)
stride = max(int(model.stride.max()), 32) # model stride
names = model.module.names if hasattr(model, "module") else model.names # get class names
model.half() if fp16 else model.float()
self.model = model # explicitly assign for to(), cpu(), cuda(), half()
elif jit: # TorchScript
LOGGER.info(f"Loading {w} for TorchScript inference...")
extra_files = {"config.txt": ""} # model metadata
model = torch.jit.load(w, _extra_files=extra_files, map_location=device)
model.half() if fp16 else model.float()
if extra_files["config.txt"]: # load metadata dict
d = json.loads(
extra_files["config.txt"],
object_hook=lambda d: {int(k) if k.isdigit() else k: v for k, v in d.items()},
)
stride, names = int(d["stride"]), d["names"]
elif dnn: # ONNX OpenCV DNN
LOGGER.info(f"Loading {w} for ONNX OpenCV DNN inference...")
check_requirements("opencv-python>=4.5.4")
net = cv2.dnn.readNetFromONNX(w)
elif onnx: # ONNX Runtime
LOGGER.info(f"Loading {w} for ONNX Runtime inference...")
check_requirements(("onnx", "onnxruntime-gpu" if cuda else "onnxruntime"))
import onnxruntime
providers = ["CUDAExecutionProvider", "CPUExecutionProvider"] if cuda else ["CPUExecutionProvider"]
session = onnxruntime.InferenceSession(w, providers=providers)
output_names = [x.name for x in session.get_outputs()]
meta = session.get_modelmeta().custom_metadata_map # metadata
if "stride" in meta:
stride, names = int(meta["stride"]), eval(meta["names"])
elif xml: # OpenVINO
LOGGER.info(f"Loading {w} for OpenVINO inference...")
check_requirements("openvino>=2023.0") # requires openvino-dev: https://pypi.org/project/openvino-dev/
from openvino.runtime import Core, Layout, get_batch
core = Core()
if not Path(w).is_file(): # if not *.xml
w = next(Path(w).glob("*.xml")) # get *.xml file from *_openvino_model dir
ov_model = core.read_model(model=w, weights=Path(w).with_suffix(".bin"))
if ov_model.get_parameters()[0].get_layout().empty:
ov_model.get_parameters()[0].set_layout(Layout("NCHW"))
batch_dim = get_batch(ov_model)
if batch_dim.is_static:
batch_size = batch_dim.get_length()
ov_compiled_model = core.compile_model(ov_model, device_name="AUTO") # AUTO selects best available device
stride, names = self._load_metadata(Path(w).with_suffix(".yaml")) # load metadata
elif engine: # TensorRT
LOGGER.info(f"Loading {w} for TensorRT inference...")
import tensorrt as trt # https://developer.nvidia.com/nvidia-tensorrt-download
check_version(trt.__version__, "7.0.0", hard=True) # require tensorrt>=7.0.0
if device.type == "cpu":
device = torch.device("cuda:0")
Binding = namedtuple("Binding", ("name", "dtype", "shape", "data", "ptr"))
logger = trt.Logger(trt.Logger.INFO)
with open(w, "rb") as f, trt.Runtime(logger) as runtime:
model = runtime.deserialize_cuda_engine(f.read())
context = model.create_execution_context()
bindings = OrderedDict()
output_names = []
fp16 = False # default updated below
dynamic = False
is_trt10 = not hasattr(model, "num_bindings")
num = range(model.num_io_tensors) if is_trt10 else range(model.num_bindings)
for i in num:
if is_trt10:
name = model.get_tensor_name(i)
dtype = trt.nptype(model.get_tensor_dtype(name))
is_input = model.get_tensor_mode(name) == trt.TensorIOMode.INPUT
if is_input:
if -1 in tuple(model.get_tensor_shape(name)): # dynamic
dynamic = True
context.set_input_shape(name, tuple(model.get_profile_shape(name, 0)[2]))
if dtype == np.float16:
fp16 = True
else: # output
output_names.append(name)
shape = tuple(context.get_tensor_shape(name))
else:
name = model.get_binding_name(i)
dtype = trt.nptype(model.get_binding_dtype(i))
if model.binding_is_input(i):
if -1 in tuple(model.get_binding_shape(i)): # dynamic
dynamic = True
context.set_binding_shape(i, tuple(model.get_profile_shape(0, i)[2]))
if dtype == np.float16:
fp16 = True
else: # output
output_names.append(name)
shape = tuple(context.get_binding_shape(i))
im = torch.from_numpy(np.empty(shape, dtype=dtype)).to(device)
bindings[name] = Binding(name, dtype, shape, im, int(im.data_ptr()))
binding_addrs = OrderedDict((n, d.ptr) for n, d in bindings.items())
batch_size = bindings["images"].shape[0] # if dynamic, this is instead max batch size
elif coreml: # CoreML
LOGGER.info(f"Loading {w} for CoreML inference...")
import coremltools as ct
model = ct.models.MLModel(w)
elif saved_model: # TF SavedModel
LOGGER.info(f"Loading {w} for TensorFlow SavedModel inference...")
import tensorflow as tf
keras = False # assume TF1 saved_model
model = tf.keras.models.load_model(w) if keras else tf.saved_model.load(w)
elif pb: # GraphDef https://www.tensorflow.org/guide/migrate#a_graphpb_or_graphpbtxt
LOGGER.info(f"Loading {w} for TensorFlow GraphDef inference...")
import tensorflow as tf
def wrap_frozen_graph(gd, inputs, outputs):
"""Wraps a TensorFlow GraphDef for inference, returning a pruned function."""
x = tf.compat.v1.wrap_function(lambda: tf.compat.v1.import_graph_def(gd, name=""), []) # wrapped
ge = x.graph.as_graph_element
return x.prune(tf.nest.map_structure(ge, inputs), tf.nest.map_structure(ge, outputs))
def gd_outputs(gd):
"""Generates a sorted list of graph outputs excluding NoOp nodes and inputs, formatted as '<name>:0'."""
name_list, input_list = [], []
for node in gd.node: # tensorflow.core.framework.node_def_pb2.NodeDef
name_list.append(node.name)
input_list.extend(node.input)
return sorted(f"{x}:0" for x in list(set(name_list) - set(input_list)) if not x.startswith("NoOp"))
gd = tf.Graph().as_graph_def() # TF GraphDef
with open(w, "rb") as f:
gd.ParseFromString(f.read())
frozen_func = wrap_frozen_graph(gd, inputs="x:0", outputs=gd_outputs(gd))
elif tflite or edgetpu: # https://www.tensorflow.org/lite/guide/python#install_tensorflow_lite_for_python
try: # https://coral.ai/docs/edgetpu/tflite-python/#update-existing-tf-lite-code-for-the-edge-tpu
from tflite_runtime.interpreter import Interpreter, load_delegate
except ImportError:
import tensorflow as tf
Interpreter, load_delegate = (
tf.lite.Interpreter,
tf.lite.experimental.load_delegate,
)
if edgetpu: # TF Edge TPU https://coral.ai/software/#edgetpu-runtime
LOGGER.info(f"Loading {w} for TensorFlow Lite Edge TPU inference...")
delegate = {"Linux": "libedgetpu.so.1", "Darwin": "libedgetpu.1.dylib", "Windows": "edgetpu.dll"}[
platform.system()
]
interpreter = Interpreter(model_path=w, experimental_delegates=[load_delegate(delegate)])
else: # TFLite
LOGGER.info(f"Loading {w} for TensorFlow Lite inference...")
interpreter = Interpreter(model_path=w) # load TFLite model
interpreter.allocate_tensors() # allocate
input_details = interpreter.get_input_details() # inputs
output_details = interpreter.get_output_details() # outputs
# load metadata
with contextlib.suppress(zipfile.BadZipFile):
with zipfile.ZipFile(w, "r") as model:
meta_file = model.namelist()[0]
meta = ast.literal_eval(model.read(meta_file).decode("utf-8"))
stride, names = int(meta["stride"]), meta["names"]
elif tfjs: # TF.js
raise NotImplementedError("ERROR: YOLOv5 TF.js inference is not supported")
elif paddle: # PaddlePaddle
LOGGER.info(f"Loading {w} for PaddlePaddle inference...")
check_requirements("paddlepaddle-gpu" if cuda else "paddlepaddle")
import paddle.inference as pdi
if not Path(w).is_file(): # if not *.pdmodel
w = next(Path(w).rglob("*.pdmodel")) # get *.pdmodel file from *_paddle_model dir
weights = Path(w).with_suffix(".pdiparams")
config = pdi.Config(str(w), str(weights))
if cuda:
config.enable_use_gpu(memory_pool_init_size_mb=2048, device_id=0)
predictor = pdi.create_predictor(config)
input_handle = predictor.get_input_handle(predictor.get_input_names()[0])
output_names = predictor.get_output_names()
elif triton: # NVIDIA Triton Inference Server
LOGGER.info(f"Using {w} as Triton Inference Server...")
check_requirements("tritonclient[all]")
from utils.triton import TritonRemoteModel
model = TritonRemoteModel(url=w)
nhwc = model.runtime.startswith("tensorflow")
else:
raise NotImplementedError(f"ERROR: {w} is not a supported format")
# class names
if "names" not in locals():
names = yaml_load(data)["names"] if data else {i: f"class{i}" for i in range(999)}
if names[0] == "n01440764" and len(names) == 1000: # ImageNet
names = yaml_load(ROOT / "data/ImageNet.yaml")["names"] # human-readable names
self.__dict__.update(locals()) # assign all variables to self
def forward(self, im, augment=False, visualize=False):
"""Performs YOLOv5 inference on input images with options for augmentation and visualization."""
b, ch, h, w = im.shape # batch, channel, height, width
if self.fp16 and im.dtype != torch.float16:
im = im.half() # to FP16
if self.nhwc:
im = im.permute(0, 2, 3, 1) # torch BCHW to numpy BHWC shape(1,320,192,3)
if self.pt: # PyTorch
y = self.model(im, augment=augment, visualize=visualize) if augment or visualize else self.model(im)
elif self.jit: # TorchScript
y = self.model(im)
elif self.dnn: # ONNX OpenCV DNN
im = im.cpu().numpy() # torch to numpy
self.net.setInput(im)
y = self.net.forward()
elif self.onnx: # ONNX Runtime
im = im.cpu().numpy() # torch to numpy
y = self.session.run(self.output_names, {self.session.get_inputs()[0].name: im})
elif self.xml: # OpenVINO
im = im.cpu().numpy() # FP32
y = list(self.ov_compiled_model(im).values())
elif self.engine: # TensorRT
if self.dynamic and im.shape != self.bindings["images"].shape:
i = self.model.get_binding_index("images")
self.context.set_binding_shape(i, im.shape) # reshape if dynamic
self.bindings["images"] = self.bindings["images"]._replace(shape=im.shape)
for name in self.output_names:
i = self.model.get_binding_index(name)
self.bindings[name].data.resize_(tuple(self.context.get_binding_shape(i)))
s = self.bindings["images"].shape
assert im.shape == s, f"input size {im.shape} {'>' if self.dynamic else 'not equal to'} max model size {s}"
self.binding_addrs["images"] = int(im.data_ptr())
self.context.execute_v2(list(self.binding_addrs.values()))
y = [self.bindings[x].data for x in sorted(self.output_names)]
elif self.coreml: # CoreML
im = im.cpu().numpy()
im = Image.fromarray((im[0] * 255).astype("uint8"))
# im = im.resize((192, 320), Image.BILINEAR)
y = self.model.predict({"image": im}) # coordinates are xywh normalized
if "confidence" in y:
box = xywh2xyxy(y["coordinates"] * [[w, h, w, h]]) # xyxy pixels
conf, cls = y["confidence"].max(1), y["confidence"].argmax(1).astype(np.float)
y = np.concatenate((box, conf.reshape(-1, 1), cls.reshape(-1, 1)), 1)
else:
y = list(reversed(y.values())) # reversed for segmentation models (pred, proto)
elif self.paddle: # PaddlePaddle
im = im.cpu().numpy().astype(np.float32)
self.input_handle.copy_from_cpu(im)
self.predictor.run()
y = [self.predictor.get_output_handle(x).copy_to_cpu() for x in self.output_names]
elif self.triton: # NVIDIA Triton Inference Server
y = self.model(im)
else: # TensorFlow (SavedModel, GraphDef, Lite, Edge TPU)
im = im.cpu().numpy()
if self.saved_model: # SavedModel
y = self.model(im, training=False) if self.keras else self.model(im)
elif self.pb: # GraphDef
y = self.frozen_func(x=self.tf.constant(im))
else: # Lite or Edge TPU
input = self.input_details[0]
int8 = input["dtype"] == np.uint8 # is TFLite quantized uint8 model
if int8:
scale, zero_point = input["quantization"]
im = (im / scale + zero_point).astype(np.uint8) # de-scale
self.interpreter.set_tensor(input["index"], im)
self.interpreter.invoke()
y = []
for output in self.output_details:
x = self.interpreter.get_tensor(output["index"])
if int8:
scale, zero_point = output["quantization"]
x = (x.astype(np.float32) - zero_point) * scale # re-scale
y.append(x)
y = [x if isinstance(x, np.ndarray) else x.numpy() for x in y]
y[0][..., :4] *= [w, h, w, h] # xywh normalized to pixels
if isinstance(y, (list, tuple)):
return self.from_numpy(y[0]) if len(y) == 1 else [self.from_numpy(x) for x in y]
else:
return self.from_numpy(y)
def from_numpy(self, x):
"""Converts a NumPy array to a torch tensor, maintaining device compatibility."""
return torch.from_numpy(x).to(self.device) if isinstance(x, np.ndarray) else x
def warmup(self, imgsz=(1, 3, 640, 640)):
"""Performs a single inference warmup to initialize model weights, accepting an `imgsz` tuple for image size."""
warmup_types = self.pt, self.jit, self.onnx, self.engine, self.saved_model, self.pb, self.triton
if any(warmup_types) and (self.device.type != "cpu" or self.triton):
im = torch.empty(*imgsz, dtype=torch.half if self.fp16 else torch.float, device=self.device) # input
for _ in range(2 if self.jit else 1): #
self.forward(im) # warmup
@staticmethod
def _model_type(p="path/to/model.pt"):
"""
Determines model type from file path or URL, supporting various export formats.
Example: path='path/to/model.onnx' -> type=onnx
"""
# types = [pt, jit, onnx, xml, engine, coreml, saved_model, pb, tflite, edgetpu, tfjs, paddle]
from export import export_formats
from utils.downloads import is_url
sf = list(export_formats().Suffix) # export suffixes
if not is_url(p, check=False):
check_suffix(p, sf) # checks
url = urlparse(p) # if url may be Triton inference server
types = [s in Path(p).name for s in sf]
types[8] &= not types[9] # tflite &= not edgetpu
triton = not any(types) and all([any(s in url.scheme for s in ["http", "grpc"]), url.netloc])
return types + [triton]
@staticmethod
def _load_metadata(f=Path("path/to/meta.yaml")):
"""Loads metadata from a YAML file, returning strides and names if the file exists, otherwise `None`."""
if f.exists():
d = yaml_load(f)
return d["stride"], d["names"] # assign stride, names
return None, None
class AutoShape(nn.Module):
"""AutoShape class for robust YOLOv5 inference with preprocessing, NMS, and support for various input formats."""
conf = 0.25 # NMS confidence threshold
iou = 0.45 # NMS IoU threshold
agnostic = False # NMS class-agnostic
multi_label = False # NMS multiple labels per box
classes = None # (optional list) filter by class, i.e. = [0, 15, 16] for COCO persons, cats and dogs
max_det = 1000 # maximum number of detections per image
amp = False # Automatic Mixed Precision (AMP) inference
def __init__(self, model, verbose=True):
"""Initializes YOLOv5 model for inference, setting up attributes and preparing model for evaluation."""
super().__init__()
if verbose:
LOGGER.info("Adding AutoShape... ")
copy_attr(self, model, include=("yaml", "nc", "hyp", "names", "stride", "abc"), exclude=()) # copy attributes
self.dmb = isinstance(model, DetectMultiBackend) # DetectMultiBackend() instance
self.pt = not self.dmb or model.pt # PyTorch model
self.model = model.eval()
if self.pt:
m = self.model.model.model[-1] if self.dmb else self.model.model[-1] # Detect()
m.inplace = False # Detect.inplace=False for safe multithread inference
m.export = True # do not output loss values
def _apply(self, fn):
"""
Applies to(), cpu(), cuda(), half() etc.
to model tensors excluding parameters or registered buffers.
"""
self = super()._apply(fn)
if self.pt:
m = self.model.model.model[-1] if self.dmb else self.model.model[-1] # Detect()
m.stride = fn(m.stride)
m.grid = list(map(fn, m.grid))
if isinstance(m.anchor_grid, list):
m.anchor_grid = list(map(fn, m.anchor_grid))
return self
@smart_inference_mode()
def forward(self, ims, size=640, augment=False, profile=False):
"""
Performs inference on inputs with optional augment & profiling.
Supports various formats including file, URI, OpenCV, PIL, numpy, torch.
"""
# For size(height=640, width=1280), RGB images example inputs are:
# file: ims = 'data/images/zidane.jpg' # str or PosixPath
# URI: = 'https://ultralytics.com/images/zidane.jpg'
# OpenCV: = cv2.imread('image.jpg')[:,:,::-1] # HWC BGR to RGB x(640,1280,3)
# PIL: = Image.open('image.jpg') or ImageGrab.grab() # HWC x(640,1280,3)
# numpy: = np.zeros((640,1280,3)) # HWC
# torch: = torch.zeros(16,3,320,640) # BCHW (scaled to size=640, 0-1 values)
# multiple: = [Image.open('image1.jpg'), Image.open('image2.jpg'), ...] # list of images
dt = (Profile(), Profile(), Profile())
with dt[0]:
if isinstance(size, int): # expand
size = (size, size)
p = next(self.model.parameters()) if self.pt else torch.empty(1, device=self.model.device) # param
autocast = self.amp and (p.device.type != "cpu") # Automatic Mixed Precision (AMP) inference
if isinstance(ims, torch.Tensor): # torch
with amp.autocast(autocast):
return self.model(ims.to(p.device).type_as(p), augment=augment) # inference
# Pre-process
n, ims = (len(ims), list(ims)) if isinstance(ims, (list, tuple)) else (1, [ims]) # number, list of images
shape0, shape1, files = [], [], [] # image and inference shapes, filenames
for i, im in enumerate(ims):
f = f"image{i}" # filename
if isinstance(im, (str, Path)): # filename or uri
im, f = Image.open(requests.get(im, stream=True).raw if str(im).startswith("http") else im), im
im = np.asarray(exif_transpose(im))
elif isinstance(im, Image.Image): # PIL Image
im, f = np.asarray(exif_transpose(im)), getattr(im, "filename", f) or f
files.append(Path(f).with_suffix(".jpg").name)
if im.shape[0] < 5: # image in CHW
im = im.transpose((1, 2, 0)) # reverse dataloader .transpose(2, 0, 1)
im = im[..., :3] if im.ndim == 3 else cv2.cvtColor(im, cv2.COLOR_GRAY2BGR) # enforce 3ch input
s = im.shape[:2] # HWC
shape0.append(s) # image shape
g = max(size) / max(s) # gain
shape1.append([int(y * g) for y in s])
ims[i] = im if im.data.contiguous else np.ascontiguousarray(im) # update
shape1 = [make_divisible(x, self.stride) for x in np.array(shape1).max(0)] # inf shape
x = [letterbox(im, shape1, auto=False)[0] for im in ims] # pad
x = np.ascontiguousarray(np.array(x).transpose((0, 3, 1, 2))) # stack and BHWC to BCHW
x = torch.from_numpy(x).to(p.device).type_as(p) / 255 # uint8 to fp16/32
with amp.autocast(autocast):
# Inference
with dt[1]:
y = self.model(x, augment=augment) # forward
# Post-process
with dt[2]:
y = non_max_suppression(
y if self.dmb else y[0],
self.conf,
self.iou,
self.classes,
self.agnostic,
self.multi_label,
max_det=self.max_det,
) # NMS
for i in range(n):
scale_boxes(shape1, y[i][:, :4], shape0[i])
return Detections(ims, y, files, dt, self.names, x.shape)
class Detections:
"""Manages YOLOv5 detection results with methods for visualization, saving, cropping, and exporting detections."""
def __init__(self, ims, pred, files, times=(0, 0, 0), names=None, shape=None):
"""Initializes the YOLOv5 Detections class with image info, predictions, filenames, timing and normalization."""
super().__init__()
d = pred[0].device # device
gn = [torch.tensor([*(im.shape[i] for i in [1, 0, 1, 0]), 1, 1], device=d) for im in ims] # normalizations
self.ims = ims # list of images as numpy arrays
self.pred = pred # list of tensors pred[0] = (xyxy, conf, cls)
self.names = names # class names
self.files = files # image filenames
self.times = times # profiling times
self.xyxy = pred # xyxy pixels
self.xywh = [xyxy2xywh(x) for x in pred] # xywh pixels
self.xyxyn = [x / g for x, g in zip(self.xyxy, gn)] # xyxy normalized
self.xywhn = [x / g for x, g in zip(self.xywh, gn)] # xywh normalized
self.n = len(self.pred) # number of images (batch size)
self.t = tuple(x.t / self.n * 1e3 for x in times) # timestamps (ms)
self.s = tuple(shape) # inference BCHW shape
def _run(self, pprint=False, show=False, save=False, crop=False, render=False, labels=True, save_dir=Path("")):
"""Executes model predictions, displaying and/or saving outputs with optional crops and labels."""
s, crops = "", []
for i, (im, pred) in enumerate(zip(self.ims, self.pred)):
s += f"\nimage {i + 1}/{len(self.pred)}: {im.shape[0]}x{im.shape[1]} " # string
if pred.shape[0]:
for c in pred[:, -1].unique():
n = (pred[:, -1] == c).sum() # detections per class
s += f"{n} {self.names[int(c)]}{'s' * (n > 1)}, " # add to string
s = s.rstrip(", ")
if show or save or render or crop:
annotator = Annotator(im, example=str(self.names))
for *box, conf, cls in reversed(pred): # xyxy, confidence, class
label = f"{self.names[int(cls)]} {conf:.2f}"
if crop:
file = save_dir / "crops" / self.names[int(cls)] / self.files[i] if save else None
crops.append(
{
"box": box,
"conf": conf,
"cls": cls,
"label": label,
"im": save_one_box(box, im, file=file, save=save),
}
)
else: # all others
annotator.box_label(box, label if labels else "", color=colors(cls))
im = annotator.im
else:
s += "(no detections)"
im = Image.fromarray(im.astype(np.uint8)) if isinstance(im, np.ndarray) else im # from np
if show:
if is_jupyter():
from IPython.display import display
display(im)
else:
im.show(self.files[i])
if save:
f = self.files[i]
im.save(save_dir / f) # save
if i == self.n - 1:
LOGGER.info(f"Saved {self.n} image{'s' * (self.n > 1)} to {colorstr('bold', save_dir)}")
if render:
self.ims[i] = np.asarray(im)
if pprint:
s = s.lstrip("\n")
return f"{s}\nSpeed: %.1fms pre-process, %.1fms inference, %.1fms NMS per image at shape {self.s}" % self.t
if crop:
if save:
LOGGER.info(f"Saved results to {save_dir}\n")
return crops
@TryExcept("Showing images is not supported in this environment")
def show(self, labels=True):
"""
Displays detection results with optional labels.
Usage: show(labels=True)
"""
self._run(show=True, labels=labels) # show results
def save(self, labels=True, save_dir="runs/detect/exp", exist_ok=False):
"""
Saves detection results with optional labels to a specified directory.
Usage: save(labels=True, save_dir='runs/detect/exp', exist_ok=False)
"""
save_dir = increment_path(save_dir, exist_ok, mkdir=True) # increment save_dir
self._run(save=True, labels=labels, save_dir=save_dir) # save results
def crop(self, save=True, save_dir="runs/detect/exp", exist_ok=False):
"""
Crops detection results, optionally saves them to a directory.
Args: save (bool), save_dir (str), exist_ok (bool).
"""
save_dir = increment_path(save_dir, exist_ok, mkdir=True) if save else None
return self._run(crop=True, save=save, save_dir=save_dir) # crop results
def render(self, labels=True):
"""Renders detection results with optional labels on images; args: labels (bool) indicating label inclusion."""
self._run(render=True, labels=labels) # render results
return self.ims
def pandas(self):
"""
Returns detections as pandas DataFrames for various box formats (xyxy, xyxyn, xywh, xywhn).
Example: print(results.pandas().xyxy[0]).
"""
new = copy(self) # return copy
ca = "xmin", "ymin", "xmax", "ymax", "confidence", "class", "name" # xyxy columns
cb = "xcenter", "ycenter", "width", "height", "confidence", "class", "name" # xywh columns
for k, c in zip(["xyxy", "xyxyn", "xywh", "xywhn"], [ca, ca, cb, cb]):
a = [[x[:5] + [int(x[5]), self.names[int(x[5])]] for x in x.tolist()] for x in getattr(self, k)] # update
setattr(new, k, [pd.DataFrame(x, columns=c) for x in a])
return new
def tolist(self):
"""
Converts a Detections object into a list of individual detection results for iteration.
Example: for result in results.tolist():
"""
r = range(self.n) # iterable
return [
Detections(
[self.ims[i]],
[self.pred[i]],
[self.files[i]],
self.times,
self.names,
self.s,
)
for i in r
]
def print(self):
"""Logs the string representation of the current object's state via the LOGGER."""
LOGGER.info(self.__str__())
def __len__(self):
"""Returns the number of results stored, overrides the default len(results)."""
return self.n
def __str__(self):
"""Returns a string representation of the model's results, suitable for printing, overrides default
print(results).
"""
return self._run(pprint=True) # print results
def __repr__(self):
"""Returns a string representation of the YOLOv5 object, including its class and formatted results."""
return f"YOLOv5 {self.__class__} instance\n" + self.__str__()
class Proto(nn.Module):
"""YOLOv5 mask Proto module for segmentation models, performing convolutions and upsampling on input tensors."""
def __init__(self, c1, c_=256, c2=32):
"""Initializes YOLOv5 Proto module for segmentation with input, proto, and mask channels configuration."""
super().__init__()
self.cv1 = Conv(c1, c_, k=3)
self.upsample = nn.Upsample(scale_factor=2, mode="nearest")
self.cv2 = Conv(c_, c_, k=3)
self.cv3 = Conv(c_, c2)
def forward(self, x):
"""Performs a forward pass using convolutional layers and upsampling on input tensor `x`."""
return self.cv3(self.cv2(self.upsample(self.cv1(x))))
class Classify(nn.Module):
"""YOLOv5 classification head with convolution, pooling, and dropout layers for channel transformation."""
def __init__(
self, c1, c2, k=1, s=1, p=None, g=1, dropout_p=0.0
): # ch_in, ch_out, kernel, stride, padding, groups, dropout probability
"""Initializes YOLOv5 classification head with convolution, pooling, and dropout layers for input to output
channel transformation.
"""
super().__init__()
c_ = 1280 # efficientnet_b0 size
self.conv = Conv(c1, c_, k, s, autopad(k, p), g)
self.pool = nn.AdaptiveAvgPool2d(1) # to x(b,c_,1,1)
self.drop = nn.Dropout(p=dropout_p, inplace=True)
self.linear = nn.Linear(c_, c2) # to x(b,c2)
def forward(self, x):
"""Processes input through conv, pool, drop, and linear layers; supports list concatenation input."""
if isinstance(x, list):
x = torch.cat(x, 1)
return self.linear(self.drop(self.pool(self.conv(x)).flatten(1)))