Add YOLOv7 support

utils/gen_wts_yoloV7.py

@@ -0,0 +1,353 @@
+import argparse
+import os
+import struct
+import torch
+from utils.torch_utils import select_device
+
+
+class Layers(object):
+    def __init__(self, n, size, fw, fc):
+        self.blocks = [0 for _ in range(n)]
+        self.current = 0
+
+        self.width = size[0] if len(size) == 1 else size[1]
+        self.height = size[0]
+
+        self.num = 0
+        self.nc = 0
+        self.anchors = ''
+        self.masks = []
+
+        self.fw = fw
+        self.fc = fc
+        self.wc = 0
+
+        self.net()
+
+    def ReOrg(self, child):
+        self.current = child.i
+        self.fc.write('\n# ReOrg\n')
+
+        self.reorg()
+
+    def Conv(self, child):
+        self.current = child.i
+        self.fc.write('\n# Conv\n')
+
+        if child.f != -1:
+            r = self.get_route(child.f)
+            self.route('%d' % r)
+        self.convolutional(child)
+
+    def DownC(self, child):
+        self.current = child.i
+        self.fc.write('\n# DownC\n')
+
+        self.maxpool(child.mp)
+        self.convolutional(child.cv3)
+        self.route('-3')
+        self.convolutional(child.cv1)
+        self.convolutional(child.cv2)
+        self.route('-1, -4')
+
+    def MP(self, child):
+        self.current = child.i
+        self.fc.write('\n# MP\n')
+
+        self.maxpool(child.m)
+
+    def SP(self, child):
+        self.current = child.i
+        self.fc.write('\n# SP\n')
+
+        if child.f != -1:
+            r = self.get_route(child.f)
+            self.route('%d' % r)
+        self.maxpool(child.m)
+
+    def SPPCSPC(self, child):
+        self.current = child.i
+        self.fc.write('\n# SPPCSPC\n')
+
+        self.convolutional(child.cv2)
+        self.route('-2')
+        self.convolutional(child.cv1)
+        self.convolutional(child.cv3)
+        self.convolutional(child.cv4)
+        self.maxpool(child.m[0])
+        self.route('-2')
+        self.maxpool(child.m[1])
+        self.route('-4')
+        self.maxpool(child.m[2])
+        self.route('-6, -5, -3, -1')
+        self.convolutional(child.cv5)
+        self.convolutional(child.cv6)
+        self.route('-1, -13')
+        self.convolutional(child.cv7)
+
+    def RepConv(self, child):
+        self.current = child.i
+        self.fc.write('\n# RepConv\n')
+
+        if child.f != -1:
+            r = self.get_route(child.f)
+            self.route('%d' % r)
+        self.convolutional(child.rbr_1x1)
+        self.route('-2')
+        self.convolutional(child.rbr_dense)
+        self.shortcut(-3, act=self.get_activation(child.act._get_name()))
+
+    def Upsample(self, child):
+        self.current = child.i
+        self.fc.write('\n# Upsample\n')
+
+        self.upsample(child)
+
+    def Concat(self, child):
+        self.current = child.i
+        self.fc.write('\n# Concat\n')
+
+        r = []
+        for i in range(1, len(child.f)):
+            r.append(self.get_route(child.f[i]))
+        self.route('-1, %s' % str(r)[1:-1])
+
+    def Shortcut(self, child):
+        self.current = child.i
+        self.fc.write('\n# Shortcut\n')
+
+        r = self.get_route(child.f[1])
+        self.shortcut(r)
+
+    def Detect(self, child):
+        self.current = child.i
+        self.fc.write('\n# Detect\n')
+
+        self.get_anchors(child.state_dict(), child.m[0].out_channels)
+
+        for i, m in enumerate(child.m):
+            r = self.get_route(child.f[i])
+            self.route('%d' % r)
+            self.convolutional(m, detect=True)
+            self.yolo(i)
+
+    def net(self):
+        self.fc.write('[net]\n' +
+                      'width=%d\n' % self.width +
+                      'height=%d\n' % self.height +
+                      'channels=3\n')
+
+    def reorg(self):
+        self.blocks[self.current] += 1
+
+        self.fc.write('\n[reorg]\n')
+
+    def convolutional(self, cv, act=None, detect=False):
+        self.blocks[self.current] += 1
+
+        self.get_state_dict(cv.state_dict())
+
+        if cv._get_name() == 'Conv2d':
+            filters = cv.out_channels
+            size = cv.kernel_size
+            stride = cv.stride
+            pad = cv.padding
+            groups = cv.groups
+            bias = cv.bias
+            bn = False
+            act = 'linear' if not detect else 'logistic'
+        elif cv._get_name() == 'Sequential':
+            filters = cv[0].out_channels
+            size = cv[0].kernel_size
+            stride = cv[0].stride
+            pad = cv[0].padding
+            groups = cv[0].groups
+            bias = cv[0].bias
+            bn = True if cv[1]._get_name() == 'BatchNorm2d' else False
+            act = 'linear'
+        else:
+            filters = cv.conv.out_channels
+            size = cv.conv.kernel_size
+            stride = cv.conv.stride
+            pad = cv.conv.padding
+            groups = cv.conv.groups
+            bias = cv.conv.bias
+            bn = True if hasattr(cv, 'bn') else False
+            if act is None:
+                act = self.get_activation(cv.act._get_name()) if hasattr(cv, 'act') else 'linear'
+
+        b = 'batch_normalize=1\n' if bn is True else ''
+        g = 'groups=%d\n' % groups if groups > 1 else ''
+        w = 'bias=0\n' if bias is None and bn is False else ''
+
+        self.fc.write('\n[convolutional]\n' +
+                      b +
+                      'filters=%d\n' % filters +
+                      'size=%s\n' % self.get_value(size) +
+                      'stride=%s\n' % self.get_value(stride) +
+                      'pad=%s\n' % self.get_value(pad) +
+                      g +
+                      w +
+                      'activation=%s\n' % act)
+
+    def route(self, layers):
+        self.blocks[self.current] += 1
+
+        self.fc.write('\n[route]\n' +
+                      'layers=%s\n' % layers)
+
+    def shortcut(self, r, act='linear'):
+        self.blocks[self.current] += 1
+
+        self.fc.write('\n[shortcut]\n' +
+                      'from=%d\n' % r +
+                      'activation=%s\n' % act)
+
+    def maxpool(self, m):
+        self.blocks[self.current] += 1
+
+        stride = m.stride
+        size = m.kernel_size
+        mode = m.ceil_mode
+
+        m = 'maxpool_up' if mode else 'maxpool'
+
+        self.fc.write('\n[%s]\n' % m +
+                      'stride=%d\n' % stride +
+                      'size=%d\n' % size)
+
+    def upsample(self, child):
+        self.blocks[self.current] += 1
+
+        stride = child.scale_factor
+
+        self.fc.write('\n[upsample]\n' +
+                      'stride=%d\n' % stride)
+
+    def yolo(self, i):
+        self.blocks[self.current] += 1
+
+        self.fc.write('\n[yolo]\n' +
+                      'mask=%s\n' % self.masks[i] +
+                      'anchors=%s\n' % self.anchors +
+                      'classes=%d\n' % self.nc +
+                      'num=%d\n' % self.num +
+                      'scale_x_y=2.0\n' +
+                      'new_coords=1\n')
+
+    def get_state_dict(self, state_dict):
+        for k, v in state_dict.items():
+            if 'num_batches_tracked' not in k:
+                vr = v.reshape(-1).numpy()
+                self.fw.write('{} {} '.format(k, len(vr)))
+                for vv in vr:
+                    self.fw.write(' ')
+                    self.fw.write(struct.pack('>f', float(vv)).hex())
+                self.fw.write('\n')
+                self.wc += 1
+
+    def get_anchors(self, state_dict, out_channels):
+        anchor_grid = state_dict['anchor_grid']
+        aa = anchor_grid.reshape(-1).tolist()
+        am = anchor_grid.tolist()
+
+        self.num = (len(aa) / 2)
+        self.nc = int((out_channels / (self.num / len(am))) - 5)
+        self.anchors = str(aa)[1:-1]
+
+        n = 0
+        for m in am:
+            mask = []
+            for _ in range(len(m)):
+                mask.append(n)
+                n += 1
+            self.masks.append(str(mask)[1:-1])
+
+    def get_value(self, key):
+        if type(key) == int:
+            return key
+        return key[0] if key[0] == key[1] else str(key)[1:-1]
+
+    def get_route(self, n):
+        r = 0
+        if n < 0:
+            for i, b in enumerate(self.blocks[self.current-1::-1]):
+                if i < abs(n) - 1:
+                    r -= b
+                else:
+                    break
+        else:
+            for i, b in enumerate(self.blocks):
+                if i <= n:
+                    r += b
+                else:
+                    break
+        return r - 1
+
+    def get_activation(self, act):
+        if act == 'Hardswish':
+            return 'hardswish'
+        elif act == 'LeakyReLU':
+            return 'leaky'
+        elif act == 'SiLU':
+            return 'silu'
+        return 'linear'
+
+
+def parse_args():
+    parser = argparse.ArgumentParser(description='PyTorch YOLOv7 conversion')
+    parser.add_argument('-w', '--weights', required=True, help='Input weights (.pt) file path (required)')
+    parser.add_argument(
+        '-s', '--size', nargs='+', type=int, default=[640], help='Inference size [H,W] (default [640])')
+    args = parser.parse_args()
+    if not os.path.isfile(args.weights):
+        raise SystemExit('Invalid weights file')
+    return args.weights, args.size
+
+
+pt_file, inference_size = parse_args()
+
+model_name = os.path.basename(pt_file).split('.pt')[0]
+wts_file = model_name + '.wts' if 'yolov7' in model_name else 'yolov7_' + model_name + '.wts'
+cfg_file = model_name + '.cfg' if 'yolov7' in model_name else 'yolov7_' + model_name + '.cfg'
+
+device = select_device('cpu')
+model = torch.load(pt_file, map_location=device)
+model = model['ema' if model.get('ema') else 'model'].float()
+
+anchor_grid = model.model[-1].anchors * model.model[-1].stride[..., None, None]
+delattr(model.model[-1], 'anchor_grid')
+model.model[-1].register_buffer('anchor_grid', anchor_grid)
+
+model.to(device).eval()
+
+with open(wts_file, 'w') as fw, open(cfg_file, 'w') as fc:
+    layers = Layers(len(model.model), inference_size, fw, fc)
+
+    for child in model.model.children():
+        if child._get_name() == 'ReOrg':
+            layers.ReOrg(child)
+        elif child._get_name() == 'Conv':
+            layers.Conv(child)
+        elif child._get_name() == 'DownC':
+            layers.DownC(child)
+        elif child._get_name() == 'MP':
+            layers.MP(child)
+        elif child._get_name() == 'SP':
+            layers.SP(child)
+        elif child._get_name() == 'SPPCSPC':
+            layers.SPPCSPC(child)
+        elif child._get_name() == 'RepConv':
+            layers.RepConv(child)
+        elif child._get_name() == 'Upsample':
+            layers.Upsample(child)
+        elif child._get_name() == 'Concat':
+            layers.Concat(child)
+        elif child._get_name() == 'Shortcut':
+            layers.Shortcut(child)
+        elif child._get_name() == 'Detect':
+            layers.Detect(child)
+        else:
+            raise SystemExit('Model not supported')
+
+os.system('echo "%d" | cat - %s > temp && mv temp %s' % (layers.wc, wts_file, wts_file))