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graph.py
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graph.py
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import torch
import models
from layer import Layer, LayerGroup
import options as opt
def get_graph_vgg(vgg):
D = dict()
n = 0
V = []
E = [[]]
def record_hook(module, input, output):
key = id(module)
if key not in D:
D[key] = len(V)
V.append(Layer(module, input[0].shape, output.shape))
hooks = []
for module in vgg.modules():
if isinstance(module, Layer.supported_base):
hooks.append(module.register_forward_hook(record_hook))
input = torch.rand(1, 3, 32, 32, device=opt.device)
output = vgg(input)
for hook in hooks:
hook.remove()
n = len(V)
E = [([False] * n) for i in range(n)]
for i in range(n - 1):
E[i][i + 1] = True
return n, V, E
def get_graph_resnet(resnet):
D = dict()
n = 0
V = []
E = [[]]
def record_hook(module, input, output):
key = id(module)
if key not in D:
D[key] = len(V)
V.append(Layer(module, input[0].shape, output.shape))
def add_edge(src, dst):
i = D[id(src)]
j = D[id(dst)]
E[i][j] = True
def add_chain(ls):
for i in range(len(ls) - 1):
add_edge(ls[i], ls[i + 1])
hooks = []
for module in resnet.modules():
if isinstance(module, Layer.supported_base):
hooks.append(module.register_forward_hook(record_hook))
input = torch.rand(1, 3, 32, 32, device=opt.device)
output = resnet(input)
for hook in hooks:
hook.remove()
n = len(V)
E = [([False] * n) for i in range(n)]
chain = [resnet.conv1, resnet.bn1, resnet.relu1]
add_chain(chain)
src = [resnet.relu1]
for module in resnet.modules():
if isinstance(module, models.BasicBlockM):
chain = [module.conv1, module.bn1, module.relu1,
module.conv2, module.bn2, module.relu2]
add_chain(chain)
dst = [module.conv1]
src_ = [module.relu2]
if module.downsample is not None:
chain = list(module.downsample.children())
add_chain(chain)
dst.append(chain[0])
add_edge(chain[-1], module.relu2)
else:
dst.append(module.relu2)
for s in src:
for d in dst:
add_edge(s, d)
src = src_
dst = []
chain = [resnet.avgpool, resnet.flatten, resnet.fc]
for s in src:
add_edge(s, chain[0])
add_chain(chain)
return n, V, E
def get_graph_shufflenet(shufflenet):
D = dict()
n = 0
V = []
E = [[]]
def record_hook(module, input, output):
key = id(module)
if key not in D:
D[key] = len(V)
in_shape = input[0][0].shape if isinstance(input[0], list) else input[0].shape
out_shape = output.shape
V.append(Layer(module, in_shape, out_shape))
def add_edge(src, dst):
i = D[id(src)]
j = D[id(dst)]
E[i][j] = True
def add_chain(ls):
for i in range(len(ls) - 1):
add_edge(ls[i], ls[i + 1])
hooks = []
for module in shufflenet.modules():
if isinstance(module, Layer.supported_base):
hooks.append(module.register_forward_hook(record_hook))
input = torch.rand(1, 3, 32, 32, device=opt.device)
output = shufflenet(input)
for hook in hooks:
hook.remove()
n = len(V)
E = [([False] * n) for i in range(n)]
chain = [shufflenet.conv1, shufflenet.bn1, shufflenet.relu1]
add_chain(chain)
src = [shufflenet.relu1]
for module in shufflenet.modules():
if isinstance(module, models.BottleneckM):
chain = [module.conv1, module.bn1, module.relu1, module.shuffle,
module.conv2, module.bn2,
module.conv3, module.bn3]
add_chain(chain)
dst = [module.conv1]
src_ = [module.relu3]
if module.stride == 2:
dst.append(module.conv4)
add_edge(module.conv4, module.avgpool)
add_edge(module.avgpool, module.concat)
add_edge(module.bn3, module.concat)
add_edge(module.concat, module.relu3)
else:
add_edge(module.bn3, module.relu3)
dst.append(module.relu3)
for s in src:
for d in dst:
add_edge(s, d)
src = src_
dst = []
chain = [shufflenet.avgpool, shufflenet.flatten, shufflenet.fc]
for s in src:
add_edge(s, chain[0])
add_chain(chain)
return n, V, E
def get_groups(V):
if opt.co_graph_gen == 'get_graph_shufflenet':
groups = []
in_layers = list(range(1, 4))
out_layers = list(range(0, 3))
groups.append(LayerGroup(-1, in_layers, out_layers))
in_layers = list(range(4, 11)) + list(range(13, 43))
out_layers = list(range(3, 11)) + list(range(13, 42))
groups.append(LayerGroup(-1, in_layers, out_layers))
in_layers = list(range(43, 50)) + list(range(52, 118))
out_layers = list(range(42, 50)) + list(range(52, 117))
groups.append(LayerGroup(-1, in_layers, out_layers))
in_layers = list(range(118, 125)) + list(range(127, 159))
out_layers = list(range(117, 125)) + list(range(127, 158))
groups.append(LayerGroup(-1, in_layers, out_layers))
return groups
else:
n = len(V)
vis = [([False] * 2) for i in range(n)]
vis[0][0] = True
vis[-1][1] = True
groups = []
for i in range(n):
for j in range(2):
if not vis[i][j]:
F = V[i].out_shape[1] if j else V[i].in_shape[1]
in_layers = []
out_layers = []
for k in range(n):
if not vis[k][0] and V[k].in_shape[1] == F:
in_layers.append(k)
vis[k][0] = True
if not vis[k][1] and V[k].out_shape[1] == F:
out_layers.append(k)
vis[k][1] = True
groups.append(LayerGroup(F, in_layers, out_layers))
return groups
def get_links(E):
n = len(E)
in_links = [[] for i in range(n)]
out_links = [[] for i in range(n)]
for i in range(n):
for j in range(n):
if E[i][j]:
in_links[j].append(i)
out_links[i].append(j)
return in_links, out_links
def get_plot(name, n, V, E, reduced=False):
from graphviz import Digraph
dot = Digraph(name=name)
for i, v in enumerate(V):
node_name = '%d %s %s->%s' % (i, v.base_type,
str(list(v.in_shape)[1:]), str(list(v.out_shape)[1:]))
colors = ['gray', 'gray', 'gray', 'gray', 'red', 'yellow', 'yellow', 'green', 'cyan', 'blue']
if v.base_type != 'Identity' or not reduced:
color = colors[Layer.supported_base.index(type(v.base))]
dot.node(str(i), node_name, shape='box', color=color)
if reduced:
for i in range(n):
if V[i].base_type == 'Identity':
in_links = []
out_links = []
for j in range(n):
if E[j][i]:
in_links.append(j)
E[j][i] = False
if E[i][j]:
out_links.append(j)
E[i][j] = False
for u in in_links:
for v in out_links:
E[u][v] = True
for i in range(n):
for j in range(n):
if E[i][j]:
dot.edge(str(i), str(j))
dot.view()