update GDAS and SETN

lib/models/shape_searchs/SearchCifarResNet_depth.py

@@ -0,0 +1,337 @@
+import math, torch
+from collections import OrderedDict
+from bisect import bisect_right
+import torch.nn as nn
+from ..initialization import initialize_resnet
+from ..SharedUtils    import additive_func
+from .SoftSelect      import select2withP, ChannelWiseInter
+from .SoftSelect      import linear_forward
+from .SoftSelect      import get_width_choices
+
+
+def get_depth_choices(nDepth, return_num):
+  if nDepth == 2:
+    choices = (1, 2)
+  elif nDepth == 3:
+    choices = (1, 2, 3)
+  elif nDepth > 3:
+    choices = list(range(1, nDepth+1, 2))
+    if choices[-1] < nDepth: choices.append(nDepth)
+  else:
+    raise ValueError('invalid nDepth : {:}'.format(nDepth))
+  if return_num: return len(choices)
+  else         : return choices
+
+
+
+class ConvBNReLU(nn.Module):
+  num_conv  = 1
+  def __init__(self, nIn, nOut, kernel, stride, padding, bias, has_avg, has_bn, has_relu):
+    super(ConvBNReLU, self).__init__()
+    self.InShape  = None
+    self.OutShape = None
+    self.choices  = get_width_choices(nOut)
+    self.register_buffer('choices_tensor', torch.Tensor( self.choices ))
+
+    if has_avg : self.avg = nn.AvgPool2d(kernel_size=2, stride=2, padding=0)
+    else       : self.avg = None
+    self.conv = nn.Conv2d(nIn, nOut, kernel_size=kernel, stride=stride, padding=padding, dilation=1, groups=1, bias=bias)
+    if has_bn  : self.bn  = nn.BatchNorm2d(nOut)
+    else       : self.bn  = None
+    if has_relu: self.relu = nn.ReLU(inplace=False)
+    else       : self.relu = None
+    self.in_dim   = nIn
+    self.out_dim  = nOut
+
+  def get_flops(self, divide=1):
+    iC, oC = self.in_dim, self.out_dim
+    assert iC <= self.conv.in_channels and oC <= self.conv.out_channels, '{:} vs {:}  |  {:} vs {:}'.format(iC, self.conv.in_channels, oC, self.conv.out_channels)
+    assert isinstance(self.InShape, tuple) and len(self.InShape) == 2, 'invalid in-shape : {:}'.format(self.InShape)
+    assert isinstance(self.OutShape, tuple) and len(self.OutShape) == 2, 'invalid out-shape : {:}'.format(self.OutShape)
+    #conv_per_position_flops = self.conv.kernel_size[0] * self.conv.kernel_size[1] * iC * oC / self.conv.groups
+    conv_per_position_flops = (self.conv.kernel_size[0] * self.conv.kernel_size[1] * 1.0 / self.conv.groups)
+    all_positions = self.OutShape[0] * self.OutShape[1]
+    flops = (conv_per_position_flops * all_positions / divide) * iC * oC
+    if self.conv.bias is not None: flops += all_positions / divide
+    return flops
+
+  def forward(self, inputs):
+    if self.avg : out = self.avg( inputs )
+    else        : out = inputs
+    conv = self.conv( out )
+    if self.bn  : out = self.bn( conv )
+    else        : out = conv
+    if self.relu: out = self.relu( out )
+    else        : out = out
+    if self.InShape is None:
+      self.InShape  = (inputs.size(-2), inputs.size(-1))
+      self.OutShape = (out.size(-2)   , out.size(-1))
+    return out
+
+
+class ResNetBasicblock(nn.Module):
+  expansion = 1
+  num_conv  = 2
+  def __init__(self, inplanes, planes, stride):
+    super(ResNetBasicblock, self).__init__()
+    assert stride == 1 or stride == 2, 'invalid stride {:}'.format(stride)
+    self.conv_a = ConvBNReLU(inplanes, planes, 3, stride, 1, False, has_avg=False, has_bn=True, has_relu=True)
+    self.conv_b = ConvBNReLU(  planes, planes, 3,      1, 1, False, has_avg=False, has_bn=True, has_relu=False)
+    if stride == 2:
+      self.downsample = ConvBNReLU(inplanes, planes, 1, 1, 0, False, has_avg=True, has_bn=False, has_relu=False)
+    elif inplanes != planes:
+      self.downsample = ConvBNReLU(inplanes, planes, 1, 1, 0, False, has_avg=False,has_bn=True , has_relu=False)
+    else:
+      self.downsample = None
+    self.out_dim     = planes
+    self.search_mode = 'basic'
+
+  def get_flops(self, divide=1):
+    flop_A = self.conv_a.get_flops(divide)
+    flop_B = self.conv_b.get_flops(divide)
+    if hasattr(self.downsample, 'get_flops'):
+      flop_C = self.downsample.get_flops(divide)
+    else:
+      flop_C = 0
+    return flop_A + flop_B + flop_C
+
+  def forward(self, inputs):
+    basicblock = self.conv_a(inputs)
+    basicblock = self.conv_b(basicblock)
+    if self.downsample is not None: residual = self.downsample(inputs)
+    else                          : residual = inputs
+    out = additive_func(residual, basicblock)
+    return nn.functional.relu(out, inplace=True)
+
+
+
+class ResNetBottleneck(nn.Module):
+  expansion = 4
+  num_conv  = 3
+  def __init__(self, inplanes, planes, stride):
+    super(ResNetBottleneck, self).__init__()
+    assert stride == 1 or stride == 2, 'invalid stride {:}'.format(stride)
+    self.conv_1x1 = ConvBNReLU(inplanes, planes, 1,      1, 0, False, has_avg=False, has_bn=True, has_relu=True)
+    self.conv_3x3 = ConvBNReLU(  planes, planes, 3, stride, 1, False, has_avg=False, has_bn=True, has_relu=True)
+    self.conv_1x4 = ConvBNReLU(planes, planes*self.expansion, 1, 1, 0, False, has_avg=False, has_bn=True, has_relu=False)
+    if stride == 2:
+      self.downsample = ConvBNReLU(inplanes, planes*self.expansion, 1, 1, 0, False, has_avg=True, has_bn=False, has_relu=False)
+    elif inplanes != planes*self.expansion:
+      self.downsample = ConvBNReLU(inplanes, planes*self.expansion, 1, 1, 0, False, has_avg=False,has_bn=True , has_relu=False)
+    else:
+      self.downsample = None
+    self.out_dim     = planes * self.expansion
+    self.search_mode = 'basic'
+
+  def get_range(self):
+    return self.conv_1x1.get_range() + self.conv_3x3.get_range() + self.conv_1x4.get_range()
+
+  def get_flops(self, divide):
+    flop_A = self.conv_1x1.get_flops(divide)
+    flop_B = self.conv_3x3.get_flops(divide)
+    flop_C = self.conv_1x4.get_flops(divide)
+    if hasattr(self.downsample, 'get_flops'):
+      flop_D = self.downsample.get_flops(divide)
+    else:
+      flop_D = 0
+    return flop_A + flop_B + flop_C + flop_D
+
+  def forward(self, inputs):
+    bottleneck = self.conv_1x1(inputs)
+    bottleneck = self.conv_3x3(bottleneck)
+    bottleneck = self.conv_1x4(bottleneck)
+    if self.downsample is not None: residual = self.downsample(inputs)
+    else                          : residual = inputs
+    out = additive_func(residual, bottleneck)
+    return nn.functional.relu(out, inplace=True)
+
+
+class SearchDepthCifarResNet(nn.Module):
+
+  def __init__(self, block_name, depth, num_classes):
+    super(SearchDepthCifarResNet, self).__init__()
+
+    #Model type specifies number of layers for CIFAR-10 and CIFAR-100 model
+    if block_name == 'ResNetBasicblock':
+      block = ResNetBasicblock
+      assert (depth - 2) % 6 == 0, 'depth should be one of 20, 32, 44, 56, 110'
+      layer_blocks = (depth - 2) // 6
+    elif block_name == 'ResNetBottleneck':
+      block = ResNetBottleneck
+      assert (depth - 2) % 9 == 0, 'depth should be one of 164'
+      layer_blocks = (depth - 2) // 9
+    else:
+      raise ValueError('invalid block : {:}'.format(block_name))
+
+    self.message      = 'SearchShapeCifarResNet : Depth : {:} , Layers for each block : {:}'.format(depth, layer_blocks)
+    self.num_classes  = num_classes
+    self.channels     = [16]
+    self.layers       = nn.ModuleList( [ ConvBNReLU(3, 16, 3, 1, 1, False, has_avg=False, has_bn=True, has_relu=True) ] )
+    self.InShape      = None
+    self.depth_info   = OrderedDict()
+    self.depth_at_i   = OrderedDict()
+    for stage in range(3):
+      cur_block_choices = get_depth_choices(layer_blocks, False)
+      assert cur_block_choices[-1] == layer_blocks, 'stage={:}, {:} vs {:}'.format(stage, cur_block_choices, layer_blocks)
+      self.message += "\nstage={:} ::: depth-block-choices={:} for {:} blocks.".format(stage, cur_block_choices, layer_blocks)
+      block_choices, xstart = [], len(self.layers)
+      for iL in range(layer_blocks):
+        iC     = self.channels[-1]
+        planes = 16 * (2**stage)
+        stride = 2 if stage > 0 and iL == 0 else 1
+        module = block(iC, planes, stride)
+        self.channels.append( module.out_dim )
+        self.layers.append  ( module )
+        self.message += "\nstage={:}, ilayer={:02d}/{:02d}, block={:03d}, iC={:3d}, oC={:3d}, stride={:}".format(stage, iL, layer_blocks, len(self.layers)-1, iC, module.out_dim, stride)
+        # added for depth
+        layer_index = len(self.layers) - 1
+        if iL + 1 in cur_block_choices: block_choices.append( layer_index )
+        if iL + 1 == layer_blocks:
+          self.depth_info[layer_index] = {'choices': block_choices,
+                                          'stage'  : stage,
+                                          'xstart' : xstart}
+    self.depth_info_list = []
+    for xend, info in self.depth_info.items():
+      self.depth_info_list.append( (xend, info) )
+      xstart, xstage = info['xstart'], info['stage']
+      for ilayer in range(xstart, xend+1):
+        idx = bisect_right(info['choices'], ilayer-1)
+        self.depth_at_i[ilayer] = (xstage, idx)
+
+    self.avgpool     = nn.AvgPool2d(8)
+    self.classifier  = nn.Linear(module.out_dim, num_classes)
+    self.InShape     = None
+    self.tau         = -1
+    self.search_mode = 'basic'
+    #assert sum(x.num_conv for x in self.layers) + 1 == depth, 'invalid depth check {:} vs {:}'.format(sum(x.num_conv for x in self.layers)+1, depth)
+    
+
+    self.register_parameter('depth_attentions', nn.Parameter(torch.Tensor(3, get_depth_choices(layer_blocks, True))))
+    nn.init.normal_(self.depth_attentions, 0, 0.01)
+    self.apply(initialize_resnet)
+
+  def arch_parameters(self):
+    return [self.depth_attentions]
+
+  def base_parameters(self):
+    return list(self.layers.parameters()) + list(self.avgpool.parameters()) + list(self.classifier.parameters())
+
+  def get_flop(self, mode, config_dict, extra_info):
+    if config_dict is not None: config_dict = config_dict.copy()
+    # select depth
+    if mode == 'genotype':
+      with torch.no_grad():
+        depth_probs = nn.functional.softmax(self.depth_attentions, dim=1)
+        choices = torch.argmax(depth_probs, dim=1).cpu().tolist()
+    elif mode == 'max':
+      choices = [depth_probs.size(1)-1 for _ in range(depth_probs.size(0))]
+    elif mode == 'random':
+      with torch.no_grad():
+        depth_probs = nn.functional.softmax(self.depth_attentions, dim=1)
+        choices = torch.multinomial(depth_probs, 1, False).cpu().tolist()
+    else:
+      raise ValueError('invalid mode : {:}'.format(mode))
+    selected_layers = []
+    for choice, xvalue in zip(choices, self.depth_info_list):
+      xtemp = xvalue[1]['choices'][choice] - xvalue[1]['xstart'] + 1
+      selected_layers.append(xtemp)
+    flop = 0
+    for i, layer in enumerate(self.layers):
+      if i in self.depth_at_i:
+        xstagei, xatti = self.depth_at_i[i]
+        if xatti <= choices[xstagei]: # leave this depth
+          flop+= layer.get_flops()
+        else:
+          flop+= 0 # do not use this layer
+      else:
+        flop+= layer.get_flops()
+    # the last fc layer
+    flop += self.classifier.in_features * self.classifier.out_features
+    if config_dict is None:
+      return flop / 1e6
+    else:
+      config_dict['xblocks']    = selected_layers
+      config_dict['super_type'] = 'infer-depth'
+      config_dict['estimated_FLOP'] = flop / 1e6
+      return flop / 1e6, config_dict
+
+  def get_arch_info(self):
+    string = "for depth, there are {:} attention probabilities.".format(len(self.depth_attentions))
+    string+= '\n{:}'.format(self.depth_info)
+    discrepancy = []
+    with torch.no_grad():
+      for i, att in enumerate(self.depth_attentions):
+        prob = nn.functional.softmax(att, dim=0)
+        prob = prob.cpu() ; selc = prob.argmax().item() ; prob = prob.tolist()
+        prob = ['{:.3f}'.format(x) for x in prob]
+        xstring = '{:03d}/{:03d}-th : {:}'.format(i, len(self.depth_attentions), ' '.join(prob))
+        logt = ['{:.4f}'.format(x) for x in att.cpu().tolist()]
+        xstring += '  ||  {:17s}'.format(' '.join(logt))
+        prob = sorted( [float(x) for x in prob] )
+        disc = prob[-1] - prob[-2]
+        xstring += '  || discrepancy={:.2f} || select={:}/{:}'.format(disc, selc, len(prob))
+        discrepancy.append( disc )
+        string += '\n{:}'.format(xstring)
+    return string, discrepancy
+
+  def set_tau(self, tau_max, tau_min, epoch_ratio):
+    assert epoch_ratio >= 0 and epoch_ratio <= 1, 'invalid epoch-ratio : {:}'.format(epoch_ratio)
+    tau = tau_min + (tau_max-tau_min) * (1 + math.cos(math.pi * epoch_ratio)) / 2
+    self.tau = tau
+
+  def get_message(self):
+    return self.message
+
+  def forward(self, inputs):
+    if self.search_mode == 'basic':
+      return self.basic_forward(inputs)
+    elif self.search_mode == 'search':
+      return self.search_forward(inputs)
+    else:
+      raise ValueError('invalid search_mode = {:}'.format(self.search_mode))
+
+  def search_forward(self, inputs):
+    flop_depth_probs = nn.functional.softmax(self.depth_attentions, dim=1)
+    flop_depth_probs = torch.flip( torch.cumsum( torch.flip(flop_depth_probs, [1]), 1 ), [1] )
+    selected_depth_probs = select2withP(self.depth_attentions, self.tau, True)
+
+    x, flops = inputs, []
+    feature_maps = []
+    for i, layer in enumerate(self.layers):
+      layer_i = layer( x )
+      feature_maps.append( layer_i )
+      if i in self.depth_info: # aggregate the information
+        choices = self.depth_info[i]['choices']
+        xstagei = self.depth_info[i]['stage']
+        possible_tensors = []
+        for tempi, A in enumerate(choices):
+          xtensor = feature_maps[A]
+          possible_tensors.append( xtensor )
+        weighted_sum = sum( xtensor * W for xtensor, W in zip(possible_tensors, selected_depth_probs[xstagei]) )
+        x = weighted_sum
+      else:
+        x = layer_i
+       
+      if i in self.depth_at_i:
+        xstagei, xatti = self.depth_at_i[i]
+        #print ('layer-{:03d}, stage={:}, att={:}, prob={:}, flop={:}'.format(i, xstagei, xatti, flop_depth_probs[xstagei, xatti].item(), layer.get_flops(1e6)))
+        x_expected_flop = flop_depth_probs[xstagei, xatti] * layer.get_flops(1e6)
+      else:
+        x_expected_flop = layer.get_flops(1e6)
+      flops.append( x_expected_flop )
+    flops.append( (self.classifier.in_features * self.classifier.out_features*1.0/1e6) )
+
+    features = self.avgpool(x)
+    features = features.view(features.size(0), -1)
+    logits   = linear_forward(features, self.classifier)
+    return logits, torch.stack( [sum(flops)] )
+
+  def basic_forward(self, inputs):
+    if self.InShape is None: self.InShape = (inputs.size(-2), inputs.size(-1))
+    x = inputs
+    for i, layer in enumerate(self.layers):
+      x = layer( x )
+    features = self.avgpool(x)
+    features = features.view(features.size(0), -1)
+    logits   = self.classifier(features)
+    return features, logits