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import pdb |
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import numpy as np |
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import torch |
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import torch.nn as nn |
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class APLoss (nn.Module): |
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""" differentiable AP loss, through quantization. |
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Input: (N, M) values in [min, max] |
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label: (N, M) values in {0, 1} |
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Returns: list of query AP (for each n in {1..N}) |
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Note: typically, you want to minimize 1 - mean(AP) |
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""" |
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def __init__(self, nq=25, min=0, max=1, euc=False): |
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nn.Module.__init__(self) |
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assert isinstance(nq, int) and 2 <= nq <= 100 |
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self.nq = nq |
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self.min = min |
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self.max = max |
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self.euc = euc |
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gap = max - min |
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assert gap > 0 |
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self.quantizer = q = nn.Conv1d(1, 2*nq, kernel_size=1, bias=True) |
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a = (nq-1) / gap |
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q.weight.data[:nq] = -a |
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q.bias.data[:nq] = torch.from_numpy(a*min + np.arange(nq, 0, -1)) |
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q.weight.data[nq:] = a |
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q.bias.data[nq:] = torch.from_numpy(np.arange(2-nq, 2, 1) - a*min) |
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q.weight.data[0] = q.weight.data[-1] = 0 |
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q.bias.data[0] = q.bias.data[-1] = 1 |
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def compute_AP(self, x, label): |
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N, M = x.shape |
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if self.euc: |
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x = 1 - torch.sqrt(2.001 - 2*x) |
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q = self.quantizer(x.unsqueeze(1)) |
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q = torch.min(q[:,:self.nq], q[:,self.nq:]).clamp(min=0) |
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nbs = q.sum(dim=-1) |
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rec = (q * label.view(N,1,M).float()).sum(dim=-1) |
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prec = rec.cumsum(dim=-1) / (1e-16 + nbs.cumsum(dim=-1)) |
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rec /= rec.sum(dim=-1).unsqueeze(1) |
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ap = (prec * rec).sum(dim=-1) |
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return ap |
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def forward(self, x, label): |
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assert x.shape == label.shape |
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return self.compute_AP(x, label) |
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