PointMLP/classification_ModelNet40/models/model31.py

"""
Based on model30, change the grouper operation by normalization.
Based on model28, only change configurations, mainly the reducer.
Based on model27, change to x-a, reorgnized structure
Based on model25, simple LocalGrouper (not x-a), reorgnized structure
Based on model24, using ReLU to replace GELU
Based on model22, remove attention
Bsed on model21, change FPS to random sampling.
Exactly based on Model10, but ReLU to GeLU
Based on Model8, add dropout and max, avg combine.
Based on Local model, add residual connections.
The extraction is doubled for depth.
Learning Point Cloud with Progressively Local representation.
[B,3,N] - {[B,G,K,d]-[B,G,d]}  - {[B,G',K,d]-[B,G',d]} -cls
"""
import torch
import torch.nn as nn
import torch.nn.functional as F
# from torch import einsum
# from einops import rearrange, repeat


from pointnet2_ops import pointnet2_utils


def get_activation(activation):
    if activation.lower() == 'gelu':
        return nn.GELU()
    elif activation.lower() == 'rrelu':
        return nn.RReLU(inplace=True)
    elif activation.lower() == 'selu':
        return nn.SELU(inplace=True)
    elif activation.lower() == 'silu':
        return nn.SiLU(inplace=True)
    elif activation.lower() == 'hardswish':
        return nn.Hardswish(inplace=True)
    elif activation.lower() == 'leakyrelu':
        return nn.LeakyReLU(inplace=True)
    else:
        return nn.ReLU(inplace=True)


def square_distance(src, dst):
    """
    Calculate Euclid distance between each two points.
    src^T * dst = xn * xm + yn * ym + zn * zm；
    sum(src^2, dim=-1) = xn*xn + yn*yn + zn*zn;
    sum(dst^2, dim=-1) = xm*xm + ym*ym + zm*zm;
    dist = (xn - xm)^2 + (yn - ym)^2 + (zn - zm)^2
         = sum(src**2,dim=-1)+sum(dst**2,dim=-1)-2*src^T*dst
    Input:
        src: source points, [B, N, C]
        dst: target points, [B, M, C]
    Output:
        dist: per-point square distance, [B, N, M]
    """
    B, N, _ = src.shape
    _, M, _ = dst.shape
    dist = -2 * torch.matmul(src, dst.permute(0, 2, 1))
    dist += torch.sum(src ** 2, -1).view(B, N, 1)
    dist += torch.sum(dst ** 2, -1).view(B, 1, M)
    return dist


def index_points(points, idx):
    """
    Input:
        points: input points data, [B, N, C]
        idx: sample index data, [B, S]
    Return:
        new_points:, indexed points data, [B, S, C]
    """
    device = points.device
    B = points.shape[0]
    view_shape = list(idx.shape)
    view_shape[1:] = [1] * (len(view_shape) - 1)
    repeat_shape = list(idx.shape)
    repeat_shape[0] = 1
    batch_indices = torch.arange(B, dtype=torch.long).to(device).view(view_shape).repeat(repeat_shape)
    new_points = points[batch_indices, idx, :]
    return new_points


def farthest_point_sample(xyz, npoint):
    """
    Input:
        xyz: pointcloud data, [B, N, 3]
        npoint: number of samples
    Return:
        centroids: sampled pointcloud index, [B, npoint]
    """
    device = xyz.device
    B, N, C = xyz.shape
    centroids = torch.zeros(B, npoint, dtype=torch.long).to(device)
    distance = torch.ones(B, N).to(device) * 1e10
    farthest = torch.randint(0, N, (B,), dtype=torch.long).to(device)
    batch_indices = torch.arange(B, dtype=torch.long).to(device)
    for i in range(npoint):
        centroids[:, i] = farthest
        centroid = xyz[batch_indices, farthest, :].view(B, 1, 3)
        dist = torch.sum((xyz - centroid) ** 2, -1)
        distance = torch.min(distance, dist)
        farthest = torch.max(distance, -1)[1]
    return centroids


def query_ball_point(radius, nsample, xyz, new_xyz):
    """
    Input:
        radius: local region radius
        nsample: max sample number in local region
        xyz: all points, [B, N, 3]
        new_xyz: query points, [B, S, 3]
    Return:
        group_idx: grouped points index, [B, S, nsample]
    """
    device = xyz.device
    B, N, C = xyz.shape
    _, S, _ = new_xyz.shape
    group_idx = torch.arange(N, dtype=torch.long).to(device).view(1, 1, N).repeat([B, S, 1])
    sqrdists = square_distance(new_xyz, xyz)
    group_idx[sqrdists > radius ** 2] = N
    group_idx = group_idx.sort(dim=-1)[0][:, :, :nsample]
    group_first = group_idx[:, :, 0].view(B, S, 1).repeat([1, 1, nsample])
    mask = group_idx == N
    group_idx[mask] = group_first[mask]
    return group_idx


def knn_point(nsample, xyz, new_xyz):
    """
    Input:
        nsample: max sample number in local region
        xyz: all points, [B, N, C]
        new_xyz: query points, [B, S, C]
    Return:
        group_idx: grouped points index, [B, S, nsample]
    """
    sqrdists = square_distance(new_xyz, xyz)
    _, group_idx = torch.topk(sqrdists, nsample, dim=-1, largest=False, sorted=False)
    return group_idx


class LocalGrouper(nn.Module):
    def __init__(self, channel, groups, kneighbors, use_xyz=True, normalize="center", **kwargs):
        """
        Give xyz[b,p,3] and fea[b,p,d], return new_xyz[b,g,3] and new_fea[b,g,k,d]
        :param groups: groups number
        :param kneighbors: k-nerighbors
        :param kwargs: others
        """
        super(LocalGrouper, self).__init__()
        self.groups = groups
        self.kneighbors = kneighbors
        self.use_xyz = use_xyz
        if normalize is not None:
            self.normalize = normalize.lower()
        else:
            self.normalize = None
        if self.normalize not in ["center", "anchor"]:
            print(f"Unrecognized normalize parameter (self.normalize), set to None. Should be one of [center, anchor].")
            self.normalize = None
        if self.normalize is not None:
            add_channel=3 if self.use_xyz else 0
            self.affine_alpha = nn.Parameter(torch.ones([1,1,1,channel + add_channel]))
            self.affine_beta = nn.Parameter(torch.zeros([1, 1, 1, channel + add_channel]))

    def forward(self, xyz, points):
        B, N, C = xyz.shape
        S = self.groups
        xyz = xyz.contiguous()  # xyz [btach, points, xyz]

        # fps_idx = torch.multinomial(torch.linspace(0, N - 1, steps=N).repeat(B, 1).to(xyz.device), num_samples=self.groups, replacement=False).long()
        # fps_idx = farthest_point_sample(xyz, self.groups).long()
        fps_idx = pointnet2_utils.furthest_point_sample(xyz, self.groups).long()  # [B, npoint]
        new_xyz = index_points(xyz, fps_idx)  # [B, npoint, 3]
        new_points = index_points(points, fps_idx)  # [B, npoint, d]

        idx = knn_point(self.kneighbors, xyz, new_xyz)
        # idx = query_ball_point(radius, nsample, xyz, new_xyz)
        grouped_xyz = index_points(xyz, idx)  # [B, npoint, k, 3]
        grouped_points = index_points(points, idx)  # [B, npoint, k, d]
        if self.use_xyz:
            grouped_points = torch.cat([grouped_points, grouped_xyz],dim=-1)  # [B, npoint, k, d+3]
        if self.normalize is not None:
            if self.normalize =="center":
                std, mean = torch.std_mean(grouped_points, dim=2, keepdim=True)
            if self.normalize =="anchor":
                mean = torch.cat([new_points, new_xyz],dim=-1) if self.use_xyz else new_points
                mean = mean.unsqueeze(dim=-2)  # [B, npoint, 1, d+3]
                std = torch.std(grouped_points-mean)
            grouped_points = (grouped_points-mean)/(std + 1e-5)
            grouped_points = self.affine_alpha*grouped_points + self.affine_beta

        new_points = torch.cat([grouped_points, new_points.view(B, S, 1, -1).repeat(1, 1, self.kneighbors, 1)], dim=-1)
        return new_xyz, new_points


class ConvBNReLU1D(nn.Module):
    def __init__(self, in_channels, out_channels, kernel_size=1, bias=True, activation='relu'):
        super(ConvBNReLU1D, self).__init__()
        self.act = get_activation(activation)
        self.net = nn.Sequential(
            nn.Conv1d(in_channels=in_channels, out_channels=out_channels, kernel_size=kernel_size, bias=bias),
            nn.BatchNorm1d(out_channels),
            self.act
        )

    def forward(self, x):
        return self.net(x)


class ConvBNReLURes1D(nn.Module):
    def __init__(self, channel, kernel_size=1, groups=1, res_expansion=1.0, bias=True, activation='relu'):
        super(ConvBNReLURes1D, self).__init__()
        self.act = get_activation(activation)
        self.net1 = nn.Sequential(
            nn.Conv1d(in_channels=channel, out_channels=int(channel * res_expansion),
                      kernel_size=kernel_size, groups=groups, bias=bias),
            nn.BatchNorm1d(int(channel * res_expansion)),
            self.act
        )
        if groups > 1:
            self.net2 = nn.Sequential(
                nn.Conv1d(in_channels=int(channel * res_expansion), out_channels=channel,
                          kernel_size=kernel_size, groups=groups, bias=bias),
                nn.BatchNorm1d(channel),
                self.act,
                nn.Conv1d(in_channels=channel, out_channels=channel,
                          kernel_size=kernel_size, bias=bias),
                nn.BatchNorm1d(channel),
            )
        else:
            self.net2 = nn.Sequential(
                nn.Conv1d(in_channels=int(channel * res_expansion), out_channels=channel,
                          kernel_size=kernel_size, bias=bias),
                nn.BatchNorm1d(channel)
            )

    def forward(self, x):
        return self.act(self.net2(self.net1(x)) + x)


class PreExtraction(nn.Module):
    def __init__(self, channels, out_channels,  blocks=1, groups=1, res_expansion=1, bias=True,
                 activation='relu', use_xyz=True):
        """
        input: [b,g,k,d]: output:[b,d,g]
        :param channels:
        :param blocks:
        """
        super(PreExtraction, self).__init__()
        in_channels = 3+2*channels if use_xyz else 2*channels
        self.transfer = ConvBNReLU1D(in_channels, out_channels, bias=bias, activation=activation)
        operation = []
        for _ in range(blocks):
            operation.append(
                ConvBNReLURes1D(out_channels, groups=groups, res_expansion=res_expansion,
                                bias=bias, activation=activation)
            )
        self.operation = nn.Sequential(*operation)

    def forward(self, x):
        b, n, s, d = x.size()  # torch.Size([32, 512, 32, 6])
        x = x.permute(0, 1, 3, 2)
        x = x.reshape(-1, d, s)
        x = self.transfer(x)
        batch_size, _, _ = x.size()
        x = self.operation(x)  # [b, d, k]
        x = F.adaptive_max_pool1d(x, 1).view(batch_size, -1)
        x = x.reshape(b, n, -1).permute(0, 2, 1)
        return x


class PosExtraction(nn.Module):
    def __init__(self, channels, blocks=1, groups=1, res_expansion=1, bias=True, activation='relu'):
        """
        input[b,d,g]; output[b,d,g]
        :param channels:
        :param blocks:
        """
        super(PosExtraction, self).__init__()
        operation = []
        for _ in range(blocks):
            operation.append(
                ConvBNReLURes1D(channels, groups=groups, res_expansion=res_expansion, bias=bias, activation=activation)
            )
        self.operation = nn.Sequential(*operation)

    def forward(self, x):  # [b, d, g]
        return self.operation(x)


class model31(nn.Module):
    def __init__(self, points=1024, class_num=40, embed_dim=64, groups=1, res_expansion=1.0,
                 activation="relu", bias=True, use_xyz=True, normalize="center",
                 dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                 k_neighbors=[32, 32, 32, 32], reducers=[2, 2, 2, 2], **kwargs):
        super(model31, self).__init__()
        self.stages = len(pre_blocks)
        self.class_num = class_num
        self.points = points
        self.embedding = ConvBNReLU1D(3, embed_dim, bias=bias, activation=activation)
        assert len(pre_blocks) == len(k_neighbors) == len(reducers) == len(pos_blocks) == len(dim_expansion), \
            "Please check stage number consistent for pre_blocks, pos_blocks k_neighbors, reducers."
        self.local_grouper_list = nn.ModuleList()
        self.pre_blocks_list = nn.ModuleList()
        self.pos_blocks_list = nn.ModuleList()
        last_channel = embed_dim
        anchor_points = self.points
        for i in range(len(pre_blocks)):
            out_channel = last_channel * dim_expansion[i]
            pre_block_num = pre_blocks[i]
            pos_block_num = pos_blocks[i]
            kneighbor = k_neighbors[i]
            reduce = reducers[i]
            anchor_points = anchor_points // reduce
            # append local_grouper_list
            local_grouper = LocalGrouper(last_channel, anchor_points, kneighbor, use_xyz, normalize)  # [b,g,k,d]
            self.local_grouper_list.append(local_grouper)
            # append pre_block_list
            pre_block_module = PreExtraction(last_channel, out_channel, pre_block_num, groups=groups,
                                             res_expansion=res_expansion,
                                             bias=bias, activation=activation, use_xyz=use_xyz)
            self.pre_blocks_list.append(pre_block_module)
            # append pos_block_list
            pos_block_module = PosExtraction(out_channel, pos_block_num, groups=groups,
                                             res_expansion=res_expansion, bias=bias, activation=activation)
            self.pos_blocks_list.append(pos_block_module)

            last_channel = out_channel

        self.act = get_activation(activation)
        self.classifier = nn.Sequential(
            nn.Linear(last_channel, 512),
            nn.BatchNorm1d(512),
            self.act,
            nn.Dropout(0.5),
            nn.Linear(512, 256),
            nn.BatchNorm1d(256),
            self.act,
            nn.Dropout(0.5),
            nn.Linear(256, self.class_num)
        )

    def forward(self, x):
        xyz = x.permute(0, 2, 1)
        batch_size, _, _ = x.size()
        x = self.embedding(x)  # B,D,N
        for i in range(self.stages):
            # Give xyz[b, p, 3] and fea[b, p, d], return new_xyz[b, g, 3] and new_fea[b, g, k, d]
            xyz, x = self.local_grouper_list[i](xyz, x.permute(0, 2, 1))  # [b,g,3]  [b,g,k,d]
            x = self.pre_blocks_list[i](x)  # [b,d,g]
            x = self.pos_blocks_list[i](x)  # [b,d,g]

        x = F.adaptive_max_pool1d(x, 1).squeeze(dim=-1)
        x = self.classifier(x)
        return x



def model31A(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=64, groups=1, res_expansion=1.0,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                   k_neighbors=[32, 32, 32, 32], reducers=[2, 2, 2, 2], **kwargs)

def model31B(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=64, groups=1, res_expansion=1.0,
                   activation="relu", bias=False, use_xyz=False, normalize="center",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                   k_neighbors=[32, 32, 32, 32], reducers=[2, 2, 2, 2], **kwargs)


def model31C(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=64, groups=1, res_expansion=1.0,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                   k_neighbors=[24, 24, 24, 24], reducers=[2, 2, 2, 2], **kwargs)

def model31D(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=64, groups=1, res_expansion=1.0,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                   k_neighbors=[20, 20, 20, 20], reducers=[2, 2, 2, 2], **kwargs)


def model31E(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=32, groups=1, res_expansion=1.0,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                   k_neighbors=[32, 32, 32, 32], reducers=[2, 2, 2, 2], **kwargs)


def model31F(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=64, groups=1, res_expansion=0.125,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                   k_neighbors=[32, 32, 32, 32], reducers=[2, 2, 2, 2], **kwargs)


def model31G(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=64, groups=16, res_expansion=2.0,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[2, 2, 2, 2], pos_blocks=[2, 2, 2, 2],
                   k_neighbors=[32, 32, 32, 32], reducers=[2, 2, 2, 2], **kwargs)

def model31H(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=128, groups=1, res_expansion=1,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2], pre_blocks=[4, 4], pos_blocks=[4, 4],
                   k_neighbors=[32, 32], reducers=[4, 4], **kwargs)

def model31I(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=128, groups=1, res_expansion=1,
                   activation="gelu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2], pre_blocks=[4, 4], pos_blocks=[4, 4],
                   k_neighbors=[32, 32], reducers=[4, 4], **kwargs)

def model31J(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=128, groups=1, res_expansion=1,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2], pre_blocks=[4, 4], pos_blocks=[4, 4],
                   k_neighbors=[24, 24], reducers=[4, 4], **kwargs)

def model31K(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=384, groups=1, res_expansion=1,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[1, 1], pre_blocks=[4, 4], pos_blocks=[4, 4],
                   k_neighbors=[32, 32], reducers=[4, 4], **kwargs)

def model31L(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=128, groups=1, res_expansion=1,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2], pre_blocks=[3, 3, 3], pos_blocks=[3, 3, 3],
                   k_neighbors=[24, 24, 24], reducers=[4, 4, 2], **kwargs)

def model31M(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=128, groups=1, res_expansion=1,
                   activation="leakyrelu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2], pre_blocks=[4, 4], pos_blocks=[4, 4],
                   k_neighbors=[32, 32], reducers=[4, 4], **kwargs)

def model31N(num_classes=40, **kwargs) -> model31:
    return model31(points=1024, class_num=num_classes, embed_dim=32, groups=1, res_expansion=1.0,
                   activation="relu", bias=False, use_xyz=False, normalize="anchor",
                   dim_expansion=[2, 2, 2, 2], pre_blocks=[4, 8, 4, 2], pos_blocks=[4, 8, 4, 2],
                   k_neighbors=[32, 32, 32, 32], reducers=[2, 2, 2, 2], **kwargs)


if __name__ == '__main__':
    # data = torch.rand(2, 128, 10)
    # model = ConvBNReLURes1D(128, groups=2, activation='relu')
    # out = model(data)
    # print(out.shape)
    #
    # batch, groups, neighbors, dim = 2, 512, 32, 16
    # x = torch.rand(batch, groups, neighbors, dim)
    # pre_extractor = PreExtraction(dim, 3)
    # out = pre_extractor(x)
    # print(out.shape)
    #
    # x = torch.rand(batch, dim, groups)
    # pos_extractor = PosExtraction(dim, 3)
    # out = pos_extractor(x)
    # print(out.shape)

    data = torch.rand(2, 3, 1024)

    print("===> testing modelK ...")
    model = model31K()
    out = model(data)
    print(out.shape)

    print("===> testing modelL ...")
    model = model31L()
    out = model(data)
    print(out.shape)

    print("===> testing modelM ...")
    model = model31M()
    out = model(data)
    print(out.shape)

    print("===> testing modelN ...")
    model = model31N()
    out = model(data)
    print(out.shape)