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import functools
import tensorflow as tf
from tensorflow.keras import backend as K
from tensorflow.keras import layers
from .blocks.attentions import SAM
from .blocks.bottleneck import BottleneckBlock
from .blocks.misc_gating import CrossGatingBlock
from .blocks.others import UpSampleRatio
from .blocks.unet import UNetDecoderBlock, UNetEncoderBlock
from .layers import Resizing
Conv1x1 = functools.partial(layers.Conv2D, kernel_size=(1, 1), padding="same")
Conv3x3 = functools.partial(layers.Conv2D, kernel_size=(3, 3), padding="same")
ConvT_up = functools.partial(
layers.Conv2DTranspose, kernel_size=(2, 2), strides=(2, 2), padding="same"
)
Conv_down = functools.partial(
layers.Conv2D, kernel_size=(4, 4), strides=(2, 2), padding="same"
)
def MAXIM(
features: int = 64,
depth: int = 3,
num_stages: int = 2,
num_groups: int = 1,
use_bias: bool = True,
num_supervision_scales: int = 1,
lrelu_slope: float = 0.2,
use_global_mlp: bool = True,
use_cross_gating: bool = True,
high_res_stages: int = 2,
block_size_hr=(16, 16),
block_size_lr=(8, 8),
grid_size_hr=(16, 16),
grid_size_lr=(8, 8),
num_bottleneck_blocks: int = 1,
block_gmlp_factor: int = 2,
grid_gmlp_factor: int = 2,
input_proj_factor: int = 2,
channels_reduction: int = 4,
num_outputs: int = 3,
dropout_rate: float = 0.0,
):
"""The MAXIM model function with multi-stage and multi-scale supervision.
For more model details, please check the CVPR paper:
MAXIM: MUlti-Axis MLP for Image Processing (https://arxiv.org/abs/2201.02973)
Attributes:
features: initial hidden dimension for the input resolution.
depth: the number of downsampling depth for the model.
num_stages: how many stages to use. It will also affects the output list.
num_groups: how many blocks each stage contains.
use_bias: whether to use bias in all the conv/mlp layers.
num_supervision_scales: the number of desired supervision scales.
lrelu_slope: the negative slope parameter in leaky_relu layers.
use_global_mlp: whether to use the multi-axis gated MLP block (MAB) in each
layer.
use_cross_gating: whether to use the cross-gating MLP block (CGB) in the
skip connections and multi-stage feature fusion layers.
high_res_stages: how many stages are specificied as high-res stages. The
rest (depth - high_res_stages) are called low_res_stages.
block_size_hr: the block_size parameter for high-res stages.
block_size_lr: the block_size parameter for low-res stages.
grid_size_hr: the grid_size parameter for high-res stages.
grid_size_lr: the grid_size parameter for low-res stages.
num_bottleneck_blocks: how many bottleneck blocks.
block_gmlp_factor: the input projection factor for block_gMLP layers.
grid_gmlp_factor: the input projection factor for grid_gMLP layers.
input_proj_factor: the input projection factor for the MAB block.
channels_reduction: the channel reduction factor for SE layer.
num_outputs: the output channels.
dropout_rate: Dropout rate.
Returns:
The output contains a list of arrays consisting of multi-stage multi-scale
outputs. For example, if num_stages = num_supervision_scales = 3 (the
model used in the paper), the output specs are: outputs =
[[output_stage1_scale1, output_stage1_scale2, output_stage1_scale3],
[output_stage2_scale1, output_stage2_scale2, output_stage2_scale3],
[output_stage3_scale1, output_stage3_scale2, output_stage3_scale3],]
The final output can be retrieved by outputs[-1][-1].
"""
def apply(x):
n, h, w, c = (
K.int_shape(x)[0],
K.int_shape(x)[1],
K.int_shape(x)[2],
K.int_shape(x)[3],
) # input image shape
shortcuts = []
shortcuts.append(x)
# Get multi-scale input images
for i in range(1, num_supervision_scales):
resizing_layer = Resizing(
height=h // (2 ** i),
width=w // (2 ** i),
method="nearest",
antialias=True, # Following `jax.image.resize()`.
name=f"initial_resizing_{K.get_uid('Resizing')}",
)
shortcuts.append(resizing_layer(x))
# store outputs from all stages and all scales
# Eg, [[(64, 64, 3), (128, 128, 3), (256, 256, 3)], # Stage-1 outputs
# [(64, 64, 3), (128, 128, 3), (256, 256, 3)],] # Stage-2 outputs
outputs_all = []
sam_features, encs_prev, decs_prev = [], [], []
for idx_stage in range(num_stages):
# Input convolution, get multi-scale input features
x_scales = []
for i in range(num_supervision_scales):
x_scale = Conv3x3(
filters=(2 ** i) * features,
use_bias=use_bias,
name=f"stage_{idx_stage}_input_conv_{i}",
)(shortcuts[i])
# If later stages, fuse input features with SAM features from prev stage
if idx_stage > 0:
# use larger blocksize at high-res stages
if use_cross_gating:
block_size = (
block_size_hr if i < high_res_stages else block_size_lr
)
grid_size = grid_size_hr if i < high_res_stages else block_size_lr
x_scale, _ = CrossGatingBlock(
features=(2 ** i) * features,
block_size=block_size,
grid_size=grid_size,
dropout_rate=dropout_rate,
input_proj_factor=input_proj_factor,
upsample_y=False,
use_bias=use_bias,
name=f"stage_{idx_stage}_input_fuse_sam_{i}",
)(x_scale, sam_features.pop())
else:
x_scale = Conv1x1(
filters=(2 ** i) * features,
use_bias=use_bias,
name=f"stage_{idx_stage}_input_catconv_{i}",
)(tf.concat([x_scale, sam_features.pop()], axis=-1))
x_scales.append(x_scale)
# start encoder blocks
encs = []
x = x_scales[0] # First full-scale input feature
for i in range(depth): # 0, 1, 2
# use larger blocksize at high-res stages, vice versa.
block_size = block_size_hr if i < high_res_stages else block_size_lr
grid_size = grid_size_hr if i < high_res_stages else block_size_lr
use_cross_gating_layer = True if idx_stage > 0 else False
# Multi-scale input if multi-scale supervision
x_scale = x_scales[i] if i < num_supervision_scales else None
# UNet Encoder block
enc_prev = encs_prev.pop() if idx_stage > 0 else None
dec_prev = decs_prev.pop() if idx_stage > 0 else None
x, bridge = UNetEncoderBlock(
num_channels=(2 ** i) * features,
num_groups=num_groups,
downsample=True,
lrelu_slope=lrelu_slope,
block_size=block_size,
grid_size=grid_size,
block_gmlp_factor=block_gmlp_factor,
grid_gmlp_factor=grid_gmlp_factor,
input_proj_factor=input_proj_factor,
channels_reduction=channels_reduction,
use_global_mlp=use_global_mlp,
dropout_rate=dropout_rate,
use_bias=use_bias,
use_cross_gating=use_cross_gating_layer,
name=f"stage_{idx_stage}_encoder_block_{i}",
)(x, skip=x_scale, enc=enc_prev, dec=dec_prev)
# Cache skip signals
encs.append(bridge)
# Global MLP bottleneck blocks
for i in range(num_bottleneck_blocks):
x = BottleneckBlock(
block_size=block_size_lr,
grid_size=block_size_lr,
features=(2 ** (depth - 1)) * features,
num_groups=num_groups,
block_gmlp_factor=block_gmlp_factor,
grid_gmlp_factor=grid_gmlp_factor,
input_proj_factor=input_proj_factor,
dropout_rate=dropout_rate,
use_bias=use_bias,
channels_reduction=channels_reduction,
name=f"stage_{idx_stage}_global_block_{i}",
)(x)
# cache global feature for cross-gating
global_feature = x
# start cross gating. Use multi-scale feature fusion
skip_features = []
for i in reversed(range(depth)): # 2, 1, 0
# use larger blocksize at high-res stages
block_size = block_size_hr if i < high_res_stages else block_size_lr
grid_size = grid_size_hr if i < high_res_stages else block_size_lr
# get additional multi-scale signals
signal = tf.concat(
[
UpSampleRatio(
num_channels=(2 ** i) * features,
ratio=2 ** (j - i),
use_bias=use_bias,
name=f"UpSampleRatio_{K.get_uid('UpSampleRatio')}",
)(enc)
for j, enc in enumerate(encs)
],
axis=-1,
)
# Use cross-gating to cross modulate features
if use_cross_gating:
skips, global_feature = CrossGatingBlock(
features=(2 ** i) * features,
block_size=block_size,
grid_size=grid_size,
input_proj_factor=input_proj_factor,
dropout_rate=dropout_rate,
upsample_y=True,
use_bias=use_bias,
name=f"stage_{idx_stage}_cross_gating_block_{i}",
)(signal, global_feature)
else:
skips = Conv1x1(
filters=(2 ** i) * features, use_bias=use_bias, name="Conv_0"
)(signal)
skips = Conv3x3(
filters=(2 ** i) * features, use_bias=use_bias, name="Conv_1"
)(skips)
skip_features.append(skips)
# start decoder. Multi-scale feature fusion of cross-gated features
outputs, decs, sam_features = [], [], []
for i in reversed(range(depth)):
# use larger blocksize at high-res stages
block_size = block_size_hr if i < high_res_stages else block_size_lr
grid_size = grid_size_hr if i < high_res_stages else block_size_lr
# get multi-scale skip signals from cross-gating block
signal = tf.concat(
[
UpSampleRatio(
num_channels=(2 ** i) * features,
ratio=2 ** (depth - j - 1 - i),
use_bias=use_bias,
name=f"UpSampleRatio_{K.get_uid('UpSampleRatio')}",
)(skip)
for j, skip in enumerate(skip_features)
],
axis=-1,
)
# Decoder block
x = UNetDecoderBlock(
num_channels=(2 ** i) * features,
num_groups=num_groups,
lrelu_slope=lrelu_slope,
block_size=block_size,
grid_size=grid_size,
block_gmlp_factor=block_gmlp_factor,
grid_gmlp_factor=grid_gmlp_factor,
input_proj_factor=input_proj_factor,
channels_reduction=channels_reduction,
use_global_mlp=use_global_mlp,
dropout_rate=dropout_rate,
use_bias=use_bias,
name=f"stage_{idx_stage}_decoder_block_{i}",
)(x, bridge=signal)
# Cache decoder features for later-stage's usage
decs.append(x)
# output conv, if not final stage, use supervised-attention-block.
if i < num_supervision_scales:
if idx_stage < num_stages - 1: # not last stage, apply SAM
sam, output = SAM(
num_channels=(2 ** i) * features,
output_channels=num_outputs,
use_bias=use_bias,
name=f"stage_{idx_stage}_supervised_attention_module_{i}",
)(x, shortcuts[i])
outputs.append(output)
sam_features.append(sam)
else: # Last stage, apply output convolutions
output = Conv3x3(
num_outputs,
use_bias=use_bias,
name=f"stage_{idx_stage}_output_conv_{i}",
)(x)
output = output + shortcuts[i]
outputs.append(output)
# Cache encoder and decoder features for later-stage's usage
encs_prev = encs[::-1]
decs_prev = decs
# Store outputs
outputs_all.append(outputs)
return outputs_all
return apply