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|
use candle::{DType, IndexOp, Result, Tensor, D};
use candle_nn::{layer_norm, LayerNorm, Linear, Module, VarBuilder};
#[derive(Debug)]
struct PatchEmbed {
proj: candle_nn::Conv2d,
}
impl PatchEmbed {
fn new(
in_chans: usize,
embed_dim: usize,
k_size: usize,
stride: usize,
padding: usize,
vb: VarBuilder,
) -> Result<Self> {
let cfg = candle_nn::Conv2dConfig {
stride,
padding,
..Default::default()
};
let proj = candle_nn::conv2d(in_chans, embed_dim, k_size, cfg, vb.pp("proj"))?;
Ok(Self { proj })
}
}
impl Module for PatchEmbed {
fn forward(&self, xs: &Tensor) -> Result<Tensor> {
xs.apply(&self.proj)?.permute((0, 2, 3, 1))
}
}
#[derive(Debug)]
struct Attention {
qkv: Linear,
proj: Linear,
num_heads: usize,
scale: f64,
use_rel_pos: bool,
rel_pos_hw: Option<(Tensor, Tensor)>,
}
impl Attention {
fn new(
dim: usize,
num_heads: usize,
qkv_bias: bool,
use_rel_pos: bool,
input_size: (usize, usize),
vb: VarBuilder,
) -> Result<Self> {
let qkv = crate::linear(vb.pp("qkv"), dim, dim * 3, qkv_bias)?;
let proj = crate::linear(vb.pp("proj"), dim, dim, true)?;
let head_dim = dim / num_heads;
let scale = 1. / (head_dim as f64).sqrt();
let rel_pos_hw = if use_rel_pos {
let h = vb.get((2 * input_size.0 - 1, head_dim), "rel_pos_h")?;
let w = vb.get((2 * input_size.1 - 1, head_dim), "rel_pos_w")?;
Some((h, w))
} else {
None
};
Ok(Self {
qkv,
proj,
num_heads,
scale,
use_rel_pos,
rel_pos_hw,
})
}
}
impl Module for Attention {
fn forward(&self, xs: &Tensor) -> Result<Tensor> {
let (b, h, w, c) = xs.dims4()?;
let qkv = self
.qkv
.forward(xs)?
.reshape((b, h * w, 3, self.num_heads, c / self.num_heads))?
.permute((2, 0, 3, 1, 4))?
.reshape((3, b * self.num_heads, h * w, c / self.num_heads))?;
let q = qkv.i(0)?;
let k = qkv.i(1)?;
let v = qkv.i(2)?;
let attn = (q * self.scale)?.matmul(&k.t()?)?;
if self.use_rel_pos {
todo!()
}
let attn = candle_nn::ops::softmax_last_dim(&attn)?;
let attn = attn
.matmul(&v)?
.reshape((b, self.num_heads, h, w, c / self.num_heads))?
.permute((0, 2, 3, 1, 4))?
.reshape((b, h, w, c / self.num_heads))?;
self.proj.forward(&attn)
}
}
#[derive(Debug)]
struct Block {
norm1: LayerNorm,
attn: Attention,
norm2: LayerNorm,
mlp: crate::MlpBlock,
window_size: usize,
}
impl Block {
fn new(
dim: usize,
num_heads: usize,
qkv_bias: bool,
use_rel_pos: bool,
window_size: usize,
input_size: (usize, usize),
vb: VarBuilder,
) -> Result<Self> {
let norm1 = layer_norm(dim, 1e-5, vb.pp("norm1"))?;
let norm2 = layer_norm(dim, 1e-5, vb.pp("norm2"))?;
let input_size_attn = if window_size == 0 {
input_size
} else {
(window_size, window_size)
};
let attn = Attention::new(
dim,
num_heads,
qkv_bias,
use_rel_pos,
input_size_attn,
vb.pp("attn"),
)?;
let mlp = crate::MlpBlock::new(dim, dim * 4, vb.pp("mlp"))?;
Ok(Self {
norm1,
attn,
norm2,
mlp,
window_size,
})
}
}
impl Module for Block {
fn forward(&self, xs: &Tensor) -> Result<Tensor> {
let shortcut = xs;
let xs = self.norm1.forward(xs)?;
if self.window_size > 0 {
todo!()
}
let xs = self.attn.forward(&xs)?;
if self.window_size > 0 {
todo!()
}
let xs = (xs + shortcut)?;
&xs + xs.apply(&self.norm2)?.apply(&self.mlp)?
}
}
#[derive(Debug)]
pub struct ImageEncoderViT {
img_size: usize,
patch_embed: PatchEmbed,
blocks: Vec<Block>,
neck_conv1: candle_nn::Conv2d,
neck_ln1: LayerNorm,
neck_conv2: candle_nn::Conv2d,
neck_ln2: LayerNorm,
pos_embed: Option<Tensor>,
}
impl ImageEncoderViT {
#[allow(clippy::too_many_arguments)]
pub fn new(
img_size: usize,
patch_size: usize,
in_chans: usize,
embed_dim: usize,
depth: usize,
num_heads: usize,
out_chans: usize,
qkv_bias: bool,
use_rel_pos: bool,
use_abs_pos: bool,
window_size: usize,
global_attn_indexes: &[usize],
vb: VarBuilder,
) -> Result<Self> {
let patch_embed = PatchEmbed::new(
in_chans,
embed_dim,
patch_size,
patch_size,
0,
vb.pp("patch_embed"),
)?;
let mut blocks = Vec::with_capacity(depth);
let vb_b = vb.pp("blocks");
for i in 0..depth {
let window_size = if global_attn_indexes.contains(&i) {
0
} else {
window_size
};
let block = Block::new(
embed_dim,
num_heads,
qkv_bias,
use_rel_pos,
window_size,
(img_size / patch_size, img_size / patch_size),
vb_b.pp(i),
)?;
blocks.push(block)
}
let neck_conv1 = candle_nn::conv2d_no_bias(
embed_dim,
out_chans,
1,
Default::default(),
vb.pp("neck.0"),
)?;
let neck_ln1 = layer_norm(out_chans, 1e-6, vb.pp("neck.1"))?;
let cfg = candle_nn::Conv2dConfig {
padding: 1,
..Default::default()
};
let neck_conv2 = candle_nn::conv2d_no_bias(out_chans, out_chans, 3, cfg, vb.pp("neck.2"))?;
let neck_ln2 = layer_norm(out_chans, 1e-6, vb.pp("neck.3"))?;
let pos_embed = if use_abs_pos {
let p = vb.get(
(1, img_size / patch_size, img_size / patch_size, embed_dim),
"pos_embed",
)?;
Some(p)
} else {
None
};
Ok(Self {
img_size,
patch_embed,
blocks,
neck_conv1,
neck_ln1,
neck_conv2,
neck_ln2,
pos_embed,
})
}
}
impl Module for ImageEncoderViT {
fn forward(&self, xs: &Tensor) -> Result<Tensor> {
let xs = self.patch_embed.forward(xs)?;
let mut xs = match &self.pos_embed {
Some(pos_embed) => (xs + pos_embed)?,
None => xs,
};
for block in self.blocks.iter() {
xs = block.forward(&xs)?
}
xs.permute((0, 3, 1, 2))?
.apply(&self.neck_conv1)?
.apply(&self.neck_ln1)?
.apply(&self.neck_conv2)?
.apply(&self.neck_ln2)
}
}
|
