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	# Copyright (c) Meta Platforms, Inc. and affiliates.
	# All rights reserved.

	# This source code is licensed under the license found in the
	# LICENSE file in the root directory of this source tree.

	import math
	from typing import Any, Optional, Tuple

	import numpy as np

	import torch
	from torch import nn


	class PositionEmbeddingSine(nn.Module):
	"""
	This is a more standard version of the position embedding, very similar to the one
	used by the Attention Is All You Need paper, generalized to work on images.
	"""

	def __init__(
	self,
	num_pos_feats,
	temperature: int = 10000,
	normalize: bool = True,
	scale: Optional[float] = None,
	# Following settings only relevant
	# for warmping up cache for compilation
	warmup_cache: bool = True,
	image_size: int = 1024,
	strides: Tuple[int] = (4, 8, 16, 32),
	):
	super().__init__()
	assert num_pos_feats % 2 == 0, "Expecting even model width"
	self.num_pos_feats = num_pos_feats // 2
	self.temperature = temperature
	self.normalize = normalize
	if scale is not None and normalize is False:
	raise ValueError("normalize should be True if scale is passed")
	if scale is None:
	scale = 2 * math.pi
	self.scale = scale

	self.cache = {}
	if warmup_cache and torch.cuda.is_available():
	# Warmup cache for cuda, to help with compilation
	device = torch.device("cuda")
	for stride in strides:
	cache_key = (image_size // stride, image_size // stride)
	self._pe(1, device, *cache_key)

	def _encode_xy(self, x, y):
	# The positions are expected to be normalized
	assert len(x) == len(y) and x.ndim == y.ndim == 1
	x_embed = x * self.scale
	y_embed = y * self.scale

	dim_t = torch.arange(self.num_pos_feats, dtype=torch.float32, device=x.device)
	dim_t = self.temperature ** (2 * (dim_t // 2) / self.num_pos_feats)

	pos_x = x_embed[:, None] / dim_t
	pos_y = y_embed[:, None] / dim_t
	pos_x = torch.stack(
	(pos_x[:, 0::2].sin(), pos_x[:, 1::2].cos()), dim=2
	).flatten(1)
	pos_y = torch.stack(
	(pos_y[:, 0::2].sin(), pos_y[:, 1::2].cos()), dim=2
	).flatten(1)
	return pos_x, pos_y

	@torch.no_grad()
	def encode_boxes(self, x, y, w, h):
	pos_x, pos_y = self._encode_xy(x, y)
	pos = torch.cat((pos_y, pos_x, h[:, None], w[:, None]), dim=1)
	return pos

	encode = encode_boxes # Backwards compatibility

	@torch.no_grad()
	def encode_points(self, x, y, labels):
	(bx, nx), (by, ny), (bl, nl) = x.shape, y.shape, labels.shape
	assert bx == by and nx == ny and bx == bl and nx == nl
	pos_x, pos_y = self._encode_xy(x.flatten(), y.flatten())
	pos_x, pos_y = pos_x.reshape(bx, nx, -1), pos_y.reshape(by, ny, -1)
	pos = torch.cat((pos_y, pos_x, labels[:, :, None]), dim=2)
	return pos

	@torch.no_grad()
	def _pe(self, B, device, *cache_key):
	H, W = cache_key
	if cache_key in self.cache:
	return self.cache[cache_key].to(device)[None].repeat(B, 1, 1, 1)

	y_embed = (
	torch.arange(1, H + 1, dtype=torch.float32, device=device)
	.view(1, -1, 1)
	.repeat(B, 1, W)
	)
	x_embed = (
	torch.arange(1, W + 1, dtype=torch.float32, device=device)
	.view(1, 1, -1)
	.repeat(B, H, 1)
	)

	if self.normalize:
	eps = 1e-6
	y_embed = y_embed / (y_embed[:, -1:, :] + eps) * self.scale
	x_embed = x_embed / (x_embed[:, :, -1:] + eps) * self.scale

	dim_t = torch.arange(self.num_pos_feats, dtype=torch.float32, device=device)
	dim_t = self.temperature ** (2 * (dim_t // 2) / self.num_pos_feats)

	pos_x = x_embed[:, :, :, None] / dim_t
	pos_y = y_embed[:, :, :, None] / dim_t
	pos_x = torch.stack(
	(pos_x[:, :, :, 0::2].sin(), pos_x[:, :, :, 1::2].cos()), dim=4
	).flatten(3)
	pos_y = torch.stack(
	(pos_y[:, :, :, 0::2].sin(), pos_y[:, :, :, 1::2].cos()), dim=4
	).flatten(3)
	pos = torch.cat((pos_y, pos_x), dim=3).permute(0, 3, 1, 2)
	self.cache[cache_key] = pos[0]
	return pos

	@torch.no_grad()
	def forward(self, x: torch.Tensor):
	B = x.shape[0]
	cache_key = (x.shape[-2], x.shape[-1])
	return self._pe(B, x.device, *cache_key)


	class PositionEmbeddingRandom(nn.Module):
	"""
	Positional encoding using random spatial frequencies.
	"""

	def __init__(self, num_pos_feats: int = 64, scale: Optional[float] = None) -> None:
	super().__init__()
	if scale is None or scale <= 0.0:
	scale = 1.0
	self.register_buffer(
	"positional_encoding_gaussian_matrix",
	scale * torch.randn((2, num_pos_feats)),
	)

	def _pe_encoding(self, coords: torch.Tensor) -> torch.Tensor:
	"""Positionally encode points that are normalized to [0,1]."""
	# assuming coords are in [0, 1]^2 square and have d_1 x ... x d_n x 2 shape
	coords = 2 * coords - 1
	coords = coords @ self.positional_encoding_gaussian_matrix
	coords = 2 * np.pi * coords
	# outputs d_1 x ... x d_n x C shape
	return torch.cat([torch.sin(coords), torch.cos(coords)], dim=-1)

	def forward(self, size: Tuple[int, int]) -> torch.Tensor:
	"""Generate positional encoding for a grid of the specified size."""
	h, w = size
	device: Any = self.positional_encoding_gaussian_matrix.device
	grid = torch.ones((h, w), device=device, dtype=torch.float32)
	y_embed = grid.cumsum(dim=0) - 0.5
	x_embed = grid.cumsum(dim=1) - 0.5
	y_embed = y_embed / h
	x_embed = x_embed / w

	pe = self._pe_encoding(torch.stack([x_embed, y_embed], dim=-1))
	return pe.permute(2, 0, 1) # C x H x W

	def forward_with_coords(
	self, coords_input: torch.Tensor, image_size: Tuple[int, int]
	) -> torch.Tensor:
	"""Positionally encode points that are not normalized to [0,1]."""
	coords = coords_input.clone()
	coords[:, :, 0] = coords[:, :, 0] / image_size[1]
	coords[:, :, 1] = coords[:, :, 1] / image_size[0]
	return self._pe_encoding(coords.to(torch.float)) # B x N x C


	# Rotary Positional Encoding, adapted from:
	# 1. https://github.com/meta-llama/codellama/blob/main/llama/model.py
	# 2. https://github.com/naver-ai/rope-vit
	# 3. https://github.com/lucidrains/rotary-embedding-torch


	def init_t_xy(end_x: int, end_y: int):
	t = torch.arange(end_x * end_y, dtype=torch.float32)
	t_x = (t % end_x).float()
	t_y = torch.div(t, end_x, rounding_mode="floor").float()
	return t_x, t_y


	def compute_axial_cis(dim: int, end_x: int, end_y: int, theta: float = 10000.0):
	freqs_x = 1.0 / (theta ** (torch.arange(0, dim, 4)[: (dim // 4)].float() / dim))
	freqs_y = 1.0 / (theta ** (torch.arange(0, dim, 4)[: (dim // 4)].float() / dim))

	t_x, t_y = init_t_xy(end_x, end_y)
	freqs_x = torch.outer(t_x, freqs_x)
	freqs_y = torch.outer(t_y, freqs_y)
	freqs_cis_x = torch.polar(torch.ones_like(freqs_x), freqs_x)
	freqs_cis_y = torch.polar(torch.ones_like(freqs_y), freqs_y)
	return torch.cat([freqs_cis_x, freqs_cis_y], dim=-1)


	def reshape_for_broadcast(freqs_cis: torch.Tensor, x: torch.Tensor):
	ndim = x.ndim
	assert 0 <= 1 < ndim
	assert freqs_cis.shape == (x.shape[-2], x.shape[-1])
	shape = [d if i >= ndim - 2 else 1 for i, d in enumerate(x.shape)]
	return freqs_cis.view(*shape)


	def apply_rotary_enc(
	xq: torch.Tensor,
	xk: torch.Tensor,
	freqs_cis: torch.Tensor,
	repeat_freqs_k: bool = False,
	):
	xq_ = torch.view_as_complex(xq.float().reshape(*xq.shape[:-1], -1, 2))
	xk_ = (
	torch.view_as_complex(xk.float().reshape(*xk.shape[:-1], -1, 2))
	if xk.shape[-2] != 0
	else None
	)
	freqs_cis = reshape_for_broadcast(freqs_cis, xq_)
	xq_out = torch.view_as_real(xq_ * freqs_cis).flatten(3)
	if xk_ is None:
	# no keys to rotate, due to dropout
	return xq_out.type_as(xq).to(xq.device), xk
	# repeat freqs along seq_len dim to match k seq_len
	if repeat_freqs_k:
	r = xk_.shape[-2] // xq_.shape[-2]
	if freqs_cis.is_cuda:
	freqs_cis = freqs_cis.repeat(([1] (freqs_cis.ndim - 2)), r, 1)
	else:
	# torch.repeat on complex numbers may not be supported on non-CUDA devices
	# (freqs_cis has 4 dims and we repeat on dim 2) so we use expand + flatten
	freqs_cis = freqs_cis.unsqueeze(2).expand(-1, -1, r, -1, -1).flatten(2, 3)
	xk_out = torch.view_as_real(xk_ * freqs_cis).flatten(3)
	return xq_out.type_as(xq).to(xq.device), xk_out.type_as(xk).to(xk.device)