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from typing import Optional, Tuple, List
import math

import torch
from torch import Tensor
from torch.nn import Linear, Module
from torch.nn import functional as F
from torch.nn.init import constant_, xavier_normal_, xavier_uniform_
from torch.nn.modules.linear import NonDynamicallyQuantizableLinear
from torch.nn.parameter import Parameter

def _in_projection_packed(
    q: Tensor,
    k: Tensor,
    v: Tensor,
    w: Tensor,
    b: Optional[Tensor] = None,
) -> List[Tensor]:
    r"""
    Performs the in-projection step of the attention operation, using packed weights.
    Output is a triple containing projection tensors for query, key and value.

    Args:
        q, k, v: query, key and value tensors to be projected. For self-attention,
            these are typically the same tensor; for encoder-decoder attention,
            k and v are typically the same tensor. (We take advantage of these
            identities for performance if they are present.) Regardless, q, k and v
            must share a common embedding dimension; otherwise their shapes may vary.
        w: projection weights for q, k and v, packed into a single tensor. Weights
            are packed along dimension 0, in q, k, v order.
        b: optional projection biases for q, k and v, packed into a single tensor
            in q, k, v order.

    Shape:
        Inputs:
        - q: :math:`(..., E)` where E is the embedding dimension
        - k: :math:`(..., E)` where E is the embedding dimension
        - v: :math:`(..., E)` where E is the embedding dimension
        - w: :math:`(E * 3, E)` where E is the embedding dimension
        - b: :math:`E * 3` where E is the embedding dimension

        Output:
        - in output list :math:`[q', k', v']`, each output tensor will have the
            same shape as the corresponding input tensor.
    """
    E = q.size(-1)
    if k is v:
        if q is k:
            # self-attention
            return F.linear(q, w, b).chunk(3, dim=-1)
        else:
            # encoder-decoder attention
            w_q, w_kv = w.split([E, E * 2])
            if b is None:
                b_q = b_kv = None
            else:
                b_q, b_kv = b.split([E, E * 2])
            return (F.linear(q, w_q, b_q),) + F.linear(k, w_kv, b_kv).chunk(2, dim=-1)
    else:
        w_q, w_k, w_v = w.chunk(3)
        if b is None:
            b_q = b_k = b_v = None
        else:
            b_q, b_k, b_v = b.chunk(3)
        return F.linear(q, w_q, b_q), F.linear(k, w_k, b_k), F.linear(v, w_v, b_v)

def _scaled_dot_product_attention(
    q: Tensor,
    k: Tensor,
    v: Tensor,
    attn_mask: Optional[Tensor] = None,
    dropout_p: float = 0.0,
) -> Tuple[Tensor, Tensor]:
    r"""
    Computes scaled dot product attention on query, key and value tensors, using
    an optional attention mask if passed, and applying dropout if a probability
    greater than 0.0 is specified.
    Returns a tensor pair containing attended values and attention weights.

    Args:
        q, k, v: query, key and value tensors. See Shape section for shape details.
        attn_mask: optional tensor containing mask values to be added to calculated
            attention. May be 2D or 3D; see Shape section for details.
        dropout_p: dropout probability. If greater than 0.0, dropout is applied.

    Shape:
        - q: :math:`(B, Nt, E)` where B is batch size, Nt is the target sequence length,
            and E is embedding dimension.
        - key: :math:`(B, Ns, E)` where B is batch size, Ns is the source sequence length,
            and E is embedding dimension.
        - value: :math:`(B, Ns, E)` where B is batch size, Ns is the source sequence length,
            and E is embedding dimension.
        - attn_mask: either a 3D tensor of shape :math:`(B, Nt, Ns)` or a 2D tensor of
            shape :math:`(Nt, Ns)`.

        - Output: attention values have shape :math:`(B, Nt, E)`; attention weights
            have shape :math:`(B, Nt, Ns)`
    """
    B, Nt, E = q.shape
    q = q / math.sqrt(E)
    # (B, Nt, E) x (B, E, Ns) -> (B, Nt, Ns)
    if attn_mask is not None:
        attn = torch.baddbmm(attn_mask, q, k.transpose(-2, -1))
    else:
        attn = torch.bmm(q, k.transpose(-2, -1))

    attn = F.softmax(attn, dim=-1)
    if dropout_p > 0.0:
        attn = F.dropout(attn, p=dropout_p)
    # (B, Nt, Ns) x (B, Ns, E) -> (B, Nt, E)
    output = torch.bmm(attn, v)
    return output, attn

def multi_head_attention_forward(
        x,
        ipw,
        ipb,
        opw,
        opb,
        n_head,
        attn_mask,
        past_kv=None,
        use_cache=False,
):
    # x = x.transpose(1, 0)
    # tgt_len, bsz, embed_dim = x.shape
    # head_dim = embed_dim // n_head
    # q, k, v = _in_projection_packed(x, x, x, ipw, ipb)
    # q = q.contiguous().view(tgt_len, bsz * n_head, head_dim).transpose(0, 1)
    # k = k.contiguous().view(k.shape[0], bsz * n_head, head_dim).transpose(0, 1)
    # v = v.contiguous().view(v.shape[0], bsz * n_head, head_dim).transpose(0, 1)

    # new_attn_mask = torch.zeros_like(attn_mask, dtype=q.dtype)
    # new_attn_mask.masked_fill_(attn_mask, float("-inf"))
    # attn_mask = new_attn_mask
    #
    # attn_output, attn_output_weights = _scaled_dot_product_attention(q, k, v, attn_mask, 0.0)
    # attn_output = attn_output.transpose(0, 1).contiguous().view(tgt_len * bsz, embed_dim)
    # attn_output = torch._C._nn.linear(attn_output, opw, opb)
    # attn_output = attn_output.view(tgt_len, bsz, attn_output.size(1))

    B, T, C = x.size()

    q, k, v = torch._C._nn.linear(x, ipw, ipb).chunk(3, dim=-1)
    k = k.view(B, T, n_head, C // n_head).transpose(1, 2)  # (B, nh, T, hs)
    q = q.view(B, T, n_head, C // n_head).transpose(1, 2)  # (B, nh, T, hs)
    v = v.view(B, T, n_head, C // n_head).transpose(1, 2)  # (B, nh, T, hs)
    if past_kv is not None:
        past_key = past_kv[0]
        past_value = past_kv[1]
        k = torch.cat((past_key, k), dim=-2)
        v = torch.cat((past_value, v), dim=-2)

    FULL_T = k.shape[-2]

    if use_cache is True:
        present = (k, v)
    else:
        present = None

    att = (q @ k.transpose(-2, -1)) * (1.0 / math.sqrt(k.size(-1)))
    att = att.masked_fill(attn_mask[FULL_T - T:FULL_T, :FULL_T], float('-inf'))
    att = F.softmax(att, dim=-1)
    y = att @ v  # (B, nh, T, T) x (B, nh, T, hs) -> (B, nh, T, hs)
    y = y.transpose(1, 2).contiguous().view(B, T, C)  # re-assemble all head outputs side by side
    y = torch._C._nn.linear(y, opw, opb)
    return (y, present)


class MultiheadAttention(Module):
    r"""Allows the model to jointly attend to information
    from different representation subspaces as described in the paper:
    `Attention Is All You Need <https://arxiv.org/abs/1706.03762>`_.

    Multi-Head Attention is defined as:

    .. math::
        \text{MultiHead}(Q, K, V) = \text{Concat}(head_1,\dots,head_h)W^O

    where :math:`head_i = \text{Attention}(QW_i^Q, KW_i^K, VW_i^V)`.

    ``forward()`` will use a special optimized implementation if all of the following
    conditions are met:

    - self attention is being computed (i.e., ``query``, ``key``, and ``value`` are the same tensor. This
      restriction will be loosened in the future.)
    - Either autograd is disabled (using ``torch.inference_mode`` or ``torch.no_grad``) or no tensor argument ``requires_grad``
    - training is disabled (using ``.eval()``)
    - dropout is 0
    - ``add_bias_kv`` is ``False``
    - ``add_zero_attn`` is ``False``
    - ``batch_first`` is ``True`` and the input is batched
    - ``kdim`` and ``vdim`` are equal to ``embed_dim``
    - at most one of ``key_padding_mask`` or ``attn_mask`` is passed
    - if a `NestedTensor <https://pytorch.org/docs/stable/nested.html>`_ is passed, neither ``key_padding_mask``
      nor ``attn_mask`` is passed

    If the optimized implementation is in use, a
    `NestedTensor <https://pytorch.org/docs/stable/nested.html>`_ can be passed for
    ``query``/``key``/``value`` to represent padding more efficiently than using a
    padding mask. In this case, a `NestedTensor <https://pytorch.org/docs/stable/nested.html>`_
    will be returned, and an additional speedup proportional to the fraction of the input
    that is padding can be expected.

    Args:
        embed_dim: Total dimension of the model.
        num_heads: Number of parallel attention heads. Note that ``embed_dim`` will be split
            across ``num_heads`` (i.e. each head will have dimension ``embed_dim // num_heads``).
        dropout: Dropout probability on ``attn_output_weights``. Default: ``0.0`` (no dropout).
        bias: If specified, adds bias to input / output projection layers. Default: ``True``.
        add_bias_kv: If specified, adds bias to the key and value sequences at dim=0. Default: ``False``.
        add_zero_attn: If specified, adds a new batch of zeros to the key and value sequences at dim=1.
            Default: ``False``.
        kdim: Total number of features for keys. Default: ``None`` (uses ``kdim=embed_dim``).
        vdim: Total number of features for values. Default: ``None`` (uses ``vdim=embed_dim``).
        batch_first: If ``True``, then the input and output tensors are provided
            as (batch, seq, feature). Default: ``False`` (seq, batch, feature).

    Examples::

        >>> # xdoctest: +SKIP
        >>> multihead_attn = nn.MultiheadAttention(embed_dim, num_heads)
        >>> attn_output, attn_output_weights = multihead_attn(query, key, value)

    """
    __constants__ = ["batch_first"]
    bias_k: Optional[torch.Tensor]
    bias_v: Optional[torch.Tensor]

    def __init__(
            self,
            embed_dim,
            num_heads,
            dropout=0.0,
            bias=True,
            add_bias_kv=False,
            add_zero_attn=False,
            kdim=None,
            vdim=None,
            batch_first=False,
            linear1_cls=Linear,
            linear2_cls=Linear,
            device=None,
            dtype=None,
    ) -> None:
        factory_kwargs = {"device": device, "dtype": dtype}
        super(MultiheadAttention, self).__init__()
        self.embed_dim = embed_dim
        self.kdim = kdim if kdim is not None else embed_dim
        self.vdim = vdim if vdim is not None else embed_dim
        self._qkv_same_embed_dim = (
                self.kdim == embed_dim and self.vdim == embed_dim
        )

        self.num_heads = num_heads
        self.dropout = dropout
        self.batch_first = batch_first
        self.head_dim = embed_dim // num_heads
        assert (
                self.head_dim * num_heads == self.embed_dim
        ), "embed_dim must be divisible by num_heads"

        if add_bias_kv:
            self.bias_k = Parameter(
                torch.empty((1, 1, embed_dim), **factory_kwargs)
            )
            self.bias_v = Parameter(
                torch.empty((1, 1, embed_dim), **factory_kwargs)
            )
        else:
            self.bias_k = self.bias_v = None

        if linear1_cls == Linear:
            if not self._qkv_same_embed_dim:
                self.q_proj_weight = Parameter(
                    torch.empty((embed_dim, embed_dim), **factory_kwargs)
                )
                self.k_proj_weight = Parameter(
                    torch.empty((embed_dim, self.kdim), **factory_kwargs)
                )
                self.v_proj_weight = Parameter(
                    torch.empty((embed_dim, self.vdim), **factory_kwargs)
                )
                self.register_parameter("in_proj_weight", None)
            else:
                self.in_proj_weight = Parameter(
                    torch.empty((3 * embed_dim, embed_dim), **factory_kwargs)
                )
                self.register_parameter("q_proj_weight", None)
                self.register_parameter("k_proj_weight", None)
                self.register_parameter("v_proj_weight", None)

            if bias:
                self.in_proj_bias = Parameter(
                    torch.empty(3 * embed_dim, **factory_kwargs)
                )
            else:
                self.register_parameter("in_proj_bias", None)
            self.out_proj = NonDynamicallyQuantizableLinear(
                embed_dim, embed_dim, bias=bias, **factory_kwargs
            )

            self._reset_parameters()
        else:
            if not self._qkv_same_embed_dim:
                raise NotImplementedError
            else:
                self.in_proj_linear = linear1_cls(
                    embed_dim, 3 * embed_dim, bias=bias, **factory_kwargs
                )
                self.in_proj_weight = self.in_proj_linear.weight

                self.register_parameter("q_proj_weight", None)
                self.register_parameter("k_proj_weight", None)
                self.register_parameter("v_proj_weight", None)

                if bias:
                    self.in_proj_bias = self.in_proj_linear.bias
                else:
                    self.register_parameter("in_proj_bias", None)

            self.out_proj = linear2_cls(
                embed_dim, embed_dim, bias=bias, **factory_kwargs
            )

            if self.bias_k is not None:
                xavier_normal_(self.bias_k)
            if self.bias_v is not None:
                xavier_normal_(self.bias_v)

        self.add_zero_attn = add_zero_attn

    def _reset_parameters(self):
        if self._qkv_same_embed_dim:
            xavier_uniform_(self.in_proj_weight)
        else:
            xavier_uniform_(self.q_proj_weight)
            xavier_uniform_(self.k_proj_weight)
            xavier_uniform_(self.v_proj_weight)

        if self.in_proj_bias is not None:
            constant_(self.in_proj_bias, 0.0)
            constant_(self.out_proj.bias, 0.0)

        if self.bias_k is not None:
            xavier_normal_(self.bias_k)
        if self.bias_v is not None:
            xavier_normal_(self.bias_v)

    def __setstate__(self, state):
        # Support loading old MultiheadAttention checkpoints generated by v1.1.0
        if "_qkv_same_embed_dim" not in state:
            state["_qkv_same_embed_dim"] = True

        super(MultiheadAttention, self).__setstate__(state)

    def forward(
            self,
            query: Tensor,
            key: Tensor,
            value: Tensor,
            key_padding_mask: Optional[Tensor] = None,
            need_weights: bool = True,
            attn_mask: Optional[Tensor] = None,
            average_attn_weights: bool = True,
    ) -> Tuple[Tensor, Optional[Tensor]]:
        r"""
        Args:
            query: Query embeddings of shape :math:`(L, E_q)` for unbatched input, :math:`(L, N, E_q)` when ``batch_first=False``
                or :math:`(N, L, E_q)` when ``batch_first=True``, where :math:`L` is the target sequence length,
                :math:`N` is the batch size, and :math:`E_q` is the query embedding dimension ``embed_dim``.
                Queries are compared against key-value pairs to produce the output.
                See "Attention Is All You Need" for more details.
            key: Key embeddings of shape :math:`(S, E_k)` for unbatched input, :math:`(S, N, E_k)` when ``batch_first=False``
                or :math:`(N, S, E_k)` when ``batch_first=True``, where :math:`S` is the source sequence length,
                :math:`N` is the batch size, and :math:`E_k` is the key embedding dimension ``kdim``.
                See "Attention Is All You Need" for more details.
            value: Value embeddings of shape :math:`(S, E_v)` for unbatched input, :math:`(S, N, E_v)` when
                ``batch_first=False`` or :math:`(N, S, E_v)` when ``batch_first=True``, where :math:`S` is the source
                sequence length, :math:`N` is the batch size, and :math:`E_v` is the value embedding dimension ``vdim``.
                See "Attention Is All You Need" for more details.
            key_padding_mask: If specified, a mask of shape :math:`(N, S)` indicating which elements within ``key``
                to ignore for the purpose of attention (i.e. treat as "padding"). For unbatched `query`, shape should be :math:`(S)`.
                Binary and byte masks are supported.
                For a binary mask, a ``True`` value indicates that the corresponding ``key`` value will be ignored for
                the purpose of attention. For a float mask, it will be directly added to the corresponding ``key`` value.
            need_weights: If specified, returns ``attn_output_weights`` in addition to ``attn_outputs``.
                Default: ``True``.
            attn_mask: If specified, a 2D or 3D mask preventing attention to certain positions. Must be of shape
                :math:`(L, S)` or :math:`(N\cdot\text{num\_heads}, L, S)`, where :math:`N` is the batch size,
                :math:`L` is the target sequence length, and :math:`S` is the source sequence length. A 2D mask will be
                broadcasted across the batch while a 3D mask allows for a different mask for each entry in the batch.
                Binary, byte, and float masks are supported. For a binary mask, a ``True`` value indicates that the
                corresponding position is not allowed to attend. For a byte mask, a non-zero value indicates that the
                corresponding position is not allowed to attend. For a float mask, the mask values will be added to
                the attention weight.
            average_attn_weights: If true, indicates that the returned ``attn_weights`` should be averaged across
                heads. Otherwise, ``attn_weights`` are provided separately per head. Note that this flag only has an
                effect when ``need_weights=True``. Default: ``True`` (i.e. average weights across heads)

        Outputs:
            - **attn_output** - Attention outputs of shape :math:`(L, E)` when input is unbatched,
              :math:`(L, N, E)` when ``batch_first=False`` or :math:`(N, L, E)` when ``batch_first=True``,
              where :math:`L` is the target sequence length, :math:`N` is the batch size, and :math:`E` is the
              embedding dimension ``embed_dim``.
            - **attn_output_weights** - Only returned when ``need_weights=True``. If ``average_attn_weights=True``,
              returns attention weights averaged across heads of shape :math:`(L, S)` when input is unbatched or
              :math:`(N, L, S)`, where :math:`N` is the batch size, :math:`L` is the target sequence length, and
              :math:`S` is the source sequence length. If ``average_attn_weights=False``, returns attention weights per
              head of shape :math:`(\text{num\_heads}, L, S)` when input is unbatched or :math:`(N, \text{num\_heads}, L, S)`.

            .. note::
                `batch_first` argument is ignored for unbatched inputs.
        """
        is_batched = query.dim() == 3
        if key_padding_mask is not None:
            _kpm_dtype = key_padding_mask.dtype
            if _kpm_dtype != torch.bool and not torch.is_floating_point(
                    key_padding_mask
            ):
                raise AssertionError(
                    "only bool and floating types of key_padding_mask are supported"
                )
        why_not_fast_path = ""
        if not is_batched:
            why_not_fast_path = f"input not batched; expected query.dim() of 3 but got {query.dim()}"
        elif query is not key or key is not value:
            # When lifting this restriction, don't forget to either
            # enforce that the dtypes all match or test cases where
            # they don't!
            why_not_fast_path = "non-self attention was used (query, key, and value are not the same Tensor)"
        elif (
                self.in_proj_bias is not None
                and query.dtype != self.in_proj_bias.dtype
        ):
            why_not_fast_path = f"dtypes of query ({query.dtype}) and self.in_proj_bias ({self.in_proj_bias.dtype}) don't match"
        elif (
                self.in_proj_weight is not None
                and query.dtype != self.in_proj_weight.dtype
        ):
            # this case will fail anyway, but at least they'll get a useful error message.
            why_not_fast_path = f"dtypes of query ({query.dtype}) and self.in_proj_weight ({self.in_proj_weight.dtype}) don't match"
        elif self.training:
            why_not_fast_path = "training is enabled"
        elif not self.batch_first:
            why_not_fast_path = "batch_first was not True"
        elif self.bias_k is not None:
            why_not_fast_path = "self.bias_k was not None"
        elif self.bias_v is not None:
            why_not_fast_path = "self.bias_v was not None"
        elif self.dropout:
            why_not_fast_path = f"dropout was {self.dropout}, required zero"
        elif self.add_zero_attn:
            why_not_fast_path = "add_zero_attn was enabled"
        elif not self._qkv_same_embed_dim:
            why_not_fast_path = "_qkv_same_embed_dim was not True"
        elif attn_mask is not None:
            why_not_fast_path = "attn_mask was not None"
        elif query.is_nested and key_padding_mask is not None:
            why_not_fast_path = (
                "key_padding_mask is not supported with NestedTensor input"
            )
        elif self.num_heads % 2 == 1:
            why_not_fast_path = "num_heads is odd"
        elif torch.is_autocast_enabled():
            why_not_fast_path = "autocast is enabled"

        if not why_not_fast_path:
            tensor_args = (
                query,
                key,
                value,
                self.in_proj_weight,
                self.in_proj_bias,
                self.out_proj.weight,
                self.out_proj.bias,
            )
            # We have to use list comprehensions below because TorchScript does not support
            # generator expressions.
            if torch.overrides.has_torch_function(tensor_args):
                why_not_fast_path = "some Tensor argument has_torch_function"
            elif not all(
                    [
                        (x is None or x.is_cuda or "cpu" in str(x.device))
                        for x in tensor_args
                    ]
            ):
                why_not_fast_path = (
                    "some Tensor argument is neither CUDA nor CPU"
                )
            elif torch.is_grad_enabled() and any(
                    [x is not None and x.requires_grad for x in tensor_args]
            ):
                why_not_fast_path = (
                    "grad is enabled and at least one of query or the "
                    "input/output projection weights or biases requires_grad"
                )
            if not why_not_fast_path:
                return torch._native_multi_head_attention(
                    query,
                    key,
                    value,
                    self.embed_dim,
                    self.num_heads,
                    self.in_proj_weight,
                    self.in_proj_bias,
                    self.out_proj.weight,
                    self.out_proj.bias,
                    key_padding_mask
                    if key_padding_mask is not None
                    else attn_mask,
                    need_weights,
                    average_attn_weights,
                    1
                    if key_padding_mask is not None
                    else 0
                    if attn_mask is not None
                    else None,
                )

        any_nested = query.is_nested or key.is_nested or value.is_nested
        assert not any_nested, (
                "MultiheadAttention does not support NestedTensor outside of its fast path. "
                + f"The fast path was not hit because {why_not_fast_path}"
        )

        if self.batch_first and is_batched:
            # make sure that the transpose op does not affect the "is" property
            if key is value:
                if query is key:
                    query = key = value = query.transpose(1, 0)
                else:
                    query, key = [x.transpose(1, 0) for x in (query, key)]
                    value = key
            else:
                query, key, value = [
                    x.transpose(1, 0) for x in (query, key, value)
                ]

        if not self._qkv_same_embed_dim:
            attn_output, attn_output_weights = F.multi_head_attention_forward(
                query,
                key,
                value,
                self.embed_dim,
                self.num_heads,
                self.in_proj_weight,
                self.in_proj_bias,
                self.bias_k,
                self.bias_v,
                self.add_zero_attn,
                self.dropout,
                self.out_proj.weight,
                self.out_proj.bias,
                training=self.training,
                key_padding_mask=key_padding_mask,
                need_weights=need_weights,
                attn_mask=attn_mask,
                use_separate_proj_weight=True,
                q_proj_weight=self.q_proj_weight,
                k_proj_weight=self.k_proj_weight,
                v_proj_weight=self.v_proj_weight,
                average_attn_weights=average_attn_weights,
            )
        else:
            attn_output, attn_output_weights = F.multi_head_attention_forward(
                query,
                key,
                value,
                self.embed_dim,
                self.num_heads,
                self.in_proj_weight,
                self.in_proj_bias,
                self.bias_k,
                self.bias_v,
                self.add_zero_attn,
                self.dropout,
                self.out_proj.weight,
                self.out_proj.bias,
                training=self.training,
                key_padding_mask=key_padding_mask,
                need_weights=need_weights,
                attn_mask=attn_mask,
                average_attn_weights=average_attn_weights,
            )
        if self.batch_first and is_batched:
            return attn_output.transpose(1, 0), attn_output_weights
        else:
            return attn_output, attn_output_weights

    def infer(self,
              x: Tensor,
              key_padding_mask: Optional[Tensor] = None,
              need_weights: bool = True,
              attn_mask: Optional[Tensor] = None,
              average_attn_weights: bool = True,
              past_kv = None,
              use_cache = False
              ):
        # x = x.transpose(1, 0)
        y, kv = multi_head_attention_forward(
                x=x,
                ipw=self.in_proj_weight,
                ipb=self.in_proj_bias,
                opw=self.out_proj.weight,
                opb=self.out_proj.bias,
                n_head=self.num_heads,
                attn_mask=attn_mask,
                past_kv=past_kv,
                use_cache=use_cache,
        )
        return (y, kv)