selective_scan_interface.py

# Copyright (c) 2023, Tri Dao, Albert Gu.

import torch
import torch.nn.functional as F
from torch.cuda.amp import custom_bwd, custom_fwd

from einops import rearrange, repeat

from causal_conv1d import causal_conv1d_fn
import causal_conv1d_cuda
import selective_scan_cuda


class SelectiveScanFn(torch.autograd.Function):

    @staticmethod
    def forward(ctx, u, delta, A, B, C, D=None, z=None, delta_bias=None, delta_softplus=False,
                return_last_state=False):
        if u.stride(-1) != 1:
            u = u.contiguous()
        if delta.stride(-1) != 1:
            delta = delta.contiguous()
        if D is not None:
            D = D.contiguous()
        if B.stride(-1) != 1:
            B = B.contiguous()
        if C.stride(-1) != 1:
            C = C.contiguous()
        if z is not None and z.stride(-1) != 1:
            z = z.contiguous()
        if B.dim() == 3:
            B = rearrange(B, "b dstate l -> b 1 dstate l")
            ctx.squeeze_B = True
        if C.dim() == 3:
            C = rearrange(C, "b dstate l -> b 1 dstate l")
            ctx.squeeze_C = True
        out, x, *rest = selective_scan_cuda.fwd(u, delta, A, B, C, D, z, delta_bias, delta_softplus)
        ctx.delta_softplus = delta_softplus
        ctx.has_z = z is not None
        last_state = x[:, :, -1, 1::2]  # (batch, dim, dstate)
        if not ctx.has_z:
            ctx.save_for_backward(u, delta, A, B, C, D, delta_bias, x)
            return out if not return_last_state else (out, last_state)
        else:
            ctx.save_for_backward(u, delta, A, B, C, D, z, delta_bias, x, out)
            out_z = rest[0]
            return out_z if not return_last_state else (out_z, last_state)

    @staticmethod
    def backward(ctx, dout, *args):
        if not ctx.has_z:
            u, delta, A, B, C, D, delta_bias, x = ctx.saved_tensors
            z = None
            out = None
        else:
            u, delta, A, B, C, D, z, delta_bias, x, out = ctx.saved_tensors
        if dout.stride(-1) != 1:
            dout = dout.contiguous()
        # The kernel supports passing in a pre-allocated dz (e.g., in case we want to fuse the
        # backward of selective_scan_cuda with the backward of chunk).
        # Here we just pass in None and dz will be allocated in the C++ code.
        du, ddelta, dA, dB, dC, dD, ddelta_bias, *rest = selective_scan_cuda.bwd(
            u, delta, A, B, C, D, z, delta_bias, dout, x, out, None, ctx.delta_softplus,
            False  # option to recompute out_z, not used here
        )
        dz = rest[0] if ctx.has_z else None
        dB = dB.squeeze(1) if getattr(ctx, "squeeze_B", False) else dB
        dC = dC.squeeze(1) if getattr(ctx, "squeeze_C", False) else dC
        return (du, ddelta, dA, dB, dC,
                dD if D is not None else None,
                dz,
                ddelta_bias if delta_bias is not None else None,
                None,
                None)


def selective_scan_fn(u, delta, A, B, C, D=None, z=None, delta_bias=None, delta_softplus=False,
                     return_last_state=False):
    """if return_last_state is True, returns (out, last_state)
    last_state has shape (batch, dim, dstate). Note that the gradient of the last state is
    not considered in the backward pass.
    """
    return SelectiveScanFn.apply(u, delta, A, B, C, D, z, delta_bias, delta_softplus, return_last_state)


def selective_scan_ref(u, delta, A, B, C, D=None, z=None, delta_bias=None, delta_softplus=False,
                      return_last_state=False):
    """
    u: r(B D L)
    delta: r(B D L)
    A: c(D N) or r(D N)
    B: c(D N) or r(B N L) or r(B N 2L) or r(B G N L) or (B G N L)
    C: c(D N) or r(B N L) or r(B N 2L) or r(B G N L) or (B G N L)
    D: r(D)
    z: r(B D L)
    delta_bias: r(D), fp32

    out: r(B D L)
    last_state (optional): r(B D dstate) or c(B D dstate)
    """
    dtype_in = u.dtype
    u = u.float()
    delta = delta.float()
    if delta_bias is not None:
        delta = delta + delta_bias[..., None].float()
    if delta_softplus:
        delta = F.softplus(delta)
    batch, dim, dstate = u.shape[0], A.shape[0], A.shape[1]
    is_variable_B = B.dim() >= 3
    is_variable_C = C.dim() >= 3
    if A.is_complex():
        if is_variable_B:
            B = torch.view_as_complex(rearrange(B.float(), "... (L two) -> ... L two", two=2))
        if is_variable_C:
            C = torch.view_as_complex(rearrange(C.float(), "... (L two) -> ... L two", two=2))
    else:
        B = B.float()
        C = C.float()
    x = A.new_zeros((batch, dim, dstate))
    ys = []
    deltaA = torch.exp(torch.einsum('bdl,dn->bdln', delta, A))
    if not is_variable_B:
        deltaB_u = torch.einsum('bdl,dn,bdl->bdln', delta, B, u)
    else:
        if B.dim() == 3:
            deltaB_u = torch.einsum('bdl,bnl,bdl->bdln', delta, B, u)
        else:
            B = repeat(B, "B G N L -> B (G H) N L", H=dim // B.shape[1])
            deltaB_u = torch.einsum('bdl,bdnl,bdl->bdln', delta, B, u)
    if is_variable_C and C.dim() == 4:
        C = repeat(C, "B G N L -> B (G H) N L", H=dim // C.shape[1])
    last_state = None
    for i in range(u.shape[2]):
        x = deltaA[:, :, i] * x + deltaB_u[:, :, i]
        if not is_variable_C:
            y = torch.einsum('bdn,dn->bd', x, C)
        else:
            if C.dim() == 3:
                y = torch.einsum('bdn,bn->bd', x, C[:, :, i])
            else:
                y = torch.einsum('bdn,bdn->bd', x, C[:, :, :, i])
        if i == u.shape[2] - 1:
            last_state = x
        if y.is_complex():
            y = y.real * 2
        ys.append(y)
    y = torch.stack(ys, dim=2) # (batch dim L)
    out = y if D is None else y + u * rearrange(D, "d -> d 1")
    if z is not None:
        out = out * F.silu(z)
    out = out.to(dtype=dtype_in)
    return out if not return_last_state else (out, last_state)


class MambaInnerFn(torch.autograd.Function):

    @staticmethod
    @custom_fwd
    def forward(ctx, xz, conv1d_weight, conv1d_bias, x_proj_weight, delta_proj_weight,
                out_proj_weight, out_proj_bias,
                A, B=None, C=None, D=None, delta_bias=None, B_proj_bias=None,
                C_proj_bias=None, delta_softplus=True, checkpoint_lvl=1):
        """
             xz: (batch, dim, seqlen)
        """
        assert checkpoint_lvl in [0, 1]
        L = xz.shape[-1]
        delta_rank = delta_proj_weight.shape[1]
        d_state = A.shape[-1] * (1 if not A.is_complex() else 2)
        if torch.is_autocast_enabled():
            x_proj_weight = x_proj_weight.to(dtype=torch.get_autocast_gpu_dtype())
            delta_proj_weight = delta_proj_weight.to(dtype=torch.get_autocast_gpu_dtype())
            out_proj_weight = out_proj_weight.to(dtype=torch.get_autocast_gpu_dtype())
            out_proj_bias = (out_proj_bias.to(dtype=torch.get_autocast_gpu_dtype())
                             if out_proj_bias is not None else None)
        if xz.stride(-1) != 1:
            xz = xz.contiguous()
        conv1d_weight = rearrange(conv1d_weight, "d 1 w -> d w")
        x, z = xz.chunk(2, dim=1)
        conv1d_bias = conv1d_bias.contiguous() if conv1d_bias is not None else None
        conv1d_out = causal_conv1d_cuda.causal_conv1d_fwd(x, conv1d_weight, conv1d_bias, True)
        # We're being very careful here about the layout, to avoid extra transposes.
        # We want delta to have d as the slowest moving dimension
        # and L as the fastest moving dimension, since those are what the ssm_scan kernel expects.
        x_dbl = F.linear(rearrange(conv1d_out, 'b d l -> (b l) d'), x_proj_weight)  # (bl d)
        delta = rearrange(delta_proj_weight @ x_dbl[:, :delta_rank].t(), "d (b l) -> b d l", l = L)
        ctx.is_variable_B = B is None
        ctx.is_variable_C = C is None
        ctx.B_proj_bias_is_None = B_proj_bias is None
        ctx.C_proj_bias_is_None = C_proj_bias is None
        if B is None:  # variable B
            B = x_dbl[:, delta_rank:delta_rank + d_state]  # (bl dstate)
            if B_proj_bias is not None:
                B = B + B_proj_bias.to(dtype=B.dtype)
            if not A.is_complex():
                # B = rearrange(B, "(b l) dstate -> b dstate l", l=L).contiguous()
                B = rearrange(B, "(b l) dstate -> b 1 dstate l", l=L).contiguous()
            else:
                B = rearrange(B, "(b l) (dstate two) -> b 1 dstate (l two)", l=L, two=2).contiguous()
        else:
            if B.stride(-1) != 1:
                B = B.contiguous()
        if C is None:  # variable C
            C = x_dbl[:, -d_state:]  # (bl dstate)
            if C_proj_bias is not None:
                C = C + C_proj_bias.to(dtype=C.dtype)
            if not A.is_complex():
                # C = rearrange(C, "(b l) dstate -> b dstate l", l=L).contiguous()
                C = rearrange(C, "(b l) dstate -> b 1 dstate l", l=L).contiguous()
            else:
                C = rearrange(C, "(b l) (dstate two) -> b 1 dstate (l two)", l=L, two=2).contiguous()
        else:
            if C.stride(-1) != 1:
                C = C.contiguous()
        if D is not None:
            D = D.contiguous()
        out, scan_intermediates, out_z = selective_scan_cuda.fwd(
            conv1d_out, delta, A, B, C, D, z, delta_bias, delta_softplus
        )
        ctx.delta_softplus = delta_softplus
        ctx.out_proj_bias_is_None = out_proj_bias is None
        ctx.checkpoint_lvl = checkpoint_lvl
        if checkpoint_lvl >= 1:  # Will recompute conv1d_out and delta in the backward pass
            conv1d_out, delta = None, None
        ctx.save_for_backward(xz, conv1d_weight, conv1d_bias, x_dbl, x_proj_weight,
                              delta_proj_weight, out_proj_weight, conv1d_out, delta,
                              A, B, C, D, delta_bias, scan_intermediates, out)
        return F.linear(rearrange(out_z, "b d l -> b l d"), out_proj_weight, out_proj_bias)

    @staticmethod
    @custom_bwd
    def backward(ctx, dout):
        # dout: (batch, seqlen, dim)
        (xz, conv1d_weight, conv1d_bias, x_dbl, x_proj_weight, delta_proj_weight, out_proj_weight,
         conv1d_out, delta, A, B, C, D, delta_bias, scan_intermediates, out) = ctx.saved_tensors
        L = xz.shape[-1]
        delta_rank = delta_proj_weight.shape[1]
        d_state = A.shape[-1] * (1 if not A.is_complex() else 2)
        x, z = xz.chunk(2, dim=1)
        if dout.stride(-1) != 1:
            dout = dout.contiguous()
        if ctx.checkpoint_lvl == 1:
            conv1d_out = causal_conv1d_cuda.causal_conv1d_fwd(x, conv1d_weight, conv1d_bias, True)
            delta = rearrange(delta_proj_weight @ x_dbl[:, :delta_rank].t(),
                              "d (b l) -> b d l", l = L)
        # The kernel supports passing in a pre-allocated dz (e.g., in case we want to fuse the
        # backward of selective_scan_cuda with the backward of chunk).
        dxz = torch.empty_like(xz)  # (batch, dim, seqlen)
        dx, dz = dxz.chunk(2, dim=1)
        dout = rearrange(dout, "b l e -> e (b l)")
        dout_y = rearrange(out_proj_weight.t() @ dout, "d (b l) -> b d l", l=L)
        dconv1d_out, ddelta, dA, dB, dC, dD, ddelta_bias, dz, out_z = selective_scan_cuda.bwd(
            conv1d_out, delta, A, B, C, D, z, delta_bias, dout_y, scan_intermediates, out, dz,
            ctx.delta_softplus,
            True  # option to recompute out_z
        )
        dout_proj_weight = torch.einsum("eB,dB->ed", dout, rearrange(out_z, "b d l -> d (b l)"))
        dout_proj_bias = dout.sum(dim=(0, 1)) if not ctx.out_proj_bias_is_None else None
        dD = dD if D is not None else None
        dx_dbl = torch.empty_like(x_dbl)
        dB_proj_bias = None
        if ctx.is_variable_B:
            if not A.is_complex():
                dB = rearrange(dB, "b 1 dstate l -> (b l) dstate").contiguous()
            else:
                dB = rearrange(dB, "b 1 dstate (l two) -> (b l) (dstate two)", two=2).contiguous()
            dB_proj_bias = dB.sum(0) if not ctx.B_proj_bias_is_None else None
            dx_dbl[:, delta_rank:delta_rank + d_state] = dB  # (bl d)
            dB = None
        dC_proj_bias = None
        if ctx.is_variable_C:
            if not A.is_complex():
                dC = rearrange(dC, "b 1 dstate l -> (b l) dstate").contiguous()
            else:
                dC = rearrange(dC, "b 1 dstate (l two) -> (b l) (dstate two)", two=2).contiguous()
            dC_proj_bias = dC.sum(0) if not ctx.C_proj_bias_is_None else None
            dx_dbl[:, -d_state:] = dC  # (bl d)
            dC = None
        ddelta = rearrange(ddelta, "b d l -> d (b l)")
        ddelta_proj_weight = torch.einsum("dB,Br->dr", ddelta, x_dbl[:, :delta_rank])
        dx_dbl[:, :delta_rank] = torch.einsum("dB,dr->Br", ddelta, delta_proj_weight)
        dconv1d_out = rearrange(dconv1d_out, "b d l -> d (b l)")
        dx_proj_weight = torch.einsum("Br,Bd->rd", dx_dbl, rearrange(conv1d_out, "b d l -> (b l) d"))
        dconv1d_out = torch.addmm(dconv1d_out, x_proj_weight.t(), dx_dbl.t(), out=dconv1d_out)
        dconv1d_out = rearrange(dconv1d_out, "d (b l) -> b d l", b=x.shape[0], l=x.shape[-1])
        # The kernel supports passing in a pre-allocated dx (e.g., in case we want to fuse the
        # backward of conv1d with the backward of chunk).
        dx, dconv1d_weight, dconv1d_bias = causal_conv1d_cuda.causal_conv1d_bwd(
            x, conv1d_weight, conv1d_bias, dconv1d_out, dx, True
        )
        dconv1d_bias = dconv1d_bias if conv1d_bias is not None else None
        dconv1d_weight = rearrange(dconv1d_weight, "d w -> d 1 w")
        return (dxz, dconv1d_weight, dconv1d_bias, dx_proj_weight, ddelta_proj_weight,
                dout_proj_weight, dout_proj_bias,
                dA, dB, dC, dD,
                ddelta_bias if delta_bias is not None else None,
                dB_proj_bias, dC_proj_bias, None)


def mamba_inner_fn(
    xz, conv1d_weight, conv1d_bias, x_proj_weight, delta_proj_weight,
    out_proj_weight, out_proj_bias,
    A, B=None, C=None, D=None, delta_bias=None, B_proj_bias=None,
    C_proj_bias=None, delta_softplus=True
):
    return MambaInnerFn.apply(xz, conv1d_weight, conv1d_bias, x_proj_weight, delta_proj_weight,
                              out_proj_weight, out_proj_bias,
                              A, B, C, D, delta_bias, B_proj_bias, C_proj_bias, delta_softplus)


def mamba_inner_ref(
    xz, conv1d_weight, conv1d_bias, x_proj_weight, delta_proj_weight,
    out_proj_weight, out_proj_bias,
    A, B=None, C=None, D=None, delta_bias=None, B_proj_bias=None,
    C_proj_bias=None, delta_softplus=True
):
    L = xz.shape[-1]
    delta_rank = delta_proj_weight.shape[1]
    d_state = A.shape[-1] * (1 if not A.is_complex() else 2)
    x, z = xz.chunk(2, dim=1)
    x = causal_conv1d_fn(x, rearrange(conv1d_weight, "d 1 w -> d w"), conv1d_bias, "silu")
    # We're being very careful here about the layout, to avoid extra transposes.
    # We want delta to have d as the slowest moving dimension
    # and L as the fastest moving dimension, since those are what the ssm_scan kernel expects.
    x_dbl = F.linear(rearrange(x, 'b d l -> (b l) d'), x_proj_weight)  # (bl d)
    delta = delta_proj_weight @ x_dbl[:, :delta_rank].t()
    delta = rearrange(delta, "d (b l) -> b d l", l=L)
    if B is None:  # variable B
        B = x_dbl[:, delta_rank:delta_rank + d_state]  # (bl d)
        if B_proj_bias is not None:
            B = B + B_proj_bias.to(dtype=B.dtype)
        if not A.is_complex():
            B = rearrange(B, "(b l) dstate -> b dstate l", l=L).contiguous()
        else:
            B = rearrange(B, "(b l) (dstate two) -> b dstate (l two)", l=L, two=2).contiguous()
    if C is None:  # variable B
        C = x_dbl[:, -d_state:]  # (bl d)
        if C_proj_bias is not None:
            C = C + C_proj_bias.to(dtype=C.dtype)
        if not A.is_complex():
            C = rearrange(C, "(b l) dstate -> b dstate l", l=L).contiguous()
        else:
            C = rearrange(C, "(b l) (dstate two) -> b dstate (l two)", l=L, two=2).contiguous()
    y = selective_scan_fn(x, delta, A, B, C, D, z=z, delta_bias=delta_bias, delta_softplus=True)
    return F.linear(rearrange(y, "b d l -> b l d"), out_proj_weight, out_proj_bias)