test_causal_conv1d.py

from typing import Optional

import pytest
import torch
import torch.nn.functional as F

from tests.kernels.utils import opcheck
from vllm import _custom_ops as ops  # noqa: F401
from vllm.attention.backends.utils import PAD_SLOT_ID
from vllm.model_executor.layers.mamba.ops.causal_conv1d import (
    causal_conv1d_fn, causal_conv1d_update)
from vllm.platforms import current_platform


def causal_conv1d_ref(
    x: torch.Tensor,
    weight: torch.Tensor,
    bias: Optional[torch.Tensor] = None,
    initial_states: Optional[torch.Tensor] = None,
    return_final_states: bool = False,
    final_states_out: Optional[torch.Tensor] = None,
    activation: Optional[str] = "silu",
):
    """
    x: (batch, dim, seqlen)
    weight: (dim, width)
    bias: (dim,)
    initial_states: (batch, dim, width - 1)
    final_states_out: (batch, dim, width - 1)

    out: (batch, dim, seqlen)
    """
    if activation not in [None, "silu", "swish"]:
        raise NotImplementedError("activation must be None, silu, or swish")
    dtype_in = x.dtype
    x = x.to(weight.dtype)
    seqlen = x.shape[-1]
    dim, width = weight.shape
    if initial_states is None:
        out = F.conv1d(x,
                       weight.unsqueeze(1),
                       bias,
                       padding=width - 1,
                       groups=dim)
    else:
        x = torch.cat([initial_states, x], dim=-1)
        out = F.conv1d(x, weight.unsqueeze(1), bias, padding=0, groups=dim)
    out = out[..., :seqlen]
    if return_final_states:
        final_states = F.pad(x, (width - 1 - x.shape[-1], 0)).to(
            dtype_in)  # (batch, dim, width - 1)
        if final_states_out is not None:
            final_states_out.copy_(final_states)
        else:
            final_states_out = final_states
    out = (out if activation is None else F.silu(out)).to(dtype=dtype_in)
    return (out, None) if not return_final_states else (out, final_states_out)


def causal_conv1d_update_ref(x,
                             conv_state,
                             weight,
                             bias=None,
                             activation=None,
                             cache_seqlens=None):
    """
    x: (batch, dim) or (batch, dim, seqlen)
    conv_state: (batch, dim, state_len), where state_len >= width - 1
    weight: (dim, width)
    bias: (dim,)
    cache_seqlens: (batch,), dtype int32.
        If not None, the conv_state is treated as a circular buffer.
        The conv_state will be updated by copying x to the
        conv_state starting at the index
        @cache_seqlens % state_len before performing the convolution.

    out: (batch, dim) or (batch, dim, seqlen)
    """
    if activation not in [None, "silu", "swish"]:
        raise NotImplementedError("activation must be None, silu, or swish")
    dtype_in = x.dtype
    unsqueeze = x.dim() == 2
    if unsqueeze:
        x = x.unsqueeze(-1)
    batch, dim, seqlen = x.shape
    width = weight.shape[1]
    state_len = conv_state.shape[-1]
    assert conv_state.shape == (batch, dim, state_len)
    assert weight.shape == (dim, width)
    if cache_seqlens is None:
        x_new = torch.cat([conv_state, x], dim=-1).to(
            weight.dtype)  # (batch, dim, state_len + seqlen)
        conv_state.copy_(x_new[:, :, -state_len:])
    else:
        width_idx = torch.arange(
            -(width - 1), 0, dtype=torch.long,
            device=x.device).unsqueeze(0) + cache_seqlens.unsqueeze(1)
        width_idx = torch.remainder(width_idx, state_len).unsqueeze(1).expand(
            -1, dim, -1)
        x_new = torch.cat([conv_state.gather(2, width_idx), x],
                          dim=-1).to(weight.dtype)
        copy_idx = torch.arange(
            seqlen, dtype=torch.long,
            device=x.device).unsqueeze(0) + cache_seqlens.unsqueeze(1)
        copy_idx = torch.remainder(copy_idx,
                                   state_len).unsqueeze(1).expand(-1, dim, -1)
        conv_state.scatter_(2, copy_idx, x)
    out = F.conv1d(x_new, weight.unsqueeze(1), bias, padding=0,
                   groups=dim)[:, :, -seqlen:]
    if unsqueeze:
        out = out.squeeze(-1)
    return (out if activation is None else F.silu(out)).to(dtype=dtype_in)


@pytest.mark.parametrize("itype", [torch.bfloat16, torch.float])
@pytest.mark.parametrize("silu_activation", [True])
@pytest.mark.parametrize("has_bias", [True])
def causal_conv1d_opcheck_fn(x: torch.Tensor,
                             weight: torch.Tensor,
                             bias: Optional[torch.Tensor] = None,
                             cu_seq_len: Optional[torch.Tensor] = None,
                             cache_indices: Optional[torch.Tensor] = None,
                             has_initial_state: Optional[torch.Tensor] = None,
                             conv_states: Optional[torch.Tensor] = None,
                             activation: Optional[str] = "silu",
                             pad_slot_id: int = PAD_SLOT_ID):
    """
    x: (batch, dim, seqlen)
    weight: (dim, width)
    bias: (dim,)
    seq_idx: (batch, seqlen)
    initial_states: (batch, dim, width - 1)
    final_states_out: (batch, dim, width - 1), to be written to
    activation: either None or "silu" or "swish"

    out: (batch, dim, seqlen)
    """
    if activation not in [None, "silu", "swish"]:
        raise NotImplementedError("activation must be None, silu, or swish")
    if x.stride(-1) != 1:
        x = x.contiguous()
    bias = bias.contiguous() if bias is not None else None

    opcheck(torch.ops._C.causal_conv1d_fwd,
            (x, weight, bias, conv_states, cu_seq_len, cache_indices,
             has_initial_state, activation in ["silu", "swish"], pad_slot_id))


@pytest.mark.parametrize("itype", [torch.bfloat16, torch.float])
@pytest.mark.parametrize("silu_activation", [True])
@pytest.mark.parametrize("has_bias", [True])
@pytest.mark.parametrize("has_initial_state", [True, False])
@pytest.mark.parametrize("width", [4])
@pytest.mark.parametrize(
    'seqlen', [1, 8, 16, 32, 64, 128, 256, 512, 784, 1024, 1025, 2048, 4096])
@pytest.mark.parametrize('dim', [64])
@pytest.mark.parametrize('batch', [1])
def test_causal_conv1d(batch, dim, seqlen, width, has_bias, silu_activation,
                       has_initial_state, itype):
    device = "cuda"
    rtol, atol = (3e-4, 1e-3) if itype == torch.float32 else (3e-3, 5e-3)
    if itype == torch.bfloat16:
        rtol, atol = 1e-2, 5e-2
    # set seed
    current_platform.seed_everything(0)
    x = torch.randn(batch, dim, seqlen, device=device,
                    dtype=itype).contiguous()

    weight = torch.randn(dim, width, device=device, dtype=itype)
    bias = torch.randn(dim, device=device, dtype=itype) if has_bias else None
    if has_initial_state:
        initial_states = torch.randn(batch,
                                     dim,
                                     width - 1,
                                     device=device,
                                     dtype=itype)
        has_initial_state_tensor = torch.ones(batch,
                                              dtype=torch.bool,
                                              device=x.device)
    else:
        initial_states = None
        has_initial_state_tensor = None
    x_ref = x.clone()
    weight_ref = weight.clone()
    bias_ref = bias.clone() if bias is not None else None
    initial_states_ref = initial_states.clone(
    ) if initial_states is not None else None
    activation = None if not silu_activation else "silu"
    out = causal_conv1d_fn(x,
                           weight,
                           bias,
                           activation=activation,
                           conv_states=initial_states,
                           has_initial_state=has_initial_state_tensor)
    out_ref, final_states_ref = causal_conv1d_ref(
        x_ref,
        weight_ref,
        bias_ref,
        initial_states=initial_states_ref,
        return_final_states=True,
        activation=activation)
    if has_initial_state:
        assert initial_states is not None and final_states_ref is not None
        assert torch.allclose(initial_states,
                              final_states_ref,
                              rtol=rtol,
                              atol=atol)
    assert torch.allclose(out, out_ref, rtol=rtol, atol=atol)

    causal_conv1d_opcheck_fn(x,
                             weight,
                             bias,
                             activation=activation,
                             conv_states=initial_states,
                             has_initial_state=has_initial_state_tensor)


@pytest.mark.parametrize("itype", [torch.bfloat16])
@pytest.mark.parametrize("silu_activation", [False, True])
@pytest.mark.parametrize("has_bias", [False, True])
@pytest.mark.parametrize("seqlen", [1])
@pytest.mark.parametrize("width", [4])
@pytest.mark.parametrize("dim", [2048, 2048 + 16, 4096])
def test_causal_conv1d_update(dim, width, seqlen, has_bias, silu_activation,
                              itype):
    device = "cuda"
    rtol, atol = (3e-4, 1e-3) if itype == torch.float32 else (3e-3, 5e-3)
    if itype == torch.bfloat16:
        rtol, atol = 1e-2, 5e-2
    # set seed
    current_platform.seed_everything(0)
    batch = 2
    x = torch.randn(batch, dim, seqlen, device=device, dtype=itype)
    x_ref = x.clone()
    conv_state = torch.randn(batch, dim, width - 1, device=device, dtype=itype)

    weight = torch.randn(dim, width, device=device, dtype=itype)
    bias = torch.randn(dim, device=device, dtype=itype) if has_bias else None
    conv_state_ref = conv_state.detach().clone()
    activation = None if not silu_activation else "silu"
    out = causal_conv1d_update(x,
                               conv_state,
                               weight,
                               bias,
                               activation=activation)
    out_ref = causal_conv1d_update_ref(x_ref,
                                       conv_state_ref,
                                       weight,
                                       bias,
                                       activation=activation)

    assert torch.equal(conv_state, conv_state_ref)
    assert torch.allclose(out, out_ref, rtol=rtol, atol=atol)

    opcheck(torch.ops._C.causal_conv1d_update,
            (x, conv_state, weight, bias, activation
             in ["silu", "swish"], None, None, PAD_SLOT_ID))


@pytest.mark.parametrize("itype",
                         [torch.float32, torch.float16, torch.bfloat16])
@pytest.mark.parametrize("silu_activation", [False, True])
@pytest.mark.parametrize("has_bias", [False, True])
@pytest.mark.parametrize("seqlen", [1, 4, 5])
@pytest.mark.parametrize("width", [2, 3, 4])
@pytest.mark.parametrize("dim", [2048, 2048 + 16, 4096])
# tests correctness in case subset of the sequences are padded
@pytest.mark.parametrize("with_padding", [True, False])
def test_causal_conv1d_update_with_batch_gather(with_padding, dim, width,
                                                seqlen, has_bias,
                                                silu_activation, itype):
    device = "cuda"
    rtol, atol = (3e-4, 1e-3) if itype == torch.float32 else (3e-3, 5e-3)
    if itype == torch.bfloat16:
        rtol, atol = 1e-2, 5e-2

    # set seed
    current_platform.seed_everything(0)

    batch_size = 3
    padding = 5 if with_padding else 0
    padded_batch_size = batch_size + padding
    total_entries = 10 * batch_size

    x = torch.randn(padded_batch_size, dim, 1, device=device, dtype=itype)
    x_ref = x.clone()

    conv_state_indices = torch.randperm(total_entries)[:batch_size].to(
        dtype=torch.int32, device=device)
    unused_states_bool = torch.ones(total_entries,
                                    dtype=torch.bool,
                                    device=device)
    unused_states_bool[conv_state_indices] = False
    padded_state_indices = torch.concat([
        conv_state_indices,
        torch.as_tensor(
            [PAD_SLOT_ID] * padding, dtype=torch.int32, device=device)
    ],
                                        dim=0)
    conv_state = torch.randn(total_entries,
                             dim,
                             width - 1,
                             device=device,
                             dtype=itype)
    conv_state_for_padding_test = conv_state.clone()

    weight = torch.randn(dim, width, device=device, dtype=itype)
    bias = torch.randn(dim, device=device, dtype=itype) if has_bias else None
    conv_state_ref = conv_state[conv_state_indices, :].detach().clone()
    activation = None if not silu_activation else "silu"
    out = causal_conv1d_update(x,
                               conv_state,
                               weight,
                               bias,
                               activation=activation,
                               conv_state_indices=padded_state_indices,
                               pad_slot_id=PAD_SLOT_ID)
    out_ref = causal_conv1d_update_ref(x_ref[:batch_size],
                                       conv_state_ref,
                                       weight,
                                       bias,
                                       activation=activation)

    assert torch.equal(conv_state[conv_state_indices, :], conv_state_ref)
    assert torch.allclose(out[:batch_size], out_ref, rtol=rtol, atol=atol)
    assert torch.equal(conv_state[unused_states_bool],
                       conv_state_for_padding_test[unused_states_bool])

    opcheck(torch.ops._C.causal_conv1d_update,
            (x, conv_state, weight, bias, activation
             in ["silu", "swish"], None, padded_state_indices, PAD_SLOT_ID))


@pytest.mark.parametrize("itype", [torch.bfloat16])
@pytest.mark.parametrize("silu_activation", [True])
@pytest.mark.parametrize("has_bias", [True])
@pytest.mark.parametrize("width", [4])
@pytest.mark.parametrize(
    'seqlen', [8, 16, 32, 64, 128, 256, 512, 784, 1024, 2048, 2049, 4096])
@pytest.mark.parametrize('dim', [64, 4096])
# tests correctness in case subset of the sequences are padded
@pytest.mark.parametrize('with_padding', [True, False])
def test_causal_conv1d_varlen(with_padding, dim, seqlen, width, has_bias,
                              silu_activation, itype):
    device = "cuda"
    torch.cuda.empty_cache()
    rtol, atol = (3e-4, 1e-3) if itype == torch.float32 else (3e-3, 5e-3)
    if itype == torch.bfloat16:
        rtol, atol = 1e-2, 5e-2
    # set seed
    current_platform.seed_everything(0)
    seqlens = []
    batch_size = 4
    if seqlen < 10:
        batch_size = 1
    padding = 3 if with_padding else 0
    padded_batch_size = batch_size + padding
    nsplits = padded_batch_size - 1

    eos_pos = torch.randperm(seqlen - 1)[:nsplits].sort().values
    seqlens.append(
        torch.diff(
            torch.cat(
                [torch.tensor([-1]), eos_pos,
                 torch.tensor([seqlen - 1])])).tolist())
    assert sum(seqlens[-1]) == seqlen
    assert all(s > 0 for s in seqlens[-1])

    total_entries = batch_size * 10
    cumsum = torch.cumsum(torch.tensor(seqlens[0]), dim=0).to(torch.int32)
    cumsum = torch.concat([torch.tensor([0], dtype=torch.int32), cumsum],
                          dim=0)
    x = torch.randn(1, 4096 + dim + 64, seqlen, device=device,
                    dtype=itype)[:, 4096:4096 + dim, :]
    weight = torch.randn(dim, width, device=device, dtype=itype)
    bias = torch.randn(dim, device=device, dtype=itype) if has_bias else None
    x_ref = x.clone()
    weight_ref = weight.clone()
    bias_ref = bias.clone() if bias is not None else None
    activation = None if not silu_activation else "silu"
    final_states = torch.randn(total_entries,
                               dim,
                               width - 1,
                               device=x.device,
                               dtype=x.dtype)
    final_states_ref = final_states.clone()
    has_initial_states = torch.randint(0,
                                       2, (cumsum.shape[0] - 1, ),
                                       dtype=torch.bool,
                                       device=x.device)
    state_indices = torch.randperm(total_entries,
                                   dtype=torch.int32,
                                   device=x.device)[:batch_size]
    padded_state_indices = torch.concat([
        state_indices,
        torch.as_tensor(
            [PAD_SLOT_ID] * padding, dtype=torch.int32, device=device),
    ],
                                        dim=-1)

    out = causal_conv1d_fn(x.squeeze(0), weight, bias, cumsum.cuda(),
                           padded_state_indices, has_initial_states,
                           final_states, activation, PAD_SLOT_ID)
    out_ref = []
    out_ref_b = []

    splits = [torch.split(var, seqlens[0], dim=-1) for var in (x_ref)]
    for i in range(len(seqlens[0])):
        x_s = [v[i].unsqueeze(0) for v in splits][0]
        if padded_state_indices[i] == PAD_SLOT_ID:
            continue
        out_ref_b.append(
            causal_conv1d_ref(
                x_s,
                weight_ref,
                bias_ref,
                activation=activation,
                return_final_states=True,
                final_states_out=final_states_ref[
                    padded_state_indices[i]].unsqueeze(0),
                initial_states=final_states_ref[padded_state_indices[i]].
                unsqueeze(0) if has_initial_states[i] else None))
    out_ref.append(torch.cat([t[0] for t in out_ref_b], dim=2))
    out_ref_tensor = torch.cat(out_ref, dim=0)

    unpadded_out = out[:, :out_ref_tensor.shape[-1]]
    assert torch.allclose(unpadded_out, out_ref_tensor, rtol=rtol, atol=atol)
    assert torch.allclose(final_states[state_indices],
                          final_states_ref[state_indices],
                          rtol=rtol,
                          atol=atol)

    causal_conv1d_opcheck_fn(x.squeeze(0), weight, bias, cumsum.cuda(),
                             padded_state_indices, has_initial_states,
                             final_states, activation)