rocm.py

# SPDX-License-Identifier: Apache-2.0
# SPDX-FileCopyrightText: Copyright contributors to the vLLM project

import os
from datetime import timedelta
from functools import cache, lru_cache, wraps
from typing import TYPE_CHECKING

import regex as re
import torch
from torch.distributed import PrefixStore, ProcessGroup
from torch.distributed.distributed_c10d import is_nccl_available

import vllm.envs as envs
from vllm.logger import init_logger
from vllm.v1.attention.backends.registry import AttentionBackendEnum

from .interface import DeviceCapability, Platform, PlatformEnum

if TYPE_CHECKING:
    from vllm.config import VllmConfig
    from vllm.config.kernel import IrOpPriorityConfig
    from vllm.v1.attention.selector import AttentionSelectorConfig

logger = init_logger(__name__)

try:
    from amdsmi import (
        AmdSmiException,
        amdsmi_get_gpu_asic_info,
        amdsmi_get_gpu_device_uuid,
        amdsmi_get_processor_handles,
        amdsmi_init,
        amdsmi_shut_down,
        amdsmi_topo_get_link_type,
    )
except ImportError as e:
    logger.warning("Failed to import from amdsmi with %r", e)

try:
    import vllm._C  # noqa: F401
except ImportError as e:
    logger.warning("Failed to import from vllm._C with %r", e)

# import custom ops, trigger op registration
try:
    import vllm._rocm_C  # noqa: F401
except ImportError as e:
    logger.warning("Failed to import from vllm._rocm_C with %r", e)

# Models not supported by ROCm.
_ROCM_UNSUPPORTED_MODELS: list[str] = []

# Models partially supported by ROCm.
# Architecture -> Reason.
_ROCM_PARTIALLY_SUPPORTED_MODELS: dict[str, str] = {}
_ROCM_DEVICE_ID_NAME_MAP: dict[str, str] = {
    "0x74a0": "AMD_Instinct_MI300A",
    "0x74a1": "AMD_Instinct_MI300X",
    "0x74b5": "AMD_Instinct_MI300X",  # MI300X VF
    "0x74a2": "AMD_Instinct_MI308X",
    "0x74a5": "AMD_Instinct_MI325X",
    "0x74b9": "AMD_Instinct_MI325X",  # MI325X VF
    "0x74a9": "AMD_Instinct_MI300X_HF",
    "0x74bd": "AMD_Instinct_MI300X_HF",
    "0x744c": "AMD_Radeon_RX7900XTX",
    # RDNA 3.5 APUs (Strix Point / Strix Halo)
    "0x150e": "AMD_Radeon_890M",  # gfx1150, Strix Point
    "0x1586": "AMD_Radeon_8060S",  # gfx1151, Strix Halo
    # RDNA 4 discrete (Navi 48)
    "0x7550": "AMD_Radeon_RX9070XT",  # gfx1201
    "0x7551": "AMD_Radeon_R9700",  # gfx1201
}


@lru_cache(maxsize=8)
def _rocm_device_count_stateless(cuda_visible_devices: str | None = None) -> int:
    """Get number of ROCm devices, caching based on the value of CUDA_VISIBLE_DEVICES
    at the time of call.

    This should be used instead of torch.accelerator.device_count() unless
    CUDA_VISIBLE_DEVICES has already been set to the desired value.

    # This can be removed and simply replaced with torch.cuda.get_device_count
    # after https://github.com/pytorch/pytorch/pull/122815 is released."""
    # Note: cuda_visible_devices is not used, but we keep it as an argument for
    # LRU Cache purposes.

    # Code below is based on
    # https://github.com/pytorch/pytorch/blob/
    # c1cd946818442aca8c7f812b16d187ce1586c3bc/
    # torch/cuda/__init__.py#L831C1-L831C17
    import torch.cuda

    if not torch.cuda._is_compiled():
        return 0
    # ROCm uses amdsmi instead of nvml for stateless device count
    # This requires a sufficiently modern version of Torch 2.4.0
    raw_count = (
        torch.cuda._device_count_amdsmi()
        if (hasattr(torch.cuda, "_device_count_amdsmi"))
        else -1
    )
    r = torch._C._cuda_getDeviceCount() if raw_count < 0 else raw_count
    return r


def _sync_hip_cuda_env_vars():
    """Ensure HIP_VISIBLE_DEVICES and CUDA_VISIBLE_DEVICES are consistent.
    Treats empty string as unset. Raises on genuine conflicts."""
    hip_val = os.environ.get("HIP_VISIBLE_DEVICES") or None
    cuda_val = os.environ.get("CUDA_VISIBLE_DEVICES") or None

    if hip_val is not None and cuda_val is not None:
        if hip_val != cuda_val:
            raise ValueError(
                f"Inconsistent GPU visibility env vars: "
                f"HIP_VISIBLE_DEVICES='{hip_val}' vs "
                f"CUDA_VISIBLE_DEVICES='{cuda_val}'. "
                f"Please set only one, or ensure they match."
            )
    elif hip_val is not None:
        os.environ["CUDA_VISIBLE_DEVICES"] = hip_val
    elif cuda_val is not None:
        os.environ["HIP_VISIBLE_DEVICES"] = cuda_val


# Sync at import time - catches misconfigurations from process start.
_sync_hip_cuda_env_vars()

# AMDSMI utils
# Note that NVML is not affected by `{CUDA/HIP}_VISIBLE_DEVICES`,
# all the related functions work on real physical device ids.
# the major benefit of using AMDSMI is that it will not initialize CUDA


def with_amdsmi_context(fn):
    @wraps(fn)
    def wrapper(*args, **kwargs):
        amdsmi_init()
        try:
            return fn(*args, **kwargs)
        finally:
            amdsmi_shut_down()

    return wrapper


@with_amdsmi_context
def _query_gcn_arch_from_amdsmi() -> str:
    """Query GCN arch from amdsmi. Raises if not available."""
    handles = amdsmi_get_processor_handles()
    if handles:
        asic_info = amdsmi_get_gpu_asic_info(handles[0])
        # Use target_graphics_version which contains the gfx name
        # e.g., 'gfx942' for MI300X/MI325X
        target_gfx = asic_info.get("target_graphics_version", "")
        if target_gfx:
            return target_gfx
    raise RuntimeError("amdsmi did not return valid GCN arch")


def _get_gcn_arch() -> str:
    """
    Get GCN arch via amdsmi (no CUDA init), fallback to torch.cuda.
    Called once at module level; result stored in _GCN_ARCH.
    """
    try:
        return _query_gcn_arch_from_amdsmi()
    except Exception as e:
        logger.debug("Failed to get GCN arch via amdsmi: %s", e)
        logger.warning_once(
            "Failed to get GCN arch via amdsmi, falling back to torch.cuda. "
            "This will initialize CUDA and may cause "
            "issues if CUDA_VISIBLE_DEVICES is not set yet."
        )
    # Ultimate fallback: use torch.cuda (will initialize CUDA)
    return torch.cuda.get_device_properties("cuda").gcnArchName


# Resolve once at module load. Uses amdsmi (no CUDA init) so Ray workers
# can still set CUDA_VISIBLE_DEVICES after import.
# These are plain Python bools — fully torch.compile/Dynamo safe.
_GCN_ARCH = _get_gcn_arch()

_ON_GFX1X = any(arch in _GCN_ARCH for arch in ["gfx11", "gfx12"])
_ON_GFX12X = any(arch in _GCN_ARCH for arch in ["gfx12"])
_ON_MI3XX = any(arch in _GCN_ARCH for arch in ["gfx942", "gfx950"])
_ON_GFX9 = any(arch in _GCN_ARCH for arch in ["gfx90a", "gfx942", "gfx950"])
_ON_GFX90A = "gfx90a" in _GCN_ARCH
_ON_GFX942 = "gfx942" in _GCN_ARCH
_ON_GFX950 = "gfx950" in _GCN_ARCH


def _capability_from_gcn_arch(gcn_arch: str) -> tuple[int, int] | None:
    """
    Parse (major, minor) from a GCN arch string, mirroring how
    HIP derives hipDeviceProp_t.major / .minor.

    Format: gfx<MAJOR><MINOR><STEPPING>
      - 1-digit major  (gfx9xx):  "gfx" + M + m + stepping
      - 2-digit major  (gfx1xxx): "gfx" + MM + m + stepping

    Examples:
      gfx90a  -> (9, 0)    gfx942  -> (9, 4)    gfx950 -> (9, 5)
      gfx1100 -> (11, 0)   gfx1101 -> (11, 0)   gfx1200 -> (12, 0)

    Returns None only when the string is not gfx-prefixed at all
    (i.e. not a ROCm arch string). Raises on any string that looks
    like a GCN arch but does not match a known layout.
    """
    m = re.match(r"gfx(\d+)", gcn_arch)
    if not m:
        # Not a gfx string at all — caller should fall back to torch.cuda
        return None

    digits = m.group(1)
    n = len(digits)

    if n < 2:
        raise ValueError(
            f"GCN arch '{gcn_arch}' has too few digits ({n}) after 'gfx' "
            f"to derive a (major, minor) capability. "
            f"Please file a vLLM issue with your GPU model."
        )

    if n in (2, 3):
        # 1-digit major: gfx9 family
        # len 2: major + minor          (e.g. gfx90 from gfx90a)
        # len 3: major + minor + step   (e.g. gfx942)
        major = int(digits[0])
        minor = int(digits[1])
    elif n == 4:
        # 2-digit major: gfx10xx, gfx11xx, gfx12xx
        # major(2) + minor(1) + stepping(1)
        major = int(digits[:2])
        minor = int(digits[2])
    elif n >= 5:
        raise ValueError(
            f"GCN arch '{gcn_arch}' has {n} digits after 'gfx', which "
            f"exceeds the known 4-digit layout (MMms). Cannot determine "
            f"major/minor split unambiguously. "
            f"Please file a vLLM issue with your GPU model."
        )

    if major < 9:
        raise ValueError(
            f"Parsed unknown ROCm architecture from GCN arch '{gcn_arch}': "
            f"major={major}, minor={minor}. "
            f"Major version < 9 is not expected for any supported AMD GPU. "
            f"Please file a vLLM issue with your GPU model."
        )

    if major > 12:
        raise ValueError(
            f"Parsed unknown ROCm architecture from GCN arch '{gcn_arch}': "
            f"major={major}, minor={minor}. "
            f"Major version > 12 is beyond currently known AMD generations. "
            f"Please file a vLLM issue with your GPU model so support "
            f"can be added."
        )

    return (major, minor)


def on_gfx1x() -> bool:
    return _ON_GFX1X


def on_gfx12x() -> bool:
    return _ON_GFX12X


def on_mi3xx() -> bool:
    return _ON_MI3XX


def on_gfx9() -> bool:
    return _ON_GFX9


def on_gfx90a() -> bool:
    return _ON_GFX90A


def on_gfx942() -> bool:
    return _ON_GFX942


def on_gfx950() -> bool:
    return _ON_GFX950


@cache
def use_rocm_custom_paged_attention(
    qtype: torch.dtype,
    head_size: int,
    block_size: int,
    gqa_ratio: int,
    max_seq_len: int,
    sliding_window: int,
    kv_cache_dtype: str,
    alibi_slopes: torch.Tensor | None = None,
    sinks: torch.Tensor | None = None,
) -> bool:
    # custom paged attn always supported on V0. On V1, requires sliding window
    # disabled due to observed numerical discrepancy.
    if _ON_GFX9:
        return (
            (sliding_window == 0 or sliding_window == (-1, -1))
            and (qtype == torch.half or qtype == torch.bfloat16)
            and (head_size == 64 or head_size == 128)
            and (block_size == 16 or block_size == 32)
            and (gqa_ratio >= 1 and gqa_ratio <= 16)
            and max_seq_len <= 128 * 1024
            and sinks is None
        )

    else:
        return (
            _ON_GFX1X
            and (sliding_window == 0 or sliding_window == (-1, -1))
            and (qtype == torch.half or qtype == torch.bfloat16)
            and head_size == 128
            and block_size == 16
            and (gqa_ratio >= 3 and gqa_ratio <= 16)
            and max_seq_len <= 128 * 1024
            and alibi_slopes is None
            and kv_cache_dtype == "auto"
            and sinks is None
        )


@cache
def flash_attn_triton_available() -> bool:
    if not on_gfx1x():
        return False
    try:
        from importlib.util import find_spec

        if find_spec("flash_attn") is None:
            return False
        if find_spec("flash_attn.flash_attn_triton_amd") is None:
            return False
        if os.environ.get("FLASH_ATTENTION_TRITON_AMD_ENABLE") != "TRUE":
            logger.info_once(
                "Set FLASH_ATTENTION_TRITON_AMD_ENABLE=TRUE to enable "
                "Flash Attention Triton backend on RDNA."
            )
            return False
        return True
    except ImportError:
        return False


def _get_backend_priorities(
    use_mla: bool,
    use_sparse: bool,
) -> list[AttentionBackendEnum]:
    from vllm._aiter_ops import is_aiter_found_and_supported, rocm_aiter_ops

    if use_sparse:
        return [AttentionBackendEnum.ROCM_AITER_MLA_SPARSE]

    if use_mla:
        if rocm_aiter_ops.is_mla_enabled():
            return [
                AttentionBackendEnum.ROCM_AITER_MLA,
                AttentionBackendEnum.TRITON_MLA,
                AttentionBackendEnum.ROCM_AITER_TRITON_MLA,
            ]
        else:
            return [
                AttentionBackendEnum.TRITON_MLA,
            ]

    backends = [
        AttentionBackendEnum.ROCM_ATTN,
    ]
    if rocm_aiter_ops.is_mha_enabled():
        backends.append(AttentionBackendEnum.ROCM_AITER_FA)
    if is_aiter_found_and_supported():
        backends.append(AttentionBackendEnum.ROCM_AITER_UNIFIED_ATTN)
    backends.append(AttentionBackendEnum.TRITON_ATTN)
    backends.append(AttentionBackendEnum.TURBOQUANT)

    return backends


class RocmPlatform(Platform):
    _enum = PlatformEnum.ROCM
    device_name: str = "rocm"
    device_type: str = "cuda"
    dispatch_key: str = "CUDA"
    ray_device_key: str = "GPU"
    dist_backend: str = "nccl"
    # rocm shares the same device control env var as CUDA
    device_control_env_var: str = "CUDA_VISIBLE_DEVICES"
    ray_noset_device_env_vars: list[str] = [
        "RAY_EXPERIMENTAL_NOSET_HIP_VISIBLE_DEVICES",
        "RAY_EXPERIMENTAL_NOSET_CUDA_VISIBLE_DEVICES",
        "RAY_EXPERIMENTAL_NOSET_ROCR_VISIBLE_DEVICES",
    ]

    supported_quantization: list[str] = [
        "awq",
        "awq_marlin",  # will be overwritten with awq
        "gptq",
        "gptq_marlin",  # will be overwritten with gptq
        "fp8",
        "compressed-tensors",
        "fbgemm_fp8",
        "gguf",
        "quark",
        "mxfp4",
        "gpt_oss_mxfp4",
        "torchao",
        "bitsandbytes",
        "modelopt_fp4",
    ]

    @classmethod
    def import_kernels(cls) -> None:
        """Import ROCm-specific kernels."""
        super().import_kernels()

        import contextlib

        # Import ROCm-specific extension
        with contextlib.suppress(ImportError):
            import vllm._rocm_C  # noqa: F401

    @classmethod
    def get_valid_backends(
        cls,
        device_capability: DeviceCapability,
        attn_selector_config: "AttentionSelectorConfig",
        num_heads: int | None = None,
    ) -> tuple[
        list[tuple["AttentionBackendEnum", int]],
        dict["AttentionBackendEnum", list[str]],
    ]:
        valid_backends_priorities = []
        invalid_reasons = {}

        backend_priorities = _get_backend_priorities(
            attn_selector_config.use_mla,
            attn_selector_config.use_sparse,
        )
        for priority, backend in enumerate(backend_priorities):
            try:
                backend_class = backend.get_class()
                invalid_reasons_i = backend_class.validate_configuration(
                    device_capability=device_capability,
                    **attn_selector_config._asdict(),
                )
            except ImportError:
                invalid_reasons_i = ["ImportError"]
            if invalid_reasons_i:
                invalid_reasons[backend] = invalid_reasons_i
            else:
                valid_backends_priorities.append((backend, priority))

        return valid_backends_priorities, invalid_reasons

    @classmethod
    def get_attn_backend_cls(
        cls,
        selected_backend: "AttentionBackendEnum",
        attn_selector_config: "AttentionSelectorConfig",
        num_heads: int | None = None,
    ) -> str:
        device_capability = cls.get_device_capability()
        assert device_capability is not None

        # First try checking just the selected backend, if there is one.
        if selected_backend is not None:
            try:
                backend_class = selected_backend.get_class()
                invalid_reasons = backend_class.validate_configuration(
                    device_capability=device_capability,
                    **attn_selector_config._asdict(),
                )
            except ImportError:
                invalid_reasons = ["ImportError"]
            if invalid_reasons:
                raise ValueError(
                    f"Selected backend {selected_backend} is not valid for "
                    f"this configuration. Reason: {invalid_reasons}"
                )
            else:
                logger.info_once(
                    "Using %s backend (selected via --attention-backend).",
                    selected_backend.name,
                )
                return selected_backend.get_path()

        # No selected backend or the selected backend is invalid,
        # so we try finding a valid backend.
        valid_backends_priorities, invalid_reasons = cls.get_valid_backends(
            device_capability=device_capability,
            attn_selector_config=attn_selector_config,
            num_heads=num_heads,
        )
        reasons_str = (
            "{"
            + ", ".join(
                f"{backend.name}: [{', '.join(reasons)}]"
                for backend, reasons in invalid_reasons.items()
            )
            + "}"
        )
        config_str = attn_selector_config.__repr__()
        logger.debug_once(
            f"Some attention backends are not valid for {cls.device_name} with "
            f"{config_str}. Reasons: {reasons_str}."
        )
        if len(valid_backends_priorities) == 0:
            raise ValueError(
                f"No valid attention backend found for {cls.device_name} "
                f"with {config_str}. Reasons: {reasons_str}."
            )

        # We have found some valid backends. Select the one with the
        # highest priority.
        sorted_indices = sorted(
            range(len(valid_backends_priorities)),
            key=lambda i: valid_backends_priorities[i][1],
        )
        selected_index = sorted_indices[0]
        selected_backend = valid_backends_priorities[selected_index][0]
        valid_str = (
            "[" + ", ".join(f"'{b[0].name}'" for b in valid_backends_priorities) + "]"
        )
        if invalid_reasons:
            rejected_str = ", ".join(b.name for b in invalid_reasons)
            logger.info(
                "Found incompatible backend(s) [%s] with %s. "
                "Overriding with %s out of potential backends: %s.",
                rejected_str,
                attn_selector_config.attn_type,
                selected_backend.name,
                valid_str,
            )
        else:
            logger.info_once(
                "Using %s backend out of potential backends: %s.",
                selected_backend.name,
                valid_str,
            )

        return selected_backend.get_path()

    @classmethod
    def get_supported_vit_attn_backends(cls) -> list["AttentionBackendEnum"]:
        return [
            AttentionBackendEnum.FLASH_ATTN,
            AttentionBackendEnum.ROCM_AITER_FA,
            AttentionBackendEnum.TRITON_ATTN,
            AttentionBackendEnum.TORCH_SDPA,
        ]

    @classmethod
    def get_vit_attn_backend(
        cls,
        head_size: int,
        dtype: torch.dtype,
        backend: "AttentionBackendEnum | None" = None,
    ) -> "AttentionBackendEnum":
        if backend is not None:
            assert backend in cls.get_supported_vit_attn_backends(), (
                f"Backend {backend} is not supported for vit attention. "
                f"Supported backends are: {cls.get_supported_vit_attn_backends()}"
            )
            logger.info_once(f"Using backend {backend} for vit attention")
            return backend

        from importlib.util import find_spec

        from vllm._aiter_ops import rocm_aiter_ops

        if rocm_aiter_ops.is_enabled() and on_gfx9():
            logger.info_once("Using AITER Flash Attention backend for ViT model.")
            return AttentionBackendEnum.ROCM_AITER_FA

        if (
            on_gfx9()
            and find_spec("flash_attn") is not None
            and (dtype == torch.float16 or dtype == torch.bfloat16)
        ):
            logger.info_once("Using Flash Attention backend for ViT model.")
            return AttentionBackendEnum.FLASH_ATTN

        # RDNA3/RDNA4 (gfx11xx/gfx12xx): Use Flash Attention Triton backend
        if (
            on_gfx1x()
            and flash_attn_triton_available()
            and (dtype == torch.float16 or dtype == torch.bfloat16)
        ):
            logger.info_once(
                "Using Flash Attention (Triton backend) for ViT model on RDNA."
            )
            return AttentionBackendEnum.FLASH_ATTN

        logger.info_once("Using Torch SDPA backend for ViT model.")
        return AttentionBackendEnum.TORCH_SDPA

    @classmethod
    def set_device(cls, device: torch.device) -> None:
        """
        Set the device for the current platform.
        """
        torch.cuda.set_device(device)

    @classmethod
    def manual_seed_all(cls, seed: int) -> None:
        torch.cuda.manual_seed_all(seed)

    @classmethod
    @lru_cache(maxsize=8)
    def get_device_capability(cls, device_id: int = 0) -> DeviceCapability | None:
        cap = _capability_from_gcn_arch(_GCN_ARCH)
        if cap is not None:
            return DeviceCapability(major=cap[0], minor=cap[1])

        logger.warning_once(
            "Could not derive device capability from GCN arch '%s', "
            "falling back to torch.cuda (this will initialize CUDA).",
            _GCN_ARCH,
        )
        major, minor = torch.cuda.get_device_capability(device_id)
        return DeviceCapability(major=major, minor=minor)

    @classmethod
    @with_amdsmi_context
    def is_fully_connected(cls, physical_device_ids: list[int]) -> bool:
        """
        Query if the set of gpus are fully connected by xgmi (1 hop)
        """
        handles = [amdsmi_get_processor_handles()[i] for i in physical_device_ids]
        for i, handle in enumerate(handles):
            for j, peer_handle in enumerate(handles):
                if i < j:
                    try:
                        link_type = amdsmi_topo_get_link_type(handle, peer_handle)
                        # type is 2 for XGMI
                        if link_type["hops"] != 1 or link_type["type"] != 2:
                            return False
                    except AmdSmiException as error:
                        logger.error("AMD 1 hop XGMI detection failed.", exc_info=error)
                        return False
        return True

    @classmethod
    @with_amdsmi_context
    @lru_cache(maxsize=8)
    def get_device_name(cls, device_id: int = 0) -> str:
        physical_device_id = cls.device_id_to_physical_device_id(device_id)
        handle = amdsmi_get_processor_handles()[physical_device_id]
        asic_info = amdsmi_get_gpu_asic_info(handle)
        asic_info_device_id: str = asic_info["device_id"]
        if asic_info_device_id in _ROCM_DEVICE_ID_NAME_MAP:
            return _ROCM_DEVICE_ID_NAME_MAP[asic_info_device_id]
        return asic_info["market_name"]

    @classmethod
    @with_amdsmi_context
    def get_device_uuid(cls, device_id: int = 0) -> str:
        try:
            device = amdsmi_get_processor_handles()[device_id]
        except AmdSmiException as error:
            logger.error("amdsmi device query failed ", exc_info=error)
            return ""
        try:
            device_uuid = amdsmi_get_gpu_device_uuid(device)
        except AmdSmiException as error:
            logger.error("amdsmi device uuid query failed ", exc_info=error)
        return device_uuid

    @classmethod
    def get_device_total_memory(cls, device_id: int = 0) -> int:
        device_props = torch.cuda.get_device_properties(device_id)
        return device_props.total_memory

    @classmethod
    def apply_config_platform_defaults(cls, vllm_config: "VllmConfig") -> None:
        from vllm._aiter_ops import rocm_aiter_ops
        from vllm.config.compilation import CUDAGraphMode

        compilation_config = vllm_config.compilation_config
        is_eager_execution = compilation_config.cudagraph_mode == CUDAGraphMode.NONE
        use_aiter_fused_moe = rocm_aiter_ops.is_fused_moe_enabled()
        use_aiter_rms_norm = rocm_aiter_ops.is_rmsnorm_enabled()
        use_aiter_fp8_linear = rocm_aiter_ops.is_linear_fp8_enabled()
        use_aiter_fused_se = rocm_aiter_ops.is_fusion_moe_shared_experts_enabled()
        #  Aiter rms norm perform best when CUDA Graph capture is enabled.
        if (
            use_aiter_rms_norm
            and not is_eager_execution
            and "-rms_norm" not in compilation_config.custom_ops
        ):
            compilation_config.custom_ops.append("+rms_norm")

        if use_aiter_fp8_linear and "-quant_fp8" not in compilation_config.custom_ops:
            compilation_config.custom_ops.append("+quant_fp8")

        if use_aiter_fused_se and "-grouped_topk" in compilation_config.custom_ops:
            logger.warning_once(
                "VLLM_ROCM_USE_AITER_FUSION_SHARED_EXPERTS is enabled, which "
                "requires the 'grouped_topk' custom op. Overriding the "
                "user-provided '-grouped_topk'."
            )
            compilation_config.custom_ops.remove("-grouped_topk")
        # Ensure grouped_topk is always enabled when using AITER if
        # its not disabled by user
        if (
            use_aiter_fused_moe
            and "+grouped_topk" not in compilation_config.custom_ops
            and "-grouped_topk" not in compilation_config.custom_ops
        ):
            compilation_config.custom_ops.append("+grouped_topk")

        # Default dispatch to rocm's sparse_attn_indexer implementation
        compilation_config.custom_ops.append("+sparse_attn_indexer")

    @classmethod
    def check_and_update_config(cls, vllm_config: "VllmConfig") -> None:
        from vllm.config.compilation import CUDAGraphMode

        compilation_config = vllm_config.compilation_config
        parallel_config = vllm_config.parallel_config

        if compilation_config.cudagraph_mode.has_full_cudagraphs():
            # decode context parallel does not support full cudagraphs
            if parallel_config.decode_context_parallel_size > 1:
                logger.warning_once(
                    "Decode context parallel (DCP) is enabled, which is "
                    "incompatible with full CUDA graphs. "
                    "Overriding cudagraph_mode to PIECEWISE."
                )
                compilation_config.cudagraph_mode = CUDAGraphMode.PIECEWISE
            # prefill context parallel do not support full cudagraphs
            elif parallel_config.prefill_context_parallel_size > 1:
                logger.warning_once(
                    "Prefill context parallel (PCP) is enabled, which is "
                    "incompatible with full CUDA graphs. "
                    "Overriding cudagraph_mode to PIECEWISE."
                )
                compilation_config.cudagraph_mode = CUDAGraphMode.PIECEWISE

        if parallel_config.worker_cls == "auto":
            parallel_config.worker_cls = "vllm.v1.worker.gpu_worker.Worker"

    @classmethod
    def verify_model_arch(cls, model_arch: str) -> None:
        if model_arch in _ROCM_UNSUPPORTED_MODELS:
            raise ValueError(
                f"Model architecture '{model_arch}' is not supported by ROCm for now."
            )

        if model_arch in _ROCM_PARTIALLY_SUPPORTED_MODELS:
            msg = _ROCM_PARTIALLY_SUPPORTED_MODELS[model_arch]
            logger.warning(
                "Model architecture '%s' is partially supported by ROCm: %s",
                model_arch,
                msg,
            )

    @classmethod
    def verify_quantization(cls, quant: str) -> None:
        super().verify_quantization(quant)
        if quant == "awq" and not envs.VLLM_USE_TRITON_AWQ:
            logger.warning(
                "Using AWQ quantization with ROCm, but VLLM_USE_TRITON_AWQ"
                " is not set, enabling VLLM_USE_TRITON_AWQ."
            )
        os.environ["VLLM_USE_TRITON_AWQ"] = "1"

    @classmethod
    def get_punica_wrapper(cls) -> str:
        return "vllm.lora.punica_wrapper.punica_gpu.PunicaWrapperGPU"

    @classmethod
    def get_current_memory_usage(
        cls, device: torch.types.Device | None = None
    ) -> float:
        torch.cuda.reset_peak_memory_stats(device)
        free_mem, total_mem = torch.cuda.mem_get_info(device)
        return total_mem - free_mem

    @classmethod
    def get_device_communicator_cls(cls) -> str:
        return (
            "vllm.distributed.device_communicators.cuda_communicator.CudaCommunicator"  # noqa
        )

    @classmethod
    def supports_mx(cls) -> bool:
        return any(gfx in _GCN_ARCH for gfx in ["gfx95"])

    @classmethod
    def supports_fp8(cls) -> bool:
        return any(gfx in _GCN_ARCH for gfx in ["gfx94", "gfx95", "gfx12"])

    @classmethod
    def is_fp8_fnuz(cls) -> bool:
        # only device 0 is checked, this assumes MI300 platforms are homogeneous
        return "gfx94" in _GCN_ARCH

    @classmethod
    def fp8_dtype(cls) -> torch.dtype:
        if cls.is_fp8_fnuz():
            return torch.float8_e4m3fnuz
        else:
            return torch.float8_e4m3fn

    @classmethod
    def use_custom_allreduce(cls) -> bool:
        # We only enable custom allreduce for MI300 series
        return any(gfx in _GCN_ARCH for gfx in ["gfx94", "gfx95"])

    @classmethod
    def opaque_attention_op(cls) -> bool:
        return True

    @classmethod
    def is_navi(cls) -> bool:
        return "gfx1" in _GCN_ARCH

    @classmethod
    def get_static_graph_wrapper_cls(cls) -> str:
        return "vllm.compilation.cuda_graph.CUDAGraphWrapper"

    @classmethod
    def stateless_init_device_torch_dist_pg(
        cls,
        backend: str,
        prefix_store: PrefixStore,
        group_rank: int,
        group_size: int,
        timeout: timedelta,
    ) -> ProcessGroup:
        assert is_nccl_available()
        pg: ProcessGroup = ProcessGroup(
            prefix_store,
            group_rank,
            group_size,
        )
        from torch.distributed.distributed_c10d import ProcessGroupNCCL

        backend_options = ProcessGroupNCCL.Options()
        backend_options._timeout = timeout

        backend_class = ProcessGroupNCCL(
            prefix_store, group_rank, group_size, backend_options
        )
        backend_type = ProcessGroup.BackendType.NCCL
        device = torch.device("cuda")
        pg._set_default_backend(backend_type)
        backend_class._set_sequence_number_for_group()

        pg._register_backend(device, backend_type, backend_class)
        return pg

    @classmethod
    def device_count(cls) -> int:
        return _rocm_device_count_stateless(getattr(envs, cls.device_control_env_var))

    @classmethod
    def check_if_supports_dtype(cls, dtype: torch.dtype):
        if dtype == torch.bfloat16:  # noqa: SIM102
            if not cls.has_device_capability(80):
                capability = cls.get_device_capability()
                gpu_name = cls.get_device_name()

                if capability is None:
                    compute_str = "does not have a compute capability"
                else:
                    version_str = capability.as_version_str()
                    compute_str = f"has compute capability {version_str}"

                raise ValueError(
                    "Bfloat16 is only supported on GPUs "
                    "with compute capability of at least 8.0. "
                    f"Your {gpu_name} GPU {compute_str}. "
                    "You can use float16 instead by explicitly setting the "
                    "`dtype` flag in CLI, for example: --dtype=half."
                )

    @classmethod
    def insert_blocks_to_device(
        cls,
        src_cache: torch.Tensor,
        dst_cache: torch.Tensor,
        src_block_indices: torch.Tensor,
        dst_block_indices: torch.Tensor,
    ) -> None:
        """Copy blocks from src_cache to dst_cache on GPU."""
        _src_cache = src_cache[:, src_block_indices]
        dst_cache[:, dst_block_indices] = _src_cache.to(dst_cache.device)

    @classmethod
    def swap_out_blocks_to_host(
        cls,
        src_cache: torch.Tensor,
        dst_cache: torch.Tensor,
        src_block_indices: torch.Tensor,
        dst_block_indices: torch.Tensor,
    ) -> None:
        """Copy blocks from GPU to host (CPU)."""
        _src_cache = src_cache[:, src_block_indices]
        dst_cache[:, dst_block_indices] = _src_cache.cpu()

    @classmethod
    def support_hybrid_kv_cache(cls) -> bool:
        return True

    @classmethod
    def support_static_graph_mode(cls) -> bool:
        return True

    @classmethod
    def num_compute_units(cls, device_id: int = 0) -> int:
        return torch.cuda.get_device_properties(device_id).multi_processor_count

    @classmethod
    def use_custom_op_collectives(cls) -> bool:
        return True

    @classmethod
    def get_default_ir_op_priority(
        cls, vllm_config: "VllmConfig"
    ) -> "IrOpPriorityConfig":
        from vllm.config.compilation import CompilationMode
        from vllm.config.kernel import IrOpPriorityConfig

        # Native used by default when compiling,
        # use vllm_c kernels where available when no codegen
        # TODO(luka/TJ) use aiter, vllm_c, native by default on ROCm
        cc = vllm_config.compilation_config
        using_inductor = cc.backend == "inductor" and cc.mode != CompilationMode.NONE
        default = ["native"] if using_inductor else ["vllm_c", "native"]

        # This (mostly) preserves previous CustomOp behavior
        # Necessary on ROCm because it's common that users
        # enable rms_norm to use the aiter kernel.
        # TODO(luka/TJ) remove env vars completely
        if (
            cc.is_custom_op_enabled("rms_norm")
            and envs.VLLM_ROCM_USE_AITER
            and envs.VLLM_ROCM_USE_AITER_RMSNORM
        ):
            rms_norm = ["aiter"] + default
        else:
            rms_norm = default

        return IrOpPriorityConfig.with_default(default, rms_norm=rms_norm)