xc-llm-ascend/csrc/utils/inc/kernel/comm_args.h

#ifndef COMM_ARGS_H
#define COMM_ARGS_H
#include <cstdint>

#define FORCE_INLINE_AICORE __attribute__((always_inline)) inline __aicore__
#include "kernel_operator.h"

namespace Moe {
constexpr int CAM_MAX_RANK_SIZE = 384; // Maximum number of NPU cards supported by the communication library

constexpr int64_t IPC_BUFF_MAX_SIZE = 100 * 1024 * 1024;
constexpr int64_t IPC_DATA_OFFSET = 2 * 1024 * 1024; // First 2MB as flag, then 100MB as data storage
constexpr int64_t PING_PONG_SIZE = 2;
constexpr int64_t UB_SINGLE_DMA_SIZE_MAX = 190 * 1024;
constexpr int64_t SMALL_DATA_SIZE = 1 * 1024 * 1024;
constexpr int64_t UB_SINGLE_PING_PONG_ADD_SIZE_MAX = UB_SINGLE_DMA_SIZE_MAX / 2;
constexpr int UB_ALIGN_SIZE = 32;
constexpr int64_t MAGIC_ALIGN_COUNT = UB_ALIGN_SIZE / sizeof(int32_t);

constexpr uint8_t COMM_NUM = 2;  // Size of communication domain
constexpr uint8_t COMM_EP_IDX = 0;
constexpr uint8_t COMM_TP_IDX = 1;

constexpr int DFX_COUNT = 50;
constexpr int64_t WAIT_SUCCESS = 112233445566;
constexpr int64_t IPC_CHUNK_FLAG = 0; // Start offset for send recv, chunk flag region
constexpr int64_t MAX_WAIT_ROUND_UNIT = 10 * 1000 * 1000; // Threshold for waiting to get Flag under normal conditions within the same SIO

constexpr static int32_t UB_HEAD_OFFSET = 96;
constexpr static int32_t UB_MID_OFFSET = UB_HEAD_OFFSET + UB_SINGLE_PING_PONG_ADD_SIZE_MAX + UB_ALIGN_SIZE;
constexpr static int64_t UB_FLAG_SIZE = 2 * 1024;
constexpr static int64_t MAX_CORE_NUM = 48;
constexpr static uint64_t STATE_WIN_OFFSET = 900 * 1024;
constexpr static int64_t COMPARE_ALIGN_SIZE = 256;

constexpr static int64_t UB_SINGLE_TOTAL_SIZE_MAX = 192 * 1024;
constexpr static int64_t START_OFFSET_FOR_SHARE = 512;

enum Op : int {
    COPYONLY = -1,
    ADD = 0,
    MUL = 1,
    MAX = 2,
    MIN = 3
};

struct CommArgs {
    int rank = 0;           // attr rank_id, global rank
    int localRank = -1;
    int rankSize = 0; // global rank size
    int localRankSize = -1;  // This parameter refers to the number of cards interconnected in fullmesh
    uint32_t extraFlag = 0; // 32 bit map, the specific meaning of each bit is above in this file
    int testFlag = 0;
    GM_ADDR peerMems[CAM_MAX_RANK_SIZE] = {}; // Buffer obtained from initialization, all allreduce is the same parameter
    /**
     * @param sendCountMatrix One-dimensional array with a size of rankSize*rankSize
     * eg: The value of sendCountMatrix[1] corresponds to the [0][1] of the two-dimensional array, indicating the number of data that card 0 needs to send to card 1
     */
    int64_t sendCountMatrix[CAM_MAX_RANK_SIZE * CAM_MAX_RANK_SIZE] = {};  // for all2allvc
    int64_t sendCounts[CAM_MAX_RANK_SIZE] = {}; // for all2allv
    int64_t sdispls[CAM_MAX_RANK_SIZE] = {};    // for all2allv
    int64_t recvCounts[CAM_MAX_RANK_SIZE] = {};  // for all2allv
    int64_t rdispls[CAM_MAX_RANK_SIZE] = {};     // for all2allv
    int64_t batchSize;
    int64_t hiddenSize;
    int64_t topk;
    int64_t sharedExpertRankNum;
    int64_t expertNumPerRank;
    int64_t dfx[DFX_COUNT] = {};
};
}
#endif // COMM_ARGS_H
[Kernel] Add moe normal ops (#4810) ### What this PR does / why we need it? 1.Add the implementation of normal Aclnn operators: MoeCombineNormal, MoeDispatchNormal, NotifyDispatch，and DispatchLayout. - MoeCombineNormal: Implements the combine logic within MoE operations. - MoeDispatchNormal: Implements the dispatch logic within MoE operations. - NotifyDispatch: Exchanges topk_idx information among different ranks to calculate the device memory required for the dispatch stage. - DispatchLayout: Used to calculate information related to the device memory layout for the dispatch stage. 2.Provide PyTorch interfaces for normal operators—get_dispatch_layout, dispatch_prefill, and combine_prefill—to be used for MoE communication during the prefill stage in vLLM. - get_dispatch_layout: Calculates information related to the device memory layout for the dispatch operator, and is called before dispatch_prefill. - dispatch_prefill: Initiates the dispatch operation. - combine_prefill: Initiates the combine operation. ### Does this PR introduce _any_ user-facing change? No ### How was this patch tested? The functionality has already been validated using the local Qwen model. Test cases will be added after support for multi-NPU use cases in the CI pipeline is finalized. - vLLM version: v0.12.0 - vLLM main: https://github.com/vllm-project/vllm/commit/ad32e3e19ccf0526cb6744a5fed09a138a5fb2f9 Signed-off-by: shiro-zzzz <zhangdianhao@huawei.com> 2025-12-10 17:15:28 +08:00			`#ifndef COMM_ARGS_H`
			`#define COMM_ARGS_H`
			`#include <cstdint>`

			`#define FORCE_INLINE_AICORE __attribute__((always_inline)) inline __aicore__`
			`#include "kernel_operator.h"`

			`namespace Moe {`
			`constexpr int CAM_MAX_RANK_SIZE = 384; // Maximum number of NPU cards supported by the communication library`

			`constexpr int64_t IPC_BUFF_MAX_SIZE = 100 * 1024 * 1024;`
			`constexpr int64_t IPC_DATA_OFFSET = 2 * 1024 * 1024; // First 2MB as flag, then 100MB as data storage`
			`constexpr int64_t PING_PONG_SIZE = 2;`
			`constexpr int64_t UB_SINGLE_DMA_SIZE_MAX = 190 * 1024;`
			`constexpr int64_t SMALL_DATA_SIZE = 1 * 1024 * 1024;`
			`constexpr int64_t UB_SINGLE_PING_PONG_ADD_SIZE_MAX = UB_SINGLE_DMA_SIZE_MAX / 2;`
			`constexpr int UB_ALIGN_SIZE = 32;`
			`constexpr int64_t MAGIC_ALIGN_COUNT = UB_ALIGN_SIZE / sizeof(int32_t);`

			`constexpr uint8_t COMM_NUM = 2; // Size of communication domain`
			`constexpr uint8_t COMM_EP_IDX = 0;`
			`constexpr uint8_t COMM_TP_IDX = 1;`

			`constexpr int DFX_COUNT = 50;`
			`constexpr int64_t WAIT_SUCCESS = 112233445566;`
			`constexpr int64_t IPC_CHUNK_FLAG = 0; // Start offset for send recv, chunk flag region`
			`constexpr int64_t MAX_WAIT_ROUND_UNIT = 10 * 1000 * 1000; // Threshold for waiting to get Flag under normal conditions within the same SIO`

			`constexpr static int32_t UB_HEAD_OFFSET = 96;`
			`constexpr static int32_t UB_MID_OFFSET = UB_HEAD_OFFSET + UB_SINGLE_PING_PONG_ADD_SIZE_MAX + UB_ALIGN_SIZE;`
			`constexpr static int64_t UB_FLAG_SIZE = 2 * 1024;`
			`constexpr static int64_t MAX_CORE_NUM = 48;`
			`constexpr static uint64_t STATE_WIN_OFFSET = 900 * 1024;`
			`constexpr static int64_t COMPARE_ALIGN_SIZE = 256;`

			`constexpr static int64_t UB_SINGLE_TOTAL_SIZE_MAX = 192 * 1024;`
			`constexpr static int64_t START_OFFSET_FOR_SHARE = 512;`

			`enum Op : int {`
			`COPYONLY = -1,`
			`ADD = 0,`
			`MUL = 1,`
			`MAX = 2,`
			`MIN = 3`
			`};`

			`struct CommArgs {`
			`int rank = 0; // attr rank_id, global rank`
			`int localRank = -1;`
			`int rankSize = 0; // global rank size`
			`int localRankSize = -1; // This parameter refers to the number of cards interconnected in fullmesh`
			`uint32_t extraFlag = 0; // 32 bit map, the specific meaning of each bit is above in this file`
			`int testFlag = 0;`
			`GM_ADDR peerMems[CAM_MAX_RANK_SIZE] = {}; // Buffer obtained from initialization, all allreduce is the same parameter`
			`/**`
			`* @param sendCountMatrix One-dimensional array with a size of rankSize*rankSize`
			`* eg: The value of sendCountMatrix[1] corresponds to the [0][1] of the two-dimensional array, indicating the number of data that card 0 needs to send to card 1`
			`*/`
			`int64_t sendCountMatrix[CAM_MAX_RANK_SIZE * CAM_MAX_RANK_SIZE] = {}; // for all2allvc`
			`int64_t sendCounts[CAM_MAX_RANK_SIZE] = {}; // for all2allv`
			`int64_t sdispls[CAM_MAX_RANK_SIZE] = {}; // for all2allv`
			`int64_t recvCounts[CAM_MAX_RANK_SIZE] = {}; // for all2allv`
			`int64_t rdispls[CAM_MAX_RANK_SIZE] = {}; // for all2allv`
			`int64_t batchSize;`
			`int64_t hiddenSize;`
			`int64_t topk;`
			`int64_t sharedExpertRankNum;`
			`int64_t expertNumPerRank;`
			`int64_t dfx[DFX_COUNT] = {};`
			`};`
			`}`
			`#endif // COMM_ARGS_H`