internode.hip

// !!! This is a file automatically generated by hipify!!!
#include <ATen/dtk_macros.h>
#include "hip/hip_runtime.h"
#include "buffer.cuh"
#include "configs.cuh"
#include "launch_hip.cuh"
#include "utils_hip.cuh"

#ifndef DISABLE_ROCSHMEM

#include <rocshmem/rocshmem.hpp>

// TODO: fix unroll warnings
// #ifdef __clang__
// #pragma clang diagnostic push
// #pragma clang diagnostic ignored "-Wpass-failed"
// #pragma clang diagnostic ignored "-Wdeprecated-volatile"
// #endif // __clang__

namespace deep_ep {

namespace internode {

extern rocshmem::rocshmem_team_t cpu_rdma_team;

struct SourceMeta {
    int src_rdma_rank, is_token_in_nvl_rank_bits;

    EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS == 8, "Invalid number of maximum NVL peers");

    __forceinline__ SourceMeta() = default;

    // TODO: faster encoding
    __device__ __forceinline__ SourceMeta(int rdma_rank, const bool *is_token_in_nvl_ranks) {
        src_rdma_rank             = rdma_rank;
        is_token_in_nvl_rank_bits = is_token_in_nvl_ranks[0];
#pragma unroll
        for (int i = 1; i < NUM_MAX_NVL_PEERS; ++i)
            is_token_in_nvl_rank_bits |= is_token_in_nvl_ranks[i] << i;
    }

    __device__ __forceinline__ bool is_token_in_nvl_rank(int nvl_rank) const {
        return (is_token_in_nvl_rank_bits >> nvl_rank) & 1;
    }
};

int get_source_meta_bytes() {
    return sizeof(SourceMeta);
}

__host__ __device__ __forceinline__ int get_num_bytes_per_rdma_token(int hidden_int4,
                                                                     int num_scales,
                                                                     int num_topk_idx,
                                                                     int num_topk_weights) {
    return static_cast<int>(ALIGN(hidden_int4 * sizeof(int4) + sizeof(SourceMeta) +
                                      num_scales * sizeof(float) + num_topk_idx * sizeof(int) +
                                      num_topk_weights * sizeof(float),
                                  sizeof(int4)));
}

__host__ __device__ __forceinline__ std::pair<int, int>
get_rdma_clean_meta(int hidden_int4, int num_scales, int num_topk_idx, int num_topk_weights,
                    int num_rdma_ranks, int num_rdma_recv_buffer_tokens, int num_sms) {
    // Return `int32_t` offset and count to clean
    return {(get_num_bytes_per_rdma_token(hidden_int4, num_scales, num_topk_idx, num_topk_weights) *
             num_rdma_recv_buffer_tokens * num_rdma_ranks * 2 * num_sms) /
                sizeof(int),
            (NUM_MAX_NVL_PEERS * 2 + 4) * num_rdma_ranks * 2 * num_sms};
}
__host__ __device__ __forceinline__ std::pair<int, int>
get_nvl_clean_meta(int hidden_int4, int num_scales, int num_topk_idx, int num_topk_weights,
                   int num_rdma_ranks, int num_nvl_ranks, int num_nvl_recv_buffer_tokens,
                   int num_sms) {
    // Return `int32_t` offset and to clean
    EP_STATIC_ASSERT(sizeof(SourceMeta) % sizeof(int) == 0,
                              "Invalid size of `SourceMeta`");
    return {
        (num_nvl_recv_buffer_tokens *
         (hidden_int4 * sizeof(int4) + num_scales * sizeof(float) + num_topk_idx * sizeof(int) +
          num_topk_weights * sizeof(float) + sizeof(SourceMeta)) *
         num_nvl_ranks * num_sms) /
            sizeof(int),
        num_nvl_ranks * (2 * num_rdma_ranks + 2) * num_sms,
    };
}

template <bool kLowLatencyMode>
__forceinline__ __device__ int translate_dst_rdma_rank(const int dst_rdma_rank,
                                                       const int nvl_rank) {
    return kLowLatencyMode ? (dst_rdma_rank * NUM_MAX_NVL_PEERS + nvl_rank) : dst_rdma_rank;
}

template <bool kLowLatencyMode>
__forceinline__ __device__ void
nvshmem_barrier_with_same_gpu_idx(const rocshmem::rocshmem_team_t &rdma_team) {
    // NOTE: shmem_device_barrier_all() might be an issue as
    // it doesn't follow OpenSHMEM specification on ROCm
    // kLowLatencyMode
    //     ? void(rocshmem::rocshmem_ctx_barrier(rocshmem::ROCSHMEM_CTX_DEFAULT, rdma_team))
    //     : rocshmem::rocshmem_barrier_all();
    rocshmem::rocshmem_barrier_all();
}

template <bool kLowLatencyMode, int kNumRDMARanks>
__global__ void
notify_dispatch(const int *num_tokens_per_rank, int *moe_recv_counter_mapped, int num_ranks,
                const int *num_tokens_per_rdma_rank, int *moe_recv_rdma_counter_mapped,
                const int *num_tokens_per_expert, int *moe_recv_expert_counter_mapped,
                int num_experts, const bool *is_token_in_rank, int num_tokens, int num_channels,
                int expert_alignment, const int rdma_clean_offset, const int rdma_num_int_clean,
                const int nvl_clean_offset, const int nvl_num_int_clean,
                int *rdma_channel_prefix_matrix, int *recv_rdma_rank_prefix_sum,
                int *gbl_channel_prefix_matrix, int *recv_gbl_rank_prefix_sum,
                void *rdma_buffer_ptr, void **buffer_ptrs, int **barrier_signal_ptrs, int rank,
                const rocshmem::rocshmem_team_t rdma_team) {
    auto sm_id     = static_cast<int>(blockIdx.x);
    auto thread_id = static_cast<int>(threadIdx.x), warp_id = thread_id / kWarpSize,
         lane_id     = get_lane_id();
    auto num_threads = static_cast<int>(blockDim.x), num_warps = num_threads / kWarpSize;

    auto rdma_rank = rank / NUM_MAX_NVL_PEERS, nvl_rank = rank % NUM_MAX_NVL_PEERS;
    auto num_rdma_experts = num_experts / kNumRDMARanks,
         num_nvl_experts  = num_rdma_experts / NUM_MAX_NVL_PEERS;

    if (sm_id == 0) {
        // Communication with others
        // Global barrier: the first warp do intra-node sync, the second warp do internode sync
        EP_DEVICE_ASSERT(num_warps > 1);
        EP_DEVICE_ASSERT(kNumRDMARanks <= num_threads);
        if (thread_id == kWarpSize)
            nvshmem_barrier_with_same_gpu_idx<kLowLatencyMode>(rdma_team);

        barrier_block<NUM_MAX_NVL_PEERS>(barrier_signal_ptrs, nvl_rank);
        __syncthreads();

        // Send numbers of tokens per rank/expert to RDMA ranks
        auto rdma_buffer_ptr_int        = reinterpret_cast<int *>(rdma_buffer_ptr);
        auto rdma_recv_num_tokens_mixed = SymBuffer<int>(
            rdma_buffer_ptr, NUM_MAX_NVL_PEERS + num_rdma_experts + 1, kNumRDMARanks);

        // Clean up for later data dispatch
        EP_DEVICE_ASSERT(rdma_recv_num_tokens_mixed.total_bytes <=
                                  rdma_clean_offset * sizeof(int));
        for (int i = thread_id; i < rdma_num_int_clean; i += num_threads)
            rdma_buffer_ptr_int[rdma_clean_offset + i] = 0;

        // Copy to send buffer
        for (int i = thread_id; i < num_ranks; i += num_threads)
            rdma_recv_num_tokens_mixed.send_buffer(i / NUM_MAX_NVL_PEERS)[i % NUM_MAX_NVL_PEERS] =
                num_tokens_per_rank[i];
        for (int i = thread_id; i < num_experts; i += num_threads)
            rdma_recv_num_tokens_mixed.send_buffer(
                i / num_rdma_experts)[NUM_MAX_NVL_PEERS + i % num_rdma_experts] =
                num_tokens_per_expert[i];
        if (thread_id < kNumRDMARanks)
            rdma_recv_num_tokens_mixed.send_buffer(
                thread_id)[NUM_MAX_NVL_PEERS + num_rdma_experts] =
                num_tokens_per_rdma_rank[thread_id];
        __syncthreads();

        // Issue send
        // TODO: more light fence or barrier or signaling
        // TODO: overlap EP barrier and NVL cleaning
        if (thread_id < kNumRDMARanks) {
            rocshmem::rocshmem_int_put_nbi(
                rdma_recv_num_tokens_mixed.recv_buffer(rdma_rank),
                rdma_recv_num_tokens_mixed.send_buffer(thread_id),
                NUM_MAX_NVL_PEERS + num_rdma_experts + 1,
                translate_dst_rdma_rank<kLowLatencyMode>(thread_id, nvl_rank));
        }
        __syncthreads();
        if (thread_id == 0)
            nvshmem_barrier_with_same_gpu_idx<kLowLatencyMode>(rdma_team);

        __syncthreads();

        // NVL buffers
        auto nvl_send_buffer = thread_id < NUM_MAX_NVL_PEERS ? buffer_ptrs[thread_id] : nullptr;
        auto nvl_recv_buffer = buffer_ptrs[nvl_rank];
        auto nvl_reduced_num_tokens_per_expert =
            Buffer<int>(nvl_recv_buffer, num_rdma_experts).advance_also(nvl_send_buffer);
        auto nvl_send_num_tokens_per_rank =
            AsymBuffer<int>(nvl_send_buffer, kNumRDMARanks, NUM_MAX_NVL_PEERS);
        auto nvl_send_num_tokens_per_expert =
            AsymBuffer<int>(nvl_send_buffer, num_nvl_experts, NUM_MAX_NVL_PEERS);
        auto nvl_recv_num_tokens_per_rank =
            AsymBuffer<int>(nvl_recv_buffer, kNumRDMARanks, NUM_MAX_NVL_PEERS);
        auto nvl_recv_num_tokens_per_expert =
            AsymBuffer<int>(nvl_recv_buffer, num_nvl_experts, NUM_MAX_NVL_PEERS);

        // Clean up for later data dispatch
        auto nvl_buffer_ptr_int = reinterpret_cast<int *>(buffer_ptrs[nvl_rank]);
        EP_DEVICE_ASSERT(nvl_reduced_num_tokens_per_expert.total_bytes +
                                      nvl_send_num_tokens_per_rank.total_bytes +
                                      nvl_send_num_tokens_per_expert.total_bytes <=
                                  nvl_clean_offset * sizeof(int));
        for (int i = thread_id; i < nvl_num_int_clean; i += num_threads)
            nvl_buffer_ptr_int[nvl_clean_offset + i] = 0;

        // Reduce number of tokens per expert into the NVL send buffer
        // TODO: may use NVSHMEM reduction
        EP_DEVICE_ASSERT(num_rdma_experts <= num_threads);
        if (thread_id < num_rdma_experts) {
            int sum = 0;
#pragma unroll
            for (int i = 0; i < kNumRDMARanks; ++i)
                sum += rdma_recv_num_tokens_mixed.recv_buffer(i)[NUM_MAX_NVL_PEERS + thread_id];
            nvl_reduced_num_tokens_per_expert[thread_id] = sum;
        }
        __syncthreads();

        // Reduce RDMA received tokens
        if (thread_id == 0) {
            int sum = 0;
#pragma unroll
            for (int i = 0; i < kNumRDMARanks; ++i) {
                sum +=
                    rdma_recv_num_tokens_mixed.recv_buffer(i)[NUM_MAX_NVL_PEERS + num_rdma_experts];
                recv_rdma_rank_prefix_sum[i] = sum;
            }
            while (ld_volatile_global(moe_recv_rdma_counter_mapped) != -1)
                ;
            *moe_recv_rdma_counter_mapped = sum;
        }

        // Send numbers of tokens per rank/expert to NVL ranks
        EP_DEVICE_ASSERT(NUM_MAX_NVL_PEERS <= num_threads);
        if (thread_id < NUM_MAX_NVL_PEERS) {
#pragma unroll
            for (int i = 0; i < kNumRDMARanks; ++i)
                nvl_send_num_tokens_per_rank.buffer(nvl_rank)[i] =
                    rdma_recv_num_tokens_mixed.recv_buffer(i)[thread_id];
            for (int i = 0; i < num_nvl_experts; ++i)
                nvl_send_num_tokens_per_expert.buffer(nvl_rank)[i] =
                    nvl_reduced_num_tokens_per_expert[thread_id * num_nvl_experts + i];
        }
        memory_fence();
        __syncthreads();
        barrier_block<NUM_MAX_NVL_PEERS>(barrier_signal_ptrs, nvl_rank);
        __syncthreads();

        // Reduce number of tokens per rank/expert
        EP_DEVICE_ASSERT(num_nvl_experts <= num_threads);
        if (thread_id == 0) {
            int sum = 0;
            for (int i = 0; i < num_ranks; ++i) {
                int src_rdma_rank = i / NUM_MAX_NVL_PEERS, src_nvl_rank = i % NUM_MAX_NVL_PEERS;
                sum += nvl_recv_num_tokens_per_rank.buffer(src_nvl_rank)[src_rdma_rank];
                recv_gbl_rank_prefix_sum[i] = sum;
            }
            while (ld_volatile_global(moe_recv_counter_mapped) != -1)
                ;
            *moe_recv_counter_mapped = sum;
        }
        if (thread_id < num_nvl_experts) {
            int sum = 0;
#pragma unroll
            for (int i = 0; i < NUM_MAX_NVL_PEERS; ++i)
                sum += nvl_recv_num_tokens_per_expert.buffer(i)[thread_id];
            sum = (sum + expert_alignment - 1) / expert_alignment * expert_alignment;
            while (ld_volatile_global(moe_recv_expert_counter_mapped + thread_id) != -1)
                ;
            moe_recv_expert_counter_mapped[thread_id] = sum;
        }

        // Finally barrier
        __syncthreads();
        if (thread_id == kWarpSize)
            nvshmem_barrier_with_same_gpu_idx<kLowLatencyMode>(rdma_team);

        barrier_block<NUM_MAX_NVL_PEERS>(barrier_signal_ptrs, nvl_rank);
    } else {
        // Calculate meta data
        int dst_rdma_rank = sm_id - 1;
        for (int channel_id = warp_id; channel_id < num_channels; channel_id += num_warps) {
            int token_start_idx, token_end_idx;
            get_channel_task_range(num_tokens, num_channels, channel_id, token_start_idx,
                                   token_end_idx);

            // Iterate over tokens
            int total_count = 0, per_nvl_rank_count[NUM_MAX_NVL_PEERS] = {0};
            for (int64_t i = token_start_idx + lane_id; i < token_end_idx; i += kWarpSize) {
                EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS * sizeof(bool) == sizeof(uint64_t),
                                          "Invalid number of NVL peers");
                auto is_token_in_rank_uint64 = *reinterpret_cast<const uint64_t *>(
                    is_token_in_rank + i * num_ranks + dst_rdma_rank * NUM_MAX_NVL_PEERS);
                auto is_token_in_rank_values =
                    reinterpret_cast<const bool *>(&is_token_in_rank_uint64);
#pragma unroll
                for (int j = 0; j < NUM_MAX_NVL_PEERS; ++j)
                    per_nvl_rank_count[j] += is_token_in_rank_values[j];
                total_count += (is_token_in_rank_uint64 != 0);
            }

            // Warp reduce
            total_count = warp_reduce_sum(total_count);
#pragma unroll
            for (int i = 0; i < NUM_MAX_NVL_PEERS; ++i)
                per_nvl_rank_count[i] = warp_reduce_sum(per_nvl_rank_count[i]);

            // Write into channel matrix
            if (lane_id == 0) {
#pragma unroll
                for (int i = 0; i < NUM_MAX_NVL_PEERS; ++i)
                    gbl_channel_prefix_matrix[(dst_rdma_rank * NUM_MAX_NVL_PEERS + i) *
                                                  num_channels +
                                              channel_id] = per_nvl_rank_count[i];
                rdma_channel_prefix_matrix[dst_rdma_rank * num_channels + channel_id] = total_count;
            }
        }

        // Calculate prefix sum
        __syncthreads();
        if (thread_id == 0) {
            auto prefix_row = rdma_channel_prefix_matrix + dst_rdma_rank * num_channels;
            for (int i = 1; i < num_channels; ++i)
                prefix_row[i] += prefix_row[i - 1];
        }

        EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS <= kWarpSize, "Invalid number of NVL peers");
        if (thread_id < NUM_MAX_NVL_PEERS) {
            auto prefix_row = gbl_channel_prefix_matrix +
                              (dst_rdma_rank * NUM_MAX_NVL_PEERS + thread_id) * num_channels;
            for (int i = 1; i < num_channels; ++i)
                prefix_row[i] += prefix_row[i - 1];
        }
    }
}

void notify_dispatch(const int *num_tokens_per_rank, int *moe_recv_counter_mapped, int num_ranks,
                     const int *num_tokens_per_rdma_rank, int *moe_recv_rdma_counter_mapped,
                     const int *num_tokens_per_expert, int *moe_recv_expert_counter_mapped,
                     int num_experts, const bool *is_token_in_rank, int num_tokens,
                     int num_channels, int hidden_int4, int num_scales, int num_topk,
                     int expert_alignment, int *rdma_channel_prefix_matrix,
                     int *recv_rdma_rank_prefix_sum, int *gbl_channel_prefix_matrix,
                     int *recv_gbl_rank_prefix_sum, void *rdma_buffer_ptr,
                     int num_max_rdma_chunked_recv_tokens, void **buffer_ptrs,
                     int num_max_nvl_chunked_recv_tokens, int **barrier_signal_ptrs, int rank,
                     hipStream_t stream, int64_t num_rdma_bytes, int64_t num_nvl_bytes,
                     bool low_latency_mode) {
#define NOTIFY_DISPATCH_LAUNCH_CASE(num_rdma_ranks)                                                \
    {                                                                                              \
        auto notify_dispatch_func = low_latency_mode ? notify_dispatch<true, num_rdma_ranks>       \
                                                     : notify_dispatch<false, num_rdma_ranks>;     \
        LAUNCH_KERNEL_NON_COOPERATIVE(                                                             \
            &cfg, notify_dispatch_func, num_tokens_per_rank, moe_recv_counter_mapped, num_ranks,   \
            num_tokens_per_rdma_rank, moe_recv_rdma_counter_mapped, num_tokens_per_expert,         \
            moe_recv_expert_counter_mapped, num_experts, is_token_in_rank, num_tokens,             \
            num_channels, expert_alignment, rdma_clean_meta.first, rdma_clean_meta.second,         \
            nvl_clean_meta.first, nvl_clean_meta.second, rdma_channel_prefix_matrix,               \
            recv_rdma_rank_prefix_sum, gbl_channel_prefix_matrix, recv_gbl_rank_prefix_sum,        \
            rdma_buffer_ptr, buffer_ptrs, barrier_signal_ptrs, rank, cpu_rdma_team);               \
    }                                                                                              \
    break

    constexpr int kNumThreads    = 256;
    const auto    num_rdma_ranks = num_ranks / NUM_MAX_NVL_PEERS;

    // Get clean meta
    auto rdma_clean_meta =
        get_rdma_clean_meta(hidden_int4, num_scales, num_topk, num_topk, num_rdma_ranks,
                            num_max_rdma_chunked_recv_tokens, num_channels);
    auto nvl_clean_meta =
        get_nvl_clean_meta(hidden_int4, num_scales, num_topk, num_topk, num_rdma_ranks,
                           NUM_MAX_NVL_PEERS, num_max_nvl_chunked_recv_tokens, num_channels);
    EP_HOST_ASSERT((rdma_clean_meta.first + rdma_clean_meta.second) * sizeof(int) <=
                       num_rdma_bytes);
    EP_HOST_ASSERT((nvl_clean_meta.first + nvl_clean_meta.second) * sizeof(int) <=
                       num_nvl_bytes);
    EP_HOST_ASSERT(num_rdma_bytes < std::numeric_limits<int>::max());
    EP_HOST_ASSERT(num_nvl_bytes < std::numeric_limits<int>::max());

    // Launch kernel
    SETUP_LAUNCH_CONFIG(1 + num_rdma_ranks, kNumThreads, stream);
    SWITCH_RDMA_RANKS(NOTIFY_DISPATCH_LAUNCH_CASE);
#undef NOTIFY_DISPATCH_LAUNCH_CASE
}

// At most 8 RDMA ranks to be sent
constexpr int get_num_topk_rdma_ranks(int num_rdma_ranks) {
    return num_rdma_ranks < 8 ? num_rdma_ranks : 8;
}


template <bool kLowLatencyMode,
          int kNumRDMARanks,
          bool kCachedMode,
          int kNumDispatchRDMASenderWarps,
          int kNumTopkRDMARanks = get_num_topk_rdma_ranks(kNumRDMARanks)>
__global__ void __launch_bounds__(((1 + NUM_MAX_NVL_PEERS) * kWarpSize), 1)
dispatch(int4 *recv_x, float *recv_x_scales, int64_t *recv_topk_idx, float *recv_topk_weights,
        SourceMeta *recv_src_meta, const int4 *x, const float *x_scales,
        const int64_t *topk_idx, const float *topk_weights, int *send_rdma_head,
        int *send_nvl_head, int *recv_rdma_channel_prefix_matrix,
        int *recv_gbl_channel_prefix_matrix, const int *rdma_channel_prefix_matrix,
        const int *recv_rdma_rank_prefix_sum, const int *gbl_channel_prefix_matrix,
        const int *recv_gbl_rank_prefix_sum, const bool *is_token_in_rank, int num_tokens,
        int hidden_int4, int num_scales, int num_topk, int num_experts, int scale_token_stride,
        int scale_hidden_stride, void *rdma_buffer_ptr, int num_max_rdma_chunked_send_tokens,
        int num_max_rdma_chunked_recv_tokens, void **buffer_ptrs,
        int num_max_nvl_chunked_send_tokens, int num_max_nvl_chunked_recv_tokens, int rank,
        int num_ranks) {
    enum class WarpRole {
        kRDMASender,            // 从x写入到RDMA发送缓存
        kRDMASenderCoordinator, // 从RDMA发送缓存写入到远端rdma_rank接收缓存
        kRDMAAndNVLForwarder,   // 从RDMA接收缓存转写到ipc nvl缓存
        kForwarderCoordinator,  // 向远端RDMA确认接收
        kNVLReceivers           // 从nvl缓存写入到recv_x
    };

    __shared__ rocshmem::rocshmem_ctx_t ctx;
    rocshmem::rocshmem_wg_ctx_create(0, &ctx);

    const auto sm_id       = static_cast<int>(blockIdx.x);
    const auto num_threads = static_cast<int>(blockDim.x), num_warps = num_threads / kWarpSize;
    const auto thread_id   = static_cast<int>(threadIdx.x), warp_id = thread_id / kWarpSize, lane_id = get_lane_id();
    const auto num_channels = static_cast<int>(gridDim.x) / NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL,
               channel_id   = sm_id / NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL;
    const auto rdma_rank = rank / NUM_MAX_NVL_PEERS, nvl_rank = rank % NUM_MAX_NVL_PEERS;

    EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS * sizeof(bool) == sizeof(uint64_t), "Invalid number of NVL peers");
    EP_DEVICE_ASSERT(num_warps == 1 + NUM_MAX_NVL_PEERS);

    const auto role_meta = [=]() -> std::pair<WarpRole, int> {
        if (sm_id % NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL == 0) {
            if(warp_id < kNumDispatchRDMASenderWarps) {
                return {WarpRole::kRDMASender, -1};
            } else if(warp_id == kNumDispatchRDMASenderWarps) {
                return {WarpRole::kRDMASenderCoordinator, -1};
            }
        } else if (sm_id % NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL == 1) {
            if(warp_id < NUM_MAX_NVL_PEERS) {
                return {WarpRole::kRDMAAndNVLForwarder, (warp_id + channel_id) % NUM_MAX_NVL_PEERS};
            } else {
                return {WarpRole::kForwarderCoordinator, warp_id - NUM_MAX_NVL_PEERS};
            }
        } else {
            return {WarpRole::kNVLReceivers, (warp_id + channel_id + 1) % NUM_MAX_NVL_PEERS};
        }
    }();

    auto warp_role = role_meta.first;
    auto target_rank = role_meta.second; // Not applicable for RDMA senders
    // if(lane_id==0){
    //     printf("tid=%d, bid=%d, warp_role=%d\n", threadIdx.x, blockIdx.x, warp_role);
    // }

    // RDMA symmetric layout
    auto hidden_bytes             = hidden_int4 * sizeof(int4);
    auto num_bytes_per_rdma_token = get_num_bytes_per_rdma_token(hidden_int4, num_scales, num_topk, num_topk);
    auto rdma_channel_data = SymBuffer<int8_t>(rdma_buffer_ptr, num_max_rdma_chunked_recv_tokens * num_bytes_per_rdma_token, kNumRDMARanks, channel_id, num_channels);
    auto rdma_channel_meta = SymBuffer<int>(rdma_buffer_ptr, NUM_MAX_NVL_PEERS * 2 + 2, kNumRDMARanks, channel_id, num_channels);
    auto rdma_channel_head = SymBuffer<uint64_t, false>(rdma_buffer_ptr, 1, kNumRDMARanks, channel_id, num_channels);
    auto rdma_channel_tail = SymBuffer<uint64_t, false>(rdma_buffer_ptr, 1, kNumRDMARanks, channel_id, num_channels);

    // NVL buffer layouts
    // NOTES: `rs_wr_buffer_ptr` means "Read for Senders, Write for Receivers", `ws_rr_buffer_ptr` means "Write for Senders, Read for Receivers"
    void *rs_wr_buffer_ptr = nullptr, *ws_rr_buffer_ptr = nullptr;
    int rs_wr_rank = 0, ws_rr_rank = 0;
    if (warp_role == WarpRole::kRDMAAndNVLForwarder)
        rs_wr_buffer_ptr = buffer_ptrs[nvl_rank], ws_rr_buffer_ptr = buffer_ptrs[target_rank], rs_wr_rank = nvl_rank, ws_rr_rank = target_rank;
    if (warp_role == WarpRole::kNVLReceivers)
        rs_wr_buffer_ptr = buffer_ptrs[target_rank], ws_rr_buffer_ptr = buffer_ptrs[nvl_rank], rs_wr_rank = target_rank, ws_rr_rank = nvl_rank;

    // Allocate buffers
    auto nvl_channel_x = AsymBuffer<int4>(ws_rr_buffer_ptr, num_max_nvl_chunked_recv_tokens * hidden_int4, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);
    auto nvl_channel_src_meta = AsymBuffer<SourceMeta>(ws_rr_buffer_ptr, num_max_nvl_chunked_recv_tokens, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);
    auto nvl_channel_x_scales = AsymBuffer<float>(ws_rr_buffer_ptr, num_max_nvl_chunked_recv_tokens * num_scales, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);
    auto nvl_channel_topk_idx = AsymBuffer<int>(ws_rr_buffer_ptr, num_max_nvl_chunked_recv_tokens * num_topk, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);
    auto nvl_channel_topk_weights = AsymBuffer<float>(ws_rr_buffer_ptr, num_max_nvl_chunked_recv_tokens * num_topk, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);
    auto nvl_channel_prefix_start = AsymBuffer<int>(ws_rr_buffer_ptr, kNumRDMARanks, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);
    auto nvl_channel_prefix_end = AsymBuffer<int>(ws_rr_buffer_ptr, kNumRDMARanks, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);
    auto nvl_channel_head = AsymBuffer<int>(rs_wr_buffer_ptr, 1, NUM_MAX_NVL_PEERS, channel_id, num_channels, ws_rr_rank).advance_also(ws_rr_buffer_ptr);
    auto nvl_channel_tail = AsymBuffer<int>(ws_rr_buffer_ptr, 1, NUM_MAX_NVL_PEERS, channel_id, num_channels, rs_wr_rank).advance_also(rs_wr_buffer_ptr);

    // RDMA sender warp synchronization
    __shared__ volatile int rdma_send_next_token_idx;
    __shared__ volatile int rdma_send_channel_tail[kNumRDMARanks];
    __shared__ volatile int rdma_send_channel_next_tail[kNumRDMARanks];

    // NVL and RDMA coordinate Forward warp synchronization
    __shared__ volatile int forward_channel_head[NUM_MAX_NVL_PEERS][kNumRDMARanks];
    __shared__ volatile bool forward_channel_retired[NUM_MAX_NVL_PEERS];

    // Place the main logic of your kernel here, using the parameters above.
    if(warp_role == WarpRole::kRDMASender) {
        /*
        这段代码的主要功能是在一个CUDA内核中协调多个线程之间的RDMA发送操作。
        它首先获取当前通道的任务范围，然后清理共享内存，接着计算并发送本通道中的令牌数量。
        然后，它遍历所有的令牌，读取每个令牌的RDMA秩的存在性，获取顺序锁，计算下一个尾部位置，存储RDMA头部，更新最后一个令牌尾部，释放顺序锁，并广播尾部位置。
        最后，它复制相关的数据到对称发送缓冲区。

        kRDMASender主要目的是将发送信息x， x_scale，source_meta, topk_idx, topk_weight等信息填充进入rdma发送缓存，
        期间要同步warp直接对token的依序操作，以及和kForwarderCoordinator, kRDMASenderCoordinator内存同步。
        同时在复制操作时， 使用ld.global.nc.L1::no_allocate.L2::256B， st.global.L1::no_allocate减少L1/L2缓存使用。
        */
        // 获取任务范围
        int token_start_idx, token_end_idx;
        get_channel_task_range(num_tokens, num_channels, channel_id, token_start_idx, token_end_idx);

        // 清理共享内存
        EP_STATIC_ASSERT(kNumRDMARanks <= kWarpSize, "无效的RDMA秩数量");
        if(warp_id == 0 && lane_id == 0) {
            rdma_send_next_token_idx = token_start_idx;
        }
        if(warp_id == 0 && lane_id < kNumRDMARanks) {
            rdma_send_channel_tail[lane_id]      = 0;
            rdma_send_channel_next_tail[lane_id] = 0;
        }

        // 发送本通道中的令牌数量，通过 `-value - 1` 表示
        EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS * 2 + 2 <= kWarpSize, "无效的NVL对等体数量");
        // 对于每个目标RDMA秩，以warp为单位进行迭代。计算发送缓冲区的值，并存储在rdma_channel_meta.send_buffer中
        // 用于填充rdma_channel_meta.send_buffer本节点发送到远端rank, rdma_rank的起始index和结束index
        for(int dst_rdma_rank = warp_id; dst_rdma_rank < kNumRDMARanks; dst_rdma_rank += kNumDispatchRDMASenderWarps) {
            auto dst_ptr = dst_rdma_rank == rdma_rank ? rdma_channel_meta.recv_buffer(dst_rdma_rank) : rdma_channel_meta.send_buffer(dst_rdma_rank);
            if (lane_id < NUM_MAX_NVL_PEERS) {
                dst_ptr[lane_id] = -(channel_id == 0 ? 0 : gbl_channel_prefix_matrix[(dst_rdma_rank * NUM_MAX_NVL_PEERS + lane_id) * num_channels + channel_id - 1]) - 1;
            } else if (lane_id < NUM_MAX_NVL_PEERS * 2) {
                dst_ptr[lane_id] = -gbl_channel_prefix_matrix[(dst_rdma_rank * NUM_MAX_NVL_PEERS + lane_id - NUM_MAX_NVL_PEERS) * num_channels + channel_id] - 1;
            } else if (lane_id == NUM_MAX_NVL_PEERS * 2) {
                dst_ptr[lane_id] = -(channel_id == 0 ? 0 : rdma_channel_prefix_matrix[dst_rdma_rank * num_channels + channel_id - 1]) - 1;
            } else if (lane_id == NUM_MAX_NVL_PEERS * 2 + 1) {
                dst_ptr[lane_id] = -rdma_channel_prefix_matrix[dst_rdma_rank * num_channels + channel_id] - 1;
            }

            syncwarp();
            if (dst_rdma_rank != rdma_rank) {
                rocshmem::rocshmem_ctx_int_put_nbi_wave(
                ctx, rdma_channel_meta.recv_buffer(rdma_rank),
                rdma_channel_meta.send_buffer(dst_rdma_rank), NUM_MAX_NVL_PEERS * 2 + 2,
                translate_dst_rdma_rank<kLowLatencyMode>(dst_rdma_rank, nvl_rank));
            }
        }
        rocshmem::rocshmem_ctx_quiet(ctx);
        // sync_rdma_sender_smem();
        __syncthreads();

        // 遍历令牌并复制到缓冲区
        int64_t token_idx;
        int cached_rdma_channel_head = 0, last_rdma_tail_idx = -1;
        auto send_buffer = lane_id == rdma_rank ? rdma_channel_data.recv_buffer(lane_id) : rdma_channel_data.send_buffer(lane_id);
        for(token_idx = token_start_idx + warp_id; token_idx < token_end_idx; token_idx += kNumDispatchRDMASenderWarps) {
            // 读取RDMA秩的存在性
            uint64_t is_token_in_rank_uint64 = 0;
            if(lane_id < kNumRDMARanks) {
                is_token_in_rank_uint64 = *reinterpret_cast<const uint64_t*>(is_token_in_rank + token_idx * num_ranks + lane_id * NUM_MAX_NVL_PEERS);
            }

            // 获得处理数据的自旋锁，获得锁后才会处理一些数据信息
            while(lane_id == 0 && rdma_send_next_token_idx != token_idx) {
                // 等待
            }
            syncwarp();

            // 获取下一个尾部位置
            int rdma_tail_idx = -1;
            if(is_token_in_rank_uint64 != 0) {
                rdma_tail_idx = rdma_send_channel_next_tail[lane_id]++;

                // 与kForwarderCoordinator相互配合，调节发送数据的频率
                while(rdma_tail_idx - cached_rdma_channel_head >= num_max_rdma_chunked_recv_tokens) {
                    cached_rdma_channel_head = static_cast<int>(ld_volatile_global(rdma_channel_head.buffer(lane_id)));
                }
            }
            syncwarp();

            // 存储RDMA头部以供合并
            if(lane_id < kNumRDMARanks && !kCachedMode) {
                send_rdma_head[token_idx * kNumRDMARanks + lane_id] = rdma_tail_idx;
            }

            // 更新最后一个令牌尾部
            if(last_rdma_tail_idx >= 0) {
                st_release_cta(const_cast<int*>(rdma_send_channel_tail + lane_id), last_rdma_tail_idx + 1);
            }
            last_rdma_tail_idx = rdma_tail_idx;

            // 释放顺序锁
            if(lane_id == 0) {
                rdma_send_next_token_idx += 1;
            }

            // 广播尾部位置
            SourceMeta src_meta;
            int num_topk_ranks = 0, topk_ranks[kNumTopkRDMARanks];
            void* dst_send_buffers[kNumTopkRDMARanks];
            /*
            该for循环主要功能是在一个CUDA内核中协调多个线程之间的RDMA发送操作
            */
            #pragma unroll
            for(int i = 0, slot_idx; i < kNumRDMARanks; ++i) {
                // 使用__shfl_sync函数在warp内同步并广播rdma_tail_idx的值
                if((slot_idx = shfl_sync(rdma_tail_idx, i)) >= 0) {
                    // warp 所有线程参与，rdma_tail_idx默认为-1， 只有对应rdma rank需要发送时， rdma_tail_idx才会>=0
                    //  计算slot_idx在接收缓冲区中的位置
                    slot_idx = slot_idx % num_max_rdma_chunked_recv_tokens;

                    // 存储当前RDMA秩到topk_ranks数组中
                    topk_ranks[num_topk_ranks] = i;

                    // 广播is_token_in_rank_uint64的值到所有线程，并解释为布尔数组
                    auto recv_is_token_in_rank_uint64 = broadcast(is_token_in_rank_uint64, i);
                    auto recv_is_token_in_rank_values = reinterpret_cast<const bool*>(&recv_is_token_in_rank_uint64);

                    // 如果当前lane_id等于num_topk_ranks，则更新src_meta
                    if(lane_id == num_topk_ranks) {
                        src_meta = SourceMeta(rdma_rank, recv_is_token_in_rank_values);
                    }

                    // 计算目标发送缓冲区的地址，并存储在dst_send_buffers数组中
                    // 获取到发送地址， num_topk_ranks-1 是需要发送的ranks数
                    dst_send_buffers[num_topk_ranks++] = reinterpret_cast<uint8_t*>(broadcast(send_buffer, i)) + slot_idx * num_bytes_per_rdma_token;
                }
            }
            EP_DEVICE_ASSERT(num_topk_ranks <= kNumTopkRDMARanks);

            // 复制 `x` 到对称发送缓冲区
            auto st_broadcast = [=](const int key, const int4& value) {
#pragma unroll
                for(int j = 0; j < num_topk_ranks; ++j) {
                    st_na_global(reinterpret_cast<int4*>(dst_send_buffers[j]) + key, value);
                }
            };
            UNROLLED_WARP_COPY(5, lane_id, hidden_int4, 0, x + token_idx * hidden_int4, ld_nc_global, st_broadcast);
#pragma unroll
            for(int i = 0; i < num_topk_ranks; ++i) {
                dst_send_buffers[i] = reinterpret_cast<int4*>(dst_send_buffers[i]) + hidden_int4;
            }

            // 复制源元数据到对称发送缓冲区
            if(lane_id < num_topk_ranks) {
                st_na_global(reinterpret_cast<SourceMeta*>(dst_send_buffers[lane_id]), src_meta);
            }
#pragma unroll
            for(int i = 0; i < num_topk_ranks; ++i) {
                dst_send_buffers[i] = reinterpret_cast<SourceMeta*>(dst_send_buffers[i]) + 1;
            }

            // 复制 `x_scales` 到对称发送缓冲区
#pragma unroll
            for(int i = lane_id; i < num_scales; i += kWarpSize) {
                auto value = ld_nc_global(x_scales + token_idx * num_scales + i);

                // auto offset = token_idx * scale_token_stride + i * scale_hidden_stride;
                // auto value = ld_nc_global(x_scales + offset);
#pragma unroll
                for(int j = 0; j < num_topk_ranks; ++j) {
                    st_na_global(reinterpret_cast<float*>(dst_send_buffers[j]) + i, value);
                }
            }
#pragma unroll
            for(int i = 0; i < num_topk_ranks; ++i) {
                dst_send_buffers[i] = reinterpret_cast<float*>(dst_send_buffers[i]) + num_scales;
            }

            // 复制 `topk_idx` 和 `topk_weights` 到对称发送缓冲区
#pragma unroll
            for(int i = lane_id; i < num_topk * num_topk_ranks; i += kWarpSize) {
                auto rank_idx = i / num_topk, copy_idx = i % num_topk;
                auto idx_value = static_cast<int>(ld_nc_global(topk_idx + token_idx * num_topk + copy_idx));
                auto weight_value = ld_nc_global(topk_weights + token_idx * num_topk + copy_idx);
                st_na_global(reinterpret_cast<int*>(dst_send_buffers[rank_idx]) + copy_idx, idx_value);
                st_na_global(reinterpret_cast<float*>(dst_send_buffers[rank_idx]) + num_topk + copy_idx, weight_value);
            }
        }

        // 结尾部分
        // 获取顺序锁
        while(lane_id == 0 && rdma_send_next_token_idx != token_idx) {
            // 等待
        }

        syncwarp();

        // 更新最后一个令牌尾部
        if(last_rdma_tail_idx >= 0) {
            st_release_cta(const_cast<int*>(rdma_send_channel_tail + lane_id), last_rdma_tail_idx + 1);
        }

        // 释放顺序锁
        if(lane_id == 0) {
            rdma_send_next_token_idx += 1;
        }
    } else if(warp_role == WarpRole::kRDMASenderCoordinator) {
        /*
        这段代码的主要功能是在一个CUDA内核中协调多个线程之间的RDMA发送操作。
        它首先计算每个RDMA秩需要发送的令牌数，然后在所有RDMA秩之间循环，检查是否有令牌需要发送。
        如果有，它将计算本次需要发出的令牌数，并发出相应的RDMA发送请求。
        最后，它更新相关的尾部位置，以便下次循环时可以正确地计算需要发送的令牌数。

        kRDMASenderCoordinator使用了同sm内存一致性（ld.acquire.cta.s32），
        nvshmem内存一致性（nvshmem_fence）和原子操作（nvshmemx_signal_op），减少硬同步，提升整体效率。
        */
        if(warp_id > kNumDispatchRDMASenderWarps) {
            return;
        }
        // 确保最大接收令牌数可以被最大发送令牌数整除，以避免缓冲区分割问题
        EP_DEVICE_ASSERT(num_max_rdma_chunked_recv_tokens % num_max_rdma_chunked_send_tokens == 0);

        // 同步共享内存，确保所有线程在继续之前都达到了这一点
        // sync_rdma_sender_smem();
        __syncthreads();

        // 计算当前通道需要发送的令牌数
        int num_tokens_to_send = 0;
        if(lane_id < kNumRDMARanks) {
            num_tokens_to_send = rdma_channel_prefix_matrix[lane_id * num_channels + channel_id];
            if(channel_id > 0)
                num_tokens_to_send -= rdma_channel_prefix_matrix[lane_id * num_channels + channel_id - 1];
        }

        // 记录上次发出的尾部位置
        int last_issued_tail = 0;
        // 当有任何RDMA秩需要发送令牌时，继续循环
        while(__any_sync(kFullWarpMask, num_tokens_to_send > 0)) {
            for(int i = 0, synced_num_tokens_to_send; i < kNumRDMARanks; ++i) {
                // 计算目标RDMA秩
                int dst_rdma_rank = (i + channel_id) % kNumRDMARanks;

                // 获取同步后的需要发送的令牌数
                synced_num_tokens_to_send = shfl_sync(num_tokens_to_send, dst_rdma_rank);

                if(synced_num_tokens_to_send == 0)
                    continue; // 如果没有令牌需要发送，则跳过

                // 读取进度
                auto synced_last_issued_tail = shfl_sync(last_issued_tail, dst_rdma_rank);
                auto processed_tail          = ld_acquire_cta(const_cast<const int*>(rdma_send_channel_tail + dst_rdma_rank));
                auto num_tokens_processed    = processed_tail - synced_last_issued_tail;

                // 如果处理的令牌数不等于需要发送的令牌数，并且处理的令牌数小于最大发送令牌数，则跳过
                if(num_tokens_processed != synced_num_tokens_to_send && num_tokens_processed < num_max_rdma_chunked_send_tokens)
                    continue;

                // 计算本次需要发出的令牌数
                auto num_tokens_to_issue = min(num_tokens_processed, num_max_rdma_chunked_send_tokens);
                EP_DEVICE_ASSERT(num_tokens_to_issue >= 0 && num_tokens_to_issue <= synced_num_tokens_to_send);

                // 发出RDMA发送请求
                if(dst_rdma_rank != rdma_rank) {
                    auto dst_slot_idx = synced_last_issued_tail % num_max_rdma_chunked_recv_tokens;
                    EP_DEVICE_ASSERT(dst_slot_idx + num_tokens_to_issue <= num_max_rdma_chunked_recv_tokens);
                    rocshmem::rocshmem_ctx_schar_put_nbi_wave(
                        ctx,
                        rdma_channel_data.recv_buffer(rdma_rank) +
                            dst_slot_idx * num_bytes_per_rdma_token,
                        rdma_channel_data.send_buffer(dst_rdma_rank) +
                            dst_slot_idx * num_bytes_per_rdma_token,
                        num_bytes_per_rdma_token * num_tokens_to_issue,
                        translate_dst_rdma_rank<kLowLatencyMode>(dst_rdma_rank, nvl_rank));
                    rocshmem::rocshmem_ctx_quiet(ctx);
                } else {
                    // 对于本地RDMA秩，使用较轻的内存屏障
                    memory_fence();
                }

                // 更新尾部位置
                syncwarp();
                if(lane_id == dst_rdma_rank) {
                    last_issued_tail += num_tokens_to_issue;
                    num_tokens_to_send -= num_tokens_to_issue;
                    // 更新远端rdma 己方已发送的token数，用于做发送信息同步。用于与kRDMAAndNVLForwarder互相通信
                    rocshmem::rocshmem_ctx_ulong_atomic_add(
                        ctx, rdma_channel_tail.buffer(rdma_rank), num_tokens_to_issue,
                        translate_dst_rdma_rank<kLowLatencyMode>(dst_rdma_rank, nvl_rank));
                }
            }
        } // while(__any(num_tokens_to_send > 0))
    } else if(warp_role == WarpRole::kRDMAAndNVLForwarder) {
        /*
        这段代码的主要功能是在一个CUDA内核中协调从RDMA消费者到NVL生产者的转发操作。
        它首先计算目标NVL秩和目标秩，然后等待相关的计数器到达。
        接着，它检查目标队列是否为空，或者等待一个缓冲区被释放。
        然后，它找到下一个源RDMA秩，并遍历RDMA缓冲区中的每一个令牌，复制相关的数据到NVL缓冲区。
        最后，它同步头部和尾部索引，并标记通道为退役状态。
        */
        // RDMA消费者和NVL生产者
        const auto dst_nvl_rank          = target_rank;                                       // 目标NVL秩
        const auto dst_rank              = rdma_rank * NUM_MAX_NVL_PEERS + dst_nvl_rank;      // 目标秩
        const auto dst_rank_expert_begin = dst_rank * (num_experts / num_ranks);              // 目标秩专家开始
        const auto dst_rank_expert_end   = dst_rank_expert_begin + (num_experts / num_ranks); // 目标秩专家结束

        // 等待计数器到达
        int num_tokens_to_recv_from_rdma = 0, src_rdma_channel_prefix = 0;
        EP_DEVICE_ASSERT(kNumRDMARanks <= kWarpSize);
        auto start_time = wall_clock64();
        if(lane_id < kNumRDMARanks) {
            while(true) {
                // 对应于kRDMASender中的数据写入
                auto meta_0 = ld_volatile_global(rdma_channel_meta.recv_buffer(lane_id) + dst_nvl_rank);                     // 是nvl节点的起始地址
                auto meta_1 = ld_volatile_global(rdma_channel_meta.recv_buffer(lane_id) + NUM_MAX_NVL_PEERS + dst_nvl_rank); // nvl节点的结束地址
                auto meta_2 = ld_volatile_global(rdma_channel_meta.recv_buffer(lane_id) + NUM_MAX_NVL_PEERS * 2);            // 本rdma节点的起始地址
                auto meta_3 = ld_volatile_global(rdma_channel_meta.recv_buffer(lane_id) + NUM_MAX_NVL_PEERS * 2 + 1);        // 本节点的结束地址
                if(meta_0 < 0 && meta_1 < 0 && meta_2 < 0 && meta_3 < 0) {
                    // 通知NVL秩
                    int start_sum = -meta_0 - 1, end_sum = -meta_1 - 1;
                    EP_DEVICE_ASSERT(start_sum >= 0 && end_sum >= 0 && end_sum >= start_sum);

                    st_relaxed_sys_global(nvl_channel_prefix_start.buffer() + lane_id, -start_sum - 1);
                    st_relaxed_sys_global(nvl_channel_prefix_end.buffer() + lane_id, -end_sum - 1);

                    // 保存从RDMA通道接收的令牌计数
                    src_rdma_channel_prefix = -meta_2 - 1;
                    auto src_rdma_channel_prefix_1 = -meta_3 - 1;
                    num_tokens_to_recv_from_rdma = src_rdma_channel_prefix_1 - src_rdma_channel_prefix; // 是远端 rdma_rank 会发送给当前节点的token数量
                    if(!kCachedMode)
                        recv_rdma_channel_prefix_matrix[lane_id * num_channels + channel_id] = src_rdma_channel_prefix_1;

                    src_rdma_channel_prefix += lane_id == 0 ? 0 : recv_rdma_rank_prefix_sum[lane_id - 1]; // 对应的远端 rdma_rank 的起始index, 存在线程0之中
                    EP_DEVICE_ASSERT(num_tokens_to_recv_from_rdma >= 0);
                    break;
                }

                // 超时检查
                if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES) {
                    printf("DeepEP dispatch forwarder timeout (RDMA meta), channel: %d, RDMA: %d, nvl: %d, src RDMA lane: %d, dst NVL: %d, meta: %d, %d, %d, %d\n",
                           channel_id, rdma_rank, nvl_rank, lane_id, dst_nvl_rank, meta_0, meta_1, meta_2, meta_3);
                    trap();
                }
            }
        }
        syncwarp();

        // 移动缓存的头部
        send_nvl_head += src_rdma_channel_prefix * NUM_MAX_NVL_PEERS + dst_nvl_rank;

        // 等待共享内存被清理
        // sync_forwarder_smem();
        __syncthreads();

        // 开始准备处理接受数据，直到所有的数据接受完成。
        // 转发从RDMA缓冲区的令牌
        // 注意：总是从本地秩开始
        int src_rdma_rank = sm_id % kNumRDMARanks;
        int cached_rdma_channel_head = 0, cached_rdma_channel_tail = 0;
        int cached_nvl_channel_head = 0, cached_nvl_channel_tail = 0, rdma_nvl_token_idx = 0;
        while(__any_sync(kFullWarpMask, num_tokens_to_recv_from_rdma > 0)) {
            // 检查nvl目标队列是否为空，或者等待一个缓冲区被释放
            start_time = wall_clock64();

            // 用于给kNVLReceivers进行互动，控制数据的传输速度
            while(lane_id == 0) {
                int num_used_slots = cached_nvl_channel_tail - cached_nvl_channel_head;
                if(num_max_nvl_chunked_recv_tokens - num_used_slots >= num_max_nvl_chunked_send_tokens)
                    break;
                cached_nvl_channel_head = ld_volatile_global(nvl_channel_head.buffer());

                // 超时检查
                if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES) {
                    printf("DeepEP dispatch forwarder timeout (NVL check), channel: %d, RDMA: %d, nvl: %d, dst NVL: %d, head: %d, tail: %d\n",
                           channel_id, rdma_rank, nvl_rank, dst_nvl_rank, ld_volatile_global(nvl_channel_head.buffer()), cached_nvl_channel_tail);
                    trap();
                }
            }
            syncwarp();

            // 找到下一个源RDMA秩（轮询）
            start_time = wall_clock64();
            while(true) {
                src_rdma_rank = (src_rdma_rank + 1) % kNumRDMARanks;
                if(shfl_sync(num_tokens_to_recv_from_rdma, src_rdma_rank) > 0) {
                    if(lane_id == src_rdma_rank && cached_rdma_channel_head == cached_rdma_channel_tail)
                        cached_rdma_channel_tail = static_cast<int>(ld_acquire_sys_global(rdma_channel_tail.buffer(src_rdma_rank)));

                    if(shfl_sync(cached_rdma_channel_tail > cached_rdma_channel_head, src_rdma_rank)) {
                        break;
                    }
                }

                // 超时检查
                if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES and lane_id < kNumRDMARanks) {
                    printf("DeepEP dispatch forwarder timeout (RDMA check), channel: %d, RDMA: %d, nvl: %d, dst NVL: %d, src RDMA lane: %d, head: %d, tail: %d, expected: %d\n",
                           channel_id, rdma_rank, nvl_rank, dst_nvl_rank, lane_id, cached_rdma_channel_head, cached_rdma_channel_tail, num_tokens_to_recv_from_rdma);
                    trap();
                }
            }

            auto src_rdma_head = shfl_sync(cached_rdma_channel_head, src_rdma_rank);
            auto src_rdma_tail = shfl_sync(cached_rdma_channel_tail, src_rdma_rank);

            // 遍历RDMA缓冲区中的每一个令牌
            for(int i = src_rdma_head, num_tokens_sent = 0; i < src_rdma_tail; ++i) {
                auto rdma_slot_idx = i % num_max_rdma_chunked_recv_tokens;
                // 首先读取SourceMeta，对应到kRDMASenderCoordinator中 kRDMASender 的数据远程写入
                void* shifted           = rdma_channel_data.recv_buffer(src_rdma_rank) + rdma_slot_idx * num_bytes_per_rdma_token;
                auto src_meta           = ld_nc_global(reinterpret_cast<SourceMeta*>(reinterpret_cast<int8_t*>(shifted) + hidden_bytes));
                if(lane_id == src_rdma_rank) {
                    num_tokens_to_recv_from_rdma -= 1;
                }

                bool is_in_dst_nvl_rank = src_meta.is_token_in_nvl_rank(dst_nvl_rank);
                if(lane_id == src_rdma_rank) {
                    auto cached_head = is_in_dst_nvl_rank ? rdma_nvl_token_idx : -1;
                    rdma_nvl_token_idx += is_in_dst_nvl_rank;
                    if(!kCachedMode)
                        send_nvl_head[i * NUM_MAX_NVL_PEERS] = cached_head;
                }

                if(!is_in_dst_nvl_rank)
                    continue;

                // 获取一个空闲槽位
                int dst_slot_idx = (cached_nvl_channel_tail++) % num_max_nvl_chunked_recv_tokens;

                // 复制数据
                UNROLLED_WARP_COPY(5, lane_id, hidden_int4,
                                   nvl_channel_x.buffer() + dst_slot_idx * hidden_int4,
                                   reinterpret_cast<int4*>(shifted),
                                   ld_nc_global, st_na_global);
                shifted = reinterpret_cast<int4*>(shifted) + hidden_int4;

                // 复制源元数据
                if(lane_id == 0)
                    st_na_global(nvl_channel_src_meta.buffer() + dst_slot_idx, src_meta);
                shifted = reinterpret_cast<SourceMeta*>(shifted) + 1;

                // 复制 `x_scales`
                UNROLLED_WARP_COPY(1, lane_id, num_scales,
                                   nvl_channel_x_scales.buffer() + dst_slot_idx * num_scales,
                                   reinterpret_cast<float*>(shifted),
                                   ld_nc_global, st_na_global);
                shifted = reinterpret_cast<float*>(shifted) + num_scales;

                // 复制 `topk_idx` 和 `topk_weights`
                if(lane_id < num_topk) {
                    // 读取
                    auto idx_value = ld_nc_global(reinterpret_cast<int*>(shifted) + lane_id);
                    shifted = reinterpret_cast<int*>(shifted) + num_topk;
                    auto weight_value = ld_nc_global(reinterpret_cast<float*>(shifted) + lane_id);

                    // 转换和写入
                    idx_value = (idx_value >= dst_rank_expert_begin && idx_value < dst_rank_expert_end) ? idx_value - dst_rank_expert_begin : -1;
                    st_na_global(nvl_channel_topk_idx.buffer() + dst_slot_idx * num_topk + lane_id, idx_value);
                    weight_value = idx_value >= 0 ? weight_value : 0.0f;
                    st_na_global(nvl_channel_topk_weights.buffer() + dst_slot_idx * num_topk + lane_id, weight_value);
                }

                // 在NVL缓冲区不足的情况下，提前停止
                if((++num_tokens_sent) == num_max_nvl_chunked_send_tokens)
                    src_rdma_tail = i + 1;
            }

            // 同步头部索引
            if(lane_id == src_rdma_rank)
                forward_channel_head[dst_nvl_rank][src_rdma_rank] = (cached_rdma_channel_head = src_rdma_tail);

            // 移动尾部索引，与kNVLReceivers互相通信使用
            syncwarp();
            if(lane_id == 0) {
                st_release_sys_global(nvl_channel_tail.buffer(), cached_nvl_channel_tail);
            }
        }

        // Retired
        syncwarp();
        if(lane_id == 0) {
            forward_channel_retired[dst_nvl_rank] = true;
        }
    } else if(warp_role == WarpRole::kForwarderCoordinator) {
        /*
        这段代码的主要功能是在一个CUDA内核中协调转发器的逻辑。
        它首先检查当前warp是否是额外的转发器协调warp，如果是，则直接退出。
        然后，它清理共享内存，并初始化转发通道的头部和退役状态。
        接着，它进入一个无限循环，在循环中，它找到最小的头部，如果所有的通道都已退役，则退出循环。
        否则，它更新远程头部，并进行纳秒级睡眠，以让其他warp工作。
        */
        // Extra warps for forwarder coordinator should exit directly
        if (warp_id > NUM_MAX_NVL_PEERS)
            return;

        // 转发warp协调器
        EP_STATIC_ASSERT(kNumRDMARanks <= kWarpSize, "无效的RDMA对等体数量");
        // 清理共享内存
        EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS <= kWarpSize, "无效的NVL对等体数量");
#pragma unroll
        for(int i = lane_id; i < kNumRDMARanks * NUM_MAX_NVL_PEERS; i += kWarpSize)
            forward_channel_head[i % NUM_MAX_NVL_PEERS][i / NUM_MAX_NVL_PEERS] = 0;
        if(lane_id < NUM_MAX_NVL_PEERS)
            forward_channel_retired[lane_id] = false;
        // sync_forwarder_smem();
        __syncthreads();

        int last_head = 0, target_rdma = lane_id < kNumRDMARanks ? lane_id : 0;

        while(true) {
            // 找到最小的头部
            int min_head = std::numeric_limits<int>::max();
#pragma unroll
            for(int i = 0; i < NUM_MAX_NVL_PEERS; ++i)
                if(!forward_channel_retired[i])
                    min_head = min(min_head, forward_channel_head[i][target_rdma]);

            if(__all_sync(kFullWarpMask, min_head == std::numeric_limits<int>::max())) {
                break;
            }

            // 更新远程头部
            if(min_head != std::numeric_limits<int>::max() && min_head >= last_head + num_max_rdma_chunked_send_tokens && lane_id < kNumRDMARanks){
                rocshmem::rocshmem_ctx_ulong_atomic_add(
                    ctx, rdma_channel_head.buffer(rdma_rank), min_head - last_head,
                    translate_dst_rdma_rank<kLowLatencyMode>(lane_id, nvl_rank));
                last_head = min_head;
            }

            // 纳秒级睡眠并让其他warp工作 // Nanosleep and let other warps work
            __builtin_amdgcn_s_sleep(NUM_WAIT_CYCLES_TIMES_64);
        }
    } else if(warp_role == WarpRole::kNVLReceivers) {
        if(warp_id >= NUM_MAX_NVL_PEERS) {
            return;
        }

        // Place the main logic of your kernel here, using the parameters above.
        // NVL消费者
        // 从屏障结果中检索秩偏移（每个通道的寄存器存储一个RDMA秩）
        int src_nvl_rank = target_rank, total_offset = 0;
        EP_STATIC_ASSERT(kNumRDMARanks <= kWarpSize, "无效的RDMA对等体数量");
        if(lane_id < kNumRDMARanks && lane_id * NUM_MAX_NVL_PEERS + src_nvl_rank > 0)
            total_offset = recv_gbl_rank_prefix_sum[lane_id * NUM_MAX_NVL_PEERS + src_nvl_rank - 1];

        // 接收通道偏移
        int start_offset = 0, end_offset = 0, num_tokens_to_recv;
        auto start_time = wall_clock64();

        while(lane_id < kNumRDMARanks) {
            start_offset = ld_volatile_global(nvl_channel_prefix_start.buffer() + lane_id);
            end_offset   = ld_volatile_global(nvl_channel_prefix_end.buffer() + lane_id);
            if(start_offset < 0 && end_offset < 0) {
                start_offset = -start_offset - 1, end_offset = -end_offset - 1;
                total_offset += start_offset;
                break;
            }
            // 超时检查
            if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES) {
                printf("DeepEP dispatch NVL receiver timeout, channel: %d, RDMA: %d, nvl: %d, src RDMA: %d, src nvl: %d, start: %d, end: %d\n",
                        channel_id, rdma_rank, nvl_rank, lane_id, src_nvl_rank, start_offset, end_offset);
                trap();
            }
        }

        num_tokens_to_recv = warp_reduce_sum(end_offset - start_offset);

        // 保存以供合并使用
        if(lane_id < kNumRDMARanks && !kCachedMode)
            recv_gbl_channel_prefix_matrix[(lane_id * NUM_MAX_NVL_PEERS + src_nvl_rank) * num_channels + channel_id] = total_offset;
        syncwarp();

        int cached_channel_head_idx = 0, cached_channel_tail_idx = 0;
        while(num_tokens_to_recv > 0) {
            // 通过通道0检查通道状态
            start_time = wall_clock64();
            while(lane_id == 0) {
                // 准备复制
                if(cached_channel_head_idx != cached_channel_tail_idx)
                    break;
                cached_channel_tail_idx = ld_acquire_sys_global(nvl_channel_tail.buffer());
                // 超时检查
                if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES) {
                    printf("DeepEP dispatch NVL receiver timeout, channel: %d, RDMA: %d, nvl: %d, src NVL: %d, head: %d, tail: %d\n",
                            channel_id, rdma_rank, nvl_rank, src_nvl_rank, cached_channel_head_idx, cached_channel_tail_idx);
                    trap();
                }
            }

            // 同步队列尾部
            cached_channel_tail_idx = shfl_sync(cached_channel_tail_idx, 0);

            // 复制数据
            int num_recv_tokens = cached_channel_tail_idx - cached_channel_head_idx;
            for(int chunk_idx = 0; chunk_idx < num_recv_tokens; ++chunk_idx, --num_tokens_to_recv) {
                int token_idx_in_buffer = (cached_channel_head_idx++) % num_max_nvl_chunked_recv_tokens;
                auto meta               = ld_nc_global(nvl_channel_src_meta.buffer() + token_idx_in_buffer);
                int64_t recv_token_idx  = shfl_sync(total_offset, meta.src_rdma_rank);
                (lane_id == meta.src_rdma_rank) ? (total_offset += 1) : 0;

                // 复制数据
                UNROLLED_WARP_COPY(5,
                                lane_id,
                                hidden_int4,
                                recv_x + recv_token_idx * hidden_int4,
                                nvl_channel_x.buffer() + token_idx_in_buffer * hidden_int4,
                                ld_nc_global,
                                st_na_global);

                // 复制源元数据
                if(lane_id == 0 && !kCachedMode)
                    st_na_global(recv_src_meta + recv_token_idx, meta);

                // 复制比例
                UNROLLED_WARP_COPY(1,
                                lane_id,
                                num_scales,
                                recv_x_scales + recv_token_idx * num_scales,
                                nvl_channel_x_scales.buffer() + token_idx_in_buffer * num_scales,
                                ld_nc_global,
                                st_na_global);

                // 复制 `topk_idx` 和 `topk_weights`
                if(lane_id < num_topk) {
                    auto recv_idx   = recv_token_idx * num_topk + lane_id;
                    auto buffer_idx = token_idx_in_buffer * num_topk + lane_id;
                    st_na_global(recv_topk_idx + recv_idx, static_cast<int64_t>(ld_nc_global(nvl_channel_topk_idx.buffer() + buffer_idx)));
                    st_na_global(recv_topk_weights + recv_idx, ld_nc_global(nvl_channel_topk_weights.buffer() + buffer_idx));
                }
            }

            // 移动队列
            syncwarp();
            if(lane_id == 0) {
                st_relaxed_sys_global(nvl_channel_head.buffer(), cached_channel_head_idx);
            }
        } // while(num_tokens_to_recv > 0)
    }
    rocshmem::rocshmem_wg_ctx_destroy(&ctx);
}

void dispatch(void *recv_x, float *recv_x_scales, int64_t *recv_topk_idx, float *recv_topk_weights,
              void *recv_src_meta, const void *x, const float *x_scales, const int64_t *topk_idx,
              const float *topk_weights, int *send_rdma_head, int *send_nvl_head,
              int *recv_rdma_channel_prefix_matrix, int *recv_gbl_channel_prefix_matrix,
              const int *rdma_channel_prefix_matrix, const int *recv_rdma_rank_prefix_sum,
              const int *gbl_channel_prefix_matrix, const int *recv_gbl_rank_prefix_sum,
              const bool *is_token_in_rank, int num_tokens, int hidden_int4, int num_scales,
              int num_topk, int num_experts, int scale_token_stride, int scale_hidden_stride,
              void *rdma_buffer_ptr, int num_max_rdma_chunked_send_tokens,
              int num_max_rdma_chunked_recv_tokens, void **buffer_ptrs,
              int num_max_nvl_chunked_send_tokens, int num_max_nvl_chunked_recv_tokens, int rank,
              int num_ranks, bool is_cached_dispatch, hipStream_t stream, int num_channels,
              bool low_latency_mode) {
    constexpr int kNumDispatchRDMASenderWarps = 7;
    // Make sure never OOB
    EP_HOST_ASSERT(static_cast<int64_t>(num_scales) * scale_hidden_stride < std::numeric_limits<int>::max());

#define DISPATCH_LAUNCH_CASE(num_rdma_ranks)                                                       \
    {                                                                                              \
        auto dispatch_func =                                                                       \
            low_latency_mode                                                                       \
                ? (is_cached_dispatch                                                              \
                       ? dispatch<true, num_rdma_ranks, true, kNumDispatchRDMASenderWarps>         \
                       : dispatch<true, num_rdma_ranks, false, kNumDispatchRDMASenderWarps>)       \
                : (is_cached_dispatch                                                              \
                       ? dispatch<false, num_rdma_ranks, true, kNumDispatchRDMASenderWarps>        \
                       : dispatch<false, num_rdma_ranks, false, kNumDispatchRDMASenderWarps>);     \
        LAUNCH_KERNEL_NON_COOPERATIVE(                                                             \
            &cfg, dispatch_func, reinterpret_cast<int4 *>(recv_x), recv_x_scales, recv_topk_idx,   \
            recv_topk_weights, reinterpret_cast<SourceMeta *>(recv_src_meta),                      \
            reinterpret_cast<const int4 *>(x), x_scales, topk_idx, topk_weights, send_rdma_head,   \
            send_nvl_head, recv_rdma_channel_prefix_matrix, recv_gbl_channel_prefix_matrix,        \
            rdma_channel_prefix_matrix, recv_rdma_rank_prefix_sum, gbl_channel_prefix_matrix,      \
            recv_gbl_rank_prefix_sum, is_token_in_rank, num_tokens, hidden_int4, num_scales,       \
            num_topk, num_experts, scale_token_stride, scale_hidden_stride, rdma_buffer_ptr,       \
            num_max_rdma_chunked_send_tokens, num_max_rdma_chunked_recv_tokens, buffer_ptrs,       \
            num_max_nvl_chunked_send_tokens, num_max_nvl_chunked_recv_tokens, rank, num_ranks);    \
    }                                                                                              \
    break

    EP_HOST_ASSERT((topk_idx == nullptr) == (topk_weights == nullptr));
    EP_HOST_ASSERT((recv_topk_idx == nullptr) == (recv_topk_weights == nullptr));

    SETUP_LAUNCH_CONFIG(num_channels * NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL,
                        (1 + NUM_MAX_NVL_PEERS) * kWarpSize, stream);
    SWITCH_RDMA_RANKS(DISPATCH_LAUNCH_CASE);
#undef DISPATCH_LAUNCH_CASE
}

template <bool kLowLatencyMode>
__global__ void __launch_bounds__(1024, 1)
cached_notify(const int rdma_clean_offset, const int rdma_num_int_clean, const int nvl_clean_offset,
              const int nvl_num_int_clean, int *combined_rdma_head, int num_combined_tokens,
              int num_channels, const int *rdma_channel_prefix_matrix,
              const int *rdma_rank_prefix_sum, int *combined_nvl_head, void *rdma_buffer_ptr,
              void **buffer_ptrs, int **barrier_signal_ptrs, int rank, int num_ranks,
              bool is_cached_dispatch, const rocshmem::rocshmem_team_t rdma_team) {
    auto sm_id       = static_cast<int>(blockIdx.x);
    auto thread_id   = static_cast<int>(threadIdx.x);
    auto num_threads = static_cast<int>(blockDim.x);
    auto num_warps   = num_threads / kWarpSize;
    auto warp_id     = thread_id / kWarpSize;
    auto lane_id     = get_lane_id();

    auto nvl_rank       = rank % NUM_MAX_NVL_PEERS;
    auto num_rdma_ranks = num_ranks / NUM_MAX_NVL_PEERS;

    // Using two SMs, which clean the RDMA/NVL buffer respectively
    if (sm_id == 0) {
        // Barrier for RDMA
        if (thread_id == 0)
            nvshmem_barrier_with_same_gpu_idx<kLowLatencyMode>(rdma_team);

        __syncthreads();

        // Clean
        auto rdma_buffer_ptr_int = reinterpret_cast<int *>(rdma_buffer_ptr);
        for (int i = thread_id; i < rdma_num_int_clean; i += num_threads)
            rdma_buffer_ptr_int[rdma_clean_offset + i] = 0;
        rocshmem::rocshmem_fence();
        __syncthreads();

        // Barrier again
        if (thread_id == 0)
            nvshmem_barrier_with_same_gpu_idx<kLowLatencyMode>(rdma_team);

    } else if (sm_id == 1) {
        // Barrier for NVL
        barrier_block<NUM_MAX_NVL_PEERS>(barrier_signal_ptrs, nvl_rank);
        __syncthreads();

        // Clean
        auto nvl_buffer_ptr_int = reinterpret_cast<int *>(buffer_ptrs[nvl_rank]);
        for (int i = thread_id; i < nvl_num_int_clean; i += num_threads)
            nvl_buffer_ptr_int[nvl_clean_offset + i] = 0;
        memory_fence();
        __syncthreads();

        // Barrier again
        barrier_block<NUM_MAX_NVL_PEERS>(barrier_signal_ptrs, nvl_rank);
    } else if (sm_id == 2) {
        if (is_cached_dispatch)
            return;

        EP_DEVICE_ASSERT(num_warps >= num_channels);
        EP_DEVICE_ASSERT(num_rdma_ranks <= kWarpSize);

        // Iterate in reverse order
        if (lane_id < num_rdma_ranks and warp_id < num_channels) {
            int token_start_idx, token_end_idx;
            get_channel_task_range(num_combined_tokens, num_channels, warp_id, token_start_idx,
                                   token_end_idx);

            // NOTES: `1 << 25` is a heuristic large number
            int last_head = 1 << 25;
            for (int token_idx = token_end_idx - 1; token_idx >= token_start_idx; --token_idx) {
                auto current_head =
                    __ldg(combined_rdma_head + token_idx * num_rdma_ranks + lane_id);
                if (current_head < 0) {
                    combined_rdma_head[token_idx * num_rdma_ranks + lane_id] = -last_head - 1;
                } else {
                    last_head = current_head;
                }
            }
        }
    } else {
        if (is_cached_dispatch)
            return;

        EP_DEVICE_ASSERT(num_warps >= num_channels);
        EP_DEVICE_ASSERT(rdma_channel_prefix_matrix != nullptr and
                                  rdma_rank_prefix_sum != nullptr);
        EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS <= kWarpSize, "Too many NVL peers");

        if (lane_id < NUM_MAX_NVL_PEERS and warp_id < num_channels) {
            for (int dst_rdma_rank = sm_id - 3; dst_rdma_rank < num_rdma_ranks;
                 dst_rdma_rank += num_channels * 2 - 3) {
                // Iterate in reverse order
                int token_start_idx =
                    warp_id == 0
                        ? 0
                        : rdma_channel_prefix_matrix[dst_rdma_rank * num_channels + warp_id - 1];
                int token_end_idx =
                    rdma_channel_prefix_matrix[dst_rdma_rank * num_channels + warp_id];
                int shift = dst_rdma_rank == 0 ? 0 : rdma_rank_prefix_sum[dst_rdma_rank - 1];
                token_start_idx += shift, token_end_idx += shift;

                // NOTES: `1 << 25` is a heuristic large number
                int last_head = 1 << 25;
                for (int token_idx = token_end_idx - 1; token_idx >= token_start_idx; --token_idx) {
                    auto current_head =
                        __ldg(combined_nvl_head + token_idx * NUM_MAX_NVL_PEERS + lane_id);
                    if (current_head < 0) {
                        combined_nvl_head[token_idx * NUM_MAX_NVL_PEERS + lane_id] = -last_head - 1;
                    } else {
                        last_head = current_head;
                    }
                }
            }
        }
    }
}

void cached_notify(int hidden_int4, int num_scales, int num_topk_idx, int num_topk_weights,
                   int num_ranks, int num_channels, int num_combined_tokens,
                   int *combined_rdma_head, const int *rdma_channel_prefix_matrix,
                   const int *rdma_rank_prefix_sum, int *combined_nvl_head, void *rdma_buffer_ptr,
                   int num_max_rdma_chunked_recv_tokens, void **buffer_ptrs,
                   int num_max_nvl_chunked_recv_tokens, int **barrier_signal_ptrs, int rank,
                   hipStream_t stream, int64_t num_rdma_bytes, int64_t num_nvl_bytes,
                   bool is_cached_dispatch, bool low_latency_mode) {
    const int  num_threads    = ::max(128, kWarpSize * num_channels);
    const auto num_rdma_ranks = num_ranks / NUM_MAX_NVL_PEERS;

    // Get clean meta
    auto rdma_clean_meta =
        get_rdma_clean_meta(hidden_int4, num_scales, num_topk_idx, num_topk_weights, num_rdma_ranks,
                            num_max_rdma_chunked_recv_tokens, num_channels);
    auto nvl_clean_meta =
        get_nvl_clean_meta(hidden_int4, num_scales, num_topk_idx, num_topk_weights, num_rdma_ranks,
                           NUM_MAX_NVL_PEERS, num_max_nvl_chunked_recv_tokens, num_channels);
    EP_HOST_ASSERT((rdma_clean_meta.first + rdma_clean_meta.second) * sizeof(int) <=
                       num_rdma_bytes);
    EP_HOST_ASSERT((nvl_clean_meta.first + nvl_clean_meta.second) * sizeof(int) <=
                       num_nvl_bytes);
    EP_HOST_ASSERT(num_rdma_bytes < std::numeric_limits<int>::max());
    EP_HOST_ASSERT(num_nvl_bytes < std::numeric_limits<int>::max());
    EP_HOST_ASSERT(num_channels * 2 > 3);

    // Launch kernel
    auto cached_notify_func = low_latency_mode ? cached_notify<true> : cached_notify<false>;
    SETUP_LAUNCH_CONFIG(num_channels * 2, num_threads, stream);
    LAUNCH_KERNEL_NON_COOPERATIVE(
        &cfg, cached_notify_func, rdma_clean_meta.first, rdma_clean_meta.second,
        nvl_clean_meta.first, nvl_clean_meta.second, combined_rdma_head, num_combined_tokens,
        num_channels, rdma_channel_prefix_matrix, rdma_rank_prefix_sum, combined_nvl_head,
        rdma_buffer_ptr, buffer_ptrs, barrier_signal_ptrs, rank, num_ranks, is_cached_dispatch,
        cpu_rdma_team);
}

template <int kNumRanks, typename dtype_t, int kMaxNumRanks, typename ReceiveFn, typename ReceiveTWFn>
__device__ int combine_token(bool is_token_in_rank, int head_idx,
                             int lane_id, int hidden_int4, int num_topk,
                             int4* combined_row, float* combined_topk_weights,
                             int num_max_recv_tokens, const ReceiveFn& recv_fn, const ReceiveTWFn& recv_tw_fn) {
    constexpr auto kDtypePerInt4 = sizeof(int4) / sizeof(dtype_t);

    // Broadcast current heads
    // Lane `i` holds the head of rank `i` and `is_token_in_rank`
    EP_STATIC_ASSERT(kMaxNumRanks <= kWarpSize, "Too many ranks");
    int num_topk_ranks = 0, topk_ranks[kMaxNumRanks], slot_indices[kMaxNumRanks];
    #pragma unroll
    for (int i = 0; i < kNumRanks; ++ i) if (shfl_sync(is_token_in_rank, i)) {
        slot_indices[num_topk_ranks] = shfl_sync(head_idx, i) % num_max_recv_tokens;
        topk_ranks[num_topk_ranks ++] = i;
    }
    EP_DEVICE_ASSERT(num_topk_ranks <= kMaxNumRanks);

    // Reduce data
    #pragma unroll
    for (int i = lane_id; i < hidden_int4; i += kWarpSize) {
        // Read buffers
        // TODO: maybe too many registers here
        int4 recv_value_int4[kMaxNumRanks];
        #pragma unroll
        for (int j = 0; j < num_topk_ranks; ++ j)
            recv_value_int4[j] = recv_fn(topk_ranks[j], slot_indices[j], i);

        // Reduce all-to-all results
        float values[kDtypePerInt4] = {0};
        #pragma unroll
        for (int j = 0; j < num_topk_ranks; ++ j) {
            auto recv_value_dtypes = reinterpret_cast<const dtype_t*>(&recv_value_int4[j]);
            #pragma unroll
            for (int k = 0; k < kDtypePerInt4; ++ k)
                values[k] += static_cast<float>(recv_value_dtypes[k]);
        }

        // Cast back to `dtype_t` and write
        int4 out_int4;
        auto out_dtypes = reinterpret_cast<dtype_t*>(&out_int4);
        #pragma unroll
        for (int j = 0; j < kDtypePerInt4; ++ j)
            out_dtypes[j] = static_cast<dtype_t>(values[j]);
        st_na_global(combined_row + i, out_int4);
    }

    // Reduce `topk_weights`
    if (lane_id < num_topk) {
        float value = 0;
        #pragma unroll
        for (int i = 0; i < num_topk_ranks; ++ i)
            value += recv_tw_fn(topk_ranks[i], slot_indices[i], lane_id);
        st_na_global(combined_topk_weights + lane_id, value);
    }

    // Return the minimum top-k rank
    return topk_ranks[0];
}

template <bool kLowLatencyMode,
          int kNumRDMARanks,
          typename dtype_t,
          int kNumCombineForwarderWarps,
          int kNumTopkRDMARanks     = get_num_topk_rdma_ranks(kNumRDMARanks),
          int kNumWarpsPerForwarder = (kNumCombineForwarderWarps / kNumRDMARanks > 0) ? kNumCombineForwarderWarps / kNumRDMARanks : 1,
          int kNumForwarders        = kNumRDMARanks * kNumWarpsPerForwarder,
          int kNumRDMAReceivers     = kNumForwarders>
__global__ void __launch_bounds__((1 + NUM_MAX_NVL_PEERS) * kWarpSize, 1) 
combine(int4 *combined_x, float *combined_topk_weights, const bool *is_combined_token_in_rank,
            const int4 *x, const float *topk_weights, const int4 *bias_0, const int4 *bias_1,
            const int *combined_rdma_head, const int *combined_nvl_head, const SourceMeta *src_meta,
            const int *rdma_channel_prefix_matrix, const int *rdma_rank_prefix_sum,
            const int *gbl_channel_prefix_matrix, int num_tokens, int num_combined_tokens,
            int hidden, int num_topk, void *rdma_buffer_ptr, int num_max_rdma_chunked_send_tokens,
            int num_max_rdma_chunked_recv_tokens, void **buffer_ptrs,
            int num_max_nvl_chunked_send_tokens, int num_max_nvl_chunked_recv_tokens, int rank,
            int num_ranks) {
    enum class WarpRole {
        kNVLSender,
        kNVLAndRDMAForwarder,
        kRDMAReceiver,
        kRDMACoordinator,
        kNVLCoordinator
    };

    __shared__ rocshmem::rocshmem_ctx_t ctx;
    rocshmem::rocshmem_wg_ctx_create(0, &ctx);

    const auto sm_id       = static_cast<int>(blockIdx.x);
    const auto num_threads = static_cast<int>(blockDim.x), num_warps = num_threads / kWarpSize;
    const auto thread_id   = static_cast<int>(threadIdx.x), warp_id = thread_id / kWarpSize, lane_id = get_lane_id();
    const auto num_channels = static_cast<int>(gridDim.x) / NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL,
               channel_id   = sm_id / NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL;

    const auto hidden_int4 = hidden / (sizeof(int4) / sizeof(dtype_t));

    // NOTES: we decouple a channel into 2 SMs
    const auto rdma_rank = rank / NUM_MAX_NVL_PEERS, nvl_rank = rank % NUM_MAX_NVL_PEERS;

    const auto role_meta = [=]() -> std::pair<WarpRole, int> {
        if (sm_id % NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL == 1) {
            return {WarpRole::kNVLSender, (warp_id + channel_id) % NUM_MAX_NVL_PEERS};
        } else if (sm_id % NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL == 0) {
            if(warp_id < kNumForwarders) {
                return {WarpRole::kNVLAndRDMAForwarder, (warp_id + channel_id) % kNumForwarders};
            } else {
                return {WarpRole::kRDMACoordinator, 0};
            }
        } else {
            if(warp_id < kNumForwarders) {
                return {WarpRole::kRDMAReceiver, warp_id};
            } else {
                return {WarpRole::kNVLCoordinator, 0};
            }
        }
    }();

    auto warp_role = role_meta.first;
    auto target_rank = role_meta.second; // Not applicable for RDMA senders

    EP_DEVICE_ASSERT(num_warps == NUM_MAX_NVL_PEERS + 1);
    auto num_max_nvl_chunked_recv_tokens_per_rdma = num_max_nvl_chunked_recv_tokens / kNumRDMARanks;

    // This approach is designed to sync multiple warps in a loop
    constexpr int num_sync_large_iteration = 64;
    constexpr int rdma_warp_counters = kNumRDMARanks * num_sync_large_iteration;
    __shared__ volatile int sync_large_warp_counters[2 * rdma_warp_counters];   
    for (int i = thread_id; i < 2 * rdma_warp_counters; i += num_threads) {
        sync_large_warp_counters[i] = 0;
    }
    __syncthreads();

    if (warp_role == WarpRole::kNVLSender) {
        if(warp_id >= NUM_MAX_NVL_PEERS) {
            return;
        }

        const auto dst_nvl_rank = target_rank;
        // NVL layouts
        // NOTES: to avoid deadlocks, we use separate NVL buffers for different RDMA sources
        auto dst_buffer_ptr = buffer_ptrs[dst_nvl_rank], local_buffer_ptr = buffer_ptrs[nvl_rank];
        auto nvl_channel_x = AsymBuffer<int4>(dst_buffer_ptr, num_max_nvl_chunked_recv_tokens * hidden_int4, NUM_MAX_NVL_PEERS, channel_id, num_channels, nvl_rank).advance_also(local_buffer_ptr);
        auto nvl_channel_src_meta = AsymBuffer<SourceMeta>(dst_buffer_ptr, num_max_nvl_chunked_recv_tokens, NUM_MAX_NVL_PEERS, channel_id, num_channels, nvl_rank).advance_also(local_buffer_ptr);
        auto nvl_channel_topk_weights = AsymBuffer<float>(dst_buffer_ptr, num_max_nvl_chunked_recv_tokens * num_topk, NUM_MAX_NVL_PEERS, channel_id, num_channels, nvl_rank).advance_also(local_buffer_ptr);
        auto nvl_channel_head = AsymBuffer<int>(local_buffer_ptr, kNumRDMARanks, NUM_MAX_NVL_PEERS, channel_id, num_channels, dst_nvl_rank).advance_also(dst_buffer_ptr);
        auto nvl_channel_tail = AsymBuffer<int>(dst_buffer_ptr, kNumRDMARanks, NUM_MAX_NVL_PEERS, channel_id, num_channels, nvl_rank).advance_also(local_buffer_ptr);

        // Get tasks for each RDMA lane
        int token_start_idx = 0, token_end_idx = 0;
        if(lane_id < kNumRDMARanks) {
            int prefix_idx  = (lane_id * NUM_MAX_NVL_PEERS + dst_nvl_rank) * num_channels + channel_id;
            token_start_idx = gbl_channel_prefix_matrix[prefix_idx];
            token_end_idx   = (prefix_idx == num_channels * num_ranks - 1) ? num_tokens : gbl_channel_prefix_matrix[prefix_idx + 1];
        }
        syncwarp();

        // NOTES: here the cached value of each lane is only responsible for a single RDMA buffer
        int cached_channel_head_idx = 0, cached_channel_tail_idx = 0;
        EP_STATIC_ASSERT(kNumRDMARanks <= kWarpSize, "Invalid number of RDMA peers");

        // Iterate over all tokens and send by chunks
        while(true) {
            // Exit if possible
            if(__all_sync(kFullWarpMask, token_start_idx >= token_end_idx))
                break;

            // Decide next RDMA buffer to send
            bool is_lane_ready = false;
            auto start_time    = wall_clock64();

            while(true) {
                int num_used_slots = cached_channel_tail_idx - cached_channel_head_idx;
                is_lane_ready      = lane_id < kNumRDMARanks and token_start_idx < token_end_idx and
                                num_max_nvl_chunked_recv_tokens_per_rdma - num_used_slots >= num_max_nvl_chunked_send_tokens;

                if(__any_sync(kFullWarpMask, is_lane_ready))
                    break;

                // Retry
                if(lane_id < kNumRDMARanks and token_start_idx < token_end_idx)
                    cached_channel_head_idx = ld_volatile_global(nvl_channel_head.buffer() + lane_id);

                // Timeout check
                if(wall_clock64() - start_time > NUM_TIMEOUT_CYCLES and lane_id < kNumRDMARanks) {
                    printf("DeepEP combine NVL sender timeout, channel: %d, RDMA: %d, nvl: %d, dst NVL: %d, "
                        "RDMA lane: %d, head: %d, tail: %d, start: %d, end: %d\n",
                        channel_id,
                        rdma_rank,
                        nvl_rank,
                        dst_nvl_rank,
                        lane_id,
                        ld_volatile_global(nvl_channel_head.buffer() + lane_id),
                        cached_channel_tail_idx,
                        token_start_idx,
                        token_end_idx);
                    trap();
                }
            }

            // Sync token start index and count
            for(int current_rdma_idx = 0; current_rdma_idx < kNumRDMARanks; ++current_rdma_idx) {
                if(shfl_sync((token_start_idx >= token_end_idx) or (not is_lane_ready), current_rdma_idx))
                    continue;

                // Sync token start index
                auto token_idx          = static_cast<int64_t>(shfl_sync(token_start_idx, current_rdma_idx));
                int num_tokens_in_chunk = shfl_sync(min(num_max_nvl_chunked_send_tokens, token_end_idx - token_start_idx), current_rdma_idx);

                // Send by chunk
                for(int chunk_idx = 0; chunk_idx < num_tokens_in_chunk; ++chunk_idx, ++token_idx) {
                    // Get an empty slot
                    int dst_slot_idx = 0;
                    if(lane_id == current_rdma_idx) {
                        dst_slot_idx = (cached_channel_tail_idx++) % num_max_nvl_chunked_recv_tokens_per_rdma;
                        dst_slot_idx = current_rdma_idx * num_max_nvl_chunked_recv_tokens_per_rdma + dst_slot_idx;
                    }
                    dst_slot_idx = shfl_sync(dst_slot_idx, current_rdma_idx);

                    // Copy data
                    auto shifted_x_buffers = nvl_channel_x.buffer() + dst_slot_idx * hidden_int4;
                    auto shifted_x         = x + token_idx * hidden_int4;
                    UNROLLED_WARP_COPY(5, lane_id, hidden_int4, shifted_x_buffers, shifted_x, ld_nc_global, st_na_global);

                    // Copy source meta
                    if(lane_id == 0)
                        st_na_global(nvl_channel_src_meta.buffer() + dst_slot_idx, ld_nc_global(src_meta + token_idx));

                    // Copy `topk_weights`
                    if(lane_id < num_topk)
                        st_na_global(nvl_channel_topk_weights.buffer() + dst_slot_idx * num_topk + lane_id,
                                    ld_nc_global(topk_weights + token_idx * num_topk + lane_id));
                }
                lane_id == current_rdma_idx ? (token_start_idx = static_cast<int>(token_idx)) : 0;
            }

            // Move queue tail
            syncwarp();
            if(lane_id < kNumRDMARanks and is_lane_ready) {
                st_release_sys_global(nvl_channel_tail.buffer() + lane_id, cached_channel_tail_idx);
            }
        }
    } else {
        if(warp_id > kNumForwarders) {
            return;
        }

        // Combiners and coordinators
        // RDMA symmetric layout
        auto hidden_bytes = hidden_int4 * sizeof(int4);
        auto num_bytes_per_rdma_token = get_num_bytes_per_rdma_token(hidden_int4, 0, 0, num_topk);
        auto rdma_channel_data = SymBuffer<int8_t>(rdma_buffer_ptr, num_max_rdma_chunked_recv_tokens * num_bytes_per_rdma_token, kNumRDMARanks, channel_id, num_channels);
        auto rdma_channel_head = SymBuffer<uint64_t, false>(rdma_buffer_ptr, 1, kNumRDMARanks, channel_id, num_channels);
        auto rdma_channel_tail = SymBuffer<uint64_t, false>(rdma_buffer_ptr, 1, kNumRDMARanks, channel_id, num_channels);

        // NVL layouts
        void* local_nvl_buffer = buffer_ptrs[nvl_rank];
        void* nvl_buffers[NUM_MAX_NVL_PEERS];
        #pragma unroll
        for (int i = 0; i < NUM_MAX_NVL_PEERS; ++ i)
            nvl_buffers[i] = buffer_ptrs[i];
        auto nvl_channel_x = AsymBuffer<int4>(local_nvl_buffer, num_max_nvl_chunked_recv_tokens * hidden_int4, NUM_MAX_NVL_PEERS, channel_id, num_channels).advance_also<NUM_MAX_NVL_PEERS>(nvl_buffers);
        auto nvl_channel_src_meta = AsymBuffer<SourceMeta>(local_nvl_buffer, num_max_nvl_chunked_recv_tokens, NUM_MAX_NVL_PEERS, channel_id, num_channels).advance_also<NUM_MAX_NVL_PEERS>(nvl_buffers);
        auto nvl_channel_topk_weights = AsymBuffer<float>(local_nvl_buffer, num_max_nvl_chunked_recv_tokens * num_topk, NUM_MAX_NVL_PEERS, channel_id, num_channels).advance_also<NUM_MAX_NVL_PEERS>(nvl_buffers);
        auto nvl_channel_head = AsymBuffer<int, NUM_MAX_NVL_PEERS>(nvl_buffers, kNumRDMARanks, NUM_MAX_NVL_PEERS, channel_id, num_channels, nvl_rank).advance_also(local_nvl_buffer);
        auto nvl_channel_tail = AsymBuffer<int>(local_nvl_buffer, kNumRDMARanks, NUM_MAX_NVL_PEERS, channel_id, num_channels).advance_also<NUM_MAX_NVL_PEERS>(nvl_buffers);

        // Combiner warp synchronization
        __shared__ volatile int forwarder_nvl_head[kNumForwarders][NUM_MAX_NVL_PEERS];
        __shared__ volatile bool forwarder_retired[kNumForwarders];
        __shared__ volatile int rdma_receiver_rdma_head[kNumRDMAReceivers][kNumRDMARanks];
        __shared__ volatile bool rdma_receiver_retired[kNumRDMAReceivers];

        if (warp_role == WarpRole::kNVLAndRDMAForwarder) {
            // Receive from NVL ranks and forward to RDMA ranks
            // NOTES: this part is using "large warps" for each RDMA ranks
            const auto dst_rdma_rank = target_rank / kNumWarpsPerForwarder;
            const auto sub_warp_id   = target_rank % kNumWarpsPerForwarder;
            auto send_buffer         = dst_rdma_rank == rdma_rank ? rdma_channel_data.recv_buffer(dst_rdma_rank) : rdma_channel_data.send_buffer(dst_rdma_rank);
            // auto sync_large_warp     = [=]() {
            //     if(kNumWarpsPerForwarder == 1) {
            //         syncwarp();
            //     } else {
            //         // asm volatile("bar.sync %0, %1;" ::"r"(dst_rdma_rank + 2), "r"(kNumWarpsPerForwarder * kWarpSize));
            //         // __syncthreads();
            //         syncwarp();
            //     }
            // };
            auto sync_large_warp = [=](const int iter, const int mode) {
                if (kNumWarpsPerForwarder == 1) {
                    syncwarp();
                } else {
                        // LDS index to store for sync
                        int lds_dst_rdma_rank = dst_rdma_rank + (iter % num_sync_large_iteration) * kNumRDMARanks + mode * rdma_warp_counters;
                        //reset index in the LDS to avoid race condition due to warp scheduling
                        int reset_idx =         dst_rdma_rank + ((iter + num_sync_large_iteration/2) % num_sync_large_iteration) * kNumRDMARanks + mode * rdma_warp_counters;
                        // // if (lane_id==0)
                        // //     printf("rank %d dst_rdma_rank %d iter %d  warp_id %d  val %d\n", rank, dst_rdma_rank, iter, warp_id, sync_large_warp_counters[lds_dst_rdma_rank]);
                        auto start_time = wall_clock64();
                        if (lane_id == 0){
                            volatile int ret = atomicAdd((int*)&sync_large_warp_counters[lds_dst_rdma_rank], 1);
                        }
                        syncwarp();
                        //The while(...) loop polls the counter until all warps have arrived
                        if (lane_id == 0){
                            while (sync_large_warp_counters[lds_dst_rdma_rank] < (kNumWarpsPerForwarder)){
                                if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES) {
                                    printf("DeepEP combine sync timeout. current num_sync_large_iteration %d. double it.\n", num_sync_large_iteration );
                                    trap();
                                }
                            }
                        }
                        syncwarp();
                        if (lane_id == 0 && sync_large_warp_counters[reset_idx] == kNumWarpsPerForwarder){
                            sync_large_warp_counters[reset_idx] = 0;
                        }
                        syncwarp();
                }
            };
            EP_STATIC_ASSERT(kNumWarpsPerForwarder == 1 or kNumRDMARanks + 2 <= kNumCombineForwarderWarps, "Barriers are not enough");

            // Advance to the corresponding NVL buffer， 基于原本指针进行的地址偏移
            nvl_channel_x.advance(dst_rdma_rank * num_max_nvl_chunked_recv_tokens_per_rdma * hidden_int4);
            nvl_channel_src_meta.advance(dst_rdma_rank * num_max_nvl_chunked_recv_tokens_per_rdma);
            nvl_channel_topk_weights.advance(dst_rdma_rank * num_max_nvl_chunked_recv_tokens_per_rdma * num_topk);
            nvl_channel_head.advance(dst_rdma_rank);
            nvl_channel_tail.advance(dst_rdma_rank);

            // Clean shared memory and sync
            EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS <= kWarpSize, "Invalid number of NVL peers");
            lane_id < NUM_MAX_NVL_PEERS ? (forwarder_nvl_head[target_rank][lane_id] = 0) : 0;
            lane_id == 0 ? (forwarder_retired[target_rank] = false) : false;
            // sync_forwarder_smem();
            __syncthreads();

            // Get count and cached head
            int cached_nvl_channel_tail_idx = 0;
            int num_tokens_to_combine = rdma_channel_prefix_matrix[dst_rdma_rank * num_channels + channel_id];
            int num_tokens_prefix = channel_id == 0 ? 0 : rdma_channel_prefix_matrix[dst_rdma_rank * num_channels + channel_id - 1];
            num_tokens_to_combine -= num_tokens_prefix;
            num_tokens_prefix += dst_rdma_rank == 0 ? 0 : rdma_rank_prefix_sum[dst_rdma_rank - 1];
            combined_nvl_head += num_tokens_prefix * NUM_MAX_NVL_PEERS;

            // Iterate over all tokens and combine by chunks
            for(int token_start_idx = 0; token_start_idx < num_tokens_to_combine; token_start_idx += num_max_rdma_chunked_send_tokens) {
                // Check destination queue emptiness, or wait a buffer to be released
                auto token_end_idx      = min(token_start_idx + num_max_rdma_chunked_send_tokens, num_tokens_to_combine);
                auto num_chunked_tokens = token_end_idx - token_start_idx;
                auto start_time         = wall_clock64();
                while(sub_warp_id == 0 and lane_id == 0) {
                    // Inequality: `num_max_rdma_chunked_recv_tokens - (tail - head) >= num_chunked_tokens`
                    // Here, `token_start_idx` is the actual tail
                    int num_used_slots = token_start_idx - ld_volatile_global(rdma_channel_head.buffer(dst_rdma_rank));

                    if(num_max_rdma_chunked_recv_tokens - num_used_slots >= num_chunked_tokens)
                        break;

                    // Timeout check
                    if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES) {
                        printf("DeepEP combine forwarder (RDMA check) timeout, channel: %d, RDMA: %d, nvl: %d, dst RDMA: %d, head: %ld, tail: %d, chunked: %d\n",
                                channel_id, rdma_rank, nvl_rank, dst_rdma_rank, ld_volatile_global(rdma_channel_head.buffer(dst_rdma_rank)), token_start_idx, num_chunked_tokens);
                        trap();
                    }
                }
                // sync_large_warp();
                sync_large_warp(token_start_idx, 0);

                // Combine and write to the RDMA buffer
                for(int token_idx = token_start_idx + sub_warp_id; token_idx < token_end_idx; token_idx += kNumWarpsPerForwarder) {
                    // Read expected head
                    EP_STATIC_ASSERT(kNumRDMARanks <= kWarpSize, "Invalid number of RDMA peers");
                    int expected_head = -1;
                    if(lane_id < NUM_MAX_NVL_PEERS)
                        expected_head = ld_nc_global(combined_nvl_head + token_idx * NUM_MAX_NVL_PEERS + lane_id);

                    // Wait lanes to be ready
                    start_time = wall_clock64();
                    while(cached_nvl_channel_tail_idx <= expected_head) {
                        cached_nvl_channel_tail_idx = ld_acquire_sys_global(nvl_channel_tail.buffer(lane_id));

                        // Timeout check
                        if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES and lane_id < NUM_MAX_NVL_PEERS) {
                            printf("DeepEP combine forwarder (NVL check) timeout, channel: %d, RDMA: %d, nvl: %d, src NVL: %d, dst RDMA: %d, tail: %d, waiting: %d, total: %d, sub: %d, large: %d, expected: %d\n",
                                    channel_id, rdma_rank, nvl_rank, lane_id, dst_rdma_rank, cached_nvl_channel_tail_idx, token_idx, num_tokens_to_combine, sub_warp_id, kNumWarpsPerForwarder, expected_head);
                            trap();
                        }
                    }

                    // Combine current token
                    auto rdma_slot_idx = token_idx % num_max_rdma_chunked_recv_tokens;
                    void* shifted = send_buffer + rdma_slot_idx * num_bytes_per_rdma_token;
                    auto recv_fn = [&](int src_nvl_rank, int slot_idx, int hidden_int4_idx) -> int4 { return ld_nc_global(nvl_channel_x.buffer(src_nvl_rank) + slot_idx * hidden_int4 + hidden_int4_idx); };
                    auto recv_tw_fn = [&](int src_nvl_rank, int slot_idx, int topk_idx) -> float { return ld_nc_global(nvl_channel_topk_weights.buffer(src_nvl_rank) + slot_idx * num_topk + topk_idx); };
                    combine_token<NUM_MAX_NVL_PEERS, dtype_t, NUM_MAX_NVL_PEERS>(expected_head >= 0,
                                                                                    expected_head, lane_id,
                                                                                    hidden_int4, num_topk,
                                                                                    reinterpret_cast<int4*>(shifted),
                                                                                    reinterpret_cast<float*>(reinterpret_cast<int8_t*>(shifted) + hidden_bytes + sizeof(SourceMeta)),
                                                                                    num_max_nvl_chunked_recv_tokens_per_rdma, recv_fn, recv_tw_fn);

                    // Update head
                    if(lane_id < NUM_MAX_NVL_PEERS) {
                        expected_head < 0 ? (forwarder_nvl_head[target_rank][lane_id] = -expected_head - 1)
                                        : (forwarder_nvl_head[target_rank][lane_id] = expected_head + 1);
                    }
                }
                // sync_large_warp();
                sync_large_warp(token_start_idx, 1);

                // Issue RDMA send
                if(sub_warp_id == kNumWarpsPerForwarder - 1) {
                    if(dst_rdma_rank != rdma_rank) {
                        auto rdma_slot_idx = token_start_idx % num_max_rdma_chunked_recv_tokens;
                        rocshmem::rocshmem_ctx_schar_put_nbi_wave(
                            ctx,
                            rdma_channel_data.recv_buffer(rdma_rank) +
                                rdma_slot_idx * num_bytes_per_rdma_token,
                            rdma_channel_data.send_buffer(dst_rdma_rank) +
                                rdma_slot_idx * num_bytes_per_rdma_token,
                            num_chunked_tokens * num_bytes_per_rdma_token,
                            translate_dst_rdma_rank<kLowLatencyMode>(dst_rdma_rank, nvl_rank));

                        rocshmem::rocshmem_ctx_quiet(ctx);
                    } else {
                        memory_fence();
                    }

                    // Write new RDMA tail
                    syncwarp();
                    if(lane_id == 0) {
                        rocshmem::rocshmem_ctx_ulong_atomic_add(
                            ctx, rdma_channel_tail.buffer(rdma_rank), num_chunked_tokens,
                            translate_dst_rdma_rank<kLowLatencyMode>(dst_rdma_rank, nvl_rank));
                    }
                }
            }

            // Retired
            syncwarp();
            if(lane_id == 0) {
                forwarder_retired[target_rank] = true;
            }
        } else if (warp_role == WarpRole::kRDMACoordinator) {
            // Coordinator
            // Sync shared memory status
            // sync_forwarder_smem();
            __syncthreads();
            constexpr int num_warps_per_rdma_rank = kNumForwarders / kNumRDMARanks;

            int last_nvl_head[kNumRDMARanks] = {0};
            int dst_nvl_rank                 = lane_id < NUM_MAX_NVL_PEERS ? lane_id : 0;
            EP_STATIC_ASSERT(kNumCombineForwarderWarps <= kWarpSize, "Invalid number of forwarder warps");

            while(true) {
                // Retired
                if(__all_sync(kFullWarpMask, lane_id >= kNumForwarders or forwarder_retired[lane_id]))
                    break;

                {
                    // Find minimum head for NVL ranks
                    #pragma unroll
                    for(int i = 0; i < kNumRDMARanks; ++i) {
                        int min_head = std::numeric_limits<int>::max();
                        #pragma unroll
                        for(int j = 0; j < num_warps_per_rdma_rank; ++j)
                            if(not forwarder_retired[i * num_warps_per_rdma_rank + j])
                                min_head = min(min_head, forwarder_nvl_head[i * num_warps_per_rdma_rank + j][dst_nvl_rank]);

                        if(min_head != std::numeric_limits<int>::max() and min_head > last_nvl_head[i] and lane_id < NUM_MAX_NVL_PEERS) {
                            st_relaxed_sys_global(nvl_channel_head.buffer_by(dst_nvl_rank) + i, last_nvl_head[i] = min_head);
                        }
                    }
                }

                // Nanosleep and let other warps work
                __builtin_amdgcn_s_sleep(NUM_WAIT_CYCLES_TIMES_64);
            }
        } else if(warp_role == WarpRole::kRDMAReceiver) {
            // Receive from RDMA ranks and write to the output tensor
            // Clean shared memory and sync
            EP_DEVICE_ASSERT(kNumRDMARanks <= kWarpSize);
            lane_id < kNumRDMARanks ? (rdma_receiver_rdma_head[target_rank][lane_id] = 0) : 0;
            lane_id == 0 ? (rdma_receiver_retired[target_rank] = false) : 0;
            // sync_rdma_receiver_smem();
            __syncthreads();

            // The same tokens as the dispatch process
            int token_start_idx, token_end_idx;
            get_channel_task_range(num_combined_tokens, num_channels, channel_id, token_start_idx, token_end_idx);

            // Iterate over all tokens and combine
            int cached_channel_tail_idx = 0;
            for(int64_t token_idx = token_start_idx + target_rank; token_idx < token_end_idx; token_idx += kNumRDMAReceivers) {
                // Read expected head
                EP_STATIC_ASSERT(kNumRDMARanks <= kWarpSize, "Invalid number of RDMA peers");
                int expected_head = -1;
                if(lane_id < kNumRDMARanks) {
                    expected_head = ld_nc_global(combined_rdma_head + token_idx * kNumRDMARanks + lane_id);
                    (expected_head < 0) ? (rdma_receiver_rdma_head[target_rank][lane_id] = -expected_head - 1)
                                        : (rdma_receiver_rdma_head[target_rank][lane_id] = expected_head);
                }

                // Wait lanes to be ready
                auto start_time = wall_clock64();
                while (cached_channel_tail_idx <= expected_head) {
                    cached_channel_tail_idx = static_cast<int>(ld_acquire_sys_global(rdma_channel_tail.buffer(lane_id)));

                    // Timeout check
                    if (wall_clock64() - start_time > NUM_TIMEOUT_CYCLES) {
                        printf("DeepEP combine RDMA receiver timeout, channel: %d, RDMA: %d, nvl: %d, src RDMA: %d, tail: %d, waiting: %ld, expect: %d\n",
                                channel_id, rdma_rank, nvl_rank, lane_id, cached_channel_tail_idx, token_idx, expected_head);
                        trap();
                    }
                }
                syncwarp();

                // Combine current token
                auto recv_fn = [&](int src_rdma_rank, int slot_idx, int hidden_int4_idx) -> int4 { return ld_nc_global(reinterpret_cast<const int4*>(rdma_channel_data.recv_buffer(src_rdma_rank) + slot_idx * num_bytes_per_rdma_token) + hidden_int4_idx);};
                auto recv_tw_fn = [&](int src_rdma_rank, int slot_idx, int topk_idx) -> float { return ld_nc_global(reinterpret_cast<const float*>(rdma_channel_data.recv_buffer(src_rdma_rank) + slot_idx * num_bytes_per_rdma_token + hidden_bytes + sizeof(SourceMeta)) + topk_idx);};
                combine_token<kNumRDMARanks, dtype_t, kNumTopkRDMARanks>(expected_head >= 0,
                                                                            expected_head, lane_id,
                                                                            hidden_int4, num_topk,
                                                                            combined_x + token_idx * hidden_int4,
                                                                            combined_topk_weights + token_idx * num_topk,
                                                                            num_max_rdma_chunked_recv_tokens, recv_fn, recv_tw_fn);
            }

            // Retired
            syncwarp();
            if(lane_id == 0) {
                rdma_receiver_retired[target_rank] = true;
            }
        } else if(warp_role == WarpRole::kNVLCoordinator) {
            // Coordinator
            // Sync shared memory status
            // sync_rdma_receiver_smem();
            __syncthreads();
            const auto num_warps_per_rdma_rank = kNumForwarders / kNumRDMARanks;

            int last_rdma_head               = 0;
            int last_nvl_head[kNumRDMARanks] = {0};
            int dst_rdma_rank                = lane_id < kNumRDMARanks ? lane_id : 0;
            int dst_nvl_rank                 = lane_id < NUM_MAX_NVL_PEERS ? lane_id : 0;
            EP_STATIC_ASSERT(kNumCombineForwarderWarps <= kWarpSize, "Invalid number of forwarder warps");

            while(true) {
                // Retired
                if(__all_sync(kFullWarpMask, lane_id >= kNumRDMAReceivers or rdma_receiver_retired[lane_id]))
                    break;

                // Find minimum head for RDMA ranks
                {
                    int min_head = std::numeric_limits<int>::max();
    #pragma unroll
                    for(int i = 0; i < kNumRDMAReceivers; ++i)
                        if(not rdma_receiver_retired[i])
                            min_head = min(min_head, rdma_receiver_rdma_head[i][dst_rdma_rank]);

                    if (min_head != std::numeric_limits<int>::max() and min_head >= last_rdma_head + num_max_rdma_chunked_send_tokens and lane_id < kNumRDMARanks) {
                        rocshmem::rocshmem_ctx_ulong_atomic_add(
                            ctx, rdma_channel_head.buffer(rdma_rank), min_head - last_rdma_head,
                            translate_dst_rdma_rank<kLowLatencyMode>(dst_rdma_rank, nvl_rank));

                        last_rdma_head = min_head;
                    }
                }

                // Nanosleep and let other warps work
                __builtin_amdgcn_s_sleep(NUM_WAIT_CYCLES_TIMES_64);
            }
        }
    }
    rocshmem::rocshmem_wg_ctx_destroy(&ctx);
}

void combine(hipDataType type, void *combined_x, float *combined_topk_weights,
             const bool *is_combined_token_in_rank, const void *x, const float *topk_weights,
             const void *bias_0, const void *bias_1, const int *combined_rdma_head,
             const int *combined_nvl_head, const void *src_meta,
             const int *rdma_channel_prefix_matrix, const int *rdma_rank_prefix_sum,
             const int *gbl_channel_prefix_matrix, int num_tokens, int num_combined_tokens,
             int hidden, int num_topk, void *rdma_buffer_ptr, int num_max_rdma_chunked_send_tokens,
             int num_max_rdma_chunked_recv_tokens, void **buffer_ptrs,
             int num_max_nvl_chunked_send_tokens, int num_max_nvl_chunked_recv_tokens, int rank,
             int num_ranks, hipStream_t stream, int num_channels, bool low_latency_mode) {
    constexpr int kNumCombineForwarderWarps = 8;

#define COMBINE_LAUNCH_CASE(num_rdma_ranks)                                                        \
    {                                                                                              \
        auto combine_func =                                                                        \
            low_latency_mode                                                                       \
                ? combine<true, num_rdma_ranks, hip_bfloat16, kNumCombineForwarderWarps>           \
                : combine<false, num_rdma_ranks, hip_bfloat16, kNumCombineForwarderWarps>;         \
        LAUNCH_KERNEL_NON_COOPERATIVE(                                                             \
            &cfg, combine_func, reinterpret_cast<int4 *>(combined_x), combined_topk_weights,       \
            is_combined_token_in_rank, reinterpret_cast<const int4 *>(x), topk_weights,            \
            reinterpret_cast<const int4 *>(bias_0), reinterpret_cast<const int4 *>(bias_1),        \
            combined_rdma_head, combined_nvl_head, reinterpret_cast<const SourceMeta *>(src_meta), \
            rdma_channel_prefix_matrix, rdma_rank_prefix_sum, gbl_channel_prefix_matrix,           \
            num_tokens, num_combined_tokens, hidden, num_topk, rdma_buffer_ptr,                    \
            num_max_rdma_chunked_send_tokens, num_max_rdma_chunked_recv_tokens, buffer_ptrs,       \
            num_max_nvl_chunked_send_tokens, num_max_nvl_chunked_recv_tokens, rank, num_ranks);    \
    }                                                                                              \
    break

    int num_rdma_ranks           = num_ranks / NUM_MAX_NVL_PEERS;
    auto num_warps_per_forwarder = std::max(kNumCombineForwarderWarps / num_rdma_ranks, 1);
    int num_forwarder_warps      = num_rdma_ranks * num_warps_per_forwarder;
    EP_HOST_ASSERT(num_forwarder_warps >= NUM_MAX_NVL_PEERS);
    EP_HOST_ASSERT(num_forwarder_warps > 0 and num_forwarder_warps % num_rdma_ranks == 0);
    EP_HOST_ASSERT(num_max_nvl_chunked_recv_tokens % num_rdma_ranks == 0);
    EP_HOST_ASSERT(num_max_nvl_chunked_recv_tokens / num_rdma_ranks > std::max(num_max_rdma_chunked_send_tokens, num_max_nvl_chunked_send_tokens));
    EP_HOST_ASSERT(type == HIP_R_16BF);

    SETUP_LAUNCH_CONFIG(num_channels * NUM_INTERNODE_DISPATCH_BLOCKS_PER_CHANNEL, (NUM_MAX_NVL_PEERS + 1) * kWarpSize, stream);
    SWITCH_RDMA_RANKS(COMBINE_LAUNCH_CASE);
#undef COMBINE_LAUNCH_CASE
}

} // namespace internode

} // namespace deep_ep

// #ifdef __clang__
// #pragma clang diagnostic pop
// #endif // __clang__

#endif