Add the transaction window data structure for RDMA senders (#245)

* Add draft

* Add fast-debugging flags

* Fix several bugs

* Add sender timeout checks

* Fix stuck

* Fix bugs

* Fix bugs
This commit is contained in:
Chenggang Zhao
2025-06-24 09:12:40 +08:00
committed by GitHub
parent 9eb2f84b3e
commit bc118b248a
6 changed files with 101 additions and 54 deletions

View File

@@ -365,7 +365,7 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
const bool is_forwarder = sm_id % 2 == 0;
const auto rdma_rank = rank / NUM_MAX_NVL_PEERS, nvl_rank = rank % NUM_MAX_NVL_PEERS;
EP_DEVICE_ASSERT(ibgda_get_state()->num_rc_per_pe == num_channels || ibgda_get_state()->num_rc_per_pe >= num_sms);
EP_DEVICE_ASSERT(ibgda_get_state()->num_rc_per_pe == num_channels or ibgda_get_state()->num_rc_per_pe >= num_sms);
const auto role_meta = [=]() -> std::pair<WarpRole, int> {
if (is_forwarder) {
@@ -419,9 +419,11 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
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];
// NOTES: `rdma_send_channel_tail` means the latest released tail
// NOTES: `rdma_send_channel_window` means the ongoing 32 transactions' status
__shared__ int rdma_send_channel_lock[kNumRDMARanks];
__shared__ int rdma_send_channel_tail[kNumRDMARanks];
__shared__ uint32_t rdma_send_channel_window[kNumRDMARanks];
auto sync_rdma_sender_smem = []() { asm volatile("bar.sync 0, %0;" :: "r"((kNumDispatchRDMASenderWarps + 1) * 32)); };
// Forward warp synchronization
@@ -434,12 +436,6 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
int token_start_idx, token_end_idx;
get_channel_task_range(num_tokens, num_channels, channel_id, token_start_idx, token_end_idx);
// Clean shared memory
EP_STATIC_ASSERT(kNumRDMARanks <= 32, "Invalid number of RDMA ranks");
(warp_id == 0 and lane_id == 0) ? (rdma_send_next_token_idx = token_start_idx) : 0;
(warp_id == 0 and lane_id < kNumRDMARanks) ? (rdma_send_channel_tail[lane_id] = 0) : 0;
(warp_id == 0 and lane_id < kNumRDMARanks) ? (rdma_send_channel_next_tail[lane_id] = 0) : 0;
// Send number of tokens in this channel by `-value - 1`
EP_STATIC_ASSERT(NUM_MAX_NVL_PEERS * 2 + 2 <= 32, "Invalid number of NVL peers");
for (int dst_rdma_rank = warp_id; dst_rdma_rank < kNumRDMARanks; dst_rdma_rank += kNumDispatchRDMASenderWarps) {
@@ -468,24 +464,33 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
// Iterate over tokens and copy into buffer
int64_t token_idx;
int cached_rdma_channel_head = 0, last_rdma_tail_idx = -1;
int cached_rdma_channel_head = 0, global_rdma_tail_idx = 0;
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) {
for (token_idx = token_start_idx; token_idx < token_end_idx; ++ token_idx) {
// Read RDMA rank existence
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);
// Acquire sequential lock
while (lane_id == 0 and rdma_send_next_token_idx != token_idx);
if (lane_id < kNumRDMARanks) {
is_token_in_rank_uint64 = __ldg(reinterpret_cast<const uint64_t*>(is_token_in_rank + token_idx * num_ranks + lane_id * NUM_MAX_NVL_PEERS));
global_rdma_tail_idx += (is_token_in_rank_uint64 != 0);
}
__syncwarp();
// Acquire next tail
int rdma_tail_idx = -1;
if (is_token_in_rank_uint64 != 0) {
rdma_tail_idx = rdma_send_channel_next_tail[lane_id] ++;
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)));
// Skip the token which does not belong to this warp
if ((token_idx - token_start_idx) % kNumDispatchRDMASenderWarps != warp_id)
continue;
auto rdma_tail_idx = is_token_in_rank_uint64 == 0 ? -1 : global_rdma_tail_idx - 1;
// Wait the remote buffer to be released
auto start_time = clock64();
while (is_token_in_rank_uint64 != 0 and 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)));
// Timeout check
if (clock64() - start_time >= NUM_TIMEOUT_CYCLES) {
printf("DeepEP dispatch RDMA sender timeout, channel: %d, RDMA: %d, nvl: %d, dst RDMA lane: %d, head: %d, tail: %d\n",
channel_id, rdma_rank, nvl_rank, lane_id, cached_rdma_channel_head, rdma_tail_idx);
trap();
}
}
__syncwarp();
@@ -493,14 +498,6 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
if (lane_id < kNumRDMARanks and not kCachedMode)
send_rdma_head[token_idx * kNumRDMARanks + lane_id] = rdma_tail_idx;
// Update last token tail
if (last_rdma_tail_idx >= 0)
st_release_cta(const_cast<const int *>(rdma_send_channel_tail + lane_id), last_rdma_tail_idx + 1);
last_rdma_tail_idx = rdma_tail_idx;
// Release sequential lock
lane_id == 0 ? (rdma_send_next_token_idx += 1) : 0;
// Broadcast tails
SourceMeta src_meta;
int num_topk_ranks = 0, topk_ranks[kNumTopkRDMARanks];
@@ -557,24 +554,46 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
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);
}
__syncwarp();
// Release the transaction in the window
if (is_token_in_rank_uint64 != 0) {
// Acquire lock first
acquire_lock(rdma_send_channel_lock + lane_id);
// Release the transaction slot
auto rdy_window = rdma_send_channel_window[lane_id];
auto latest_tail = rdma_send_channel_tail[lane_id];
auto offset = rdma_tail_idx - latest_tail;
// The same effect with `EP_DEVICE_ASSERT(offset < 32);`
EP_STATIC_ASSERT(kNumDispatchRDMASenderWarps < 32, "Invalid warps");
// Erase bit and move the ones if possible
rdy_window ^= 1u << offset;
if (offset == 0) {
EP_DEVICE_ASSERT(rdy_window & 1);
auto num_empty_slots = __ffs(~rdy_window) - 1;
st_release_cta(rdma_send_channel_tail + lane_id, latest_tail + num_empty_slots);
rdy_window >>= num_empty_slots;
}
rdma_send_channel_window[lane_id] = rdy_window;
// Release lock
release_lock(rdma_send_channel_lock + lane_id);
}
__syncwarp();
}
// Epilogue
// Acquire sequential lock
while (lane_id == 0 and rdma_send_next_token_idx != token_idx);
__syncwarp();
// Update last token tail
if (last_rdma_tail_idx >= 0)
st_release_cta(const_cast<const int*>(rdma_send_channel_tail + lane_id), last_rdma_tail_idx + 1);
__syncwarp();
// Release sequential lock
lane_id == 0 ? (rdma_send_next_token_idx += 1) : 0;
} else if (warp_role == WarpRole::kRDMASenderCoordinator) {
// NOTES: in case of splitting, the issued put at the end of the buffer
EP_DEVICE_ASSERT(num_max_rdma_chunked_recv_tokens % num_max_rdma_chunked_send_tokens == 0);
// Clean shared memory
EP_STATIC_ASSERT(kNumRDMARanks <= 32, "Invalid number of RDMA ranks");
(lane_id < kNumRDMARanks) ? (rdma_send_channel_lock[lane_id] = 0) : 0;
(lane_id < kNumRDMARanks) ? (rdma_send_channel_tail[lane_id] = 0) : 0;
(lane_id < kNumRDMARanks) ? (rdma_send_channel_window[lane_id] = 0) : 0;
// Synchronize shared memory
sync_rdma_sender_smem();
@@ -592,10 +611,12 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
while (__any_sync(0xffffffff, num_tokens_to_send > 0)) {
// Timeout check
if (clock64() - start_time > NUM_TIMEOUT_CYCLES and lane_id < kNumRDMARanks) {
printf("DeepEP RDMA sender coordinator timeout, channel: %d, IB: %d, nvl %d, dst IB: %d, tail %d, num_tokens_to_send %d\n",
printf("DeepEP RDMA sender coordinator timeout, channel: %d, IB: %d, nvl %d, dst IB: %d, tail: %d, remaining: %d\n",
channel_id, rdma_rank, nvl_rank, lane_id, last_issued_tail, num_tokens_to_send);
trap();
}
// TODO: try thread-level `put_nbi`?
for (int i = 0, synced_num_tokens_to_send; i < kNumRDMARanks; ++ i) {
// To mitigate incast congestion, shuffle the starting index of target rank for different ranks and channels
int dst_rdma_rank = (i + channel_id + rdma_rank) % kNumRDMARanks;
@@ -603,9 +624,10 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
if (synced_num_tokens_to_send == 0)
continue;
// Read progress
auto synced_last_issued_tail = __shfl_sync(0xffffffff, last_issued_tail, dst_rdma_rank);
// Read the latest progress
// NOTES: `rdma_send_channel_tail` does not need to be protected by lock
auto processed_tail = __shfl_sync(0xffffffff, ld_acquire_cta(const_cast<const int*>(rdma_send_channel_tail + dst_rdma_rank)), 0);
auto synced_last_issued_tail = __shfl_sync(0xffffffff, last_issued_tail, dst_rdma_rank);
auto num_tokens_processed = processed_tail - synced_last_issued_tail;
if (num_tokens_processed != synced_num_tokens_to_send and num_tokens_processed < num_max_rdma_chunked_send_tokens)
continue;
@@ -625,9 +647,9 @@ dispatch(int4* recv_x, float* recv_x_scales, int64_t* recv_topk_idx, float* recv
// Lighter fence for local RDMA rank
memory_fence();
}
__syncwarp();
// Update tails
__syncwarp();
if (lane_id == dst_rdma_rank) {
last_issued_tail += num_tokens_to_issue;
num_tokens_to_send -= num_tokens_to_issue;