1 /* Copyright (c) 2013-2014. The SimGrid Team.
2 * All rights reserved. */
4 /* This program is free software; you can redistribute it and/or modify it
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9 * University Research and Technology
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14 * Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
15 * University of Stuttgart. All rights reserved.
16 * Copyright (c) 2004-2005 The Regents of the University of California.
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18 * Copyright (c) 2009 University of Houston. All rights reserved.
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59 * ompi_coll_tuned_allreduce_intra_ring_segmented
61 * Function: Pipelined ring algorithm for allreduce operation
62 * Accepts: Same as MPI_Allreduce(), segment size
63 * Returns: MPI_SUCCESS or error code
65 * Description: Implements pipelined ring algorithm for allreduce:
66 * user supplies suggested segment size for the pipelining of
68 * The segment size determines the number of phases, np, for
69 * the algorithm execution.
70 * The message is automatically divided into blocks of
71 * approximately (count / (np * segcount)) elements.
72 * At the end of reduction phase, allgather like step is
74 * Algorithm requires (np + 1)*(N - 1) steps.
76 * Limitations: The algorithm DOES NOT preserve order of operations so it
77 * can be used only for commutative operations.
78 * In addition, algorithm cannot work if the total size is
79 * less than size * segment size.
80 * Example on 3 nodes with 2 phases
90 * COMPUTATION PHASE 0 (a)
91 * Step 0: rank r sends block ra to rank (r+1) and receives bloc (r-1)a
92 * from rank (r-1) [with wraparound].
94 * [00a] [00a+10a] [20a]
96 * [01a] [11a] [11a+21a]
98 * [22a+02a] [12a] [22a]
101 * Step 1: rank r sends block (r-1)a to rank (r+1) and receives bloc
102 * (r-2)a from rank (r-1) [with wraparound].
104 * [00a] [00a+10a] [00a+10a+20a]
106 * [11a+21a+01a] [11a] [11a+21a]
108 * [22a+02a] [22a+02a+12a] [22a]
111 * COMPUTATION PHASE 1 (b)
112 * Step 0: rank r sends block rb to rank (r+1) and receives bloc (r-1)b
113 * from rank (r-1) [with wraparound].
115 * [00a] [00a+10a] [20a]
116 * [00b] [00b+10b] [20b]
117 * [01a] [11a] [11a+21a]
118 * [01b] [11b] [11b+21b]
119 * [22a+02a] [12a] [22a]
120 * [22b+02b] [12b] [22b]
122 * Step 1: rank r sends block (r-1)b to rank (r+1) and receives bloc
123 * (r-2)b from rank (r-1) [with wraparound].
125 * [00a] [00a+10a] [00a+10a+20a]
126 * [00b] [10b] [0bb+10b+20b]
127 * [11a+21a+01a] [11a] [11a+21a]
128 * [11b+21b+01b] [11b] [21b]
129 * [22a+02a] [22a+02a+12a] [22a]
130 * [02b] [22b+01b+12b] [22b]
133 * DISTRIBUTION PHASE: ring ALLGATHER with ranks shifted by 1 (same as
134 * in regular ring algorithm.
138 #define COLL_TUNED_COMPUTED_SEGCOUNT(SEGSIZE, TYPELNG, SEGCOUNT) \
139 if( ((SEGSIZE) >= (TYPELNG)) && \
140 ((SEGSIZE) < ((TYPELNG) * (SEGCOUNT))) ) { \
142 (SEGCOUNT) = (int)((SEGSIZE) / (TYPELNG)); \
143 residual = (SEGSIZE) - (SEGCOUNT) * (TYPELNG); \
144 if( residual > ((TYPELNG) >> 1) ) \
148 #define COLL_TUNED_COMPUTE_BLOCKCOUNT( COUNT, NUM_BLOCKS, SPLIT_INDEX, \
149 EARLY_BLOCK_COUNT, LATE_BLOCK_COUNT ) \
150 EARLY_BLOCK_COUNT = LATE_BLOCK_COUNT = COUNT / NUM_BLOCKS; \
151 SPLIT_INDEX = COUNT % NUM_BLOCKS; \
152 if (0 != SPLIT_INDEX) { \
153 EARLY_BLOCK_COUNT = EARLY_BLOCK_COUNT + 1; \
156 #include "colls_private.h"
158 smpi_coll_tuned_allreduce_ompi_ring_segmented(void *sbuf, void *rbuf, int count,
163 int ret = MPI_SUCCESS;
165 int k, recv_from, send_to;
166 int early_blockcount, late_blockcount, split_rank;
167 int segcount, max_segcount;
168 int num_phases, phase;
172 char *tmpsend = NULL, *tmprecv = NULL;
173 char *inbuf[2] = {NULL, NULL};
174 ptrdiff_t true_extent, extent;
175 ptrdiff_t block_offset, max_real_segsize;
176 MPI_Request reqs[2] = {NULL, NULL};
177 const size_t segsize = 1 << 20; /* 1 MB */
178 unsigned int size = smpi_comm_size(comm);
179 unsigned int rank = smpi_comm_rank(comm);
181 XBT_DEBUG("coll:tuned:allreduce_intra_ring_segmented rank %d, count %d", rank, count);
183 /* Special case for size == 1 */
185 if (MPI_IN_PLACE != sbuf) {
186 ret= smpi_datatype_copy(sbuf, count, dtype,rbuf, count, dtype);
187 if (ret < 0) { line = __LINE__; goto error_hndl; }
192 /* Determine segment count based on the suggested segment size */
193 extent = smpi_datatype_get_extent(dtype);
194 if (MPI_SUCCESS != ret) { line = __LINE__; goto error_hndl; }
195 true_extent = smpi_datatype_get_extent(dtype);
196 if (MPI_SUCCESS != ret) { line = __LINE__; goto error_hndl; }
197 typelng = smpi_datatype_size(dtype);
198 if (MPI_SUCCESS != ret) { line = __LINE__; goto error_hndl; }
200 COLL_TUNED_COMPUTED_SEGCOUNT(segsize, typelng, segcount)
202 /* Special case for count less than size * segcount - use regular ring */
203 if (count < size * segcount) {
204 XBT_DEBUG( "coll:tuned:allreduce_ring_segmented rank %d/%d, count %d, switching to regular ring", rank, size, count);
205 return (smpi_coll_tuned_allreduce_lr(sbuf, rbuf, count, dtype, op,
209 /* Determine the number of phases of the algorithm */
210 num_phases = count / (size * segcount);
211 if ((count % (size * segcount) >= size) &&
212 (count % (size * segcount) > ((size * segcount) / 2))) {
216 /* Determine the number of elements per block and corresponding
218 The blocks are divided into "early" and "late" ones:
219 blocks 0 .. (split_rank - 1) are "early" and
220 blocks (split_rank) .. (size - 1) are "late".
221 Early blocks are at most 1 element larger than the late ones.
222 Note, these blocks will be split into num_phases segments,
223 out of the largest one will have max_segcount elements.
225 COLL_TUNED_COMPUTE_BLOCKCOUNT( count, size, split_rank,
226 early_blockcount, late_blockcount )
227 COLL_TUNED_COMPUTE_BLOCKCOUNT( early_blockcount, num_phases, inbi,
229 max_real_segsize = true_extent + (max_segcount - 1) * extent;
231 /* Allocate and initialize temporary buffers */
232 inbuf[0] = (char*)smpi_get_tmp_sendbuffer(max_real_segsize);
233 if (NULL == inbuf[0]) { ret = -1; line = __LINE__; goto error_hndl; }
235 inbuf[1] = (char*)smpi_get_tmp_recvbuffer(max_real_segsize);
236 if (NULL == inbuf[1]) { ret = -1; line = __LINE__; goto error_hndl; }
239 /* Handle MPI_IN_PLACE */
240 if (MPI_IN_PLACE != sbuf) {
241 ret= smpi_datatype_copy(sbuf, count, dtype,rbuf, count, dtype);
242 if (ret < 0) { line = __LINE__; goto error_hndl; }
245 /* Computation loop: for each phase, repeat ring allreduce computation loop */
246 for (phase = 0; phase < num_phases; phase ++) {
247 ptrdiff_t phase_offset;
248 int early_phase_segcount, late_phase_segcount, split_phase, phase_count;
251 For each of the remote nodes:
252 - post irecv for block (r-1)
254 To do this, first compute block offset and count, and use block offset
255 to compute phase offset.
256 - in loop for every step k = 2 .. n
257 - post irecv for block (r + n - k) % n
258 - wait on block (r + n - k + 1) % n to arrive
259 - compute on block (r + n - k + 1) % n
260 - send block (r + n - k + 1) % n
261 - wait on block (r + 1)
262 - compute on block (r + 1)
263 - send block (r + 1) to rank (r + 1)
264 Note that we must be careful when computing the begining of buffers and
265 for send operations and computation we must compute the exact block size.
267 send_to = (rank + 1) % size;
268 recv_from = (rank + size - 1) % size;
271 /* Initialize first receive from the neighbor on the left */
272 reqs[inbi] = smpi_mpi_irecv(inbuf[inbi], max_segcount, dtype, recv_from,
274 /* Send first block (my block) to the neighbor on the right:
275 - compute my block and phase offset
277 block_offset = ((rank < split_rank)?
278 (rank * early_blockcount) :
279 (rank * late_blockcount + split_rank));
280 block_count = ((rank < split_rank)? early_blockcount : late_blockcount);
281 COLL_TUNED_COMPUTE_BLOCKCOUNT(block_count, num_phases, split_phase,
282 early_phase_segcount, late_phase_segcount)
283 phase_count = ((phase < split_phase)?
284 (early_phase_segcount) : (late_phase_segcount));
285 phase_offset = ((phase < split_phase)?
286 (phase * early_phase_segcount) :
287 (phase * late_phase_segcount + split_phase));
288 tmpsend = ((char*)rbuf) + (block_offset + phase_offset) * extent;
289 smpi_mpi_send(tmpsend, phase_count, dtype, send_to,
292 for (k = 2; k < size; k++) {
293 const int prevblock = (rank + size - k + 1) % size;
297 /* Post irecv for the current block */
298 reqs[inbi] = smpi_mpi_irecv(inbuf[inbi], max_segcount, dtype, recv_from,
300 if (MPI_SUCCESS != ret) { line = __LINE__; goto error_hndl; }
302 /* Wait on previous block to arrive */
303 smpi_mpi_wait(&reqs[inbi ^ 0x1], MPI_STATUS_IGNORE);
305 /* Apply operation on previous block: result goes to rbuf
306 rbuf[prevblock] = inbuf[inbi ^ 0x1] (op) rbuf[prevblock]
308 block_offset = ((prevblock < split_rank)?
309 (prevblock * early_blockcount) :
310 (prevblock * late_blockcount + split_rank));
311 block_count = ((prevblock < split_rank)?
312 early_blockcount : late_blockcount);
313 COLL_TUNED_COMPUTE_BLOCKCOUNT(block_count, num_phases, split_phase,
314 early_phase_segcount, late_phase_segcount)
315 phase_count = ((phase < split_phase)?
316 (early_phase_segcount) : (late_phase_segcount));
317 phase_offset = ((phase < split_phase)?
318 (phase * early_phase_segcount) :
319 (phase * late_phase_segcount + split_phase));
320 tmprecv = ((char*)rbuf) + (block_offset + phase_offset) * extent;
321 smpi_op_apply(op, inbuf[inbi ^ 0x1], tmprecv, &phase_count, &dtype);
322 /* send previous block to send_to */
323 smpi_mpi_send(tmprecv, phase_count, dtype, send_to,
327 /* Wait on the last block to arrive */
328 smpi_mpi_wait(&reqs[inbi], MPI_STATUS_IGNORE);
331 /* Apply operation on the last block (from neighbor (rank + 1)
332 rbuf[rank+1] = inbuf[inbi] (op) rbuf[rank + 1] */
333 recv_from = (rank + 1) % size;
334 block_offset = ((recv_from < split_rank)?
335 (recv_from * early_blockcount) :
336 (recv_from * late_blockcount + split_rank));
337 block_count = ((recv_from < split_rank)?
338 early_blockcount : late_blockcount);
339 COLL_TUNED_COMPUTE_BLOCKCOUNT(block_count, num_phases, split_phase,
340 early_phase_segcount, late_phase_segcount)
341 phase_count = ((phase < split_phase)?
342 (early_phase_segcount) : (late_phase_segcount));
343 phase_offset = ((phase < split_phase)?
344 (phase * early_phase_segcount) :
345 (phase * late_phase_segcount + split_phase));
346 tmprecv = ((char*)rbuf) + (block_offset + phase_offset) * extent;
347 smpi_op_apply(op, inbuf[inbi], tmprecv, &phase_count, &dtype);
350 /* Distribution loop - variation of ring allgather */
351 send_to = (rank + 1) % size;
352 recv_from = (rank + size - 1) % size;
353 for (k = 0; k < size - 1; k++) {
354 const int recv_data_from = (rank + size - k) % size;
355 const int send_data_from = (rank + 1 + size - k) % size;
356 const int send_block_offset =
357 ((send_data_from < split_rank)?
358 (send_data_from * early_blockcount) :
359 (send_data_from * late_blockcount + split_rank));
360 const int recv_block_offset =
361 ((recv_data_from < split_rank)?
362 (recv_data_from * early_blockcount) :
363 (recv_data_from * late_blockcount + split_rank));
364 block_count = ((send_data_from < split_rank)?
365 early_blockcount : late_blockcount);
367 tmprecv = (char*)rbuf + recv_block_offset * extent;
368 tmpsend = (char*)rbuf + send_block_offset * extent;
370 smpi_mpi_sendrecv(tmpsend, block_count, dtype, send_to,
372 tmprecv, early_blockcount, dtype, recv_from,
374 comm, MPI_STATUS_IGNORE);
378 if (NULL != inbuf[0]) smpi_free_tmp_buffer(inbuf[0]);
379 if (NULL != inbuf[1]) smpi_free_tmp_buffer(inbuf[1]);
384 XBT_DEBUG("%s:%4d\tRank %d Error occurred %d\n",
385 __FILE__, line, rank, ret);
386 if (NULL != inbuf[0]) smpi_free_tmp_buffer(inbuf[0]);
387 if (NULL != inbuf[1]) smpi_free_tmp_buffer(inbuf[1]);