/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * Given several files containing CTF data, merge and uniquify that data into * a single CTF section in an output file. * * Merges can proceed independently. As such, we perform the merges in parallel * using a worker thread model. A given glob of CTF data (either all of the CTF * data from a single input file, or the result of one or more merges) can only * be involved in a single merge at any given time, so the process decreases in * parallelism, especially towards the end, as more and more files are * consolidated, finally resulting in a single merge of two large CTF graphs. * Unfortunately, the last merge is also the slowest, as the two graphs being * merged are each the product of merges of half of the input files. * * The algorithm consists of two phases, described in detail below. The first * phase entails the merging of CTF data in groups of eight. The second phase * takes the results of Phase I, and merges them two at a time. This disparity * is due to an observation that the merge time increases at least quadratically * with the size of the CTF data being merged. As such, merges of CTF graphs * newly read from input files are much faster than merges of CTF graphs that * are themselves the results of prior merges. * * A further complication is the need to ensure the repeatability of CTF merges. * That is, a merge should produce the same output every time, given the same * input. In both phases, this consistency requirement is met by imposing an * ordering on the merge process, thus ensuring that a given set of input files * are merged in the same order every time. * * Phase I * * The main thread reads the input files one by one, transforming the CTF * data they contain into tdata structures. When a given file has been read * and parsed, it is placed on the work queue for retrieval by worker threads. * * Central to Phase I is the Work In Progress (wip) array, which is used to * merge batches of files in a predictable order. Files are read by the main * thread, and are merged into wip array elements in round-robin order. When * the number of files merged into a given array slot equals the batch size, * the merged CTF graph in that array is added to the done slot in order by * array slot. * * For example, consider a case where we have five input files, a batch size * of two, a wip array size of two, and two worker threads (T1 and T2). * * 1. The wip array elements are assigned initial batch numbers 0 and 1. * 2. T1 reads an input file from the input queue (wq_queue). This is the * first input file, so it is placed into wip[0]. The second file is * similarly read and placed into wip[1]. The wip array slots now contain * one file each (wip_nmerged == 1). * 3. T1 reads the third input file, which it merges into wip[0]. The * number of files in wip[0] is equal to the batch size. * 4. T2 reads the fourth input file, which it merges into wip[1]. wip[1] * is now full too. * 5. T2 attempts to place the contents of wip[1] on the done queue * (wq_done_queue), but it can't, since the batch ID for wip[1] is 1. * Batch 0 needs to be on the done queue before batch 1 can be added, so * T2 blocks on wip[1]'s cv. * 6. T1 attempts to place the contents of wip[0] on the done queue, and * succeeds, updating wq_lastdonebatch to 0. It clears wip[0], and sets * its batch ID to 2. T1 then signals wip[1]'s cv to awaken T2. * 7. T2 wakes up, notices that wq_lastdonebatch is 0, which means that * batch 1 can now be added. It adds wip[1] to the done queue, clears * wip[1], and sets its batch ID to 3. It signals wip[0]'s cv, and * restarts. * * The above process continues until all input files have been consumed. At * this point, a pair of barriers are used to allow a single thread to move * any partial batches from the wip array to the done array in batch ID order. * When this is complete, wq_done_queue is moved to wq_queue, and Phase II * begins. * * Locking Semantics (Phase I) * * The input queue (wq_queue) and the done queue (wq_done_queue) are * protected by separate mutexes - wq_queue_lock and wq_done_queue. wip * array slots are protected by their own mutexes, which must be grabbed * before releasing the input queue lock. The wip array lock is dropped * when the thread restarts the loop. If the array slot was full, the * array lock will be held while the slot contents are added to the done * queue. The done queue lock is used to protect the wip slot cv's. * * The pow number is protected by the queue lock. The master batch ID * and last completed batch (wq_lastdonebatch) counters are protected *in * Phase I* by the done queue lock. * * Phase II * * When Phase II begins, the queue consists of the merged batches from the * first phase. Assume we have five batches: * * Q: a b c d e * * Using the same batch ID mechanism we used in Phase I, but without the wip * array, worker threads remove two entries at a time from the beginning of * the queue. These two entries are merged, and are added back to the tail * of the queue, as follows: * * Q: a b c d e # start * Q: c d e ab # a, b removed, merged, added to end * Q: e ab cd # c, d removed, merged, added to end * Q: cd eab # e, ab removed, merged, added to end * Q: cdeab # cd, eab removed, merged, added to end * * When one entry remains on the queue, with no merges outstanding, Phase II * finishes. We pre-determine the stopping point by pre-calculating the * number of nodes that will appear on the list. In the example above, the * number (wq_ninqueue) is 9. When ninqueue is 1, we conclude Phase II by * signaling the main thread via wq_done_cv. * * Locking Semantics (Phase II) * * The queue (wq_queue), ninqueue, and the master batch ID and last * completed batch counters are protected by wq_queue_lock. The done * queue and corresponding lock are unused in Phase II as is the wip array. * * Uniquification * * We want the CTF data that goes into a given module to be as small as * possible. For example, we don't want it to contain any type data that may * be present in another common module. As such, after creating the master * tdata_t for a given module, we can, if requested by the user, uniquify it * against the tdata_t from another module (genunix in the case of the SunOS * kernel). We perform a merge between the tdata_t for this module and the * tdata_t from genunix. Nodes found in this module that are not present in * genunix are added to a third tdata_t - the uniquified tdata_t. * * Additive Merges * * In some cases, for example if we are issuing a new version of a common * module in a patch, we need to make sure that the CTF data already present * in that module does not change. Changes to this data would void the CTF * data in any module that uniquified against the common module. To preserve * the existing data, we can perform what is known as an additive merge. In * this case, a final uniquification is performed against the CTF data in the * previous version of the module. The result will be the placement of new * and changed data after the existing data, thus preserving the existing type * ID space. * * Saving the result * * When the merges are complete, the resulting tdata_t is placed into the * output file, replacing the .SUNW_ctf section (if any) already in that file. * * The person who changes the merging thread code in this file without updating * this comment will not live to see the stock hit five. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ctf_headers.h" #include "ctftools.h" #include "ctfmerge.h" #include "traverse.h" #include "memory.h" #include "fifo.h" #include "barrier.h" #pragma init(bigheap) #define MERGE_PHASE1_BATCH_SIZE 8 #define MERGE_PHASE1_MAX_SLOTS 5 #define MERGE_INPUT_THROTTLE_LEN 10 const char *progname; static char *outfile = NULL; static char *tmpname = NULL; static int dynsym; int debug_level = DEBUG_LEVEL; static size_t maxpgsize = 0x400000; void usage(void) { (void) fprintf(stderr, "Usage: %s [-fstv] -l label | -L labelenv -o outfile file ...\n" " %s [-fstv] -l label | -L labelenv -o outfile -d uniqfile\n" " %*s [-D uniqlabel] file ...\n" " %s [-fstv] -l label | -L labelenv -o outfile -w withfile " "file ...\n" " %s -c srcfile destfile\n" "\n" " Note: if -L labelenv is specified and labelenv is not set in\n" " the environment, a default value is used.\n", progname, progname, strlen(progname), " ", progname, progname); } static void bigheap(void) { size_t big, *size; int sizes; struct memcntl_mha mha; /* * First, get the available pagesizes. */ if ((sizes = getpagesizes(NULL, 0)) == -1) return; if (sizes == 1 || (size = alloca(sizeof (size_t) * sizes)) == NULL) return; if (getpagesizes(size, sizes) == -1) return; while (size[sizes - 1] > maxpgsize) sizes--; /* set big to the largest allowed page size */ big = size[sizes - 1]; if (big & (big - 1)) { /* * The largest page size is not a power of two for some * inexplicable reason; return. */ return; } /* * Now, align our break to the largest page size. */ if (brk((void *)((((uintptr_t)sbrk(0) - 1) & ~(big - 1)) + big)) != 0) return; /* * set the preferred page size for the heap */ mha.mha_cmd = MHA_MAPSIZE_BSSBRK; mha.mha_flags = 0; mha.mha_pagesize = big; (void) memcntl(NULL, 0, MC_HAT_ADVISE, (caddr_t)&mha, 0, 0); } static void finalize_phase_one(workqueue_t *wq) { int startslot, i; /* * wip slots are cleared out only when maxbatchsz td's have been merged * into them. We're not guaranteed that the number of files we're * merging is a multiple of maxbatchsz, so there will be some partial * groups in the wip array. Move them to the done queue in batch ID * order, starting with the slot containing the next batch that would * have been placed on the done queue, followed by the others. * One thread will be doing this while the others wait at the barrier * back in worker_thread(), so we don't need to worry about pesky things * like locks. */ for (startslot = -1, i = 0; i < wq->wq_nwipslots; i++) { if (wq->wq_wip[i].wip_batchid == wq->wq_lastdonebatch + 1) { startslot = i; break; } } assert(startslot != -1); for (i = startslot; i < startslot + wq->wq_nwipslots; i++) { int slotnum = i % wq->wq_nwipslots; wip_t *wipslot = &wq->wq_wip[slotnum]; if (wipslot->wip_td != NULL) { debug(2, "clearing slot %d (%d) (saving %d)\n", slotnum, i, wipslot->wip_nmerged); } else debug(2, "clearing slot %d (%d)\n", slotnum, i); if (wipslot->wip_td != NULL) { fifo_add(wq->wq_donequeue, wipslot->wip_td); wq->wq_wip[slotnum].wip_td = NULL; } } wq->wq_lastdonebatch = wq->wq_next_batchid++; debug(2, "phase one done: donequeue has %d items\n", fifo_len(wq->wq_donequeue)); } static void init_phase_two(workqueue_t *wq) { int num; /* * We're going to continually merge the first two entries on the queue, * placing the result on the end, until there's nothing left to merge. * At that point, everything will have been merged into one. The * initial value of ninqueue needs to be equal to the total number of * entries that will show up on the queue, both at the start of the * phase and as generated by merges during the phase. */ wq->wq_ninqueue = num = fifo_len(wq->wq_donequeue); while (num != 1) { wq->wq_ninqueue += num / 2; num = num / 2 + num % 2; } /* * Move the done queue to the work queue. We won't be using the done * queue in phase 2. */ assert(fifo_len(wq->wq_queue) == 0); fifo_free(wq->wq_queue, NULL); wq->wq_queue = wq->wq_donequeue; } static void wip_save_work(workqueue_t *wq, wip_t *slot, int slotnum) { pthread_mutex_lock(&wq->wq_donequeue_lock); while (wq->wq_lastdonebatch + 1 < slot->wip_batchid) pthread_cond_wait(&slot->wip_cv, &wq->wq_donequeue_lock); assert(wq->wq_lastdonebatch + 1 == slot->wip_batchid); fifo_add(wq->wq_donequeue, slot->wip_td); wq->wq_lastdonebatch++; pthread_cond_signal(&wq->wq_wip[(slotnum + 1) % wq->wq_nwipslots].wip_cv); /* reset the slot for next use */ slot->wip_td = NULL; slot->wip_batchid = wq->wq_next_batchid++; pthread_mutex_unlock(&wq->wq_donequeue_lock); } static void wip_add_work(wip_t *slot, tdata_t *pow) { if (slot->wip_td == NULL) { slot->wip_td = pow; slot->wip_nmerged = 1; } else { debug(2, "%d: merging %p into %p\n", pthread_self(), (void *)pow, (void *)slot->wip_td); merge_into_master(pow, slot->wip_td, NULL, 0); tdata_free(pow); slot->wip_nmerged++; } } static void worker_runphase1(workqueue_t *wq) { wip_t *wipslot; tdata_t *pow; int wipslotnum, pownum; for (;;) { pthread_mutex_lock(&wq->wq_queue_lock); while (fifo_empty(wq->wq_queue)) { if (wq->wq_nomorefiles == 1) { pthread_cond_broadcast(&wq->wq_work_avail); pthread_mutex_unlock(&wq->wq_queue_lock); /* on to phase 2 ... */ return; } pthread_cond_wait(&wq->wq_work_avail, &wq->wq_queue_lock); } /* there's work to be done! */ pow = fifo_remove(wq->wq_queue); pownum = wq->wq_nextpownum++; pthread_cond_broadcast(&wq->wq_work_removed); assert(pow != NULL); /* merge it into the right slot */ wipslotnum = pownum % wq->wq_nwipslots; wipslot = &wq->wq_wip[wipslotnum]; pthread_mutex_lock(&wipslot->wip_lock); pthread_mutex_unlock(&wq->wq_queue_lock); wip_add_work(wipslot, pow); if (wipslot->wip_nmerged == wq->wq_maxbatchsz) wip_save_work(wq, wipslot, wipslotnum); pthread_mutex_unlock(&wipslot->wip_lock); } } static void worker_runphase2(workqueue_t *wq) { tdata_t *pow1, *pow2; int batchid; for (;;) { pthread_mutex_lock(&wq->wq_queue_lock); if (wq->wq_ninqueue == 1) { pthread_cond_broadcast(&wq->wq_work_avail); pthread_mutex_unlock(&wq->wq_queue_lock); debug(2, "%d: entering p2 completion barrier\n", pthread_self()); if (barrier_wait(&wq->wq_bar1)) { pthread_mutex_lock(&wq->wq_queue_lock); wq->wq_alldone = 1; pthread_cond_signal(&wq->wq_alldone_cv); pthread_mutex_unlock(&wq->wq_queue_lock); } return; } if (fifo_len(wq->wq_queue) < 2) { pthread_cond_wait(&wq->wq_work_avail, &wq->wq_queue_lock); pthread_mutex_unlock(&wq->wq_queue_lock); continue; } /* there's work to be done! */ pow1 = fifo_remove(wq->wq_queue); pow2 = fifo_remove(wq->wq_queue); wq->wq_ninqueue -= 2; batchid = wq->wq_next_batchid++; pthread_mutex_unlock(&wq->wq_queue_lock); debug(2, "%d: merging %p into %p\n", pthread_self(), (void *)pow1, (void *)pow2); merge_into_master(pow1, pow2, NULL, 0); tdata_free(pow1); /* * merging is complete. place at the tail of the queue in * proper order. */ pthread_mutex_lock(&wq->wq_queue_lock); while (wq->wq_lastdonebatch + 1 != batchid) { pthread_cond_wait(&wq->wq_done_cv, &wq->wq_queue_lock); } wq->wq_lastdonebatch = batchid; fifo_add(wq->wq_queue, pow2); debug(2, "%d: added %p to queue, len now %d, ninqueue %d\n", pthread_self(), (void *)pow2, fifo_len(wq->wq_queue), wq->wq_ninqueue); pthread_cond_broadcast(&wq->wq_done_cv); pthread_cond_signal(&wq->wq_work_avail); pthread_mutex_unlock(&wq->wq_queue_lock); } } /* * Main loop for worker threads. */ static void worker_thread(workqueue_t *wq) { worker_runphase1(wq); debug(2, "%d: entering first barrier\n", pthread_self()); if (barrier_wait(&wq->wq_bar1)) { debug(2, "%d: doing work in first barrier\n", pthread_self()); finalize_phase_one(wq); init_phase_two(wq); debug(2, "%d: ninqueue is %d, %d on queue\n", pthread_self(), wq->wq_ninqueue, fifo_len(wq->wq_queue)); } debug(2, "%d: entering second barrier\n", pthread_self()); (void) barrier_wait(&wq->wq_bar2); debug(2, "%d: phase 1 complete\n", pthread_self()); worker_runphase2(wq); } /* * Pass a tdata_t tree, built from an input file, off to the work queue for * consumption by worker threads. */ static int merge_ctf_cb(tdata_t *td, char *name, void *arg) { workqueue_t *wq = arg; debug(3, "Adding tdata %p for processing\n", (void *)td); pthread_mutex_lock(&wq->wq_queue_lock); while (fifo_len(wq->wq_queue) > wq->wq_ithrottle) { debug(2, "Throttling input (len = %d, throttle = %d)\n", fifo_len(wq->wq_queue), wq->wq_ithrottle); pthread_cond_wait(&wq->wq_work_removed, &wq->wq_queue_lock); } fifo_add(wq->wq_queue, td); debug(1, "Thread %d announcing %s\n", pthread_self(), name); pthread_cond_broadcast(&wq->wq_work_avail); pthread_mutex_unlock(&wq->wq_queue_lock); return (1); } /* * This program is intended to be invoked from a Makefile, as part of the build. * As such, in the event of a failure or user-initiated interrupt (^C), we need * to ensure that a subsequent re-make will cause ctfmerge to be executed again. * Unfortunately, ctfmerge will usually be invoked directly after (and as part * of the same Makefile rule as) a link, and will operate on the linked file * in place. If we merely exit upon receipt of a SIGINT, a subsequent make * will notice that the *linked* file is newer than the object files, and thus * will not reinvoke ctfmerge. The only way to ensure that a subsequent make * reinvokes ctfmerge, is to remove the file to which we are adding CTF * data (confusingly named the output file). This means that the link will need * to happen again, but links are generally fast, and we can't allow the merge * to be skipped. * * Another possibility would be to block SIGINT entirely - to always run to * completion. The run time of ctfmerge can, however, be measured in minutes * in some cases, so this is not a valid option. */ static void handle_sig(int sig) { terminate("Caught signal %d - exiting\n", sig); } static void terminate_cleanup(void) { int dounlink = getenv("CTFMERGE_TERMINATE_NO_UNLINK") ? 0 : 1; if (tmpname != NULL && dounlink) unlink(tmpname); if (outfile == NULL) return; if (dounlink) { fprintf(stderr, "Removing %s\n", outfile); unlink(outfile); } } static void copy_ctf_data(char *srcfile, char *destfile) { tdata_t *srctd; if (read_ctf(&srcfile, 1, NULL, read_ctf_save_cb, &srctd, 1) == 0) terminate("No CTF data found in source file %s\n", srcfile); tmpname = mktmpname(destfile, ".ctf"); write_ctf(srctd, destfile, tmpname, CTF_COMPRESS); if (rename(tmpname, destfile) != 0) { terminate("Couldn't rename temp file %s to %s", tmpname, destfile); } free(tmpname); tdata_free(srctd); } static void wq_init(workqueue_t *wq, int nfiles) { int throttle, nslots, i; if (getenv("CTFMERGE_MAX_SLOTS")) nslots = atoi(getenv("CTFMERGE_MAX_SLOTS")); else nslots = MERGE_PHASE1_MAX_SLOTS; if (getenv("CTFMERGE_PHASE1_BATCH_SIZE")) wq->wq_maxbatchsz = atoi(getenv("CTFMERGE_PHASE1_BATCH_SIZE")); else wq->wq_maxbatchsz = MERGE_PHASE1_BATCH_SIZE; nslots = MIN(nslots, (nfiles + wq->wq_maxbatchsz - 1) / wq->wq_maxbatchsz); wq->wq_wip = xcalloc(sizeof (wip_t) * nslots); wq->wq_nwipslots = nslots; wq->wq_nthreads = MIN(sysconf(_SC_NPROCESSORS_ONLN) * 3 / 2, nslots); wq->wq_thread = xmalloc(sizeof (pthread_t) * wq->wq_nthreads); if (getenv("CTFMERGE_INPUT_THROTTLE")) throttle = atoi(getenv("CTFMERGE_INPUT_THROTTLE")); else throttle = MERGE_INPUT_THROTTLE_LEN; wq->wq_ithrottle = throttle * wq->wq_nthreads; debug(1, "Using %d slots, %d threads\n", wq->wq_nwipslots, wq->wq_nthreads); wq->wq_next_batchid = 0; for (i = 0; i < nslots; i++) { pthread_mutex_init(&wq->wq_wip[i].wip_lock, NULL); wq->wq_wip[i].wip_batchid = wq->wq_next_batchid++; } pthread_mutex_init(&wq->wq_queue_lock, NULL); wq->wq_queue = fifo_new(); pthread_cond_init(&wq->wq_work_avail, NULL); pthread_cond_init(&wq->wq_work_removed, NULL); wq->wq_ninqueue = nfiles; wq->wq_nextpownum = 0; pthread_mutex_init(&wq->wq_donequeue_lock, NULL); wq->wq_donequeue = fifo_new(); wq->wq_lastdonebatch = -1; pthread_cond_init(&wq->wq_done_cv, NULL); pthread_cond_init(&wq->wq_alldone_cv, NULL); wq->wq_alldone = 0; barrier_init(&wq->wq_bar1, wq->wq_nthreads); barrier_init(&wq->wq_bar2, wq->wq_nthreads); wq->wq_nomorefiles = 0; } static void start_threads(workqueue_t *wq) { sigset_t sets; int i; sigemptyset(&sets); sigaddset(&sets, SIGINT); sigaddset(&sets, SIGQUIT); sigaddset(&sets, SIGTERM); pthread_sigmask(SIG_BLOCK, &sets, NULL); for (i = 0; i < wq->wq_nthreads; i++) { pthread_create(&wq->wq_thread[i], NULL, (void *(*)(void *))worker_thread, wq); } sigset(SIGINT, handle_sig); sigset(SIGQUIT, handle_sig); sigset(SIGTERM, handle_sig); pthread_sigmask(SIG_UNBLOCK, &sets, NULL); } static void join_threads(workqueue_t *wq) { int i; for (i = 0; i < wq->wq_nthreads; i++) { pthread_join(wq->wq_thread[i], NULL); } } static int strcompare(const void *p1, const void *p2) { char *s1 = *((char **)p1); char *s2 = *((char **)p2); return (strcmp(s1, s2)); } /* * Core work queue structure; passed to worker threads on thread creation * as the main point of coordination. Allocate as a static structure; we * could have put this into a local variable in main, but passing a pointer * into your stack to another thread is fragile at best and leads to some * hard-to-debug failure modes. */ static workqueue_t wq; int main(int argc, char **argv) { tdata_t *mstrtd, *savetd; char *uniqfile = NULL, *uniqlabel = NULL; char *withfile = NULL; char *label = NULL; char **ifiles, **tifiles; int verbose = 0, docopy = 0; int write_fuzzy_match = 0; int require_ctf = 0; int nifiles, nielems; int c, i, idx, tidx, err; progname = basename(argv[0]); ctf_altexec("CTFMERGE_ALTEXEC", argc, argv); if (getenv("CTFMERGE_DEBUG_LEVEL")) debug_level = atoi(getenv("CTFMERGE_DEBUG_LEVEL")); err = 0; while ((c = getopt(argc, argv, ":cd:D:fl:L:o:tvw:s")) != EOF) { switch (c) { case 'c': docopy = 1; break; case 'd': /* Uniquify against `uniqfile' */ uniqfile = optarg; break; case 'D': /* Uniquify against label `uniqlabel' in `uniqfile' */ uniqlabel = optarg; break; case 'f': write_fuzzy_match = CTF_FUZZY_MATCH; break; case 'l': /* Label merged types with `label' */ label = optarg; break; case 'L': /* Label merged types with getenv(`label`) */ if ((label = getenv(optarg)) == NULL) label = CTF_DEFAULT_LABEL; break; case 'o': /* Place merged types in CTF section in `outfile' */ outfile = optarg; break; case 't': /* Insist *all* object files built from C have CTF */ require_ctf = 1; break; case 'v': /* More debugging information */ verbose = 1; break; case 'w': /* Additive merge with data from `withfile' */ withfile = optarg; break; case 's': /* use the dynsym rather than the symtab */ dynsym = CTF_USE_DYNSYM; break; default: usage(); exit(2); } } /* Validate arguments */ if (docopy) { if (uniqfile != NULL || uniqlabel != NULL || label != NULL || outfile != NULL || withfile != NULL || dynsym != 0) err++; if (argc - optind != 2) err++; } else { if (uniqfile != NULL && withfile != NULL) err++; if (uniqlabel != NULL && uniqfile == NULL) err++; if (outfile == NULL || label == NULL) err++; if (argc - optind == 0) err++; } if (err) { usage(); exit(2); } if (uniqfile && access(uniqfile, R_OK) != 0) { warning("Uniquification file %s couldn't be opened and " "will be ignored.\n", uniqfile); uniqfile = NULL; } if (withfile && access(withfile, R_OK) != 0) { warning("With file %s couldn't be opened and will be " "ignored.\n", withfile); withfile = NULL; } if (outfile && access(outfile, R_OK|W_OK) != 0) terminate("Cannot open output file %s for r/w", outfile); /* * This is ugly, but we don't want to have to have a separate tool * (yet) just for copying an ELF section with our specific requirements, * so we shoe-horn a copier into ctfmerge. */ if (docopy) { copy_ctf_data(argv[optind], argv[optind + 1]); exit(0); } set_terminate_cleanup(terminate_cleanup); /* Sort the input files and strip out duplicates */ nifiles = argc - optind; ifiles = xmalloc(sizeof (char *) * nifiles); tifiles = xmalloc(sizeof (char *) * nifiles); for (i = 0; i < nifiles; i++) tifiles[i] = argv[optind + i]; qsort(tifiles, nifiles, sizeof (char *), (int (*)())strcompare); ifiles[0] = tifiles[0]; for (idx = 0, tidx = 1; tidx < nifiles; tidx++) { if (strcmp(ifiles[idx], tifiles[tidx]) != 0) ifiles[++idx] = tifiles[tidx]; } nifiles = idx + 1; /* Make sure they all exist */ if ((nielems = count_files(ifiles, nifiles)) < 0) terminate("Some input files were inaccessible\n"); /* Prepare for the merge */ wq_init(&wq, nielems); start_threads(&wq); /* * Start the merge * * We're reading everything from each of the object files, so we * don't need to specify labels. */ if (read_ctf(ifiles, nifiles, NULL, merge_ctf_cb, &wq, require_ctf) == 0) { /* * If we're verifying that C files have CTF, it's safe to * assume that in this case, we're building only from assembly * inputs. */ if (require_ctf) exit(0); terminate("No ctf sections found to merge\n"); } pthread_mutex_lock(&wq.wq_queue_lock); wq.wq_nomorefiles = 1; pthread_cond_broadcast(&wq.wq_work_avail); pthread_mutex_unlock(&wq.wq_queue_lock); pthread_mutex_lock(&wq.wq_queue_lock); while (wq.wq_alldone == 0) pthread_cond_wait(&wq.wq_alldone_cv, &wq.wq_queue_lock); pthread_mutex_unlock(&wq.wq_queue_lock); join_threads(&wq); /* * All requested files have been merged, with the resulting tree in * mstrtd. savetd is the tree that will be placed into the output file. * * Regardless of whether we're doing a normal uniquification or an * additive merge, we need a type tree that has been uniquified * against uniqfile or withfile, as appropriate. * * If we're doing a uniquification, we stuff the resulting tree into * outfile. Otherwise, we add the tree to the tree already in withfile. */ assert(fifo_len(wq.wq_queue) == 1); mstrtd = fifo_remove(wq.wq_queue); if (verbose || debug_level) { debug(2, "Statistics for td %p\n", (void *)mstrtd); iidesc_stats(mstrtd->td_iihash); } if (uniqfile != NULL || withfile != NULL) { char *reffile, *reflabel = NULL; tdata_t *reftd; if (uniqfile != NULL) { reffile = uniqfile; reflabel = uniqlabel; } else reffile = withfile; if (read_ctf(&reffile, 1, reflabel, read_ctf_save_cb, &reftd, require_ctf) == 0) { terminate("No CTF data found in reference file %s\n", reffile); } savetd = tdata_new(); if (CTF_TYPE_ISCHILD(reftd->td_nextid)) terminate("No room for additional types in master\n"); savetd->td_nextid = withfile ? reftd->td_nextid : CTF_INDEX_TO_TYPE(1, TRUE); merge_into_master(mstrtd, reftd, savetd, 0); tdata_label_add(savetd, label, CTF_LABEL_LASTIDX); if (withfile) { /* * savetd holds the new data to be added to the withfile */ tdata_t *withtd = reftd; tdata_merge(withtd, savetd); savetd = withtd; } else { char uniqname[MAXPATHLEN]; labelent_t *parle; parle = tdata_label_top(reftd); savetd->td_parlabel = xstrdup(parle->le_name); strncpy(uniqname, reffile, sizeof (uniqname)); uniqname[MAXPATHLEN - 1] = '\0'; savetd->td_parname = xstrdup(basename(uniqname)); } } else { /* * No post processing. Write the merged tree as-is into the * output file. */ tdata_label_free(mstrtd); tdata_label_add(mstrtd, label, CTF_LABEL_LASTIDX); savetd = mstrtd; } tmpname = mktmpname(outfile, ".ctf"); write_ctf(savetd, outfile, tmpname, CTF_COMPRESS | write_fuzzy_match | dynsym); if (rename(tmpname, outfile) != 0) terminate("Couldn't rename output temp file %s", tmpname); free(tmpname); return (0); }