/* $OpenBSD: make.c,v 1.82 2020/01/26 12:41:21 espie Exp $ */ /* $NetBSD: make.c,v 1.10 1996/11/06 17:59:15 christos Exp $ */ /* * Copyright (c) 1988, 1989, 1990, 1993 * The Regents of the University of California. All rights reserved. * Copyright (c) 1989 by Berkeley Softworks * All rights reserved. * * This code is derived from software contributed to Berkeley by * Adam de Boor. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /*- * make.c -- * The functions which perform the examination of targets and * their suitability for creation * * Interface: * Make_Run Initialize things for the module and recreate * whatever needs recreating. Returns true if * work was (or would have been) done and * false * otherwise. * * Make_Update Update all parents of a given child. Performs * various bookkeeping chores like finding the * youngest child of the parent, filling * the IMPSRC local variable, etc. It will * place the parent on the to_build queue if it * should be. * */ #include #include #include #include #include #include #include #include #include "config.h" #include "defines.h" #include "dir.h" #include "job.h" #include "suff.h" #include "var.h" #include "error.h" #include "expandchildren.h" #include "make.h" #include "gnode.h" #include "extern.h" #include "timestamp.h" #include "engine.h" #include "lst.h" #include "targ.h" #include "targequiv.h" #include "garray.h" #include "memory.h" /* what gets added each time. Kept as one static array so that it doesn't * get resized every time. */ static struct growableArray examine; /* The current fringe of the graph. These are nodes which await examination by * MakeOODate. It is added to by Make_Update and subtracted from by * MakeStartJobs */ static struct growableArray to_build; /* Hold back on nodes where equivalent stuff is already building... */ static struct growableArray heldBack; static struct ohash targets; /* stuff we must build */ static void MakeAddChild(void *, void *); static void MakeHandleUse(void *, void *); static bool MakeStartJobs(void); static void MakePrintStatus(void *); /* Cycle detection functions */ static bool targets_contain_cycles(void); static void print_unlink_cycle(struct growableArray *, GNode *); static void break_and_print_cycles(Lst); static GNode *find_cycle(Lst, struct growableArray *); static bool try_to_make_node(GNode *); static void add_targets_to_make(Lst); static bool has_predecessor_left_to_build(GNode *); static void requeue_successors(GNode *); static void random_setup(void); static bool randomize_queue; long random_delay = 0; bool nothing_left_to_build() { return Array_IsEmpty(&to_build); } static void random_setup() { randomize_queue = Var_Definedi("RANDOM_ORDER", NULL); /* no random delay in the new engine for now */ #if 0 if (Var_Definedi("RANDOM_DELAY", NULL)) random_delay = strtonum(Var_Value("RANDOM_DELAY"), 0, 1000, NULL) * 1000000; #endif } static void randomize_garray(struct growableArray *g) { /* This is a fairly standard algorithm to randomize an array. */ unsigned int i, v; GNode *e; for (i = g->n; i > 0; i--) { v = arc4random_uniform(i); if (v == i-1) continue; else { e = g->a[i-1]; g->a[i-1] = g->a[v]; g->a[v] = e; } } } static bool has_predecessor_left_to_build(GNode *gn) { LstNode ln; if (Lst_IsEmpty(&gn->predecessors)) return false; for (ln = Lst_First(&gn->predecessors); ln != NULL; ln = Lst_Adv(ln)) { GNode *pgn = Lst_Datum(ln); if (pgn->must_make && pgn->built_status == UNKNOWN) { if (DEBUG(MAKE)) printf("predecessor %s not made yet.\n", pgn->name); return true; } } return false; } static void requeue_successors(GNode *gn) { LstNode ln; /* Deal with successor nodes. If any is marked for making and has an * children_left count of 0, has not been made and isn't in the * examination queue, it means we need to place it in the queue as * it restrained itself before. */ for (ln = Lst_First(&gn->successors); ln != NULL; ln = Lst_Adv(ln)) { GNode *succ = Lst_Datum(ln); if (succ->must_make && succ->children_left == 0 && succ->built_status == UNKNOWN) Array_PushNew(&to_build, succ); } } static void requeue(GNode *gn) { /* this is where we go inside the array and move things around */ unsigned int i, j; for (i = 0, j = 0; i < heldBack.n; i++, j++) { if (heldBack.a[i]->watched == gn) { j--; heldBack.a[i]->built_status = UNKNOWN; if (DEBUG(HELDJOBS)) printf("%s finished, releasing: %s\n", gn->name, heldBack.a[i]->name); Array_Push(&to_build, heldBack.a[i]); continue; } heldBack.a[j] = heldBack.a[i]; } heldBack.n = j; } /*- *----------------------------------------------------------------------- * Make_Update -- * Perform update on the parents of a node. Used by JobFinish once * a node has been dealt with and by MakeStartJobs if it finds an * up-to-date node. * * Results: * Always returns 0 * * Side Effects: * The children_left field of pgn is decremented and pgn may be placed on * the to_build queue if this field becomes 0. * * If the child got built, the parent's child_rebuilt field will be set to * true *----------------------------------------------------------------------- */ void Make_Update(GNode *cgn) /* the child node */ { GNode *pgn; /* the parent node */ LstNode ln; /* Element in parents list */ /* * If the child was actually made, see what its modification time is * now -- some rules won't actually update the file. If the file still * doesn't exist, make its mtime now. */ if (cgn->built_status != UPTODATE) { /* * This is what Make does and it's actually a good thing, as it * allows rules like * * cmp -s y.tab.h parse.h || cp y.tab.h parse.h * * to function as intended. Unfortunately, thanks to the * stateless nature of NFS, there are times when the * modification time of a file created on a remote machine * will not be modified before the local stat() implied by * the Dir_MTime occurs, thus leading us to believe that the * file is unchanged, wreaking havoc with files that depend * on this one. */ if (noExecute || is_out_of_date(Dir_MTime(cgn))) clock_gettime(CLOCK_REALTIME, &cgn->mtime); if (DEBUG(MAKE)) printf("update time: %s\n", time_to_string(&cgn->mtime)); } requeue(cgn); /* SIB: this is where I should mark the build as finished */ for (ln = Lst_First(&cgn->parents); ln != NULL; ln = Lst_Adv(ln)) { pgn = Lst_Datum(ln); /* SIB: there should be a siblings loop there */ pgn->children_left--; if (pgn->must_make) { if (DEBUG(MAKE)) printf("%s--=%d ", pgn->name, pgn->children_left); if ( ! (cgn->type & OP_USE)) { if (cgn->built_status == REBUILT) pgn->child_rebuilt = true; (void)Make_TimeStamp(pgn, cgn); } if (pgn->children_left == 0) { /* * Queue the node up -- any yet-to-build * predecessors will be dealt with in * MakeStartJobs. */ if (DEBUG(MAKE)) printf("QUEUING "); Array_Push(&to_build, pgn); } else if (pgn->children_left < 0) { Error("Child %s discovered graph cycles through %s", cgn->name, pgn->name); } } } if (DEBUG(MAKE)) printf("\n"); requeue_successors(cgn); } static bool try_to_make_node(GNode *gn) { if (DEBUG(MAKE)) printf("Examining %s...", gn->name); if (gn->built_status == HELDBACK) { if (DEBUG(HELDJOBS)) printf("%s already held back ???\n", gn->name); return false; } if (gn->children_left != 0) { if (DEBUG(MAKE)) printf(" Requeuing (%d)\n", gn->children_left); add_targets_to_make(&gn->children); Array_Push(&to_build, gn); return false; } if (has_been_built(gn)) { if (DEBUG(MAKE)) printf(" already made\n"); return false; } if (has_predecessor_left_to_build(gn)) { if (DEBUG(MAKE)) printf(" Dropping for now\n"); return false; } /* SIB: this is where there should be a siblings loop */ if (gn->children_left != 0) { if (DEBUG(MAKE)) printf(" Requeuing (after deps: %d)\n", gn->children_left); add_targets_to_make(&gn->children); return false; } /* this is where we hold back nodes */ if (gn->groupling != NULL) { GNode *gn2; for (gn2 = gn->groupling; gn2 != gn; gn2 = gn2->groupling) if (gn2->built_status == BUILDING) { gn->watched = gn2; gn->built_status = HELDBACK; if (DEBUG(HELDJOBS)) printf("Holding back job %s, " "groupling to %s\n", gn->name, gn2->name); Array_Push(&heldBack, gn); return false; } } if (gn->sibling != gn) { GNode *gn2; for (gn2 = gn->sibling; gn2 != gn; gn2 = gn2->sibling) if (gn2->built_status == BUILDING) { gn->watched = gn2; gn->built_status = HELDBACK; if (DEBUG(HELDJOBS)) printf("Holding back job %s, " "sibling to %s\n", gn->name, gn2->name); Array_Push(&heldBack, gn); return false; } } if (Make_OODate(gn)) { if (DEBUG(MAKE)) printf("out-of-date\n"); if (queryFlag) return true; /* SIB: this is where commands should get prepared */ Make_DoAllVar(gn); if (node_find_valid_commands(gn)) { if (touchFlag) Job_Touch(gn); else Job_Make(gn); } else node_failure(gn); } else { if (DEBUG(MAKE)) printf("up-to-date\n"); gn->built_status = UPTODATE; Make_Update(gn); } return false; } /* *----------------------------------------------------------------------- * MakeStartJobs -- * Start as many jobs as possible. * * Results: * If the query flag was given to pmake, no job will be started, * but as soon as an out-of-date target is found, this function * returns true. At all other times, this function returns false. * * Side Effects: * Nodes are removed from the to_build queue and job table slots * are filled. *----------------------------------------------------------------------- */ static bool MakeStartJobs(void) { GNode *gn; while (can_start_job() && (gn = Array_Pop(&to_build)) != NULL) { if (try_to_make_node(gn)) return true; } return false; } static void MakePrintStatus(void *gnp) { GNode *gn = gnp; if (gn->built_status == UPTODATE) { printf("`%s' is up to date.\n", gn->name); } else if (gn->children_left != 0) { printf("`%s' not remade because of errors.\n", gn->name); } } static void MakeAddChild(void *to_addp, void *ap) { GNode *gn = to_addp; struct growableArray *a = ap; if (!gn->must_make && !(gn->type & OP_USE)) Array_Push(a, gn); } static void MakeHandleUse(void *cgnp, void *pgnp) { GNode *cgn = cgnp; GNode *pgn = pgnp; if (cgn->type & OP_USE) Make_HandleUse(cgn, pgn); } /* Add stuff to the to_build queue. we try to sort things so that stuff * that can be done directly is done right away. This won't be perfect, * since some dependencies are only discovered later (e.g., SuffFindDeps). */ static void add_targets_to_make(Lst todo) { GNode *gn; unsigned int slot; AppendList2Array(todo, &examine); while ((gn = Array_Pop(&examine)) != NULL) { if (gn->must_make) /* already known */ continue; gn->must_make = true; slot = ohash_qlookup(&targets, gn->name); if (!ohash_find(&targets, slot)) ohash_insert(&targets, slot, gn); look_harder_for_target(gn); kludge_look_harder_for_target(gn); /* * Apply any .USE rules before looking for implicit * dependencies to make sure everything that should have * commands has commands ... */ Lst_ForEach(&gn->children, MakeHandleUse, gn); Suff_FindDeps(gn); expand_all_children(gn); if (gn->children_left != 0) { if (DEBUG(MAKE)) printf("%s: not queuing (%d children left to build)\n", gn->name, gn->children_left); Lst_ForEach(&gn->children, MakeAddChild, &examine); } else { if (DEBUG(MAKE)) printf("%s: queuing\n", gn->name); Array_Push(&to_build, gn); } } if (randomize_queue) randomize_garray(&to_build); } void Make_Init() { /* wild guess at initial sizes */ Array_Init(&to_build, 500); Array_Init(&examine, 150); Array_Init(&heldBack, 100); ohash_init(&targets, 10, &gnode_info); } /*- *----------------------------------------------------------------------- * Make_Run -- * Initialize the nodes to remake and the list of nodes which are * ready to be made by doing a breadth-first traversal of the graph * starting from the nodes in the given list. Once this traversal * is finished, all the 'leaves' of the graph are in the to_build * queue. * Using this queue and the Job module, work back up the graph, * calling on MakeStartJobs to keep the job table as full as * possible. * * Side Effects: * The must_make field of all nodes involved in the creation of the given * targets is set to 1. The to_build list is set to contain all the * 'leaves' of these subgraphs. *----------------------------------------------------------------------- */ void Make_Run(Lst targs, bool *has_errors, bool *out_of_date) { if (DEBUG(PARALLEL)) random_setup(); add_targets_to_make(targs); if (queryFlag) { /* * We wouldn't do any work unless we could start some jobs in * the next loop... (we won't actually start any, of course, * this is just to see if any of the targets was out of date) */ if (MakeStartJobs()) *out_of_date = true; } else { /* * Initialization. At the moment, no jobs are running and until * some get started, nothing will happen since the remaining * upward traversal of the graph is performed by the routines * in job.c upon the finishing of a job. So we fill the Job * table as much as we can before going into our loop. */ (void)MakeStartJobs(); } /* * Main Loop: The idea here is that the ending of jobs will take * care of the maintenance of data structures and the waiting for output * will cause us to be idle most of the time while our children run as * much as possible. Because the job table is kept as full as possible, * the only time when it will be empty is when all the jobs which need * running have been run, so that is the end condition of this loop. * Note that the Job module will exit if there were any errors unless * the keepgoing flag was given. */ while (!Job_Empty()) { handle_running_jobs(); (void)MakeStartJobs(); } if (errorJobs != NULL) *has_errors = true; /* * Print the final status of each target. E.g. if it wasn't made * because some inferior reported an error. */ if (targets_contain_cycles()) { break_and_print_cycles(targs); *has_errors = true; } Lst_Every(targs, MakePrintStatus); } /* round-about detection: assume make is bug-free, if there are targets * that have not been touched, it means they never were reached, so we can * look for a cycle */ static bool targets_contain_cycles(void) { GNode *gn; unsigned int i; bool cycle = false; bool first = true; for (gn = ohash_first(&targets, &i); gn != NULL; gn = ohash_next(&targets, &i)) { if (has_been_built(gn)) continue; cycle = true; if (first) printf("Error target(s) unaccounted for: "); printf("%s ", gn->name); first = false; } if (!first) printf("\n"); return cycle; } static void print_unlink_cycle(struct growableArray *l, GNode *c) { LstNode ln; GNode *gn = NULL; unsigned int i; printf("Cycle found: "); for (i = 0; i != l->n; i++) { gn = l->a[i]; if (gn == c) printf("("); printf("%s -> ", gn->name); } printf("%s)\n", c->name); assert(gn); /* So the first element is tied to our node, find and kill the link */ for (ln = Lst_First(&gn->children); ln != NULL; ln = Lst_Adv(ln)) { GNode *gn2 = Lst_Datum(ln); if (gn2 == c) { Lst_Remove(&gn->children, ln); return; } } /* this shouldn't happen ever */ assert(0); } /* each call to find_cycle records a cycle in cycle, to break at node c. * this will stop eventually. */ static void break_and_print_cycles(Lst t) { struct growableArray cycle; Array_Init(&cycle, 16); /* cycles are generally shorter */ while (1) { GNode *c; Array_Reset(&cycle); c = find_cycle(t, &cycle); if (c) print_unlink_cycle(&cycle, c); else break; } free(cycle.a); } static GNode * find_cycle(Lst l, struct growableArray *cycle) { LstNode ln; for (ln = Lst_First(l); ln != NULL; ln = Lst_Adv(ln)) { GNode *gn = Lst_Datum(ln); if (gn->in_cycle) { /* we should print the cycle and not do more */ return gn; } if (gn->built_status == UPTODATE) continue; if (gn->children_left != 0) { GNode *c; gn->in_cycle = true; Array_Push(cycle, gn); c = find_cycle(&gn->children, cycle); gn->in_cycle = false; if (c) return c; Array_Pop(cycle); } } return NULL; }