/* * %CopyrightBegin% * * Copyright Ericsson AB 2000-2011. All Rights Reserved. * * The contents of this file are subject to the Erlang Public License, * Version 1.1, (the "License"); you may not use this file except in * compliance with the License. You should have received a copy of the * Erlang Public License along with this software. If not, it can be * retrieved online at http://www.erlang.org/. * * Software distributed under the License is distributed on an "AS IS" * basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See * the License for the specific language governing rights and limitations * under the License. * * %CopyrightEnd% */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include "sys.h" #include "erl_vm.h" #include "global.h" #include "erl_process.h" #include "beam_load.h" #include "bif.h" #include "error.h" #include "erl_binary.h" #include "beam_bp.h" #include "erl_term.h" /* ************************************************************************* ** Macros */ /* ** Memory allocation macros */ /* Breakpoint data */ #define Alloc(SZ) erts_alloc(ERTS_ALC_T_BPD, (SZ)) #define ReAlloc(P, SIZ) erts_realloc(ERTS_ALC_T_BPD, (P), (SZ)) #define Free(P) erts_free(ERTS_ALC_T_BPD, (P)) /* ** Doubly linked ring macros */ #define BpInit(a,i) \ do { \ (a)->orig_instr = (i); \ (a)->next = (a); \ (a)->prev = (a); \ } while (0) #define BpSpliceNext(a,b) \ do { \ register BpData *c = (a), *d = (b), *e; \ e = c->next->prev; \ c->next->prev = d->next->prev; \ d->next->prev = e; \ e = c->next; \ c->next = d->next; \ d->next = e; \ } while (0) #define BpSplicePrev(a,b) \ do { \ register BpData *c = (a), *d = (b), *e; \ e = c->prev->next; \ c->prev->next = d->prev->next; \ d->prev->next = e; \ e = c->prev; \ c->prev = d->prev; \ d->prev = e; \ } while (0) #ifdef DEBUG # define BpSingleton(a) ((a)->next == (a) && (a)->prev == (a)) #else # define BpSingleton(a) ((a)->next == (a)) #endif #define BpInitAndSpliceNext(a,i,b) \ do { \ (a)->orig_instr = (i); \ (a)->prev = (b); \ (b)->next->prev = (a); \ (a)->next = (b)->next; \ (b)->next = (a); \ } while (0) #define BpInitAndSplicePrev(a,i,b) \ do { \ (a)->orig_instr = (i); \ (a)->next = (b); \ (b)->prev->next = (a); \ (a)->prev = (b)->prev; \ (b)->prev = (a); \ } while (0) #define BREAK_IS_BIF (1) #define BREAK_IS_ERL (0) /* ************************************************************************* ** Local prototypes */ /* ** Helpers */ static int set_break(Eterm mfa[3], int specified, Binary *match_spec, BeamInstr break_op, enum erts_break_op count_op, Eterm tracer_pid); static int set_module_break(Module *modp, Eterm mfa[3], int specified, Binary *match_spec, BeamInstr break_op, enum erts_break_op count_op, Eterm tracer_pid); static int set_function_break(Module *modp, BeamInstr *pc, int bif, Binary *match_spec, BeamInstr break_op, enum erts_break_op count_op, Eterm tracer_pid); static int clear_break(Eterm mfa[3], int specified, BeamInstr break_op); static int clear_module_break(Module *modp, Eterm mfa[3], int specified, BeamInstr break_op); static int clear_function_break(Module *modp, BeamInstr *pc, int bif, BeamInstr break_op); static BpData *is_break(BeamInstr *pc, BeamInstr break_op); static BpData *get_break(Process *p, BeamInstr *pc, BeamInstr break_op); /* bp_hash */ #define BP_TIME_ADD(pi0, pi1) \ do { \ Uint r; \ (pi0)->count += (pi1)->count; \ (pi0)->s_time += (pi1)->s_time; \ (pi0)->us_time += (pi1)->us_time; \ r = (pi0)->us_time / 1000000; \ (pi0)->s_time += r; \ (pi0)->us_time = (pi0)->us_time % 1000000; \ } while(0) static void bp_hash_init(bp_time_hash_t *hash, Uint n); static void bp_hash_rehash(bp_time_hash_t *hash, Uint n); static ERTS_INLINE bp_data_time_item_t * bp_hash_get(bp_time_hash_t *hash, bp_data_time_item_t *sitem); static ERTS_INLINE bp_data_time_item_t * bp_hash_put(bp_time_hash_t *hash, bp_data_time_item_t *sitem); static void bp_hash_delete(bp_time_hash_t *hash); /* ************************************************************************* ** External interfaces */ erts_smp_spinlock_t erts_bp_lock; void erts_bp_init(void) { erts_smp_spinlock_init(&erts_bp_lock, "breakpoints"); } int erts_set_trace_break(Eterm mfa[3], int specified, Binary *match_spec, Eterm tracer_pid) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return set_break(mfa, specified, match_spec, (BeamInstr) BeamOp(op_i_trace_breakpoint), 0, tracer_pid); } int erts_set_mtrace_break(Eterm mfa[3], int specified, Binary *match_spec, Eterm tracer_pid) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return set_break(mfa, specified, match_spec, (BeamInstr) BeamOp(op_i_mtrace_breakpoint), 0, tracer_pid); } /* set breakpoint data for on exported bif entry */ void erts_set_mtrace_bif(BeamInstr *pc, Binary *match_spec, Eterm tracer_pid) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); set_function_break(NULL, pc, BREAK_IS_BIF, match_spec, (BeamInstr) BeamOp(op_i_mtrace_breakpoint), 0, tracer_pid); } void erts_set_time_trace_bif(BeamInstr *pc, enum erts_break_op count_op) { set_function_break(NULL, pc, BREAK_IS_BIF, NULL, (BeamInstr) BeamOp(op_i_time_breakpoint), count_op, NIL); } void erts_clear_time_trace_bif(BeamInstr *pc) { clear_function_break(NULL, pc, BREAK_IS_BIF, (BeamInstr) BeamOp(op_i_time_breakpoint)); } int erts_set_debug_break(Eterm mfa[3], int specified) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return set_break(mfa, specified, NULL, (BeamInstr) BeamOp(op_i_debug_breakpoint), 0, NIL); } int erts_set_count_break(Eterm mfa[3], int specified, enum erts_break_op count_op) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return set_break(mfa, specified, NULL, (BeamInstr) BeamOp(op_i_count_breakpoint), count_op, NIL); } int erts_set_time_break(Eterm mfa[3], int specified, enum erts_break_op count_op) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return set_break(mfa, specified, NULL, (BeamInstr) BeamOp(op_i_time_breakpoint), count_op, NIL); } int erts_clear_trace_break(Eterm mfa[3], int specified) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return clear_break(mfa, specified, (BeamInstr) BeamOp(op_i_trace_breakpoint)); } int erts_clear_mtrace_break(Eterm mfa[3], int specified) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return clear_break(mfa, specified, (BeamInstr) BeamOp(op_i_mtrace_breakpoint)); } void erts_clear_mtrace_bif(BeamInstr *pc) { clear_function_break(NULL, pc, BREAK_IS_BIF, (BeamInstr) BeamOp(op_i_mtrace_breakpoint)); } int erts_clear_debug_break(Eterm mfa[3], int specified) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return clear_break(mfa, specified, (BeamInstr) BeamOp(op_i_debug_breakpoint)); } int erts_clear_count_break(Eterm mfa[3], int specified) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return clear_break(mfa, specified, (BeamInstr) BeamOp(op_i_count_breakpoint)); } int erts_clear_time_break(Eterm mfa[3], int specified) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return clear_break(mfa, specified, (BeamInstr) BeamOp(op_i_time_breakpoint)); } int erts_clear_break(Eterm mfa[3], int specified) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); return clear_break(mfa, specified, 0); } int erts_clear_module_break(Module *modp) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); ASSERT(modp); return clear_module_break(modp, NULL, 0, 0); } int erts_clear_function_break(Module *modp, BeamInstr *pc) { ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); ASSERT(modp); return clear_function_break(modp, pc, BREAK_IS_ERL, 0); } /* * SMP NOTE: Process p may have become exiting on return! */ BeamInstr erts_trace_break(Process *p, BeamInstr *pc, Eterm *args, Uint32 *ret_flags, Eterm *tracer_pid) { Eterm tpid1, tpid2; BpData **bds = (BpData **) (pc)[-4]; BpDataTrace *bdt = NULL; ASSERT(bds); ASSERT(pc[-5] == (BeamInstr) BeamOp(op_i_func_info_IaaI)); bdt = (BpDataTrace *) bds[bp_sched2ix_proc(p)]; ASSERT(bdt); bdt = (BpDataTrace *) bdt->next; ASSERT(bdt); ASSERT(ret_flags); ASSERT(tracer_pid); ErtsSmpBPLock(bdt); tpid1 = tpid2 = bdt->tracer_pid; ErtsSmpBPUnlock(bdt); *ret_flags = erts_call_trace(p, pc-3/*mfa*/, bdt->match_spec, args, 1, &tpid2); *tracer_pid = tpid2; if (tpid1 != tpid2) { ErtsSmpBPLock(bdt); bdt->tracer_pid = tpid2; ErtsSmpBPUnlock(bdt); } bds[bp_sched2ix_proc(p)] = (BpData *) bdt; return bdt->orig_instr; } /* * SMP NOTE: Process p may have become exiting on return! */ Uint32 erts_bif_mtrace(Process *p, BeamInstr *pc, Eterm *args, int local, Eterm *tracer_pid) { BpData **bds = (BpData **) (pc)[-4]; BpDataTrace *bdt = NULL; ASSERT(tracer_pid); if (bds) { Eterm tpid1, tpid2; Uint32 flags; bdt = (BpDataTrace *)bds[bp_sched2ix_proc(p)]; ErtsSmpBPLock(bdt); tpid1 = tpid2 = bdt->tracer_pid; ErtsSmpBPUnlock(bdt); flags = erts_call_trace(p, pc-3/*mfa*/, bdt->match_spec, args, local, &tpid2); *tracer_pid = tpid2; if (tpid1 != tpid2) { ErtsSmpBPLock(bdt); bdt->tracer_pid = tpid2; ErtsSmpBPUnlock(bdt); } return flags; } *tracer_pid = NIL; return 0; } int erts_is_trace_break(BeamInstr *pc, Binary **match_spec_ret, Eterm *tracer_pid_ret) { BpDataTrace *bdt = (BpDataTrace *) is_break(pc, (BeamInstr) BeamOp(op_i_trace_breakpoint)); if (bdt) { if (match_spec_ret) { *match_spec_ret = bdt->match_spec; } if (tracer_pid_ret) { ErtsSmpBPLock(bdt); *tracer_pid_ret = bdt->tracer_pid; ErtsSmpBPUnlock(bdt); } return !0; } return 0; } int erts_is_mtrace_break(BeamInstr *pc, Binary **match_spec_ret, Eterm *tracer_pid_ret) { BpDataTrace *bdt = (BpDataTrace *) is_break(pc, (BeamInstr) BeamOp(op_i_mtrace_breakpoint)); if (bdt) { if (match_spec_ret) { *match_spec_ret = bdt->match_spec; } if (tracer_pid_ret) { ErtsSmpBPLock(bdt); *tracer_pid_ret = bdt->tracer_pid; ErtsSmpBPUnlock(bdt); } return !0; } return 0; } int erts_is_native_break(BeamInstr *pc) { #ifdef HIPE ASSERT(pc[-5] == (BeamInstr) BeamOp(op_i_func_info_IaaI)); return pc[0] == (BeamInstr) BeamOp(op_hipe_trap_call) || pc[0] == (BeamInstr) BeamOp(op_hipe_trap_call_closure); #else return 0; #endif } int erts_is_count_break(BeamInstr *pc, Sint *count_ret) { BpDataCount *bdc = (BpDataCount *) is_break(pc, (BeamInstr) BeamOp(op_i_count_breakpoint)); if (bdc) { if (count_ret) { *count_ret = (Sint) erts_smp_atomic_read_nob(&bdc->acount); } return !0; } return 0; } int erts_is_time_break(Process *p, BeamInstr *pc, Eterm *retval) { Uint i, ix; bp_time_hash_t hash; Uint size; Eterm *hp, t; bp_data_time_item_t *item = NULL; BpDataTime *bdt = (BpDataTime *) is_break(pc, (BeamInstr) BeamOp(op_i_time_breakpoint)); if (bdt) { if (retval) { /* collect all hashes to one hash */ bp_hash_init(&hash, 64); /* foreach threadspecific hash */ for (i = 0; i < bdt->n; i++) { bp_data_time_item_t *sitem; /* foreach hash bucket not NIL*/ for(ix = 0; ix < bdt->hash[i].n; ix++) { item = &(bdt->hash[i].item[ix]); if (item->pid != NIL) { sitem = bp_hash_get(&hash, item); if (sitem) { BP_TIME_ADD(sitem, item); } else { bp_hash_put(&hash, item); } } } } /* *retval should be NIL or term from previous bif in export entry */ if (hash.used > 0) { size = (5 + 2)*hash.used; hp = HAlloc(p, size); for(ix = 0; ix < hash.n; ix++) { item = &(hash.item[ix]); if (item->pid != NIL) { t = TUPLE4(hp, item->pid, make_small(item->count), make_small(item->s_time), make_small(item->us_time)); hp += 5; *retval = CONS(hp, t, *retval); hp += 2; } } } bp_hash_delete(&hash); } return !0; } return 0; } BeamInstr * erts_find_local_func(Eterm mfa[3]) { Module *modp; BeamInstr** code_base; BeamInstr* code_ptr; Uint i,n; if ((modp = erts_get_module(mfa[0])) == NULL) return NULL; if ((code_base = (BeamInstr **) modp->code) == NULL) return NULL; n = (BeamInstr) code_base[MI_NUM_FUNCTIONS]; for (i = 0; i < n; ++i) { code_ptr = code_base[MI_FUNCTIONS+i]; ASSERT(((BeamInstr) BeamOp(op_i_func_info_IaaI)) == code_ptr[0]); ASSERT(mfa[0] == ((Eterm) code_ptr[2])); if (mfa[1] == ((Eterm) code_ptr[3]) && ((BeamInstr) mfa[2]) == code_ptr[4]) { return code_ptr + 5; } } return NULL; } /* bp_hash */ ERTS_INLINE Uint bp_sched2ix() { #ifdef ERTS_SMP ErtsSchedulerData *esdp; esdp = erts_get_scheduler_data(); return esdp->no - 1; #else return 0; #endif } static void bp_hash_init(bp_time_hash_t *hash, Uint n) { Uint size = sizeof(bp_data_time_item_t)*n; Uint i; hash->n = n; hash->used = 0; hash->item = (bp_data_time_item_t *)Alloc(size); sys_memzero(hash->item, size); for(i = 0; i < n; ++i) { hash->item[i].pid = NIL; } } static void bp_hash_rehash(bp_time_hash_t *hash, Uint n) { bp_data_time_item_t *item = NULL; Uint size = sizeof(bp_data_time_item_t)*n; Uint ix; Uint hval; item = (bp_data_time_item_t *)Alloc(size); sys_memzero(item, size); for( ix = 0; ix < n; ++ix) { item[ix].pid = NIL; } /* rehash, old hash -> new hash */ for( ix = 0; ix < hash->n; ix++) { if (hash->item[ix].pid != NIL) { hval = ((hash->item[ix].pid) >> 4) % n; /* new n */ while (item[hval].pid != NIL) { hval = (hval + 1) % n; } item[hval].pid = hash->item[ix].pid; item[hval].count = hash->item[ix].count; item[hval].s_time = hash->item[ix].s_time; item[hval].us_time = hash->item[ix].us_time; } } Free(hash->item); hash->n = n; hash->item = item; } static ERTS_INLINE bp_data_time_item_t * bp_hash_get(bp_time_hash_t *hash, bp_data_time_item_t *sitem) { Eterm pid = sitem->pid; Uint hval = (pid >> 4) % hash->n; bp_data_time_item_t *item = NULL; item = hash->item; while (item[hval].pid != pid) { if (item[hval].pid == NIL) return NULL; hval = (hval + 1) % hash->n; } return &(item[hval]); } static ERTS_INLINE bp_data_time_item_t * bp_hash_put(bp_time_hash_t *hash, bp_data_time_item_t* sitem) { Uint hval; float r = 0.0; bp_data_time_item_t *item; /* make sure that the hash is not saturated */ /* if saturated, rehash it */ r = hash->used / (float) hash->n; if (r > 0.7f) { bp_hash_rehash(hash, hash->n * 2); } /* Do hval after rehash */ hval = (sitem->pid >> 4) % hash->n; /* find free slot */ item = hash->item; while (item[hval].pid != NIL) { hval = (hval + 1) % hash->n; } item = &(hash->item[hval]); item->pid = sitem->pid; item->s_time = sitem->s_time; item->us_time = sitem->us_time; item->count = sitem->count; hash->used++; return item; } static void bp_hash_delete(bp_time_hash_t *hash) { hash->n = 0; hash->used = 0; Free(hash->item); hash->item = NULL; } static void bp_time_diff(bp_data_time_item_t *item, /* out */ process_breakpoint_time_t *pbt, /* in */ Uint ms, Uint s, Uint us) { int dms,ds,dus; dms = ms - pbt->ms; ds = s - pbt->s; dus = us - pbt->us; /* get_sys_now may return zero difftime, * this is ok. */ ASSERT(dms >= 0 || ds >= 0 || dus >= 0); if (dus < 0) { dus += 1000000; ds -= 1; } if (ds < 0) { ds += 1000000; } item->s_time = ds; item->us_time = dus; } void erts_schedule_time_break(Process *p, Uint schedule) { Uint ms, s, us; process_breakpoint_time_t *pbt = NULL; bp_data_time_item_t sitem, *item = NULL; bp_time_hash_t *h = NULL; BpDataTime *pbdt = NULL; ASSERT(p); pbt = ERTS_PROC_GET_CALL_TIME(p); if (pbt) { switch(schedule) { case ERTS_BP_CALL_TIME_SCHEDULE_EXITING : break; case ERTS_BP_CALL_TIME_SCHEDULE_OUT : /* When a process is scheduled _out_, * timestamp it and add its delta to * the previous breakpoint. */ pbdt = (BpDataTime *) get_break(p, pbt->pc, (BeamInstr) BeamOp(op_i_time_breakpoint)); if (pbdt) { get_sys_now(&ms,&s,&us); bp_time_diff(&sitem, pbt, ms, s, us); sitem.pid = p->id; sitem.count = 0; h = &(pbdt->hash[bp_sched2ix_proc(p)]); ASSERT(h); ASSERT(h->item); item = bp_hash_get(h, &sitem); if (!item) { item = bp_hash_put(h, &sitem); } else { BP_TIME_ADD(item, &sitem); } } break; case ERTS_BP_CALL_TIME_SCHEDULE_IN : /* When a process is scheduled _in_, * timestamp it and remove the previous * timestamp in the psd. */ get_sys_now(&ms,&s,&us); pbt->ms = ms; pbt->s = s; pbt->us = us; break; default : ASSERT(0); /* will never happen */ break; } } /* pbt */ } /* call_time breakpoint * Accumulated times are added to the previous bp, * not the current one. The current one is saved * for future reference. * The previous breakpoint is stored in the process it self, the psd. * We do not need to store in a stack frame. * There is no need for locking, each thread has its own * area in each bp to save data. * Since we need to diffrentiate between processes for each bp, * every bp has a hash (per thread) to process-bp statistics. * - egil */ void erts_trace_time_break(Process *p, BeamInstr *pc, BpDataTime *bdt, Uint type) { Uint ms,s,us; process_breakpoint_time_t *pbt = NULL; bp_data_time_item_t sitem, *item = NULL; bp_time_hash_t *h = NULL; BpDataTime *pbdt = NULL; ASSERT(p); ASSERT(p->status == P_RUNNING); /* get previous timestamp and breakpoint * from the process psd */ pbt = ERTS_PROC_GET_CALL_TIME(p); get_sys_now(&ms,&s,&us); switch(type) { /* get pbt * timestamp = t0 * lookup bdt from code * set ts0 to pbt * add call count here? */ case ERTS_BP_CALL_TIME_CALL: case ERTS_BP_CALL_TIME_TAIL_CALL: if (pbt) { ASSERT(pbt->pc); /* add time to previous code */ bp_time_diff(&sitem, pbt, ms, s, us); sitem.pid = p->id; sitem.count = 0; /* previous breakpoint */ pbdt = (BpDataTime *) get_break(p, pbt->pc, (BeamInstr) BeamOp(op_i_time_breakpoint)); /* if null then the breakpoint was removed */ if (pbdt) { h = &(pbdt->hash[bp_sched2ix_proc(p)]); ASSERT(h); ASSERT(h->item); item = bp_hash_get(h, &sitem); if (!item) { item = bp_hash_put(h, &sitem); } else { BP_TIME_ADD(item, &sitem); } } } else { /* first call of process to instrumented function */ pbt = Alloc(sizeof(process_breakpoint_time_t)); (void *) ERTS_PROC_SET_CALL_TIME(p, ERTS_PROC_LOCK_MAIN, pbt); } /* add count to this code */ sitem.pid = p->id; sitem.count = 1; sitem.s_time = 0; sitem.us_time = 0; /* this breakpoint */ ASSERT(bdt); h = &(bdt->hash[bp_sched2ix_proc(p)]); ASSERT(h); ASSERT(h->item); item = bp_hash_get(h, &sitem); if (!item) { item = bp_hash_put(h, &sitem); } else { BP_TIME_ADD(item, &sitem); } pbt->pc = pc; pbt->ms = ms; pbt->s = s; pbt->us = us; break; case ERTS_BP_CALL_TIME_RETURN: /* get pbt * lookup bdt from code * timestamp = t1 * get ts0 from pbt * get item from bdt->hash[bp_hash(p->id)] * ack diff (t1, t0) to item */ if(pbt) { /* might have been removed due to * trace_pattern(false) */ ASSERT(pbt->pc); bp_time_diff(&sitem, pbt, ms, s, us); sitem.pid = p->id; sitem.count = 0; /* previous breakpoint */ pbdt = (BpDataTime *) get_break(p, pbt->pc, (BeamInstr) BeamOp(op_i_time_breakpoint)); /* beware, the trace_pattern might have been removed */ if (pbdt) { h = &(pbdt->hash[bp_sched2ix_proc(p)]); ASSERT(h); ASSERT(h->item); item = bp_hash_get(h, &sitem); if (!item) { item = bp_hash_put(h, &sitem); } else { BP_TIME_ADD(item, &sitem); } } pbt->pc = pc; pbt->ms = ms; pbt->s = s; pbt->us = us; } break; default : ASSERT(0); /* will never happen */ break; } } /* ************************************************************************* ** Local helpers */ static int set_break(Eterm mfa[3], int specified, Binary *match_spec, BeamInstr break_op, enum erts_break_op count_op, Eterm tracer_pid) { Module *modp; int num_processed = 0; if (!specified) { /* Find and process all modules in the system... */ int current; int last = module_code_size(); for (current = 0; current < last; current++) { modp = module_code(current); ASSERT(modp != NULL); num_processed += set_module_break(modp, mfa, specified, match_spec, break_op, count_op, tracer_pid); } } else { /* Process a single module */ if ((modp = erts_get_module(mfa[0])) != NULL) { num_processed += set_module_break(modp, mfa, specified, match_spec, break_op, count_op, tracer_pid); } } return num_processed; } static int set_module_break(Module *modp, Eterm mfa[3], int specified, Binary *match_spec, BeamInstr break_op, enum erts_break_op count_op, Eterm tracer_pid) { BeamInstr** code_base; BeamInstr* code_ptr; int num_processed = 0; Uint i,n; ASSERT(break_op); ASSERT(modp); code_base = (BeamInstr **) modp->code; if (code_base == NULL) { return 0; } n = (BeamInstr) code_base[MI_NUM_FUNCTIONS]; for (i = 0; i < n; ++i) { code_ptr = code_base[MI_FUNCTIONS+i]; ASSERT(code_ptr[0] == (BeamInstr) BeamOp(op_i_func_info_IaaI)); if ((specified < 2 || mfa[1] == ((Eterm) code_ptr[3])) && (specified < 3 || ((int) mfa[2]) == ((int) code_ptr[4]))) { BeamInstr *pc = code_ptr+5; num_processed += set_function_break(modp, pc, BREAK_IS_ERL, match_spec, break_op, count_op, tracer_pid); } } return num_processed; } static int set_function_break(Module *modp, BeamInstr *pc, int bif, Binary *match_spec, BeamInstr break_op, enum erts_break_op count_op, Eterm tracer_pid) { BeamInstr **code_base = NULL; BpData *bd, **r, ***rs; size_t size; Uint ix = 0; if (bif == BREAK_IS_ERL) { code_base = (BeamInstr **)modp->code; ASSERT(code_base); ASSERT(code_base <= (BeamInstr **)pc); ASSERT((BeamInstr **)pc < code_base + (modp->code_length/sizeof(BeamInstr *))); } else { ASSERT(*pc == (BeamInstr) em_apply_bif); ASSERT(modp == NULL); } /* * Currently no trace support for native code. */ if (erts_is_native_break(pc)) { return 0; } /* Do not allow two breakpoints of the same kind */ if ( (bd = is_break(pc, break_op))) { if (break_op == (BeamInstr) BeamOp(op_i_trace_breakpoint) || break_op == (BeamInstr) BeamOp(op_i_mtrace_breakpoint)) { BpDataTrace *bdt = (BpDataTrace *) bd; Binary *old_match_spec; /* Update match spec and tracer */ MatchSetRef(match_spec); ErtsSmpBPLock(bdt); old_match_spec = bdt->match_spec; bdt->match_spec = match_spec; bdt->tracer_pid = tracer_pid; ErtsSmpBPUnlock(bdt); MatchSetUnref(old_match_spec); } else { BpDataCount *bdc = (BpDataCount *) bd; erts_aint_t count = 0; erts_aint_t res = 0; ASSERT(! match_spec); ASSERT(is_nil(tracer_pid)); if (break_op == (BeamInstr) BeamOp(op_i_count_breakpoint)) { if (count_op == erts_break_stop) { count = erts_smp_atomic_read_nob(&bdc->acount); if (count >= 0) { while(1) { res = erts_smp_atomic_cmpxchg_nob(&bdc->acount, -count - 1, count); if ((res == count) || count < 0) break; count = res; } } } else { /* Reset call counter */ erts_smp_atomic_set_nob(&bdc->acount, 0); } } else if (break_op == (BeamInstr) BeamOp(op_i_time_breakpoint)) { BpDataTime *bdt = (BpDataTime *) bd; Uint i = 0; ERTS_SMP_LC_ASSERT(erts_smp_is_system_blocked(0)); if (count_op == erts_break_stop) { bdt->pause = 1; } else { bdt->pause = 0; for (i = 0; i < bdt->n; i++) { bp_hash_delete(&(bdt->hash[i])); bp_hash_init(&(bdt->hash[i]), 32); } } } else { ASSERT (! count_op); } } return 1; } if (break_op == (BeamInstr) BeamOp(op_i_trace_breakpoint) || break_op == (BeamInstr) BeamOp(op_i_mtrace_breakpoint)) { size = sizeof(BpDataTrace); } else { ASSERT(! match_spec); ASSERT(is_nil(tracer_pid)); if (break_op == (BeamInstr) BeamOp(op_i_count_breakpoint)) { if (count_op == erts_break_reset || count_op == erts_break_stop) { /* Do not insert a new breakpoint */ return 1; } size = sizeof(BpDataCount); } else if (break_op == (BeamInstr) BeamOp(op_i_time_breakpoint)) { if (count_op == erts_break_reset || count_op == erts_break_stop) { /* Do not insert a new breakpoint */ return 1; } size = sizeof(BpDataTime); } else { ASSERT(! count_op); ASSERT(break_op == (BeamInstr) BeamOp(op_i_debug_breakpoint)); size = sizeof(BpDataDebug); } } rs = (BpData ***) (pc-4); if (! *rs) { size_t ssize = sizeof(BeamInstr) * erts_no_schedulers; *rs = (BpData **) Alloc(ssize); sys_memzero(*rs, ssize); } r = &((*rs)[0]); if (! *r) { ASSERT(*pc != (BeamInstr) BeamOp(op_i_trace_breakpoint)); ASSERT(*pc != (BeamInstr) BeamOp(op_i_mtrace_breakpoint)); ASSERT(*pc != (BeamInstr) BeamOp(op_i_debug_breakpoint)); ASSERT(*pc != (BeamInstr) BeamOp(op_i_count_breakpoint)); ASSERT(*pc != (BeamInstr) BeamOp(op_i_time_breakpoint)); /* First breakpoint; create singleton ring */ bd = Alloc(size); BpInit(bd, *pc); *r = bd; if (bif == BREAK_IS_ERL) { *pc = break_op; } } else { ASSERT(*pc == (BeamInstr) BeamOp(op_i_trace_breakpoint) || *pc == (BeamInstr) BeamOp(op_i_mtrace_breakpoint) || *pc == (BeamInstr) BeamOp(op_i_debug_breakpoint) || *pc == (BeamInstr) BeamOp(op_i_time_breakpoint) || *pc == (BeamInstr) BeamOp(op_i_count_breakpoint) || *pc == (BeamInstr) em_apply_bif); if (*pc == (BeamInstr) BeamOp(op_i_debug_breakpoint)) { /* Debug bp must be last, so if it is also first; * it must be singleton. */ ASSERT(BpSingleton(*r)); /* Insert new bp first in the ring, i.e second to last. */ bd = Alloc(size); BpInitAndSpliceNext(bd, *pc, *r); if (bif == BREAK_IS_ERL) { *pc = break_op; } } else if ((*r)->prev->orig_instr == (BeamInstr) BeamOp(op_i_debug_breakpoint)) { /* Debug bp last in the ring; insert new second to last. */ bd = Alloc(size); BpInitAndSplicePrev(bd, (*r)->prev->orig_instr, *r); (*r)->prev->orig_instr = break_op; } else { /* Just insert last in the ring */ bd = Alloc(size); BpInitAndSpliceNext(bd, (*r)->orig_instr, *r); (*r)->orig_instr = break_op; *r = bd; } } for (ix = 1; ix < erts_no_schedulers; ++ix) { (*rs)[ix] = (*rs)[0]; } bd->this_instr = break_op; /* Init the bp type specific data */ if (break_op == (BeamInstr) BeamOp(op_i_trace_breakpoint) || break_op == (BeamInstr) BeamOp(op_i_mtrace_breakpoint)) { BpDataTrace *bdt = (BpDataTrace *) bd; MatchSetRef(match_spec); bdt->match_spec = match_spec; bdt->tracer_pid = tracer_pid; } else if (break_op == (BeamInstr) BeamOp(op_i_time_breakpoint)) { BpDataTime *bdt = (BpDataTime *) bd; Uint i = 0; bdt->pause = 0; bdt->n = erts_no_schedulers; bdt->hash = Alloc(sizeof(bp_time_hash_t)*(bdt->n)); for (i = 0; i < bdt->n; i++) { bp_hash_init(&(bdt->hash[i]), 32); } } else if (break_op == (BeamInstr) BeamOp(op_i_count_breakpoint)) { BpDataCount *bdc = (BpDataCount *) bd; erts_smp_atomic_init_nob(&bdc->acount, 0); } if (bif == BREAK_IS_ERL) { ++(*(BeamInstr*)&code_base[MI_NUM_BREAKPOINTS]); } return 1; } static int clear_break(Eterm mfa[3], int specified, BeamInstr break_op) { int num_processed = 0; Module *modp; if (!specified) { /* Iterate over all modules */ int current; int last = module_code_size(); for (current = 0; current < last; current++) { modp = module_code(current); ASSERT(modp != NULL); num_processed += clear_module_break(modp, mfa, specified, break_op); } } else { /* Process a single module */ if ((modp = erts_get_module(mfa[0])) != NULL) { num_processed += clear_module_break(modp, mfa, specified, break_op); } } return num_processed; } static int clear_module_break(Module *m, Eterm mfa[3], int specified, BeamInstr break_op) { BeamInstr** code_base; BeamInstr* code_ptr; int num_processed = 0; Uint i; BeamInstr n; ASSERT(m); code_base = (BeamInstr **) m->code; if (code_base == NULL) { return 0; } n = (BeamInstr) code_base[MI_NUM_FUNCTIONS]; for (i = 0; i < n; ++i) { code_ptr = code_base[MI_FUNCTIONS+i]; if ((specified < 2 || mfa[1] == ((Eterm) code_ptr[3])) && (specified < 3 || ((int) mfa[2]) == ((int) code_ptr[4]))) { BeamInstr *pc = code_ptr + 5; num_processed += clear_function_break(m, pc, BREAK_IS_ERL, break_op); } } return num_processed; } static int clear_function_break(Module *m, BeamInstr *pc, int bif, BeamInstr break_op) { BpData *bd; Uint ix = 0; BeamInstr **code_base = NULL; if (bif == BREAK_IS_ERL) { code_base = (BeamInstr **)m->code; ASSERT(code_base); ASSERT(code_base <= (BeamInstr **)pc); ASSERT((BeamInstr **)pc < code_base + (m->code_length/sizeof(BeamInstr *))); } else { ASSERT(*pc == (BeamInstr) em_apply_bif); ASSERT(m == NULL); } /* * Currently no trace support for native code. */ if (erts_is_native_break(pc)) { return 0; } while ( (bd = is_break(pc, break_op))) { /* Remove all breakpoints of this type. * There should be only one of each type, * but break_op may be 0 which matches any type. */ BeamInstr op; BpData ***rs = (BpData ***) (pc - 4); BpData **r = NULL; #ifdef DEBUG for (ix = 1; ix < erts_no_schedulers; ++ix) { ASSERT((*rs)[ix] == (*rs)[0]); } #endif r = &((*rs)[0]); ASSERT(*r); /* Find opcode for this breakpoint */ if (break_op) { op = break_op; } else { if (bd == (*r)->next) { /* First breakpoint in ring */ op = *pc; } else { op = bd->prev->orig_instr; } } if (BpSingleton(bd)) { ASSERT(*r == bd); /* Only one breakpoint to remove */ if (bif == BREAK_IS_ERL) { *pc = bd->orig_instr; } Free(*rs); *rs = NULL; } else { BpData *bd_prev = bd->prev; BpSpliceNext(bd, bd_prev); ASSERT(BpSingleton(bd)); if (bd == *r) { /* We removed the last breakpoint in the ring */ *r = bd_prev; bd_prev->orig_instr = bd->orig_instr; } else if (bd_prev == *r) { /* We removed the first breakpoint in the ring */ if (bif == BREAK_IS_ERL) { *pc = bd->orig_instr; } } else { bd_prev->orig_instr = bd->orig_instr; } } if (op == (BeamInstr) BeamOp(op_i_trace_breakpoint) || op == (BeamInstr) BeamOp(op_i_mtrace_breakpoint)) { BpDataTrace *bdt = (BpDataTrace *) bd; MatchSetUnref(bdt->match_spec); } if (op == (BeamInstr) BeamOp(op_i_time_breakpoint)) { BpDataTime *bdt = (BpDataTime *) bd; Uint i = 0; Uint j = 0; Process *h_p = NULL; bp_data_time_item_t *item = NULL; process_breakpoint_time_t *pbt = NULL; /* remove all psd associated with the hash * and then delete the hash. * ... sigh ... */ for( i = 0; i < bdt->n; ++i) { if (bdt->hash[i].used) { for (j = 0; j < bdt->hash[i].n; ++j) { item = &(bdt->hash[i].item[j]); if (item->pid != NIL) { h_p = process_tab[internal_pid_index(item->pid)]; if (h_p) { pbt = ERTS_PROC_SET_CALL_TIME(h_p, ERTS_PROC_LOCK_MAIN, NULL); if (pbt) { Free(pbt); } } } } } bp_hash_delete(&(bdt->hash[i])); } Free(bdt->hash); bdt->hash = NULL; bdt->n = 0; } Free(bd); if (bif == BREAK_IS_ERL) { ASSERT(((BeamInstr) code_base[MI_NUM_BREAKPOINTS]) > 0); --(*(BeamInstr*)&code_base[MI_NUM_BREAKPOINTS]); } if (*rs) { for (ix = 1; ix < erts_no_schedulers; ++ix) { (*rs)[ix] = (*rs)[0]; } } } /* while bd != NULL */ return 1; } /* ** Searches (linear forward) the breakpoint ring for a specified opcode ** and returns a pointer to the breakpoint data structure or NULL if ** not found. If the specified opcode is 0, the last breakpoint is ** returned. The program counter must point to the first executable ** (breakpoint) instruction of the function. */ BpData *erts_get_time_break(Process *p, BeamInstr *pc) { return get_break(p, pc, (BeamInstr) BeamOp(op_i_time_breakpoint)); } static BpData *get_break(Process *p, BeamInstr *pc, BeamInstr break_op) { ASSERT(pc[-5] == (BeamInstr) BeamOp(op_i_func_info_IaaI)); if (! erts_is_native_break(pc)) { BpData **rs = (BpData **) pc[-4]; BpData *bd = NULL, *ebd = NULL; if (! rs) { return NULL; } bd = ebd = rs[bp_sched2ix_proc(p)]; ASSERT(bd); if (bd->this_instr == break_op) { return bd; } bd = bd->next; while (bd != ebd) { ASSERT(bd); if (bd->this_instr == break_op) { ASSERT(bd); return bd; } bd = bd->next; } } return NULL; } static BpData *is_break(BeamInstr *pc, BeamInstr break_op) { BpData **rs = (BpData **) pc[-4]; BpData *bd = NULL, *ebd = NULL; ASSERT(pc[-5] == (BeamInstr) BeamOp(op_i_func_info_IaaI)); if (! rs) { return NULL; } bd = ebd = rs[bp_sched2ix()]; ASSERT(bd); if ( (break_op == 0) || (bd->this_instr == break_op)) { return bd; } bd = bd->next; while (bd != ebd) { ASSERT(bd); if (bd->this_instr == break_op) { ASSERT(bd); return bd; } bd = bd->next; } return NULL; }