ref: 41d4cecf6d55af3ee0ced4c45d34450f4501608b
dir: /sys/src/cmd/dtracy/act.c/
#include <u.h> #include <libc.h> #include <ctype.h> #include <dtracy.h> #include <bio.h> #include "dat.h" #include "fns.h" /* this contains the code to prepare the kernel data structures and to parse records */ Clause *clause; Clause **clauses; int nclauses; /* we could just rely on the types in the expression tree but i'm paranoid */ typedef struct Val Val; struct Val { enum { VALINT, VALSTR, } type; union { vlong v; char *s; }; }; Val mkval(int type, ...) { Val r; va_list va; r.type = type; va_start(va, type); switch(type){ case VALINT: r.v = va_arg(va, uvlong); break; case VALSTR: r.s = va_arg(va, char*); break; } va_end(va); return r; } static char * insertstars(char *n) { Fmt f; int partlen; fmtstrinit(&f); partlen = 0; for(; *n != 0; n++){ if(*n == ':'){ if(partlen == 0) fmtrune(&f, '*'); partlen = 0; }else partlen++; fmtrune(&f, *n); } if(partlen == 0) fmtrune(&f, '*'); return fmtstrflush(&f); } void clausebegin(void) { clause = emalloc(sizeof(Clause)); clause->id = nclauses; } void addprobe(char *s) { clause->probs = erealloc(clause->probs, sizeof(char *) * (clause->nprob + 1)); clause->probs[clause->nprob++] = insertstars(s); } static char *aggtypes[] = { [AGGCNT] "count", [AGGMIN] "min", [AGGMAX] "max", [AGGSUM] "sum", [AGGAVG] "avg", [AGGSTD] "std", }; int aggtype(Symbol *s) { int i; for(i = 0; i < nelem(aggtypes); i++) if(strcmp(s->name, aggtypes[i]) == 0) return i; error("%s unknown aggregation type", s->name); return 0; } void addstat(int type, ...) { Stat *s; va_list va; clause->stats = erealloc(clause->stats, sizeof(Stat) * (clause->nstats + 1)); s = &clause->stats[clause->nstats++]; memset(s, 0, sizeof(Stat)); s->type = type; va_start(va, type); switch(type){ case STATEXPR: s->n = va_arg(va, Node *); break; case STATPRINT: case STATPRINTF: break; case STATAGG: s->agg.name = va_arg(va, Symbol *); s->agg.key = va_arg(va, Node *); s->agg.type = aggtype(va_arg(va, Symbol *)); s->agg.value = va_arg(va, Node *); if(s->agg.type == AGGCNT){ if(s->agg.value != nil) error("too many arguments for count()"); }else{ if(s->agg.value == nil) error("need argument for %s()", aggtypes[s->agg.type]); } break; default: sysfatal("addstat: unknown type %d", type); } va_end(va); } void addarg(Node *n) { Stat *s; assert(clause->nstats > 0); s = &clause->stats[clause->nstats - 1]; s->arg = erealloc(s->arg, sizeof(Node *) * (s->narg + 1)); s->arg[s->narg++] = n; } void clauseend(void) { clauses = erealloc(clauses, sizeof(Clause) * (nclauses + 1)); clauses[nclauses++] = clause; } void actgradd(DTActGr *a, DTAct b) { a->acts = erealloc(a->acts, sizeof(DTAct) * (a->nact + 1)); a->acts[a->nact++] = b; } void addpred(DTExpr *e) { clause->pred = e; } static void prepprintf(Node **arg, int narg, DTActGr *g, int *recoff) { char *fmt; int n; Fmt f; if(narg <= 0) sysfatal("printf() needs an argument"); if((*arg)->type != OSTR) sysfatal("printf() format string must be a literal"); fmt = (*arg)->str; fmtstrinit(&f); n = 1; for(; *fmt != 0; fmt++){ fmtrune(&f, *fmt); if(*fmt != '%') continue; fmt++; again: switch(*fmt){ case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': case 'u': case '+': case '-': case ',': case '#': case ' ': case '.': fmtrune(&f, *fmt); fmt++; goto again; case 'x': case 'X': case 'o': case 'b': case 'd': if(n >= narg) sysfatal("printf() too few arguments"); if(arg[n]->typ->type != TYPINT) sysfatal("print() %%%c with non-integer", *fmt); arg[n] = tracegen(arg[n], g, recoff); n++; fmtrune(&f, 'l'); fmtrune(&f, 'l'); fmtrune(&f, *fmt); break; case 's': if(n >= narg) sysfatal("printf() too few arguments"); if(arg[n]->typ->type != TYPSTRING) sysfatal("print() %%s with non-string"); arg[n] = tracegen(arg[n], g, recoff); n++; fmtrune(&f, *fmt); break; case 0: sysfatal("printf() missing verb"); default: sysfatal("printf() unknown verb %%%c", *fmt); } } if(n < narg) sysfatal("printf() too many arguments"); (*arg)->str = fmtstrflush(&f); } int aggid; int allagg(Clause *c) { Stat *s; for(s = c->stats; s < c->stats + c->nstats; s++) if(s->type != STATAGG) return 0; return 1; } DTClause * mkdtclause(Clause *c) { DTClause *d; Stat *s; int recoff, i; Node *n; d = emalloc(sizeof(DTClause)); d->nprob = c->nprob; d->probs = c->probs; d->gr = emalloc(sizeof(DTActGr)); d->gr->pred = c->pred; d->gr->id = c->id; recoff = 12; for(s = c->stats; s < c->stats + c->nstats; s++) switch(s->type){ case STATEXPR: actgradd(d->gr, (DTAct){ACTTRACE, codegen(s->n), 0, noagg}); break; case STATPRINT: for(i = 0; i < s->narg; i++) s->arg[i] = tracegen(s->arg[i], d->gr, &recoff); break; case STATPRINTF: prepprintf(s->arg, s->narg, d->gr, &recoff); break; case STATAGG: { DTAgg agg = {.id = s->agg.type << 28 | 1 << 16 | aggid++}; assert(dtaunpackid(&agg) >= 0); aggs = realloc(aggs, sizeof(Agg) * aggid); memset(&aggs[aggid-1], 0, sizeof(Agg)); aggs[aggid-1].DTAgg = agg; aggs[aggid-1].name = strdup(s->agg.name == nil ? "" : s->agg.name->name); actgradd(d->gr, (DTAct){ACTAGGKEY, codegen(s->agg.key), 8, agg}); n = s->agg.value; if(n == nil) n = node(ONUM, 0ULL); actgradd(d->gr, (DTAct){ACTAGGVAL, codegen(n), 8, agg}); break; } } if(allagg(c)) actgradd(d->gr, (DTAct){ACTCANCEL, codegen(node(ONUM, 0)), 0, noagg}); return d; } void packclauses(Fmt *f) { int i; DTClause *d; for(i = 0; i < nclauses; i++){ d = mkdtclause(clauses[i]); dtclpack(f, d); } } /* epid lookup table, filled with info from the kernel */ Enab *enabtab[1024]; void addepid(u32int epid, u32int cid, int reclen, char *p) { Enab *e, **ep; assert(cid < nclauses); assert((uint)reclen >= 12); e = emalloc(sizeof(Enab)); e->epid = epid; e->cl = clauses[cid]; e->reclen = reclen; e->probe = strdup(p); ep = &enabtab[epid % nelem(enabtab)]; e->next = *ep; *ep = e; } Enab * epidlookup(u32int epid) { Enab *e; for(e = enabtab[epid % nelem(enabtab)]; e != nil; e = e->next) if(e->epid == epid) return e; return nil; } uchar * unpack(uchar *p, uchar *e, char *fmt, ...) { va_list va; u64int vl; va_start(va, fmt); for(;;) switch(*fmt++){ case 'c': if(p + 1 > e) return nil; *va_arg(va, u8int *) = p[0]; p += 1; break; case 's': if(p + 2 > e) return nil; *va_arg(va, u16int *) = p[0] | p[1] << 8; p += 2; break; case 'i': if(p + 4 > e) return nil; *va_arg(va, u32int *) = p[0] | p[1] << 8 | p[2] << 16 | p[3] << 24; p += 4; break; case 'v': if(p + 8 > e) return nil; vl = p[0] | p[1] << 8 | p[2] << 16 | p[3] << 24; vl |= (uvlong)p[4] << 32 | (uvlong)p[5] << 40 | (uvlong)p[6] << 48 | (uvlong)p[7] << 56; *va_arg(va, u64int *) = vl; p += 8; break; case 0: return p; default: abort(); } } static Val receval(Node *n, uchar *p, uchar *e, Enab *en) { u8int c; u16int s; u32int i; uvlong v; char *sp; uchar *q; Val a, b; switch(n->type){ case OSYM: switch(n->sym->type){ case SYMVAR: switch(n->sym->idx){ case DTV_TIME: q = unpack(p + 4, e, "v", &v); assert(q != nil); return mkval(VALINT, v); case DTV_PROBE: return mkval(VALSTR, en->probe); default: sysfatal("receval: unknown variable %d", n->type); return mkval(VALINT, 0LL); } break; default: sysfatal("receval: unknown symbol type %d", n->type); return mkval(VALINT, 0LL); } case ONUM: return mkval(VALINT, n->num); case OBIN: a = receval(n->n1, p, e, en); b = receval(n->n2, p, e, en); assert(a.type == VALINT); assert(b.type == VALINT); return mkval(VALINT, evalop(n->op, n->typ->sign, a.v, b.v)); case OLNOT: a = receval(n->n1, p, e, en); assert(a.type == VALINT); return mkval(VALINT, (uvlong) !a.v); case OTERN: a = receval(n->n1, p, e, en); assert(a.type == VALINT); return a.v ? receval(n->n2, p, e, en) : receval(n->n3, p, e, en); case ORECORD: switch(n->typ->type){ case TYPINT: switch(n->typ->size){ case 1: q = unpack(p + n->num, e, "c", &c); v = n->typ->sign ? (s8int)c : (u8int)c; break; case 2: q = unpack(p + n->num, e, "s", &s); v = n->typ->sign ? (s16int)s : (u16int)s; break; case 4: q = unpack(p + n->num, e, "i", &i); v = n->typ->sign ? (s32int)i : (u32int)i; break; case 8: q = unpack(p + n->num, e, "v", &v); break; default: q = nil; } assert(q != nil); return mkval(VALINT, v); case TYPSTRING: assert(p + n->num + n->typ->size <= e); sp = emalloc(n->typ->size + 1); memcpy(sp, p + n->num, n->typ->size); return mkval(VALSTR, sp); /* TODO: fix leak */ default: sysfatal("receval: don't know how to parse record for %τ", n->typ); } default: sysfatal("receval: unknown type %α", n->type); return mkval(VALINT, 0LL); } } static void execprintf(Node **arg, int narg, uchar *p, uchar *e, Enab *en) { char *x, *xp; Val v; int i; x = emalloc(sizeof(uvlong) * (narg - 1)); xp = x; for(i = 0; i < narg - 1; i++){ v = receval(arg[i + 1], p, e, en); switch(v.type){ case VALINT: *(uvlong*)xp = v.v; xp += sizeof(uvlong); break; case VALSTR: *(char**)xp = v.s; xp += sizeof(char*); break; default: abort(); } } vfprint(1, (*arg)->str, (va_list) x); free(x); } int parseclause(Clause *cl, uchar *p, uchar *e, Enab *en, Biobuf *bp) { Stat *s; int i; Val v; for(s = cl->stats; s < cl->stats + cl->nstats; s++) switch(s->type){ case STATEXPR: break; case STATPRINT: for(i = 0; i < s->narg; i++){ v = receval(s->arg[i], p, e, en); switch(v.type){ case VALINT: Bprint(bp, "%lld", v.v); break; case VALSTR: Bprint(bp, "%s", v.s); break; default: sysfatal("parseclause: unknown val type %d", s->type); } Bprint(bp, "%c", i == s->narg - 1 ? '\n' : ' '); } break; case STATPRINTF: execprintf(s->arg, s->narg, p, e, en); break; case STATAGG: break; default: sysfatal("parseclause: unknown type %d", s->type); } return 0; } uchar * parsefault(uchar *p0, uchar *e) { uchar *p; u32int epid; u8int type, dummy; u16int n; Enab *en; p = unpack(p0, e, "csci", &type, &n, &dummy, &epid); if(p == nil) return nil; en = epidlookup(epid); switch(type){ case DTFILL: { u32int pid; u64int addr; p = unpack(p, e, "iv", &pid, &addr); if(p == nil) return nil; fprint(2, "dtracy: illegal access: probe=%s, pid=%d, addr=%#llx\n", en != nil ? en->probe : nil, pid, addr); break; } default: fprint(2, "dtracy: unknown fault type %#.2ux\n", type); } return p0 + n - 12; } int parsebuf(uchar *p, int n, Biobuf *bp) { uchar *e; u32int epid; u64int ts; Enab *en; e = p + n; while(p < e){ p = unpack(p, e, "iv", &epid, &ts); if(p == nil) goto err; if(epid == (u32int)-1){ p = parsefault(p, e); if(p == nil) goto err; continue; } en = epidlookup(epid); if(en == nil) goto err; if(parseclause(en->cl, p - 12, p + en->reclen - 12, en, bp) < 0) return -1; p += en->reclen - 12; } return 0; err: werrstr("buffer invalid"); return -1; } static void dumpexpr(DTExpr *e, char *prefix) { int i; for(i = 0; i < e->n; i++) print("%s%.8ux %I\n", prefix, e->b[i], e->b[i]); } #pragma varargck type "ε" Node* static void fmtstring(Fmt *f, char *s) { fmtrune(f, '"'); for(; *s != 0; s++) switch(*s){ case '\n': fmtprint(f, "\\n"); break; case '\r': fmtprint(f, "\\r"); break; case '\t': fmtprint(f, "\\t"); break; case '\v': fmtprint(f, "\\v"); break; case '\b': fmtprint(f, "\\b"); break; case '\a': fmtprint(f, "\\a"); break; case '"': fmtprint(f, "\""); break; case '\\': fmtprint(f, "\\"); break; default: if(*s < 0x20 || *s >= 0x7f) fmtprint(f, "\\%.3o", (uchar)*s); else fmtrune(f, *s); } fmtrune(f, '"'); } typedef struct Op Op; struct Op { char *name; int pred; enum { PRECRIGHT = 1 } flags; }; static Op optab[] = { [OPLOR] {"||", 3, 0}, [OPLAND] {"&&", 4, 0}, [OPOR] {"|", 5, 0}, [OPXNOR] {"~^", 6, 0}, [OPXOR] {"^", 6, 0}, [OPAND] {"&", 7, 0}, [OPEQ] {"==", 8, }, [OPNE] {"!=", 8, 0}, [OPLE] {"<=", 9, 0}, [OPLT] {"<", 9, 0}, [OPLSH] {"<<", 10, 0}, [OPRSH] {">>", 10, 0}, [OPADD] {"+", 11, 0}, [OPSUB] {"-", 11, 0}, [OPDIV] {"/", 12, 0}, [OPMOD] {"%", 12, 0}, [OPMUL] {"*", 12, 0}, }; enum { PREDUNARY = 14 }; int nodefmt(Fmt *f) { Node *n; Op *op; int p; p = f->width; n = va_arg(f->args, Node *); switch(n->type){ case OSYM: fmtprint(f, "%s", n->sym->name); break; case ONUM: fmtprint(f, "%lld", n->num); break; case OSTR: fmtstring(f, n->str); break; case OBIN: if(n->op >= nelem(optab) || optab[n->op].name == nil) fmtprint(f, "(%*ε ??op%d %*ε)", PREDUNARY, n->n1, n->op, PREDUNARY, n->n2); else{ op = &optab[n->op]; if(op->pred < p) fmtrune(f, '('); fmtprint(f, "%*ε %s %*ε", op->pred + (op->flags & PRECRIGHT), n->n1, op->name, op->pred + (~op->flags & PRECRIGHT), n->n2); if(op->pred < p) fmtrune(f, ')'); } break; case OLNOT: fmtprint(f, "!%*ε", PREDUNARY, n->n1); break; case OTERN: fmtprint(f, "%2ε ? %1ε : %1ε", n->n1, n->n2, n->n3); break; case ORECORD: fmtprint(f, "record(%ε, %τ, %d)", n->n1, n->typ, (int)n->num); break; case OCAST: fmtprint(f, "(%τ) %*ε", n->typ, PREDUNARY, n->n1); break; default: fmtprint(f, "??? %α", n->type); } return 0; } void dump(void) { int i, j; Stat *s; Clause *c; DTClause *d; DTAct *a; for(i = 0; i < nclauses; i++){ c = clauses[i]; d = mkdtclause(c); print("clause %d:\n", c->id); for(j = 0; j < c->nprob; j++) print("\tprobe '%s'\n", c->probs[j]); print("\tkernel code:\n"); if(c->pred == nil) print("\t\tno predicate\n"); else{ print("\t\tpredicate\n"); dumpexpr(c->pred, "\t\t\t"); } for(a = d->gr->acts; a < d->gr->acts + d->gr->nact; a++) switch(a->type){ case ACTTRACE: print("\t\ttrace (%d bytes)\n", a->size); dumpexpr(a->p, "\t\t\t"); break; case ACTTRACESTR: print("\t\ttrace string (%d bytes)\n", a->size); dumpexpr(a->p, "\t\t\t"); break; case ACTAGGKEY: print("\t\taggregation key (%s,%d,%d)\n", a->agg.type >= nelem(aggtypes) ? "???" : aggtypes[a->agg.type], a->agg.keysize, (u16int)a->agg.id); dumpexpr(a->p, "\t\t\t"); break; case ACTAGGVAL: print("\t\taggregation value (%s,%d,%d)\n", a->agg.type >= nelem(aggtypes) ? "???" : aggtypes[a->agg.type], a->agg.keysize, (u16int)a->agg.id); dumpexpr(a->p, "\t\t\t"); break; case ACTCANCEL: print("\t\tcancel record\n"); break; default: print("\t\t??? %d\n", a->type); } print("\trecord formatting:\n"); for(s = c->stats; s < c->stats + c->nstats; s++) switch(s->type){ case STATEXPR: break; case STATPRINT: print("\t\tprint\n"); for(j = 0; j < s->narg; j++) print("\t\t\targ %ε\n", s->arg[j]); break; case STATPRINTF: print("\t\tprintf\n"); for(j = 0; j < s->narg; j++) print("\t\t\targ %ε\n", s->arg[j]); break; case STATAGG: break; default: print("\t\t??? %d\n", s->type); } } }