/* ----------------------------------------------------------------------------- * * (c) The GHC Team, 2001 * Author: Sungwoo Park * * Retainer set implementation for retainer profiling (see RetainerProfile.c) * * ---------------------------------------------------------------------------*/ #ifdef PROFILING #include "PosixSource.h" #include "Rts.h" #include "Stats.h" #include "RtsUtils.h" #include "RetainerSet.h" #include "Arena.h" #include "Profiling.h" #include #define HASH_TABLE_SIZE 255 #define hash(hk) (hk % HASH_TABLE_SIZE) static RetainerSet *hashTable[HASH_TABLE_SIZE]; static Arena *arena; // arena in which we store retainer sets static int nextId; // id of next retainer set /* ----------------------------------------------------------------------------- * rs_MANY is a distinguished retainer set, such that * * isMember(e, rs_MANY) = True * * addElement(e, rs) = rs_MANY, if rs->num >= maxRetainerSetSize * addElement(e, rs_MANY) = rs_MANY * * The point of rs_MANY is to keep the total number of retainer sets * from growing too large. * -------------------------------------------------------------------------- */ RetainerSet rs_MANY = { .num = 0, .hashKey = 0, .link = NULL, .id = 1, .element = {} }; /* ----------------------------------------------------------------------------- * calculate the size of a RetainerSet structure * -------------------------------------------------------------------------- */ STATIC_INLINE size_t sizeofRetainerSet( int elems ) { return (sizeof(RetainerSet) + elems * sizeof(retainer)); } /* ----------------------------------------------------------------------------- * Creates the first pool and initializes hashTable[]. * Frees all pools if any. * -------------------------------------------------------------------------- */ void initializeAllRetainerSet(void) { int i; arena = newArena(); for (i = 0; i < HASH_TABLE_SIZE; i++) hashTable[i] = NULL; nextId = 2; // Initial value must be positive, 2 is MANY. } /* ----------------------------------------------------------------------------- * Refreshes all pools for reuse and initializes hashTable[]. * -------------------------------------------------------------------------- */ void refreshAllRetainerSet(void) { #ifdef FIRST_APPROACH int i; // first approach: completely refresh arenaFree(arena); arena = newArena(); for (i = 0; i < HASH_TABLE_SIZE; i++) hashTable[i] = NULL; nextId = 2; #endif /* FIRST_APPROACH */ } /* ----------------------------------------------------------------------------- * Frees all pools. * -------------------------------------------------------------------------- */ void closeAllRetainerSet(void) { arenaFree(arena); } /* ----------------------------------------------------------------------------- * Finds or creates if needed a singleton retainer set. * -------------------------------------------------------------------------- */ RetainerSet * singleton(retainer r) { RetainerSet *rs; StgWord hk; hk = hashKeySingleton(r); for (rs = hashTable[hash(hk)]; rs != NULL; rs = rs->link) if (rs->num == 1 && rs->element[0] == r) return rs; // found it // create it rs = arenaAlloc( arena, sizeofRetainerSet(1) ); rs->num = 1; rs->hashKey = hk; rs->link = hashTable[hash(hk)]; rs->id = nextId++; rs->element[0] = r; // The new retainer set is placed at the head of the linked list. hashTable[hash(hk)] = rs; return rs; } /* ----------------------------------------------------------------------------- * Finds or creates a retainer set *rs augmented with r. * Invariants: * r is not a member of rs, i.e., isMember(r, rs) returns rtsFalse. * rs is not NULL. * Note: * We could check if rs is NULL, in which case this function call * reverts to singleton(). We do not choose this strategy because * in most cases addElement() is invoked with non-NULL rs. * -------------------------------------------------------------------------- */ RetainerSet * addElement(retainer r, RetainerSet *rs) { uint32_t i; uint32_t nl; // Number of retainers in *rs Less than r RetainerSet *nrs; // New Retainer Set StgWord hk; // Hash Key #ifdef DEBUG_RETAINER // debugBelch("addElement(%p, %p) = ", r, rs); #endif ASSERT(rs != NULL); ASSERT(rs->num <= RtsFlags.ProfFlags.maxRetainerSetSize); if (rs == &rs_MANY || rs->num == RtsFlags.ProfFlags.maxRetainerSetSize) { return &rs_MANY; } ASSERT(!isMember(r, rs)); for (nl = 0; nl < rs->num; nl++) if (r < rs->element[nl]) break; // Now nl is the index for r into the new set. // Also it denotes the number of retainers less than r in *rs. // Thus, compare the first nl retainers, then r itself, and finally the // remaining (rs->num - nl) retainers. hk = hashKeyAddElement(r, rs); for (nrs = hashTable[hash(hk)]; nrs != NULL; nrs = nrs->link) { // test *rs and *nrs for equality // check their size if (rs->num + 1 != nrs->num) continue; // compare the first nl retainers and find the first non-matching one. for (i = 0; i < nl; i++) if (rs->element[i] != nrs->element[i]) break; if (i < nl) continue; // compare r itself if (r != nrs->element[i]) continue; // i == nl // compare the remaining retainers for (; i < rs->num; i++) if (rs->element[i] != nrs->element[i + 1]) break; if (i < rs->num) continue; #ifdef DEBUG_RETAINER // debugBelch("%p\n", nrs); #endif // The set we are seeking already exists! return nrs; } // create a new retainer set nrs = arenaAlloc( arena, sizeofRetainerSet(rs->num + 1) ); nrs->num = rs->num + 1; nrs->hashKey = hk; nrs->link = hashTable[hash(hk)]; nrs->id = nextId++; for (i = 0; i < nl; i++) { // copy the first nl retainers nrs->element[i] = rs->element[i]; } nrs->element[i] = r; // copy r for (; i < rs->num; i++) { // copy the remaining retainers nrs->element[i + 1] = rs->element[i]; } hashTable[hash(hk)] = nrs; #ifdef DEBUG_RETAINER // debugBelch("%p\n", nrs); #endif return nrs; } /* ----------------------------------------------------------------------------- * printRetainer() prints the full information on a given retainer, * not a retainer set. * -------------------------------------------------------------------------- */ #if defined(RETAINER_SCHEME_INFO) // Retainer scheme 1: retainer = info table static void printRetainer(FILE *f, retainer itbl) { fprintf(f, "%s[%s]", GET_PROF_DESC(itbl), itbl->prof.closure_type); } #elif defined(RETAINER_SCHEME_CCS) // Retainer scheme 2: retainer = cost centre stack static void printRetainer(FILE *f, retainer ccs) { fprintCCS(f, ccs); } #elif defined(RETAINER_SCHEME_CC) // Retainer scheme 3: retainer = cost centre static void printRetainer(FILE *f, retainer cc) { fprintf(f,"%s.%s", cc->module, cc->label); } #endif /* ----------------------------------------------------------------------------- * printRetainerSetShort() should always display the same output for * a given retainer set regardless of the time of invocation. * -------------------------------------------------------------------------- */ #ifdef SECOND_APPROACH #if defined(RETAINER_SCHEME_INFO) // Retainer scheme 1: retainer = info table void printRetainerSetShort(FILE *f, RetainerSet *rs, uint32_t max_length) { char tmp[max_length + 1]; int size; uint32_t j; ASSERT(rs->id < 0); tmp[max_length] = '\0'; // No blank characters are allowed. sprintf(tmp + 0, "(%d)", -(rs->id)); size = strlen(tmp); ASSERT(size < max_length); for (j = 0; j < rs->num; j++) { if (j < rs->num - 1) { strncpy(tmp + size, GET_PROF_DESC(rs->element[j]), max_length - size); size = strlen(tmp); if (size == max_length) break; strncpy(tmp + size, ",", max_length - size); size = strlen(tmp); if (size == max_length) break; } else { strncpy(tmp + size, GET_PROF_DESC(rs->element[j]), max_length - size); // size = strlen(tmp); } } fprintf(f, tmp); } #elif defined(RETAINER_SCHEME_CC) // Retainer scheme 3: retainer = cost centre void printRetainerSetShort(FILE *f, RetainerSet *rs, uint32_t max_length) { char tmp[max_length + 1]; int size; uint32_t j; } #elif defined(RETAINER_SCHEME_CCS) // Retainer scheme 2: retainer = cost centre stack void printRetainerSetShort(FILE *f, RetainerSet *rs, uint32_t max_length) { char tmp[max_length + 1]; uint32_t size; uint32_t j; ASSERT(rs->id < 0); tmp[max_length] = '\0'; // No blank characters are allowed. sprintf(tmp + 0, "(%d)", -(rs->id)); size = strlen(tmp); ASSERT(size < max_length); for (j = 0; j < rs->num; j++) { if (j < rs->num - 1) { strncpy(tmp + size, rs->element[j]->cc->label, max_length - size); size = strlen(tmp); if (size == max_length) break; strncpy(tmp + size, ",", max_length - size); size = strlen(tmp); if (size == max_length) break; } else { strncpy(tmp + size, rs->element[j]->cc->label, max_length - size); // size = strlen(tmp); } } fputs(tmp, f); } #elif defined(RETAINER_SCHEME_CC) // Retainer scheme 3: retainer = cost centre static void printRetainerSetShort(FILE *f, retainerSet *rs, uint32_t max_length) { char tmp[max_length + 1]; int size; uint32_t j; ASSERT(rs->id < 0); tmp[max_length] = '\0'; // No blank characters are allowed. sprintf(tmp + 0, "(%d)", -(rs->id)); size = strlen(tmp); ASSERT(size < max_length); for (j = 0; j < rs->num; j++) { if (j < rs->num - 1) { strncpy(tmp + size, rs->element[j]->label, max_length - size); size = strlen(tmp); if (size == max_length) break; strncpy(tmp + size, ",", max_length - size); size = strlen(tmp); if (size == max_length) break; } else { strncpy(tmp + size, rs->element[j]->label, max_length - size); // size = strlen(tmp); } } fprintf(f, tmp); /* #define DOT_NUMBER 3 // 1. 32 > max_length + 1 (1 for '\0') // 2. (max_length - DOT_NUMBER ) characters should be enough for // printing one natural number (plus '(' and ')'). char tmp[32]; int size, ts; uint32_t j; ASSERT(rs->id < 0); // No blank characters are allowed. sprintf(tmp + 0, "(%d)", -(rs->id)); size = strlen(tmp); ASSERT(size < max_length - DOT_NUMBER); for (j = 0; j < rs->num; j++) { ts = strlen(rs->element[j]->label); if (j < rs->num - 1) { if (size + ts + 1 > max_length - DOT_NUMBER) { sprintf(tmp + size, "..."); break; } sprintf(tmp + size, "%s,", rs->element[j]->label); size += ts + 1; } else { if (size + ts > max_length - DOT_NUMBER) { sprintf(tmp + size, "..."); break; } sprintf(tmp + size, "%s", rs->element[j]->label); size += ts; } } fprintf(f, tmp); */ } #endif /* RETAINER_SCHEME_CC */ #endif /* SECOND_APPROACH */ /* ----------------------------------------------------------------------------- * Dump the contents of each retainer set into the log file at the end * of the run, so the user can find out for a given retainer set ID * the full contents of that set. * -------------------------------------------------------------------------- */ #ifdef SECOND_APPROACH void outputAllRetainerSet(FILE *prof_file) { uint32_t i, j; uint32_t numSet; RetainerSet *rs, **rsArray, *tmp; // find out the number of retainer sets which have had a non-zero cost at // least once during retainer profiling numSet = 0; for (i = 0; i < HASH_TABLE_SIZE; i++) for (rs = hashTable[i]; rs != NULL; rs = rs->link) { if (rs->id < 0) numSet++; } if (numSet == 0) // retainer profiling was not done at all. return; // allocate memory rsArray = stgMallocBytes(numSet * sizeof(RetainerSet *), "outputAllRetainerSet()"); // prepare for sorting j = 0; for (i = 0; i < HASH_TABLE_SIZE; i++) for (rs = hashTable[i]; rs != NULL; rs = rs->link) { if (rs->id < 0) { rsArray[j] = rs; j++; } } ASSERT(j == numSet); // sort rsArray[] according to the id of each retainer set for (i = numSet - 1; i > 0; i--) { for (j = 0; j <= i - 1; j++) { // if (-(rsArray[j]->id) < -(rsArray[j + 1]->id)) if (rsArray[j]->id < rsArray[j + 1]->id) { tmp = rsArray[j]; rsArray[j] = rsArray[j + 1]; rsArray[j + 1] = tmp; } } } fprintf(prof_file, "\nRetainer sets created during profiling:\n"); for (i = 0;i < numSet; i++) { fprintf(prof_file, "SET %u = {", -(rsArray[i]->id)); for (j = 0; j < rsArray[i]->num - 1; j++) { printRetainer(prof_file, rsArray[i]->element[j]); fprintf(prof_file, ", "); } printRetainer(prof_file, rsArray[i]->element[j]); fprintf(prof_file, "}\n"); } stgFree(rsArray); } #endif /* SECOND_APPROACH */ #endif /* PROFILING */