/* * %CopyrightBegin% * * Copyright Ericsson AB 2003-2016. All Rights Reserved. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * %CopyrightEnd% */ /* * Description: * * Author: Rickard Green */ /* Headers to include ... */ #ifdef __WIN32__ # include # undef WIN32_LEAN_AND_MEAN # define WIN32_LEAN_AND_MEAN # include typedef int socklen_t; #else # if defined(__linux__) && defined(__GNUC__) # define _GNU_SOURCE 1 # endif # include # include # include # include # include # include # include #endif #include #include #include #include #include "erl_fixed_size_int_types.h" #include "erl_memory_trace_parser.h" #include "erl_memory_trace_block_table.h" #include "ethread.h" /* Increment when changes are made */ #define EMEM_VSN_STR "0.9" /* Features not fully implemented yet */ #define EMEM_A_SWITCH 0 #define EMEM_C_SWITCH 0 #define EMEM_c_SWITCH 0 #define EMEM_d_SWITCH 0 /* Some system specific defines ... */ #ifdef __WIN32__ # define ssize_t int # define GET_SOCK_ERRNO() (WSAGetLastError() - WSABASEERR) # define IS_INVALID_SOCKET(X) ((X) == INVALID_SOCKET) # ifdef __GNUC__ # define INLINE __inline__ # else # define INLINE __forceinline # endif # define DIR_SEP_CHAR '\\' #else # define SOCKET int # define closesocket close # define GET_SOCK_ERRNO() (errno ? errno : INT_MAX) # define INVALID_SOCKET (-1) # define IS_INVALID_SOCKET(X) ((X) < 0) # ifdef __GNUC__ # define INLINE __inline__ # else # define INLINE # endif # define DIR_SEP_CHAR '/' #endif #define EM_ERL_CMD_FILE_NAME "erl_cmd.txt" #define EM_OUTPUT_FILE_SUFFIX ".emem" #define PRINT_OPERATIONS 0 /* Our own assert() ... */ #ifdef DEBUG #define ASSERT(A) ((void) ((A) ? 1 : assert_failed(__FILE__, __LINE__, #A))) #include static int assert_failed(char *f, int l, char *a) { fprintf(stderr, "%s:%d: Assertion failed: %s\n", f, l, a); abort(); return 0; } #else #define ASSERT(A) ((void) 1) #endif #define ERR_RET(X) return (X) #if 1 # undef ERR_RET # define ERR_RET(X) abort() #endif /* #define HARD_DEBUG */ #define EM_EXIT_RESULT (EMTBT_MIN_ERROR - 1) #define EM_TRUNCATED_TRACE_ERROR (EMTBT_MIN_ERROR - 2) #define EM_INTERNAL_ERROR (EMTBT_MIN_ERROR - 3) #define EM_DEFAULT_BUF_SZ 8192 #define EM_LINES_UNTIL_HEADER 20 #define EM_NO_OF_OPS 400 #define EM_MAX_CONSECUTIVE_TRACE_READS 10 #define EM_MAX_NO_OF_TRACE_BUFS 1280 #define EM_MIN_TRACE_READ_SIZE (EM_DEFAULT_BUF_SZ/20) #define EM_TIME_FIELD_WIDTH 11 static void error(int res); static void error_msg(int res, char *msg); typedef struct { usgnd_int_max size; usgnd_int_max min_size; usgnd_int_max max_size; usgnd_int_max max_ever_size; usgnd_int_max no; usgnd_int_max min_no; usgnd_int_max max_no; usgnd_int_max max_ever_no; usgnd_int_max allocs; usgnd_int_max reallocs; usgnd_int_max frees; } em_mem_info; typedef struct em_buffer_ { struct em_buffer_ *next; int write; char *data; char *data_end; char *end; size_t size; char start[EM_DEFAULT_BUF_SZ]; } em_buffer; typedef struct { int no_writer; int no_reader; size_t tot_buf_size; size_t max_buf_size; char *name; em_buffer *first; em_buffer *last; ethr_mutex mutex; ethr_cond cond; int used_def_buf_a; em_buffer def_buf_a; int used_def_buf_b; em_buffer def_buf_b; } em_buf_queue; typedef struct { char *ptr; size_t size; } em_area; typedef struct { char *name; int ix; } em_output_types; typedef struct { /* Memory allocation functions */ void * (*alloc)(size_t); void * (*realloc)(void *, size_t); void (*free)(void *); emtbt_table *block_table; emtbt_table **carrier_table; struct { em_mem_info total; em_mem_info *btype; em_mem_info *allctr; em_mem_info **allctr_prv_crr; em_mem_info **allctr_usd_crr; struct { usgnd_int_32 secs; usgnd_int_32 usecs; } stop_time; emtp_op_type stop_reason; usgnd_int_32 exit_status; } info; /* Input ... */ struct { usgnd_int_16 listen_port; SOCKET socket; usgnd_int_max total_trace_size; int error; char *error_descr; em_buf_queue queue; } input; /* Output ... */ struct { usgnd_int_32 next_print; usgnd_int_32 next_print_inc; char *header; size_t header_size; size_t values_per_object; size_t values_per_line; size_t field_width; int verbose; int total; int all_allctrs; int no_allctrs; em_output_types *allctrs; int all_btypes; int no_btypes; em_output_types *btypes; int max_min_values; int block_counts; int op_counts; int lines_until_header; FILE *stream; char *file_name; #if EMEM_d_SWITCH char *dir_name; FILE *erl_cmd_file; struct { ethr_mutex *mutex; ethr_cond *cond; } go; #endif em_buf_queue queue; } output; /* Trace info */ emtp_state *trace_state; emtp_info trace_info; } em_state; /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * Threads... * * * \* */ static INLINE void mutex_init(ethr_mutex *mtx) { int res = ethr_mutex_init(mtx); if (res) error_msg(res, "Mutex init"); } static INLINE void mutex_destroy(ethr_mutex *mtx) { int res = ethr_mutex_destroy(mtx); if (res) error_msg(res, "Mutex destroy"); } static INLINE void mutex_lock(ethr_mutex *mtx) { ethr_mutex_lock(mtx); } static INLINE void mutex_unlock(ethr_mutex *mtx) { ethr_mutex_unlock(mtx); } static INLINE void cond_init(ethr_cond *cnd) { int res = ethr_cond_init(cnd); if (res) error_msg(res, "Cond init"); } static INLINE void cond_destroy(ethr_cond *cnd) { int res = ethr_cond_destroy(cnd); if (res) error_msg(res, "Cond destroy"); } static INLINE void cond_wait(ethr_cond *cnd, ethr_mutex *mtx) { int res = ethr_cond_wait(cnd, mtx); if (res != 0 && res != EINTR) error_msg(res, "Cond wait"); } static INLINE void cond_signal(ethr_cond *cnd) { ethr_cond_signal(cnd); } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * Buffer queues * * * \* */ static INLINE void reset_buffer(em_buffer *b, size_t size) { b->write = 1; b->next = NULL; if (size) { b->size = size; b->end = b->start + size; } b->data_end = b->data = b->start; } static void init_queue(em_state *state, em_buf_queue *queue) { reset_buffer(&queue->def_buf_a, EM_DEFAULT_BUF_SZ); reset_buffer(&queue->def_buf_b, EM_DEFAULT_BUF_SZ); queue->first = NULL; queue->last = NULL; queue->no_writer = 0; queue->no_reader = 0; queue->tot_buf_size = 0; queue->max_buf_size = ~0; queue->name = ""; queue->used_def_buf_a = 0; queue->used_def_buf_b = 0; mutex_init(&queue->mutex); cond_init(&queue->cond); } static void destroy_queue(em_state *state, em_buf_queue *queue) { while (queue->first) { em_buffer *buf = queue->first; queue->first = queue->first->next; if (buf != &queue->def_buf_a && buf != &queue->def_buf_b) (*state->free)((void *) buf); } mutex_destroy(&queue->mutex); cond_destroy(&queue->cond); } static void disconnect_queue_writer(em_buf_queue *queue) { mutex_lock(&queue->mutex); queue->no_writer = 1; cond_signal(&queue->cond); mutex_unlock(&queue->mutex); } static void disconnect_queue_reader(em_buf_queue *queue) { mutex_lock(&queue->mutex); queue->no_reader = 1; cond_signal(&queue->cond); mutex_unlock(&queue->mutex); } static int is_queue_writer_disconnected(em_buf_queue *queue) { int res; mutex_lock(&queue->mutex); res = queue->no_writer; mutex_unlock(&queue->mutex); return res; } static int is_queue_reader_disconnected(em_buf_queue *queue) { int res; mutex_lock(&queue->mutex); res = queue->no_reader; mutex_unlock(&queue->mutex); return res; } static INLINE void dequeue(em_state *state, em_buf_queue *queue) { em_buffer *buf; ASSERT(queue->first); ASSERT(queue->tot_buf_size > 0); buf = queue->first; queue->first = buf->next; if (!queue->first) queue->last = NULL; ASSERT(queue->tot_buf_size >= buf->size); queue->tot_buf_size -= buf->size; if (buf == &queue->def_buf_a) queue->used_def_buf_a = 0; else if (buf == &queue->def_buf_b) queue->used_def_buf_b = 0; else (*state->free)((void *) buf); } static INLINE em_buffer * enqueue(em_state *state, em_buf_queue *queue, size_t min_size) { em_buffer *buf; if (min_size > EM_DEFAULT_BUF_SZ) goto alloc_buf; if (!queue->used_def_buf_a) { buf = &queue->def_buf_a; queue->used_def_buf_a = 1; reset_buffer(buf, 0); } else if (!queue->used_def_buf_b) { buf = &queue->def_buf_b; queue->used_def_buf_b = 1; reset_buffer(buf, 0); } else { size_t bsize; alloc_buf: bsize = EM_DEFAULT_BUF_SZ; if (bsize < min_size) bsize = min_size; buf = (em_buffer *) (*state->alloc)(sizeof(em_buffer) + (sizeof(char) * (bsize-EM_DEFAULT_BUF_SZ))); if (buf) { buf->size = bsize; reset_buffer(buf, bsize); } } if (queue->last) { ASSERT(queue->first); queue->last->write = 0; queue->last->next = buf; } else { ASSERT(!queue->first); queue->first = buf; } queue->tot_buf_size += buf->size; queue->last = buf; return buf; } static void get_next_read_area(em_area *area, em_state *state, em_buf_queue *queue) { mutex_lock(&queue->mutex); while (!queue->first || queue->first->data == queue->first->data_end) { if (queue->first && (!queue->first->write || queue->first->data == queue->first->end)) { dequeue(state, queue); continue; } if (queue->no_writer) { area->ptr = NULL; area->size = 0; mutex_unlock(&queue->mutex); return; } cond_wait(&queue->cond, &queue->mutex); } ASSERT(queue->first->data < queue->first->data_end); area->ptr = queue->first->data; area->size = queue->first->data_end - queue->first->data; queue->first->data = queue->first->data_end; mutex_unlock(&queue->mutex); } static INLINE void wrote_area_aux(em_area *area, em_state *state, em_buf_queue *queue, int do_lock) { em_buffer *buf; if (do_lock) mutex_lock(&queue->mutex); buf = queue->last; ASSERT(area->ptr); ASSERT(area->size); ASSERT(buf); ASSERT(buf->data_end == area->ptr); ASSERT(buf->end >= area->ptr + area->size); buf->data_end = area->ptr + area->size; area->ptr = NULL; area->size = 0; cond_signal(&queue->cond); if (do_lock) mutex_unlock(&queue->mutex); } static INLINE void wrote_area(em_area *area, em_state *state, em_buf_queue *queue) { wrote_area_aux(area, state, queue, 1); } static void get_next_write_area(em_area *area, em_state *state, em_buf_queue *queue, size_t size) { em_buffer *buf; mutex_lock(&queue->mutex); ASSERT(!area->size || area->ptr); if (area->size) wrote_area_aux(area, state, queue, 0); buf = ((queue->last && queue->last->end - queue->last->data_end >= size) ? queue->last : enqueue(state, queue, size)); if (buf) { ASSERT(buf->end - buf->data_end >= size); area->ptr = buf->data_end; area->size = buf->end - buf->data_end; } else { area->ptr = NULL; area->size = 0; } if (queue->tot_buf_size > queue->max_buf_size) { fprintf(stderr, "emem: Maximum %s buffer size (%lu) exceeded. " "Terminating...\n", queue->name, (unsigned long) queue->max_buf_size); exit(1); } mutex_unlock(&queue->mutex); } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * Output * * * \* */ static INLINE size_t write_str(char **dstpp, char *srcp) { size_t i = 0; if (dstpp) while (srcp[i]) *((*dstpp)++) = srcp[i++]; else while (srcp[i]) i++; return i; } static size_t write_strings(char **ptr, char **strings, char *first_line_prefix, char *line_prefix, size_t max_line_size) { size_t size; size_t tot_size = 0; size_t line_size = 0; size_t line_prefix_size; sgnd_int_32 ix; tot_size = line_size = line_prefix_size = write_str(ptr, first_line_prefix); for (ix = 0; strings[ix]; ix++) { size = write_str(NULL, strings[ix]); if (line_size + 1 + size > max_line_size) { tot_size += write_str(ptr, "\n"); tot_size += write_str(ptr, line_prefix); line_size = line_prefix_size; } tot_size += write_str(ptr, " "); tot_size += ptr ? write_str(ptr, strings[ix]) : size; line_size += 1 + size; } tot_size += write_str(ptr, "\n"); return tot_size; } static size_t write_title(char **bufp, size_t *overflow, size_t width, char *str) { size_t i, sz, ws; char *p, *endp; /* * Writes at least one '|' character at the beginning. * Right aligns "str". * If "str" is larger than "width - 1" and overflow is NULL, * then "str" is trucated; otherwise, string is not truncated. */ if (width <= 0) return 0; if (!bufp && !overflow) return width; sz = strlen(str) + 1; if (sz > width) { ws = 0; if (overflow) *overflow += sz - width; else sz = width; } else { ws = width - sz; if (overflow) { if (ws >= *overflow) { ws -= *overflow; *overflow = 0; } else { *overflow -= ws; ws = 0; } } sz += ws; } if (!bufp) return sz; p = *bufp; endp = p + width; *(p++) = '|'; while (ws > 1) { ws--; *(p++) = ' '; } i = 0; while (str[i] && (overflow || p < endp)) *(p++) = str[i++]; while (ws) { ws--; *(p++) = ' '; } ASSERT(overflow || p == endp); ASSERT(sz == (size_t) (p - *bufp)); *bufp = p; return sz; } static size_t write_obj_sub_titles(em_state *state, char **bufp, size_t *overflow) { size_t field_width = state->output.field_width; size_t size = write_title(bufp, overflow, field_width, "size"); if (state->output.max_min_values) { size += write_title(bufp, overflow, field_width, "min size"); size += write_title(bufp, overflow, field_width, "max size"); } if (state->output.block_counts) { size += write_title(bufp, overflow, field_width, "no"); if (state->output.max_min_values) { size += write_title(bufp, overflow, field_width, "min no"); size += write_title(bufp, overflow, field_width, "max no"); } } if (state->output.op_counts) { size += write_title(bufp, overflow, field_width, "alloc()"); size += write_title(bufp, overflow, field_width, "realloc()"); size += write_title(bufp, overflow, field_width, "free()"); } return size; } static size_t write_header(em_state *state, char *ptr, int trunc) { #define MIN_LTEXT_SZ 18 #define HEADER_EOL_STR "|\n" char *p; char **pp; int i; size_t overflow; size_t *ofp; size_t obj_size = state->output.values_per_object*state->output.field_width; size_t size = 0; int have_seg_crr = state->trace_info.have_segment_carrier_info; if (ptr) { p = ptr; pp = &p; } else { p = NULL; pp = NULL; } overflow = 0; ofp = trunc ? NULL : &overflow; size += write_title(pp, ofp, EM_TIME_FIELD_WIDTH, "time"); if (state->output.total) { int no = 1; if (have_seg_crr) { if (state->info.allctr_prv_crr[state->trace_info.segment_ix]) no++; if (state->info.allctr_usd_crr[state->trace_info.segment_ix]) no++; } size += write_title(pp, ofp, (have_seg_crr ? 3 : 1)*obj_size, "total"); } for (i = 0; i < state->output.no_allctrs; i++) { int no = 1; if (state->info.allctr_prv_crr[state->output.allctrs[i].ix]) no++; if (state->info.allctr_usd_crr[state->output.allctrs[i].ix]) no++; size += write_title(pp, ofp, no*obj_size, state->output.allctrs[i].name); } for (i = 0; i < state->output.no_btypes; i++) size += write_title(pp, ofp, obj_size, state->output.btypes[i].name); size += write_str(pp, HEADER_EOL_STR); overflow = 0; size += write_title(pp, ofp, EM_TIME_FIELD_WIDTH, ""); if (state->output.total) { size += write_title(pp, ofp, obj_size, (obj_size <= MIN_LTEXT_SZ ? "alcd blks" : "allocated blocks")); if (have_seg_crr) { if (state->info.allctr_prv_crr[state->trace_info.segment_ix]) size += write_title(pp, ofp, obj_size, (obj_size <= MIN_LTEXT_SZ ? "mpd segs" : "mapped segments")); if (state->info.allctr_usd_crr[state->trace_info.segment_ix]) size += write_title(pp, ofp, obj_size, (obj_size <= MIN_LTEXT_SZ ? "chd segs" : "cached segments")); } } for (i = 0; i < state->output.no_allctrs; i++) { size += write_title(pp, ofp, obj_size, (obj_size <= MIN_LTEXT_SZ ? "alcd blks" : "allocated blocks")); if (state->info.allctr_prv_crr[state->output.allctrs[i].ix]) size += write_title(pp, ofp, obj_size, (obj_size <= MIN_LTEXT_SZ ? "prvd crrs" : "provided carriers")); if (state->info.allctr_usd_crr[state->output.allctrs[i].ix]) size += write_title(pp, ofp, obj_size, (obj_size <= MIN_LTEXT_SZ ? "usd crrs" : "used carriers")); } for (i = 0; i < state->output.no_btypes; i++) size += write_title(pp, ofp, obj_size, (obj_size <= MIN_LTEXT_SZ ? "alcd blks" : "allocated blocks")); size += write_str(pp, HEADER_EOL_STR); overflow = 0; size += write_title(pp, ofp, EM_TIME_FIELD_WIDTH, ""); if (state->output.total) { size += write_obj_sub_titles(state, pp, ofp); if (have_seg_crr) { if (state->info.allctr_prv_crr[state->trace_info.segment_ix]) size += write_obj_sub_titles(state, pp, ofp); if (state->info.allctr_usd_crr[state->trace_info.segment_ix]) size += write_obj_sub_titles(state, pp, ofp); } } for (i = 0; i < state->output.no_allctrs; i++) { size += write_obj_sub_titles(state, pp, ofp); if (state->info.allctr_prv_crr[state->output.allctrs[i].ix]) size += write_obj_sub_titles(state, pp, ofp); if (state->info.allctr_usd_crr[state->output.allctrs[i].ix]) size += write_obj_sub_titles(state, pp, ofp); } for (i = 0; i < state->output.no_btypes; i++) size += write_obj_sub_titles(state, pp, ofp); size += write_str(pp, HEADER_EOL_STR); #undef MIN_LTEXT_SZ #undef HEADER_EOL_STR return size; } static INLINE void write_mem_info(em_state *state, char **p, em_mem_info *mi) { int fw = state->output.field_width - 1; *p += sprintf(*p, "%*" USGND_INT_MAX_FSTR " ", fw, mi->size); if (state->output.max_min_values) *p += sprintf(*p, "%*" USGND_INT_MAX_FSTR " %*" USGND_INT_MAX_FSTR " ", fw, mi->min_size, fw, mi->max_size); if (state->output.block_counts) { *p += sprintf(*p, "%*" USGND_INT_MAX_FSTR " ", fw, mi->no); if (state->output.max_min_values) *p += sprintf(*p, "%*" USGND_INT_MAX_FSTR " %*" USGND_INT_MAX_FSTR " ", fw, mi->min_no, fw, mi->max_no); } if (state->output.op_counts) *p += sprintf(*p, "%*" USGND_INT_MAX_FSTR " %*" USGND_INT_MAX_FSTR " %*" USGND_INT_MAX_FSTR " ", fw, mi->allocs, fw, mi->reallocs, fw, mi->frees); /* Update max ever values */ if (mi->max_ever_size < mi->max_size) mi->max_ever_size = mi->max_size; if (mi->max_ever_no < mi->max_no) mi->max_ever_no = mi->max_no; /* Reset max/min values */ mi->max_size = mi->min_size = mi->size; mi->max_no = mi->min_no = mi->no; } static INLINE void write_max_ever_mem_info(em_state *state, char **p, em_mem_info *mi) { int fw = state->output.field_width - 1; *p += sprintf(*p, "%*" USGND_INT_MAX_FSTR " ", fw, mi->max_ever_size); if (state->output.max_min_values) *p += sprintf(*p, "%*s %*s ", fw, "", fw, ""); if (state->output.block_counts) { *p += sprintf(*p, "%*" USGND_INT_MAX_FSTR " ", fw, mi->max_ever_no); if (state->output.max_min_values) *p += sprintf(*p, "%*s %*s ", fw, "", fw, ""); } if (state->output.op_counts) *p += sprintf(*p, "%*s %*s %*s ", fw, "", fw, "", fw, ""); } static void print_string(em_state *state, char *str) { em_area area = {NULL, 0}; char *p; /* Get area */ get_next_write_area(&area,state,&state->output.queue,write_str(NULL,str)); p = area.ptr; area.size = write_str(&p, str); /* Leave area */ wrote_area(&area, state, &state->output.queue); } static int print_emu_arg(em_state *state) { em_area area = {NULL, 0}; char hostname[100]; char carg[22]; struct sockaddr_in saddr; struct hostent *hp; struct in_addr iaddr; usgnd_int_16 port; socklen_t saddr_size = sizeof(saddr); size_t size; char *format = "> Emulator command line argument: +Mit %s\n"; if (getsockname(state->input.socket, (struct sockaddr *) &saddr, &saddr_size) != 0) goto error; port = ntohs(saddr.sin_port); ASSERT(state->input.listen_port == 0 || state->input.listen_port == port); state->input.listen_port = port; if (gethostname(hostname, sizeof(hostname)) != 0) goto error; hp = gethostbyname(hostname); if (!hp) goto error; if (hp->h_addr_list) { (void) memcpy(&iaddr.s_addr, *hp->h_addr_list, sizeof(iaddr.s_addr)); (void) sprintf(carg, "%s:%d", inet_ntoa(iaddr), (int) port); } else (void) sprintf(carg, "127.0.0.1:%d", (int) port); #if EMEM_d_SWITCH if (state->output.erl_cmd_file) { fprintf(state->output.erl_cmd_file, "+Mit %s\n", carg); fclose(state->output.erl_cmd_file); state->output.erl_cmd_file = NULL; } #endif size = strlen(format) + strlen(carg); /* Get area */ get_next_write_area(&area, state, &state->output.queue, size); area.size = sprintf(area.ptr, format, carg); /* Leave area */ wrote_area(&area, state, &state->output.queue); return 0; error: return GET_SOCK_ERRNO(); } static size_t write_allocator_info(em_state *state, char *ptr) { usgnd_int_32 aix, i, j; char *header = "> Allocator information:\n"; char *allctr_str = "> * Allocator:"; char *crr_prv_str = "> * Carrier providers:"; char *blk_tp_str = "> * Block types:"; char *line_prefix = "> "; size_t size = 0; char **strings; size_t strings_size; size_t max_line_size = 80; char *p = ptr; char **pp = ptr ? &p : NULL; strings_size = state->trace_info.max_block_type_ix + 1; if (strings_size < state->trace_info.max_allocator_ix + 1) strings_size = state->trace_info.max_allocator_ix + 1; strings = (char **) (*state->alloc)((strings_size + 1)*sizeof(char *)); if (!strings) error(ENOMEM); size += write_str(pp, header); for (aix = 0; aix <= state->trace_info.max_allocator_ix; aix++) { emtp_allocator *allctr = state->trace_info.allocator[aix]; if (!allctr->valid) continue; strings[0] = allctr->name; strings[1] = NULL; size += write_strings(pp,strings,allctr_str,line_prefix,max_line_size); i = 0; if (allctr->carrier.provider) for (j = 0; j < allctr->carrier.no_providers; j++) { usgnd_int_32 cpix = allctr->carrier.provider[j]; if (cpix == state->trace_info.segment_ix) strings[i++] = "segment"; else strings[i++] = state->trace_info.allocator[cpix]->name; } strings[i] = NULL; size += write_strings(pp,strings,crr_prv_str,line_prefix,max_line_size); i = 0; for (j = 0; j <= state->trace_info.max_block_type_ix; j++) if (state->trace_info.block_type[j]->allocator == aix) strings[i++] = state->trace_info.block_type[j]->name; strings[i] = NULL; size += write_strings(pp,strings,blk_tp_str,line_prefix,max_line_size); } (*state->free)((void *) strings); return size; } static void print_main_header(em_state *state) { #if HAVE_INT_64 #define MAX_WORD_SZ_STR "64" #else #define MAX_WORD_SZ_STR "32" #endif em_area area = {NULL, 0}; char *format1 = "> emem version: " EMEM_VSN_STR "\n" "> Nodename: %s\n" "> Hostname: %s\n" "> Pid: %s\n" "> Start time (UTC): "; char *format2 = "%4.4" USGND_INT_32_FSTR "-%2.2" USGND_INT_32_FSTR "-%2.2" USGND_INT_32_FSTR " %2.2" USGND_INT_32_FSTR ":%2.2" USGND_INT_32_FSTR ":%2.2" USGND_INT_32_FSTR ".%6.6" USGND_INT_32_FSTR "\n"; char *format3 = "> Trace parser version: %" USGND_INT_32_FSTR ".%" USGND_INT_32_FSTR "\n" "> Actual trace version: %" USGND_INT_32_FSTR ".%" USGND_INT_32_FSTR "\n" "> Maximum trace word size: " MAX_WORD_SZ_STR " bits\n" "> Actual trace word size: %d bits\n"; size_t size = (strlen(format1) + (state->trace_info.start_time.month ? (strlen(format2) + 7*10) : 1) + strlen(format3) + strlen(state->trace_info.nodename) + strlen(state->trace_info.hostname) + strlen(state->trace_info.pid) + 5*10 + 1); if (state->output.verbose) { size += write_allocator_info(state, NULL); } size += write_header(state, NULL, 0); /* Get area */ get_next_write_area(&area, state, &state->output.queue, size); area.size = sprintf(area.ptr, format1, state->trace_info.nodename, state->trace_info.hostname, state->trace_info.pid); if (state->trace_info.start_time.month) area.size += sprintf(area.ptr + area.size, format2, state->trace_info.start_time.year, state->trace_info.start_time.month, state->trace_info.start_time.day, state->trace_info.start_time.hour, state->trace_info.start_time.minute, state->trace_info.start_time.second, state->trace_info.start_time.micro_second); else *(area.ptr + area.size++) = '\n'; area.size += sprintf(area.ptr + area.size, format3, state->trace_info.version.parser.major, state->trace_info.version.parser.minor, state->trace_info.version.trace.major, state->trace_info.version.trace.minor, state->trace_info.bits); if (state->output.verbose) { area.size += write_allocator_info(state, area.ptr + area.size); } area.size += write_header(state, area.ptr + area.size, 0); /* Leave area */ wrote_area(&area, state, &state->output.queue); #undef MAX_WORD_SZ_STR } static void print_main_footer(em_state *state) { em_area area = {NULL, 0}; char *p; int i; char *stop_str = "> Trace stopped\n"; char *exit_str = "> Emulator exited with code: %" USGND_INT_32_FSTR "\n"; char *format = "> Total trace size: %" USGND_INT_MAX_FSTR " bytes\n" "> Average band width used: %" USGND_INT_MAX_FSTR " Kbit/s\n"; size_t size; usgnd_int_max tsz = state->input.total_trace_size; usgnd_int_32 secs = state->info.stop_time.secs; usgnd_int_32 usecs = state->info.stop_time.usecs; usgnd_int_max bw; /* Max size of the max value line. Each value can at most use 21 characters: largest possible usgnd_int_64 (20 digits) and one white space. */ size = state->output.values_per_line*21 + 1; switch (state->info.stop_reason) { case EMTP_STOP: size += strlen(stop_str) + 1; break; case EMTP_EXIT: size += strlen(exit_str); size += 10; /* Enough for one unsgn_int_32 */ size++; break; default: break; } size += strlen(format); size += 2*20; /* Enough for two unsgn_int_64 */ size += 2; bw = (tsz + 1023)/1024; bw *= 1000; bw /= secs*1000 + usecs/1000; bw *= 8; /* Get area */ get_next_write_area(&area, state, &state->output.queue, size); p = area.ptr; p += sprintf(p, "> %-*s", EM_TIME_FIELD_WIDTH - 2, "Maximum:"); if (state->output.total) { int six = state->trace_info.segment_ix; write_max_ever_mem_info(state, &p, &state->info.total); if (state->trace_info.have_segment_carrier_info) { if (state->info.allctr_prv_crr[six]) write_max_ever_mem_info(state, &p, state->info.allctr_prv_crr[six]); if (state->info.allctr_usd_crr[six]) write_max_ever_mem_info(state, &p, state->info.allctr_usd_crr[six]); } } for (i = 0; i < state->output.no_allctrs; i++) { int ix = state->output.allctrs[i].ix; write_max_ever_mem_info(state, &p, &state->info.allctr[ix]); if (state->info.allctr_prv_crr[ix]) write_max_ever_mem_info(state, &p, state->info.allctr_prv_crr[ix]); if (state->info.allctr_usd_crr[ix]) write_max_ever_mem_info(state, &p, state->info.allctr_usd_crr[ix]); } for (i = 0; i < state->output.no_btypes; i++) write_max_ever_mem_info(state, &p, &state->info.btype[state->output.btypes[i].ix]); p += sprintf(p, "\n"); switch (state->info.stop_reason) { case EMTP_STOP: p += sprintf(p, "%s", stop_str); break; case EMTP_EXIT: p += sprintf(p, exit_str, state->info.exit_status); break; default: break; } p += sprintf(p, format, tsz, bw); area.size = p - area.ptr; ASSERT(area.size <= size); /* Leave area */ wrote_area(&area, state, &state->output.queue); } static void print_info(em_state *state, usgnd_int_32 secs, char *extra) { char *p; int i; size_t size; em_area area = {NULL, 0}; /* Get area */ size = 0; if (!state->output.lines_until_header) size += state->output.header_size; /* Max size of one line of values. Each value can at most use 21 characters: largest possible usgnd_int_64 (20 digits) and one white space. */ size += state->output.values_per_line*21 + 1; if (extra) size += write_str(NULL, extra); get_next_write_area(&area, state, &state->output.queue, size); /* Write to area */ p = area.ptr; if (!state->output.lines_until_header) { memcpy((void *) area.ptr, (void *) state->output.header, state->output.header_size); p += state->output.header_size; state->output.lines_until_header = EM_LINES_UNTIL_HEADER; } else state->output.lines_until_header--; p += sprintf(p, "%*" USGND_INT_32_FSTR " ", EM_TIME_FIELD_WIDTH - 1, secs); if (state->output.total) { int six = state->trace_info.segment_ix; write_mem_info(state, &p, &state->info.total); if (state->trace_info.have_segment_carrier_info) { if (state->info.allctr_prv_crr[six]) write_mem_info(state, &p, state->info.allctr_prv_crr[six]); if (state->info.allctr_usd_crr[six]) write_mem_info(state, &p, state->info.allctr_usd_crr[six]); } } for (i = 0; i < state->output.no_allctrs; i++) { int ix = state->output.allctrs[i].ix; write_mem_info(state, &p, &state->info.allctr[ix]); if (state->info.allctr_prv_crr[ix]) write_mem_info(state, &p, state->info.allctr_prv_crr[ix]); if (state->info.allctr_usd_crr[ix]) write_mem_info(state, &p, state->info.allctr_usd_crr[ix]); } for (i = 0; i < state->output.no_btypes; i++) write_mem_info(state, &p, &state->info.btype[state->output.btypes[i].ix]); p += sprintf(p, "\n"); if (extra) p += write_str(&p, extra); ASSERT(area.size >= p - area.ptr); area.size = p - area.ptr; /* Leave area */ wrote_area(&area, state, &state->output.queue); } static void reset_mem_info(em_mem_info *mi) { mi->size = 0; mi->min_size = 0; mi->max_size = 0; mi->max_ever_size = 0; mi->no = 0; mi->min_no = 0; mi->max_no = 0; mi->max_ever_no = 0; mi->allocs = 0; mi->reallocs = 0; mi->frees = 0; } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * State creation and destruction * * * \* */ static void destroy_state(em_state *state) { int i; void (*freep)(void *); freep = state->free; if (state->block_table) emtbt_destroy_table(state->block_table); if (state->carrier_table) { for (i = -1; i <= state->trace_info.max_allocator_ix; i++) if (state->carrier_table[i]) emtbt_destroy_table(state->carrier_table[i]); state->carrier_table--; (*freep)((void *) state->carrier_table); } if (state->info.btype) { state->info.btype--; (*freep)((void *) state->info.btype); } if (state->info.allctr) { state->info.allctr--; (*freep)((void *) state->info.allctr); } if (state->info.allctr_prv_crr) { for (i = -1; i <= state->trace_info.max_allocator_ix; i++) if (state->info.allctr_prv_crr[i]) (*freep)((void *) state->info.allctr_prv_crr[i]); state->info.allctr_prv_crr--; (*freep)((void *) state->info.allctr_prv_crr); } if (state->info.allctr_usd_crr) { for (i = -1; i <= state->trace_info.max_allocator_ix; i++) if (state->info.allctr_usd_crr[i]) (*freep)((void *) state->info.allctr_usd_crr[i]); state->info.allctr_usd_crr--; (*freep)((void *) state->info.allctr_usd_crr); } emtp_state_destroy(state->trace_state); destroy_queue(state, &state->input.queue); if (state->output.btypes) (*freep)((void *) state->output.btypes); if (state->output.allctrs) (*freep)((void *) state->output.allctrs); destroy_queue(state, &state->output.queue); #if EMEM_d_SWITCH if (state->output.go.mutex) { mutex_destroy(state->output.go.mutex); (*state->free)((void *) state->output.go.mutex); state->output.go.mutex = NULL; } if (state->output.go.cond) { cond_destroy(state->output.go.cond); (*state->free)((void *) state->output.go.cond); state->output.go.cond = NULL; } #endif if (!IS_INVALID_SOCKET(state->input.socket)) { closesocket(state->input.socket); state->input.socket = INVALID_SOCKET; } (*freep)((void *) state); } static em_state * new_state(void * (*alloc)(size_t), void * (*realloc)(void *, size_t), void (*free)(void *)) { em_state *state = NULL; state = (*alloc)(sizeof(em_state)); if (!state) goto error; /* Stuff that might fail (used after the error label) */ state->trace_state = NULL; /* Init state ... */ state->alloc = alloc; state->realloc = realloc; state->free = free; state->block_table = NULL; state->carrier_table = NULL; reset_mem_info(&state->info.total); state->info.btype = NULL; state->info.allctr = NULL; state->info.allctr_prv_crr = NULL; state->info.allctr_usd_crr = NULL; state->info.stop_time.secs = 0; state->info.stop_time.usecs = 0; state->info.stop_reason = EMTP_UNDEF; state->info.exit_status = 0; state->output.next_print = 0; state->output.next_print_inc = 10; state->output.header = NULL; state->output.header_size = 0; state->output.values_per_object = 0; state->output.values_per_line = 0; state->output.field_width = 11; state->output.verbose = 0; state->output.total = 0; state->output.all_allctrs = 0; state->output.no_allctrs = 0; state->output.allctrs = NULL; state->output.all_btypes = 0; state->output.no_btypes = 0; state->output.btypes = NULL; state->output.max_min_values = 0; state->output.block_counts = 0; state->output.op_counts = 0; state->output.lines_until_header = EM_LINES_UNTIL_HEADER; #if PRINT_OPERATIONS state->output.stream = stderr; #else state->output.stream = stdout; #endif state->output.file_name = NULL; #if EMEM_d_SWITCH state->output.dir_name = NULL; state->output.erl_cmd_file = NULL; state->output.go.mutex = NULL; state->output.go.cond = NULL; #endif init_queue(state, &state->output.queue); state->output.queue.max_buf_size = 10*1024*1024; state->output.queue.name = "output"; state->trace_state = emtp_state_new(alloc, realloc, free); if (!state->trace_state) goto error; state->trace_info.version.parser.major = 0; state->trace_info.version.parser.minor = 0; state->trace_info.version.trace.major = 0; state->trace_info.version.trace.minor = 0; state->trace_info.bits = 0; state->trace_info.max_allocator_ix = 0; state->trace_info.allocator = NULL; state->trace_info.max_block_type_ix = 0; state->trace_info.block_type = NULL; state->input.listen_port = 0; state->input.socket = INVALID_SOCKET; state->input.total_trace_size = 0; state->input.error = 0; state->input.error_descr = NULL; init_queue(state, &state->input.queue); state->input.queue.max_buf_size = 10*1024*1024; state->input.queue.name = "input"; return state; error: if (state) { if (state->trace_state) emtp_state_destroy(state->trace_state); (*free)(state); } return NULL; } static emtbt_table * mk_block_table(em_state *state) { return emtbt_new_table(state->trace_info.bits == 64, state->alloc, state->realloc, state->free); } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * * * * \* */ #if PRINT_OPERATIONS void print_op(em_state *state, emtp_operation *op); #endif static INLINE void update_max_values(em_mem_info *mi) { if (mi->max_size < mi->size) mi->max_size = mi->size; if (mi->max_no < mi->no) mi->max_no = mi->no; } static INLINE void update_min_values(em_mem_info *mi) { if (mi->min_size > mi->size) mi->min_size = mi->size; if (mi->min_no > mi->no) mi->min_no = mi->no; } static INLINE void update_alloc_op(em_mem_info *mi, usgnd_int_max size) { mi->allocs++; mi->size += size; mi->no++; update_max_values(mi); } static INLINE void update_realloc_op(em_mem_info *mi, usgnd_int_max size, usgnd_int_max prev_size, int no_change) { mi->reallocs++; ASSERT(mi->size >= prev_size); mi->size -= prev_size; mi->size += size; if (no_change) { if (no_change > 0) mi->no++; else { ASSERT(mi->no > 0); mi->no--; } } update_max_values(mi); update_min_values(mi); } static INLINE void update_free_op(em_mem_info *mi, usgnd_int_max prev_size) { mi->frees++; ASSERT(mi->size >= prev_size); mi->size -= prev_size; ASSERT(mi->no > 0); mi->no--; update_min_values(mi); } static int insert_operations(em_state *state, emtp_operation ops[], size_t len) { emtbt_table *crr_table; emtbt_block old_blk; usgnd_int_32 prev_size; usgnd_int_max size; size_t i; int res; int aix, btix, crrix; for (i = 0; i < len; i++) { while (state->output.next_print <= ops[i].time.secs) { print_info(state, state->output.next_print, NULL); state->output.next_print += state->output.next_print_inc; } switch (ops[i].type) { case EMTP_ALLOC: #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif btix = (int) ops[i].u.block.type; aix = state->trace_info.block_type[btix]->allocator; if (!ops[i].u.block.new_ptr) continue; res = emtbt_alloc_op(state->block_table, &ops[i]); if (res != 0) ERR_RET(res); size = ops[i].u.block.new_size; update_alloc_op(&state->info.btype[btix], size); update_alloc_op(&state->info.allctr[aix], size); update_alloc_op(&state->info.total, size); break; case EMTP_REALLOC: { int no; #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif res = emtbt_realloc_op(state->block_table, &ops[i], &old_blk); if (res != 0) ERR_RET(res); size = ops[i].u.block.new_size; prev_size = old_blk.size; if (!ops[i].u.block.prev_ptr) btix = (int) ops[i].u.block.type; else btix = (int) old_blk.type; aix = state->trace_info.block_type[btix]->allocator; no = ((!old_blk.pointer && ops[i].u.block.new_ptr) ? 1 : ((old_blk.pointer && !ops[i].u.block.new_size) ? -1 : 0)); update_realloc_op(&state->info.btype[btix], size, prev_size, no); update_realloc_op(&state->info.allctr[aix], size, prev_size, no); update_realloc_op(&state->info.total, size, prev_size, no); break; } case EMTP_FREE: #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif if (!ops[i].u.block.prev_ptr) continue; res = emtbt_free_op(state->block_table, &ops[i], &old_blk); if (res != 0) ERR_RET(res); prev_size = old_blk.size; btix = (int) old_blk.type; aix = state->trace_info.block_type[btix]->allocator; update_free_op(&state->info.btype[btix], prev_size); update_free_op(&state->info.allctr[aix], prev_size); update_free_op(&state->info.total, prev_size); break; case EMTP_CARRIER_ALLOC: #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif aix = (int) ops[i].u.block.type; crrix = (int) ops[i].u.block.carrier_type; if (!state->carrier_table[crrix]) { state->carrier_table[crrix] = mk_block_table(state); if (!state->carrier_table[crrix]) ERR_RET(ENOMEM); } crr_table = state->carrier_table[crrix]; if (!ops[i].u.block.new_ptr) continue; res = emtbt_alloc_op(crr_table, &ops[i]); if (res != 0) ERR_RET(res); size = ops[i].u.block.new_size; if (state->info.allctr_usd_crr[aix]) update_alloc_op(state->info.allctr_usd_crr[aix], size); if (state->info.allctr_prv_crr[crrix]) update_alloc_op(state->info.allctr_prv_crr[crrix], size); update_alloc_op(&state->info.allctr[crrix], size); break; case EMTP_CARRIER_REALLOC: { int no; #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif crrix = (int) ops[i].u.block.carrier_type; if (!state->carrier_table[crrix]) { state->carrier_table[crrix] = mk_block_table(state); if (!state->carrier_table[crrix]) ERR_RET(ENOMEM); } crr_table = state->carrier_table[crrix]; res = emtbt_realloc_op(crr_table, &ops[i], &old_blk); if (res != 0) ERR_RET(res); size = ops[i].u.block.new_size; prev_size = old_blk.size; if (!ops[i].u.block.prev_ptr) aix = (int) ops[i].u.block.type; else aix = (int) old_blk.type; no = ((!old_blk.pointer && ops[i].u.block.new_ptr) ? 1 : ((old_blk.pointer && !ops[i].u.block.new_size) ? -1 : 0)); if (state->info.allctr_usd_crr[aix]) update_realloc_op(state->info.allctr_usd_crr[aix], size, prev_size, no); if (state->info.allctr_prv_crr[crrix]) update_realloc_op(state->info.allctr_prv_crr[crrix], size, prev_size, no); update_realloc_op(&state->info.allctr[crrix], size, prev_size, no); break; } case EMTP_CARRIER_FREE: #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif crrix = (int) ops[i].u.block.carrier_type; crr_table = state->carrier_table[crrix]; if (!crr_table) ERR_RET(EMTBT_FREE_NOBLK_ERROR); if (!ops[i].u.block.prev_ptr) continue; res = emtbt_free_op(crr_table, &ops[i], &old_blk); if (res != 0) ERR_RET(res); prev_size = old_blk.size; aix = (int) old_blk.type; if (state->info.allctr_usd_crr[aix]) update_free_op(state->info.allctr_usd_crr[aix], prev_size); if (state->info.allctr_prv_crr[crrix]) update_free_op(state->info.allctr_prv_crr[crrix], prev_size); update_free_op(&state->info.allctr[crrix], prev_size); break; case EMTP_STOP: #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif state->info.stop_reason = EMTP_STOP; state->info.stop_time.secs = ops[i].time.secs; state->info.stop_time.usecs = ops[i].time.usecs; print_info(state, ops[i].time.secs, NULL); return EM_EXIT_RESULT; case EMTP_EXIT: #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif state->info.stop_reason = EMTP_EXIT; state->info.exit_status = ops[i].u.exit_status; state->info.stop_time.secs = ops[i].time.secs; state->info.stop_time.usecs = ops[i].time.usecs; print_info(state, ops[i].time.secs, NULL); return EM_EXIT_RESULT; default: #if PRINT_OPERATIONS print_op(state, &ops[i]); #endif /* Ignore not understood operation */ break; } } return 0; } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * * * * \* */ static const char * error_string(int error) { const char *str; const char *error_str; static const char unknown_error[] = "Unknown error"; error_str = unknown_error; if (error > 0) { char *str = strerror(error); if (str) error_str = str; } else if (error < 0) { str = emtp_error_string(error); if (!str) { str = emtbt_error_string(error); if (!str) { switch (error) { case EM_TRUNCATED_TRACE_ERROR: error_str = "Truncated trace"; break; case EM_INTERNAL_ERROR: error_str = "emem internal error"; break; default: break; } } } if (str) error_str = str; } return error_str; } static void error(int res) { error_msg(res, NULL); } static void error_msg(int res, char *msg) { fprintf(stderr, "emem: %s%sFatal error: %s (%d)\n", msg ? msg : "", msg ? ": ": "", error_string(res), res); exit(1); } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * * * * \* */ #if EMEM_d_SWITCH static size_t write_output_filename(char *ptr, char *dirname, char *nodename, char *hostname, char *datetime, char *pid) { size_t sz = 0; char *p = ptr; char **pp = ptr ? &p : NULL; sz += write_str(pp, dirname); if (pp) *((*pp)++) = DIR_SEP_CHAR; sz++; sz += write_str(pp, nodename); sz += write_str(pp, "_"); sz += write_str(pp, hostname); sz += write_str(pp, "_"); sz += write_str(pp, datetime); sz += write_str(pp, "_"); sz += write_str(pp, pid); sz += write_str(pp, EM_OUTPUT_FILE_SUFFIX); if (pp) *((*pp)++) = '\0'; sz++; return sz; } static char * make_output_filename(em_state *state) { char *fname; size_t fname_size; char *nodename = state->trace_info.nodename; char *hostname = state->trace_info.hostname; char *pid = state->trace_info.pid; char dt_buf[20]; char *date_time = NULL; if (*nodename == '\0') nodename = "nonode"; if (*hostname == '\0') hostname = "nohost"; if (!state->trace_info.start_time.day) date_time = "notime"; else { sprintf(dt_buf, "%d-%2.2d-%2.2d_%2.2d.%2.2d.%2.2d", state->trace_info.start_time.year % 10000, state->trace_info.start_time.month % 100, state->trace_info.start_time.day % 100, state->trace_info.start_time.hour % 100, state->trace_info.start_time.minute % 100, state->trace_info.start_time.second % 100); date_time = &dt_buf[0]; } if (*pid == '\0') pid = "nopid"; fname = (*state->alloc)(write_output_filename(NULL, state->output.dir_name, nodename, hostname, date_time, pid)); if (!fname) return NULL; (void) write_output_filename(fname, state->output.dir_name, nodename, hostname, date_time, pid); return fname; } #endif static int complete_state(em_state *state) { int i, j, vpo, vpl; void * (*allocp)(size_t); void * (*reallocp)(void *, size_t); void (*freep)(void *); size_t size = sizeof(emtp_info); if (!emtp_get_info(&state->trace_info, &size, state->trace_state) || size < sizeof(emtp_info)) return EM_INTERNAL_ERROR; #if EMEM_d_SWITCH if (!state->output.stream) { char *fname = make_filename(state); mutex_lock(state->output.go.mutex); state->output.stream = fopen(fname, "w"); if (!state->output.stream) { disconnect_queue_reader(&state->input.queue); disconnect_queue_writer(&state->output.queue); } cond_signal(state->output.go.cond); mutex_unlock(state->output.go.mutex); (*state->free)((void *) fname); if (!state->output.stream) return EIO; } #endif allocp = state->alloc; reallocp = state->realloc; freep = state->free; state->carrier_table = (*allocp)((state->trace_info.max_allocator_ix+2) * sizeof(emtbt_table *)); if (!state->carrier_table) return ENOMEM; state->carrier_table++; for (i = -1; i <= state->trace_info.max_allocator_ix; i++) state->carrier_table[i] = NULL; state->block_table = mk_block_table(state); state->info.btype = (*allocp)((state->trace_info.max_block_type_ix+2) * sizeof(em_mem_info)); state->info.allctr = (*allocp)((state->trace_info.max_allocator_ix+2) * sizeof(em_mem_info)); if (!state->block_table || !state->info.btype || !state->info.allctr) return ENOMEM; state->info.btype++; state->info.allctr++; state->info.allctr_prv_crr = (*allocp)((state->trace_info.max_allocator_ix+2) * sizeof(em_mem_info *)); if (!state->info.allctr_prv_crr) return ENOMEM; state->info.allctr_prv_crr++; for (i = -1; i <= state->trace_info.max_allocator_ix; i++) state->info.allctr_prv_crr[i] = NULL; state->info.allctr_usd_crr = (*allocp)((state->trace_info.max_allocator_ix+2) * sizeof(em_mem_info *)); if (!state->info.allctr_usd_crr) return ENOMEM; state->info.allctr_usd_crr++; for (i = -1; i <= state->trace_info.max_allocator_ix; i++) state->info.allctr_usd_crr[i] = NULL; if (state->output.all_btypes) { if (state->output.btypes) (*state->free)((void *) state->output.btypes); state->output.no_btypes = state->trace_info.max_block_type_ix + 2; state->output.btypes = (*allocp)(state->output.no_btypes * sizeof(em_output_types)); if (!state->output.btypes) return ENOMEM; } if (state->output.all_allctrs) { if (state->output.allctrs) (*state->free)((void *) state->output.allctrs); state->output.no_allctrs = state->trace_info.max_allocator_ix + 2; state->output.allctrs = (*allocp)(state->output.no_allctrs * sizeof(em_output_types)); if (!state->output.allctrs) return ENOMEM; } for (i = -1; i <= state->trace_info.max_block_type_ix; i++) { /* Save block type if we should print info about it */ emtp_block_type *btp = state->trace_info.block_type[i]; reset_mem_info(&state->info.btype[i]); if (state->output.no_btypes) { if (state->output.all_btypes) { state->output.btypes[i+1].name = btp->name; state->output.btypes[i+1].ix = btp->valid ? i : -1; } else { for (j = 0; j < state->output.no_btypes; j++) if (strcmp(btp->name, state->output.btypes[j].name) == 0) { state->output.btypes[j].ix = i; break; } } } } /* Remove invalid block types */ if (state->output.no_btypes) { for (i = 0, j = 0; i < state->output.no_btypes; i++) { if (state->output.btypes[i].ix >= 0) { state->output.btypes[j].name = state->output.btypes[i].name; state->output.btypes[j].ix = state->output.btypes[i].ix; j++; } } state->output.no_btypes = j; } for (i = -1; i <= state->trace_info.max_allocator_ix; i++) { /* Save allocator if we should print info about it */ emtp_allocator *ap = state->trace_info.allocator[i]; reset_mem_info(&state->info.allctr[i]); if (state->output.no_allctrs) { if (state->output.all_allctrs) { state->output.allctrs[i+1].name = ap->name; state->output.allctrs[i+1].ix = ap->valid ? i : -1; } else { for (j = 0; j < state->output.no_allctrs; j++) if (strcmp(ap->name, state->output.allctrs[j].name) == 0) { state->output.allctrs[j].ix = i; break; } } } /* Allocate em_mem_info if used carrier info is available */ if (ap->flags & EMTP_ALLOCATOR_FLAG_HAVE_USED_CARRIERS_INFO || (i == state->trace_info.segment_ix && state->trace_info.have_segment_carrier_info)) { state->info.allctr_usd_crr[i] = (em_mem_info *) (*allocp)(sizeof(em_mem_info)); if (!state->info.allctr_usd_crr[i]) return ENOMEM; reset_mem_info(state->info.allctr_usd_crr[i]); } /* Allocate em_mem_info for carrier providers */ if (ap->carrier.provider) { sgnd_int_32 j; for (j = 0; j < ap->carrier.no_providers; j++) { sgnd_int_32 crr_prvdr = ap->carrier.provider[j]; if (!state->info.allctr_prv_crr[crr_prvdr]) { state->info.allctr_prv_crr[crr_prvdr] = (em_mem_info *) (*allocp)(sizeof(em_mem_info)); if (!state->info.allctr_prv_crr[crr_prvdr]) return ENOMEM; reset_mem_info(state->info.allctr_prv_crr[crr_prvdr]); } } } } /* Remove invalid allocators */ if (state->output.no_allctrs) { for (i = 0, j = 0; i < state->output.no_allctrs; i++) { if (state->output.allctrs[i].ix >= 0) { state->output.allctrs[j].name = state->output.allctrs[i].name; state->output.allctrs[j].ix = state->output.allctrs[i].ix; j++; } } state->output.no_allctrs = j; } if (state->output.no_btypes) { state->output.btypes = (*reallocp)(state->output.btypes, sizeof(em_output_types) * state->output.no_btypes); if (!state->output.btypes) return ENOMEM; } if (state->output.no_allctrs) { state->output.allctrs = (*reallocp)(state->output.allctrs, sizeof(em_output_types) * state->output.no_allctrs); if (!state->output.allctrs) return ENOMEM; } vpo = 1; if (state->output.max_min_values) vpo += 2; if (state->output.block_counts) { vpo++; if (state->output.max_min_values) vpo += 2; } if (state->output.op_counts) vpo += 3; state->output.values_per_object = vpo; vpl = 0; vpl++; /* time */ if (state->output.total) { vpl += vpo; /* total allocated */ if (state->trace_info.have_segment_carrier_info) { vpl += vpo; /* total carriers */ vpl += vpo; /* cached carriers */ } } for (i = 0; i < state->output.no_allctrs; i++) { vpl += vpo; /* allocated */ if (state->trace_info.have_carrier_info) { if (state->info.allctr_prv_crr[state->output.allctrs[i].ix]) vpl += vpo; /* provided carriers */ vpl += vpo; /* used carriers */ } } vpl += state->output.no_btypes*vpo; /* allocated */ state->output.values_per_line = vpl; state->output.header_size = write_header(state, NULL, 1); state->output.header = (*state->alloc)(state->output.header_size + 1); if (!state->output.header) return ENOMEM; size = write_header(state, state->output.header, 1); ASSERT(state->output.header_size == size); return 0; } static int process_trace(em_state *state) { emtp_operation ops[EM_NO_OF_OPS]; int res; size_t ops_len; em_area area; while (1) { get_next_read_area(&area, state, &state->input.queue); if (!area.size) return EM_TRUNCATED_TRACE_ERROR; res = emtp_parse(state->trace_state, (usgnd_int_8 **)&area.ptr, &area.size, NULL, 0, NULL); if (res == EMTP_HEADER_PARSED) break; if (res == EMTP_NEED_MORE_TRACE) continue; if (res < 0) return res; else return EM_TRUNCATED_TRACE_ERROR; } res = complete_state(state); if (res != 0) return res; print_main_header(state); while (1) { if (!area.size) { get_next_read_area(&area, state, &state->input.queue); if (!area.size) return EM_TRUNCATED_TRACE_ERROR; } while (area.size) { ops_len = EM_NO_OF_OPS; res = emtp_parse(state->trace_state, (usgnd_int_8 **)&area.ptr, &area.size, ops, sizeof(emtp_operation), &ops_len); if (res < 0) return res; res = insert_operations(state, ops, ops_len); if (res != 0) return res; } } } static void usage(char *sw, char *error) { int status = 0; FILE *filep = stdout; #ifdef __WIN32__ #define SW_CHAR "/" #else #define SW_CHAR "-" #endif if (error) { ASSERT(sw); status = 1; filep = stderr; fprintf(filep, "emem: %s: %s\n", sw, error); } fprintf(filep, "Usage: emem " #if EMEM_A_SWITCH "[" SW_CHAR "A ] " #endif "[" SW_CHAR "a ] " "[" SW_CHAR "b ] " #if EMEM_C_SWITCH "[" SW_CHAR "C ] " #endif #if EMEM_c_SWITCH "[" SW_CHAR "c ] " #endif "{" #if EMEM_d_SWITCH SW_CHAR "d |" #endif SW_CHAR "f } " "[" SW_CHAR "h] " "[" SW_CHAR "i ] " "[" SW_CHAR "m] " "[" SW_CHAR "n] " "[" SW_CHAR "o] " "{" SW_CHAR "p } " "[" SW_CHAR "t] " "[" SW_CHAR "v] " "\n"); if (error) exit(1); else { fprintf(filep, "\n" " [] - switch is allowed any number of times\n" " {} - switch is allowed at most one time\n" #if EMEM_d_SWITCH " | - exclusive or\n" #endif "\n" " Switches:\n" #if EMEM_A_SWITCH " " SW_CHAR "a - display info about Allocator and all block types using \n" #endif " " SW_CHAR "a - display info about allocator \n" " " SW_CHAR "b - display info about block type \n" #if EMEM_C_SWITCH " " SW_CHAR "C - display info about class and all block types in class \n" #endif #if EMEM_c_SWITCH " " SW_CHAR "b - display info about class \n" #endif #if EMEM_d_SWITCH " " SW_CHAR "d - run as daemon and set output directory to \n" #endif " " SW_CHAR "f - set output file to \n" " " SW_CHAR "h - display help and exit\n" " " SW_CHAR "i - set display interval to seconds\n" " " SW_CHAR "m - display max/min values\n" " " SW_CHAR "n - display block/carrier/segment count values\n" " " SW_CHAR "o - display operation count values\n" " " SW_CHAR "p

- set listen port to

\n" " " SW_CHAR "t - display info about total values\n" " " SW_CHAR "v - verbose output\n"); exit(0); } #undef SW_CHAR } static void parse_args(em_state *state, int argc, char *argv[]) { int port; int i; port = -1; i = 1; while (i < argc) { if ((argv[i][0] != '-' && argv[i][0] != '/') || argv[i][2] != '\0') { unknown_switch: usage(argv[i], "unknown switch"); } switch (argv[i][1]) { #if EMEM_A_SWITCH case 'A': /* TODO: Allocator + blocktypes using allocator */ #endif case 'a': if (i + 1 >= argc) usage(argv[i], "missing allocator"); i++; if (state->output.all_allctrs || strcmp(argv[i],"all") == 0) { state->output.all_allctrs = 1; break; } if (!state->output.allctrs) state->output.allctrs = (*state->alloc)(sizeof(em_output_types)*argc/2); if (!state->output.allctrs) error(ENOMEM); state->output.allctrs[state->output.no_allctrs].name = argv[i]; state->output.allctrs[state->output.no_allctrs].ix = -1; state->output.no_allctrs++; break; case 'b': if (i + 1 >= argc) usage(argv[i], "missing block type"); i++; if (state->output.all_btypes || strcmp(argv[i],"all") == 0) { state->output.all_btypes = 1; break; } if (!state->output.btypes) state->output.btypes = (*state->alloc)(sizeof(em_output_types)*argc/2); if (!state->output.btypes) error(ENOMEM); state->output.btypes[state->output.no_btypes].name = argv[i]; state->output.btypes[state->output.no_btypes].ix = -1; state->output.no_btypes++; break; #if EMEM_C_SWITCH #endif #if EMEM_c_SWITCH case 'c': break; #endif #if EMEM_d_SWITCH case 'd': { char *p; char *fname; if (state->output.dir_name) usage(argv[i], "directory already set"); if (state->output.file_name) usage(argv[i], "file name already set"); if (i + 1 >= argc) usage(argv[i], "missing directory name"); state->output.dir_name = argv[i+1]; fname = (*state->alloc)(strlen(state->output.dir_name) + 1 + strlen(EM_ERL_CMD_FILE_NAME) + 1); state->output.go.mutex = (*state->alloc)(sizeof(ethr_mutex)); state->output.go.cond = (*state->alloc)(sizeof(ethr_cond)); if (!fname || !state->output.go.mutex || !state->output.go.cond) error(ENOMEM); p = fname; (void) write_str(&p, state->output.dir_name); *(p++) = DIR_SEP_CHAR; (void) write_str(&p, EM_ERL_CMD_FILE_NAME); *(p++) = '\0'; state->output.erl_cmd_file = fopen(fname, "w"); if (!state->output.erl_cmd_file) usage(argv[i], "cannot create files in directory"); (*state->free)((void *) fname); state->output.stream = NULL; mutex_init(state->output.go.mutex); cond_init(state->output.go.cond); i++; break; } #endif case 'f': #if EMEM_d_SWITCH if (state->output.dir_name) usage(argv[i], "directory already set"); #endif if (state->output.file_name) usage(argv[i], "file name already set"); if (i + 1 >= argc) usage(argv[i], "missing file name"); state->output.file_name = argv[i+1]; state->output.stream = fopen(state->output.file_name, "w"); if (!state->output.stream) usage(argv[i], "cannot create file"); if (setvbuf(state->output.stream, NULL, _IONBF, 0) != 0) { fprintf(stderr, "emem: failed to set file %s in unbuffered mode\n", state->output.file_name); exit(1); } i++; break; case 'h': usage(NULL, NULL); break; case 'i': { int interval; if (argv[i][2]) goto unknown_switch; if (i + 1 >= argc) usage(argv[i], "missing interval"); interval = atoi(argv[i+1]); if (interval < 1) usage(argv[i], "bad interval"); i++; state->output.next_print_inc = interval; break; } case 'm': state->output.max_min_values = 1; break; case 'n': state->output.block_counts = 1; break; case 'o': state->output.op_counts = 1; break; case 'p': if (state->input.listen_port) usage(argv[i], "port already set"); if (i + 1 >= argc) usage(argv[i], "missing port number"); port = atoi(argv[i+1]); if (port <= 1024 || port >= (1 << 16)) usage(argv[i], "bad port number"); i++; state->input.listen_port = (usgnd_int_16) port; break; case 't': state->output.total = 1; break; case 'v': state->output.verbose = 1; break; default: goto unknown_switch; } i++; } if (!state->output.allctrs && !state->output.btypes) state->output.total = 1; } static int init_connection(em_state *state) { int res; SOCKET lsock; SOCKET sock = INVALID_SOCKET; struct sockaddr_in my_addr; socklen_t oth_addr_len; struct sockaddr_in oth_addr; #ifdef __WIN32__ WORD wVersionRequested = MAKEWORD(2,0); WSADATA wsaData; if (WSAStartup(wVersionRequested, &wsaData) != 0) return EIO; if ((LOBYTE(wsaData.wVersion) != 2) || (HIBYTE(wsaData.wVersion) != 0)) return EIO; #endif do_socket: sock = socket(AF_INET, SOCK_STREAM, 0); if (IS_INVALID_SOCKET(sock)) { res = GET_SOCK_ERRNO(); if (res == EINTR) goto do_socket; goto error; } memset((void *) &my_addr, 0, sizeof(struct sockaddr_in)); my_addr.sin_family = AF_INET; my_addr.sin_addr.s_addr = htonl(INADDR_ANY); my_addr.sin_port = htons(state->input.listen_port); do_bind: if (bind(sock, (struct sockaddr*) &my_addr, sizeof(my_addr)) < 0) { res = GET_SOCK_ERRNO(); if (res == EINTR) goto do_bind; goto error; } do_listen: if (listen(sock, 1) < 0) { res = GET_SOCK_ERRNO(); if (res == EINTR) goto do_listen; goto error; } lsock = sock; state->input.socket = sock; res = print_emu_arg(state); if (res != 0) goto error; print_string(state, "> Waiting for emulator to connect... "); do_accept: oth_addr_len = sizeof(oth_addr); sock = accept(lsock, (struct sockaddr *) &oth_addr, &oth_addr_len); if (IS_INVALID_SOCKET(sock)) { res = GET_SOCK_ERRNO(); if (res == EINTR) goto do_accept; sock = lsock; goto error; } print_string(state, "connected\n"); closesocket(lsock); state->input.socket = sock; return 0; error: if (!IS_INVALID_SOCKET(sock)) { closesocket(sock); state->input.socket = INVALID_SOCKET; } return res; } /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\ * IO threads * * * \* */ /* * The input thread reads from a socket and puts the received data * in the input buffer queue. * * Note: There is intentionally no flow control. If the emem program * cannot process data as fast as it arrives, it is supposed * to crash when hitting the maximum buffersize; otherwise, * the traced emulator would be slowed down. */ static void * input_thread_func(void *arg) { int res; char *edescr = NULL; ssize_t recv_sz; usgnd_int_max total_trace_size = 0; em_state *state = (em_state *) arg; em_area area = {NULL, 0}; SOCKET sock = state->input.socket; em_buf_queue *queue = &state->input.queue; while(1) { get_next_write_area(&area, state, queue, EM_MIN_TRACE_READ_SIZE); if (!area.ptr) { res = ENOMEM; edescr = "Input alloc"; goto stop; } do_recv: if (is_queue_reader_disconnected(queue)) { res = 0; edescr = "Input"; goto stop; } recv_sz = recv(sock, (void *) area.ptr, area.size, 0); if (recv_sz <= 0) { res = GET_SOCK_ERRNO(); if (res == EINTR) goto do_recv; edescr = "Input recv"; goto stop; } area.size = (size_t) recv_sz; total_trace_size += (usgnd_int_max) recv_sz; } stop: state->input.error = res; state->input.error_descr = edescr; state->input.total_trace_size = total_trace_size; disconnect_queue_writer(queue); if (!IS_INVALID_SOCKET(state->input.socket)) { closesocket(sock); state->input.socket = INVALID_SOCKET; } return NULL; } static void * output_thread_func(void *arg) { em_state *state = (em_state *) arg; em_area area = {NULL, 0}; #if EMEM_d_SWITCH if (state->output.go.mutex) { mutex_lock(state->output.go.mutex); while (!state->output.stream && !is_queue_writer_disconnected(&state->output.queue)) cond_wait(state->output.go.cond, state->output.go.mutex); mutex_unlock(state->output.go.mutex); mutex_destroy(state->output.go.mutex); (*state->free)((void *) state->output.go.mutex); state->output.go.mutex = NULL; cond_destroy(state->output.go.cond); (*state->free)((void *) state->output.go.cond); state->output.go.cond = NULL; } #endif while (1) { get_next_read_area(&area, state, &state->output.queue); if (!area.size) { disconnect_queue_reader(&state->output.queue); if (is_queue_writer_disconnected(&state->output.queue)) goto stop; else error_msg(EIO, "Output queue"); } if (fwrite((void *) area.ptr, sizeof(char), area.size, state->output.stream) != area.size) { disconnect_queue_reader(&state->output.queue); error_msg(0, "Write"); } } stop: if (state->output.stream != stdout && state->output.stream != stderr) fclose(state->output.stream); return NULL; } int main(int argc, char *argv[]) { int res, ires, jres; ethr_tid input_tid; ethr_tid output_tid; em_state *state; /* set stdout in unbuffered mode */ if (setvbuf(stdout, NULL, _IONBF, 0) != 0) { fprintf(stderr, "emem: failed to set stdout in unbuffered mode\n"); exit(1); } if (ethr_init(NULL) != 0 || ethr_late_init(NULL) != 0) { fprintf(stderr, "emem: failed to initialize thread package\n"); exit(1); } state = new_state(malloc, realloc, free); if (!state) error(ENOMEM); parse_args(state, argc, argv); res = ethr_thr_create(&output_tid, output_thread_func, (void *) state, NULL); if (res != 0) error_msg(res, "Output thread create"); #ifdef DEBUG print_string(state, "> [debug]\n"); #endif #ifdef PURIFY print_string(state, "> [purify]\n"); #endif #ifdef QUANTIFY print_string(state, "> [quantify]\n"); #endif #ifdef PURECOV print_string(state, "> [purecov]\n"); #endif res = init_connection(state); if (res != 0) error_msg(res, "Initialize connection"); res = ethr_thr_create(&input_tid, input_thread_func, (void *) state, NULL); if (res != 0) error_msg(res, "Input thread create"); res = process_trace(state); disconnect_queue_reader(&state->input.queue); jres = ethr_thr_join(input_tid, NULL); if (jres != 0) error_msg(jres, "Input thread join"); if (res == EM_EXIT_RESULT) print_main_footer(state); disconnect_queue_writer(&state->output.queue); jres = ethr_thr_join(output_tid, NULL); if (jres != 0) error_msg(jres, "Output thread join"); ires = state->input.error; destroy_state(state); #ifdef __WIN32__ WSACleanup(); #endif switch (res) { case EM_EXIT_RESULT: res = 0; break; case EM_TRUNCATED_TRACE_ERROR: error_msg(ires, state->input.error_descr); break; default: error(res); break; } return 0; } #if PRINT_OPERATIONS void print_op(em_state *state, emtp_operation *op) { #if 0 printf("%5" USGND_INT_32_FSTR ":%6.6" USGND_INT_32_FSTR " ", op->time.secs, op->time.usecs); #endif if (state->trace_info.version.parser.major >= 2) { switch (op->type) { case EMTP_ALLOC: printf(" %" USGND_INT_MAX_FSTR " = alloc(%" USGND_INT_16_FSTR ", %" USGND_INT_MAX_FSTR ")\n", op->u.block.new_ptr, op->u.block.type, op->u.block.new_size); break; case EMTP_REALLOC: printf(" %" USGND_INT_MAX_FSTR " = realloc(%" USGND_INT_16_FSTR ", %" USGND_INT_MAX_FSTR ", %" USGND_INT_MAX_FSTR ")\n", op->u.block.new_ptr, op->u.block.type, op->u.block.prev_ptr, op->u.block.new_size); break; case EMTP_FREE: printf(" free(%" USGND_INT_16_FSTR ", %" USGND_INT_MAX_FSTR ")" "\n", op->u.block.type, op->u.block.prev_ptr); break; case EMTP_CARRIER_ALLOC: printf(" %" USGND_INT_MAX_FSTR " = carrier_alloc(%" USGND_INT_16_FSTR ", %" USGND_INT_16_FSTR ", %" USGND_INT_MAX_FSTR ")\n", op->u.block.new_ptr, op->u.block.carrier_type, op->u.block.type, op->u.block.new_size); break; case EMTP_CARRIER_REALLOC: printf(" %" USGND_INT_MAX_FSTR " = carrier_realloc(%" USGND_INT_16_FSTR ", %" USGND_INT_16_FSTR ", %" USGND_INT_MAX_FSTR ", %" USGND_INT_MAX_FSTR ")\n", op->u.block.new_ptr, op->u.block.carrier_type, op->u.block.type, op->u.block.prev_ptr, op->u.block.new_size); case EMTP_CARRIER_FREE: printf(" carrier_free(%" USGND_INT_16_FSTR ", %" USGND_INT_16_FSTR ", %" USGND_INT_MAX_FSTR ")\n", op->u.block.carrier_type, op->u.block.type, op->u.block.prev_ptr); break; default: printf(" op = %d\n", op->type); break; } } else { switch (op->type) { case EMTP_ALLOC: printf(" %" USGND_INT_MAX_FSTR " = alloc(%" USGND_INT_MAX_FSTR ")" "\n", op->u.block.new_ptr, op->u.block.new_size); break; case EMTP_REALLOC: printf(" %" USGND_INT_MAX_FSTR " = realloc(%" USGND_INT_MAX_FSTR ", %" USGND_INT_MAX_FSTR ")\n", op->u.block.new_ptr, op->u.block.prev_ptr, op->u.block.new_size); break; case EMTP_FREE: printf(" free(%" USGND_INT_MAX_FSTR ")\n", op->u.block.prev_ptr); break; default: printf(" op = %d\n", op->type); break; } } fflush(stdout); } #endif