/* * * Copyright 2016 gRPC authors. * * 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. * */ #include #include "src/core/lib/iomgr/error.h" #include #include #include #include #include #include #ifdef GPR_WINDOWS #include #endif #include "src/core/lib/debug/trace.h" #include "src/core/lib/gpr/useful.h" #include "src/core/lib/iomgr/error_internal.h" #include "src/core/lib/profiling/timers.h" #include "src/core/lib/slice/slice_internal.h" grpc_core::DebugOnlyTraceFlag grpc_trace_error_refcount(false, "error_refcount"); grpc_core::DebugOnlyTraceFlag grpc_trace_closure(false, "closure"); static const char* error_int_name(grpc_error_ints key) { switch (key) { case GRPC_ERROR_INT_ERRNO: return "errno"; case GRPC_ERROR_INT_FILE_LINE: return "file_line"; case GRPC_ERROR_INT_STREAM_ID: return "stream_id"; case GRPC_ERROR_INT_GRPC_STATUS: return "grpc_status"; case GRPC_ERROR_INT_OFFSET: return "offset"; case GRPC_ERROR_INT_INDEX: return "index"; case GRPC_ERROR_INT_SIZE: return "size"; case GRPC_ERROR_INT_HTTP2_ERROR: return "http2_error"; case GRPC_ERROR_INT_TSI_CODE: return "tsi_code"; case GRPC_ERROR_INT_SECURITY_STATUS: return "security_status"; case GRPC_ERROR_INT_FD: return "fd"; case GRPC_ERROR_INT_WSA_ERROR: return "wsa_error"; case GRPC_ERROR_INT_HTTP_STATUS: return "http_status"; case GRPC_ERROR_INT_LIMIT: return "limit"; case GRPC_ERROR_INT_OCCURRED_DURING_WRITE: return "occurred_during_write"; case GRPC_ERROR_INT_CHANNEL_CONNECTIVITY_STATE: return "channel_connectivity_state"; case GRPC_ERROR_INT_MAX: GPR_UNREACHABLE_CODE(return "unknown"); } GPR_UNREACHABLE_CODE(return "unknown"); } static const char* error_str_name(grpc_error_strs key) { switch (key) { case GRPC_ERROR_STR_KEY: return "key"; case GRPC_ERROR_STR_VALUE: return "value"; case GRPC_ERROR_STR_DESCRIPTION: return "description"; case GRPC_ERROR_STR_OS_ERROR: return "os_error"; case GRPC_ERROR_STR_TARGET_ADDRESS: return "target_address"; case GRPC_ERROR_STR_SYSCALL: return "syscall"; case GRPC_ERROR_STR_FILE: return "file"; case GRPC_ERROR_STR_GRPC_MESSAGE: return "grpc_message"; case GRPC_ERROR_STR_RAW_BYTES: return "raw_bytes"; case GRPC_ERROR_STR_TSI_ERROR: return "tsi_error"; case GRPC_ERROR_STR_FILENAME: return "filename"; case GRPC_ERROR_STR_QUEUED_BUFFERS: return "queued_buffers"; case GRPC_ERROR_STR_MAX: GPR_UNREACHABLE_CODE(return "unknown"); } GPR_UNREACHABLE_CODE(return "unknown"); } static const char* error_time_name(grpc_error_times key) { switch (key) { case GRPC_ERROR_TIME_CREATED: return "created"; case GRPC_ERROR_TIME_MAX: GPR_UNREACHABLE_CODE(return "unknown"); } GPR_UNREACHABLE_CODE(return "unknown"); } #ifndef NDEBUG grpc_error* grpc_error_do_ref(grpc_error* err, const char* file, int line) { if (grpc_trace_error_refcount.enabled()) { gpr_log(GPR_DEBUG, "%p: %" PRIdPTR " -> %" PRIdPTR " [%s:%d]", err, gpr_atm_no_barrier_load(&err->atomics.refs.count), gpr_atm_no_barrier_load(&err->atomics.refs.count) + 1, file, line); } gpr_ref(&err->atomics.refs); return err; } #else grpc_error* grpc_error_do_ref(grpc_error* err) { gpr_ref(&err->atomics.refs); return err; } #endif static void unref_errs(grpc_error* err) { uint8_t slot = err->first_err; while (slot != UINT8_MAX) { grpc_linked_error* lerr = reinterpret_cast(err->arena + slot); GRPC_ERROR_UNREF(lerr->err); GPR_ASSERT(err->last_err == slot ? lerr->next == UINT8_MAX : lerr->next != UINT8_MAX); slot = lerr->next; } } static void unref_strs(grpc_error* err) { for (size_t which = 0; which < GRPC_ERROR_STR_MAX; ++which) { uint8_t slot = err->strs[which]; if (slot != UINT8_MAX) { grpc_slice_unref_internal( *reinterpret_cast(err->arena + slot)); } } } static void error_destroy(grpc_error* err) { GPR_ASSERT(!grpc_error_is_special(err)); unref_errs(err); unref_strs(err); gpr_free((void*)gpr_atm_acq_load(&err->atomics.error_string)); gpr_free(err); } #ifndef NDEBUG void grpc_error_do_unref(grpc_error* err, const char* file, int line) { if (grpc_trace_error_refcount.enabled()) { gpr_log(GPR_DEBUG, "%p: %" PRIdPTR " -> %" PRIdPTR " [%s:%d]", err, gpr_atm_no_barrier_load(&err->atomics.refs.count), gpr_atm_no_barrier_load(&err->atomics.refs.count) - 1, file, line); } if (gpr_unref(&err->atomics.refs)) { error_destroy(err); } } #else void grpc_error_do_unref(grpc_error* err) { if (gpr_unref(&err->atomics.refs)) { error_destroy(err); } } #endif static uint8_t get_placement(grpc_error** err, size_t size) { GPR_ASSERT(*err); uint8_t slots = static_cast(size / sizeof(intptr_t)); if ((*err)->arena_size + slots > (*err)->arena_capacity) { (*err)->arena_capacity = static_cast GPR_MIN( UINT8_MAX - 1, (3 * (*err)->arena_capacity / 2)); if ((*err)->arena_size + slots > (*err)->arena_capacity) { return UINT8_MAX; } #ifndef NDEBUG grpc_error* orig = *err; #endif *err = static_cast(gpr_realloc( *err, sizeof(grpc_error) + (*err)->arena_capacity * sizeof(intptr_t))); #ifndef NDEBUG if (grpc_trace_error_refcount.enabled()) { if (*err != orig) { gpr_log(GPR_DEBUG, "realloc %p -> %p", orig, *err); } } #endif } uint8_t placement = (*err)->arena_size; (*err)->arena_size = static_cast((*err)->arena_size + slots); return placement; } static void internal_set_int(grpc_error** err, grpc_error_ints which, intptr_t value) { uint8_t slot = (*err)->ints[which]; if (slot == UINT8_MAX) { slot = get_placement(err, sizeof(value)); if (slot == UINT8_MAX) { gpr_log(GPR_ERROR, "Error %p is full, dropping int {\"%s\":%" PRIiPTR "}", *err, error_int_name(which), value); return; } } (*err)->ints[which] = slot; (*err)->arena[slot] = value; } static void internal_set_str(grpc_error** err, grpc_error_strs which, const grpc_slice& value) { uint8_t slot = (*err)->strs[which]; if (slot == UINT8_MAX) { slot = get_placement(err, sizeof(value)); if (slot == UINT8_MAX) { const char* str = grpc_slice_to_c_string(value); gpr_log(GPR_ERROR, "Error %p is full, dropping string {\"%s\":\"%s\"}", *err, error_str_name(which), str); gpr_free((void*)str); return; } } else { grpc_slice_unref_internal( *reinterpret_cast((*err)->arena + slot)); } (*err)->strs[which] = slot; memcpy((*err)->arena + slot, &value, sizeof(value)); } static char* fmt_time(gpr_timespec tm); static void internal_set_time(grpc_error** err, grpc_error_times which, gpr_timespec value) { uint8_t slot = (*err)->times[which]; if (slot == UINT8_MAX) { slot = get_placement(err, sizeof(value)); if (slot == UINT8_MAX) { const char* time_str = fmt_time(value); gpr_log(GPR_ERROR, "Error %p is full, dropping \"%s\":\"%s\"}", *err, error_time_name(which), time_str); gpr_free((void*)time_str); return; } } (*err)->times[which] = slot; memcpy((*err)->arena + slot, &value, sizeof(value)); } static void internal_add_error(grpc_error** err, grpc_error* new_err) { grpc_linked_error new_last = {new_err, UINT8_MAX}; uint8_t slot = get_placement(err, sizeof(grpc_linked_error)); if (slot == UINT8_MAX) { gpr_log(GPR_ERROR, "Error %p is full, dropping error %p = %s", *err, new_err, grpc_error_string(new_err)); GRPC_ERROR_UNREF(new_err); return; } if ((*err)->first_err == UINT8_MAX) { GPR_ASSERT((*err)->last_err == UINT8_MAX); (*err)->last_err = slot; (*err)->first_err = slot; } else { GPR_ASSERT((*err)->last_err != UINT8_MAX); grpc_linked_error* old_last = reinterpret_cast((*err)->arena + (*err)->last_err); old_last->next = slot; (*err)->last_err = slot; } memcpy((*err)->arena + slot, &new_last, sizeof(grpc_linked_error)); } #define SLOTS_PER_INT (sizeof(intptr_t) / sizeof(intptr_t)) #define SLOTS_PER_STR (sizeof(grpc_slice) / sizeof(intptr_t)) #define SLOTS_PER_TIME (sizeof(gpr_timespec) / sizeof(intptr_t)) #define SLOTS_PER_LINKED_ERROR (sizeof(grpc_linked_error) / sizeof(intptr_t)) // size of storing one int and two slices and a timespec. For line, desc, file, // and time created #define DEFAULT_ERROR_CAPACITY \ (SLOTS_PER_INT + (SLOTS_PER_STR * 2) + SLOTS_PER_TIME) // It is very common to include and extra int and string in an error #define SURPLUS_CAPACITY (2 * SLOTS_PER_INT + SLOTS_PER_TIME) static gpr_atm g_error_creation_allowed = true; void grpc_disable_error_creation() { gpr_atm_no_barrier_store(&g_error_creation_allowed, false); } void grpc_enable_error_creation() { gpr_atm_no_barrier_store(&g_error_creation_allowed, true); } grpc_error* grpc_error_create(const char* file, int line, const grpc_slice& desc, grpc_error** referencing, size_t num_referencing) { GPR_TIMER_SCOPE("grpc_error_create", 0); uint8_t initial_arena_capacity = static_cast( DEFAULT_ERROR_CAPACITY + static_cast(num_referencing * SLOTS_PER_LINKED_ERROR) + SURPLUS_CAPACITY); grpc_error* err = static_cast( gpr_malloc(sizeof(*err) + initial_arena_capacity * sizeof(intptr_t))); if (err == nullptr) { // TODO(ctiller): make gpr_malloc return NULL return GRPC_ERROR_OOM; } #ifndef NDEBUG if (!gpr_atm_no_barrier_load(&g_error_creation_allowed)) { gpr_log(GPR_ERROR, "Error creation occurred when error creation was disabled [%s:%d]", file, line); abort(); } if (grpc_trace_error_refcount.enabled()) { gpr_log(GPR_DEBUG, "%p create [%s:%d]", err, file, line); } #endif err->arena_size = 0; err->arena_capacity = initial_arena_capacity; err->first_err = UINT8_MAX; err->last_err = UINT8_MAX; memset(err->ints, UINT8_MAX, GRPC_ERROR_INT_MAX); memset(err->strs, UINT8_MAX, GRPC_ERROR_STR_MAX); memset(err->times, UINT8_MAX, GRPC_ERROR_TIME_MAX); internal_set_int(&err, GRPC_ERROR_INT_FILE_LINE, line); internal_set_str(&err, GRPC_ERROR_STR_FILE, grpc_slice_from_static_string(file)); internal_set_str(&err, GRPC_ERROR_STR_DESCRIPTION, desc); for (size_t i = 0; i < num_referencing; ++i) { if (referencing[i] == GRPC_ERROR_NONE) continue; internal_add_error( &err, GRPC_ERROR_REF( referencing[i])); // TODO(ncteisen), change ownership semantics } internal_set_time(&err, GRPC_ERROR_TIME_CREATED, gpr_now(GPR_CLOCK_REALTIME)); gpr_atm_no_barrier_store(&err->atomics.error_string, 0); gpr_ref_init(&err->atomics.refs, 1); return err; } static void ref_strs(grpc_error* err) { for (size_t i = 0; i < GRPC_ERROR_STR_MAX; ++i) { uint8_t slot = err->strs[i]; if (slot != UINT8_MAX) { grpc_slice_ref_internal( *reinterpret_cast(err->arena + slot)); } } } static void ref_errs(grpc_error* err) { uint8_t slot = err->first_err; while (slot != UINT8_MAX) { grpc_linked_error* lerr = reinterpret_cast(err->arena + slot); GRPC_ERROR_REF(lerr->err); slot = lerr->next; } } static grpc_error* copy_error_and_unref(grpc_error* in) { GPR_TIMER_SCOPE("copy_error_and_unref", 0); grpc_error* out; if (grpc_error_is_special(in)) { out = GRPC_ERROR_CREATE_FROM_STATIC_STRING("unknown"); if (in == GRPC_ERROR_NONE) { internal_set_str(&out, GRPC_ERROR_STR_DESCRIPTION, grpc_slice_from_static_string("no error")); internal_set_int(&out, GRPC_ERROR_INT_GRPC_STATUS, GRPC_STATUS_OK); } else if (in == GRPC_ERROR_OOM) { internal_set_str(&out, GRPC_ERROR_STR_DESCRIPTION, grpc_slice_from_static_string("oom")); } else if (in == GRPC_ERROR_CANCELLED) { internal_set_str(&out, GRPC_ERROR_STR_DESCRIPTION, grpc_slice_from_static_string("cancelled")); internal_set_int(&out, GRPC_ERROR_INT_GRPC_STATUS, GRPC_STATUS_CANCELLED); } } else if (gpr_ref_is_unique(&in->atomics.refs)) { out = in; } else { uint8_t new_arena_capacity = in->arena_capacity; // the returned err will be added to, so we ensure this is room to avoid // unneeded allocations. if (in->arena_capacity - in->arena_size < static_cast SLOTS_PER_STR) { new_arena_capacity = static_cast(3 * new_arena_capacity / 2); } out = static_cast( gpr_malloc(sizeof(*in) + new_arena_capacity * sizeof(intptr_t))); #ifndef NDEBUG if (grpc_trace_error_refcount.enabled()) { gpr_log(GPR_DEBUG, "%p create copying %p", out, in); } #endif // bulk memcpy of the rest of the struct. size_t skip = sizeof(&out->atomics); memcpy((void*)((uintptr_t)out + skip), (void*)((uintptr_t)in + skip), sizeof(*in) + (in->arena_size * sizeof(intptr_t)) - skip); // manually set the atomics and the new capacity gpr_atm_no_barrier_store(&out->atomics.error_string, 0); gpr_ref_init(&out->atomics.refs, 1); out->arena_capacity = new_arena_capacity; ref_strs(out); ref_errs(out); GRPC_ERROR_UNREF(in); } return out; } grpc_error* grpc_error_set_int(grpc_error* src, grpc_error_ints which, intptr_t value) { GPR_TIMER_SCOPE("grpc_error_set_int", 0); grpc_error* new_err = copy_error_and_unref(src); internal_set_int(&new_err, which, value); return new_err; } typedef struct { grpc_status_code code; const char* msg; size_t len; } special_error_status_map; const special_error_status_map error_status_map[] = { {GRPC_STATUS_OK, "", 0}, // GRPC_ERROR_NONE {GRPC_STATUS_INVALID_ARGUMENT, "", 0}, // GRPC_ERROR_RESERVED_1 {GRPC_STATUS_RESOURCE_EXHAUSTED, "Out of memory", strlen("Out of memory")}, // GRPC_ERROR_OOM {GRPC_STATUS_INVALID_ARGUMENT, "", 0}, // GRPC_ERROR_RESERVED_2 {GRPC_STATUS_CANCELLED, "Cancelled", strlen("Cancelled")}, // GRPC_ERROR_CANCELLED }; bool grpc_error_get_int(grpc_error* err, grpc_error_ints which, intptr_t* p) { GPR_TIMER_SCOPE("grpc_error_get_int", 0); if (grpc_error_is_special(err)) { if (which != GRPC_ERROR_INT_GRPC_STATUS) return false; *p = error_status_map[reinterpret_cast(err)].code; return true; } uint8_t slot = err->ints[which]; if (slot != UINT8_MAX) { if (p != nullptr) *p = err->arena[slot]; return true; } return false; } grpc_error* grpc_error_set_str(grpc_error* src, grpc_error_strs which, const grpc_slice& str) { GPR_TIMER_SCOPE("grpc_error_set_str", 0); grpc_error* new_err = copy_error_and_unref(src); internal_set_str(&new_err, which, str); return new_err; } bool grpc_error_get_str(grpc_error* err, grpc_error_strs which, grpc_slice* str) { if (grpc_error_is_special(err)) { if (which != GRPC_ERROR_STR_GRPC_MESSAGE) return false; const special_error_status_map& msg = error_status_map[reinterpret_cast(err)]; str->refcount = &grpc_core::kNoopRefcount; str->data.refcounted.bytes = reinterpret_cast(const_cast(msg.msg)); str->data.refcounted.length = msg.len; return true; } uint8_t slot = err->strs[which]; if (slot != UINT8_MAX) { *str = *reinterpret_cast(err->arena + slot); return true; } else { return false; } } grpc_error* grpc_error_add_child(grpc_error* src, grpc_error* child) { GPR_TIMER_SCOPE("grpc_error_add_child", 0); if (src != GRPC_ERROR_NONE) { if (child == GRPC_ERROR_NONE) { /* \a child is empty. Simply return the ref to \a src */ return src; } else if (child != src) { grpc_error* new_err = copy_error_and_unref(src); internal_add_error(&new_err, child); return new_err; } else { /* \a src and \a child are the same. Drop one of the references and return * the other */ GRPC_ERROR_UNREF(child); return src; } } else { /* \a src is empty. Simply return the ref to \a child */ return child; } } static const char* no_error_string = "\"No Error\""; static const char* oom_error_string = "\"Out of memory\""; static const char* cancelled_error_string = "\"Cancelled\""; typedef struct { char* key; char* value; } kv_pair; typedef struct { kv_pair* kvs; size_t num_kvs; size_t cap_kvs; } kv_pairs; static void append_chr(char c, char** s, size_t* sz, size_t* cap) { if (*sz == *cap) { *cap = GPR_MAX(8, 3 * *cap / 2); *s = static_cast(gpr_realloc(*s, *cap)); } (*s)[(*sz)++] = c; } static void append_str(const char* str, char** s, size_t* sz, size_t* cap) { for (const char* c = str; *c; c++) { append_chr(*c, s, sz, cap); } } static void append_esc_str(const uint8_t* str, size_t len, char** s, size_t* sz, size_t* cap) { static const char* hex = "0123456789abcdef"; append_chr('"', s, sz, cap); for (size_t i = 0; i < len; i++, str++) { if (*str < 32 || *str >= 127) { append_chr('\\', s, sz, cap); switch (*str) { case '\b': append_chr('b', s, sz, cap); break; case '\f': append_chr('f', s, sz, cap); break; case '\n': append_chr('n', s, sz, cap); break; case '\r': append_chr('r', s, sz, cap); break; case '\t': append_chr('t', s, sz, cap); break; default: append_chr('u', s, sz, cap); append_chr('0', s, sz, cap); append_chr('0', s, sz, cap); append_chr(hex[*str >> 4], s, sz, cap); append_chr(hex[*str & 0x0f], s, sz, cap); break; } } else { append_chr(static_cast(*str), s, sz, cap); } } append_chr('"', s, sz, cap); } static void append_kv(kv_pairs* kvs, char* key, char* value) { if (kvs->num_kvs == kvs->cap_kvs) { kvs->cap_kvs = GPR_MAX(3 * kvs->cap_kvs / 2, 4); kvs->kvs = static_cast( gpr_realloc(kvs->kvs, sizeof(*kvs->kvs) * kvs->cap_kvs)); } kvs->kvs[kvs->num_kvs].key = key; kvs->kvs[kvs->num_kvs].value = value; kvs->num_kvs++; } static char* key_int(grpc_error_ints which) { return gpr_strdup(error_int_name(which)); } static char* fmt_int(intptr_t p) { char* s; gpr_asprintf(&s, "%" PRIdPTR, p); return s; } static void collect_ints_kvs(grpc_error* err, kv_pairs* kvs) { for (size_t which = 0; which < GRPC_ERROR_INT_MAX; ++which) { uint8_t slot = err->ints[which]; if (slot != UINT8_MAX) { append_kv(kvs, key_int(static_cast(which)), fmt_int(err->arena[slot])); } } } static char* key_str(grpc_error_strs which) { return gpr_strdup(error_str_name(which)); } static char* fmt_str(const grpc_slice& slice) { char* s = nullptr; size_t sz = 0; size_t cap = 0; append_esc_str((const uint8_t*)GRPC_SLICE_START_PTR(slice), GRPC_SLICE_LENGTH(slice), &s, &sz, &cap); append_chr(0, &s, &sz, &cap); return s; } static void collect_strs_kvs(grpc_error* err, kv_pairs* kvs) { for (size_t which = 0; which < GRPC_ERROR_STR_MAX; ++which) { uint8_t slot = err->strs[which]; if (slot != UINT8_MAX) { append_kv(kvs, key_str(static_cast(which)), fmt_str(*reinterpret_cast(err->arena + slot))); } } } static char* key_time(grpc_error_times which) { return gpr_strdup(error_time_name(which)); } static char* fmt_time(gpr_timespec tm) { char* out; const char* pfx = "!!"; switch (tm.clock_type) { case GPR_CLOCK_MONOTONIC: pfx = "@monotonic:"; break; case GPR_CLOCK_REALTIME: pfx = "@"; break; case GPR_CLOCK_PRECISE: pfx = "@precise:"; break; case GPR_TIMESPAN: pfx = ""; break; } gpr_asprintf(&out, "\"%s%" PRId64 ".%09d\"", pfx, tm.tv_sec, tm.tv_nsec); return out; } static void collect_times_kvs(grpc_error* err, kv_pairs* kvs) { for (size_t which = 0; which < GRPC_ERROR_TIME_MAX; ++which) { uint8_t slot = err->times[which]; if (slot != UINT8_MAX) { append_kv(kvs, key_time(static_cast(which)), fmt_time(*reinterpret_cast(err->arena + slot))); } } } static void add_errs(grpc_error* err, char** s, size_t* sz, size_t* cap) { uint8_t slot = err->first_err; bool first = true; while (slot != UINT8_MAX) { grpc_linked_error* lerr = reinterpret_cast(err->arena + slot); if (!first) append_chr(',', s, sz, cap); first = false; const char* e = grpc_error_string(lerr->err); append_str(e, s, sz, cap); GPR_ASSERT(err->last_err == slot ? lerr->next == UINT8_MAX : lerr->next != UINT8_MAX); slot = lerr->next; } } static char* errs_string(grpc_error* err) { char* s = nullptr; size_t sz = 0; size_t cap = 0; append_chr('[', &s, &sz, &cap); add_errs(err, &s, &sz, &cap); append_chr(']', &s, &sz, &cap); append_chr(0, &s, &sz, &cap); return s; } static int cmp_kvs(const void* a, const void* b) { const kv_pair* ka = static_cast(a); const kv_pair* kb = static_cast(b); return strcmp(ka->key, kb->key); } static char* finish_kvs(kv_pairs* kvs) { char* s = nullptr; size_t sz = 0; size_t cap = 0; append_chr('{', &s, &sz, &cap); for (size_t i = 0; i < kvs->num_kvs; i++) { if (i != 0) append_chr(',', &s, &sz, &cap); append_esc_str(reinterpret_cast(kvs->kvs[i].key), strlen(kvs->kvs[i].key), &s, &sz, &cap); gpr_free(kvs->kvs[i].key); append_chr(':', &s, &sz, &cap); append_str(kvs->kvs[i].value, &s, &sz, &cap); gpr_free(kvs->kvs[i].value); } append_chr('}', &s, &sz, &cap); append_chr(0, &s, &sz, &cap); gpr_free(kvs->kvs); return s; } const char* grpc_error_string(grpc_error* err) { GPR_TIMER_SCOPE("grpc_error_string", 0); if (err == GRPC_ERROR_NONE) return no_error_string; if (err == GRPC_ERROR_OOM) return oom_error_string; if (err == GRPC_ERROR_CANCELLED) return cancelled_error_string; void* p = (void*)gpr_atm_acq_load(&err->atomics.error_string); if (p != nullptr) { return static_cast(p); } kv_pairs kvs; memset(&kvs, 0, sizeof(kvs)); collect_ints_kvs(err, &kvs); collect_strs_kvs(err, &kvs); collect_times_kvs(err, &kvs); if (err->first_err != UINT8_MAX) { append_kv(&kvs, gpr_strdup("referenced_errors"), errs_string(err)); } qsort(kvs.kvs, kvs.num_kvs, sizeof(kv_pair), cmp_kvs); char* out = finish_kvs(&kvs); if (!gpr_atm_rel_cas(&err->atomics.error_string, 0, (gpr_atm)out)) { gpr_free(out); out = (char*)gpr_atm_acq_load(&err->atomics.error_string); } return out; } grpc_error* grpc_os_error(const char* file, int line, int err, const char* call_name) { return grpc_error_set_str( grpc_error_set_str( grpc_error_set_int( grpc_error_create(file, line, grpc_slice_from_static_string(strerror(err)), nullptr, 0), GRPC_ERROR_INT_ERRNO, err), GRPC_ERROR_STR_OS_ERROR, grpc_slice_from_static_string(strerror(err))), GRPC_ERROR_STR_SYSCALL, grpc_slice_from_copied_string(call_name)); } #ifdef GPR_WINDOWS grpc_error* grpc_wsa_error(const char* file, int line, int err, const char* call_name) { char* utf8_message = gpr_format_message(err); grpc_error* error = grpc_error_set_str( grpc_error_set_str( grpc_error_set_int( grpc_error_create(file, line, grpc_slice_from_static_string("OS Error"), NULL, 0), GRPC_ERROR_INT_WSA_ERROR, err), GRPC_ERROR_STR_OS_ERROR, grpc_slice_from_copied_string(utf8_message)), GRPC_ERROR_STR_SYSCALL, grpc_slice_from_static_string(call_name)); gpr_free(utf8_message); return error; } #endif bool grpc_log_error(const char* what, grpc_error* error, const char* file, int line) { GPR_DEBUG_ASSERT(error != GRPC_ERROR_NONE); const char* msg = grpc_error_string(error); gpr_log(file, line, GPR_LOG_SEVERITY_ERROR, "%s: %s", what, msg); GRPC_ERROR_UNREF(error); return false; }