// Copyright Joyent, Inc. and other Node contributors. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to permit // persons to whom the Software is furnished to do so, subject to the // following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN // NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, // DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE // USE OR OTHER DEALINGS IN THE SOFTWARE. #define CARES_STATICLIB #include "ares.h" #include "async_wrap-inl.h" #include "env-inl.h" #include "node.h" #include "node_internals.h" #include "req_wrap-inl.h" #include "util-inl.h" #include "uv.h" #include #include #include #include #ifdef __POSIX__ # include #endif // __POSIX__ #if defined(__ANDROID__) || \ defined(__MINGW32__) || \ defined(__OpenBSD__) || \ defined(_MSC_VER) # include #else # include #endif #if defined(__OpenBSD__) # define AI_V4MAPPED 0 #endif namespace node { namespace cares_wrap { using v8::Array; using v8::Context; using v8::EscapableHandleScope; using v8::FunctionCallbackInfo; using v8::FunctionTemplate; using v8::HandleScope; using v8::Int32; using v8::Integer; using v8::Local; using v8::Null; using v8::Object; using v8::String; using v8::Value; namespace { Mutex ares_library_mutex; inline uint16_t cares_get_16bit(const unsigned char* p) { return static_cast(p[0] << 8U) | (static_cast(p[1])); } inline uint32_t cares_get_32bit(const unsigned char* p) { return static_cast(p[0] << 24U) | static_cast(p[1] << 16U) | static_cast(p[2] << 8U) | static_cast(p[3]); } const int ns_t_cname_or_a = -1; #define DNS_ESETSRVPENDING -1000 inline const char* ToErrorCodeString(int status) { switch (status) { #define V(code) case ARES_##code: return #code; V(EADDRGETNETWORKPARAMS) V(EBADFAMILY) V(EBADFLAGS) V(EBADHINTS) V(EBADNAME) V(EBADQUERY) V(EBADRESP) V(EBADSTR) V(ECANCELLED) V(ECONNREFUSED) V(EDESTRUCTION) V(EFILE) V(EFORMERR) V(ELOADIPHLPAPI) V(ENODATA) V(ENOMEM) V(ENONAME) V(ENOTFOUND) V(ENOTIMP) V(ENOTINITIALIZED) V(EOF) V(EREFUSED) V(ESERVFAIL) V(ETIMEOUT) #undef V } return "UNKNOWN_ARES_ERROR"; } class ChannelWrap; struct node_ares_task : public MemoryRetainer { ChannelWrap* channel; ares_socket_t sock; uv_poll_t poll_watcher; inline void MemoryInfo(MemoryTracker* tracker) const override; SET_MEMORY_INFO_NAME(node_ares_task) SET_SELF_SIZE(node_ares_task) }; struct TaskHash { size_t operator()(node_ares_task* a) const { return std::hash()(a->sock); } }; struct TaskEqual { inline bool operator()(node_ares_task* a, node_ares_task* b) const { return a->sock == b->sock; } }; using node_ares_task_list = std::unordered_set; class ChannelWrap : public AsyncWrap { public: ChannelWrap(Environment* env, Local object); ~ChannelWrap(); static void New(const FunctionCallbackInfo& args); void Setup(); void EnsureServers(); void StartTimer(); void CloseTimer(); void ModifyActivityQueryCount(int count); inline uv_timer_t* timer_handle() { return timer_handle_; } inline ares_channel cares_channel() { return channel_; } inline void set_query_last_ok(bool ok) { query_last_ok_ = ok; } inline void set_is_servers_default(bool is_default) { is_servers_default_ = is_default; } inline int active_query_count() { return active_query_count_; } inline node_ares_task_list* task_list() { return &task_list_; } void MemoryInfo(MemoryTracker* tracker) const override { if (timer_handle_ != nullptr) tracker->TrackField("timer_handle", *timer_handle_); tracker->TrackField("task_list", task_list_, "node_ares_task_list"); } SET_MEMORY_INFO_NAME(ChannelWrap) SET_SELF_SIZE(ChannelWrap) static void AresTimeout(uv_timer_t* handle); private: uv_timer_t* timer_handle_; ares_channel channel_; bool query_last_ok_; bool is_servers_default_; bool library_inited_; int active_query_count_; node_ares_task_list task_list_; }; ChannelWrap::ChannelWrap(Environment* env, Local object) : AsyncWrap(env, object, PROVIDER_DNSCHANNEL), timer_handle_(nullptr), channel_(nullptr), query_last_ok_(true), is_servers_default_(true), library_inited_(false), active_query_count_(0) { MakeWeak(); Setup(); } void ChannelWrap::New(const FunctionCallbackInfo& args) { CHECK(args.IsConstructCall()); CHECK_EQ(args.Length(), 0); Environment* env = Environment::GetCurrent(args); new ChannelWrap(env, args.This()); } class GetAddrInfoReqWrap : public ReqWrap { public: GetAddrInfoReqWrap(Environment* env, Local req_wrap_obj, bool verbatim); SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(GetAddrInfoReqWrap) SET_SELF_SIZE(GetAddrInfoReqWrap) bool verbatim() const { return verbatim_; } private: const bool verbatim_; }; GetAddrInfoReqWrap::GetAddrInfoReqWrap(Environment* env, Local req_wrap_obj, bool verbatim) : ReqWrap(env, req_wrap_obj, AsyncWrap::PROVIDER_GETADDRINFOREQWRAP) , verbatim_(verbatim) { } class GetNameInfoReqWrap : public ReqWrap { public: GetNameInfoReqWrap(Environment* env, Local req_wrap_obj); SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(GetNameInfoReqWrap) SET_SELF_SIZE(GetNameInfoReqWrap) }; GetNameInfoReqWrap::GetNameInfoReqWrap(Environment* env, Local req_wrap_obj) : ReqWrap(env, req_wrap_obj, AsyncWrap::PROVIDER_GETNAMEINFOREQWRAP) { } /* This is called once per second by loop->timer. It is used to constantly */ /* call back into c-ares for possibly processing timeouts. */ void ChannelWrap::AresTimeout(uv_timer_t* handle) { ChannelWrap* channel = static_cast(handle->data); CHECK_EQ(channel->timer_handle(), handle); CHECK_EQ(false, channel->task_list()->empty()); ares_process_fd(channel->cares_channel(), ARES_SOCKET_BAD, ARES_SOCKET_BAD); } void ares_poll_cb(uv_poll_t* watcher, int status, int events) { node_ares_task* task = ContainerOf(&node_ares_task::poll_watcher, watcher); ChannelWrap* channel = task->channel; /* Reset the idle timer */ uv_timer_again(channel->timer_handle()); if (status < 0) { /* An error happened. Just pretend that the socket is both readable and */ /* writable. */ ares_process_fd(channel->cares_channel(), task->sock, task->sock); return; } /* Process DNS responses */ ares_process_fd(channel->cares_channel(), events & UV_READABLE ? task->sock : ARES_SOCKET_BAD, events & UV_WRITABLE ? task->sock : ARES_SOCKET_BAD); } void ares_poll_close_cb(uv_poll_t* watcher) { node_ares_task* task = ContainerOf(&node_ares_task::poll_watcher, watcher); delete task; } void node_ares_task::MemoryInfo(MemoryTracker* tracker) const { tracker->TrackField("channel", channel); } /* Allocates and returns a new node_ares_task */ node_ares_task* ares_task_create(ChannelWrap* channel, ares_socket_t sock) { auto task = new node_ares_task(); if (task == nullptr) { /* Out of memory. */ return nullptr; } task->channel = channel; task->sock = sock; if (uv_poll_init_socket(channel->env()->event_loop(), &task->poll_watcher, sock) < 0) { /* This should never happen. */ free(task); return nullptr; } return task; } /* Callback from ares when socket operation is started */ void ares_sockstate_cb(void* data, ares_socket_t sock, int read, int write) { ChannelWrap* channel = static_cast(data); node_ares_task* task; node_ares_task lookup_task; lookup_task.sock = sock; auto it = channel->task_list()->find(&lookup_task); task = (it == channel->task_list()->end()) ? nullptr : *it; if (read || write) { if (!task) { /* New socket */ channel->StartTimer(); task = ares_task_create(channel, sock); if (task == nullptr) { /* This should never happen unless we're out of memory or something */ /* is seriously wrong. The socket won't be polled, but the query will */ /* eventually time out. */ return; } channel->task_list()->insert(task); } /* This should never fail. If it fails anyway, the query will eventually */ /* time out. */ uv_poll_start(&task->poll_watcher, (read ? UV_READABLE : 0) | (write ? UV_WRITABLE : 0), ares_poll_cb); } else { /* read == 0 and write == 0 this is c-ares's way of notifying us that */ /* the socket is now closed. We must free the data associated with */ /* socket. */ CHECK(task && "When an ares socket is closed we should have a handle for it"); channel->task_list()->erase(it); channel->env()->CloseHandle(&task->poll_watcher, ares_poll_close_cb); if (channel->task_list()->empty()) { channel->CloseTimer(); } } } Local HostentToNames(Environment* env, struct hostent* host, Local append_to = Local()) { EscapableHandleScope scope(env->isolate()); auto context = env->context(); bool append = !append_to.IsEmpty(); Local names = append ? append_to : Array::New(env->isolate()); size_t offset = names->Length(); for (uint32_t i = 0; host->h_aliases[i] != nullptr; ++i) { Local address = OneByteString(env->isolate(), host->h_aliases[i]); names->Set(context, i + offset, address).FromJust(); } return append ? names : scope.Escape(names); } void safe_free_hostent(struct hostent* host) { int idx; if (host->h_addr_list != nullptr) { idx = 0; while (host->h_addr_list[idx]) { free(host->h_addr_list[idx++]); } free(host->h_addr_list); host->h_addr_list = 0; } if (host->h_aliases != nullptr) { idx = 0; while (host->h_aliases[idx]) { free(host->h_aliases[idx++]); } free(host->h_aliases); host->h_aliases = 0; } if (host->h_name != nullptr) { free(host->h_name); } host->h_addrtype = host->h_length = 0; } void cares_wrap_hostent_cpy(struct hostent* dest, struct hostent* src) { dest->h_addr_list = nullptr; dest->h_addrtype = 0; dest->h_aliases = nullptr; dest->h_length = 0; dest->h_name = nullptr; /* copy `h_name` */ size_t name_size = strlen(src->h_name) + 1; dest->h_name = node::Malloc(name_size); memcpy(dest->h_name, src->h_name, name_size); /* copy `h_aliases` */ size_t alias_count; for (alias_count = 0; src->h_aliases[alias_count] != nullptr; alias_count++) { } dest->h_aliases = node::Malloc(alias_count + 1); for (size_t i = 0; i < alias_count; i++) { const size_t cur_alias_size = strlen(src->h_aliases[i]) + 1; dest->h_aliases[i] = node::Malloc(cur_alias_size); memcpy(dest->h_aliases[i], src->h_aliases[i], cur_alias_size); } dest->h_aliases[alias_count] = nullptr; /* copy `h_addr_list` */ size_t list_count; for (list_count = 0; src->h_addr_list[list_count] != nullptr; list_count++) { } dest->h_addr_list = node::Malloc(list_count + 1); for (size_t i = 0; i < list_count; i++) { dest->h_addr_list[i] = node::Malloc(src->h_length); memcpy(dest->h_addr_list[i], src->h_addr_list[i], src->h_length); } dest->h_addr_list[list_count] = nullptr; /* work after work */ dest->h_length = src->h_length; dest->h_addrtype = src->h_addrtype; } class QueryWrap; struct CaresAsyncData { QueryWrap* wrap; int status; bool is_host; union { hostent* host; unsigned char* buf; } data; int len; uv_async_t async_handle; }; void ChannelWrap::Setup() { struct ares_options options; memset(&options, 0, sizeof(options)); options.flags = ARES_FLAG_NOCHECKRESP; options.sock_state_cb = ares_sockstate_cb; options.sock_state_cb_data = this; int r; if (!library_inited_) { Mutex::ScopedLock lock(ares_library_mutex); // Multiple calls to ares_library_init() increase a reference counter, // so this is a no-op except for the first call to it. r = ares_library_init(ARES_LIB_INIT_ALL); if (r != ARES_SUCCESS) return env()->ThrowError(ToErrorCodeString(r)); } /* We do the call to ares_init_option for caller. */ r = ares_init_options(&channel_, &options, ARES_OPT_FLAGS | ARES_OPT_SOCK_STATE_CB); if (r != ARES_SUCCESS) { Mutex::ScopedLock lock(ares_library_mutex); ares_library_cleanup(); return env()->ThrowError(ToErrorCodeString(r)); } library_inited_ = true; } void ChannelWrap::StartTimer() { if (timer_handle_ == nullptr) { timer_handle_ = new uv_timer_t(); timer_handle_->data = static_cast(this); uv_timer_init(env()->event_loop(), timer_handle_); } else if (uv_is_active(reinterpret_cast(timer_handle_))) { return; } uv_timer_start(timer_handle_, AresTimeout, 1000, 1000); } void ChannelWrap::CloseTimer() { if (timer_handle_ == nullptr) return; env()->CloseHandle(timer_handle_, [](uv_timer_t* handle) { delete handle; }); timer_handle_ = nullptr; } ChannelWrap::~ChannelWrap() { if (library_inited_) { Mutex::ScopedLock lock(ares_library_mutex); // This decreases the reference counter increased by ares_library_init(). ares_library_cleanup(); } ares_destroy(channel_); CloseTimer(); } void ChannelWrap::ModifyActivityQueryCount(int count) { active_query_count_ += count; if (active_query_count_ < 0) active_query_count_ = 0; } /** * This function is to check whether current servers are fallback servers * when cares initialized. * * The fallback servers of cares is [ "127.0.0.1" ] with no user additional * setting. */ void ChannelWrap::EnsureServers() { /* if last query is OK or servers are set by user self, do not check */ if (query_last_ok_ || !is_servers_default_) { return; } ares_addr_port_node* servers = nullptr; ares_get_servers_ports(channel_, &servers); /* if no server or multi-servers, ignore */ if (servers == nullptr) return; if (servers->next != nullptr) { ares_free_data(servers); is_servers_default_ = false; return; } /* if the only server is not 127.0.0.1, ignore */ if (servers[0].family != AF_INET || servers[0].addr.addr4.s_addr != htonl(INADDR_LOOPBACK) || servers[0].tcp_port != 0 || servers[0].udp_port != 0) { ares_free_data(servers); is_servers_default_ = false; return; } ares_free_data(servers); servers = nullptr; /* destroy channel and reset channel */ ares_destroy(channel_); CloseTimer(); Setup(); } class QueryWrap : public AsyncWrap { public: QueryWrap(ChannelWrap* channel, Local req_wrap_obj, const char* name) : AsyncWrap(channel->env(), req_wrap_obj, AsyncWrap::PROVIDER_QUERYWRAP), channel_(channel), trace_name_(name) { // Make sure the channel object stays alive during the query lifetime. req_wrap_obj->Set(env()->context(), env()->channel_string(), channel->object()).FromJust(); } ~QueryWrap() override { CHECK_EQ(false, persistent().IsEmpty()); } // Subclasses should implement the appropriate Send method. virtual int Send(const char* name) { UNREACHABLE(); return 0; } virtual int Send(const char* name, int family) { UNREACHABLE(); return 0; } protected: void AresQuery(const char* name, int dnsclass, int type) { channel_->EnsureServers(); TRACE_EVENT_NESTABLE_ASYNC_BEGIN1( TRACING_CATEGORY_NODE2(dns, native), trace_name_, this, "name", TRACE_STR_COPY(name)); ares_query(channel_->cares_channel(), name, dnsclass, type, Callback, static_cast(this)); } static void CaresAsyncClose(uv_async_t* async) { auto data = static_cast(async->data); delete data->wrap; delete data; } static void CaresAsyncCb(uv_async_t* handle) { auto data = static_cast(handle->data); QueryWrap* wrap = data->wrap; int status = data->status; if (status != ARES_SUCCESS) { wrap->ParseError(status); } else if (!data->is_host) { unsigned char* buf = data->data.buf; wrap->Parse(buf, data->len); free(buf); } else { hostent* host = data->data.host; wrap->Parse(host); safe_free_hostent(host); free(host); } wrap->env()->CloseHandle(handle, CaresAsyncClose); } static void Callback(void* arg, int status, int timeouts, unsigned char* answer_buf, int answer_len) { QueryWrap* wrap = static_cast(arg); unsigned char* buf_copy = nullptr; if (status == ARES_SUCCESS) { buf_copy = node::Malloc(answer_len); memcpy(buf_copy, answer_buf, answer_len); } CaresAsyncData* data = new CaresAsyncData(); data->status = status; data->wrap = wrap; data->is_host = false; data->data.buf = buf_copy; data->len = answer_len; uv_async_t* async_handle = &data->async_handle; CHECK_EQ(0, uv_async_init(wrap->env()->event_loop(), async_handle, CaresAsyncCb)); wrap->channel_->set_query_last_ok(status != ARES_ECONNREFUSED); wrap->channel_->ModifyActivityQueryCount(-1); async_handle->data = data; uv_async_send(async_handle); } static void Callback(void* arg, int status, int timeouts, struct hostent* host) { QueryWrap* wrap = static_cast(arg); struct hostent* host_copy = nullptr; if (status == ARES_SUCCESS) { host_copy = node::Malloc(1); cares_wrap_hostent_cpy(host_copy, host); } CaresAsyncData* data = new CaresAsyncData(); data->status = status; data->data.host = host_copy; data->wrap = wrap; data->is_host = true; uv_async_t* async_handle = &data->async_handle; CHECK_EQ(0, uv_async_init(wrap->env()->event_loop(), async_handle, CaresAsyncCb)); wrap->channel_->set_query_last_ok(status != ARES_ECONNREFUSED); async_handle->data = data; uv_async_send(async_handle); } void CallOnComplete(Local answer, Local extra = Local()) { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); Local argv[] = { Integer::New(env()->isolate(), 0), answer, extra }; const int argc = arraysize(argv) - extra.IsEmpty(); TRACE_EVENT_NESTABLE_ASYNC_END0( TRACING_CATEGORY_NODE2(dns, native), trace_name_, this); MakeCallback(env()->oncomplete_string(), argc, argv); } void ParseError(int status) { CHECK_NE(status, ARES_SUCCESS); HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); const char* code = ToErrorCodeString(status); Local arg = OneByteString(env()->isolate(), code); TRACE_EVENT_NESTABLE_ASYNC_END1( TRACING_CATEGORY_NODE2(dns, native), trace_name_, this, "error", status); MakeCallback(env()->oncomplete_string(), 1, &arg); } // Subclasses should implement the appropriate Parse method. virtual void Parse(unsigned char* buf, int len) { UNREACHABLE(); } virtual void Parse(struct hostent* host) { UNREACHABLE(); } ChannelWrap* channel_; private: const char* trace_name_; }; template Local AddrTTLToArray(Environment* env, const T* addrttls, size_t naddrttls) { auto isolate = env->isolate(); EscapableHandleScope escapable_handle_scope(isolate); auto context = env->context(); Local ttls = Array::New(isolate, naddrttls); for (size_t i = 0; i < naddrttls; i++) { auto value = Integer::New(isolate, addrttls[i].ttl); ttls->Set(context, i, value).FromJust(); } return escapable_handle_scope.Escape(ttls); } int ParseGeneralReply(Environment* env, const unsigned char* buf, int len, int* type, Local ret, void* addrttls = nullptr, int* naddrttls = nullptr) { HandleScope handle_scope(env->isolate()); auto context = env->context(); hostent* host; int status; switch (*type) { case ns_t_a: case ns_t_cname: case ns_t_cname_or_a: status = ares_parse_a_reply(buf, len, &host, static_cast(addrttls), naddrttls); break; case ns_t_aaaa: status = ares_parse_aaaa_reply(buf, len, &host, static_cast(addrttls), naddrttls); break; case ns_t_ns: status = ares_parse_ns_reply(buf, len, &host); break; case ns_t_ptr: status = ares_parse_ptr_reply(buf, len, nullptr, 0, AF_INET, &host); break; default: CHECK(0 && "Bad NS type"); break; } if (status != ARES_SUCCESS) return status; /* If it's `CNAME`, return the CNAME value; * And if it's `CNAME_OR_A` and it has value in `h_name` and `h_aliases[0]`, * we consider it's a CNAME record, otherwise we consider it's an A record. */ if ((*type == ns_t_cname_or_a && host->h_name && host->h_aliases[0]) || *type == ns_t_cname) { // A cname lookup always returns a single record but we follow the // common API here. *type = ns_t_cname; ret->Set(context, ret->Length(), OneByteString(env->isolate(), host->h_name)).FromJust(); ares_free_hostent(host); return ARES_SUCCESS; } if (*type == ns_t_cname_or_a) *type = ns_t_a; if (*type == ns_t_ns) { HostentToNames(env, host, ret); } else if (*type == ns_t_ptr) { uint32_t offset = ret->Length(); for (uint32_t i = 0; host->h_aliases[i] != nullptr; i++) { auto alias = OneByteString(env->isolate(), host->h_aliases[i]); ret->Set(context, i + offset, alias).FromJust(); } } else { uint32_t offset = ret->Length(); char ip[INET6_ADDRSTRLEN]; for (uint32_t i = 0; host->h_addr_list[i] != nullptr; ++i) { uv_inet_ntop(host->h_addrtype, host->h_addr_list[i], ip, sizeof(ip)); auto address = OneByteString(env->isolate(), ip); ret->Set(context, i + offset, address).FromJust(); } } ares_free_hostent(host); return ARES_SUCCESS; } int ParseMxReply(Environment* env, const unsigned char* buf, int len, Local ret, bool need_type = false) { HandleScope handle_scope(env->isolate()); auto context = env->context(); struct ares_mx_reply* mx_start; int status = ares_parse_mx_reply(buf, len, &mx_start); if (status != ARES_SUCCESS) { return status; } uint32_t offset = ret->Length(); ares_mx_reply* current = mx_start; for (uint32_t i = 0; current != nullptr; ++i, current = current->next) { Local mx_record = Object::New(env->isolate()); mx_record->Set(context, env->exchange_string(), OneByteString(env->isolate(), current->host)).FromJust(); mx_record->Set(context, env->priority_string(), Integer::New(env->isolate(), current->priority)).FromJust(); if (need_type) mx_record->Set(context, env->type_string(), env->dns_mx_string()).FromJust(); ret->Set(context, i + offset, mx_record).FromJust(); } ares_free_data(mx_start); return ARES_SUCCESS; } int ParseTxtReply(Environment* env, const unsigned char* buf, int len, Local ret, bool need_type = false) { HandleScope handle_scope(env->isolate()); auto context = env->context(); struct ares_txt_ext* txt_out; int status = ares_parse_txt_reply_ext(buf, len, &txt_out); if (status != ARES_SUCCESS) { return status; } Local txt_chunk; struct ares_txt_ext* current = txt_out; uint32_t i = 0, j; uint32_t offset = ret->Length(); for (j = 0; current != nullptr; current = current->next) { Local txt = OneByteString(env->isolate(), current->txt); // New record found - write out the current chunk if (current->record_start) { if (!txt_chunk.IsEmpty()) { if (need_type) { Local elem = Object::New(env->isolate()); elem->Set(context, env->entries_string(), txt_chunk).FromJust(); elem->Set(context, env->type_string(), env->dns_txt_string()).FromJust(); ret->Set(context, offset + i++, elem).FromJust(); } else { ret->Set(context, offset + i++, txt_chunk).FromJust(); } } txt_chunk = Array::New(env->isolate()); j = 0; } txt_chunk->Set(context, j++, txt).FromJust(); } // Push last chunk if it isn't empty if (!txt_chunk.IsEmpty()) { if (need_type) { Local elem = Object::New(env->isolate()); elem->Set(context, env->entries_string(), txt_chunk).FromJust(); elem->Set(context, env->type_string(), env->dns_txt_string()).FromJust(); ret->Set(context, offset + i, elem).FromJust(); } else { ret->Set(context, offset + i, txt_chunk).FromJust(); } } ares_free_data(txt_out); return ARES_SUCCESS; } int ParseSrvReply(Environment* env, const unsigned char* buf, int len, Local ret, bool need_type = false) { HandleScope handle_scope(env->isolate()); auto context = env->context(); struct ares_srv_reply* srv_start; int status = ares_parse_srv_reply(buf, len, &srv_start); if (status != ARES_SUCCESS) { return status; } ares_srv_reply* current = srv_start; int offset = ret->Length(); for (uint32_t i = 0; current != nullptr; ++i, current = current->next) { Local srv_record = Object::New(env->isolate()); srv_record->Set(context, env->name_string(), OneByteString(env->isolate(), current->host)).FromJust(); srv_record->Set(context, env->port_string(), Integer::New(env->isolate(), current->port)).FromJust(); srv_record->Set(context, env->priority_string(), Integer::New(env->isolate(), current->priority)).FromJust(); srv_record->Set(context, env->weight_string(), Integer::New(env->isolate(), current->weight)).FromJust(); if (need_type) srv_record->Set(context, env->type_string(), env->dns_srv_string()).FromJust(); ret->Set(context, i + offset, srv_record).FromJust(); } ares_free_data(srv_start); return ARES_SUCCESS; } int ParseNaptrReply(Environment* env, const unsigned char* buf, int len, Local ret, bool need_type = false) { HandleScope handle_scope(env->isolate()); auto context = env->context(); ares_naptr_reply* naptr_start; int status = ares_parse_naptr_reply(buf, len, &naptr_start); if (status != ARES_SUCCESS) { return status; } ares_naptr_reply* current = naptr_start; int offset = ret->Length(); for (uint32_t i = 0; current != nullptr; ++i, current = current->next) { Local naptr_record = Object::New(env->isolate()); naptr_record->Set(context, env->flags_string(), OneByteString(env->isolate(), current->flags)).FromJust(); naptr_record->Set(context, env->service_string(), OneByteString(env->isolate(), current->service)).FromJust(); naptr_record->Set(context, env->regexp_string(), OneByteString(env->isolate(), current->regexp)).FromJust(); naptr_record->Set(context, env->replacement_string(), OneByteString(env->isolate(), current->replacement)).FromJust(); naptr_record->Set(context, env->order_string(), Integer::New(env->isolate(), current->order)).FromJust(); naptr_record->Set(context, env->preference_string(), Integer::New(env->isolate(), current->preference)).FromJust(); if (need_type) naptr_record->Set(context, env->type_string(), env->dns_naptr_string()).FromJust(); ret->Set(context, i + offset, naptr_record).FromJust(); } ares_free_data(naptr_start); return ARES_SUCCESS; } int ParseSoaReply(Environment* env, unsigned char* buf, int len, Local* ret) { EscapableHandleScope handle_scope(env->isolate()); auto context = env->context(); // Manage memory using standardard smart pointer std::unique_tr struct AresDeleter { void operator()(char* ptr) const noexcept { ares_free_string(ptr); } }; using ares_unique_ptr = std::unique_ptr; // Can't use ares_parse_soa_reply() here which can only parse single record const unsigned int ancount = cares_get_16bit(buf + 6); unsigned char* ptr = buf + NS_HFIXEDSZ; char* name_temp; long temp_len; // NOLINT(runtime/int) int status = ares_expand_name(ptr, buf, len, &name_temp, &temp_len); const ares_unique_ptr name(name_temp); if (status != ARES_SUCCESS) { // returns EBADRESP in case of invalid input return status == ARES_EBADNAME ? ARES_EBADRESP : status; } if (ptr + temp_len + NS_QFIXEDSZ > buf + len) { return ARES_EBADRESP; } ptr += temp_len + NS_QFIXEDSZ; for (unsigned int i = 0; i < ancount; i++) { char* rr_name_temp; long rr_temp_len; // NOLINT(runtime/int) int status2 = ares_expand_name(ptr, buf, len, &rr_name_temp, &rr_temp_len); const ares_unique_ptr rr_name(rr_name_temp); if (status2 != ARES_SUCCESS) return status2 == ARES_EBADNAME ? ARES_EBADRESP : status2; ptr += rr_temp_len; if (ptr + NS_RRFIXEDSZ > buf + len) { return ARES_EBADRESP; } const int rr_type = cares_get_16bit(ptr); const int rr_len = cares_get_16bit(ptr + 8); ptr += NS_RRFIXEDSZ; // only need SOA if (rr_type == ns_t_soa) { char* nsname_temp; long nsname_temp_len; // NOLINT(runtime/int) int status3 = ares_expand_name(ptr, buf, len, &nsname_temp, &nsname_temp_len); const ares_unique_ptr nsname(nsname_temp); if (status3 != ARES_SUCCESS) { return status3 == ARES_EBADNAME ? ARES_EBADRESP : status3; } ptr += nsname_temp_len; char* hostmaster_temp; long hostmaster_temp_len; // NOLINT(runtime/int) int status4 = ares_expand_name(ptr, buf, len, &hostmaster_temp, &hostmaster_temp_len); const ares_unique_ptr hostmaster(hostmaster_temp); if (status4 != ARES_SUCCESS) { return status4 == ARES_EBADNAME ? ARES_EBADRESP : status4; } ptr += hostmaster_temp_len; if (ptr + 5 * 4 > buf + len) { return ARES_EBADRESP; } const unsigned int serial = cares_get_32bit(ptr + 0 * 4); const unsigned int refresh = cares_get_32bit(ptr + 1 * 4); const unsigned int retry = cares_get_32bit(ptr + 2 * 4); const unsigned int expire = cares_get_32bit(ptr + 3 * 4); const unsigned int minttl = cares_get_32bit(ptr + 4 * 4); Local soa_record = Object::New(env->isolate()); soa_record->Set(context, env->nsname_string(), OneByteString(env->isolate(), nsname.get())).FromJust(); soa_record->Set(context, env->hostmaster_string(), OneByteString(env->isolate(), hostmaster.get())).FromJust(); soa_record->Set(context, env->serial_string(), Integer::New(env->isolate(), serial)).FromJust(); soa_record->Set(context, env->refresh_string(), Integer::New(env->isolate(), refresh)).FromJust(); soa_record->Set(context, env->retry_string(), Integer::New(env->isolate(), retry)).FromJust(); soa_record->Set(context, env->expire_string(), Integer::New(env->isolate(), expire)).FromJust(); soa_record->Set(context, env->minttl_string(), Integer::New(env->isolate(), minttl)).FromJust(); soa_record->Set(context, env->type_string(), env->dns_soa_string()).FromJust(); *ret = handle_scope.Escape(soa_record); break; } ptr += rr_len; } return ARES_SUCCESS; } class QueryAnyWrap: public QueryWrap { public: QueryAnyWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveAny") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_any); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryAnyWrap) SET_SELF_SIZE(QueryAnyWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); auto context = env()->context(); Context::Scope context_scope(context); Local ret = Array::New(env()->isolate()); int type, status, old_count; /* Parse A records or CNAME records */ ares_addrttl addrttls[256]; int naddrttls = arraysize(addrttls); type = ns_t_cname_or_a; status = ParseGeneralReply(env(), buf, len, &type, ret, addrttls, &naddrttls); uint32_t a_count = ret->Length(); if (status != ARES_SUCCESS && status != ARES_ENODATA) { ParseError(status); return; } if (type == ns_t_a) { CHECK_EQ(static_cast(naddrttls), a_count); for (uint32_t i = 0; i < a_count; i++) { Local obj = Object::New(env()->isolate()); obj->Set(context, env()->address_string(), ret->Get(context, i).ToLocalChecked()).FromJust(); obj->Set(context, env()->ttl_string(), Integer::New(env()->isolate(), addrttls[i].ttl)).FromJust(); obj->Set(context, env()->type_string(), env()->dns_a_string()).FromJust(); ret->Set(context, i, obj).FromJust(); } } else { for (uint32_t i = 0; i < a_count; i++) { Local obj = Object::New(env()->isolate()); obj->Set(context, env()->value_string(), ret->Get(context, i).ToLocalChecked()).FromJust(); obj->Set(context, env()->type_string(), env()->dns_cname_string()).FromJust(); ret->Set(context, i, obj).FromJust(); } } /* Parse AAAA records */ ares_addr6ttl addr6ttls[256]; int naddr6ttls = arraysize(addr6ttls); type = ns_t_aaaa; status = ParseGeneralReply(env(), buf, len, &type, ret, addr6ttls, &naddr6ttls); uint32_t aaaa_count = ret->Length() - a_count; if (status != ARES_SUCCESS && status != ARES_ENODATA) { ParseError(status); return; } CHECK_EQ(aaaa_count, static_cast(naddr6ttls)); CHECK_EQ(ret->Length(), a_count + aaaa_count); for (uint32_t i = a_count; i < ret->Length(); i++) { Local obj = Object::New(env()->isolate()); obj->Set(context, env()->address_string(), ret->Get(context, i).ToLocalChecked()).FromJust(); obj->Set(context, env()->ttl_string(), Integer::New(env()->isolate(), addr6ttls[i - a_count].ttl)) .FromJust(); obj->Set(context, env()->type_string(), env()->dns_aaaa_string()).FromJust(); ret->Set(context, i, obj).FromJust(); } /* Parse MX records */ status = ParseMxReply(env(), buf, len, ret, true); if (status != ARES_SUCCESS && status != ARES_ENODATA) { ParseError(status); return; } /* Parse NS records */ type = ns_t_ns; old_count = ret->Length(); status = ParseGeneralReply(env(), buf, len, &type, ret); if (status != ARES_SUCCESS && status != ARES_ENODATA) { ParseError(status); return; } for (uint32_t i = old_count; i < ret->Length(); i++) { Local obj = Object::New(env()->isolate()); obj->Set(context, env()->value_string(), ret->Get(context, i).ToLocalChecked()).FromJust(); obj->Set(context, env()->type_string(), env()->dns_ns_string()).FromJust(); ret->Set(context, i, obj).FromJust(); } /* Parse TXT records */ status = ParseTxtReply(env(), buf, len, ret, true); if (status != ARES_SUCCESS && status != ARES_ENODATA) { ParseError(status); return; } /* Parse SRV records */ status = ParseSrvReply(env(), buf, len, ret, true); if (status != ARES_SUCCESS && status != ARES_ENODATA) { return; } /* Parse PTR records */ type = ns_t_ptr; old_count = ret->Length(); status = ParseGeneralReply(env(), buf, len, &type, ret); for (uint32_t i = old_count; i < ret->Length(); i++) { Local obj = Object::New(env()->isolate()); obj->Set(context, env()->value_string(), ret->Get(context, i).ToLocalChecked()).FromJust(); obj->Set(context, env()->type_string(), env()->dns_ptr_string()).FromJust(); ret->Set(context, i, obj).FromJust(); } /* Parse NAPTR records */ status = ParseNaptrReply(env(), buf, len, ret, true); if (status != ARES_SUCCESS && status != ARES_ENODATA) { ParseError(status); return; } /* Parse SOA records */ Local soa_record = Local(); status = ParseSoaReply(env(), buf, len, &soa_record); if (status != ARES_SUCCESS && status != ARES_ENODATA) { ParseError(status); return; } if (!soa_record.IsEmpty()) ret->Set(context, ret->Length(), soa_record).FromJust(); CallOnComplete(ret); } }; class QueryAWrap: public QueryWrap { public: QueryAWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolve4") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_a); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryAWrap) SET_SELF_SIZE(QueryAWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); ares_addrttl addrttls[256]; int naddrttls = arraysize(addrttls), status; Local ret = Array::New(env()->isolate()); int type = ns_t_a; status = ParseGeneralReply(env(), buf, len, &type, ret, addrttls, &naddrttls); if (status != ARES_SUCCESS) { ParseError(status); return; } Local ttls = AddrTTLToArray(env(), addrttls, naddrttls); CallOnComplete(ret, ttls); } }; class QueryAaaaWrap: public QueryWrap { public: QueryAaaaWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolve6") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_aaaa); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryAaaaWrap) SET_SELF_SIZE(QueryAaaaWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); ares_addr6ttl addrttls[256]; int naddrttls = arraysize(addrttls), status; Local ret = Array::New(env()->isolate()); int type = ns_t_aaaa; status = ParseGeneralReply(env(), buf, len, &type, ret, addrttls, &naddrttls); if (status != ARES_SUCCESS) { ParseError(status); return; } Local ttls = AddrTTLToArray(env(), addrttls, naddrttls); CallOnComplete(ret, ttls); } }; class QueryCnameWrap: public QueryWrap { public: QueryCnameWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveCname") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_cname); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryCnameWrap) SET_SELF_SIZE(QueryCnameWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); Local ret = Array::New(env()->isolate()); int type = ns_t_cname; int status = ParseGeneralReply(env(), buf, len, &type, ret); if (status != ARES_SUCCESS) { ParseError(status); return; } this->CallOnComplete(ret); } }; class QueryMxWrap: public QueryWrap { public: QueryMxWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveMx") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_mx); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryMxWrap) SET_SELF_SIZE(QueryMxWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); Local mx_records = Array::New(env()->isolate()); int status = ParseMxReply(env(), buf, len, mx_records); if (status != ARES_SUCCESS) { ParseError(status); return; } this->CallOnComplete(mx_records); } }; class QueryNsWrap: public QueryWrap { public: QueryNsWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveNs") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_ns); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryNsWrap) SET_SELF_SIZE(QueryNsWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); int type = ns_t_ns; Local names = Array::New(env()->isolate()); int status = ParseGeneralReply(env(), buf, len, &type, names); if (status != ARES_SUCCESS) { ParseError(status); return; } this->CallOnComplete(names); } }; class QueryTxtWrap: public QueryWrap { public: QueryTxtWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveTxt") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_txt); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryTxtWrap) SET_SELF_SIZE(QueryTxtWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); Local txt_records = Array::New(env()->isolate()); int status = ParseTxtReply(env(), buf, len, txt_records); if (status != ARES_SUCCESS) { ParseError(status); return; } this->CallOnComplete(txt_records); } }; class QuerySrvWrap: public QueryWrap { public: explicit QuerySrvWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveSrv") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_srv); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QuerySrvWrap) SET_SELF_SIZE(QuerySrvWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); Local srv_records = Array::New(env()->isolate()); int status = ParseSrvReply(env(), buf, len, srv_records); if (status != ARES_SUCCESS) { ParseError(status); return; } this->CallOnComplete(srv_records); } }; class QueryPtrWrap: public QueryWrap { public: explicit QueryPtrWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolvePtr") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_ptr); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryPtrWrap) SET_SELF_SIZE(QueryPtrWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); int type = ns_t_ptr; Local aliases = Array::New(env()->isolate()); int status = ParseGeneralReply(env(), buf, len, &type, aliases); if (status != ARES_SUCCESS) { ParseError(status); return; } this->CallOnComplete(aliases); } }; class QueryNaptrWrap: public QueryWrap { public: explicit QueryNaptrWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveNaptr") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_naptr); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QueryNaptrWrap) SET_SELF_SIZE(QueryNaptrWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); Local naptr_records = Array::New(env()->isolate()); int status = ParseNaptrReply(env(), buf, len, naptr_records); if (status != ARES_SUCCESS) { ParseError(status); return; } this->CallOnComplete(naptr_records); } }; class QuerySoaWrap: public QueryWrap { public: QuerySoaWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "resolveSoa") { } int Send(const char* name) override { AresQuery(name, ns_c_in, ns_t_soa); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(QuerySoaWrap) SET_SELF_SIZE(QuerySoaWrap) protected: void Parse(unsigned char* buf, int len) override { HandleScope handle_scope(env()->isolate()); auto context = env()->context(); Context::Scope context_scope(context); ares_soa_reply* soa_out; int status = ares_parse_soa_reply(buf, len, &soa_out); if (status != ARES_SUCCESS) { ParseError(status); return; } Local soa_record = Object::New(env()->isolate()); soa_record->Set(context, env()->nsname_string(), OneByteString(env()->isolate(), soa_out->nsname)).FromJust(); soa_record->Set(context, env()->hostmaster_string(), OneByteString(env()->isolate(), soa_out->hostmaster)).FromJust(); soa_record->Set(context, env()->serial_string(), Integer::New(env()->isolate(), soa_out->serial)).FromJust(); soa_record->Set(context, env()->refresh_string(), Integer::New(env()->isolate(), soa_out->refresh)).FromJust(); soa_record->Set(context, env()->retry_string(), Integer::New(env()->isolate(), soa_out->retry)).FromJust(); soa_record->Set(context, env()->expire_string(), Integer::New(env()->isolate(), soa_out->expire)).FromJust(); soa_record->Set(context, env()->minttl_string(), Integer::New(env()->isolate(), soa_out->minttl)).FromJust(); ares_free_data(soa_out); this->CallOnComplete(soa_record); } }; class GetHostByAddrWrap: public QueryWrap { public: explicit GetHostByAddrWrap(ChannelWrap* channel, Local req_wrap_obj) : QueryWrap(channel, req_wrap_obj, "reverse") { } int Send(const char* name) override { int length, family; char address_buffer[sizeof(struct in6_addr)]; if (uv_inet_pton(AF_INET, name, &address_buffer) == 0) { length = sizeof(struct in_addr); family = AF_INET; } else if (uv_inet_pton(AF_INET6, name, &address_buffer) == 0) { length = sizeof(struct in6_addr); family = AF_INET6; } else { return UV_EINVAL; // So errnoException() reports a proper error. } TRACE_EVENT_NESTABLE_ASYNC_BEGIN2( TRACING_CATEGORY_NODE2(dns, native), "reverse", this, "name", TRACE_STR_COPY(name), "family", family == AF_INET ? "ipv4" : "ipv6"); ares_gethostbyaddr(channel_->cares_channel(), address_buffer, length, family, Callback, static_cast(static_cast(this))); return 0; } SET_NO_MEMORY_INFO() SET_MEMORY_INFO_NAME(GetHostByAddrWrap) SET_SELF_SIZE(GetHostByAddrWrap) protected: void Parse(struct hostent* host) override { HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); this->CallOnComplete(HostentToNames(env(), host)); } }; template static void Query(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); ChannelWrap* channel; ASSIGN_OR_RETURN_UNWRAP(&channel, args.Holder()); CHECK_EQ(false, args.IsConstructCall()); CHECK(args[0]->IsObject()); CHECK(args[1]->IsString()); Local req_wrap_obj = args[0].As(); Local string = args[1].As(); auto wrap = std::make_unique(channel, req_wrap_obj); node::Utf8Value name(env->isolate(), string); channel->ModifyActivityQueryCount(1); int err = wrap->Send(*name); if (err) { channel->ModifyActivityQueryCount(-1); } else { // Release ownership of the pointer allowing the ownership to be transferred USE(wrap.release()); } args.GetReturnValue().Set(err); } void AfterGetAddrInfo(uv_getaddrinfo_t* req, int status, struct addrinfo* res) { std::unique_ptr req_wrap { static_cast(req->data)}; Environment* env = req_wrap->env(); HandleScope handle_scope(env->isolate()); Context::Scope context_scope(env->context()); Local argv[] = { Integer::New(env->isolate(), status), Null(env->isolate()) }; uint64_t n = 0; const bool verbatim = req_wrap->verbatim(); if (status == 0) { Local results = Array::New(env->isolate()); auto add = [&] (bool want_ipv4, bool want_ipv6) { for (auto p = res; p != nullptr; p = p->ai_next) { CHECK_EQ(p->ai_socktype, SOCK_STREAM); const char* addr; if (want_ipv4 && p->ai_family == AF_INET) { addr = reinterpret_cast( &(reinterpret_cast(p->ai_addr)->sin_addr)); } else if (want_ipv6 && p->ai_family == AF_INET6) { addr = reinterpret_cast( &(reinterpret_cast(p->ai_addr)->sin6_addr)); } else { continue; } char ip[INET6_ADDRSTRLEN]; if (uv_inet_ntop(p->ai_family, addr, ip, sizeof(ip))) continue; Local s = OneByteString(env->isolate(), ip); results->Set(n, s); n++; } }; add(true, verbatim); if (verbatim == false) add(false, true); // No responses were found to return if (n == 0) { argv[0] = Integer::New(env->isolate(), UV_EAI_NODATA); } argv[1] = results; } uv_freeaddrinfo(res); TRACE_EVENT_NESTABLE_ASYNC_END2( TRACING_CATEGORY_NODE2(dns, native), "lookup", req_wrap.get(), "count", n, "verbatim", verbatim); // Make the callback into JavaScript req_wrap->MakeCallback(env->oncomplete_string(), arraysize(argv), argv); } void AfterGetNameInfo(uv_getnameinfo_t* req, int status, const char* hostname, const char* service) { std::unique_ptr req_wrap { static_cast(req->data)}; Environment* env = req_wrap->env(); HandleScope handle_scope(env->isolate()); Context::Scope context_scope(env->context()); Local argv[] = { Integer::New(env->isolate(), status), Null(env->isolate()), Null(env->isolate()) }; if (status == 0) { // Success Local js_hostname = OneByteString(env->isolate(), hostname); Local js_service = OneByteString(env->isolate(), service); argv[1] = js_hostname; argv[2] = js_service; } TRACE_EVENT_NESTABLE_ASYNC_END2( TRACING_CATEGORY_NODE2(dns, native), "lookupService", req_wrap.get(), "hostname", TRACE_STR_COPY(hostname), "service", TRACE_STR_COPY(service)); // Make the callback into JavaScript req_wrap->MakeCallback(env->oncomplete_string(), arraysize(argv), argv); } using ParseIPResult = decltype(static_cast(0)->addr); int ParseIP(const char* ip, ParseIPResult* result = nullptr) { ParseIPResult tmp; if (result == nullptr) result = &tmp; if (0 == uv_inet_pton(AF_INET, ip, result)) return 4; if (0 == uv_inet_pton(AF_INET6, ip, result)) return 6; return 0; } void CanonicalizeIP(const FunctionCallbackInfo& args) { v8::Isolate* isolate = args.GetIsolate(); node::Utf8Value ip(isolate, args[0]); ParseIPResult result; const int rc = ParseIP(*ip, &result); if (rc == 0) return; char canonical_ip[INET6_ADDRSTRLEN]; const int af = (rc == 4 ? AF_INET : AF_INET6); CHECK_EQ(0, uv_inet_ntop(af, &result, canonical_ip, sizeof(canonical_ip))); v8::Local val = String::NewFromUtf8(isolate, canonical_ip, v8::NewStringType::kNormal).ToLocalChecked(); args.GetReturnValue().Set(val); } void GetAddrInfo(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); CHECK(args[0]->IsObject()); CHECK(args[1]->IsString()); CHECK(args[2]->IsInt32()); CHECK(args[4]->IsBoolean()); Local req_wrap_obj = args[0].As(); node::Utf8Value hostname(env->isolate(), args[1]); int32_t flags = 0; if (args[3]->IsInt32()) { flags = args[3].As()->Value(); } int family; switch (args[2].As()->Value()) { case 0: family = AF_UNSPEC; break; case 4: family = AF_INET; break; case 6: family = AF_INET6; break; default: CHECK(0 && "bad address family"); } auto req_wrap = std::make_unique(env, req_wrap_obj, args[4]->IsTrue()); struct addrinfo hints; memset(&hints, 0, sizeof(struct addrinfo)); hints.ai_family = family; hints.ai_socktype = SOCK_STREAM; hints.ai_flags = flags; TRACE_EVENT_NESTABLE_ASYNC_BEGIN2( TRACING_CATEGORY_NODE2(dns, native), "lookup", req_wrap.get(), "hostname", TRACE_STR_COPY(*hostname), "family", family == AF_INET ? "ipv4" : family == AF_INET6 ? "ipv6" : "unspec"); int err = req_wrap->Dispatch(uv_getaddrinfo, AfterGetAddrInfo, *hostname, nullptr, &hints); if (err == 0) // Release ownership of the pointer allowing the ownership to be transferred USE(req_wrap.release()); args.GetReturnValue().Set(err); } void GetNameInfo(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); CHECK(args[0]->IsObject()); CHECK(args[1]->IsString()); CHECK(args[2]->IsUint32()); Local req_wrap_obj = args[0].As(); node::Utf8Value ip(env->isolate(), args[1]); const unsigned port = args[2]->Uint32Value(env->context()).FromJust(); struct sockaddr_storage addr; CHECK(uv_ip4_addr(*ip, port, reinterpret_cast(&addr)) == 0 || uv_ip6_addr(*ip, port, reinterpret_cast(&addr)) == 0); auto req_wrap = std::make_unique(env, req_wrap_obj); TRACE_EVENT_NESTABLE_ASYNC_BEGIN2( TRACING_CATEGORY_NODE2(dns, native), "lookupService", req_wrap.get(), "ip", TRACE_STR_COPY(*ip), "port", port); int err = req_wrap->Dispatch(uv_getnameinfo, AfterGetNameInfo, reinterpret_cast(&addr), NI_NAMEREQD); if (err == 0) // Release ownership of the pointer allowing the ownership to be transferred USE(req_wrap.release()); args.GetReturnValue().Set(err); } void GetServers(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); ChannelWrap* channel; ASSIGN_OR_RETURN_UNWRAP(&channel, args.Holder()); Local server_array = Array::New(env->isolate()); ares_addr_port_node* servers; int r = ares_get_servers_ports(channel->cares_channel(), &servers); CHECK_EQ(r, ARES_SUCCESS); ares_addr_port_node* cur = servers; for (uint32_t i = 0; cur != nullptr; ++i, cur = cur->next) { char ip[INET6_ADDRSTRLEN]; const void* caddr = static_cast(&cur->addr); int err = uv_inet_ntop(cur->family, caddr, ip, sizeof(ip)); CHECK_EQ(err, 0); Local ret = Array::New(env->isolate(), 2); ret->Set(0, OneByteString(env->isolate(), ip)); ret->Set(1, Integer::New(env->isolate(), cur->udp_port)); server_array->Set(i, ret); } ares_free_data(servers); args.GetReturnValue().Set(server_array); } void SetServers(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); ChannelWrap* channel; ASSIGN_OR_RETURN_UNWRAP(&channel, args.Holder()); if (channel->active_query_count()) { return args.GetReturnValue().Set(DNS_ESETSRVPENDING); } CHECK(args[0]->IsArray()); Local arr = Local::Cast(args[0]); uint32_t len = arr->Length(); if (len == 0) { int rv = ares_set_servers(channel->cares_channel(), nullptr); return args.GetReturnValue().Set(rv); } std::vector servers(len); ares_addr_port_node* last = nullptr; int err; for (uint32_t i = 0; i < len; i++) { CHECK(arr->Get(env->context(), i).ToLocalChecked()->IsArray()); Local elm = Local::Cast(arr->Get(env->context(), i).ToLocalChecked()); CHECK(elm->Get(env->context(), 0).ToLocalChecked()->Int32Value(env->context()).FromJust()); CHECK(elm->Get(env->context(), 1).ToLocalChecked()->IsString()); CHECK(elm->Get(env->context(), 2).ToLocalChecked()->Int32Value(env->context()).FromJust()); int fam = elm->Get(env->context(), 0) .ToLocalChecked()->Int32Value(env->context()).FromJust(); node::Utf8Value ip(env->isolate(), elm->Get(env->context(), 1).ToLocalChecked()); int port = elm->Get(env->context(), 2) .ToLocalChecked()->Int32Value(env->context()).FromJust(); ares_addr_port_node* cur = &servers[i]; cur->tcp_port = cur->udp_port = port; switch (fam) { case 4: cur->family = AF_INET; err = uv_inet_pton(AF_INET, *ip, &cur->addr); break; case 6: cur->family = AF_INET6; err = uv_inet_pton(AF_INET6, *ip, &cur->addr); break; default: CHECK(0 && "Bad address family."); } if (err) break; cur->next = nullptr; if (last != nullptr) last->next = cur; last = cur; } if (err == 0) err = ares_set_servers_ports(channel->cares_channel(), &servers[0]); else err = ARES_EBADSTR; if (err == ARES_SUCCESS) channel->set_is_servers_default(false); args.GetReturnValue().Set(err); } void Cancel(const FunctionCallbackInfo& args) { ChannelWrap* channel; ASSIGN_OR_RETURN_UNWRAP(&channel, args.Holder()); TRACE_EVENT_INSTANT0(TRACING_CATEGORY_NODE2(dns, native), "cancel", TRACE_EVENT_SCOPE_THREAD); ares_cancel(channel->cares_channel()); } const char EMSG_ESETSRVPENDING[] = "There are pending queries."; void StrError(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); int code = args[0]->Int32Value(env->context()).FromJust(); const char* errmsg = (code == DNS_ESETSRVPENDING) ? EMSG_ESETSRVPENDING : ares_strerror(code); args.GetReturnValue().Set(OneByteString(env->isolate(), errmsg)); } void Initialize(Local target, Local unused, Local context) { Environment* env = Environment::GetCurrent(context); env->SetMethod(target, "getaddrinfo", GetAddrInfo); env->SetMethod(target, "getnameinfo", GetNameInfo); env->SetMethodNoSideEffect(target, "canonicalizeIP", CanonicalizeIP); env->SetMethod(target, "strerror", StrError); target->Set(FIXED_ONE_BYTE_STRING(env->isolate(), "AF_INET"), Integer::New(env->isolate(), AF_INET)); target->Set(FIXED_ONE_BYTE_STRING(env->isolate(), "AF_INET6"), Integer::New(env->isolate(), AF_INET6)); target->Set(FIXED_ONE_BYTE_STRING(env->isolate(), "AF_UNSPEC"), Integer::New(env->isolate(), AF_UNSPEC)); target->Set(FIXED_ONE_BYTE_STRING(env->isolate(), "AI_ADDRCONFIG"), Integer::New(env->isolate(), AI_ADDRCONFIG)); target->Set(FIXED_ONE_BYTE_STRING(env->isolate(), "AI_V4MAPPED"), Integer::New(env->isolate(), AI_V4MAPPED)); Local aiw = BaseObject::MakeLazilyInitializedJSTemplate(env); aiw->Inherit(AsyncWrap::GetConstructorTemplate(env)); Local addrInfoWrapString = FIXED_ONE_BYTE_STRING(env->isolate(), "GetAddrInfoReqWrap"); aiw->SetClassName(addrInfoWrapString); target->Set(addrInfoWrapString, aiw->GetFunction(context).ToLocalChecked()); Local niw = BaseObject::MakeLazilyInitializedJSTemplate(env); niw->Inherit(AsyncWrap::GetConstructorTemplate(env)); Local nameInfoWrapString = FIXED_ONE_BYTE_STRING(env->isolate(), "GetNameInfoReqWrap"); niw->SetClassName(nameInfoWrapString); target->Set(nameInfoWrapString, niw->GetFunction(context).ToLocalChecked()); Local qrw = BaseObject::MakeLazilyInitializedJSTemplate(env); qrw->Inherit(AsyncWrap::GetConstructorTemplate(env)); Local queryWrapString = FIXED_ONE_BYTE_STRING(env->isolate(), "QueryReqWrap"); qrw->SetClassName(queryWrapString); target->Set(queryWrapString, qrw->GetFunction(context).ToLocalChecked()); Local channel_wrap = env->NewFunctionTemplate(ChannelWrap::New); channel_wrap->InstanceTemplate()->SetInternalFieldCount(1); channel_wrap->Inherit(AsyncWrap::GetConstructorTemplate(env)); env->SetProtoMethod(channel_wrap, "queryAny", Query); env->SetProtoMethod(channel_wrap, "queryA", Query); env->SetProtoMethod(channel_wrap, "queryAaaa", Query); env->SetProtoMethod(channel_wrap, "queryCname", Query); env->SetProtoMethod(channel_wrap, "queryMx", Query); env->SetProtoMethod(channel_wrap, "queryNs", Query); env->SetProtoMethod(channel_wrap, "queryTxt", Query); env->SetProtoMethod(channel_wrap, "querySrv", Query); env->SetProtoMethod(channel_wrap, "queryPtr", Query); env->SetProtoMethod(channel_wrap, "queryNaptr", Query); env->SetProtoMethod(channel_wrap, "querySoa", Query); env->SetProtoMethod(channel_wrap, "getHostByAddr", Query); env->SetProtoMethodNoSideEffect(channel_wrap, "getServers", GetServers); env->SetProtoMethod(channel_wrap, "setServers", SetServers); env->SetProtoMethod(channel_wrap, "cancel", Cancel); Local channelWrapString = FIXED_ONE_BYTE_STRING(env->isolate(), "ChannelWrap"); channel_wrap->SetClassName(channelWrapString); target->Set(channelWrapString, channel_wrap->GetFunction(context).ToLocalChecked()); } } // anonymous namespace } // namespace cares_wrap } // namespace node NODE_BUILTIN_MODULE_CONTEXT_AWARE(cares_wrap, node::cares_wrap::Initialize)