// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "net/proxy/proxy_resolver_v8.h" #include #include #include #include "base/auto_reset.h" #include "base/compiler_specific.h" #include "base/debug/leak_annotations.h" #include "base/lazy_instance.h" #include "base/logging.h" #include "base/macros.h" #include "base/strings/string_tokenizer.h" #include "base/strings/string_util.h" #include "base/strings/utf_string_conversions.h" #include "base/synchronization/lock.h" #include "base/threading/thread_task_runner_handle.h" #include "gin/array_buffer.h" #include "gin/public/isolate_holder.h" #include "gin/v8_initializer.h" #include "net/base/ip_address.h" #include "net/base/net_errors.h" #include "net/proxy/proxy_info.h" #include "net/proxy/proxy_resolver_script.h" #include "net/proxy/proxy_resolver_script_data.h" #include "url/gurl.h" #include "url/url_canon.h" #include "v8/include/v8.h" // Notes on the javascript environment: // // For the majority of the PAC utility functions, we use the same code // as Firefox. See the javascript library that proxy_resolver_scipt.h // pulls in. // // In addition, we implement a subset of Microsoft's extensions to PAC. // - myIpAddressEx() // - dnsResolveEx() // - isResolvableEx() // - isInNetEx() // - sortIpAddressList() // // It is worth noting that the original PAC specification does not describe // the return values on failure. Consequently, there are compatibility // differences between browsers on what to return on failure, which are // illustrated below: // // --------------------+-------------+-------------------+-------------- // | Firefox3 | InternetExplorer8 | --> Us <--- // --------------------+-------------+-------------------+-------------- // myIpAddress() | "127.0.0.1" | ??? | "127.0.0.1" // dnsResolve() | null | false | null // myIpAddressEx() | N/A | "" | "" // sortIpAddressList() | N/A | false | false // dnsResolveEx() | N/A | "" | "" // isInNetEx() | N/A | false | false // --------------------+-------------+-------------------+-------------- // // TODO(eroman): The cell above reading ??? means I didn't test it. // // Another difference is in how dnsResolve() and myIpAddress() are // implemented -- whether they should restrict to IPv4 results, or // include both IPv4 and IPv6. The following table illustrates the // differences: // // --------------------+-------------+-------------------+-------------- // | Firefox3 | InternetExplorer8 | --> Us <--- // --------------------+-------------+-------------------+-------------- // myIpAddress() | IPv4/IPv6 | IPv4 | IPv4 // dnsResolve() | IPv4/IPv6 | IPv4 | IPv4 // isResolvable() | IPv4/IPv6 | IPv4 | IPv4 // myIpAddressEx() | N/A | IPv4/IPv6 | IPv4/IPv6 // dnsResolveEx() | N/A | IPv4/IPv6 | IPv4/IPv6 // sortIpAddressList() | N/A | IPv4/IPv6 | IPv4/IPv6 // isResolvableEx() | N/A | IPv4/IPv6 | IPv4/IPv6 // isInNetEx() | N/A | IPv4/IPv6 | IPv4/IPv6 // -----------------+-------------+-------------------+-------------- namespace net { namespace { // Pseudo-name for the PAC script. const char kPacResourceName[] = "proxy-pac-script.js"; // Pseudo-name for the PAC utility script. const char kPacUtilityResourceName[] = "proxy-pac-utility-script.js"; // External string wrapper so V8 can access the UTF16 string wrapped by // ProxyResolverScriptData. class V8ExternalStringFromScriptData : public v8::String::ExternalStringResource { public: explicit V8ExternalStringFromScriptData( const scoped_refptr& script_data) : script_data_(script_data) {} const uint16_t* data() const override { return reinterpret_cast(script_data_->utf16().data()); } size_t length() const override { return script_data_->utf16().size(); } private: const scoped_refptr script_data_; DISALLOW_COPY_AND_ASSIGN(V8ExternalStringFromScriptData); }; // External string wrapper so V8 can access a string literal. class V8ExternalASCIILiteral : public v8::String::ExternalOneByteStringResource { public: // |ascii| must be a NULL-terminated C string, and must remain valid // throughout this object's lifetime. V8ExternalASCIILiteral(const char* ascii, size_t length) : ascii_(ascii), length_(length) { DCHECK(base::IsStringASCII(ascii)); } const char* data() const override { return ascii_; } size_t length() const override { return length_; } private: const char* ascii_; size_t length_; DISALLOW_COPY_AND_ASSIGN(V8ExternalASCIILiteral); }; // When creating a v8::String from a C++ string we have two choices: create // a copy, or create a wrapper that shares the same underlying storage. // For small strings it is better to just make a copy, whereas for large // strings there are savings by sharing the storage. This number identifies // the cutoff length for when to start wrapping rather than creating copies. const size_t kMaxStringBytesForCopy = 256; // Converts a V8 String to a UTF8 std::string. std::string V8StringToUTF8(v8::Local s) { int len = s->Length(); std::string result; if (len > 0) s->WriteUtf8(base::WriteInto(&result, len + 1)); return result; } // Converts a V8 String to a UTF16 base::string16. base::string16 V8StringToUTF16(v8::Local s) { int len = s->Length(); base::string16 result; // Note that the reinterpret cast is because on Windows string16 is an alias // to wstring, and hence has character type wchar_t not uint16_t. if (len > 0) { s->Write(reinterpret_cast(base::WriteInto(&result, len + 1)), 0, len); } return result; } // Converts an ASCII std::string to a V8 string. v8::Local ASCIIStringToV8String(v8::Isolate* isolate, const std::string& s) { DCHECK(base::IsStringASCII(s)); return v8::String::NewFromUtf8(isolate, s.data(), v8::NewStringType::kNormal, s.size()).ToLocalChecked(); } // Converts a UTF16 base::string16 (warpped by a ProxyResolverScriptData) to a // V8 string. v8::Local ScriptDataToV8String( v8::Isolate* isolate, const scoped_refptr& s) { if (s->utf16().size() * 2 <= kMaxStringBytesForCopy) { return v8::String::NewFromTwoByte( isolate, reinterpret_cast(s->utf16().data()), v8::NewStringType::kNormal, s->utf16().size()).ToLocalChecked(); } return v8::String::NewExternalTwoByte( isolate, new V8ExternalStringFromScriptData(s)).ToLocalChecked(); } // Converts an ASCII string literal to a V8 string. v8::Local ASCIILiteralToV8String(v8::Isolate* isolate, const char* ascii) { DCHECK(base::IsStringASCII(ascii)); size_t length = strlen(ascii); if (length <= kMaxStringBytesForCopy) return v8::String::NewFromUtf8(isolate, ascii, v8::NewStringType::kNormal, length).ToLocalChecked(); return v8::String::NewExternalOneByte( isolate, new V8ExternalASCIILiteral(ascii, length)) .ToLocalChecked(); } // Stringizes a V8 object by calling its toString() method. Returns true // on success. This may fail if the toString() throws an exception. bool V8ObjectToUTF16String(v8::Local object, base::string16* utf16_result, v8::Isolate* isolate) { if (object.IsEmpty()) return false; v8::HandleScope scope(isolate); v8::Local str_object; if (!object->ToString(isolate->GetCurrentContext()).ToLocal(&str_object)) return false; *utf16_result = V8StringToUTF16(str_object); return true; } // Extracts an hostname argument from |args|. On success returns true // and fills |*hostname| with the result. bool GetHostnameArgument(const v8::FunctionCallbackInfo& args, std::string* hostname) { // The first argument should be a string. if (args.Length() == 0 || args[0].IsEmpty() || !args[0]->IsString()) return false; const base::string16 hostname_utf16 = V8StringToUTF16(v8::Local::Cast(args[0])); // If the hostname is already in ASCII, simply return it as is. if (base::IsStringASCII(hostname_utf16)) { *hostname = base::UTF16ToASCII(hostname_utf16); return true; } // Otherwise try to convert it from IDN to punycode. const int kInitialBufferSize = 256; url::RawCanonOutputT punycode_output; if (!url::IDNToASCII(hostname_utf16.data(), hostname_utf16.length(), &punycode_output)) { return false; } // |punycode_output| should now be ASCII; convert it to a std::string. // (We could use UTF16ToASCII() instead, but that requires an extra string // copy. Since ASCII is a subset of UTF8 the following is equivalent). bool success = base::UTF16ToUTF8(punycode_output.data(), punycode_output.length(), hostname); DCHECK(success); DCHECK(base::IsStringASCII(*hostname)); return success; } // Wrapper around an IP address that stores the original string as well as a // corresponding parsed IPAddress. // This struct is used as a helper for sorting IP address strings - the IP // literal is parsed just once and used as the sorting key, while also // preserving the original IP literal string. struct IPAddressSortingEntry { IPAddressSortingEntry(const std::string& ip_string, const IPAddress& ip_address) : string_value(ip_string), ip_address(ip_address) {} // Used for sorting IP addresses in ascending order in SortIpAddressList(). // IPv6 addresses are placed ahead of IPv4 addresses. bool operator<(const IPAddressSortingEntry& rhs) const { const IPAddress& ip1 = this->ip_address; const IPAddress& ip2 = rhs.ip_address; if (ip1.size() != ip2.size()) return ip1.size() > ip2.size(); // IPv6 before IPv4. return ip1 < ip2; // Ascending order. } std::string string_value; IPAddress ip_address; }; // Handler for "sortIpAddressList(IpAddressList)". |ip_address_list| is a // semi-colon delimited string containing IP addresses. // |sorted_ip_address_list| is the resulting list of sorted semi-colon delimited // IP addresses or an empty string if unable to sort the IP address list. // Returns 'true' if the sorting was successful, and 'false' if the input was an // empty string, a string of separators (";" in this case), or if any of the IP // addresses in the input list failed to parse. bool SortIpAddressList(const std::string& ip_address_list, std::string* sorted_ip_address_list) { sorted_ip_address_list->clear(); // Strip all whitespace (mimics IE behavior). std::string cleaned_ip_address_list; base::RemoveChars(ip_address_list, " \t", &cleaned_ip_address_list); if (cleaned_ip_address_list.empty()) return false; // Split-up IP addresses and store them in a vector. std::vector ip_vector; IPAddress ip_address; base::StringTokenizer str_tok(cleaned_ip_address_list, ";"); while (str_tok.GetNext()) { if (!ip_address.AssignFromIPLiteral(str_tok.token())) return false; ip_vector.push_back(IPAddressSortingEntry(str_tok.token(), ip_address)); } if (ip_vector.empty()) // Can happen if we have something like return false; // sortIpAddressList(";") or sortIpAddressList("; ;") DCHECK(!ip_vector.empty()); // Sort lists according to ascending numeric value. if (ip_vector.size() > 1) std::stable_sort(ip_vector.begin(), ip_vector.end()); // Return a semi-colon delimited list of sorted addresses (IPv6 followed by // IPv4). for (size_t i = 0; i < ip_vector.size(); ++i) { if (i > 0) *sorted_ip_address_list += ";"; *sorted_ip_address_list += ip_vector[i].string_value; } return true; } // Handler for "isInNetEx(ip_address, ip_prefix)". |ip_address| is a string // containing an IPv4/IPv6 address, and |ip_prefix| is a string containg a // slash-delimited IP prefix with the top 'n' bits specified in the bit // field. This returns 'true' if the address is in the same subnet, and // 'false' otherwise. Also returns 'false' if the prefix is in an incorrect // format, or if an address and prefix of different types are used (e.g. IPv6 // address and IPv4 prefix). bool IsInNetEx(const std::string& ip_address, const std::string& ip_prefix) { IPAddress address; if (!address.AssignFromIPLiteral(ip_address)) return false; IPAddress prefix; size_t prefix_length_in_bits; if (!ParseCIDRBlock(ip_prefix, &prefix, &prefix_length_in_bits)) return false; // Both |address| and |prefix| must be of the same type (IPv4 or IPv6). if (address.size() != prefix.size()) return false; DCHECK((address.IsIPv4() && prefix.IsIPv4()) || (address.IsIPv6() && prefix.IsIPv6())); return IPAddressMatchesPrefix(address, prefix, prefix_length_in_bits); } // Consider only single component domains like 'foo' as plain host names. bool IsPlainHostName(const std::string& hostname_utf8) { if (hostname_utf8.find('.') != std::string::npos) return false; // IPv6 literals might not contain any periods, however are not considered // plain host names. IPAddress unused; return !unused.AssignFromIPLiteral(hostname_utf8); } // All instances of ProxyResolverV8 share the same v8::Isolate. This isolate is // created lazily the first time it is needed and lives until process shutdown. // This creation might happen from any thread, as ProxyResolverV8 is typically // run in a threadpool. // // TODO(eroman): The lazily created isolate is never freed. Instead it should be // disposed once there are no longer any ProxyResolverV8 referencing it. class SharedIsolateFactory { public: SharedIsolateFactory() : has_initialized_v8_(false) {} // Lazily creates a v8::Isolate, or returns the already created instance. v8::Isolate* GetSharedIsolate() { base::AutoLock lock(lock_); if (!holder_) { // Do one-time initialization for V8. if (!has_initialized_v8_) { #ifdef V8_USE_EXTERNAL_STARTUP_DATA gin::V8Initializer::LoadV8Snapshot(); gin::V8Initializer::LoadV8Natives(); #endif // The performance of the proxy resolver is limited by DNS resolution, // and not V8, so tune down V8 to use as little memory as possible. static const char kOptimizeForSize[] = "--optimize_for_size"; v8::V8::SetFlagsFromString(kOptimizeForSize, strlen(kOptimizeForSize)); static const char kNoOpt[] = "--noopt"; v8::V8::SetFlagsFromString(kNoOpt, strlen(kNoOpt)); gin::IsolateHolder::Initialize( gin::IsolateHolder::kNonStrictMode, gin::IsolateHolder::kStableV8Extras, gin::ArrayBufferAllocator::SharedInstance()); has_initialized_v8_ = true; } holder_.reset(new gin::IsolateHolder(base::ThreadTaskRunnerHandle::Get(), gin::IsolateHolder::kUseLocker)); } return holder_->isolate(); } v8::Isolate* GetSharedIsolateWithoutCreating() { base::AutoLock lock(lock_); return holder_ ? holder_->isolate() : NULL; } private: base::Lock lock_; std::unique_ptr holder_; bool has_initialized_v8_; DISALLOW_COPY_AND_ASSIGN(SharedIsolateFactory); }; base::LazyInstance::Leaky g_isolate_factory = LAZY_INSTANCE_INITIALIZER; } // namespace // ProxyResolverV8::Context --------------------------------------------------- class ProxyResolverV8::Context { public: explicit Context(v8::Isolate* isolate) : js_bindings_(nullptr), isolate_(isolate) { DCHECK(isolate); } ~Context() { v8::Locker locked(isolate_); v8::Isolate::Scope isolate_scope(isolate_); v8_this_.Reset(); v8_context_.Reset(); } JSBindings* js_bindings() { return js_bindings_; } int ResolveProxy(const GURL& query_url, ProxyInfo* results, JSBindings* bindings) { DCHECK(bindings); base::AutoReset bindings_reset(&js_bindings_, bindings); v8::Locker locked(isolate_); v8::Isolate::Scope isolate_scope(isolate_); v8::HandleScope scope(isolate_); v8::Local context = v8::Local::New(isolate_, v8_context_); v8::Context::Scope function_scope(context); v8::Local function; int rv = GetFindProxyForURL(&function); if (rv != OK) return rv; v8::Local argv[] = { ASCIIStringToV8String(isolate_, query_url.spec()), ASCIIStringToV8String(isolate_, query_url.HostNoBrackets()), }; v8::TryCatch try_catch(isolate_); v8::Local ret; if (!v8::Function::Cast(*function) ->Call(context, context->Global(), arraysize(argv), argv) .ToLocal(&ret)) { DCHECK(try_catch.HasCaught()); HandleError(try_catch.Message()); return ERR_PAC_SCRIPT_FAILED; } if (!ret->IsString()) { js_bindings()->OnError( -1, base::ASCIIToUTF16("FindProxyForURL() did not return a string.")); return ERR_PAC_SCRIPT_FAILED; } base::string16 ret_str = V8StringToUTF16(v8::Local::Cast(ret)); if (!base::IsStringASCII(ret_str)) { // TODO(eroman): Rather than failing when a wide string is returned, we // could extend the parsing to handle IDNA hostnames by // converting them to ASCII punycode. // crbug.com/47234 base::string16 error_message = base::ASCIIToUTF16("FindProxyForURL() returned a non-ASCII string " "(crbug.com/47234): ") + ret_str; js_bindings()->OnError(-1, error_message); return ERR_PAC_SCRIPT_FAILED; } results->UsePacString(base::UTF16ToASCII(ret_str)); return OK; } int InitV8(const scoped_refptr& pac_script, JSBindings* bindings) { base::AutoReset bindings_reset(&js_bindings_, bindings); v8::Locker locked(isolate_); v8::Isolate::Scope isolate_scope(isolate_); v8::HandleScope scope(isolate_); v8_this_.Reset(isolate_, v8::External::New(isolate_, this)); v8::Local v8_this = v8::Local::New(isolate_, v8_this_); v8::Local global_template = v8::ObjectTemplate::New(isolate_); // Attach the javascript bindings. v8::Local alert_template = v8::FunctionTemplate::New(isolate_, &AlertCallback, v8_this); alert_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "alert"), alert_template); v8::Local my_ip_address_template = v8::FunctionTemplate::New(isolate_, &MyIpAddressCallback, v8_this); my_ip_address_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "myIpAddress"), my_ip_address_template); v8::Local dns_resolve_template = v8::FunctionTemplate::New(isolate_, &DnsResolveCallback, v8_this); dns_resolve_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "dnsResolve"), dns_resolve_template); v8::Local is_plain_host_name_template = v8::FunctionTemplate::New(isolate_, &IsPlainHostNameCallback, v8_this); is_plain_host_name_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "isPlainHostName"), is_plain_host_name_template); // Microsoft's PAC extensions: v8::Local dns_resolve_ex_template = v8::FunctionTemplate::New(isolate_, &DnsResolveExCallback, v8_this); dns_resolve_ex_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "dnsResolveEx"), dns_resolve_ex_template); v8::Local my_ip_address_ex_template = v8::FunctionTemplate::New(isolate_, &MyIpAddressExCallback, v8_this); my_ip_address_ex_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "myIpAddressEx"), my_ip_address_ex_template); v8::Local sort_ip_address_list_template = v8::FunctionTemplate::New(isolate_, &SortIpAddressListCallback, v8_this); sort_ip_address_list_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "sortIpAddressList"), sort_ip_address_list_template); v8::Local is_in_net_ex_template = v8::FunctionTemplate::New(isolate_, &IsInNetExCallback, v8_this); is_in_net_ex_template->RemovePrototype(); global_template->Set(ASCIILiteralToV8String(isolate_, "isInNetEx"), is_in_net_ex_template); v8_context_.Reset( isolate_, v8::Context::New(isolate_, NULL, global_template)); v8::Local context = v8::Local::New(isolate_, v8_context_); v8::Context::Scope ctx(context); // Add the PAC utility functions to the environment. // (This script should never fail, as it is a string literal!) // Note that the two string literals are concatenated. int rv = RunScript( ASCIILiteralToV8String( isolate_, PROXY_RESOLVER_SCRIPT PROXY_RESOLVER_SCRIPT_EX), kPacUtilityResourceName); if (rv != OK) { NOTREACHED(); return rv; } // Add the user's PAC code to the environment. rv = RunScript(ScriptDataToV8String(isolate_, pac_script), kPacResourceName); if (rv != OK) return rv; // At a minimum, the FindProxyForURL() function must be defined for this // to be a legitimiate PAC script. v8::Local function; return GetFindProxyForURL(&function); } private: int GetFindProxyForURL(v8::Local* function) { v8::Local context = v8::Local::New(isolate_, v8_context_); v8::TryCatch try_catch(isolate_); if (!context->Global() ->Get(context, ASCIILiteralToV8String(isolate_, "FindProxyForURL")) .ToLocal(function)) { DCHECK(try_catch.HasCaught()); HandleError(try_catch.Message()); } // The value should only be empty if an exception was thrown. Code // defensively just in case. DCHECK_EQ(function->IsEmpty(), try_catch.HasCaught()); if (function->IsEmpty() || try_catch.HasCaught()) { js_bindings()->OnError( -1, base::ASCIIToUTF16("Accessing FindProxyForURL threw an exception.")); return ERR_PAC_SCRIPT_FAILED; } if (!(*function)->IsFunction()) { js_bindings()->OnError( -1, base::ASCIIToUTF16( "FindProxyForURL is undefined or not a function.")); return ERR_PAC_SCRIPT_FAILED; } return OK; } // Handle an exception thrown by V8. void HandleError(v8::Local message) { v8::Local context = v8::Local::New(isolate_, v8_context_); base::string16 error_message; int line_number = -1; if (!message.IsEmpty()) { auto maybe = message->GetLineNumber(context); if (maybe.IsJust()) line_number = maybe.FromJust(); V8ObjectToUTF16String(message->Get(), &error_message, isolate_); } js_bindings()->OnError(line_number, error_message); } // Compiles and runs |script| in the current V8 context. // Returns OK on success, otherwise an error code. int RunScript(v8::Local script, const char* script_name) { v8::Local context = v8::Local::New(isolate_, v8_context_); v8::TryCatch try_catch(isolate_); // Compile the script. v8::ScriptOrigin origin = v8::ScriptOrigin(ASCIILiteralToV8String(isolate_, script_name)); v8::Local code; if (!v8::Script::Compile(context, script, &origin).ToLocal(&code)) { DCHECK(try_catch.HasCaught()); HandleError(try_catch.Message()); return ERR_PAC_SCRIPT_FAILED; } // Execute. auto result = code->Run(context); if (result.IsEmpty()) { DCHECK(try_catch.HasCaught()); HandleError(try_catch.Message()); return ERR_PAC_SCRIPT_FAILED; } return OK; } // V8 callback for when "alert()" is invoked by the PAC script. static void AlertCallback(const v8::FunctionCallbackInfo& args) { Context* context = static_cast(v8::External::Cast(*args.Data())->Value()); // Like firefox we assume "undefined" if no argument was specified, and // disregard any arguments beyond the first. base::string16 message; if (args.Length() == 0) { message = base::ASCIIToUTF16("undefined"); } else { if (!V8ObjectToUTF16String(args[0], &message, args.GetIsolate())) return; // toString() threw an exception. } context->js_bindings()->Alert(message); } // V8 callback for when "myIpAddress()" is invoked by the PAC script. static void MyIpAddressCallback( const v8::FunctionCallbackInfo& args) { DnsResolveCallbackHelper(args, JSBindings::MY_IP_ADDRESS); } // V8 callback for when "myIpAddressEx()" is invoked by the PAC script. static void MyIpAddressExCallback( const v8::FunctionCallbackInfo& args) { DnsResolveCallbackHelper(args, JSBindings::MY_IP_ADDRESS_EX); } // V8 callback for when "dnsResolve()" is invoked by the PAC script. static void DnsResolveCallback( const v8::FunctionCallbackInfo& args) { DnsResolveCallbackHelper(args, JSBindings::DNS_RESOLVE); } // V8 callback for when "dnsResolveEx()" is invoked by the PAC script. static void DnsResolveExCallback( const v8::FunctionCallbackInfo& args) { DnsResolveCallbackHelper(args, JSBindings::DNS_RESOLVE_EX); } // Shared code for implementing: // - myIpAddress(), myIpAddressEx(), dnsResolve(), dnsResolveEx(). static void DnsResolveCallbackHelper( const v8::FunctionCallbackInfo& args, JSBindings::ResolveDnsOperation op) { Context* context = static_cast(v8::External::Cast(*args.Data())->Value()); std::string hostname; // dnsResolve() and dnsResolveEx() need at least 1 argument. if (op == JSBindings::DNS_RESOLVE || op == JSBindings::DNS_RESOLVE_EX) { if (!GetHostnameArgument(args, &hostname)) { if (op == JSBindings::DNS_RESOLVE) args.GetReturnValue().SetNull(); return; } } std::string result; bool success; bool terminate = false; { v8::Unlocker unlocker(args.GetIsolate()); success = context->js_bindings()->ResolveDns( hostname, op, &result, &terminate); } if (terminate) args.GetIsolate()->TerminateExecution(); if (success) { args.GetReturnValue().Set( ASCIIStringToV8String(args.GetIsolate(), result)); return; } // Each function handles resolution errors differently. switch (op) { case JSBindings::DNS_RESOLVE: args.GetReturnValue().SetNull(); return; case JSBindings::DNS_RESOLVE_EX: args.GetReturnValue().SetEmptyString(); return; case JSBindings::MY_IP_ADDRESS: args.GetReturnValue().Set( ASCIILiteralToV8String(args.GetIsolate(), "127.0.0.1")); return; case JSBindings::MY_IP_ADDRESS_EX: args.GetReturnValue().SetEmptyString(); return; } NOTREACHED(); } // V8 callback for when "sortIpAddressList()" is invoked by the PAC script. static void SortIpAddressListCallback( const v8::FunctionCallbackInfo& args) { // We need at least one string argument. if (args.Length() == 0 || args[0].IsEmpty() || !args[0]->IsString()) { args.GetReturnValue().SetNull(); return; } std::string ip_address_list = V8StringToUTF8(v8::Local::Cast(args[0])); if (!base::IsStringASCII(ip_address_list)) { args.GetReturnValue().SetNull(); return; } std::string sorted_ip_address_list; bool success = SortIpAddressList(ip_address_list, &sorted_ip_address_list); if (!success) { args.GetReturnValue().Set(false); return; } args.GetReturnValue().Set( ASCIIStringToV8String(args.GetIsolate(), sorted_ip_address_list)); } // V8 callback for when "isInNetEx()" is invoked by the PAC script. static void IsInNetExCallback( const v8::FunctionCallbackInfo& args) { // We need at least 2 string arguments. if (args.Length() < 2 || args[0].IsEmpty() || !args[0]->IsString() || args[1].IsEmpty() || !args[1]->IsString()) { args.GetReturnValue().SetNull(); return; } std::string ip_address = V8StringToUTF8(v8::Local::Cast(args[0])); if (!base::IsStringASCII(ip_address)) { args.GetReturnValue().Set(false); return; } std::string ip_prefix = V8StringToUTF8(v8::Local::Cast(args[1])); if (!base::IsStringASCII(ip_prefix)) { args.GetReturnValue().Set(false); return; } args.GetReturnValue().Set(IsInNetEx(ip_address, ip_prefix)); } // V8 callback for when "isPlainHostName()" is invoked by the PAC script. static void IsPlainHostNameCallback( const v8::FunctionCallbackInfo& args) { // Need at least 1 string arguments. if (args.Length() < 1 || args[0].IsEmpty() || !args[0]->IsString()) { args.GetIsolate()->ThrowException( v8::Exception::TypeError(ASCIIStringToV8String( args.GetIsolate(), "Requires 1 string parameter"))); return; } std::string hostname_utf8 = V8StringToUTF8(v8::Local::Cast(args[0])); args.GetReturnValue().Set(IsPlainHostName(hostname_utf8)); } mutable base::Lock lock_; ProxyResolverV8::JSBindings* js_bindings_; v8::Isolate* isolate_; v8::Persistent v8_this_; v8::Persistent v8_context_; }; // ProxyResolverV8 ------------------------------------------------------------ ProxyResolverV8::ProxyResolverV8(std::unique_ptr context) : context_(std::move(context)) { DCHECK(context_); } ProxyResolverV8::~ProxyResolverV8() {} int ProxyResolverV8::GetProxyForURL(const GURL& query_url, ProxyInfo* results, ProxyResolverV8::JSBindings* bindings) { return context_->ResolveProxy(query_url, results, bindings); } // static int ProxyResolverV8::Create( const scoped_refptr& script_data, ProxyResolverV8::JSBindings* js_bindings, std::unique_ptr* resolver) { DCHECK(script_data.get()); DCHECK(js_bindings); if (script_data->utf16().empty()) return ERR_PAC_SCRIPT_FAILED; // Try parsing the PAC script. std::unique_ptr context( new Context(g_isolate_factory.Get().GetSharedIsolate())); int rv = context->InitV8(script_data, js_bindings); if (rv == OK) resolver->reset(new ProxyResolverV8(std::move(context))); return rv; } // static size_t ProxyResolverV8::GetTotalHeapSize() { v8::Isolate* isolate = g_isolate_factory.Get().GetSharedIsolateWithoutCreating(); if (!isolate) return 0; v8::Locker locked(isolate); v8::Isolate::Scope isolate_scope(isolate); v8::HeapStatistics heap_statistics; isolate->GetHeapStatistics(&heap_statistics); return heap_statistics.total_heap_size(); } // static size_t ProxyResolverV8::GetUsedHeapSize() { v8::Isolate* isolate = g_isolate_factory.Get().GetSharedIsolateWithoutCreating(); if (!isolate) return 0; v8::Locker locked(isolate); v8::Isolate::Scope isolate_scope(isolate); v8::HeapStatistics heap_statistics; isolate->GetHeapStatistics(&heap_statistics); return heap_statistics.used_heap_size(); } } // namespace net