// Copyright 2018-2019 the Deno authors. All rights reserved. MIT license. #include #include #include #include #include // Cpplint bans the use of because it duplicates functionality in // chromium //base. However Deno doensn't use that, so suppress this lint. #include // NOLINT #include "third_party/v8/include/libplatform/libplatform.h" #include "third_party/v8/include/v8.h" #include "third_party/v8/src/base/logging.h" #include "deno.h" #include "exceptions.h" #include "file_util.h" #include "internal.h" extern "C" { Deno* deno_new_snapshotter(deno_config config) { CHECK(config.will_snapshot); // TODO(ry) Support loading snapshots before snapshotting. CHECK_NULL(config.load_snapshot.data_ptr); auto* creator = new v8::SnapshotCreator(deno::external_references); auto* isolate = creator->GetIsolate(); auto* d = new deno::DenoIsolate(config); d->snapshot_creator_ = creator; d->AddIsolate(isolate); { v8::Locker locker(isolate); v8::Isolate::Scope isolate_scope(isolate); v8::HandleScope handle_scope(isolate); auto context = v8::Context::New(isolate); d->context_.Reset(isolate, context); creator->SetDefaultContext(context, v8::SerializeInternalFieldsCallback( deno::SerializeInternalFields, nullptr)); deno::InitializeContext(isolate, context); } return reinterpret_cast(d); } Deno* deno_new(deno_config config) { if (config.will_snapshot) { return deno_new_snapshotter(config); } deno::DenoIsolate* d = new deno::DenoIsolate(config); v8::Isolate::CreateParams params; params.array_buffer_allocator = &deno::ArrayBufferAllocator::global(); params.external_references = deno::external_references; if (config.load_snapshot.data_ptr) { params.snapshot_blob = &d->snapshot_; } v8::Isolate* isolate; { #ifdef _WIN32 // Work around an apparent V8 bug where initializing multiple isolates // concurrently leads to a crash. At the time of writing the cause of this // crash is not exactly understood, but it seems to be related to the V8 // internal function win64_unwindinfo::RegisterNonABICompliantCodeRange(), // which didn't exist in older versions of V8. static std::mutex mutex; std::lock_guard lock(mutex); #endif isolate = v8::Isolate::New(params); } d->AddIsolate(isolate); v8::Locker locker(isolate); v8::Isolate::Scope isolate_scope(isolate); { v8::HandleScope handle_scope(isolate); auto context = v8::Context::New(isolate, nullptr, v8::MaybeLocal(), v8::MaybeLocal(), v8::DeserializeInternalFieldsCallback( deno::DeserializeInternalFields, nullptr)); if (!config.load_snapshot.data_ptr) { // If no snapshot is provided, we initialize the context with empty // main source code and source maps. deno::InitializeContext(isolate, context); } d->context_.Reset(isolate, context); } return reinterpret_cast(d); } deno::DenoIsolate* unwrap(Deno* d_) { return reinterpret_cast(d_); } void deno_lock(Deno* d_) { auto* d = unwrap(d_); CHECK_NULL(d->locker_); d->locker_ = new v8::Locker(d->isolate_); } void deno_unlock(Deno* d_) { auto* d = unwrap(d_); CHECK_NOT_NULL(d->locker_); delete d->locker_; d->locker_ = nullptr; } deno_snapshot deno_snapshot_new(Deno* d_) { auto* d = unwrap(d_); CHECK_NOT_NULL(d->snapshot_creator_); d->ClearModules(); d->context_.Reset(); auto blob = d->snapshot_creator_->CreateBlob( v8::SnapshotCreator::FunctionCodeHandling::kKeep); d->has_snapshotted_ = true; return {reinterpret_cast(const_cast(blob.data)), blob.raw_size}; } void deno_snapshot_delete(deno_snapshot snapshot) { delete[] snapshot.data_ptr; } static std::unique_ptr platform; void deno_init() { if (platform.get() == nullptr) { platform = v8::platform::NewDefaultPlatform(); v8::V8::InitializePlatform(platform.get()); v8::V8::Initialize(); } } const char* deno_v8_version() { return v8::V8::GetVersion(); } void deno_set_v8_flags(int* argc, char** argv) { v8::V8::SetFlagsFromCommandLine(argc, argv, true); } const char* deno_last_exception(Deno* d_) { auto* d = unwrap(d_); if (d->last_exception_.length() > 0) { return d->last_exception_.c_str(); } else { return nullptr; } } void deno_execute(Deno* d_, void* user_data, const char* js_filename, const char* js_source) { auto* d = unwrap(d_); deno::UserDataScope user_data_scope(d, user_data); auto* isolate = d->isolate_; v8::Locker locker(isolate); v8::Isolate::Scope isolate_scope(isolate); v8::HandleScope handle_scope(isolate); auto context = d->context_.Get(d->isolate_); CHECK(!context.IsEmpty()); deno::Execute(context, js_filename, js_source); } void deno_pinned_buf_delete(deno_pinned_buf* buf) { // The PinnedBuf destructor implicitly releases the ArrayBuffer reference. auto _ = deno::PinnedBuf(*buf); } void deno_respond(Deno* d_, void* user_data, deno_buf buf) { auto* d = unwrap(d_); if (d->current_args_ != nullptr) { // Synchronous response. if (buf.data_ptr != nullptr) { auto ab = deno::ImportBuf(d, buf); d->current_args_->GetReturnValue().Set(ab); } d->current_args_ = nullptr; return; } // Asynchronous response. deno::UserDataScope user_data_scope(d, user_data); v8::Locker locker(d->isolate_); v8::Isolate::Scope isolate_scope(d->isolate_); v8::HandleScope handle_scope(d->isolate_); auto context = d->context_.Get(d->isolate_); v8::Context::Scope context_scope(context); v8::TryCatch try_catch(d->isolate_); auto recv_ = d->recv_.Get(d->isolate_); if (recv_.IsEmpty()) { d->last_exception_ = "Deno.core.recv has not been called."; return; } v8::Local args[1]; int argc = 0; if (buf.data_ptr != nullptr) { args[0] = deno::ImportBuf(d, buf); argc = 1; } auto v = recv_->Call(context, context->Global(), argc, args); if (try_catch.HasCaught()) { CHECK(v.IsEmpty()); deno::HandleException(context, try_catch.Exception()); } } void deno_check_promise_errors(Deno* d_) { auto* d = unwrap(d_); if (d->pending_promise_map_.size() > 0) { auto* isolate = d->isolate_; v8::Locker locker(isolate); v8::Isolate::Scope isolate_scope(isolate); v8::HandleScope handle_scope(isolate); auto context = d->context_.Get(d->isolate_); v8::Context::Scope context_scope(context); auto it = d->pending_promise_map_.begin(); while (it != d->pending_promise_map_.end()) { auto error = it->second.Get(isolate); deno::HandleException(context, error); it = d->pending_promise_map_.erase(it); } } } void deno_delete(Deno* d_) { deno::DenoIsolate* d = reinterpret_cast(d_); delete d; } void deno_terminate_execution(Deno* d_) { deno::DenoIsolate* d = reinterpret_cast(d_); d->isolate_->TerminateExecution(); } }