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140 lines
4.4 KiB
C++
140 lines
4.4 KiB
C++
// Copyright 2018-2019 the Deno authors. All rights reserved. MIT license.
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#ifndef BUFFER_H_
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#define BUFFER_H_
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// Cpplint bans the use of <mutex> because it duplicates functionality in
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// chromium //base. However Deno doensn't use that, so suppress that lint.
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#include <memory>
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#include <mutex> // NOLINT
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#include <string>
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#include <unordered_map>
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#include <utility>
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#include "third_party/v8/include/v8.h"
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#include "third_party/v8/src/base/logging.h"
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namespace deno {
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class ArrayBufferAllocator : public v8::ArrayBuffer::Allocator {
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public:
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static ArrayBufferAllocator& global() {
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static ArrayBufferAllocator global_instance;
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return global_instance;
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}
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void* Allocate(size_t length) override { return new uint8_t[length](); }
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void* AllocateUninitialized(size_t length) override {
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return new uint8_t[length];
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}
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void Free(void* data, size_t length) override { Unref(data); }
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private:
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friend class PinnedBuf;
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void Ref(void* data) {
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std::lock_guard<std::mutex> lock(ref_count_map_mutex_);
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// Note:
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// - `unordered_map::insert(make_pair(key, value))` returns the existing
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// item if the key, already exists in the map, otherwise it creates an
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// new entry with `value`.
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// - Buffers not in the map have an implicit reference count of one.
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auto entry = ref_count_map_.insert(std::make_pair(data, 1)).first;
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++entry->second;
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}
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void Unref(void* data) {
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{
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std::lock_guard<std::mutex> lock(ref_count_map_mutex_);
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auto entry = ref_count_map_.find(data);
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if (entry == ref_count_map_.end()) {
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// Buffers not in the map have an implicit ref count of one. After
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// dereferencing there are no references left, so we delete the buffer.
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} else if (--entry->second == 0) {
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// The reference count went to zero, so erase the map entry and free the
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// buffer.
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ref_count_map_.erase(entry);
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} else {
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// After decreasing the reference count the buffer still has references
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// left, so we leave the pin in place.
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return;
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}
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delete[] reinterpret_cast<uint8_t*>(data);
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}
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}
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private:
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ArrayBufferAllocator() {}
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~ArrayBufferAllocator() {
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// TODO(pisciaureus): Enable this check. It currently fails sometimes
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// because the compiler worker isolate never actually exits, so when the
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// process exits this isolate still holds on to some buffers.
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// CHECK(ref_count_map_.empty());
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}
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std::unordered_map<void*, size_t> ref_count_map_;
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std::mutex ref_count_map_mutex_;
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};
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class PinnedBuf {
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struct Unref {
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// This callback gets called from the Pin destructor.
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void operator()(void* ptr) { ArrayBufferAllocator::global().Unref(ptr); }
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};
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// The Pin is a unique (non-copyable) smart pointer which automatically
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// unrefs the referenced ArrayBuffer in its destructor.
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using Pin = std::unique_ptr<void, Unref>;
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uint8_t* data_ptr_;
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size_t data_len_;
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Pin pin_;
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public:
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// PinnedBuf::Raw is a POD struct with the same memory layout as the PinBuf
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// itself. It is used to move a PinnedBuf between C and Rust.
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struct Raw {
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uint8_t* data_ptr;
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size_t data_len;
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void* pin;
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};
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PinnedBuf() : data_ptr_(nullptr), data_len_(0), pin_() {}
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explicit PinnedBuf(v8::Local<v8::ArrayBufferView> view) {
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auto buf = view->Buffer()->GetContents().Data();
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ArrayBufferAllocator::global().Ref(buf);
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data_ptr_ = reinterpret_cast<uint8_t*>(buf) + view->ByteOffset();
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data_len_ = view->ByteLength();
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pin_ = Pin(buf);
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}
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// This constructor recreates a PinnedBuf that has previously been converted
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// to a PinnedBuf::Raw using the IntoRaw() method. This is a move operation;
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// the Raw struct is emptied in the process.
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explicit PinnedBuf(Raw* raw)
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: data_ptr_(raw->data_ptr), data_len_(raw->data_len), pin_(raw->pin) {
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raw->data_ptr = nullptr;
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raw->data_len = 0;
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raw->pin = nullptr;
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}
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// The IntoRaw() method converts the PinnedBuf to a PinnedBuf::Raw so it's
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// ownership can be moved to Rust. The source PinnedBuf is emptied in the
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// process, but the pinned ArrayBuffer is not dereferenced. In order to not
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// leak it, the raw struct must eventually be turned back into a PinnedBuf
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// using the constructor above.
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Raw IntoRaw() {
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Raw raw{
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.data_ptr = data_ptr_, .data_len = data_len_, .pin = pin_.release()};
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data_ptr_ = nullptr;
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data_len_ = 0;
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return raw;
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}
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};
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} // namespace deno
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#endif // BUFFER_H_
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