path: root/src/node_file-inl.h

#ifndef SRC_NODE_FILE_INL_H_
#define SRC_NODE_FILE_INL_H_

#if defined(NODE_WANT_INTERNALS) && NODE_WANT_INTERNALS

#include "node_file.h"
#include "req_wrap-inl.h"

namespace node {
namespace fs {

FSContinuationData::FSContinuationData(uv_fs_t* req, int mode, uv_fs_cb done_cb)
  : done_cb_(done_cb), req_(req), mode_(mode) {
}

void FSContinuationData::PushPath(std::string&& path) {
  paths_.emplace_back(std::move(path));
}

void FSContinuationData::PushPath(const std::string& path) {
  paths_.push_back(path);
}

std::string FSContinuationData::PopPath() {
  CHECK_GT(paths_.size(), 0);
  std::string path = std::move(paths_.back());
  paths_.pop_back();
  return path;
}

void FSContinuationData::Done(int result) {
  req_->result = result;
  done_cb_(req_);
}

FSReqBase::FSReqBase(Environment* env,
          v8::Local<v8::Object> req,
          AsyncWrap::ProviderType type,
          bool use_bigint)
  : ReqWrap(env, req, type), use_bigint_(use_bigint) {
}

void FSReqBase::Init(const char* syscall,
                     const char* data,
                     size_t len,
                     enum encoding encoding) {
  syscall_ = syscall;
  encoding_ = encoding;

  if (data != nullptr) {
    CHECK(!has_data_);
    buffer_.AllocateSufficientStorage(len + 1);
    buffer_.SetLengthAndZeroTerminate(len);
    memcpy(*buffer_, data, len);
    has_data_ = true;
  }
}

FSReqBase::FSReqBuffer&
FSReqBase::Init(const char* syscall, size_t len, enum encoding encoding) {
  syscall_ = syscall;
  encoding_ = encoding;

  buffer_.AllocateSufficientStorage(len + 1);
  has_data_ = false;  // so that the data does not show up in error messages
  return buffer_;
}

FSReqCallback::FSReqCallback(Environment* env,
                             v8::Local<v8::Object> req, bool use_bigint)
  : FSReqBase(env, req, AsyncWrap::PROVIDER_FSREQCALLBACK, use_bigint) {}

template <typename NativeT, typename V8T>
void FillStatsArray(AliasedBufferBase<NativeT, V8T>* fields,
                    const uv_stat_t* s,
                    const size_t offset) {
#define SET_FIELD_WITH_STAT(stat_offset, stat)                               \
  fields->SetValue(offset + static_cast<size_t>(FsStatsOffset::stat_offset), \
                   static_cast<NativeT>(stat))

#define SET_FIELD_WITH_TIME_STAT(stat_offset, stat)                          \
  /* NOLINTNEXTLINE(runtime/int) */                                          \
  SET_FIELD_WITH_STAT(stat_offset, static_cast<unsigned long>(stat))

  SET_FIELD_WITH_STAT(kDev, s->st_dev);
  SET_FIELD_WITH_STAT(kMode, s->st_mode);
  SET_FIELD_WITH_STAT(kNlink, s->st_nlink);
  SET_FIELD_WITH_STAT(kUid, s->st_uid);
  SET_FIELD_WITH_STAT(kGid, s->st_gid);
  SET_FIELD_WITH_STAT(kRdev, s->st_rdev);
  SET_FIELD_WITH_STAT(kBlkSize, s->st_blksize);
  SET_FIELD_WITH_STAT(kIno, s->st_ino);
  SET_FIELD_WITH_STAT(kSize, s->st_size);
  SET_FIELD_WITH_STAT(kBlocks, s->st_blocks);

  SET_FIELD_WITH_TIME_STAT(kATimeSec, s->st_atim.tv_sec);
  SET_FIELD_WITH_TIME_STAT(kATimeNsec, s->st_atim.tv_nsec);
  SET_FIELD_WITH_TIME_STAT(kMTimeSec, s->st_mtim.tv_sec);
  SET_FIELD_WITH_TIME_STAT(kMTimeNsec, s->st_mtim.tv_nsec);
  SET_FIELD_WITH_TIME_STAT(kCTimeSec, s->st_ctim.tv_sec);
  SET_FIELD_WITH_TIME_STAT(kCTimeNsec, s->st_ctim.tv_nsec);
  SET_FIELD_WITH_TIME_STAT(kBirthTimeSec, s->st_birthtim.tv_sec);
  SET_FIELD_WITH_TIME_STAT(kBirthTimeNsec, s->st_birthtim.tv_nsec);

#undef SET_FIELD_WITH_TIME_STAT
#undef SET_FIELD_WITH_STAT
}

v8::Local<v8::Value> FillGlobalStatsArray(Environment* env,
                                          const bool use_bigint,
                                          const uv_stat_t* s,
                                          const bool second) {
  const ptrdiff_t offset =
      second ? static_cast<ptrdiff_t>(FsStatsOffset::kFsStatsFieldsNumber) : 0;
  if (use_bigint) {
    auto* const arr = env->fs_stats_field_bigint_array();
    FillStatsArray(arr, s, offset);
    return arr->GetJSArray();
  } else {
    auto* const arr = env->fs_stats_field_array();
    FillStatsArray(arr, s, offset);
    return arr->GetJSArray();
  }
}

template <typename AliasedBufferT>
FSReqPromise<AliasedBufferT>*
FSReqPromise<AliasedBufferT>::New(Environment* env, bool use_bigint) {
  v8::Local<v8::Object> obj;
  if (!env->fsreqpromise_constructor_template()
           ->NewInstance(env->context())
           .ToLocal(&obj)) {
    return nullptr;
  }
  v8::Local<v8::Promise::Resolver> resolver;
  if (!v8::Promise::Resolver::New(env->context()).ToLocal(&resolver) ||
      obj->Set(env->context(), env->promise_string(), resolver).IsNothing()) {
    return nullptr;
  }
  return new FSReqPromise(env, obj, use_bigint);
}

template <typename AliasedBufferT>
FSReqPromise<AliasedBufferT>::~FSReqPromise() {
  // Validate that the promise was explicitly resolved or rejected.
  CHECK(finished_);
}

template <typename AliasedBufferT>
FSReqPromise<AliasedBufferT>::FSReqPromise(
    Environment* env,
    v8::Local<v8::Object> obj,
    bool use_bigint)
  : FSReqBase(env, obj, AsyncWrap::PROVIDER_FSREQPROMISE, use_bigint),
    stats_field_array_(
        env->isolate(),
        static_cast<size_t>(FsStatsOffset::kFsStatsFieldsNumber)) {}

template <typename AliasedBufferT>
void FSReqPromise<AliasedBufferT>::Reject(v8::Local<v8::Value> reject) {
  finished_ = true;
  v8::HandleScope scope(env()->isolate());
  InternalCallbackScope callback_scope(this);
  v8::Local<v8::Value> value =
      object()->Get(env()->context(),
                    env()->promise_string()).ToLocalChecked();
  v8::Local<v8::Promise::Resolver> resolver = value.As<v8::Promise::Resolver>();
  USE(resolver->Reject(env()->context(), reject).FromJust());
}

template <typename AliasedBufferT>
void FSReqPromise<AliasedBufferT>::Resolve(v8::Local<v8::Value> value) {
  finished_ = true;
  v8::HandleScope scope(env()->isolate());
  InternalCallbackScope callback_scope(this);
  v8::Local<v8::Value> val =
      object()->Get(env()->context(),
                    env()->promise_string()).ToLocalChecked();
  v8::Local<v8::Promise::Resolver> resolver = val.As<v8::Promise::Resolver>();
  USE(resolver->Resolve(env()->context(), value).FromJust());
}

template <typename AliasedBufferT>
void FSReqPromise<AliasedBufferT>::ResolveStat(const uv_stat_t* stat) {
  FillStatsArray(&stats_field_array_, stat);
  Resolve(stats_field_array_.GetJSArray());
}

template <typename AliasedBufferT>
void FSReqPromise<AliasedBufferT>::SetReturnValue(
    const v8::FunctionCallbackInfo<v8::Value>& args) {
  v8::Local<v8::Value> val =
      object()->Get(env()->context(),
                    env()->promise_string()).ToLocalChecked();
  v8::Local<v8::Promise::Resolver> resolver = val.As<v8::Promise::Resolver>();
  args.GetReturnValue().Set(resolver->GetPromise());
}

template <typename AliasedBufferT>
void FSReqPromise<AliasedBufferT>::MemoryInfo(MemoryTracker* tracker) const {
  FSReqBase::MemoryInfo(tracker);
  tracker->TrackField("stats_field_array", stats_field_array_);
}

FSReqBase* GetReqWrap(Environment* env, v8::Local<v8::Value> value,
                      bool use_bigint) {
  if (value->IsObject()) {
    return Unwrap<FSReqBase>(value.As<v8::Object>());
  } else if (value->StrictEquals(env->fs_use_promises_symbol())) {
    if (use_bigint) {
      return FSReqPromise<AliasedBigUint64Array>::New(env, use_bigint);
    } else {
      return FSReqPromise<AliasedFloat64Array>::New(env, use_bigint);
    }
  }
  return nullptr;
}

// Returns nullptr if the operation fails from the start.
template <typename Func, typename... Args>
FSReqBase* AsyncDestCall(Environment* env, FSReqBase* req_wrap,
                         const v8::FunctionCallbackInfo<v8::Value>& args,
                         const char* syscall, const char* dest,
                         size_t len, enum encoding enc, uv_fs_cb after,
                         Func fn, Args... fn_args) {
  CHECK_NOT_NULL(req_wrap);
  req_wrap->Init(syscall, dest, len, enc);
  int err = req_wrap->Dispatch(fn, fn_args..., after);
  if (err < 0) {
    uv_fs_t* uv_req = req_wrap->req();
    uv_req->result = err;
    uv_req->path = nullptr;
    after(uv_req);  // after may delete req_wrap if there is an error
    req_wrap = nullptr;
  } else {
    req_wrap->SetReturnValue(args);
  }

  return req_wrap;
}

// Returns nullptr if the operation fails from the start.
template <typename Func, typename... Args>
FSReqBase* AsyncCall(Environment* env,
                     FSReqBase* req_wrap,
                     const v8::FunctionCallbackInfo<v8::Value>& args,
                     const char* syscall, enum encoding enc,
                     uv_fs_cb after, Func fn, Args... fn_args) {
  return AsyncDestCall(env, req_wrap, args,
                       syscall, nullptr, 0, enc,
                       after, fn, fn_args...);
}

// Template counterpart of SYNC_CALL, except that it only puts
// the error number and the syscall in the context instead of
// creating an error in the C++ land.
// ctx must be checked using value->IsObject() before being passed.
template <typename Func, typename... Args>
int SyncCall(Environment* env, v8::Local<v8::Value> ctx,
             FSReqWrapSync* req_wrap, const char* syscall,
             Func fn, Args... args) {
  env->PrintSyncTrace();
  int err = fn(env->event_loop(), &(req_wrap->req), args..., nullptr);
  if (err < 0) {
    v8::Local<v8::Context> context = env->context();
    v8::Local<v8::Object> ctx_obj = ctx.As<v8::Object>();
    v8::Isolate* isolate = env->isolate();
    ctx_obj->Set(context,
                 env->errno_string(),
                 v8::Integer::New(isolate, err)).Check();
    ctx_obj->Set(context,
                 env->syscall_string(),
                 OneByteString(isolate, syscall)).Check();
  }
  return err;
}

}  // namespace fs
}  // namespace node

#endif  // defined(NODE_WANT_INTERNALS) && NODE_WANT_INTERNALS

#endif  // SRC_NODE_FILE_INL_H_