runtime/vm/kernel_binary.cc - sdk.git - Git at Google

 // Copyright (c) 2016, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.
 #if !defined(DART_PRECOMPILED_RUNTIME)

 #include "vm/kernel_binary.h"

 #include <memory>

 #include "platform/globals.h"
 #include "vm/compiler/frontend/kernel_to_il.h"
 #include "vm/dart_api_impl.h"
 #include "vm/flags.h"
 #include "vm/growable_array.h"
 #include "vm/kernel.h"
 #include "vm/object.h"
 #include "vm/os.h"
 #include "vm/version.h"

 namespace dart {

 namespace kernel {

 const char* Reader::TagName(Tag tag) {
   switch (tag) {
 #define CASE(Name, value)                                                      \
   case k##Name:                                                                \
     return #Name;
     KERNEL_TAG_LIST(CASE)
 #undef CASE
     default:
       break;
   }
   return "Unknown";
 }

 TypedDataPtr Reader::ReadLineStartsData(intptr_t line_start_count) {
   TypedData& line_starts_data = TypedData::Handle(
       TypedData::New(kTypedDataInt8ArrayCid, line_start_count, Heap::kOld));

   const intptr_t start_offset = offset();
   intptr_t i = 0;
   for (; i < line_start_count; ++i) {
     const intptr_t delta = ReadUInt();
     if (delta > kMaxInt8) {
       break;
     }
     line_starts_data.SetInt8(i, static_cast<int8_t>(delta));
   }

   if (i < line_start_count) {
     // Slow path: choose representation between Int16 and Int32 typed data.
     set_offset(start_offset);
     intptr_t max_delta = 0;
     for (intptr_t i = 0; i < line_start_count; ++i) {
       const intptr_t delta = ReadUInt();
       if (delta > max_delta) {
         max_delta = delta;
       }
     }

     ASSERT(max_delta > kMaxInt8);
     const intptr_t cid = (max_delta <= kMaxInt16) ? kTypedDataInt16ArrayCid
                                                   : kTypedDataInt32ArrayCid;
     line_starts_data = TypedData::New(cid, line_start_count, Heap::kOld);

     set_offset(start_offset);
     for (intptr_t i = 0; i < line_start_count; ++i) {
       const intptr_t delta = ReadUInt();
       if (cid == kTypedDataInt16ArrayCid) {
         line_starts_data.SetInt16(i << 1, static_cast<int16_t>(delta));
       } else {
         line_starts_data.SetInt32(i << 2, delta);
       }
     }
   }

   return line_starts_data.ptr();
 }

 const char* kKernelInvalidFilesize =
     "File size is too small to be a valid kernel file";
 const char* kKernelInvalidMagicIdentifier = "Invalid magic identifier";
 const char* kKernelInvalidBinaryFormatVersion =
     "Invalid kernel binary format version";
 const char* kKernelInvalidSizeIndicated =
     "Invalid kernel binary: Indicated size is invalid";
 const char* kKernelInvalidSdkHash = "Invalid SDK hash";

 const int kSdkHashSizeInBytes = 10;
 const char* kSdkHashNull = "0000000000";

 std::unique_ptr<Program> Program::ReadFrom(Reader* reader, const char** error) {
   if (reader->size() < 70) {
     // A kernel file (v43) currently contains at least the following:
     //   * Magic number (32)
     //   * Kernel version (32)
     //   * SDK Hash (10 * 8)
     //   * List of problems (8)
     //   * Length of source map (32)
     //   * Length of canonical name table (8)
     //   * Metadata length (32)
     //   * Length of string table (8)
     //   * Length of constant table (8)
     //   * Component index (11 * 32)
     //
     // so is at least 74 bytes.
     // (Technically it will also contain an empty entry in both source map and
     // string table, taking up another 8 bytes.)
     if (error != nullptr) {
       *error = kKernelInvalidFilesize;
     }
     return nullptr;
   }

   uint32_t magic = reader->ReadUInt32();
   if (magic != kMagicProgramFile) {
     if (error != nullptr) {
       *error = kKernelInvalidMagicIdentifier;
     }
     return nullptr;
   }

   uint32_t formatVersion = reader->ReadUInt32();
   if ((formatVersion < kMinSupportedKernelFormatVersion) ||
       (formatVersion > kMaxSupportedKernelFormatVersion)) {
     if (error != nullptr) {
       *error = kKernelInvalidBinaryFormatVersion;
     }
     return nullptr;
   }

   uint8_t sdkHash[kSdkHashSizeInBytes + 1];
   reader->ReadBytes(sdkHash, kSdkHashSizeInBytes);
   sdkHash[kSdkHashSizeInBytes] = 0;  // Null terminate.
   if (strcmp(Version::SdkHash(), kSdkHashNull) != 0 &&
       strcmp((const char*)sdkHash, kSdkHashNull) != 0 &&
       strcmp((const char*)sdkHash, Version::SdkHash()) != 0) {
     if (error != nullptr) {
       *error = kKernelInvalidSdkHash;
     }
     return nullptr;
   }

   std::unique_ptr<Program> program(new Program());
   program->binary_version_ = formatVersion;
   program->binary_.typed_data = reader->typed_data();
   program->binary_.kernel_data = reader->buffer();
   program->binary_.kernel_data_size = reader->size();

   // Dill files can be concatenated (e.g. cat a.dill b.dill > c.dill). Find out
   // if this dill contains more than one program.
   int subprogram_count = 0;
   reader->set_offset(reader->size() - 4);
   while (reader->offset() > 0) {
     intptr_t size = reader->ReadUInt32();
     intptr_t start = reader->offset() - size;
     if (start < 0 || size <= 0) {
       if (error != nullptr) {
         *error = kKernelInvalidSizeIndicated;
       }
       return nullptr;
     }
     ++subprogram_count;
     if (subprogram_count > 1) break;
     reader->set_offset(start - 4);
   }
   program->single_program_ = subprogram_count == 1;

   // Read backwards at the end.
   program->library_count_ = reader->ReadFromIndexNoReset(
       reader->size_, LibraryCountFieldCountFromEnd, 1, 0);
   intptr_t count_from_first_library_offset =
       SourceTableFieldCountFromFirstLibraryOffset41Plus;
   program->source_table_offset_ = reader->ReadFromIndexNoReset(
       reader->size_,
       LibraryCountFieldCountFromEnd + 1 + program->library_count_ + 1 +
           count_from_first_library_offset,
       1, 0);
   program->name_table_offset_ = reader->ReadUInt32();
   program->metadata_payloads_offset_ = reader->ReadUInt32();
   program->metadata_mappings_offset_ = reader->ReadUInt32();
   program->string_table_offset_ = reader->ReadUInt32();
   program->constant_table_offset_ = reader->ReadUInt32();

   program->main_method_reference_ = NameIndex(reader->ReadUInt32() - 1);
   NNBDCompiledMode compilation_mode =
       static_cast<NNBDCompiledMode>(reader->ReadUInt32());
   program->compilation_mode_ = compilation_mode;

   return program;
 }

 std::unique_ptr<Program> Program::ReadFromFile(
     const char* script_uri, const char** error /* = nullptr */) {
   Thread* thread = Thread::Current();
   auto isolate_group = thread->isolate_group();
   if (script_uri == NULL) {
     return nullptr;
   }
   if (!isolate_group->HasTagHandler()) {
     return nullptr;
   }
   std::unique_ptr<kernel::Program> kernel_program;

   const String& uri = String::Handle(String::New(script_uri));
   const Object& ret = Object::Handle(isolate_group->CallTagHandler(
       Dart_kKernelTag, Object::null_object(), uri));
   if (ret.IsExternalTypedData()) {
     const auto& typed_data = ExternalTypedData::Handle(
         thread->zone(), ExternalTypedData::RawCast(ret.ptr()));
     kernel_program = kernel::Program::ReadFromTypedData(typed_data);
     return kernel_program;
   } else if (error != nullptr) {
     Api::Scope api_scope(thread);
     Dart_Handle retval = Api::NewHandle(thread, ret.ptr());
     {
       TransitionVMToNative transition(thread);
       *error = Dart_GetError(retval);
     }
   }
   return kernel_program;
 }

 std::unique_ptr<Program> Program::ReadFromBuffer(const uint8_t* buffer,
                                                  intptr_t buffer_length,
                                                  const char** error) {
   kernel::Reader reader(buffer, buffer_length);
   return kernel::Program::ReadFrom(&reader, error);
 }

 std::unique_ptr<Program> Program::ReadFromTypedData(
     const ExternalTypedData& typed_data, const char** error) {
   kernel::Reader reader(typed_data);
   return kernel::Program::ReadFrom(&reader, error);
 }

 }  // namespace kernel
 }  // namespace dart
 #endif  // !defined(DART_PRECOMPILED_RUNTIME)
	// Copyright (c) 2016, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.
	#if !defined(DART_PRECOMPILED_RUNTIME)

	#include "vm/kernel_binary.h"

	#include <memory>

	#include "platform/globals.h"
	#include "vm/compiler/frontend/kernel_to_il.h"
	#include "vm/dart_api_impl.h"
	#include "vm/flags.h"
	#include "vm/growable_array.h"
	#include "vm/kernel.h"
	#include "vm/object.h"
	#include "vm/os.h"
	#include "vm/version.h"

	namespace dart {

	namespace kernel {

	const char* Reader::TagName(Tag tag) {
	switch (tag) {
	#define CASE(Name, value) \
	case k##Name: \
	return #Name;
	KERNEL_TAG_LIST(CASE)
	#undef CASE
	default:
	break;
	}
	return "Unknown";
	}

	TypedDataPtr Reader::ReadLineStartsData(intptr_t line_start_count) {
	TypedData& line_starts_data = TypedData::Handle(
	TypedData::New(kTypedDataInt8ArrayCid, line_start_count, Heap::kOld));

	const intptr_t start_offset = offset();
	intptr_t i = 0;
	for (; i < line_start_count; ++i) {
	const intptr_t delta = ReadUInt();
	if (delta > kMaxInt8) {
	break;
	}
	line_starts_data.SetInt8(i, static_cast<int8_t>(delta));
	}

	if (i < line_start_count) {
	// Slow path: choose representation between Int16 and Int32 typed data.
	set_offset(start_offset);
	intptr_t max_delta = 0;
	for (intptr_t i = 0; i < line_start_count; ++i) {
	const intptr_t delta = ReadUInt();
	if (delta > max_delta) {
	max_delta = delta;
	}
	}

	ASSERT(max_delta > kMaxInt8);
	const intptr_t cid = (max_delta <= kMaxInt16) ? kTypedDataInt16ArrayCid
	: kTypedDataInt32ArrayCid;
	line_starts_data = TypedData::New(cid, line_start_count, Heap::kOld);

	set_offset(start_offset);
	for (intptr_t i = 0; i < line_start_count; ++i) {
	const intptr_t delta = ReadUInt();
	if (cid == kTypedDataInt16ArrayCid) {
	line_starts_data.SetInt16(i << 1, static_cast<int16_t>(delta));
	} else {
	line_starts_data.SetInt32(i << 2, delta);
	}
	}
	}

	return line_starts_data.ptr();
	}

	const char* kKernelInvalidFilesize =
	"File size is too small to be a valid kernel file";
	const char* kKernelInvalidMagicIdentifier = "Invalid magic identifier";
	const char* kKernelInvalidBinaryFormatVersion =
	"Invalid kernel binary format version";
	const char* kKernelInvalidSizeIndicated =
	"Invalid kernel binary: Indicated size is invalid";
	const char* kKernelInvalidSdkHash = "Invalid SDK hash";

	const int kSdkHashSizeInBytes = 10;
	const char* kSdkHashNull = "0000000000";

	std::unique_ptr<Program> Program::ReadFrom(Reader* reader, const char** error) {
	if (reader->size() < 70) {
	// A kernel file (v43) currently contains at least the following:
	// * Magic number (32)
	// * Kernel version (32)
	// * SDK Hash (10 * 8)
	// * List of problems (8)
	// * Length of source map (32)
	// * Length of canonical name table (8)
	// * Metadata length (32)
	// * Length of string table (8)
	// * Length of constant table (8)
	// * Component index (11 * 32)
	//
	// so is at least 74 bytes.
	// (Technically it will also contain an empty entry in both source map and
	// string table, taking up another 8 bytes.)
	if (error != nullptr) {
	*error = kKernelInvalidFilesize;
	}
	return nullptr;
	}

	uint32_t magic = reader->ReadUInt32();
	if (magic != kMagicProgramFile) {
	if (error != nullptr) {
	*error = kKernelInvalidMagicIdentifier;
	}
	return nullptr;
	}

	uint32_t formatVersion = reader->ReadUInt32();
	if ((formatVersion < kMinSupportedKernelFormatVersion) \|\|
	(formatVersion > kMaxSupportedKernelFormatVersion)) {
	if (error != nullptr) {
	*error = kKernelInvalidBinaryFormatVersion;
	}
	return nullptr;
	}

	uint8_t sdkHash[kSdkHashSizeInBytes + 1];
	reader->ReadBytes(sdkHash, kSdkHashSizeInBytes);
	sdkHash[kSdkHashSizeInBytes] = 0; // Null terminate.
	if (strcmp(Version::SdkHash(), kSdkHashNull) != 0 &&
	strcmp((const char*)sdkHash, kSdkHashNull) != 0 &&
	strcmp((const char*)sdkHash, Version::SdkHash()) != 0) {
	if (error != nullptr) {
	*error = kKernelInvalidSdkHash;
	}
	return nullptr;
	}

	std::unique_ptr<Program> program(new Program());
	program->binary_version_ = formatVersion;
	program->binary_.typed_data = reader->typed_data();
	program->binary_.kernel_data = reader->buffer();
	program->binary_.kernel_data_size = reader->size();

	// Dill files can be concatenated (e.g. cat a.dill b.dill > c.dill). Find out
	// if this dill contains more than one program.
	int subprogram_count = 0;
	reader->set_offset(reader->size() - 4);
	while (reader->offset() > 0) {
	intptr_t size = reader->ReadUInt32();
	intptr_t start = reader->offset() - size;
	if (start < 0 \|\| size <= 0) {
	if (error != nullptr) {
	*error = kKernelInvalidSizeIndicated;
	}
	return nullptr;
	}
	++subprogram_count;
	if (subprogram_count > 1) break;
	reader->set_offset(start - 4);
	}
	program->single_program_ = subprogram_count == 1;

	// Read backwards at the end.
	program->library_count_ = reader->ReadFromIndexNoReset(
	reader->size_, LibraryCountFieldCountFromEnd, 1, 0);
	intptr_t count_from_first_library_offset =
	SourceTableFieldCountFromFirstLibraryOffset41Plus;
	program->source_table_offset_ = reader->ReadFromIndexNoReset(
	reader->size_,
	LibraryCountFieldCountFromEnd + 1 + program->library_count_ + 1 +
	count_from_first_library_offset,
	1, 0);
	program->name_table_offset_ = reader->ReadUInt32();
	program->metadata_payloads_offset_ = reader->ReadUInt32();
	program->metadata_mappings_offset_ = reader->ReadUInt32();
	program->string_table_offset_ = reader->ReadUInt32();
	program->constant_table_offset_ = reader->ReadUInt32();

	program->main_method_reference_ = NameIndex(reader->ReadUInt32() - 1);
	NNBDCompiledMode compilation_mode =
	static_cast<NNBDCompiledMode>(reader->ReadUInt32());
	program->compilation_mode_ = compilation_mode;

	return program;
	}

	std::unique_ptr<Program> Program::ReadFromFile(
	const char* script_uri, const char** error /* = nullptr */) {
	Thread* thread = Thread::Current();
	auto isolate_group = thread->isolate_group();
	if (script_uri == NULL) {
	return nullptr;
	}
	if (!isolate_group->HasTagHandler()) {
	return nullptr;
	}
	std::unique_ptr<kernel::Program> kernel_program;

	const String& uri = String::Handle(String::New(script_uri));
	const Object& ret = Object::Handle(isolate_group->CallTagHandler(
	Dart_kKernelTag, Object::null_object(), uri));
	if (ret.IsExternalTypedData()) {
	const auto& typed_data = ExternalTypedData::Handle(
	thread->zone(), ExternalTypedData::RawCast(ret.ptr()));
	kernel_program = kernel::Program::ReadFromTypedData(typed_data);
	return kernel_program;
	} else if (error != nullptr) {
	Api::Scope api_scope(thread);
	Dart_Handle retval = Api::NewHandle(thread, ret.ptr());
	{
	TransitionVMToNative transition(thread);
	*error = Dart_GetError(retval);
	}
	}
	return kernel_program;
	}

	std::unique_ptr<Program> Program::ReadFromBuffer(const uint8_t* buffer,
	intptr_t buffer_length,
	const char** error) {
	kernel::Reader reader(buffer, buffer_length);
	return kernel::Program::ReadFrom(&reader, error);
	}

	std::unique_ptr<Program> Program::ReadFromTypedData(
	const ExternalTypedData& typed_data, const char** error) {
	kernel::Reader reader(typed_data);
	return kernel::Program::ReadFrom(&reader, error);
	}

	} // namespace kernel
	} // namespace dart
	#endif // !defined(DART_PRECOMPILED_RUNTIME)