src/v8/src/wasm/wasm-code-manager.h - cobalt - Git at Google

 // Copyright 2017 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_WASM_HEAP_H_
 #define V8_WASM_HEAP_H_

 #include <functional>
 #include <list>
 #include <map>
 #include <unordered_map>
 #include <unordered_set>

 #include "src/base/macros.h"
 #include "src/handles.h"
 #include "src/trap-handler/trap-handler.h"
 #include "src/vector.h"

 namespace v8 {
 class Isolate;
 namespace internal {

 struct CodeDesc;
 class Code;
 class WasmCompiledModule;

 namespace wasm {

 using GlobalHandleAddress = Address;
 class NativeModule;
 struct WasmModule;

 struct AddressHasher {
   size_t operator()(const Address& addr) const {
     return std::hash<intptr_t>()(reinterpret_cast<intptr_t>(addr));
   }
 };

 // Sorted, disjoint and non-overlapping memory ranges. A range is of the
 // form [start, end). So there's no [start, end), [end, other_end),
 // because that should have been reduced to [start, other_end).
 using AddressRange = std::pair<Address, Address>;
 class V8_EXPORT_PRIVATE DisjointAllocationPool final {
  public:
   enum ExtractionMode : bool { kAny = false, kContiguous = true };
   DisjointAllocationPool() {}

   explicit DisjointAllocationPool(Address, Address);

   DisjointAllocationPool(DisjointAllocationPool&& other) = default;
   DisjointAllocationPool& operator=(DisjointAllocationPool&& other) = default;

   // Merge the ranges of the parameter into this object. Ordering is
   // preserved. The assumption is that the passed parameter is
   // not intersecting this object - for example, it was obtained
   // from a previous Allocate{Pool}.
   void Merge(DisjointAllocationPool&&);

   // Allocate a contiguous range of size {size}. Return an empty pool on
   // failure.
   DisjointAllocationPool Allocate(size_t size) {
     return Extract(size, kContiguous);
   }

   // Allocate a sub-pool of size {size}. Return an empty pool on failure.
   DisjointAllocationPool AllocatePool(size_t size) {
     return Extract(size, kAny);
   }

   bool IsEmpty() const { return ranges_.empty(); }
   const std::list<AddressRange>& ranges() const { return ranges_; }

  private:
   // Extract out a total of {size}. By default, the return may
   // be more than one range. If kContiguous is passed, the return
   // will be one range. If the operation fails, this object is
   // unchanged, and the return {IsEmpty()}
   DisjointAllocationPool Extract(size_t size, ExtractionMode mode);

   std::list<AddressRange> ranges_;

   DISALLOW_COPY_AND_ASSIGN(DisjointAllocationPool)
 };

 using ProtectedInstructions =
     std::vector<trap_handler::ProtectedInstructionData>;

 class V8_EXPORT_PRIVATE WasmCode final {
  public:
   enum Kind {
     kFunction,
     kWasmToWasmWrapper,
     kWasmToJsWrapper,
     kLazyStub,
     kInterpreterStub,
     kCopiedStub,
     kTrampoline
   };

   Vector<byte> instructions() const { return instructions_; }
   Vector<const byte> reloc_info() const {
     return {reloc_info_.get(), reloc_size_};
   }

   uint32_t index() const { return index_.ToChecked(); }
   // Anonymous functions are functions that don't carry an index, like
   // trampolines.
   bool IsAnonymous() const { return index_.IsNothing(); }
   Kind kind() const { return kind_; }
   NativeModule* owner() const { return owner_; }
   Address constant_pool() const;
   size_t constant_pool_offset() const { return constant_pool_offset_; }
   size_t safepoint_table_offset() const { return safepoint_table_offset_; }
   uint32_t stack_slots() const { return stack_slots_; }
   bool is_liftoff() const { return is_liftoff_; }

   size_t trap_handler_index() const;
   void set_trap_handler_index(size_t);
   bool HasTrapHandlerIndex() const;
   void ResetTrapHandlerIndex();

   const ProtectedInstructions& protected_instructions() const {
     return *protected_instructions_.get();
   }

   void Print(Isolate* isolate) const;
   void Disassemble(const char* name, Isolate* isolate, std::ostream& os) const;

   ~WasmCode();

  private:
   friend class NativeModule;
   friend class NativeModuleDeserializer;

   // A constructor used just for implementing Lookup.
   WasmCode(Address pc) : instructions_(pc, 0), index_(Nothing<uint32_t>()) {}

   WasmCode(Vector<byte> instructions,
            std::unique_ptr<const byte[]>&& reloc_info, size_t reloc_size,
            NativeModule* owner, Maybe<uint32_t> index, Kind kind,
            size_t constant_pool_offset, uint32_t stack_slots,
            size_t safepoint_table_offset,
            std::shared_ptr<ProtectedInstructions> protected_instructions,
            bool is_liftoff = false)
       : instructions_(instructions),
         reloc_info_(std::move(reloc_info)),
         reloc_size_(reloc_size),
         owner_(owner),
         index_(index),
         kind_(kind),
         constant_pool_offset_(constant_pool_offset),
         stack_slots_(stack_slots),
         safepoint_table_offset_(safepoint_table_offset),
         protected_instructions_(std::move(protected_instructions)),
         is_liftoff_(is_liftoff) {}

   WasmCode(const WasmCode&) = delete;
   WasmCode& operator=(const WasmCode&) = delete;

   Vector<byte> instructions_;
   std::unique_ptr<const byte[]> reloc_info_;
   size_t reloc_size_ = 0;
   NativeModule* owner_ = nullptr;
   Maybe<uint32_t> index_;
   Kind kind_;
   size_t constant_pool_offset_ = 0;
   uint32_t stack_slots_ = 0;
   // we care about safepoint data for wasm-to-js functions,
   // since there may be stack/register tagged values for large number
   // conversions.
   size_t safepoint_table_offset_ = 0;
   intptr_t trap_handler_index_ = -1;
   std::shared_ptr<ProtectedInstructions> protected_instructions_;
   bool is_liftoff_;
 };

 // Return a textual description of the kind.
 const char* GetWasmCodeKindAsString(WasmCode::Kind);

 class WasmCodeManager;

 // Note that we currently need to add code on the main thread, because we may
 // trigger a GC if we believe there's a chance the GC would clear up native
 // modules. The code is ready for concurrency otherwise, we just need to be
 // careful about this GC consideration. See WouldGCHelp and
 // WasmCodeManager::Commit.
 class V8_EXPORT_PRIVATE NativeModule final {
  public:
   std::unique_ptr<NativeModule> Clone();

   WasmCode* AddCode(const CodeDesc& desc, uint32_t frame_count, uint32_t index,
                     size_t safepoint_table_offset,
                     std::unique_ptr<ProtectedInstructions>,
                     bool is_liftoff = false);

   // A way to copy over JS-allocated code. This is because we compile
   // certain wrappers using a different pipeline.
   WasmCode* AddCodeCopy(Handle<Code> code, WasmCode::Kind kind, uint32_t index);

   // Add an interpreter wrapper. For the same reason as AddCodeCopy, we
   // currently compile these using a different pipeline and we can't get a
   // CodeDesc here. When adding interpreter wrappers, we do not insert them in
   // the code_table, however, we let them self-identify as the {index} function
   WasmCode* AddInterpreterWrapper(Handle<Code> code, uint32_t index);

   // When starting lazy compilation, provide the WasmLazyCompile builtin by
   // calling SetLazyBuiltin. It will initialize the code table with it, and the
   // lazy_builtin_ field. The latter is used when creating entries for exported
   // functions and indirect callable functions, so that they may be identified
   // by the runtime.
   WasmCode* SetLazyBuiltin(Handle<Code> code);

   // ExportedWrappers are WasmToWasmWrappers for functions placed on import
   // tables. We construct them as-needed.
   WasmCode* GetExportedWrapper(uint32_t index);
   WasmCode* AddExportedWrapper(Handle<Code> code, uint32_t index);

   // FunctionCount is WasmModule::functions.size().
   uint32_t FunctionCount() const;
   WasmCode* GetCode(uint32_t index) const;

   WasmCode* lazy_builtin() const { return lazy_builtin_; }

   // We special-case lazy cloning because we currently rely on making copies
   // of the lazy builtin, to be able to identify, in the runtime, which function
   // the lazy builtin is a placeholder of. If we used trampolines, we would call
   // the runtime function from a common pc. We could, then, figure who the
   // caller was if the trampolines called rather than jumped to the common
   // builtin. The logic for seeking though frames would change, though.
   // TODO(mtrofin): perhaps we can do exactly that - either before or after
   // this change.
   WasmCode* CloneLazyBuiltinInto(uint32_t);

   bool SetExecutable(bool executable);

   // For cctests, where we build both WasmModule and the runtime objects
   // on the fly, and bypass the instance builder pipeline.
   void ResizeCodeTableForTest(size_t);
   void LinkAll();
   void Link(uint32_t index);

   // TODO(mtrofin): needed until we sort out exception handlers and
   // source positions, which are still on the  GC-heap.
   WasmCompiledModule* compiled_module() const;
   void SetCompiledModule(Handle<WasmCompiledModule>);

   // Shorthand accessors to the specialization data content.
   std::vector<wasm::GlobalHandleAddress>& function_tables() {
     return specialization_data_.function_tables;
   }

   std::vector<wasm::GlobalHandleAddress>& empty_function_tables() {
     return specialization_data_.empty_function_tables;
   }

   uint32_t num_imported_functions() const { return num_imported_functions_; }
   size_t num_function_tables() const {
     return specialization_data_.empty_function_tables.size();
   }

   size_t committed_memory() const { return committed_memory_; }
   const size_t instance_id = 0;
   ~NativeModule();

  private:
   friend class WasmCodeManager;
   friend class NativeModuleSerializer;
   friend class NativeModuleDeserializer;

   struct WasmCodeUniquePtrComparer {
     bool operator()(const std::unique_ptr<WasmCode>& a,
                     const std::unique_ptr<WasmCode>& b) {
       DCHECK(a);
       DCHECK(b);
       return a->instructions().start() < b->instructions().start();
     }
   };

   static base::AtomicNumber<uint32_t> next_id_;
   NativeModule(const NativeModule&) = delete;
   NativeModule& operator=(const NativeModule&) = delete;
   NativeModule(uint32_t num_functions, uint32_t num_imports,
                bool can_request_more, VirtualMemory* vmem,
                WasmCodeManager* code_manager);

   WasmCode* AddAnonymousCode(Handle<Code>, WasmCode::Kind kind);
   Address AllocateForCode(size_t size);

   // Primitive for adding code to the native module. All code added to a native
   // module is owned by that module. Various callers get to decide on how the
   // code is obtained (CodeDesc vs, as a point in time, Code*), the kind,
   // whether it has an index or is anonymous, etc.
   WasmCode* AddOwnedCode(Vector<const byte> orig_instructions,
                          std::unique_ptr<const byte[]> reloc_info,
                          size_t reloc_size, Maybe<uint32_t> index,
                          WasmCode::Kind kind, size_t constant_pool_offset,
                          uint32_t stack_slots, size_t safepoint_table_offset,
                          std::shared_ptr<ProtectedInstructions>,
                          bool is_liftoff = false);
   void SetCodeTable(uint32_t, wasm::WasmCode*);
   WasmCode* CloneCode(const WasmCode*);
   bool CloneTrampolinesAndStubs(const NativeModule* other);
   WasmCode* Lookup(Address);
   Address GetLocalAddressFor(Handle<Code>);
   Address CreateTrampolineTo(Handle<Code>);

   std::vector<std::unique_ptr<WasmCode>> owned_code_;
   std::unordered_map<uint32_t, WasmCode*> exported_wasm_to_wasm_wrappers_;

   WasmCodeUniquePtrComparer owned_code_comparer_;

   std::vector<WasmCode*> code_table_;
   uint32_t num_imported_functions_;

   std::unordered_map<Address, Address, AddressHasher> trampolines_;
   std::unordered_map<uint32_t, WasmCode*> stubs_;

   DisjointAllocationPool free_memory_;
   DisjointAllocationPool allocated_memory_;
   std::list<VirtualMemory> owned_memory_;
   WasmCodeManager* wasm_code_manager_;
   wasm::WasmCode* lazy_builtin_ = nullptr;
   base::Mutex allocation_mutex_;
   Handle<WasmCompiledModule> compiled_module_;
   size_t committed_memory_ = 0;
   bool can_request_more_memory_;
   bool is_executable_ = false;

   // Specialization data that needs to be serialized and cloned.
   // Keeping it groupped together because it makes cloning of all these
   // elements a 1 line copy.
   struct {
     std::vector<wasm::GlobalHandleAddress> function_tables;
     std::vector<wasm::GlobalHandleAddress> empty_function_tables;
   } specialization_data_;
 };

 class V8_EXPORT_PRIVATE WasmCodeManager final {
  public:
   // The only reason we depend on Isolate is to report native memory used
   // and held by a GC-ed object. We'll need to mitigate that when we
   // start sharing wasm heaps.
   WasmCodeManager(v8::Isolate*, size_t max_committed);
   // Create a new NativeModule. The caller is responsible for its
   // lifetime. The native module will be given some memory for code,
   // which will be page size aligned. The size of the initial memory
   // is determined with a heuristic based on the total size of wasm
   // code. The native module may later request more memory.
   std::unique_ptr<NativeModule> NewNativeModule(const WasmModule&);
   std::unique_ptr<NativeModule> NewNativeModule(size_t memory_estimate,
                                                 uint32_t num_functions,
                                                 uint32_t num_imported_functions,
                                                 bool can_request_more);

   WasmCode* LookupCode(Address pc) const;
   WasmCode* GetCodeFromStartAddress(Address pc) const;
   intptr_t remaining_uncommitted() const;

   // TODO(mtrofin): replace this API with an alternative that is Isolate-
   // independent.
   void FlushICache(Address start, size_t size);

  private:
   friend class NativeModule;

   WasmCodeManager(const WasmCodeManager&) = delete;
   WasmCodeManager& operator=(const WasmCodeManager&) = delete;
   void TryAllocate(size_t size, VirtualMemory*, void* hint = nullptr);
   bool Commit(Address, size_t);
   // Currently, we uncommit a whole module, so all we need is account
   // for the freed memory size. We do that in FreeNativeModuleMemories.
   // There's no separate Uncommit.

   void FreeNativeModuleMemories(NativeModule*);
   void Free(VirtualMemory* mem);
   void AssignRanges(void* start, void* end, NativeModule*);
   size_t GetAllocationChunk(const WasmModule& module);
   bool WouldGCHelp() const;

   std::map<Address, std::pair<Address, NativeModule*>> lookup_map_;
   // count of NativeModules not yet collected. Helps determine if it's
   // worth requesting a GC on memory pressure.
   size_t active_ = 0;
   base::AtomicNumber<intptr_t> remaining_uncommitted_;

   // TODO(mtrofin): remove the dependency on isolate.
   v8::Isolate* isolate_;
 };

 // Within the scope, the native_module is writable and not executable.
 // At the scope's destruction, the native_module is executable and not writable.
 // The states inside the scope and at the scope termination are irrespective of
 // native_module's state when entering the scope.
 // We currently mark the entire module's memory W^X:
 //  - for AOT, that's as efficient as it can be.
 //  - for Lazy, we don't have a heuristic for functions that may need patching,
 //    and even if we did, the resulting set of pages may be fragmented.
 //    Currently, we try and keep the number of syscalls low.
 // -  similar argument for debug time.
 class NativeModuleModificationScope final {
  public:
   explicit NativeModuleModificationScope(NativeModule* native_module);
   ~NativeModuleModificationScope();

  private:
   NativeModule* native_module_;
 };

 // Utilities specific to wasm code generation. We embed a tag for call sites -
 // the index of the called function - when serializing and when creating the
 // code, initially. These APIs offer accessors. The implementation has platform
 // specific nuances.
 void SetWasmCalleeTag(RelocInfo* rinfo, uint32_t tag);
 uint32_t GetWasmCalleeTag(RelocInfo* rinfo);

 }  // namespace wasm
 }  // namespace internal
 }  // namespace v8
 #endif
	// Copyright 2017 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_WASM_HEAP_H_
	#define V8_WASM_HEAP_H_

	#include <functional>
	#include <list>
	#include <map>
	#include <unordered_map>
	#include <unordered_set>

	#include "src/base/macros.h"
	#include "src/handles.h"
	#include "src/trap-handler/trap-handler.h"
	#include "src/vector.h"

	namespace v8 {
	class Isolate;
	namespace internal {

	struct CodeDesc;
	class Code;
	class WasmCompiledModule;

	namespace wasm {

	using GlobalHandleAddress = Address;
	class NativeModule;
	struct WasmModule;

	struct AddressHasher {
	size_t operator()(const Address& addr) const {
	return std::hash<intptr_t>()(reinterpret_cast<intptr_t>(addr));
	}
	};

	// Sorted, disjoint and non-overlapping memory ranges. A range is of the
	// form [start, end). So there's no [start, end), [end, other_end),
	// because that should have been reduced to [start, other_end).
	using AddressRange = std::pair<Address, Address>;
	class V8_EXPORT_PRIVATE DisjointAllocationPool final {
	public:
	enum ExtractionMode : bool { kAny = false, kContiguous = true };
	DisjointAllocationPool() {}

	explicit DisjointAllocationPool(Address, Address);

	DisjointAllocationPool(DisjointAllocationPool&& other) = default;
	DisjointAllocationPool& operator=(DisjointAllocationPool&& other) = default;

	// Merge the ranges of the parameter into this object. Ordering is
	// preserved. The assumption is that the passed parameter is
	// not intersecting this object - for example, it was obtained
	// from a previous Allocate{Pool}.
	void Merge(DisjointAllocationPool&&);

	// Allocate a contiguous range of size {size}. Return an empty pool on
	// failure.
	DisjointAllocationPool Allocate(size_t size) {
	return Extract(size, kContiguous);
	}

	// Allocate a sub-pool of size {size}. Return an empty pool on failure.
	DisjointAllocationPool AllocatePool(size_t size) {
	return Extract(size, kAny);
	}

	bool IsEmpty() const { return ranges_.empty(); }
	const std::list<AddressRange>& ranges() const { return ranges_; }

	private:
	// Extract out a total of {size}. By default, the return may
	// be more than one range. If kContiguous is passed, the return
	// will be one range. If the operation fails, this object is
	// unchanged, and the return {IsEmpty()}
	DisjointAllocationPool Extract(size_t size, ExtractionMode mode);

	std::list<AddressRange> ranges_;

	DISALLOW_COPY_AND_ASSIGN(DisjointAllocationPool)
	};

	using ProtectedInstructions =
	std::vector<trap_handler::ProtectedInstructionData>;

	class V8_EXPORT_PRIVATE WasmCode final {
	public:
	enum Kind {
	kFunction,
	kWasmToWasmWrapper,
	kWasmToJsWrapper,
	kLazyStub,
	kInterpreterStub,
	kCopiedStub,
	kTrampoline
	};

	Vector<byte> instructions() const { return instructions_; }
	Vector<const byte> reloc_info() const {
	return {reloc_info_.get(), reloc_size_};
	}

	uint32_t index() const { return index_.ToChecked(); }
	// Anonymous functions are functions that don't carry an index, like
	// trampolines.
	bool IsAnonymous() const { return index_.IsNothing(); }
	Kind kind() const { return kind_; }
	NativeModule* owner() const { return owner_; }
	Address constant_pool() const;
	size_t constant_pool_offset() const { return constant_pool_offset_; }
	size_t safepoint_table_offset() const { return safepoint_table_offset_; }
	uint32_t stack_slots() const { return stack_slots_; }
	bool is_liftoff() const { return is_liftoff_; }

	size_t trap_handler_index() const;
	void set_trap_handler_index(size_t);
	bool HasTrapHandlerIndex() const;
	void ResetTrapHandlerIndex();

	const ProtectedInstructions& protected_instructions() const {
	return *protected_instructions_.get();
	}

	void Print(Isolate* isolate) const;
	void Disassemble(const char* name, Isolate* isolate, std::ostream& os) const;

	~WasmCode();

	private:
	friend class NativeModule;
	friend class NativeModuleDeserializer;

	// A constructor used just for implementing Lookup.
	WasmCode(Address pc) : instructions_(pc, 0), index_(Nothing<uint32_t>()) {}

	WasmCode(Vector<byte> instructions,
	std::unique_ptr<const byte[]>&& reloc_info, size_t reloc_size,
	NativeModule* owner, Maybe<uint32_t> index, Kind kind,
	size_t constant_pool_offset, uint32_t stack_slots,
	size_t safepoint_table_offset,
	std::shared_ptr<ProtectedInstructions> protected_instructions,
	bool is_liftoff = false)
	: instructions_(instructions),
	reloc_info_(std::move(reloc_info)),
	reloc_size_(reloc_size),
	owner_(owner),
	index_(index),
	kind_(kind),
	constant_pool_offset_(constant_pool_offset),
	stack_slots_(stack_slots),
	safepoint_table_offset_(safepoint_table_offset),
	protected_instructions_(std::move(protected_instructions)),
	is_liftoff_(is_liftoff) {}

	WasmCode(const WasmCode&) = delete;
	WasmCode& operator=(const WasmCode&) = delete;

	Vector<byte> instructions_;
	std::unique_ptr<const byte[]> reloc_info_;
	size_t reloc_size_ = 0;
	NativeModule* owner_ = nullptr;
	Maybe<uint32_t> index_;
	Kind kind_;
	size_t constant_pool_offset_ = 0;
	uint32_t stack_slots_ = 0;
	// we care about safepoint data for wasm-to-js functions,
	// since there may be stack/register tagged values for large number
	// conversions.
	size_t safepoint_table_offset_ = 0;
	intptr_t trap_handler_index_ = -1;
	std::shared_ptr<ProtectedInstructions> protected_instructions_;
	bool is_liftoff_;
	};

	// Return a textual description of the kind.
	const char* GetWasmCodeKindAsString(WasmCode::Kind);

	class WasmCodeManager;

	// Note that we currently need to add code on the main thread, because we may
	// trigger a GC if we believe there's a chance the GC would clear up native
	// modules. The code is ready for concurrency otherwise, we just need to be
	// careful about this GC consideration. See WouldGCHelp and
	// WasmCodeManager::Commit.
	class V8_EXPORT_PRIVATE NativeModule final {
	public:
	std::unique_ptr<NativeModule> Clone();

	WasmCode* AddCode(const CodeDesc& desc, uint32_t frame_count, uint32_t index,
	size_t safepoint_table_offset,
	std::unique_ptr<ProtectedInstructions>,
	bool is_liftoff = false);

	// A way to copy over JS-allocated code. This is because we compile
	// certain wrappers using a different pipeline.
	WasmCode* AddCodeCopy(Handle<Code> code, WasmCode::Kind kind, uint32_t index);

	// Add an interpreter wrapper. For the same reason as AddCodeCopy, we
	// currently compile these using a different pipeline and we can't get a
	// CodeDesc here. When adding interpreter wrappers, we do not insert them in
	// the code_table, however, we let them self-identify as the {index} function
	WasmCode* AddInterpreterWrapper(Handle<Code> code, uint32_t index);

	// When starting lazy compilation, provide the WasmLazyCompile builtin by
	// calling SetLazyBuiltin. It will initialize the code table with it, and the
	// lazy_builtin_ field. The latter is used when creating entries for exported
	// functions and indirect callable functions, so that they may be identified
	// by the runtime.
	WasmCode* SetLazyBuiltin(Handle<Code> code);

	// ExportedWrappers are WasmToWasmWrappers for functions placed on import
	// tables. We construct them as-needed.
	WasmCode* GetExportedWrapper(uint32_t index);
	WasmCode* AddExportedWrapper(Handle<Code> code, uint32_t index);

	// FunctionCount is WasmModule::functions.size().
	uint32_t FunctionCount() const;
	WasmCode* GetCode(uint32_t index) const;

	WasmCode* lazy_builtin() const { return lazy_builtin_; }

	// We special-case lazy cloning because we currently rely on making copies
	// of the lazy builtin, to be able to identify, in the runtime, which function
	// the lazy builtin is a placeholder of. If we used trampolines, we would call
	// the runtime function from a common pc. We could, then, figure who the
	// caller was if the trampolines called rather than jumped to the common
	// builtin. The logic for seeking though frames would change, though.
	// TODO(mtrofin): perhaps we can do exactly that - either before or after
	// this change.
	WasmCode* CloneLazyBuiltinInto(uint32_t);

	bool SetExecutable(bool executable);

	// For cctests, where we build both WasmModule and the runtime objects
	// on the fly, and bypass the instance builder pipeline.
	void ResizeCodeTableForTest(size_t);
	void LinkAll();
	void Link(uint32_t index);

	// TODO(mtrofin): needed until we sort out exception handlers and
	// source positions, which are still on the GC-heap.
	WasmCompiledModule* compiled_module() const;
	void SetCompiledModule(Handle<WasmCompiledModule>);

	// Shorthand accessors to the specialization data content.
	std::vector<wasm::GlobalHandleAddress>& function_tables() {
	return specialization_data_.function_tables;
	}

	std::vector<wasm::GlobalHandleAddress>& empty_function_tables() {
	return specialization_data_.empty_function_tables;
	}

	uint32_t num_imported_functions() const { return num_imported_functions_; }
	size_t num_function_tables() const {
	return specialization_data_.empty_function_tables.size();
	}

	size_t committed_memory() const { return committed_memory_; }
	const size_t instance_id = 0;
	~NativeModule();

	private:
	friend class WasmCodeManager;
	friend class NativeModuleSerializer;
	friend class NativeModuleDeserializer;

	struct WasmCodeUniquePtrComparer {
	bool operator()(const std::unique_ptr<WasmCode>& a,
	const std::unique_ptr<WasmCode>& b) {
	DCHECK(a);
	DCHECK(b);
	return a->instructions().start() < b->instructions().start();
	}
	};

	static base::AtomicNumber<uint32_t> next_id_;
	NativeModule(const NativeModule&) = delete;
	NativeModule& operator=(const NativeModule&) = delete;
	NativeModule(uint32_t num_functions, uint32_t num_imports,
	bool can_request_more, VirtualMemory* vmem,
	WasmCodeManager* code_manager);

	WasmCode* AddAnonymousCode(Handle<Code>, WasmCode::Kind kind);
	Address AllocateForCode(size_t size);

	// Primitive for adding code to the native module. All code added to a native
	// module is owned by that module. Various callers get to decide on how the
	// code is obtained (CodeDesc vs, as a point in time, Code*), the kind,
	// whether it has an index or is anonymous, etc.
	WasmCode* AddOwnedCode(Vector<const byte> orig_instructions,
	std::unique_ptr<const byte[]> reloc_info,
	size_t reloc_size, Maybe<uint32_t> index,
	WasmCode::Kind kind, size_t constant_pool_offset,
	uint32_t stack_slots, size_t safepoint_table_offset,
	std::shared_ptr<ProtectedInstructions>,
	bool is_liftoff = false);
	void SetCodeTable(uint32_t, wasm::WasmCode*);
	WasmCode* CloneCode(const WasmCode*);
	bool CloneTrampolinesAndStubs(const NativeModule* other);
	WasmCode* Lookup(Address);
	Address GetLocalAddressFor(Handle<Code>);
	Address CreateTrampolineTo(Handle<Code>);

	std::vector<std::unique_ptr<WasmCode>> owned_code_;
	std::unordered_map<uint32_t, WasmCode*> exported_wasm_to_wasm_wrappers_;

	WasmCodeUniquePtrComparer owned_code_comparer_;

	std::vector<WasmCode*> code_table_;
	uint32_t num_imported_functions_;

	std::unordered_map<Address, Address, AddressHasher> trampolines_;
	std::unordered_map<uint32_t, WasmCode*> stubs_;

	DisjointAllocationPool free_memory_;
	DisjointAllocationPool allocated_memory_;
	std::list<VirtualMemory> owned_memory_;
	WasmCodeManager* wasm_code_manager_;
	wasm::WasmCode* lazy_builtin_ = nullptr;
	base::Mutex allocation_mutex_;
	Handle<WasmCompiledModule> compiled_module_;
	size_t committed_memory_ = 0;
	bool can_request_more_memory_;
	bool is_executable_ = false;

	// Specialization data that needs to be serialized and cloned.
	// Keeping it groupped together because it makes cloning of all these
	// elements a 1 line copy.
	struct {
	std::vector<wasm::GlobalHandleAddress> function_tables;
	std::vector<wasm::GlobalHandleAddress> empty_function_tables;
	} specialization_data_;
	};

	class V8_EXPORT_PRIVATE WasmCodeManager final {
	public:
	// The only reason we depend on Isolate is to report native memory used
	// and held by a GC-ed object. We'll need to mitigate that when we
	// start sharing wasm heaps.
	WasmCodeManager(v8::Isolate*, size_t max_committed);
	// Create a new NativeModule. The caller is responsible for its
	// lifetime. The native module will be given some memory for code,
	// which will be page size aligned. The size of the initial memory
	// is determined with a heuristic based on the total size of wasm
	// code. The native module may later request more memory.
	std::unique_ptr<NativeModule> NewNativeModule(const WasmModule&);
	std::unique_ptr<NativeModule> NewNativeModule(size_t memory_estimate,
	uint32_t num_functions,
	uint32_t num_imported_functions,
	bool can_request_more);

	WasmCode* LookupCode(Address pc) const;
	WasmCode* GetCodeFromStartAddress(Address pc) const;
	intptr_t remaining_uncommitted() const;

	// TODO(mtrofin): replace this API with an alternative that is Isolate-
	// independent.
	void FlushICache(Address start, size_t size);

	private:
	friend class NativeModule;

	WasmCodeManager(const WasmCodeManager&) = delete;
	WasmCodeManager& operator=(const WasmCodeManager&) = delete;
	void TryAllocate(size_t size, VirtualMemory, void hint = nullptr);
	bool Commit(Address, size_t);
	// Currently, we uncommit a whole module, so all we need is account
	// for the freed memory size. We do that in FreeNativeModuleMemories.
	// There's no separate Uncommit.

	void FreeNativeModuleMemories(NativeModule*);
	void Free(VirtualMemory* mem);
	void AssignRanges(void* start, void* end, NativeModule*);
	size_t GetAllocationChunk(const WasmModule& module);
	bool WouldGCHelp() const;

	std::map<Address, std::pair<Address, NativeModule*>> lookup_map_;
	// count of NativeModules not yet collected. Helps determine if it's
	// worth requesting a GC on memory pressure.
	size_t active_ = 0;
	base::AtomicNumber<intptr_t> remaining_uncommitted_;

	// TODO(mtrofin): remove the dependency on isolate.
	v8::Isolate* isolate_;
	};

	// Within the scope, the native_module is writable and not executable.
	// At the scope's destruction, the native_module is executable and not writable.
	// The states inside the scope and at the scope termination are irrespective of
	// native_module's state when entering the scope.
	// We currently mark the entire module's memory W^X:
	// - for AOT, that's as efficient as it can be.
	// - for Lazy, we don't have a heuristic for functions that may need patching,
	// and even if we did, the resulting set of pages may be fragmented.
	// Currently, we try and keep the number of syscalls low.
	// - similar argument for debug time.
	class NativeModuleModificationScope final {
	public:
	explicit NativeModuleModificationScope(NativeModule* native_module);
	~NativeModuleModificationScope();

	private:
	NativeModule* native_module_;
	};

	// Utilities specific to wasm code generation. We embed a tag for call sites -
	// the index of the called function - when serializing and when creating the
	// code, initially. These APIs offer accessors. The implementation has platform
	// specific nuances.
	void SetWasmCalleeTag(RelocInfo* rinfo, uint32_t tag);
	uint32_t GetWasmCalleeTag(RelocInfo* rinfo);

	} // namespace wasm
	} // namespace internal
	} // namespace v8
	#endif