src/third_party/mozjs/js/src/jit/IonFrames.h - cobalt - Git at Google

 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
  * vim: set ts=8 sts=4 et sw=4 tw=99:
  * This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

 #ifndef jit_IonFrames_h
 #define jit_IonFrames_h

 #ifdef JS_ION

 #include "mozilla/DebugOnly.h"

 #include "jsfun.h"
 #include "jstypes.h"
 #include "jsutil.h"
 #include "Registers.h"
 #include "IonCode.h"
 #include "IonFrameIterator.h"

 class JSFunction;
 class JSScript;

 namespace js {
 namespace jit {

 typedef void * CalleeToken;

 enum CalleeTokenTag
 {
     CalleeToken_Function = 0x0, // untagged
     CalleeToken_Script = 0x1,
     CalleeToken_ParallelFunction = 0x2
 };

 static inline CalleeTokenTag
 GetCalleeTokenTag(CalleeToken token)
 {
     CalleeTokenTag tag = CalleeTokenTag(uintptr_t(token) & 0x3);
     JS_ASSERT(tag <= CalleeToken_ParallelFunction);
     return tag;
 }
 static inline CalleeToken
 CalleeToToken(JSFunction *fun)
 {
     return CalleeToken(uintptr_t(fun) | uintptr_t(CalleeToken_Function));
 }
 static inline CalleeToken
 CalleeToParallelToken(JSFunction *fun)
 {
     return CalleeToken(uintptr_t(fun) | uintptr_t(CalleeToken_ParallelFunction));
 }
 static inline CalleeToken
 CalleeToToken(JSScript *script)
 {
     return CalleeToken(uintptr_t(script) | uintptr_t(CalleeToken_Script));
 }
 static inline bool
 CalleeTokenIsFunction(CalleeToken token)
 {
     return GetCalleeTokenTag(token) == CalleeToken_Function;
 }
 static inline JSFunction *
 CalleeTokenToFunction(CalleeToken token)
 {
     JS_ASSERT(CalleeTokenIsFunction(token));
     return (JSFunction *)token;
 }
 static inline JSFunction *
 CalleeTokenToParallelFunction(CalleeToken token)
 {
     JS_ASSERT(GetCalleeTokenTag(token) == CalleeToken_ParallelFunction);
     return (JSFunction *)(uintptr_t(token) & ~uintptr_t(0x3));
 }
 static inline JSScript *
 CalleeTokenToScript(CalleeToken token)
 {
     JS_ASSERT(GetCalleeTokenTag(token) == CalleeToken_Script);
     return (JSScript *)(uintptr_t(token) & ~uintptr_t(0x3));
 }

 static inline JSScript *
 ScriptFromCalleeToken(CalleeToken token)
 {
     switch (GetCalleeTokenTag(token)) {
       case CalleeToken_Script:
         return CalleeTokenToScript(token);
       case CalleeToken_Function:
         return CalleeTokenToFunction(token)->nonLazyScript();
       case CalleeToken_ParallelFunction:
         return CalleeTokenToParallelFunction(token)->nonLazyScript();
     }
     JS_NOT_REACHED("invalid callee token tag");
     return NULL;
 }

 // In between every two frames lies a small header describing both frames. This
 // header, minimally, contains a returnAddress word and a descriptor word. The
 // descriptor describes the size and type of the previous frame, whereas the
 // returnAddress describes the address the newer frame (the callee) will return
 // to. The exact mechanism in which frames are laid out is architecture
 // dependent.
 //
 // Two special frame types exist. Entry frames begin an ion activation, and
 // therefore there is exactly one per activation of jit::Cannon. Exit frames
 // are necessary to leave JIT code and enter C++, and thus, C++ code will
 // always begin iterating from the topmost exit frame.

 class LSafepoint;

 // Two-tuple that lets you look up the safepoint entry given the
 // displacement of a call instruction within the JIT code.
 class SafepointIndex
 {
     // The displacement is the distance from the first byte of the JIT'd code
     // to the return address (of the call that the safepoint was generated for).
     uint32_t displacement_;

     union {
         LSafepoint *safepoint_;

         // Offset to the start of the encoded safepoint in the safepoint stream.
         uint32_t safepointOffset_;
     };

     mozilla::DebugOnly<bool> resolved;

   public:
     SafepointIndex(uint32_t displacement, LSafepoint *safepoint)
       : displacement_(displacement),
         safepoint_(safepoint),
         resolved(false)
     { }

     void resolve();

     LSafepoint *safepoint() {
         JS_ASSERT(!resolved);
         return safepoint_;
     }
     uint32_t displacement() const {
         return displacement_;
     }
     uint32_t safepointOffset() const {
         return safepointOffset_;
     }
     void adjustDisplacement(uint32_t offset) {
         JS_ASSERT(offset >= displacement_);
         displacement_ = offset;
     }
     inline SnapshotOffset snapshotOffset() const;
     inline bool hasSnapshotOffset() const;
 };

 class MacroAssembler;
 // The OSI point is patched to a call instruction. Therefore, the
 // returnPoint for an OSI call is the address immediately following that
 // call instruction. The displacement of that point within the assembly
 // buffer is the |returnPointDisplacement|.
 class OsiIndex
 {
     uint32_t callPointDisplacement_;
     uint32_t snapshotOffset_;

   public:
     OsiIndex(uint32_t callPointDisplacement, uint32_t snapshotOffset)
       : callPointDisplacement_(callPointDisplacement),
         snapshotOffset_(snapshotOffset)
     { }

     uint32_t returnPointDisplacement() const;
     uint32_t callPointDisplacement() const {
         return callPointDisplacement_;
     }
     uint32_t snapshotOffset() const {
         return snapshotOffset_;
     }
     void fixUpOffset(MacroAssembler &masm);
 };

 // The layout of an Ion frame on the C stack is roughly:
 //      argN     _
 //      ...       \ - These are jsvals
 //      arg0      /
 //   -3 this    _/
 //   -2 callee
 //   -1 descriptor
 //    0 returnAddress
 //   .. locals ..

 // The descriptor is organized into three sections:
 // [ frame size | constructing bit | frame type ]
 // < highest - - - - - - - - - - - - - - lowest >
 static const uintptr_t FRAMESIZE_SHIFT = 4;
 static const uintptr_t FRAMETYPE_BITS = 4;
 static const uintptr_t FRAMETYPE_MASK = (1 << FRAMETYPE_BITS) - 1;

 // Ion frames have a few important numbers associated with them:
 //      Local depth:    The number of bytes required to spill local variables.
 //      Argument depth: The number of bytes required to push arguments and make
 //                      a function call.
 //      Slack:          A frame may temporarily use extra stack to resolve cycles.
 //
 // The (local + argument) depth determines the "fixed frame size". The fixed
 // frame size is the distance between the stack pointer and the frame header.
 // Thus, fixed >= (local + argument).
 //
 // In order to compress guards, we create shared jump tables that recover the
 // script from the stack and recover a snapshot pointer based on which jump was
 // taken. Thus, we create a jump table for each fixed frame size.
 //
 // Jump tables are big. To control the amount of jump tables we generate, each
 // platform chooses how to segregate stack size classes based on its
 // architecture.
 //
 // On some architectures, these jump tables are not used at all, or frame
 // size segregation is not needed. Thus, there is an option for a frame to not
 // have any frame size class, and to be totally dynamic.
 static const uint32_t NO_FRAME_SIZE_CLASS_ID = uint32_t(-1);

 class FrameSizeClass
 {
     uint32_t class_;

     explicit FrameSizeClass(uint32_t class_) : class_(class_)
     { }

   public:
     FrameSizeClass()
     { }

     static FrameSizeClass None() {
         return FrameSizeClass(NO_FRAME_SIZE_CLASS_ID);
     }
     static FrameSizeClass FromClass(uint32_t class_) {
         return FrameSizeClass(class_);
     }

     // These functions are implemented in specific CodeGenerator-* files.
     static FrameSizeClass FromDepth(uint32_t frameDepth);
     static FrameSizeClass ClassLimit();
     uint32_t frameSize() const;

     uint32_t classId() const {
         JS_ASSERT(class_ != NO_FRAME_SIZE_CLASS_ID);
         return class_;
     }

     bool operator ==(const FrameSizeClass &other) const {
         return class_ == other.class_;
     }
     bool operator !=(const FrameSizeClass &other) const {
         return class_ != other.class_;
     }
 };

 // Data needed to recover from an exception.
 struct ResumeFromException
 {
     static const uint32_t RESUME_ENTRY_FRAME = 0;
     static const uint32_t RESUME_CATCH = 1;
     static const uint32_t RESUME_FINALLY = 2;
     static const uint32_t RESUME_FORCED_RETURN = 3;

     uint8_t *framePointer;
     uint8_t *stackPointer;
     uint8_t *target;
     uint32_t kind;

     // Value to push when resuming into a |finally| block.
     Value exception;
 };

 void HandleException(ResumeFromException *rfe);
 void HandleParallelFailure(ResumeFromException *rfe);

 void EnsureExitFrame(IonCommonFrameLayout *frame);

 void MarkJitActivations(JSRuntime *rt, JSTracer *trc);
 void MarkIonCompilerRoots(JSTracer *trc);

 static inline uint32_t
 MakeFrameDescriptor(uint32_t frameSize, FrameType type)
 {
     return (frameSize << FRAMESIZE_SHIFT) | type;
 }

 } // namespace jit
 } // namespace js

 #if defined(JS_CPU_X86) || defined (JS_CPU_X64)
 # include "jit/shared/IonFrames-x86-shared.h"
 #elif defined (JS_CPU_ARM)
 # include "jit/arm/IonFrames-arm.h"
 #elif defined(JS_CPU_MIPS)
 # include "jit/mips/IonFrames-mips.h"
 #else
 # error "unsupported architecture"
 #endif

 namespace js {
 namespace jit {

 JSScript *
 GetTopIonJSScript(JSContext *cx,
                   const SafepointIndex **safepointIndexOut = NULL,
                   void **returnAddrOut = NULL);

 void
 GetPcScript(JSContext *cx, JSScript **scriptRes, jsbytecode **pcRes);

 // Given a slot index, returns the offset, in bytes, of that slot from an
 // IonJSFrameLayout. Slot distances are uniform across architectures, however,
 // the distance does depend on the size of the frame header.
 static inline int32_t
 OffsetOfFrameSlot(int32_t slot)
 {
     if (slot <= 0)
         return -slot;
     return -(slot * STACK_SLOT_SIZE);
 }

 static inline uintptr_t
 ReadFrameSlot(IonJSFrameLayout *fp, int32_t slot)
 {
     return *(uintptr_t *)((char *)fp + OffsetOfFrameSlot(slot));
 }

 static inline double
 ReadFrameDoubleSlot(IonJSFrameLayout *fp, int32_t slot)
 {
     return *(double *)((char *)fp + OffsetOfFrameSlot(slot));
 }

 CalleeToken
 MarkCalleeToken(JSTracer *trc, CalleeToken token);

 } /* namespace jit */
 } /* namespace js */

 #endif // JS_ION

 #endif /* jit_IonFrames_h */
	/* -- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 --
	* vim: set ts=8 sts=4 et sw=4 tw=99:
	* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */

	#ifndef jit_IonFrames_h
	#define jit_IonFrames_h

	#ifdef JS_ION

	#include "mozilla/DebugOnly.h"

	#include "jsfun.h"
	#include "jstypes.h"
	#include "jsutil.h"
	#include "Registers.h"
	#include "IonCode.h"
	#include "IonFrameIterator.h"

	class JSFunction;
	class JSScript;

	namespace js {
	namespace jit {

	typedef void * CalleeToken;

	enum CalleeTokenTag
	{
	CalleeToken_Function = 0x0, // untagged
	CalleeToken_Script = 0x1,
	CalleeToken_ParallelFunction = 0x2
	};

	static inline CalleeTokenTag
	GetCalleeTokenTag(CalleeToken token)
	{
	CalleeTokenTag tag = CalleeTokenTag(uintptr_t(token) & 0x3);
	JS_ASSERT(tag <= CalleeToken_ParallelFunction);
	return tag;
	}
	static inline CalleeToken
	CalleeToToken(JSFunction *fun)
	{
	return CalleeToken(uintptr_t(fun) \| uintptr_t(CalleeToken_Function));
	}
	static inline CalleeToken
	CalleeToParallelToken(JSFunction *fun)
	{
	return CalleeToken(uintptr_t(fun) \| uintptr_t(CalleeToken_ParallelFunction));
	}
	static inline CalleeToken
	CalleeToToken(JSScript *script)
	{
	return CalleeToken(uintptr_t(script) \| uintptr_t(CalleeToken_Script));
	}
	static inline bool
	CalleeTokenIsFunction(CalleeToken token)
	{
	return GetCalleeTokenTag(token) == CalleeToken_Function;
	}
	static inline JSFunction *
	CalleeTokenToFunction(CalleeToken token)
	{
	JS_ASSERT(CalleeTokenIsFunction(token));
	return (JSFunction *)token;
	}
	static inline JSFunction *
	CalleeTokenToParallelFunction(CalleeToken token)
	{
	JS_ASSERT(GetCalleeTokenTag(token) == CalleeToken_ParallelFunction);
	return (JSFunction *)(uintptr_t(token) & ~uintptr_t(0x3));
	}
	static inline JSScript *
	CalleeTokenToScript(CalleeToken token)
	{
	JS_ASSERT(GetCalleeTokenTag(token) == CalleeToken_Script);
	return (JSScript *)(uintptr_t(token) & ~uintptr_t(0x3));
	}

	static inline JSScript *
	ScriptFromCalleeToken(CalleeToken token)
	{
	switch (GetCalleeTokenTag(token)) {
	case CalleeToken_Script:
	return CalleeTokenToScript(token);
	case CalleeToken_Function:
	return CalleeTokenToFunction(token)->nonLazyScript();
	case CalleeToken_ParallelFunction:
	return CalleeTokenToParallelFunction(token)->nonLazyScript();
	}
	JS_NOT_REACHED("invalid callee token tag");
	return NULL;
	}

	// In between every two frames lies a small header describing both frames. This
	// header, minimally, contains a returnAddress word and a descriptor word. The
	// descriptor describes the size and type of the previous frame, whereas the
	// returnAddress describes the address the newer frame (the callee) will return
	// to. The exact mechanism in which frames are laid out is architecture
	// dependent.
	//
	// Two special frame types exist. Entry frames begin an ion activation, and
	// therefore there is exactly one per activation of jit::Cannon. Exit frames
	// are necessary to leave JIT code and enter C++, and thus, C++ code will
	// always begin iterating from the topmost exit frame.

	class LSafepoint;

	// Two-tuple that lets you look up the safepoint entry given the
	// displacement of a call instruction within the JIT code.
	class SafepointIndex
	{
	// The displacement is the distance from the first byte of the JIT'd code
	// to the return address (of the call that the safepoint was generated for).
	uint32_t displacement_;

	union {
	LSafepoint *safepoint_;

	// Offset to the start of the encoded safepoint in the safepoint stream.
	uint32_t safepointOffset_;
	};

	mozilla::DebugOnly<bool> resolved;

	public:
	SafepointIndex(uint32_t displacement, LSafepoint *safepoint)
	: displacement_(displacement),
	safepoint_(safepoint),
	resolved(false)
	{ }

	void resolve();

	LSafepoint *safepoint() {
	JS_ASSERT(!resolved);
	return safepoint_;
	}
	uint32_t displacement() const {
	return displacement_;
	}
	uint32_t safepointOffset() const {
	return safepointOffset_;
	}
	void adjustDisplacement(uint32_t offset) {
	JS_ASSERT(offset >= displacement_);
	displacement_ = offset;
	}
	inline SnapshotOffset snapshotOffset() const;
	inline bool hasSnapshotOffset() const;
	};

	class MacroAssembler;
	// The OSI point is patched to a call instruction. Therefore, the
	// returnPoint for an OSI call is the address immediately following that
	// call instruction. The displacement of that point within the assembly
	// buffer is the \|returnPointDisplacement\|.
	class OsiIndex
	{
	uint32_t callPointDisplacement_;
	uint32_t snapshotOffset_;

	public:
	OsiIndex(uint32_t callPointDisplacement, uint32_t snapshotOffset)
	: callPointDisplacement_(callPointDisplacement),
	snapshotOffset_(snapshotOffset)
	{ }

	uint32_t returnPointDisplacement() const;
	uint32_t callPointDisplacement() const {
	return callPointDisplacement_;
	}
	uint32_t snapshotOffset() const {
	return snapshotOffset_;
	}
	void fixUpOffset(MacroAssembler &masm);
	};

	// The layout of an Ion frame on the C stack is roughly:
	// argN _
	// ... \ - These are jsvals
	// arg0 /
	// -3 this _/
	// -2 callee
	// -1 descriptor
	// 0 returnAddress
	// .. locals ..

	// The descriptor is organized into three sections:
	// [ frame size \| constructing bit \| frame type ]
	// < highest - - - - - - - - - - - - - - lowest >
	static const uintptr_t FRAMESIZE_SHIFT = 4;
	static const uintptr_t FRAMETYPE_BITS = 4;
	static const uintptr_t FRAMETYPE_MASK = (1 << FRAMETYPE_BITS) - 1;

	// Ion frames have a few important numbers associated with them:
	// Local depth: The number of bytes required to spill local variables.
	// Argument depth: The number of bytes required to push arguments and make
	// a function call.
	// Slack: A frame may temporarily use extra stack to resolve cycles.
	//
	// The (local + argument) depth determines the "fixed frame size". The fixed
	// frame size is the distance between the stack pointer and the frame header.
	// Thus, fixed >= (local + argument).
	//
	// In order to compress guards, we create shared jump tables that recover the
	// script from the stack and recover a snapshot pointer based on which jump was
	// taken. Thus, we create a jump table for each fixed frame size.
	//
	// Jump tables are big. To control the amount of jump tables we generate, each
	// platform chooses how to segregate stack size classes based on its
	// architecture.
	//
	// On some architectures, these jump tables are not used at all, or frame
	// size segregation is not needed. Thus, there is an option for a frame to not
	// have any frame size class, and to be totally dynamic.
	static const uint32_t NO_FRAME_SIZE_CLASS_ID = uint32_t(-1);

	class FrameSizeClass
	{
	uint32_t class_;

	explicit FrameSizeClass(uint32_t class_) : class_(class_)
	{ }

	public:
	FrameSizeClass()
	{ }

	static FrameSizeClass None() {
	return FrameSizeClass(NO_FRAME_SIZE_CLASS_ID);
	}
	static FrameSizeClass FromClass(uint32_t class_) {
	return FrameSizeClass(class_);
	}

	// These functions are implemented in specific CodeGenerator-* files.
	static FrameSizeClass FromDepth(uint32_t frameDepth);
	static FrameSizeClass ClassLimit();
	uint32_t frameSize() const;

	uint32_t classId() const {
	JS_ASSERT(class_ != NO_FRAME_SIZE_CLASS_ID);
	return class_;
	}

	bool operator ==(const FrameSizeClass &other) const {
	return class_ == other.class_;
	}
	bool operator !=(const FrameSizeClass &other) const {
	return class_ != other.class_;
	}
	};

	// Data needed to recover from an exception.
	struct ResumeFromException
	{
	static const uint32_t RESUME_ENTRY_FRAME = 0;
	static const uint32_t RESUME_CATCH = 1;
	static const uint32_t RESUME_FINALLY = 2;
	static const uint32_t RESUME_FORCED_RETURN = 3;

	uint8_t *framePointer;
	uint8_t *stackPointer;
	uint8_t *target;
	uint32_t kind;

	// Value to push when resuming into a \|finally\| block.
	Value exception;
	};

	void HandleException(ResumeFromException *rfe);
	void HandleParallelFailure(ResumeFromException *rfe);

	void EnsureExitFrame(IonCommonFrameLayout *frame);

	void MarkJitActivations(JSRuntime rt, JSTracer trc);
	void MarkIonCompilerRoots(JSTracer *trc);

	static inline uint32_t
	MakeFrameDescriptor(uint32_t frameSize, FrameType type)
	{
	return (frameSize << FRAMESIZE_SHIFT) \| type;
	}

	} // namespace jit
	} // namespace js

	#if defined(JS_CPU_X86) \|\| defined (JS_CPU_X64)
	# include "jit/shared/IonFrames-x86-shared.h"
	#elif defined (JS_CPU_ARM)
	# include "jit/arm/IonFrames-arm.h"
	#elif defined(JS_CPU_MIPS)
	# include "jit/mips/IonFrames-mips.h"
	#else
	# error "unsupported architecture"
	#endif

	namespace js {
	namespace jit {

	JSScript *
	GetTopIonJSScript(JSContext *cx,
	const SafepointIndex **safepointIndexOut = NULL,
	void **returnAddrOut = NULL);

	void
	GetPcScript(JSContext cx, JSScript scriptRes, jsbytecode *pcRes);

	// Given a slot index, returns the offset, in bytes, of that slot from an
	// IonJSFrameLayout. Slot distances are uniform across architectures, however,
	// the distance does depend on the size of the frame header.
	static inline int32_t
	OffsetOfFrameSlot(int32_t slot)
	{
	if (slot <= 0)
	return -slot;
	return -(slot * STACK_SLOT_SIZE);
	}

	static inline uintptr_t
	ReadFrameSlot(IonJSFrameLayout *fp, int32_t slot)
	{
	return (uintptr_t )((char *)fp + OffsetOfFrameSlot(slot));
	}

	static inline double
	ReadFrameDoubleSlot(IonJSFrameLayout *fp, int32_t slot)
	{
	return (double )((char *)fp + OffsetOfFrameSlot(slot));
	}

	CalleeToken
	MarkCalleeToken(JSTracer *trc, CalleeToken token);

	} /* namespace jit */
	} /* namespace js */

	#endif // JS_ION

	#endif /* jit_IonFrames_h */