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// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.
// See the LICENSE file in the project root for more information.
// Garbage-collector information
// Keeps track of which variables hold pointers.
// Generates the GC-tables
#ifndef _JITGCINFO_H_
#define _JITGCINFO_H_
#include "gcinfotypes.h"
#ifndef JIT32_GCENCODER
#include "gcinfoencoder.h"
#endif
/*****************************************************************************/
#ifndef JIT32_GCENCODER
// Shash typedefs
struct RegSlotIdKey
{
unsigned short m_regNum;
unsigned short m_flags;
RegSlotIdKey()
{
}
RegSlotIdKey(unsigned short regNum, unsigned short flags) : m_regNum(regNum), m_flags(flags)
{
}
static unsigned GetHashCode(RegSlotIdKey rsk)
{
return (rsk.m_flags << (8 * sizeof(unsigned short))) + rsk.m_regNum;
}
static bool Equals(RegSlotIdKey rsk1, RegSlotIdKey rsk2)
{
return rsk1.m_regNum == rsk2.m_regNum && rsk1.m_flags == rsk2.m_flags;
}
};
struct StackSlotIdKey
{
int m_offset;
bool m_fpRel;
unsigned short m_flags;
StackSlotIdKey()
{
}
StackSlotIdKey(int offset, bool fpRel, unsigned short flags) : m_offset(offset), m_fpRel(fpRel), m_flags(flags)
{
}
static unsigned GetHashCode(StackSlotIdKey ssk)
{
return (ssk.m_flags << (8 * sizeof(unsigned short))) ^ (unsigned)ssk.m_offset ^ (ssk.m_fpRel ? 0x1000000 : 0);
}
static bool Equals(StackSlotIdKey ssk1, StackSlotIdKey ssk2)
{
return ssk1.m_offset == ssk2.m_offset && ssk1.m_fpRel == ssk2.m_fpRel && ssk1.m_flags == ssk2.m_flags;
}
};
typedef JitHashTable<RegSlotIdKey, RegSlotIdKey, GcSlotId> RegSlotMap;
typedef JitHashTable<StackSlotIdKey, StackSlotIdKey, GcSlotId> StackSlotMap;
#endif
typedef JitHashTable<GenTree*, JitPtrKeyFuncs<GenTree>, VARSET_TP*> NodeToVarsetPtrMap;
class GCInfo
{
friend class CodeGen;
private:
Compiler* compiler;
RegSet* regSet;
public:
GCInfo(Compiler* theCompiler);
void gcResetForBB();
void gcMarkRegSetGCref(regMaskTP regMask DEBUGARG(bool forceOutput = false));
void gcMarkRegSetByref(regMaskTP regMask DEBUGARG(bool forceOutput = false));
void gcMarkRegSetNpt(regMaskTP regMask DEBUGARG(bool forceOutput = false));
void gcMarkRegPtrVal(regNumber reg, var_types type);
#ifdef DEBUG
void gcDspGCrefSetChanges(regMaskTP gcRegGCrefSetNew DEBUGARG(bool forceOutput = false));
void gcDspByrefSetChanges(regMaskTP gcRegByrefSetNew DEBUGARG(bool forceOutput = false));
#endif // DEBUG
/*****************************************************************************/
//-------------------------------------------------------------------------
//
// The following keeps track of which registers currently hold pointer
// values.
//
regMaskTP gcRegGCrefSetCur; // current regs holding GCrefs
regMaskTP gcRegByrefSetCur; // current regs holding Byrefs
VARSET_TP gcTrkStkPtrLcls; // set of tracked stack ptr lcls (GCref and Byref) - no args
VARSET_TP gcVarPtrSetCur; // currently live part of "gcTrkStkPtrLcls"
//-------------------------------------------------------------------------
//
// The following keeps track of the lifetimes of non-register variables that
// hold pointers.
//
struct varPtrDsc
{
varPtrDsc* vpdNext;
unsigned vpdVarNum; // which variable is this about?
unsigned vpdBegOfs; // the offset where life starts
unsigned vpdEndOfs; // the offset where life starts
};
varPtrDsc* gcVarPtrList;
varPtrDsc* gcVarPtrLast;
void gcVarPtrSetInit();
/*****************************************************************************/
// 'pointer value' register tracking and argument pushes/pops tracking.
enum rpdArgType_t
{
rpdARG_POP,
rpdARG_PUSH,
rpdARG_KILL
};
struct regPtrDsc
{
regPtrDsc* rpdNext; // next entry in the list
unsigned rpdOffs; // the offset of the instruction
union // 2-16 byte union (depending on architecture)
{
struct // 2-16 byte structure (depending on architecture)
{
regMaskSmall rpdAdd; // regptr bitset being added
regMaskSmall rpdDel; // regptr bitset being removed
} rpdCompiler;
unsigned short rpdPtrArg; // arg offset or popped arg count
};
#ifndef JIT32_GCENCODER
unsigned char rpdCallInstrSize; // Length of the call instruction.
#endif
unsigned short rpdArg : 1; // is this an argument descriptor?
unsigned short rpdArgType : 2; // is this an argument push,pop, or kill?
rpdArgType_t rpdArgTypeGet()
{
return (rpdArgType_t)rpdArgType;
}
unsigned short rpdGCtype : 2; // is this a pointer, after all?
GCtype rpdGCtypeGet()
{
return (GCtype)rpdGCtype;
}
unsigned short rpdIsThis : 1; // is it the 'this' pointer
unsigned short rpdCall : 1; // is this a true call site?
unsigned short : 1; // Padding bit, so next two start on a byte boundary
unsigned short rpdCallGCrefRegs : CNT_CALLEE_SAVED; // Callee-saved registers containing GC pointers.
unsigned short rpdCallByrefRegs : CNT_CALLEE_SAVED; // Callee-saved registers containing byrefs.
#ifndef JIT32_GCENCODER
bool rpdIsCallInstr()
{
return rpdCall && rpdCallInstrSize != 0;
}
#endif
};
regPtrDsc* gcRegPtrList;
regPtrDsc* gcRegPtrLast;
unsigned gcPtrArgCnt;
#ifndef JIT32_GCENCODER
enum MakeRegPtrMode
{
MAKE_REG_PTR_MODE_ASSIGN_SLOTS,
MAKE_REG_PTR_MODE_DO_WORK
};
// This method has two modes. In the "assign slots" mode, it figures out what stack locations are
// used to contain GC references, and whether those locations contain byrefs or pinning references,
// building up mappings from tuples of <offset X byref/pinning> to the corresponding slot id.
// In the "do work" mode, we use these slot ids to actually declare live ranges to the encoder.
void gcMakeVarPtrTable(GcInfoEncoder* gcInfoEncoder, MakeRegPtrMode mode);
// At instruction offset "instrOffset," the set of registers indicated by "regMask" is becoming live or dead,
// depending on whether "newState" is "GC_SLOT_DEAD" or "GC_SLOT_LIVE". The subset of registers whose corresponding
// bits are set in "byRefMask" contain by-refs rather than regular GC pointers. "*pPtrRegs" is the set of
// registers currently known to contain pointers. If "mode" is "ASSIGN_SLOTS", computes and records slot
// ids for the registers. If "mode" is "DO_WORK", informs "gcInfoEncoder" about the state transition,
// using the previously assigned slot ids, and updates "*pPtrRegs" appropriately.
void gcInfoRecordGCRegStateChange(GcInfoEncoder* gcInfoEncoder,
MakeRegPtrMode mode,
unsigned instrOffset,
regMaskSmall regMask,
GcSlotState newState,
regMaskSmall byRefMask,
regMaskSmall* pPtrRegs);
// regPtrDsc is also used to encode writes to the outgoing argument space (as if they were pushes)
void gcInfoRecordGCStackArgLive(GcInfoEncoder* gcInfoEncoder, MakeRegPtrMode mode, regPtrDsc* genStackPtr);
// Walk all the pushes between genStackPtrFirst (inclusive) and genStackPtrLast (exclusive)
// and mark them as going dead at instrOffset
void gcInfoRecordGCStackArgsDead(GcInfoEncoder* gcInfoEncoder,
unsigned instrOffset,
regPtrDsc* genStackPtrFirst,
regPtrDsc* genStackPtrLast);
// Update the flags for a stack allocated object
void gcUpdateFlagForStackAllocatedObjects(GcSlotFlags& flags);
#endif
#if MEASURE_PTRTAB_SIZE
static size_t s_gcRegPtrDscSize;
static size_t s_gcTotalPtrTabSize;
#endif
regPtrDsc* gcRegPtrAllocDsc();
/*****************************************************************************/
//-------------------------------------------------------------------------
//
// If we're not generating fully interruptible code, we create a simple
// linked list of call descriptors.
//
struct CallDsc
{
CallDsc* cdNext;
void* cdBlock; // the code block of the call
unsigned cdOffs; // the offset of the call
#ifndef JIT32_GCENCODER
unsigned short cdCallInstrSize; // the size of the call instruction.
#endif
unsigned short cdArgCnt;
union {
struct // used if cdArgCnt == 0
{
unsigned cdArgMask; // ptr arg bitfield
unsigned cdByrefArgMask; // byref qualifier for cdArgMask
} u1;
unsigned* cdArgTable; // used if cdArgCnt != 0
};
regMaskSmall cdGCrefRegs;
regMaskSmall cdByrefRegs;
};
CallDsc* gcCallDescList;
CallDsc* gcCallDescLast;
//-------------------------------------------------------------------------
void gcCountForHeader(UNALIGNED unsigned int* untrackedCount, UNALIGNED unsigned int* varPtrTableSize);
#ifdef JIT32_GCENCODER
size_t gcMakeRegPtrTable(BYTE* dest, int mask, const InfoHdr& header, unsigned codeSize, size_t* pArgTabOffset);
#else
RegSlotMap* m_regSlotMap;
StackSlotMap* m_stackSlotMap;
// This method has two modes. In the "assign slots" mode, it figures out what registers and stack
// locations are used to contain GC references, and whether those locations contain byrefs or pinning
// references, building up mappings from tuples of <reg/offset X byref/pinning> to the corresponding
// slot id (in the two member fields declared above). In the "do work" mode, we use these slot ids to
// actually declare live ranges to the encoder.
void gcMakeRegPtrTable(GcInfoEncoder* gcInfoEncoder,
unsigned codeSize,
unsigned prologSize,
MakeRegPtrMode mode,
unsigned* callCntRef);
#endif
#ifdef JIT32_GCENCODER
size_t gcPtrTableSize(const InfoHdr& header, unsigned codeSize, size_t* pArgTabOffset);
BYTE* gcPtrTableSave(BYTE* destPtr, const InfoHdr& header, unsigned codeSize, size_t* pArgTabOffset);
#endif
void gcRegPtrSetInit();
/*****************************************************************************/
// This enumeration yields the result of the analysis below, whether a store
// requires a write barrier:
enum WriteBarrierForm
{
WBF_NoBarrier, // No barrier is required
WBF_BarrierUnknown, // A barrier is required, no information on checked/unchecked.
WBF_BarrierChecked, // A checked barrier is required.
WBF_BarrierUnchecked, // An unchecked barrier is required.
WBF_NoBarrier_CheckNotHeapInDebug, // We believe that no barrier is required because the
// target is not in the heap -- but in debug build use a
// barrier call that verifies this property. (Because the
// target not being in the heap relies on a convention that
// might accidentally be violated in the future.)
};
WriteBarrierForm gcIsWriteBarrierCandidate(GenTree* tgt, GenTree* assignVal);
bool gcIsWriteBarrierStoreIndNode(GenTree* op);
// Returns a WriteBarrierForm decision based on the form of "tgtAddr", which is assumed to be the
// argument of a GT_IND LHS.
WriteBarrierForm gcWriteBarrierFormFromTargetAddress(GenTree* tgtAddr);
//-------------------------------------------------------------------------
//
// These record the info about the procedure in the info-block
//
CLANG_FORMAT_COMMENT_ANCHOR;
#ifdef JIT32_GCENCODER
private:
BYTE* gcEpilogTable;
unsigned gcEpilogPrevOffset;
size_t gcInfoBlockHdrSave(BYTE* dest,
int mask,
unsigned methodSize,
unsigned prologSize,
unsigned epilogSize,
InfoHdr* header,
int* s_cached);
public:
static void gcInitEncoderLookupTable();
private:
static size_t gcRecordEpilog(void* pCallBackData, unsigned offset);
#else // JIT32_GCENCODER
void gcInfoBlockHdrSave(GcInfoEncoder* gcInfoEncoder, unsigned methodSize, unsigned prologSize);
#endif // JIT32_GCENCODER
#if !defined(JIT32_GCENCODER) || defined(WIN64EXCEPTIONS)
// This method expands the tracked stack variables lifetimes so that any lifetimes within filters
// are reported as pinned.
void gcMarkFilterVarsPinned();
// Insert a varPtrDsc to gcVarPtrList that was generated by splitting lifetimes
void gcInsertVarPtrDscSplit(varPtrDsc* desc, varPtrDsc* begin);
#ifdef DEBUG
void gcDumpVarPtrDsc(varPtrDsc* desc);
#endif // DEBUG
#endif // !defined(JIT32_GCENCODER) || defined(WIN64EXCEPTIONS)
#if DUMP_GC_TABLES
void gcFindPtrsInFrame(const void* infoBlock, const void* codeBlock, unsigned offs);
#ifdef JIT32_GCENCODER
unsigned gcInfoBlockHdrDump(const BYTE* table,
InfoHdr* header, /* OUT */
unsigned* methodSize); /* OUT */
unsigned gcDumpPtrTable(const BYTE* table, const InfoHdr& header, unsigned methodSize);
#endif // JIT32_GCENCODER
#endif // DUMP_GC_TABLES
public:
// This method updates the appropriate reg masks when a variable is moved.
void gcUpdateForRegVarMove(regMaskTP srcMask, regMaskTP dstMask, LclVarDsc* varDsc);
private:
ReturnKind getReturnKind();
};
inline unsigned char encodeUnsigned(BYTE* dest, unsigned value)
{
unsigned char size = 1;
unsigned tmp = value;
while (tmp > 0x7F)
{
tmp >>= 7;
assert(size < 6); // Invariant.
size++;
}
if (dest)
{
// write the bytes starting at the end of dest in LSB to MSB order
BYTE* p = dest + size;
BYTE cont = 0; // The last byte has no continuation flag
while (value > 0x7F)
{
*--p = cont | (value & 0x7f);
value >>= 7;
cont = 0x80; // Non last bytes have a continuation flag
}
*--p = cont | (BYTE)value; // Now write the first byte
assert(p == dest);
}
return size;
}
inline unsigned char encodeUDelta(BYTE* dest, unsigned value, unsigned lastValue)
{
assert(value >= lastValue);
return encodeUnsigned(dest, value - lastValue);
}
inline unsigned char encodeSigned(BYTE* dest, int val)
{
unsigned char size = 1;
unsigned value = val;
BYTE neg = 0;
if (val < 0)
{
value = -val;
neg = 0x40;
}
unsigned tmp = value;
while (tmp > 0x3F)
{
tmp >>= 7;
assert(size < 16); // Definitely sufficient for unsigned. Fits in an unsigned char, certainly.
size++;
}
if (dest)
{
// write the bytes starting at the end of dest in LSB to MSB order
BYTE* p = dest + size;
BYTE cont = 0; // The last byte has no continuation flag
while (value > 0x3F)
{
*--p = cont | (value & 0x7f);
value >>= 7;
cont = 0x80; // Non last bytes have a continuation flag
}
*--p = neg | cont | (BYTE)value; // Now write the first byte
assert(p == dest);
}
return size;
}
#endif // _JITGCINFO_H_
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