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ee_il_dll.cpp
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ee_il_dll.cpp
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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.
/*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
XX XX
XX ee_jit.cpp XX
XX XX
XX The functionality needed for the JIT DLL. Includes the DLL entry point XX
XX XX
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
*/
#include "jitpch.h"
#ifdef _MSC_VER
#pragma hdrstop
#endif
#include "emit.h"
#include "corexcep.h"
#if !defined(HOST_UNIX)
#include <io.h> // For _dup, _setmode
#include <fcntl.h> // For _O_TEXT
#include <errno.h> // For EINVAL
#endif
#ifndef DLLEXPORT
#define DLLEXPORT
#endif // !DLLEXPORT
/*****************************************************************************/
ICorJitHost* g_jitHost = nullptr;
bool g_jitInitialized = false;
/*****************************************************************************/
extern "C" DLLEXPORT void jitStartup(ICorJitHost* jitHost)
{
if (g_jitInitialized)
{
if (jitHost != g_jitHost)
{
// We normally don't expect jitStartup() to be invoked more than once.
// (We check whether it has been called once due to an abundance of caution.)
// However, during SuperPMI playback of MCH file, we need to JIT many different methods.
// Each one carries its own environment configuration state.
// So, we need the JIT to reload the JitConfig state for each change in the environment state of the
// replayed compilations.
// We do this by calling jitStartup with a different ICorJitHost,
// and have the JIT re-initialize its JitConfig state when this happens.
JitConfig.destroy(g_jitHost);
JitConfig.initialize(jitHost);
g_jitHost = jitHost;
}
return;
}
#ifdef HOST_UNIX
int err = PAL_InitializeDLL();
if (err != 0)
{
return;
}
#endif
g_jitHost = jitHost;
assert(!JitConfig.isInitialized());
JitConfig.initialize(jitHost);
Compiler::compStartup();
g_jitInitialized = true;
}
static FILE* volatile s_jitstdout;
static FILE* jitstdoutInit()
{
const char* jitStdOutFile = JitConfig.JitStdOutFile();
FILE* file = nullptr;
if (jitStdOutFile != nullptr)
{
file = fopen_utf8(jitStdOutFile, "a");
assert(file != nullptr);
}
#if !defined(HOST_UNIX)
if (file == nullptr)
{
int stdoutFd = _fileno(procstdout());
// Check fileno error output(s) -1 may overlap with errno result
// but is included for completeness.
// We want to detect the case where the initial handle is null
// or bogus and avoid making further calls.
if ((stdoutFd != -1) && (stdoutFd != -2) && (errno != EINVAL))
{
int jitstdoutFd = _dup(stdoutFd);
// Check the error status returned by dup.
if (jitstdoutFd != -1)
{
_setmode(jitstdoutFd, _O_TEXT);
file = _fdopen(jitstdoutFd, "w");
assert(file != nullptr);
// Prevent the FILE* from buffering its output in order to avoid calls to
// `fflush()` throughout the code.
setvbuf(file, nullptr, _IONBF, 0);
}
}
}
#endif // !HOST_UNIX
if (file == nullptr)
{
file = procstdout();
}
FILE* observed = InterlockedCompareExchangeT(&s_jitstdout, file, nullptr);
if (observed != nullptr)
{
if (file != procstdout())
{
fclose(file);
}
return observed;
}
return file;
}
FILE* jitstdout()
{
FILE* file = s_jitstdout;
if (file != nullptr)
{
return file;
}
return jitstdoutInit();
}
// Like printf/logf, but only outputs to jitstdout -- skips call back into EE.
int jitprintf(const char* fmt, ...)
{
va_list vl;
va_start(vl, fmt);
int status = vfprintf(jitstdout(), fmt, vl);
va_end(vl);
return status;
}
void jitShutdown(bool processIsTerminating)
{
if (!g_jitInitialized)
{
return;
}
Compiler::compShutdown();
FILE* file = s_jitstdout;
if ((file != nullptr) && (file != procstdout()))
{
// When the process is terminating, the fclose call is unnecessary and is also prone to
// crashing since the UCRT itself often frees the backing memory earlier on in the
// termination sequence.
if (!processIsTerminating)
{
fclose(file);
}
}
g_jitInitialized = false;
}
/*****************************************************************************/
static CILJit g_CILJit;
DLLEXPORT ICorJitCompiler* getJit()
{
if (!g_jitInitialized)
{
return nullptr;
}
return &g_CILJit;
}
/*****************************************************************************/
// Information kept in thread-local storage. This is used in the noway_assert exceptional path.
// If you are using it more broadly in retail code, you would need to understand the
// performance implications of accessing TLS.
thread_local void* gJitTls = nullptr;
static void* GetJitTls()
{
return gJitTls;
}
void SetJitTls(void* value)
{
gJitTls = value;
}
#if defined(DEBUG)
JitTls::JitTls(ICorJitInfo* jitInfo)
: m_compiler(nullptr)
, m_logEnv(jitInfo)
{
m_next = reinterpret_cast<JitTls*>(GetJitTls());
SetJitTls(this);
}
JitTls::~JitTls()
{
SetJitTls(m_next);
}
LogEnv* JitTls::GetLogEnv()
{
return &reinterpret_cast<JitTls*>(GetJitTls())->m_logEnv;
}
Compiler* JitTls::GetCompiler()
{
return reinterpret_cast<JitTls*>(GetJitTls())->m_compiler;
}
void JitTls::SetCompiler(Compiler* compiler)
{
reinterpret_cast<JitTls*>(GetJitTls())->m_compiler = compiler;
}
#else // !defined(DEBUG)
JitTls::JitTls(ICorJitInfo* jitInfo)
{
}
JitTls::~JitTls()
{
}
Compiler* JitTls::GetCompiler()
{
return reinterpret_cast<Compiler*>(GetJitTls());
}
void JitTls::SetCompiler(Compiler* compiler)
{
SetJitTls(compiler);
}
#endif // !defined(DEBUG)
//****************************************************************************
// The main JIT function for the 32 bit JIT. See code:ICorJitCompiler#EEToJitInterface for more on the EE-JIT
// interface. Things really don't get going inside the JIT until the code:Compiler::compCompile#Phases
// method. Usually that is where you want to go.
CorJitResult CILJit::compileMethod(ICorJitInfo* compHnd,
CORINFO_METHOD_INFO* methodInfo,
unsigned flags,
uint8_t** entryAddress,
uint32_t* nativeSizeOfCode)
{
JitFlags jitFlags;
assert(flags == CORJIT_FLAGS::CORJIT_FLAG_CALL_GETJITFLAGS);
CORJIT_FLAGS corJitFlags;
DWORD jitFlagsSize = compHnd->getJitFlags(&corJitFlags, sizeof(corJitFlags));
assert(jitFlagsSize == sizeof(corJitFlags));
jitFlags.SetFromFlags(corJitFlags);
int result;
void* methodCodePtr = nullptr;
CORINFO_METHOD_HANDLE methodHandle = methodInfo->ftn;
JitTls jitTls(compHnd); // Initialize any necessary thread-local state
assert(methodInfo->ILCode);
result = jitNativeCode(methodHandle, methodInfo->scope, compHnd, methodInfo, &methodCodePtr, nativeSizeOfCode,
&jitFlags, nullptr);
if (result == CORJIT_OK)
{
*entryAddress = (BYTE*)methodCodePtr;
}
return CorJitResult(result);
}
void CILJit::ProcessShutdownWork(ICorStaticInfo* statInfo)
{
jitShutdown(false);
Compiler::ProcessShutdownWork(statInfo);
}
/*****************************************************************************
* Verify the JIT/EE interface identifier.
*/
void CILJit::getVersionIdentifier(GUID* versionIdentifier)
{
assert(versionIdentifier != nullptr);
memcpy(versionIdentifier, &JITEEVersionIdentifier, sizeof(GUID));
}
#ifdef TARGET_OS_RUNTIMEDETERMINED
bool TargetOS::OSSettingConfigured = false;
#ifndef TARGET_UNIX_OS_RUNTIMEDETERMINED // This define is only set if ONLY the different unix variants are
// runtimedetermined
bool TargetOS::IsWindows = false;
bool TargetOS::IsUnix = false;
#endif
bool TargetOS::IsApplePlatform = false;
#endif
/*****************************************************************************
* Set the OS that this JIT should be generating code for. The contract with the VM
* is that this must be called before compileMethod is called.
*/
void CILJit::setTargetOS(CORINFO_OS os)
{
#ifdef TARGET_OS_RUNTIMEDETERMINED
TargetOS::IsApplePlatform = os == CORINFO_APPLE;
#ifndef TARGET_UNIX_OS_RUNTIMEDETERMINED // This define is only set if ONLY the different unix variants are
// runtimedetermined
TargetOS::IsUnix = (os == CORINFO_UNIX) || (os == CORINFO_APPLE);
TargetOS::IsWindows = os == CORINFO_WINNT;
#endif
TargetOS::OSSettingConfigured = true;
#endif
}
//------------------------------------------------------------------------
// eeGetArgSize: Returns the number of bytes required for the given type argument
// including padding after the actual value.
//
// Arguments:
// corInfoType - EE type of the argument
// typeHnd - if the type is a value class, its class handle
//
// Return value:
// the size in bytes when the type is passed on the stack for the call.
//
// Notes:
// - On most platforms arguments are passed with TARGET_POINTER_SIZE alignment,
// so all types take an integer number of TARGET_POINTER_SIZE slots.
// It is different for arm64 apple that packs some types without alignment and padding.
// If the argument is passed by reference then the method returns REF size.
//
unsigned Compiler::eeGetArgSize(CorInfoType corInfoType, CORINFO_CLASS_HANDLE typeHnd)
{
var_types argType = JITtype2varType(corInfoType);
#if defined(TARGET_AMD64)
// Everything fits into a single 'slot' size
// to accommodate irregular sized structs, they are passed byref
#ifdef UNIX_AMD64_ABI
if (varTypeIsStruct(argType))
{
unsigned structSize = info.compCompHnd->getClassSize(typeHnd);
return roundUp(structSize, TARGET_POINTER_SIZE);
}
#endif // UNIX_AMD64_ABI
return TARGET_POINTER_SIZE;
#else // !TARGET_AMD64
unsigned argSize;
var_types hfaType = TYP_UNDEF;
bool isHfa = false;
if (varTypeIsStruct(argType))
{
hfaType = GetHfaType(typeHnd);
isHfa = (hfaType != TYP_UNDEF);
unsigned structSize = info.compCompHnd->getClassSize(typeHnd);
// make certain the EE passes us back the right thing for refanys
assert(corInfoType != CORINFO_TYPE_REFANY || structSize == 2 * TARGET_POINTER_SIZE);
// For each target that supports passing struct args in multiple registers
// apply the target specific rules for them here:
#if FEATURE_MULTIREG_ARGS
#if defined(TARGET_ARM64)
// Any structs that are larger than MAX_PASS_MULTIREG_BYTES are always passed by reference
if (structSize > MAX_PASS_MULTIREG_BYTES)
{
// This struct is passed by reference using a single 'slot'
return TARGET_POINTER_SIZE;
}
else
{
// Is the struct larger than 16 bytes
if (structSize > (2 * TARGET_POINTER_SIZE))
{
if (TargetOS::IsWindows && info.compIsVarArgs)
{
// Arm64 Varargs ABI requires passing in general purpose
// registers. Force the decision of whether this is an HFA
// to false to correctly pass as if it was not an HFA.
isHfa = false;
}
if (!isHfa)
{
// This struct is passed by reference using a single 'slot'
return TARGET_POINTER_SIZE;
}
}
}
#elif defined(TARGET_LOONGARCH64) || defined(TARGET_RISCV64)
// Any structs that are larger than MAX_PASS_MULTIREG_BYTES are always passed by reference
if (structSize > MAX_PASS_MULTIREG_BYTES)
{
// This struct is passed by reference using a single 'slot'
return TARGET_POINTER_SIZE;
}
// otherwise will we pass this struct by value in multiple registers
#elif !defined(TARGET_ARM)
NYI("unknown target");
#endif // defined(TARGET_XXX)
#endif // FEATURE_MULTIREG_ARGS
// Otherwise we will pass this struct by value in multiple registers/stack bytes.
argSize = structSize;
}
else
{
argSize = genTypeSize(argType);
}
const unsigned argSizeAlignment = eeGetArgSizeAlignment(argType, (hfaType == TYP_FLOAT));
const unsigned alignedArgSize = roundUp(argSize, argSizeAlignment);
return alignedArgSize;
#endif
}
//------------------------------------------------------------------------
// eeGetArgSizeAlignment: Return alignment for an argument size.
//
// Arguments:
// type - the argument type
// isFloatHfa - is it an HFA<float> type
//
// Return value:
// the required argument size alignment in bytes.
//
// Notes:
// Usually values passed on the stack are aligned to stack slot (i.e. pointer size), except for
// on Apple ARM ABI that allows packing multiple args into a single stack slot.
//
// The arg size alignment can be different from the normal alignment. One
// example is on arm32 where a struct containing a double and float can
// explicitly have size 12 but with alignment 8, in which case the size is
// aligned to 4 (the stack slot size) while frame layout must still handle
// aligning the argument to 8.
//
// static
unsigned Compiler::eeGetArgSizeAlignment(var_types type, bool isFloatHfa)
{
if (compAppleArm64Abi())
{
if (isFloatHfa)
{
assert(varTypeIsStruct(type));
return sizeof(float);
}
if (varTypeIsStruct(type))
{
return TARGET_POINTER_SIZE;
}
const unsigned argSize = genTypeSize(type);
assert((0 < argSize) && (argSize <= TARGET_POINTER_SIZE));
return argSize;
}
else
{
return TARGET_POINTER_SIZE;
}
}
/*****************************************************************************/
GenTree* Compiler::eeGetPInvokeCookie(CORINFO_SIG_INFO* szMetaSig)
{
void *cookie, *pCookie;
cookie = info.compCompHnd->GetCookieForPInvokeCalliSig(szMetaSig, &pCookie);
assert((cookie == nullptr) != (pCookie == nullptr));
return gtNewIconEmbHndNode(cookie, pCookie, GTF_ICON_PINVKI_HDL, szMetaSig);
}
//------------------------------------------------------------------------
// eeGetArrayDataOffset: Gets the offset of a SDArray's first element
//
// Return Value:
// The offset to the first array element.
//
// Notes:
// See the comments at the definition of CORINFO_Array for a description of how arrays are laid out in memory.
//
// static
unsigned Compiler::eeGetArrayDataOffset()
{
return OFFSETOF__CORINFO_Array__data;
}
//------------------------------------------------------------------------
// eeGetMDArrayDataOffset: Gets the offset of a MDArray's first element
//
// Arguments:
// rank - The array rank
//
// Return Value:
// The offset to the first array element.
//
// Assumptions:
// The rank should be greater than 0.
//
// static
unsigned Compiler::eeGetMDArrayDataOffset(unsigned rank)
{
assert(rank > 0);
// Note that below we're specifically using genTypeSize(TYP_INT) because array
// indices are not native int.
return eeGetArrayDataOffset() + 2 * genTypeSize(TYP_INT) * rank;
}
//------------------------------------------------------------------------
// eeGetMDArrayLengthOffset: Returns the offset from the Array object to the
// size for the given dimension.
//
// Arguments:
// rank - the rank of the array
// dimension - the dimension for which the lower bound offset will be returned.
//
// Return Value:
// The offset.
//
// static
unsigned Compiler::eeGetMDArrayLengthOffset(unsigned rank, unsigned dimension)
{
// Note that we don't actually need the `rank` value for this calculation, but we pass it anyway,
// to be consistent with other MD array functions.
assert(rank > 0);
assert(dimension < rank);
// Note that the lower bound and length fields of the Array object are always TYP_INT, even on 64-bit targets.
return eeGetArrayDataOffset() + genTypeSize(TYP_INT) * dimension;
}
//------------------------------------------------------------------------
// eeGetMDArrayLowerBoundOffset: Returns the offset from the Array object to the
// lower bound for the given dimension.
//
// Arguments:
// rank - the rank of the array
// dimension - the dimension for which the lower bound offset will be returned.
//
// Return Value:
// The offset.
//
// static
unsigned Compiler::eeGetMDArrayLowerBoundOffset(unsigned rank, unsigned dimension)
{
assert(rank > 0);
assert(dimension < rank);
// Note that the lower bound and length fields of the Array object are always TYP_INT, even on 64-bit targets.
return eeGetArrayDataOffset() + genTypeSize(TYP_INT) * (dimension + rank);
}
/*****************************************************************************/
void Compiler::eeGetStmtOffsets()
{
ULONG32 offsetsCount;
uint32_t* offsets;
ICorDebugInfo::BoundaryTypes offsetsImplicit;
if (compIsForInlining())
{
// We do not get explicit boundaries for inlinees, only implicit ones.
offsetsImplicit = impInlineRoot()->info.compStmtOffsetsImplicit;
offsetsCount = 0;
offsets = nullptr;
}
else
{
info.compCompHnd->getBoundaries(info.compMethodHnd, &offsetsCount, &offsets, &offsetsImplicit);
}
/* Set the implicit boundaries */
info.compStmtOffsetsImplicit = (ICorDebugInfo::BoundaryTypes)offsetsImplicit;
/* Process the explicit boundaries */
info.compStmtOffsetsCount = 0;
if (offsetsCount == 0)
{
return;
}
info.compStmtOffsets = new (this, CMK_DebugInfo) IL_OFFSET[offsetsCount];
for (unsigned i = 0; i < offsetsCount; i++)
{
if (offsets[i] > info.compILCodeSize)
{
continue;
}
info.compStmtOffsets[info.compStmtOffsetsCount] = offsets[i];
info.compStmtOffsetsCount++;
}
info.compCompHnd->freeArray(offsets);
}
/*****************************************************************************
*
* Debugging support - Local var info
*/
void Compiler::eeSetLVcount(unsigned count)
{
assert(opts.compScopeInfo);
JITDUMP("VarLocInfo count is %d\n", count);
eeVarsCount = count;
if (eeVarsCount)
{
eeVars = (VarResultInfo*)info.compCompHnd->allocateArray(eeVarsCount * sizeof(eeVars[0]));
}
else
{
eeVars = nullptr;
}
}
void Compiler::eeSetLVinfo(unsigned which,
UNATIVE_OFFSET startOffs,
UNATIVE_OFFSET length,
unsigned varNum,
const CodeGenInterface::siVarLoc& varLoc)
{
// ICorDebugInfo::VarLoc and CodeGenInterface::siVarLoc have to overlap
// This is checked in siInit()
assert(opts.compScopeInfo);
assert(eeVarsCount > 0);
assert(which < eeVarsCount);
if (eeVars != nullptr)
{
eeVars[which].startOffset = startOffs;
eeVars[which].endOffset = startOffs + length;
eeVars[which].varNumber = varNum;
eeVars[which].loc = varLoc;
}
}
void Compiler::eeSetLVdone()
{
// necessary but not sufficient condition that the 2 struct definitions overlap
assert(sizeof(eeVars[0]) == sizeof(ICorDebugInfo::NativeVarInfo));
assert(opts.compScopeInfo);
#ifdef DEBUG
if (verbose || opts.dspDebugInfo)
{
eeDispVars(info.compMethodHnd, eeVarsCount, (ICorDebugInfo::NativeVarInfo*)eeVars);
}
#endif // DEBUG
if ((eeVarsCount == 0) && (eeVars != nullptr))
{
// We still call setVars with nullptr when eeVarsCount is 0 as part of the contract.
// We also need to free the nonused memory.
info.compCompHnd->freeArray(eeVars);
eeVars = nullptr;
}
info.compCompHnd->setVars(info.compMethodHnd, eeVarsCount, (ICorDebugInfo::NativeVarInfo*)eeVars);
eeVars = nullptr; // We give up ownership after setVars()
}
void Compiler::eeGetVars()
{
ICorDebugInfo::ILVarInfo* varInfoTable;
ULONG32 varInfoCount;
bool extendOthers;
info.compCompHnd->getVars(info.compMethodHnd, &varInfoCount, &varInfoTable, &extendOthers);
#ifdef DEBUG
if (verbose)
{
printf("getVars() returned cVars = %d, extendOthers = %s\n", varInfoCount, extendOthers ? "true" : "false");
}
#endif
// Over allocate in case extendOthers is set.
SIZE_T varInfoCountExtra = varInfoCount;
if (extendOthers)
{
varInfoCountExtra += info.compLocalsCount;
}
if (varInfoCountExtra == 0)
{
return;
}
info.compVarScopes = new (this, CMK_DebugInfo) VarScopeDsc[varInfoCountExtra];
VarScopeDsc* localVarPtr = info.compVarScopes;
ICorDebugInfo::ILVarInfo* v = varInfoTable;
for (unsigned i = 0; i < varInfoCount; i++, v++)
{
#ifdef DEBUG
if (verbose)
{
printf("var:%d start:%d end:%d\n", v->varNumber, v->startOffset, v->endOffset);
}
#endif
if (v->startOffset >= v->endOffset)
{
continue;
}
assert(v->startOffset <= info.compILCodeSize);
assert(v->endOffset <= info.compILCodeSize);
localVarPtr->vsdLifeBeg = v->startOffset;
localVarPtr->vsdLifeEnd = v->endOffset;
localVarPtr->vsdLVnum = i;
localVarPtr->vsdVarNum = compMapILvarNum(v->varNumber);
#ifdef DEBUG
localVarPtr->vsdName = gtGetLclVarName(localVarPtr->vsdVarNum);
#endif
localVarPtr++;
info.compVarScopesCount++;
}
/* If extendOthers is set, then assume the scope of unreported vars
is the entire method. Note that this will cause fgExtendDbgLifetimes()
to zero-initialize all of them. This will be expensive if it's used
for too many variables.
*/
if (extendOthers)
{
// Allocate a bit-array for all the variables and initialize to false
bool* varInfoProvided = getAllocator(CMK_Unknown).allocate<bool>(info.compLocalsCount);
unsigned i;
for (i = 0; i < info.compLocalsCount; i++)
{
varInfoProvided[i] = false;
}
// Find which vars have absolutely no varInfo provided
for (i = 0; i < info.compVarScopesCount; i++)
{
varInfoProvided[info.compVarScopes[i].vsdVarNum] = true;
}
// Create entries for the variables with no varInfo
for (unsigned varNum = 0; varNum < info.compLocalsCount; varNum++)
{
if (varInfoProvided[varNum])
{
continue;
}
// Create a varInfo with scope over the entire method
localVarPtr->vsdLifeBeg = 0;
localVarPtr->vsdLifeEnd = info.compILCodeSize;
localVarPtr->vsdVarNum = varNum;
localVarPtr->vsdLVnum = info.compVarScopesCount;
#ifdef DEBUG
localVarPtr->vsdName = gtGetLclVarName(localVarPtr->vsdVarNum);
#endif
localVarPtr++;
info.compVarScopesCount++;
}
}
assert(localVarPtr <= info.compVarScopes + varInfoCountExtra);
if (varInfoCount != 0)
{
info.compCompHnd->freeArray(varInfoTable);
}
#ifdef DEBUG
if (verbose)
{
compDispLocalVars();
}
#endif // DEBUG
}
#ifdef DEBUG
void Compiler::eeDispVar(ICorDebugInfo::NativeVarInfo* var)
{
const char* name = nullptr;
if (var->varNumber == (DWORD)ICorDebugInfo::VARARGS_HND_ILNUM)
{
name = "varargsHandle";
}
else if (var->varNumber == (DWORD)ICorDebugInfo::RETBUF_ILNUM)
{
name = "retBuff";
}
else if (var->varNumber == (DWORD)ICorDebugInfo::TYPECTXT_ILNUM)
{
name = "typeCtx";
}
if (0 <= var->varNumber && var->varNumber < lvaCount)
{
printf("(");
gtDispLclVar(var->varNumber, false);
printf(")");
}
else
{
printf("(%10s)", (VarNameToStr(name) == nullptr) ? "UNKNOWN" : VarNameToStr(name));
}
printf(" : From %08Xh to %08Xh, in ", var->startOffset, var->endOffset);
switch ((CodeGenInterface::siVarLocType)var->loc.vlType)
{
case CodeGenInterface::VLT_REG:
case CodeGenInterface::VLT_REG_BYREF:
case CodeGenInterface::VLT_REG_FP:
printf("%s", getRegName(var->loc.vlReg.vlrReg));
if (var->loc.vlType == (ICorDebugInfo::VarLocType)CodeGenInterface::VLT_REG_BYREF)
{
printf(" byref");
}
break;
case CodeGenInterface::VLT_STK:
case CodeGenInterface::VLT_STK_BYREF:
if ((int)var->loc.vlStk.vlsBaseReg != (int)ICorDebugInfo::REGNUM_AMBIENT_SP)
{
printf("%s[%d] (1 slot)", getRegName(var->loc.vlStk.vlsBaseReg), var->loc.vlStk.vlsOffset);
}
else
{
printf(STR_SPBASE "'[%d] (1 slot)", var->loc.vlStk.vlsOffset);
}
if (var->loc.vlType == (ICorDebugInfo::VarLocType)CodeGenInterface::VLT_REG_BYREF)
{
printf(" byref");
}
break;
case CodeGenInterface::VLT_REG_REG:
printf("%s-%s", getRegName(var->loc.vlRegReg.vlrrReg1), getRegName(var->loc.vlRegReg.vlrrReg2));
break;
#ifndef TARGET_AMD64
case CodeGenInterface::VLT_REG_STK:
if ((int)var->loc.vlRegStk.vlrsStk.vlrssBaseReg != (int)ICorDebugInfo::REGNUM_AMBIENT_SP)
{
printf("%s-%s[%d]", getRegName(var->loc.vlRegStk.vlrsReg),
getRegName(var->loc.vlRegStk.vlrsStk.vlrssBaseReg), var->loc.vlRegStk.vlrsStk.vlrssOffset);
}
else
{
printf("%s-" STR_SPBASE "'[%d]", getRegName(var->loc.vlRegStk.vlrsReg),
var->loc.vlRegStk.vlrsStk.vlrssOffset);
}
break;
case CodeGenInterface::VLT_STK_REG:
unreached(); // unexpected
case CodeGenInterface::VLT_STK2:
if ((int)var->loc.vlStk2.vls2BaseReg != (int)ICorDebugInfo::REGNUM_AMBIENT_SP)
{
printf("%s[%d] (2 slots)", getRegName(var->loc.vlStk2.vls2BaseReg), var->loc.vlStk2.vls2Offset);
}
else
{
printf(STR_SPBASE "'[%d] (2 slots)", var->loc.vlStk2.vls2Offset);
}
break;
case CodeGenInterface::VLT_FPSTK:
printf("ST(L-%d)", var->loc.vlFPstk.vlfReg);
break;
case CodeGenInterface::VLT_FIXED_VA:
printf("fxd_va[%d]", var->loc.vlFixedVarArg.vlfvOffset);
break;
#endif // !TARGET_AMD64
default:
unreached(); // unexpected
}
printf("\n");
}
// Same parameters as ICorStaticInfo::setVars().
void Compiler::eeDispVars(CORINFO_METHOD_HANDLE ftn, ULONG32 cVars, ICorDebugInfo::NativeVarInfo* vars)
{
// Estimate number of unique vars with debug info
//
ALLVARSET_TP uniqueVars(AllVarSetOps::MakeEmpty(this));
for (unsigned i = 0; i < cVars; i++)
{
// ignore "special vars" and out of bounds vars
if ((((int)vars[i].varNumber) >= 0) && (vars[i].varNumber < lclMAX_ALLSET_TRACKED))
{
AllVarSetOps::AddElemD(this, uniqueVars, vars[i].varNumber);
}
}
printf("; Variable debug info: %d live ranges, %d vars for method %s\n", cVars,
AllVarSetOps::Count(this, uniqueVars), info.compFullName);
for (unsigned i = 0; i < cVars; i++)
{
eeDispVar(&vars[i]);
}
}
#endif // DEBUG
/*****************************************************************************
*
* Debugging support - Line number info
*/
void Compiler::eeSetLIcount(unsigned count)
{
assert(opts.compDbgInfo);
eeBoundariesCount = count;
if (eeBoundariesCount)
{
eeBoundaries =
(ICorDebugInfo::OffsetMapping*)info.compCompHnd->allocateArray(eeBoundariesCount * sizeof(eeBoundaries[0]));
}
else
{
eeBoundaries = nullptr;
}
}
void Compiler::eeSetLIinfo(unsigned which, UNATIVE_OFFSET nativeOffset, IPmappingDscKind kind, const ILLocation& loc)
{
assert(opts.compDbgInfo);
assert(eeBoundariesCount > 0 && eeBoundaries != nullptr);
assert(which < eeBoundariesCount);
eeBoundaries[which].nativeOffset = nativeOffset;
eeBoundaries[which].source = (ICorDebugInfo::SourceTypes)0;
switch (kind)
{
case IPmappingDscKind::Normal:
eeBoundaries[which].ilOffset = loc.GetOffset();
eeBoundaries[which].source = loc.EncodeSourceTypes();
break;
case IPmappingDscKind::Prolog:
eeBoundaries[which].ilOffset = ICorDebugInfo::PROLOG;
eeBoundaries[which].source = ICorDebugInfo::STACK_EMPTY;
break;