path: root/src/ToolBox/superpmi/superpmi-shim-simple/icorjitinfo.cpp

//
// Copyright (c) Microsoft. All rights reserved.
// Licensed under the MIT license. See LICENSE file in the project root for full license information.
//

#include "standardpch.h"
#include "icorjitinfo.h"
#include "superpmi-shim-simple.h"
#include "ieememorymanager.h"
#include "icorjitcompiler.h"
#include "spmiutil.h"

//Stuff on ICorStaticInfo
/**********************************************************************************/
//
// ICorMethodInfo
//
/**********************************************************************************/
// return flags (defined above, CORINFO_FLG_PUBLIC ...)
DWORD interceptor_ICJI::getMethodAttribs (CORINFO_METHOD_HANDLE ftn /* IN */)
{
    return original_ICorJitInfo->getMethodAttribs(ftn);
}

// sets private JIT flags, which can be, retrieved using getAttrib.
void interceptor_ICJI::setMethodAttribs (CORINFO_METHOD_HANDLE ftn,/* IN */
                               CorInfoMethodRuntimeFlags attribs/* IN */)
{
    original_ICorJitInfo->setMethodAttribs(ftn, attribs);
}


// Given a method descriptor ftnHnd, extract signature information into sigInfo
//
// 'memberParent' is typically only set when verifying.  It should be the
// result of calling getMemberParent.
void interceptor_ICJI::getMethodSig (
            CORINFO_METHOD_HANDLE      ftn,        /* IN  */
            CORINFO_SIG_INFO          *sig,        /* OUT */
            CORINFO_CLASS_HANDLE      memberParent/* IN */
            )
{
    original_ICorJitInfo->getMethodSig(ftn, sig, memberParent);
}


 /*********************************************************************
 * Note the following methods can only be used on functions known
 * to be IL.  This includes the method being compiled and any method
 * that 'getMethodInfo' returns true for
 *********************************************************************/

 // return information about a method private to the implementation
 //      returns false if method is not IL, or is otherwise unavailable.
 //      This method is used to fetch data needed to inline functions
 bool interceptor_ICJI::getMethodInfo (
            CORINFO_METHOD_HANDLE   ftn,            /* IN  */
            CORINFO_METHOD_INFO*    info            /* OUT */
            )
{
    return original_ICorJitInfo->getMethodInfo(ftn, info);
}

// Decides if you have any limitations for inlining. If everything's OK, it will return
// INLINE_PASS and will fill out pRestrictions with a mask of restrictions the caller of this
// function must respect. If caller passes pRestrictions = nullptr, if there are any restrictions
// INLINE_FAIL will be returned
//
// The callerHnd must be the immediate caller (i.e. when we have a chain of inlined calls)
//
// The inlined method need not be verified

CorInfoInline interceptor_ICJI::canInline (
            CORINFO_METHOD_HANDLE       callerHnd,                  /* IN  */
            CORINFO_METHOD_HANDLE       calleeHnd,                  /* IN  */
            DWORD*                      pRestrictions               /* OUT */
            )
{
    return original_ICorJitInfo->canInline(callerHnd, calleeHnd, pRestrictions);
}

// Reports whether or not a method can be inlined, and why.  canInline is responsible for reporting all
// inlining results when it returns INLINE_FAIL and INLINE_NEVER.  All other results are reported by the
// JIT.
void interceptor_ICJI::reportInliningDecision (CORINFO_METHOD_HANDLE inlinerHnd,
                                                CORINFO_METHOD_HANDLE inlineeHnd,
                                                CorInfoInline inlineResult,
                                                const char * reason)
{
    original_ICorJitInfo->reportInliningDecision(inlinerHnd, inlineeHnd, inlineResult, reason);
}


// Returns false if the call is across security boundaries thus we cannot tailcall
//
// The callerHnd must be the immediate caller (i.e. when we have a chain of inlined calls)
bool interceptor_ICJI::canTailCall (
            CORINFO_METHOD_HANDLE   callerHnd,          /* IN */
            CORINFO_METHOD_HANDLE   declaredCalleeHnd,  /* IN */
            CORINFO_METHOD_HANDLE   exactCalleeHnd,     /* IN */
            bool fIsTailPrefix                          /* IN */
            )
{
    return original_ICorJitInfo->canTailCall(callerHnd, declaredCalleeHnd, exactCalleeHnd, fIsTailPrefix);
}

// Reports whether or not a method can be tail called, and why.
// canTailCall is responsible for reporting all results when it returns
// false.  All other results are reported by the JIT.
void interceptor_ICJI::reportTailCallDecision (CORINFO_METHOD_HANDLE callerHnd,
                                                   CORINFO_METHOD_HANDLE calleeHnd,
                                                   bool fIsTailPrefix,
                                                   CorInfoTailCall tailCallResult,
                                                   const char * reason)
{
    original_ICorJitInfo->reportTailCallDecision(callerHnd, calleeHnd, fIsTailPrefix, tailCallResult, reason);
}

// get individual exception handler
void interceptor_ICJI::getEHinfo(
            CORINFO_METHOD_HANDLE ftn,              /* IN  */
            unsigned          EHnumber,             /* IN */
            CORINFO_EH_CLAUSE* clause               /* OUT */
            )
{
    original_ICorJitInfo->getEHinfo(ftn, EHnumber, clause);
}

// return class it belongs to
CORINFO_CLASS_HANDLE interceptor_ICJI::getMethodClass (
            CORINFO_METHOD_HANDLE       method
            )
{
    return original_ICorJitInfo->getMethodClass(method);
}

// return module it belongs to
CORINFO_MODULE_HANDLE interceptor_ICJI::getMethodModule (
            CORINFO_METHOD_HANDLE       method
            )
{
    return original_ICorJitInfo->getMethodModule(method);
}

// This function returns the offset of the specified method in the
// vtable of it's owning class or interface.
void interceptor_ICJI::getMethodVTableOffset (
            CORINFO_METHOD_HANDLE       method,                 /* IN */
            unsigned*                   offsetOfIndirection,    /* OUT */
            unsigned*                   offsetAfterIndirection  /* OUT */
            )
{
    original_ICorJitInfo->getMethodVTableOffset(method, offsetOfIndirection, offsetAfterIndirection);
}

// Find the virtual method in implementingClass that overrides virtualMethod.
// Return null if devirtualization is not possible.
CORINFO_METHOD_HANDLE interceptor_ICJI::resolveVirtualMethod(
    CORINFO_METHOD_HANDLE virtualMethod,
    CORINFO_CLASS_HANDLE implementingClass,
    CORINFO_CONTEXT_HANDLE ownerType
    )
{
    return original_ICorJitInfo->resolveVirtualMethod(virtualMethod, implementingClass, ownerType);
}

// If a method's attributes have (getMethodAttribs) CORINFO_FLG_INTRINSIC set,
// getIntrinsicID() returns the intrinsic ID.
CorInfoIntrinsics interceptor_ICJI::getIntrinsicID(
            CORINFO_METHOD_HANDLE       method,
            bool*                       pMustExpand             /* OUT */
            )
{
    return original_ICorJitInfo->getIntrinsicID(method, pMustExpand);
}

// Is the given module the System.Numerics.Vectors module?
bool interceptor_ICJI::isInSIMDModule(
            CORINFO_CLASS_HANDLE        classHnd
            )
{
    return original_ICorJitInfo->isInSIMDModule(classHnd);
}

// return the unmanaged calling convention for a PInvoke
CorInfoUnmanagedCallConv interceptor_ICJI::getUnmanagedCallConv(
            CORINFO_METHOD_HANDLE       method
            )
{
    return original_ICorJitInfo->getUnmanagedCallConv(method);
}

// return if any marshaling is required for PInvoke methods.  Note that
// method == 0 => calli.  The call site sig is only needed for the varargs or calli case
BOOL interceptor_ICJI::pInvokeMarshalingRequired(
            CORINFO_METHOD_HANDLE       method,
            CORINFO_SIG_INFO*           callSiteSig
            )
{
    return original_ICorJitInfo->pInvokeMarshalingRequired(method, callSiteSig);
}

// Check constraints on method type arguments (only).
// The parent class should be checked separately using satisfiesClassConstraints(parent).
BOOL interceptor_ICJI::satisfiesMethodConstraints(
            CORINFO_CLASS_HANDLE        parent, // the exact parent of the method
            CORINFO_METHOD_HANDLE       method
            )
{
    return original_ICorJitInfo->satisfiesMethodConstraints(parent, method);
}

// Given a delegate target class, a target method parent class,  a  target method,
// a delegate class, check if the method signature is compatible with the Invoke method of the delegate
// (under the typical instantiation of any free type variables in the memberref signatures).
BOOL interceptor_ICJI::isCompatibleDelegate(
            CORINFO_CLASS_HANDLE        objCls,           /* type of the delegate target, if any */
            CORINFO_CLASS_HANDLE        methodParentCls,  /* exact parent of the target method, if any */
            CORINFO_METHOD_HANDLE       method,           /* (representative) target method, if any */
            CORINFO_CLASS_HANDLE        delegateCls,      /* exact type of the delegate */
            BOOL                        *pfIsOpenDelegate /* is the delegate open */
            )
{
    return original_ICorJitInfo->isCompatibleDelegate(objCls, methodParentCls, method, delegateCls, pfIsOpenDelegate);
}

// Determines whether the delegate creation obeys security transparency rules
BOOL interceptor_ICJI::isDelegateCreationAllowed (
            CORINFO_CLASS_HANDLE        delegateHnd,
            CORINFO_METHOD_HANDLE       calleeHnd
            )
{
    return original_ICorJitInfo->isDelegateCreationAllowed(delegateHnd, calleeHnd);
}


// Indicates if the method is an instance of the generic
// method that passes (or has passed) verification
CorInfoInstantiationVerification interceptor_ICJI::isInstantiationOfVerifiedGeneric (
            CORINFO_METHOD_HANDLE   method /* IN  */
            )
{
    return original_ICorJitInfo->isInstantiationOfVerifiedGeneric(method);
}

// Loads the constraints on a typical method definition, detecting cycles;
// for use in verification.
void interceptor_ICJI::initConstraintsForVerification(
            CORINFO_METHOD_HANDLE   method, /* IN */
            BOOL *pfHasCircularClassConstraints, /* OUT */
            BOOL *pfHasCircularMethodConstraint /* OUT */
            )
{
    original_ICorJitInfo->initConstraintsForVerification(method, pfHasCircularClassConstraints, pfHasCircularMethodConstraint);
}

CorInfoCanSkipVerificationResult interceptor_ICJI::canSkipMethodVerification (
            CORINFO_METHOD_HANDLE       ftnHandle
            )
{
    return original_ICorJitInfo->canSkipMethodVerification(ftnHandle);
}

// load and restore the method
void interceptor_ICJI::methodMustBeLoadedBeforeCodeIsRun(
            CORINFO_METHOD_HANDLE       method
            )
{
    original_ICorJitInfo->methodMustBeLoadedBeforeCodeIsRun(method);
}

CORINFO_METHOD_HANDLE interceptor_ICJI::mapMethodDeclToMethodImpl(
            CORINFO_METHOD_HANDLE       method
            )
{
    return original_ICorJitInfo->mapMethodDeclToMethodImpl(method);
}

// Returns the global cookie for the /GS unsafe buffer checks
// The cookie might be a constant value (JIT), or a handle to memory location (Ngen)
void interceptor_ICJI::getGSCookie(
            GSCookie * pCookieVal,                     // OUT
            GSCookie ** ppCookieVal                    // OUT
            )
{
    original_ICorJitInfo->getGSCookie(pCookieVal, ppCookieVal);
}

/**********************************************************************************/
//
// ICorModuleInfo
//
/**********************************************************************************/

// Resolve metadata token into runtime method handles.
void interceptor_ICJI::resolveToken(/* IN, OUT */ CORINFO_RESOLVED_TOKEN * pResolvedToken)
{
    original_ICorJitInfo->resolveToken(pResolvedToken);
}

bool interceptor_ICJI::tryResolveToken(/* IN, OUT */ CORINFO_RESOLVED_TOKEN * pResolvedToken)
{
    return original_ICorJitInfo->tryResolveToken(pResolvedToken);
}

// Signature information about the call sig
void interceptor_ICJI::findSig (
            CORINFO_MODULE_HANDLE       module,     /* IN */
            unsigned                    sigTOK,     /* IN */
            CORINFO_CONTEXT_HANDLE      context,    /* IN */
            CORINFO_SIG_INFO           *sig         /* OUT */
            )
{
    original_ICorJitInfo->findSig(module, sigTOK, context, sig);
}

// for Varargs, the signature at the call site may differ from
// the signature at the definition.  Thus we need a way of
// fetching the call site information
void interceptor_ICJI::findCallSiteSig (
            CORINFO_MODULE_HANDLE       module,     /* IN */
            unsigned                    methTOK,    /* IN */
            CORINFO_CONTEXT_HANDLE      context,    /* IN */
            CORINFO_SIG_INFO           *sig         /* OUT */
            )
{
    original_ICorJitInfo->findCallSiteSig(module, methTOK, context, sig);
}

CORINFO_CLASS_HANDLE interceptor_ICJI::getTokenTypeAsHandle (
            CORINFO_RESOLVED_TOKEN *    pResolvedToken /* IN  */)
{
    return original_ICorJitInfo->getTokenTypeAsHandle(pResolvedToken);
}

// Returns true if the module does not require verification
//
// If fQuickCheckOnlyWithoutCommit=TRUE, the function only checks that the
// module does not currently require verification in the current AppDomain.
// This decision could change in the future, and so should not be cached.
// If it is cached, it should only be used as a hint.
// This is only used by ngen for calculating certain hints.
//

// Returns enum whether the module does not require verification
// Also see ICorMethodInfo::canSkipMethodVerification();
CorInfoCanSkipVerificationResult interceptor_ICJI::canSkipVerification (
            CORINFO_MODULE_HANDLE       module     /* IN  */
            )
{
    return original_ICorJitInfo->canSkipVerification(module);
}

// Checks if the given metadata token is valid
BOOL interceptor_ICJI::isValidToken (
            CORINFO_MODULE_HANDLE       module,     /* IN  */
            unsigned                    metaTOK     /* IN  */
            )
{
    return original_ICorJitInfo->isValidToken(module, metaTOK);
}

// Checks if the given metadata token is valid StringRef
BOOL interceptor_ICJI::isValidStringRef (
            CORINFO_MODULE_HANDLE       module,     /* IN  */
            unsigned                    metaTOK     /* IN  */
            )
{
    return original_ICorJitInfo->isValidStringRef(module, metaTOK);
}

BOOL interceptor_ICJI::shouldEnforceCallvirtRestriction(
            CORINFO_MODULE_HANDLE   scope
            )
{
    return original_ICorJitInfo->shouldEnforceCallvirtRestriction(scope);
}

/**********************************************************************************/
//
// ICorClassInfo
//
/**********************************************************************************/

// If the value class 'cls' is isomorphic to a primitive type it will
// return that type, otherwise it will return CORINFO_TYPE_VALUECLASS
CorInfoType interceptor_ICJI::asCorInfoType (
            CORINFO_CLASS_HANDLE    cls
            )
{
    return original_ICorJitInfo->asCorInfoType(cls);
}

// for completeness
const char* interceptor_ICJI::getClassName (
            CORINFO_CLASS_HANDLE    cls
            )
{
    return original_ICorJitInfo->getClassName(cls);
}


// Append a (possibly truncated) representation of the type cls to the preallocated buffer ppBuf of length pnBufLen
// If fNamespace=TRUE, include the namespace/enclosing classes
// If fFullInst=TRUE (regardless of fNamespace and fAssembly), include namespace and assembly for any type parameters
// If fAssembly=TRUE, suffix with a comma and the full assembly qualification
// return size of representation
int interceptor_ICJI::appendClassName(
            __deref_inout_ecount(*pnBufLen) WCHAR** ppBuf,
            int* pnBufLen,
            CORINFO_CLASS_HANDLE    cls,
            BOOL fNamespace,
            BOOL fFullInst,
            BOOL fAssembly
            )
{
    return original_ICorJitInfo->appendClassName(ppBuf, pnBufLen, cls, fNamespace, fFullInst, fAssembly);
}

// Quick check whether the type is a value class. Returns the same value as getClassAttribs(cls) & CORINFO_FLG_VALUECLASS, except faster.
BOOL interceptor_ICJI::isValueClass(CORINFO_CLASS_HANDLE cls)
{
    return original_ICorJitInfo->isValueClass(cls);
}

// If this method returns true, JIT will do optimization to inline the check for
//     GetTypeFromHandle(handle) == obj.GetType()
BOOL interceptor_ICJI::canInlineTypeCheckWithObjectVTable(CORINFO_CLASS_HANDLE cls)
{
    return original_ICorJitInfo->canInlineTypeCheckWithObjectVTable(cls);
}

// return flags (defined above, CORINFO_FLG_PUBLIC ...)
DWORD interceptor_ICJI::getClassAttribs (
            CORINFO_CLASS_HANDLE    cls
            )
{
    return original_ICorJitInfo->getClassAttribs(cls);
}

// Returns "TRUE" iff "cls" is a struct type such that return buffers used for returning a value
// of this type must be stack-allocated.  This will generally be true only if the struct
// contains GC pointers, and does not exceed some size limit.  Maintaining this as an invariant allows
// an optimization: the JIT may assume that return buffer pointers for return types for which this predicate
// returns TRUE are always stack allocated, and thus, that stores to the GC-pointer fields of such return
// buffers do not require GC write barriers.
BOOL interceptor_ICJI::isStructRequiringStackAllocRetBuf(CORINFO_CLASS_HANDLE cls)
{
    return original_ICorJitInfo->isStructRequiringStackAllocRetBuf(cls);
}

CORINFO_MODULE_HANDLE interceptor_ICJI::getClassModule (
            CORINFO_CLASS_HANDLE    cls
            )
{
    return original_ICorJitInfo->getClassModule(cls);
}

// Returns the assembly that contains the module "mod".
CORINFO_ASSEMBLY_HANDLE interceptor_ICJI::getModuleAssembly (
            CORINFO_MODULE_HANDLE   mod
            )
{
    return original_ICorJitInfo->getModuleAssembly(mod);
}

// Returns the name of the assembly "assem".
const char* interceptor_ICJI::getAssemblyName (
            CORINFO_ASSEMBLY_HANDLE assem
            )
{
    return original_ICorJitInfo->getAssemblyName(assem);
}

// Allocate and delete process-lifetime objects.  Should only be
// referred to from static fields, lest a leak occur.
// Note that "LongLifetimeFree" does not execute destructors, if "obj"
// is an array of a struct type with a destructor.
void* interceptor_ICJI::LongLifetimeMalloc(size_t sz)
{
    return original_ICorJitInfo->LongLifetimeMalloc(sz);
}

void interceptor_ICJI::LongLifetimeFree(void* obj)
{
    original_ICorJitInfo->LongLifetimeFree(obj);
}

size_t interceptor_ICJI::getClassModuleIdForStatics (
        CORINFO_CLASS_HANDLE    cls,
        CORINFO_MODULE_HANDLE *pModule,
        void **ppIndirection
        )
{
    return original_ICorJitInfo->getClassModuleIdForStatics(cls, pModule, ppIndirection);
}

// return the number of bytes needed by an instance of the class
unsigned interceptor_ICJI::getClassSize (
            CORINFO_CLASS_HANDLE        cls
            )
{
    return original_ICorJitInfo->getClassSize(cls);
}

unsigned interceptor_ICJI::getClassAlignmentRequirement (
            CORINFO_CLASS_HANDLE        cls,
            BOOL                        fDoubleAlignHint
            )
{
    return original_ICorJitInfo->getClassAlignmentRequirement(cls, fDoubleAlignHint);
}

// This is only called for Value classes.  It returns a boolean array
// in representing of 'cls' from a GC perspective.  The class is
// assumed to be an array of machine words
// (of length // getClassSize(cls) / sizeof(void*)),
// 'gcPtrs' is a pointer to an array of BYTEs of this length.
// getClassGClayout fills in this array so that gcPtrs[i] is set
// to one of the CorInfoGCType values which is the GC type of
// the i-th machine word of an object of type 'cls'
// returns the number of GC pointers in the array
unsigned interceptor_ICJI::getClassGClayout (
            CORINFO_CLASS_HANDLE        cls,        /* IN */
            BYTE                       *gcPtrs      /* OUT */
            )
{
    return original_ICorJitInfo->getClassGClayout(cls, gcPtrs);
}

// returns the number of instance fields in a class
unsigned interceptor_ICJI::getClassNumInstanceFields (
            CORINFO_CLASS_HANDLE        cls        /* IN */
            )
{
    return original_ICorJitInfo->getClassNumInstanceFields(cls);
}

CORINFO_FIELD_HANDLE interceptor_ICJI::getFieldInClass(
            CORINFO_CLASS_HANDLE clsHnd,
            INT num
            )
{
    return original_ICorJitInfo->getFieldInClass(clsHnd, num);
}

BOOL interceptor_ICJI::checkMethodModifier(
            CORINFO_METHOD_HANDLE hMethod,
            LPCSTR modifier,
            BOOL fOptional
            )
{
    return original_ICorJitInfo->checkMethodModifier(hMethod, modifier, fOptional);
}

// returns the "NEW" helper optimized for "newCls."
CorInfoHelpFunc interceptor_ICJI::getNewHelper(
            CORINFO_RESOLVED_TOKEN * pResolvedToken,
            CORINFO_METHOD_HANDLE    callerHandle
            )
{
    return original_ICorJitInfo->getNewHelper(pResolvedToken, callerHandle);
}

// returns the newArr (1-Dim array) helper optimized for "arrayCls."
CorInfoHelpFunc interceptor_ICJI::getNewArrHelper(
            CORINFO_CLASS_HANDLE        arrayCls
            )
{
    return original_ICorJitInfo->getNewArrHelper(arrayCls);
}

// returns the optimized "IsInstanceOf" or "ChkCast" helper
CorInfoHelpFunc interceptor_ICJI::getCastingHelper(
            CORINFO_RESOLVED_TOKEN * pResolvedToken,
            bool fThrowing
            )
{
    return original_ICorJitInfo->getCastingHelper(pResolvedToken, fThrowing);
}

// returns helper to trigger static constructor
CorInfoHelpFunc interceptor_ICJI::getSharedCCtorHelper(
            CORINFO_CLASS_HANDLE clsHnd
            )
{
    return original_ICorJitInfo->getSharedCCtorHelper(clsHnd);
}

CorInfoHelpFunc interceptor_ICJI::getSecurityPrologHelper(
            CORINFO_METHOD_HANDLE   ftn
            )
{
    return original_ICorJitInfo->getSecurityPrologHelper(ftn);
}

// This is not pretty.  Boxing nullable<T> actually returns
// a boxed<T> not a boxed Nullable<T>.  This call allows the verifier
// to call back to the EE on the 'box' instruction and get the transformed
// type to use for verification.
CORINFO_CLASS_HANDLE  interceptor_ICJI::getTypeForBox(
            CORINFO_CLASS_HANDLE        cls
            )
{
    return original_ICorJitInfo->getTypeForBox(cls);
}

// returns the correct box helper for a particular class.  Note
// that if this returns CORINFO_HELP_BOX, the JIT can assume
// 'standard' boxing (allocate object and copy), and optimize
CorInfoHelpFunc interceptor_ICJI::getBoxHelper(
            CORINFO_CLASS_HANDLE        cls
            )
{
    return original_ICorJitInfo->getBoxHelper(cls);
}

// returns the unbox helper.  If 'helperCopies' points to a true
// value it means the JIT is requesting a helper that unboxes the
// value into a particular location and thus has the signature
//     void unboxHelper(void* dest, CORINFO_CLASS_HANDLE cls, Object* obj)
// Otherwise (it is null or points at a FALSE value) it is requesting
// a helper that returns a pointer to the unboxed data
//     void* unboxHelper(CORINFO_CLASS_HANDLE cls, Object* obj)
// The EE has the option of NOT returning the copy style helper
// (But must be able to always honor the non-copy style helper)
// The EE set 'helperCopies' on return to indicate what kind of
// helper has been created.

CorInfoHelpFunc interceptor_ICJI::getUnBoxHelper(
            CORINFO_CLASS_HANDLE        cls
            )
{
    return original_ICorJitInfo->getUnBoxHelper(cls);
}

bool interceptor_ICJI::getReadyToRunHelper(
            CORINFO_RESOLVED_TOKEN * pResolvedToken,
            CORINFO_LOOKUP_KIND *    pGenericLookupKind,
            CorInfoHelpFunc          id,
            CORINFO_CONST_LOOKUP *   pLookup
            )
{
    return original_ICorJitInfo->getReadyToRunHelper(pResolvedToken, pGenericLookupKind, id, pLookup);
}

void interceptor_ICJI::getReadyToRunDelegateCtorHelper(
    CORINFO_RESOLVED_TOKEN * pTargetMethod,
    CORINFO_CLASS_HANDLE     delegateType,
    CORINFO_LOOKUP *   pLookup
    )
{
    original_ICorJitInfo->getReadyToRunDelegateCtorHelper(pTargetMethod, delegateType, pLookup);
}

const char* interceptor_ICJI::getHelperName(
            CorInfoHelpFunc funcNum
            )
{
    return original_ICorJitInfo->getHelperName(funcNum);
}

// This function tries to initialize the class (run the class constructor).
// this function returns whether the JIT must insert helper calls before
// accessing static field or method.
//
// See code:ICorClassInfo#ClassConstruction.
CorInfoInitClassResult interceptor_ICJI::initClass(
            CORINFO_FIELD_HANDLE    field,          // Non-nullptr - inquire about cctor trigger before static field access
                                                    // nullptr - inquire about cctor trigger in method prolog
            CORINFO_METHOD_HANDLE   method,         // Method referencing the field or prolog
            CORINFO_CONTEXT_HANDLE  context,        // Exact context of method
            BOOL                    speculative     // TRUE means don't actually run it
            )
{
    return original_ICorJitInfo->initClass(field, method, context, speculative);
}

// This used to be called "loadClass".  This records the fact
// that the class must be loaded (including restored if necessary) before we execute the
// code that we are currently generating.  When jitting code
// the function loads the class immediately.  When zapping code
// the zapper will if necessary use the call to record the fact that we have
// to do a fixup/restore before running the method currently being generated.
//
// This is typically used to ensure value types are loaded before zapped
// code that manipulates them is executed, so that the GC can access information
// about those value types.
void interceptor_ICJI::classMustBeLoadedBeforeCodeIsRun(
            CORINFO_CLASS_HANDLE        cls
            )
{
    original_ICorJitInfo->classMustBeLoadedBeforeCodeIsRun(cls);
}

// returns the class handle for the special builtin classes
CORINFO_CLASS_HANDLE interceptor_ICJI::getBuiltinClass (
            CorInfoClassId              classId
            )
{
    return original_ICorJitInfo->getBuiltinClass(classId);
}

// "System.Int32" ==> CORINFO_TYPE_INT..
CorInfoType interceptor_ICJI::getTypeForPrimitiveValueClass(
            CORINFO_CLASS_HANDLE        cls
            )
{
    return original_ICorJitInfo->getTypeForPrimitiveValueClass(cls);
}

// TRUE if child is a subtype of parent
// if parent is an interface, then does child implement / extend parent
BOOL interceptor_ICJI::canCast(
            CORINFO_CLASS_HANDLE        child,  // subtype (extends parent)
            CORINFO_CLASS_HANDLE        parent  // base type
            )
{
    return original_ICorJitInfo->canCast(child, parent);
}

// TRUE if cls1 and cls2 are considered equivalent types.
BOOL interceptor_ICJI::areTypesEquivalent(
            CORINFO_CLASS_HANDLE        cls1,
            CORINFO_CLASS_HANDLE        cls2
            )
{
    return original_ICorJitInfo->areTypesEquivalent(cls1, cls2);
}

// returns is the intersection of cls1 and cls2.
CORINFO_CLASS_HANDLE interceptor_ICJI::mergeClasses(
            CORINFO_CLASS_HANDLE        cls1,
            CORINFO_CLASS_HANDLE        cls2
            )
{
    return original_ICorJitInfo->mergeClasses(cls1, cls2);
}

// Given a class handle, returns the Parent type.
// For COMObjectType, it returns Class Handle of System.Object.
// Returns 0 if System.Object is passed in.
CORINFO_CLASS_HANDLE interceptor_ICJI::getParentType (
            CORINFO_CLASS_HANDLE        cls
            )
{
    return original_ICorJitInfo->getParentType(cls);
}

// Returns the CorInfoType of the "child type". If the child type is
// not a primitive type, *clsRet will be set.
// Given an Array of Type Foo, returns Foo.
// Given BYREF Foo, returns Foo
CorInfoType interceptor_ICJI::getChildType (
            CORINFO_CLASS_HANDLE       clsHnd,
            CORINFO_CLASS_HANDLE       *clsRet
            )
{
    return original_ICorJitInfo->getChildType(clsHnd, clsRet);
}

// Check constraints on type arguments of this class and parent classes
BOOL interceptor_ICJI::satisfiesClassConstraints(
            CORINFO_CLASS_HANDLE cls
            )
{
    return original_ICorJitInfo->satisfiesClassConstraints(cls);
}

// Check if this is a single dimensional array type
BOOL interceptor_ICJI::isSDArray(
            CORINFO_CLASS_HANDLE        cls
            )
{
    return original_ICorJitInfo->isSDArray(cls);
}

// Get the numbmer of dimensions in an array
unsigned interceptor_ICJI::getArrayRank(
        CORINFO_CLASS_HANDLE        cls
        )
{
    return original_ICorJitInfo->getArrayRank(cls);
}

// Get static field data for an array
void * interceptor_ICJI::getArrayInitializationData(
        CORINFO_FIELD_HANDLE        field,
        DWORD                       size
        )
{
    return original_ICorJitInfo->getArrayInitializationData(field, size);
}

// Check Visibility rules.
CorInfoIsAccessAllowedResult interceptor_ICJI::canAccessClass(
                    CORINFO_RESOLVED_TOKEN * pResolvedToken,
                    CORINFO_METHOD_HANDLE   callerHandle,
                    CORINFO_HELPER_DESC    *pAccessHelper /* If canAccessMethod returns something other
                                                                than ALLOWED, then this is filled in. */
                    )
{
    return original_ICorJitInfo->canAccessClass(pResolvedToken, callerHandle, pAccessHelper);
}

/**********************************************************************************/
//
// ICorFieldInfo
//
/**********************************************************************************/

// this function is for debugging only.  It returns the field name
// and if 'moduleName' is non-null, it sets it to something that will
// says which method (a class name, or a module name)
const char* interceptor_ICJI::getFieldName (
                    CORINFO_FIELD_HANDLE        ftn,        /* IN */
                    const char                **moduleName  /* OUT */
                    )
{
    return original_ICorJitInfo->getFieldName(ftn, moduleName);
}

// return class it belongs to
CORINFO_CLASS_HANDLE interceptor_ICJI::getFieldClass (
                    CORINFO_FIELD_HANDLE    field
                    )
{
    return original_ICorJitInfo->getFieldClass(field);
}

// Return the field's type, if it is CORINFO_TYPE_VALUECLASS 'structType' is set
// the field's value class (if 'structType' == 0, then don't bother
// the structure info).
//
// 'memberParent' is typically only set when verifying.  It should be the
// result of calling getMemberParent.
CorInfoType interceptor_ICJI::getFieldType(
                        CORINFO_FIELD_HANDLE    field,
                        CORINFO_CLASS_HANDLE   *structType,
                        CORINFO_CLASS_HANDLE    memberParent/* IN */
                        )
{
    return original_ICorJitInfo->getFieldType(field, structType, memberParent);
}

// return the data member's instance offset
unsigned interceptor_ICJI::getFieldOffset(
                    CORINFO_FIELD_HANDLE    field
                    )
{
    return original_ICorJitInfo->getFieldOffset(field);
}

// TODO: jit64 should be switched to the same plan as the i386 jits - use
// getClassGClayout to figure out the need for writebarrier helper, and inline the copying.
// The interpretted value class copy is slow. Once this happens, USE_WRITE_BARRIER_HELPERS
bool interceptor_ICJI::isWriteBarrierHelperRequired(
                    CORINFO_FIELD_HANDLE    field)
{
    return original_ICorJitInfo->isWriteBarrierHelperRequired(field);
}

void interceptor_ICJI::getFieldInfo (CORINFO_RESOLVED_TOKEN * pResolvedToken,
                            CORINFO_METHOD_HANDLE  callerHandle,
                            CORINFO_ACCESS_FLAGS   flags,
                            CORINFO_FIELD_INFO    *pResult
                            )
{
    original_ICorJitInfo->getFieldInfo(pResolvedToken, callerHandle, flags, pResult);
}

// Returns true iff "fldHnd" represents a static field.
bool interceptor_ICJI::isFieldStatic(CORINFO_FIELD_HANDLE fldHnd)
{
    // this method does exist in some forms of the jit interface... if trip into one we'll know about it
    DebugBreakorAV(67);
    return true;
}

/*********************************************************************************/
//
// ICorDebugInfo
//
/*********************************************************************************/

// Query the EE to find out where interesting break points
// in the code are.  The native compiler will ensure that these places
// have a corresponding break point in native code.
//
// Note that unless CORJIT_FLAG_DEBUG_CODE is specified, this function will
// be used only as a hint and the native compiler should not change its
// code generation.
void interceptor_ICJI::getBoundaries(
            CORINFO_METHOD_HANDLE   ftn,                // [IN] method of interest
            unsigned int           *cILOffsets,         // [OUT] size of pILOffsets
            DWORD                 **pILOffsets,         // [OUT] IL offsets of interest
                                                        //       jit MUST free with freeArray!
            ICorDebugInfo::BoundaryTypes *implictBoundaries // [OUT] tell jit, all boundries of this type
            )
{
    original_ICorJitInfo->getBoundaries(ftn, cILOffsets, pILOffsets, implictBoundaries);
}

// Report back the mapping from IL to native code,
// this map should include all boundaries that 'getBoundaries'
// reported as interesting to the debugger.

// Note that debugger (and profiler) is assuming that all of the
// offsets form a contiguous block of memory, and that the
// OffsetMapping is sorted in order of increasing native offset.
void interceptor_ICJI::setBoundaries(
            CORINFO_METHOD_HANDLE   ftn,            // [IN] method of interest
            ULONG32                 cMap,           // [IN] size of pMap
            ICorDebugInfo::OffsetMapping *pMap      // [IN] map including all points of interest.
                                                    //      jit allocated with allocateArray, EE frees
            )
{
    original_ICorJitInfo->setBoundaries(ftn, cMap, pMap);
}

// Query the EE to find out the scope of local varables.
// normally the JIT would trash variables after last use, but
// under debugging, the JIT needs to keep them live over their
// entire scope so that they can be inspected.
//
// Note that unless CORJIT_FLAG_DEBUG_CODE is specified, this function will
// be used only as a hint and the native compiler should not change its
// code generation.
void interceptor_ICJI::getVars(
        CORINFO_METHOD_HANDLE           ftn,            // [IN]  method of interest
        ULONG32                        *cVars,          // [OUT] size of 'vars'
        ICorDebugInfo::ILVarInfo       **vars,          // [OUT] scopes of variables of interest
                                                        //       jit MUST free with freeArray!
        bool                           *extendOthers    // [OUT] it TRUE, then assume the scope
                                                        //       of unmentioned vars is entire method
        )
{
    original_ICorJitInfo->getVars(ftn, cVars, vars, extendOthers);
}

// Report back to the EE the location of every variable.
// note that the JIT might split lifetimes into different
// locations etc.

void interceptor_ICJI::setVars(
        CORINFO_METHOD_HANDLE           ftn,            // [IN] method of interest
        ULONG32                         cVars,          // [IN] size of 'vars'
        ICorDebugInfo::NativeVarInfo   *vars            // [IN] map telling where local vars are stored at what points
                                                        //      jit allocated with allocateArray, EE frees
        )
{
    original_ICorJitInfo->setVars(ftn, cVars, vars);
}

/*-------------------------- Misc ---------------------------------------*/

// Used to allocate memory that needs to handed to the EE.
// For eg, use this to allocated memory for reporting debug info,
// which will be handed to the EE by setVars() and setBoundaries()
void * interceptor_ICJI::allocateArray(
                    ULONG              cBytes
                    )
{
    return original_ICorJitInfo->allocateArray(cBytes);
}

// JitCompiler will free arrays passed by the EE using this
// For eg, The EE returns memory in getVars() and getBoundaries()
// to the JitCompiler, which the JitCompiler should release using
// freeArray()
void interceptor_ICJI::freeArray(
        void               *array
        )
{
    original_ICorJitInfo->freeArray(array);
}

/*********************************************************************************/
//
// ICorArgInfo
//
/*********************************************************************************/

// advance the pointer to the argument list.
// a ptr of 0, is special and always means the first argument
CORINFO_ARG_LIST_HANDLE interceptor_ICJI::getArgNext (
        CORINFO_ARG_LIST_HANDLE     args            /* IN */
        )
{
    return original_ICorJitInfo->getArgNext(args);
}

// Get the type of a particular argument
// CORINFO_TYPE_UNDEF is returned when there are no more arguments
// If the type returned is a primitive type (or an enum) *vcTypeRet set to nullptr
// otherwise it is set to the TypeHandle associted with the type
// Enumerations will always look their underlying type (probably should fix this)
// Otherwise vcTypeRet is the type as would be seen by the IL,
// The return value is the type that is used for calling convention purposes
// (Thus if the EE wants a value class to be passed like an int, then it will
// return CORINFO_TYPE_INT
CorInfoTypeWithMod interceptor_ICJI::getArgType (
        CORINFO_SIG_INFO*           sig,            /* IN */
        CORINFO_ARG_LIST_HANDLE     args,           /* IN */
        CORINFO_CLASS_HANDLE       *vcTypeRet       /* OUT */
        )
{
    return original_ICorJitInfo->getArgType(sig, args, vcTypeRet);
}

// If the Arg is a CORINFO_TYPE_CLASS fetch the class handle associated with it
CORINFO_CLASS_HANDLE interceptor_ICJI::getArgClass (
        CORINFO_SIG_INFO*           sig,            /* IN */
        CORINFO_ARG_LIST_HANDLE     args            /* IN */
        )
{
    return original_ICorJitInfo->getArgClass(sig, args);
}

// Returns type of HFA for valuetype
CorInfoType interceptor_ICJI::getHFAType (
        CORINFO_CLASS_HANDLE hClass
        )
{
    return original_ICorJitInfo->getHFAType(hClass);
}

/*****************************************************************************
* ICorErrorInfo contains methods to deal with SEH exceptions being thrown
* from the corinfo interface.  These methods may be called when an exception
* with code EXCEPTION_COMPLUS is caught.
*****************************************************************************/

// Returns the HRESULT of the current exception
HRESULT interceptor_ICJI::GetErrorHRESULT(
        struct _EXCEPTION_POINTERS *pExceptionPointers
        )
{
    return original_ICorJitInfo->GetErrorHRESULT(pExceptionPointers);
}

// Fetches the message of the current exception
// Returns the size of the message (including terminating null). This can be
// greater than bufferLength if the buffer is insufficient.
ULONG interceptor_ICJI::GetErrorMessage(
        __inout_ecount(bufferLength) LPWSTR buffer,
        ULONG bufferLength
        )
{
    return original_ICorJitInfo->GetErrorMessage(buffer, bufferLength);
}

// returns EXCEPTION_EXECUTE_HANDLER if it is OK for the compile to handle the
//                        exception, abort some work (like the inlining) and continue compilation
// returns EXCEPTION_CONTINUE_SEARCH if exception must always be handled by the EE
//                    things like ThreadStoppedException ...
// returns EXCEPTION_CONTINUE_EXECUTION if exception is fixed up by the EE

int interceptor_ICJI::FilterException(
        struct _EXCEPTION_POINTERS *pExceptionPointers
        )
{
    return original_ICorJitInfo->FilterException(pExceptionPointers);
}

// Cleans up internal EE tracking when an exception is caught.
void interceptor_ICJI::HandleException(
        struct _EXCEPTION_POINTERS *pExceptionPointers
        )
{
    original_ICorJitInfo->HandleException(pExceptionPointers);
}

void interceptor_ICJI::ThrowExceptionForJitResult(
        HRESULT result)
{
    original_ICorJitInfo->ThrowExceptionForJitResult(result);
}

//Throws an exception defined by the given throw helper.
void interceptor_ICJI::ThrowExceptionForHelper(
        const CORINFO_HELPER_DESC * throwHelper)
{
    original_ICorJitInfo->ThrowExceptionForHelper(throwHelper);
}

/*****************************************************************************
 * ICorStaticInfo contains EE interface methods which return values that are
 * constant from invocation to invocation.  Thus they may be embedded in
 * persisted information like statically generated code. (This is of course
 * assuming that all code versions are identical each time.)
 *****************************************************************************/

// Return details about EE internal data structures
void interceptor_ICJI::getEEInfo(
            CORINFO_EE_INFO            *pEEInfoOut
            )
{
    original_ICorJitInfo->getEEInfo(pEEInfoOut);
}

// Returns name of the JIT timer log
LPCWSTR interceptor_ICJI::getJitTimeLogFilename()
{
  return original_ICorJitInfo->getJitTimeLogFilename();
}


    /*********************************************************************************/
    //
    // Diagnostic methods
    //
    /*********************************************************************************/

// this function is for debugging only. Returns method token.
// Returns mdMethodDefNil for dynamic methods.
mdMethodDef interceptor_ICJI::getMethodDefFromMethod(
        CORINFO_METHOD_HANDLE hMethod
        )
{
    return original_ICorJitInfo->getMethodDefFromMethod(hMethod);
}

// this function is for debugging only.  It returns the method name
// and if 'moduleName' is non-null, it sets it to something that will
// says which method (a class name, or a module name)
const char* interceptor_ICJI::getMethodName (
        CORINFO_METHOD_HANDLE       ftn,        /* IN */
        const char                **moduleName  /* OUT */
        )
{
    return original_ICorJitInfo->getMethodName(ftn, moduleName);
}

// this function is for debugging only.  It returns a value that
// is will always be the same for a given method.  It is used
// to implement the 'jitRange' functionality
unsigned interceptor_ICJI::getMethodHash (
        CORINFO_METHOD_HANDLE       ftn         /* IN */
        )
{
    return original_ICorJitInfo->getMethodHash(ftn);
}

// this function is for debugging only.
size_t interceptor_ICJI::findNameOfToken (
        CORINFO_MODULE_HANDLE       module,     /* IN  */
        mdToken                     metaTOK,     /* IN  */
        __out_ecount (FQNameCapacity) char * szFQName, /* OUT */
        size_t FQNameCapacity  /* IN */
        )
{
    return original_ICorJitInfo->findNameOfToken(module, metaTOK, szFQName, FQNameCapacity);
}

bool interceptor_ICJI::getSystemVAmd64PassStructInRegisterDescriptor(
        /* IN */    CORINFO_CLASS_HANDLE        structHnd,
        /* OUT */   SYSTEMV_AMD64_CORINFO_STRUCT_REG_PASSING_DESCRIPTOR* structPassInRegDescPtr
        )
{
    return original_ICorJitInfo->getSystemVAmd64PassStructInRegisterDescriptor(structHnd, structPassInRegDescPtr);
}

//Stuff on ICorDynamicInfo
DWORD interceptor_ICJI::getThreadTLSIndex(
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getThreadTLSIndex(ppIndirection);
}

const void * interceptor_ICJI::getInlinedCallFrameVptr(
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getInlinedCallFrameVptr(ppIndirection);
}

LONG * interceptor_ICJI::getAddrOfCaptureThreadGlobal(
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getAddrOfCaptureThreadGlobal(ppIndirection);
}

SIZE_T*       interceptor_ICJI::getAddrModuleDomainID(CORINFO_MODULE_HANDLE   module)
{
    return original_ICorJitInfo->getAddrModuleDomainID(module);
}

// return the native entry point to an EE helper (see CorInfoHelpFunc)
void* interceptor_ICJI::getHelperFtn (
                CorInfoHelpFunc         ftnNum,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getHelperFtn(ftnNum, ppIndirection);
}

// return a callable address of the function (native code). This function
// may return a different value (depending on whether the method has
// been JITed or not.
void interceptor_ICJI::getFunctionEntryPoint(
                            CORINFO_METHOD_HANDLE   ftn,                 /* IN  */
                            CORINFO_CONST_LOOKUP *  pResult,             /* OUT */
                            CORINFO_ACCESS_FLAGS    accessFlags)
{
    original_ICorJitInfo->getFunctionEntryPoint(ftn, pResult, accessFlags);
}

// return a directly callable address. This can be used similarly to the
// value returned by getFunctionEntryPoint() except that it is
// guaranteed to be multi callable entrypoint.
void interceptor_ICJI::getFunctionFixedEntryPoint(
                            CORINFO_METHOD_HANDLE   ftn,
                            CORINFO_CONST_LOOKUP *  pResult)
{
    original_ICorJitInfo->getFunctionFixedEntryPoint(ftn, pResult);
}

// get the synchronization handle that is passed to monXstatic function
void* interceptor_ICJI::getMethodSync(
                CORINFO_METHOD_HANDLE               ftn,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getMethodSync(ftn, ppIndirection);
}

// These entry points must be called if a handle is being embedded in
// the code to be passed to a JIT helper function. (as opposed to just
// being passed back into the ICorInfo interface.)

// get slow lazy string literal helper to use (CORINFO_HELP_STRCNS*).
// Returns CORINFO_HELP_UNDEF if lazy string literal helper cannot be used.
CorInfoHelpFunc interceptor_ICJI::getLazyStringLiteralHelper(
    CORINFO_MODULE_HANDLE   handle
    )
{
    return original_ICorJitInfo->getLazyStringLiteralHelper(handle);
}

CORINFO_MODULE_HANDLE interceptor_ICJI::embedModuleHandle(
                CORINFO_MODULE_HANDLE   handle,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->embedModuleHandle(handle, ppIndirection);
}

CORINFO_CLASS_HANDLE interceptor_ICJI::embedClassHandle(
                CORINFO_CLASS_HANDLE    handle,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->embedClassHandle(handle, ppIndirection);
}

CORINFO_METHOD_HANDLE interceptor_ICJI::embedMethodHandle(
                CORINFO_METHOD_HANDLE   handle,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->embedMethodHandle(handle, ppIndirection);
}

CORINFO_FIELD_HANDLE interceptor_ICJI::embedFieldHandle(
                CORINFO_FIELD_HANDLE    handle,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->embedFieldHandle(handle, ppIndirection);
}

// Given a module scope (module), a method handle (context) and
// a metadata token (metaTOK), fetch the handle
// (type, field or method) associated with the token.
// If this is not possible at compile-time (because the current method's
// code is shared and the token contains generic parameters)
// then indicate how the handle should be looked up at run-time.
//
void interceptor_ICJI::embedGenericHandle(
                    CORINFO_RESOLVED_TOKEN *        pResolvedToken,
                    BOOL                            fEmbedParent, // TRUE - embeds parent type handle of the field/method handle
                    CORINFO_GENERICHANDLE_RESULT *  pResult)
{
    original_ICorJitInfo->embedGenericHandle(pResolvedToken, fEmbedParent, pResult);
}

// Return information used to locate the exact enclosing type of the current method.
// Used only to invoke .cctor method from code shared across generic instantiations
//   !needsRuntimeLookup       statically known (enclosing type of method itself)
//   needsRuntimeLookup:
//      CORINFO_LOOKUP_THISOBJ     use vtable pointer of 'this' param
//      CORINFO_LOOKUP_CLASSPARAM  use vtable hidden param
//      CORINFO_LOOKUP_METHODPARAM use enclosing type of method-desc hidden param
CORINFO_LOOKUP_KIND interceptor_ICJI::getLocationOfThisType(
                CORINFO_METHOD_HANDLE context
                )
{
    return original_ICorJitInfo->getLocationOfThisType(context);
}

// return the unmanaged target *if method has already been prelinked.*
void* interceptor_ICJI::getPInvokeUnmanagedTarget(
                CORINFO_METHOD_HANDLE   method,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getPInvokeUnmanagedTarget(method, ppIndirection);
}

// return address of fixup area for late-bound PInvoke calls.
void* interceptor_ICJI::getAddressOfPInvokeFixup(
                CORINFO_METHOD_HANDLE   method,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getAddressOfPInvokeFixup(method, ppIndirection);
}

// return address of fixup area for late-bound PInvoke calls.
void interceptor_ICJI::getAddressOfPInvokeTarget(
                CORINFO_METHOD_HANDLE   method,
                CORINFO_CONST_LOOKUP   *pLookup
                )
{
    original_ICorJitInfo->getAddressOfPInvokeTarget(method, pLookup);
}

// Generate a cookie based on the signature that would needs to be passed
// to CORINFO_HELP_PINVOKE_CALLI
LPVOID interceptor_ICJI::GetCookieForPInvokeCalliSig(
        CORINFO_SIG_INFO* szMetaSig,
        void           ** ppIndirection
        )
{
    return original_ICorJitInfo->GetCookieForPInvokeCalliSig(szMetaSig, ppIndirection);
}

// returns true if a VM cookie can be generated for it (might be false due to cross-module
// inlining, in which case the inlining should be aborted)
bool interceptor_ICJI::canGetCookieForPInvokeCalliSig(
                CORINFO_SIG_INFO* szMetaSig
                )
{
    return original_ICorJitInfo->canGetCookieForPInvokeCalliSig(szMetaSig);
}

// Gets a handle that is checked to see if the current method is
// included in "JustMyCode"
CORINFO_JUST_MY_CODE_HANDLE interceptor_ICJI::getJustMyCodeHandle(
                CORINFO_METHOD_HANDLE       method,
                CORINFO_JUST_MY_CODE_HANDLE**ppIndirection
                )
{
    return original_ICorJitInfo->getJustMyCodeHandle(method, ppIndirection);
}

// Gets a method handle that can be used to correlate profiling data.
// This is the IP of a native method, or the address of the descriptor struct
// for IL.  Always guaranteed to be unique per process, and not to move. */
void interceptor_ICJI::GetProfilingHandle(
                    BOOL                      *pbHookFunction,
                    void                     **pProfilerHandle,
                    BOOL                      *pbIndirectedHandles
                    )
{
    original_ICorJitInfo->GetProfilingHandle(pbHookFunction, pProfilerHandle, pbIndirectedHandles);
}

// Returns instructions on how to make the call. See code:CORINFO_CALL_INFO for possible return values.
void interceptor_ICJI::getCallInfo(
                    // Token info
                    CORINFO_RESOLVED_TOKEN * pResolvedToken,

                    //Generics info
                    CORINFO_RESOLVED_TOKEN * pConstrainedResolvedToken,

                    //Security info
                    CORINFO_METHOD_HANDLE   callerHandle,

                    //Jit info
                    CORINFO_CALLINFO_FLAGS  flags,

                    //out params
                    CORINFO_CALL_INFO       *pResult
                    )
{
    original_ICorJitInfo->getCallInfo(pResolvedToken, pConstrainedResolvedToken, callerHandle, flags, pResult);
}

BOOL interceptor_ICJI::canAccessFamily(CORINFO_METHOD_HANDLE hCaller,
                                        CORINFO_CLASS_HANDLE hInstanceType)

{
    return original_ICorJitInfo->canAccessFamily(hCaller, hInstanceType);
}
// Returns TRUE if the Class Domain ID is the RID of the class (currently true for every class
// except reflection emitted classes and generics)
BOOL interceptor_ICJI::isRIDClassDomainID(CORINFO_CLASS_HANDLE cls)
{
    return original_ICorJitInfo->isRIDClassDomainID(cls);
}

// returns the class's domain ID for accessing shared statics
unsigned interceptor_ICJI::getClassDomainID (
                CORINFO_CLASS_HANDLE    cls,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getClassDomainID(cls, ppIndirection);
}


// return the data's address (for static fields only)
void* interceptor_ICJI::getFieldAddress(
                CORINFO_FIELD_HANDLE    field,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getFieldAddress(field, ppIndirection);
}

// registers a vararg sig & returns a VM cookie for it (which can contain other stuff)
CORINFO_VARARGS_HANDLE interceptor_ICJI::getVarArgsHandle(
                CORINFO_SIG_INFO       *pSig,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getVarArgsHandle(pSig, ppIndirection);
}

// returns true if a VM cookie can be generated for it (might be false due to cross-module
// inlining, in which case the inlining should be aborted)
bool interceptor_ICJI::canGetVarArgsHandle(
                CORINFO_SIG_INFO       *pSig
                )
{
    return original_ICorJitInfo->canGetVarArgsHandle(pSig);
}

// Allocate a string literal on the heap and return a handle to it
InfoAccessType interceptor_ICJI::constructStringLiteral(
                CORINFO_MODULE_HANDLE   module,
                mdToken                 metaTok,
                void                  **ppValue
                )
{
    return original_ICorJitInfo->constructStringLiteral(module, metaTok, ppValue);
}

InfoAccessType interceptor_ICJI::emptyStringLiteral(
                void                  **ppValue
                )
{
    return original_ICorJitInfo->emptyStringLiteral(ppValue);
}

// (static fields only) given that 'field' refers to thread local store,
// return the ID (TLS index), which is used to find the begining of the
// TLS data area for the particular DLL 'field' is associated with.
DWORD interceptor_ICJI::getFieldThreadLocalStoreID (
                CORINFO_FIELD_HANDLE    field,
                void                  **ppIndirection
                )
{
    return original_ICorJitInfo->getFieldThreadLocalStoreID(field, ppIndirection);
}

// Sets another object to intercept calls to "self" and current method being compiled
void interceptor_ICJI::setOverride(
            ICorDynamicInfo             *pOverride,
            CORINFO_METHOD_HANDLE       currentMethod
            )
{
    original_ICorJitInfo->setOverride(pOverride, currentMethod);
}

// Adds an active dependency from the context method's module to the given module
// This is internal callback for the EE. JIT should not call it directly.
void interceptor_ICJI::addActiveDependency(
            CORINFO_MODULE_HANDLE       moduleFrom,
            CORINFO_MODULE_HANDLE       moduleTo
            )
{
    original_ICorJitInfo->addActiveDependency(moduleFrom, moduleTo);
}

CORINFO_METHOD_HANDLE interceptor_ICJI::GetDelegateCtor(
        CORINFO_METHOD_HANDLE  methHnd,
        CORINFO_CLASS_HANDLE   clsHnd,
        CORINFO_METHOD_HANDLE  targetMethodHnd,
        DelegateCtorArgs *     pCtorData
        )
{
    return original_ICorJitInfo->GetDelegateCtor(methHnd, clsHnd, targetMethodHnd, pCtorData);
}

void interceptor_ICJI::MethodCompileComplete(
            CORINFO_METHOD_HANDLE methHnd
            )
{
    original_ICorJitInfo->MethodCompileComplete(methHnd);
}

// return a thunk that will copy the arguments for the given signature.
void* interceptor_ICJI::getTailCallCopyArgsThunk (
                CORINFO_SIG_INFO       *pSig,
                CorInfoHelperTailCallSpecialHandling flags
                )
{
    return original_ICorJitInfo->getTailCallCopyArgsThunk(pSig, flags);
}

//Stuff directly on ICorJitInfo

// Returns extended flags for a particular compilation instance.
DWORD interceptor_ICJI::getJitFlags(CORJIT_FLAGS* jitFlags, DWORD sizeInBytes)
{
    return original_ICorJitInfo->getJitFlags(jitFlags, sizeInBytes);
}

// Runs the given function with the given parameter under an error trap
// and returns true if the function completes successfully.
bool interceptor_ICJI::runWithErrorTrap(void (*function)(void*), void *param)
{
    return original_ICorJitInfo->runWithErrorTrap(function, param);
}

// return memory manager that the JIT can use to allocate a regular memory
IEEMemoryManager* interceptor_ICJI::getMemoryManager()
{
    if(current_IEEMM->original_IEEMM == nullptr)
        current_IEEMM->original_IEEMM = original_ICorJitInfo->getMemoryManager();

    return current_IEEMM;
}

// get a block of memory for the code, readonly data, and read-write data
void interceptor_ICJI::allocMem (
        ULONG               hotCodeSize,    /* IN */
        ULONG               coldCodeSize,   /* IN */
        ULONG               roDataSize,     /* IN */
        ULONG               xcptnsCount,    /* IN */
        CorJitAllocMemFlag  flag,           /* IN */
        void **             hotCodeBlock,   /* OUT */
        void **             coldCodeBlock,  /* OUT */
        void **             roDataBlock     /* OUT */
        )
{
    return original_ICorJitInfo->allocMem(hotCodeSize, coldCodeSize, roDataSize, xcptnsCount, flag, hotCodeBlock, coldCodeBlock, roDataBlock);
}

// Reserve memory for the method/funclet's unwind information.
// Note that this must be called before allocMem. It should be
// called once for the main method, once for every funclet, and
// once for every block of cold code for which allocUnwindInfo
// will be called.
//
// This is necessary because jitted code must allocate all the
// memory needed for the unwindInfo at the allocMem call.
// For prejitted code we split up the unwinding information into
// separate sections .rdata and .pdata.
//
void interceptor_ICJI::reserveUnwindInfo (
        BOOL                isFunclet,             /* IN */
        BOOL                isColdCode,            /* IN */
        ULONG               unwindSize             /* IN */
        )
{
    original_ICorJitInfo->reserveUnwindInfo(isFunclet, isColdCode, unwindSize);
}

// Allocate and initialize the .rdata and .pdata for this method or
// funclet, and get the block of memory needed for the machine-specific
// unwind information (the info for crawling the stack frame).
// Note that allocMem must be called first.
//
// Parameters:
//
//    pHotCode        main method code buffer, always filled in
//    pColdCode       cold code buffer, only filled in if this is cold code,
//                      null otherwise
//    startOffset     start of code block, relative to appropriate code buffer
//                      (e.g. pColdCode if cold, pHotCode if hot).
//    endOffset       end of code block, relative to appropriate code buffer
//    unwindSize      size of unwind info pointed to by pUnwindBlock
//    pUnwindBlock    pointer to unwind info
//    funcKind        type of funclet (main method code, handler, filter)
//
void interceptor_ICJI::allocUnwindInfo (
        BYTE *              pHotCode,              /* IN */
        BYTE *              pColdCode,             /* IN */
        ULONG               startOffset,           /* IN */
        ULONG               endOffset,             /* IN */
        ULONG               unwindSize,            /* IN */
        BYTE *              pUnwindBlock,          /* IN */
        CorJitFuncKind      funcKind               /* IN */
        )
{
    original_ICorJitInfo->allocUnwindInfo(pHotCode, pColdCode, startOffset, endOffset, unwindSize, pUnwindBlock, funcKind);
}

// Get a block of memory needed for the code manager information,
// (the info for enumerating the GC pointers while crawling the
// stack frame).
// Note that allocMem must be called first
void * interceptor_ICJI::allocGCInfo (
        size_t                  size        /* IN */
        )
{
    return original_ICorJitInfo->allocGCInfo(size);
}

// only used on x64
void interceptor_ICJI::yieldExecution()
{
    original_ICorJitInfo->yieldExecution();
}

// Indicate how many exception handler blocks are to be returned.
// This is guaranteed to be called before any 'setEHinfo' call.
// Note that allocMem must be called before this method can be called.
void interceptor_ICJI::setEHcount (
        unsigned                cEH          /* IN */
        )
{
    original_ICorJitInfo->setEHcount(cEH);
}

// Set the values for one particular exception handler block.
//
// Handler regions should be lexically contiguous.
// This is because FinallyIsUnwinding() uses lexicality to
// determine if a "finally" clause is executing.
void interceptor_ICJI::setEHinfo (
        unsigned                 EHnumber,   /* IN  */
        const CORINFO_EH_CLAUSE *clause      /* IN */
        )
{
    original_ICorJitInfo->setEHinfo(EHnumber, clause);
}

// Level 1 -> fatalError, Level 2 -> Error, Level 3 -> Warning
// Level 4 means happens 10 times in a run, level 5 means 100, level 6 means 1000 ...
// returns non-zero if the logging succeeded
BOOL interceptor_ICJI::logMsg(unsigned level, const char* fmt, va_list args)
{
    return original_ICorJitInfo->logMsg(level, fmt, args);
}

// do an assert.  will return true if the code should retry (DebugBreak)
// returns false, if the assert should be igored.
int interceptor_ICJI::doAssert(const char* szFile, int iLine, const char* szExpr)
{
    return original_ICorJitInfo->doAssert(szFile, iLine, szExpr);
}

void interceptor_ICJI::reportFatalError(CorJitResult result)
{
    original_ICorJitInfo->reportFatalError(result);
}

// allocate a basic block profile buffer where execution counts will be stored
// for jitted basic blocks.
HRESULT interceptor_ICJI::allocBBProfileBuffer (
        ULONG                 count,           // The number of basic blocks that we have
        ProfileBuffer **      profileBuffer
        )
{
    return original_ICorJitInfo->allocBBProfileBuffer(count, profileBuffer);
}

// get profile information to be used for optimizing the current method.  The format
// of the buffer is the same as the format the JIT passes to allocBBProfileBuffer.
HRESULT interceptor_ICJI::getBBProfileData(
        CORINFO_METHOD_HANDLE ftnHnd,
        ULONG *               count,           // The number of basic blocks that we have
        ProfileBuffer **      profileBuffer,
        ULONG *               numRuns
        )
{
    return original_ICorJitInfo->getBBProfileData(ftnHnd, count, profileBuffer, numRuns);
}

// Associates a native call site, identified by its offset in the native code stream, with
// the signature information and method handle the JIT used to lay out the call site. If
// the call site has no signature information (e.g. a helper call) or has no method handle
// (e.g. a CALLI P/Invoke), then null should be passed instead.
void interceptor_ICJI::recordCallSite(
        ULONG                 instrOffset,  /* IN */
        CORINFO_SIG_INFO *    callSig,      /* IN */
        CORINFO_METHOD_HANDLE methodHandle  /* IN */
        )
{
    original_ICorJitInfo->recordCallSite(instrOffset, callSig, methodHandle);
}

// A relocation is recorded if we are pre-jitting.
// A jump thunk may be inserted if we are jitting
void interceptor_ICJI::recordRelocation(
        void *                 location,   /* IN  */
        void *                 target,     /* IN  */
        WORD                   fRelocType, /* IN  */
        WORD                   slotNum,  /* IN  */
        INT32                  addlDelta /* IN  */
        )
{
    original_ICorJitInfo->recordRelocation(location, target, fRelocType, slotNum, addlDelta);
}

WORD interceptor_ICJI::getRelocTypeHint(void * target)
{
    return original_ICorJitInfo->getRelocTypeHint(target);
}

// A callback to identify the range of address known to point to
// compiler-generated native entry points that call back into
// MSIL.
void interceptor_ICJI::getModuleNativeEntryPointRange(
        void ** pStart, /* OUT */
        void ** pEnd    /* OUT */
        )
{
    original_ICorJitInfo->getModuleNativeEntryPointRange(pStart, pEnd);
}

// For what machine does the VM expect the JIT to generate code? The VM
// returns one of the IMAGE_FILE_MACHINE_* values. Note that if the VM
// is cross-compiling (such as the case for crossgen), it will return a
// different value than if it was compiling for the host architecture.
//
DWORD interceptor_ICJI::getExpectedTargetArchitecture()
{
    return original_ICorJitInfo->getExpectedTargetArchitecture();
}