1 // Licensed to the .NET Foundation under one or more agreements.
2 // The .NET Foundation licenses this file to you under the MIT license.
3 // See the LICENSE file in the project root for more information.
5 /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
6 XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
10 XX This is the node in the semantic tree graph. It represents the operation XX
11 XX corresponding to the node, and other information during code-gen. XX
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14 XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
17 /*****************************************************************************/
20 /*****************************************************************************/
22 #include "vartype.h" // For "var_types"
23 #include "target.h" // For "regNumber"
24 #include "ssaconfig.h" // For "SsaConfig::RESERVED_SSA_NUM"
26 #include "valuenumtype.h"
27 #include "simplerhash.h"
31 // Debugging GenTree is much easier if we add a magic virtual function to make the debugger able to figure out what type it's got.
32 // This is enabled by default in DEBUG. To enable it in RET builds (temporarily!), you need to change the build to define DEBUGGABLE_GENTREE=1,
33 // as well as pass /OPT:NOICF to the linker (or else all the vtables get merged, making the debugging value supplied by them useless).
34 // See protojit.nativeproj for a commented example of setting the build flags correctly.
35 #ifndef DEBUGGABLE_GENTREE
37 #define DEBUGGABLE_GENTREE 1
39 #define DEBUGGABLE_GENTREE 0
41 #endif // !DEBUGGABLE_GENTREE
43 // The SpecialCodeKind enum is used to indicate the type of special (unique)
44 // target block that will be targeted by an instruction.
46 // GenTreeBoundsChk nodes (SCK_RNGCHK_FAIL, SCK_ARG_EXCPN, SCK_ARG_RNG_EXCPN)
47 // - these nodes have a field (gtThrowKind) to indicate which kind
48 // GenTreeOps nodes, for which codegen will generate the branch
49 // - it will use the appropriate kind based on the opcode, though it's not
50 // clear why SCK_OVERFLOW == SCK_ARITH_EXCPN
51 // SCK_PAUSE_EXEC is not currently used.
56 SCK_RNGCHK_FAIL, // target when range check fails
57 SCK_PAUSE_EXEC, // target to stop (e.g. to allow GC)
58 SCK_DIV_BY_ZERO, // target for divide by zero (Not used on X86/X64)
59 SCK_ARITH_EXCPN, // target on arithmetic exception
60 SCK_OVERFLOW = SCK_ARITH_EXCPN, // target on overflow
61 SCK_ARG_EXCPN, // target on ArgumentException (currently used only for SIMD intrinsics)
62 SCK_ARG_RNG_EXCPN, // target on ArgumentOutOfRangeException (currently used only for SIMD intrinsics)
66 /*****************************************************************************/
68 DECLARE_TYPED_ENUM(genTreeOps,BYTE)
70 #define GTNODE(en,sn,cm,ok) GT_ ## en,
75 // GT_CNS_NATIVELONG is the gtOper symbol for GT_CNS_LNG or GT_CNS_INT, depending on the target.
76 // For the 64-bit targets we will only use GT_CNS_INT as it used to represent all the possible sizes
77 // For the 32-bit targets we use a GT_CNS_LNG to hold a 64-bit integer constant and GT_CNS_INT for all others.
78 // In the future when we retarget the JIT for x86 we should consider eliminating GT_CNS_LNG
81 GT_CNS_NATIVELONG = GT_CNS_INT,
83 GT_CNS_NATIVELONG = GT_CNS_LNG,
86 END_DECLARE_TYPED_ENUM(genTreeOps,BYTE)
88 /*****************************************************************************
90 * The following enum defines a set of bit flags that can be used
91 * to classify expression tree nodes. Note that some operators will
92 * have more than one bit set, as follows:
94 * GTK_CONST implies GTK_LEAF
95 * GTK_RELOP implies GTK_BINOP
96 * GTK_LOGOP implies GTK_BINOP
101 GTK_SPECIAL = 0x0000, // unclassified operator (special handling reqd)
103 GTK_CONST = 0x0001, // constant operator
104 GTK_LEAF = 0x0002, // leaf operator
105 GTK_UNOP = 0x0004, // unary operator
106 GTK_BINOP = 0x0008, // binary operator
107 GTK_RELOP = 0x0010, // comparison operator
108 GTK_LOGOP = 0x0020, // logical operator
109 GTK_ASGOP = 0x0040, // assignment operator
111 GTK_KINDMASK= 0x007F, // operator kind mask
113 GTK_COMMUTE = 0x0080, // commutative operator
115 GTK_EXOP = 0x0100, // Indicates that an oper for a node type that extends GenTreeOp (or GenTreeUnOp)
116 // by adding non-node fields to unary or binary operator.
118 GTK_LOCAL = 0x0200, // is a local access (load, store, phi)
120 /* Define composite value(s) */
122 GTK_SMPOP = (GTK_UNOP|GTK_BINOP|GTK_RELOP|GTK_LOGOP)
125 /*****************************************************************************/
127 #define SMALL_TREE_NODES 1
129 /*****************************************************************************/
131 DECLARE_TYPED_ENUM(gtCallTypes,BYTE)
133 CT_USER_FUNC, // User function
134 CT_HELPER, // Jit-helper
135 CT_INDIRECT, // Indirect call
137 CT_COUNT // fake entry (must be last)
139 END_DECLARE_TYPED_ENUM(gtCallTypes,BYTE)
142 /*****************************************************************************/
146 struct InlineCandidateInfo;
148 /*****************************************************************************/
150 // GT_FIELD nodes will be lowered into more "code-gen-able" representations, like
151 // GT_IND's of addresses, or GT_LCL_FLD nodes. We'd like to preserve the more abstract
152 // information, and will therefore annotate such lowered nodes with FieldSeq's. A FieldSeq
153 // represents a (possibly) empty sequence of fields. The fields are in the order
154 // in which they are dereferenced. The first field may be an object field or a struct field;
155 // all subsequent fields must be struct fields.
158 CORINFO_FIELD_HANDLE m_fieldHnd;
159 FieldSeqNode* m_next;
161 FieldSeqNode(CORINFO_FIELD_HANDLE fieldHnd, FieldSeqNode* next) : m_fieldHnd(fieldHnd), m_next(next) {}
163 // returns true when this is the pseudo #FirstElem field sequence
164 bool IsFirstElemFieldSeq();
166 // returns true when this is the pseudo #ConstantIndex field sequence
167 bool IsConstantIndexFieldSeq();
169 // returns true when this is the the pseudo #FirstElem field sequence or the pseudo #ConstantIndex field sequence
170 bool IsPseudoField();
172 // Make sure this provides methods that allow it to be used as a KeyFuncs type in SimplerHash.
173 static int GetHashCode(FieldSeqNode fsn)
175 return static_cast<int>(reinterpret_cast<intptr_t>(fsn.m_fieldHnd)) ^ static_cast<int>(reinterpret_cast<intptr_t>(fsn.m_next));
178 static bool Equals(FieldSeqNode fsn1, FieldSeqNode fsn2)
180 return fsn1.m_fieldHnd == fsn2.m_fieldHnd && fsn1.m_next == fsn2.m_next;
184 // This class canonicalizes field sequences.
187 typedef SimplerHashTable<FieldSeqNode, /*KeyFuncs*/FieldSeqNode, FieldSeqNode*, JitSimplerHashBehavior> FieldSeqNodeCanonMap;
190 FieldSeqNodeCanonMap* m_canonMap;
192 static FieldSeqNode s_notAField; // No value, just exists to provide an address.
194 // Dummy variables to provide the addresses for the "pseudo field handle" statics below.
195 static int FirstElemPseudoFieldStruct;
196 static int ConstantIndexPseudoFieldStruct;
199 FieldSeqStore(IAllocator* alloc);
201 // Returns the (canonical in the store) singleton field sequence for the given handle.
202 FieldSeqNode* CreateSingleton(CORINFO_FIELD_HANDLE fieldHnd);
204 // This is a special distinguished FieldSeqNode indicating that a constant does *not*
205 // represent a valid field sequence. This is "infectious", in the sense that appending it
206 // (on either side) to any field sequence yields the "NotAField()" sequence.
207 static FieldSeqNode* NotAField() { return &s_notAField; }
209 // Returns the (canonical in the store) field sequence representing the concatenation of
210 // the sequences represented by "a" and "b". Assumes that "a" and "b" are canonical; that is,
211 // they are the results of CreateSingleton, NotAField, or Append calls. If either of the arguments
212 // are the "NotAField" value, so is the result.
213 FieldSeqNode* Append(FieldSeqNode* a, FieldSeqNode* b);
215 // We have a few "pseudo" field handles:
217 // This treats the constant offset of the first element of something as if it were a field.
218 // Works for method table offsets of boxed structs, or first elem offset of arrays/strings.
219 static CORINFO_FIELD_HANDLE FirstElemPseudoField;
221 // If there is a constant index, we make a psuedo field to correspond to the constant added to
222 // offset of the indexed field. This keeps the field sequence structure "normalized", especially in the
223 // case where the element type is a struct, so we might add a further struct field offset.
224 static CORINFO_FIELD_HANDLE ConstantIndexPseudoField;
226 static bool IsPseudoField(CORINFO_FIELD_HANDLE hnd)
228 return hnd == FirstElemPseudoField || hnd == ConstantIndexPseudoField;
234 /*****************************************************************************/
236 typedef struct GenTree * GenTreePtr;
237 struct GenTreeArgList;
239 // Forward declarations of the subtypes
240 #define GTSTRUCT_0(fn, en) struct GenTree##fn;
241 #define GTSTRUCT_1(fn, en) struct GenTree##fn;
242 #define GTSTRUCT_2(fn, en, en2) struct GenTree##fn;
243 #define GTSTRUCT_3(fn, en, en2, en3) struct GenTree##fn;
244 #define GTSTRUCT_4(fn, en, en2, en3, en4) struct GenTree##fn;
245 #define GTSTRUCT_N(fn, ...) struct GenTree##fn;
246 #include "gtstructs.h"
248 /*****************************************************************************/
251 #include <pshpack4.h>
256 // We use GT_STRUCT_0 only for the category of simple ops.
257 #define GTSTRUCT_0(fn, en) GenTree##fn* As##fn() \
259 assert(this->OperIsSimple()); \
260 return reinterpret_cast<GenTree##fn*>(this); \
262 GenTree##fn& As##fn##Ref() { return *As##fn(); } \
263 __declspec(property(get=As##fn##Ref)) GenTree##fn& gt##fn;
264 #define GTSTRUCT_1(fn, en) GenTree##fn* As##fn() \
266 assert(this->gtOper == en); \
267 return reinterpret_cast<GenTree##fn*>(this); \
269 GenTree##fn& As##fn##Ref() { return *As##fn(); } \
270 __declspec(property(get=As##fn##Ref)) GenTree##fn& gt##fn;
271 #define GTSTRUCT_2(fn, en, en2) GenTree##fn* As##fn() \
273 assert(this->gtOper == en || this->gtOper == en2); \
274 return reinterpret_cast<GenTree##fn*>(this); \
276 GenTree##fn& As##fn##Ref() { return *As##fn(); } \
277 __declspec(property(get=As##fn##Ref)) GenTree##fn& gt##fn;
278 #define GTSTRUCT_3(fn, en, en2, en3) GenTree##fn* As##fn() \
280 assert(this->gtOper == en || this->gtOper == en2 || this->gtOper == en3); \
281 return reinterpret_cast<GenTree##fn*>(this); \
283 GenTree##fn& As##fn##Ref() { return *As##fn(); } \
284 __declspec(property(get=As##fn##Ref)) GenTree##fn& gt##fn;
286 #define GTSTRUCT_4(fn, en, en2, en3, en4) GenTree##fn* As##fn() \
288 assert(this->gtOper == en || this->gtOper == en2 || this->gtOper == en3 || this->gtOper == en4); \
289 return reinterpret_cast<GenTree##fn*>(this); \
291 GenTree##fn& As##fn##Ref() { return *As##fn(); } \
292 __declspec(property(get=As##fn##Ref)) GenTree##fn& gt##fn;
295 // VC does not optimize out this loop in retail even though the value it computes is unused
296 // so we need a separate version for non-debug
297 #define GTSTRUCT_N(fn, ...) GenTree##fn* As##fn() \
299 genTreeOps validOps[] = {__VA_ARGS__}; \
300 bool found = false; \
301 for (unsigned i=0; i<ArrLen(validOps); i++) { \
302 if (this->gtOper == validOps[i]) \
309 return reinterpret_cast<GenTree##fn*>(this); \
311 GenTree##fn& As##fn##Ref() { return *As##fn(); } \
312 __declspec(property(get=As##fn##Ref)) GenTree##fn& gt##fn;
314 #define GTSTRUCT_N(fn, ...) GenTree##fn* As##fn() \
316 return reinterpret_cast<GenTree##fn*>(this); \
318 GenTree##fn& As##fn##Ref() { return *As##fn(); } \
319 __declspec(property(get=As##fn##Ref)) GenTree##fn& gt##fn;
322 #include "gtstructs.h"
324 genTreeOps gtOper; // enum subtype BYTE
325 var_types gtType; // enum subtype BYTE
327 genTreeOps OperGet() const { return gtOper; }
328 var_types TypeGet() const { return gtType; }
331 genTreeOps gtOperSave; // Only used to save gtOper when we destroy a node, to aid debugging.
338 #define IS_CSE_INDEX(x) (x != 0)
339 #define IS_CSE_USE(x) (x > 0)
340 #define IS_CSE_DEF(x) (x < 0)
341 #define GET_CSE_INDEX(x) ((x > 0) ? x : -x)
342 #define TO_CSE_DEF(x) (-x)
344 signed char gtCSEnum; // 0 or the CSE index (negated if def)
345 // valid only for CSE expressions
347 #endif // FEATURE_ANYCSE
350 unsigned short gtAssertionNum; // 0 or Assertion table index
351 // valid only for non-GT_STMT nodes
353 bool HasAssertion() const { return gtAssertionNum != 0; }
354 void ClearAssertion() { gtAssertionNum = 0; }
356 unsigned short GetAssertion() const { return gtAssertionNum; }
357 void SetAssertion(unsigned short value) { assert((unsigned short)value == value); gtAssertionNum = (unsigned short)value; }
361 #if FEATURE_STACK_FP_X87
362 unsigned char gtFPlvl; // x87 stack depth at this node
363 void gtCopyFPlvl(GenTree * other) { gtFPlvl = other->gtFPlvl; }
364 void gtSetFPlvl(unsigned level) { noway_assert(FitsIn<unsigned char>(level)); gtFPlvl = (unsigned char)level; }
365 #else // FEATURE_STACK_FP_X87
366 void gtCopyFPlvl(GenTree * other) { }
367 void gtSetFPlvl(unsigned level) { }
368 #endif // FEATURE_STACK_FP_X87
371 // Cost metrics on the node. Don't allow direct access to the variable for setting.
377 // You are not allowed to read the cost values before they have been set in gtSetEvalOrder().
378 // Keep track of whether the costs have been initialized, and assert if they are read before being initialized.
379 // Obviously, this information does need to be initialized when a node is created.
380 // This is public so the dumpers can see it.
382 bool gtCostsInitialized;
385 #define MAX_COST UCHAR_MAX
386 #define IND_COST_EX 3 // execution cost for an indirection
388 __declspec(property(get=GetCostEx))
389 unsigned char gtCostEx; // estimate of expression execution cost
391 __declspec(property(get=GetCostSz))
392 unsigned char gtCostSz; // estimate of expression code size cost
394 unsigned char GetCostEx() const { assert(gtCostsInitialized); return _gtCostEx; }
395 unsigned char GetCostSz() const { assert(gtCostsInitialized); return _gtCostSz; }
397 // Set the costs. They are always both set at the same time.
398 // Don't use the "put" property: force calling this function, to make it more obvious in the few places
399 // that set the values.
400 // Note that costs are only set in gtSetEvalOrder() and its callees.
401 void SetCosts(unsigned costEx, unsigned costSz)
403 assert(costEx != (unsigned)-1); // looks bogus
404 assert(costSz != (unsigned)-1); // looks bogus
405 INDEBUG(gtCostsInitialized = true;)
407 _gtCostEx = (costEx > MAX_COST) ? MAX_COST : (unsigned char)costEx;
408 _gtCostSz = (costSz > MAX_COST) ? MAX_COST : (unsigned char)costSz;
411 // Opimized copy function, to avoid the SetCosts() function comparisons, and make it more clear that a node copy is happening.
412 void CopyCosts(const GenTree* const tree)
414 INDEBUG(gtCostsInitialized = tree->gtCostsInitialized;) // If the 'tree' costs aren't initialized, we'll hit an assert below.
415 _gtCostEx = tree->gtCostEx;
416 _gtCostSz = tree->gtCostSz;
419 // Same as CopyCosts, but avoids asserts if the costs we are copying have not been initialized.
420 // This is because the importer, for example, clones nodes, before these costs have been initialized.
421 // Note that we directly access the 'tree' costs, not going through the accessor functions (either
422 // directly or through the properties).
423 void CopyRawCosts(const GenTree* const tree)
425 INDEBUG(gtCostsInitialized = tree->gtCostsInitialized;)
426 _gtCostEx = tree->_gtCostEx;
427 _gtCostSz = tree->_gtCostSz;
432 unsigned char _gtCostEx; // estimate of expression execution cost
433 unsigned char _gtCostSz; // estimate of expression code size cost
436 // Register or register pair number of the node.
443 GT_REGTAG_NONE, // Nothing has been assigned to _gtRegNum/_gtRegPair
444 GT_REGTAG_REG, // _gtRegNum has been assigned
445 #if CPU_LONG_USES_REGPAIR
446 GT_REGTAG_REGPAIR // _gtRegPair has been assigned
449 genRegTag GetRegTag() const
451 #if CPU_LONG_USES_REGPAIR
452 assert(gtRegTag == GT_REGTAG_NONE || gtRegTag == GT_REGTAG_REG || gtRegTag == GT_REGTAG_REGPAIR);
454 assert(gtRegTag == GT_REGTAG_NONE || gtRegTag == GT_REGTAG_REG);
459 genRegTag gtRegTag; // What is in _gtRegNum/_gtRegPair?
466 // NOTE: After LSRA, one of these values may be valid even if GTF_REG_VAL is not set in gtFlags.
467 // They store the register assigned to the node. If a register is not assigned, _gtRegNum is set to REG_NA
468 // or _gtRegPair is set to REG_PAIR_NONE, depending on the node type.
469 regNumberSmall _gtRegNum; // which register the value is in
470 regPairNoSmall _gtRegPair; // which register pair the value is in
475 // The register number is stored in a small format (8 bits), but the getters return and the setters take
476 // a full-size (unsigned) format, to localize the casts here.
478 __declspec(property(get=GetRegNum,put=SetRegNum))
481 // for codegen purposes, is this node a subnode of its parent
482 bool isContained() const;
484 bool isContainedIndir() const;
486 bool isIndirAddrMode();
488 bool isIndir() const;
490 bool isContainedIntOrIImmed() const { return isContained() && IsCnsIntOrI(); }
492 bool isContainedFltOrDblImmed() const { return isContained() && (OperGet() == GT_CNS_DBL); }
494 bool isLclField() const { return OperGet() == GT_LCL_FLD || OperGet() == GT_STORE_LCL_FLD; }
496 bool isContainedLclField() const { return isContained() && isLclField(); }
498 // Indicates whether it is a memory op.
499 // Right now it includes Indir and LclField ops.
500 bool isMemoryOp() const { return isIndir() || isLclField(); }
502 bool isContainedMemoryOp() const { return isContained() && isMemoryOp(); }
504 regNumber GetRegNum() const
506 assert((gtRegTag == GT_REGTAG_REG) ||
507 (gtRegTag == GT_REGTAG_NONE)); // TODO-Cleanup: get rid of the NONE case, and fix everyplace that reads undefined values
508 regNumber reg = (regNumber) _gtRegNum;
509 assert((gtRegTag == GT_REGTAG_NONE) || // TODO-Cleanup: get rid of the NONE case, and fix everyplace that reads undefined values
515 void SetRegNum(regNumber reg)
517 assert(reg >= REG_FIRST &&
519 // Make sure the upper bits of _gtRegPair are clear
520 _gtRegPair = (regPairNoSmall) 0;
521 _gtRegNum = (regNumberSmall) reg;
522 INDEBUG(gtRegTag = GT_REGTAG_REG;)
523 assert(_gtRegNum == reg);
526 #if CPU_LONG_USES_REGPAIR
527 __declspec(property(get=GetRegPair,put=SetRegPair))
530 regPairNo GetRegPair() const
532 assert((gtRegTag == GT_REGTAG_REGPAIR) ||
533 (gtRegTag == GT_REGTAG_NONE)); // TODO-Cleanup: get rid of the NONE case, and fix everyplace that reads undefined values
534 regPairNo regPair = (regPairNo) _gtRegPair;
535 assert((gtRegTag == GT_REGTAG_NONE) || // TODO-Cleanup: get rid of the NONE case, and fix everyplace that reads undefined values
536 (regPair >= REG_PAIR_FIRST &&
537 regPair <= REG_PAIR_LAST) ||
538 (regPair == REG_PAIR_NONE)); // allow initializing to an undefined value
542 void SetRegPair(regPairNo regPair)
544 assert((regPair >= REG_PAIR_FIRST &&
545 regPair <= REG_PAIR_LAST) ||
546 (regPair == REG_PAIR_NONE)); // allow initializing to an undefined value
547 _gtRegPair = (regPairNoSmall) regPair;
548 INDEBUG(gtRegTag = GT_REGTAG_REGPAIR;)
549 assert(_gtRegPair == regPair);
553 // Copy the _gtRegNum/_gtRegPair/gtRegTag fields
554 void CopyReg(GenTreePtr from);
556 void gtClearReg(Compiler* compiler);
558 bool gtHasReg() const;
560 regMaskTP gtGetRegMask() const;
562 unsigned gtFlags; // see GTF_xxxx below
565 unsigned gtDebugFlags; // see GTF_DEBUG_xxx below
566 #endif // defined(DEBUG)
568 ValueNumPair gtVNPair;
570 regMaskSmall gtRsvdRegs; // set of fixed trashed registers
571 #ifdef LEGACY_BACKEND
572 regMaskSmall gtUsedRegs; // set of used (trashed) registers
573 #endif // LEGACY_BACKEND
575 #ifndef LEGACY_BACKEND
576 TreeNodeInfo gtLsraInfo;
577 #endif // !LEGACY_BACKEND
579 void SetVNsFromNode(GenTreePtr tree)
581 gtVNPair = tree->gtVNPair;
584 ValueNum GetVN(ValueNumKind vnk) const
586 if (vnk == VNK_Liberal)
588 return gtVNPair.GetLiberal();
592 assert(vnk == VNK_Conservative);
593 return gtVNPair.GetConservative();
596 void SetVN(ValueNumKind vnk, ValueNum vn)
598 if (vnk == VNK_Liberal)
600 return gtVNPair.SetLiberal(vn);
604 assert(vnk == VNK_Conservative);
605 return gtVNPair.SetConservative(vn);
608 void SetVNs(ValueNumPair vnp)
614 gtVNPair = ValueNumPair(); // Initializes both elements to "NoVN".
617 //---------------------------------------------------------------------
618 // The first set of flags can be used with a large set of nodes, and
619 // thus they must all have distinct values. That is, one can test any
620 // expression node for one of these flags.
621 //---------------------------------------------------------------------
623 #define GTF_ASG 0x00000001 // sub-expression contains an assignment
624 #define GTF_CALL 0x00000002 // sub-expression contains a func. call
625 #define GTF_EXCEPT 0x00000004 // sub-expression might throw an exception
626 #define GTF_GLOB_REF 0x00000008 // sub-expression uses global variable(s)
627 #define GTF_ORDER_SIDEEFF 0x00000010 // sub-expression has a re-ordering side effect
629 // If you set these flags, make sure that code:gtExtractSideEffList knows how to find the tree,
630 // otherwise the C# (run csc /o-)
631 // var v = side_eff_operation
632 // with no use of v will drop your tree on the floor.
633 #define GTF_PERSISTENT_SIDE_EFFECTS (GTF_ASG|GTF_CALL)
634 #define GTF_SIDE_EFFECT (GTF_PERSISTENT_SIDE_EFFECTS|GTF_EXCEPT)
635 #define GTF_GLOB_EFFECT (GTF_SIDE_EFFECT|GTF_GLOB_REF)
636 #define GTF_ALL_EFFECT (GTF_GLOB_EFFECT|GTF_ORDER_SIDEEFF)
638 // The extra flag GTF_DEAD is used to tell the consumer of these flags
639 // that we are calling in the context of performing a CSE, thus we
640 // should allow the run-once side effects of running a class constructor.
642 #define GTF_PERSISTENT_SIDE_EFFECTS_IN_CSE (GTF_ASG|GTF_CALL|GTF_DEAD)
644 // Can any side-effects be observed externally, say by a caller method?
645 // For assignments, only assignments to global memory can be observed
646 // externally, whereas simple assignments to local variables can not.
648 // Be careful when using this inside a "try" protected region as the
649 // order of assignments to local variables would need to be preserved
650 // wrt side effects if the variables are alive on entry to the
651 // "catch/finally" region. In such cases, even assignments to locals
652 // will have to be restricted.
653 #define GTF_GLOBALLY_VISIBLE_SIDE_EFFECTS(flags) \
654 (((flags) & (GTF_CALL|GTF_EXCEPT)) || \
655 (((flags) & (GTF_ASG|GTF_GLOB_REF)) == (GTF_ASG|GTF_GLOB_REF)))
657 #define GTF_REVERSE_OPS 0x00000020 // operand op2 should be evaluated before op1 (normally, op1 is evaluated first and op2 is evaluated second)
658 #define GTF_REG_VAL 0x00000040 // operand is sitting in a register (or part of a TYP_LONG operand is sitting in a register)
660 #define GTF_SPILLED 0x00000080 // the value has been spilled
661 #define GTF_SPILLED_OPER 0x00000100 // op1 has been spilled
663 #ifdef LEGACY_BACKEND
664 #define GTF_SPILLED_OP2 0x00000200 // op2 has been spilled
665 #endif // LEGACY_BACKEND
667 #define GTF_REDINDEX_CHECK 0x00000100 // Used for redundant range checks. Disjoint from GTF_SPILLED_OPER
669 #define GTF_ZSF_SET 0x00000400 // the zero(ZF) and sign(SF) flags set to the operand
670 #if FEATURE_SET_FLAGS
671 #define GTF_SET_FLAGS 0x00000800 // Requires that codegen for this node set the flags
672 // Use gtSetFlags() to check this flags
674 #define GTF_IND_NONFAULTING 0x00000800 // An indir that cannot fault. GTF_SET_FLAGS is not used on indirs
677 #define GTF_DEAD 0x00001000 // this node won't be used any more
678 #endif // FEATURE_ANYCSE
680 #define GTF_MAKE_CSE 0x00002000 // Hoisted Expression: try hard to make this into CSE (see optPerformHoistExpr)
681 #define GTF_DONT_CSE 0x00004000 // don't bother CSE'ing this expr
682 #define GTF_COLON_COND 0x00008000 // this node is conditionally executed (part of ? :)
684 #define GTF_NODE_MASK (GTF_COLON_COND)
686 #define GTF_BOOLEAN 0x00040000 // value is known to be 0/1
688 #define GTF_SMALL_OK 0x00080000 // actual small int sufficient
690 #define GTF_UNSIGNED 0x00100000 // with GT_CAST: the source operand is an unsigned type
691 // with operators: the specified node is an unsigned operator
693 #define GTF_LATE_ARG 0x00200000 // the specified node is evaluated to a temp in the arg list, and this temp is added to gtCallLateArgs.
695 #define GTF_SPILL 0x00400000 // needs to be spilled here
696 #define GTF_SPILL_HIGH 0x00040000 // shared with GTF_BOOLEAN
698 #define GTF_COMMON_MASK 0x007FFFFF // mask of all the flags above
700 #define GTF_REUSE_REG_VAL 0x00800000 // This is set by the register allocator on nodes whose value already exists in the
701 // register assigned to this node, so the code generator does not have to generate
702 // code to produce the value.
703 // It is currently used only on constant nodes.
704 // It CANNOT be set on var (GT_LCL*) nodes, or on indir (GT_IND or GT_STOREIND) nodes, since
705 // it is not needed for lclVars and is highly unlikely to be useful for indir nodes
707 //---------------------------------------------------------------------
708 // The following flags can be used only with a small set of nodes, and
709 // thus their values need not be distinct (other than within the set
710 // that goes with a particular node/nodes, of course). That is, one can
711 // only test for one of these flags if the 'gtOper' value is tested as
712 // well to make sure it's the right operator for the particular flag.
713 //---------------------------------------------------------------------
715 // NB: GTF_VAR_* and GTF_REG_* share the same namespace of flags, because
716 // GT_LCL_VAR nodes may be changed to GT_REG_VAR nodes without resetting
717 // the flags. These are also used by GT_LCL_FLD.
718 #define GTF_VAR_DEF 0x80000000 // GT_LCL_VAR -- this is a definition
719 #define GTF_VAR_USEASG 0x40000000 // GT_LCL_VAR -- this is a use/def for a x<op>=y
720 #define GTF_VAR_USEDEF 0x20000000 // GT_LCL_VAR -- this is a use/def as in x=x+y (only the lhs x is tagged)
721 #define GTF_VAR_CAST 0x10000000 // GT_LCL_VAR -- has been explictly cast (variable node may not be type of local)
722 #define GTF_VAR_ITERATOR 0x08000000 // GT_LCL_VAR -- this is a iterator reference in the loop condition
723 #define GTF_VAR_CLONED 0x01000000 // GT_LCL_VAR -- this node has been cloned or is a clone
724 // Relevant for inlining optimizations (see fgInlinePrependStatements)
726 // TODO-Cleanup: Currently, GTF_REG_BIRTH is used only by stackfp
727 // We should consider using it more generally for VAR_BIRTH, instead of
728 // GTF_VAR_DEF && !GTF_VAR_USEASG
729 #define GTF_REG_BIRTH 0x04000000 // GT_REG_VAR -- enregistered variable born here
730 #define GTF_VAR_DEATH 0x02000000 // GT_LCL_VAR, GT_REG_VAR -- variable dies here (last use)
732 #define GTF_VAR_ARR_INDEX 0x00000020 // The variable is part of (the index portion of) an array index expression.
733 // Shares a value with GTF_REVERSE_OPS, which is meaningless for local var.
735 #define GTF_LIVENESS_MASK (GTF_VAR_DEF|GTF_VAR_USEASG|GTF_VAR_USEDEF|GTF_REG_BIRTH|GTF_VAR_DEATH)
737 #define GTF_CALL_UNMANAGED 0x80000000 // GT_CALL -- direct call to unmanaged code
738 #define GTF_CALL_INLINE_CANDIDATE 0x40000000 // GT_CALL -- this call has been marked as an inline candidate
740 #define GTF_CALL_VIRT_KIND_MASK 0x30000000
741 #define GTF_CALL_NONVIRT 0x00000000 // GT_CALL -- a non virtual call
742 #define GTF_CALL_VIRT_STUB 0x10000000 // GT_CALL -- a stub-dispatch virtual call
743 #define GTF_CALL_VIRT_VTABLE 0x20000000 // GT_CALL -- a vtable-based virtual call
745 #define GTF_CALL_NULLCHECK 0x08000000 // GT_CALL -- must check instance pointer for null
746 #define GTF_CALL_POP_ARGS 0x04000000 // GT_CALL -- caller pop arguments?
747 #define GTF_CALL_HOISTABLE 0x02000000 // GT_CALL -- call is hoistable
748 #define GTF_CALL_REG_SAVE 0x01000000 // GT_CALL -- This call preserves all integer regs
749 // For additional flags for GT_CALL node see GTF_CALL_M_
751 #define GTF_NOP_DEATH 0x40000000 // GT_NOP -- operand dies here
753 #define GTF_FLD_NULLCHECK 0x80000000 // GT_FIELD -- need to nullcheck the "this" pointer
754 #define GTF_FLD_VOLATILE 0x40000000 // GT_FIELD/GT_CLS_VAR -- same as GTF_IND_VOLATILE
756 #define GTF_INX_RNGCHK 0x80000000 // GT_INDEX -- the array reference should be range-checked.
757 #define GTF_INX_REFARR_LAYOUT 0x20000000 // GT_INDEX -- same as GTF_IND_REFARR_LAYOUT
758 #define GTF_INX_STRING_LAYOUT 0x40000000 // GT_INDEX -- this uses the special string array layout
760 #define GTF_IND_VOLATILE 0x40000000 // GT_IND -- the load or store must use volatile sematics (this is a nop on X86)
761 #define GTF_IND_REFARR_LAYOUT 0x20000000 // GT_IND -- the array holds object refs (only effects layout of Arrays)
762 #define GTF_IND_TGTANYWHERE 0x10000000 // GT_IND -- the target could be anywhere
763 #define GTF_IND_TLS_REF 0x08000000 // GT_IND -- the target is accessed via TLS
764 #define GTF_IND_ASG_LHS 0x04000000 // GT_IND -- this GT_IND node is (the effective val) of the LHS of an assignment; don't evaluate it independently.
765 #define GTF_IND_UNALIGNED 0x02000000 // GT_IND -- the load or store is unaligned (we assume worst case alignment of 1 byte)
766 #define GTF_IND_INVARIANT 0x01000000 // GT_IND -- the target is invariant (a prejit indirection)
767 #define GTF_IND_ARR_LEN 0x80000000 // GT_IND -- the indirection represents an array length (of the REF contribution to its argument).
768 #define GTF_IND_ARR_INDEX 0x00800000 // GT_IND -- the indirection represents an (SZ) array index
770 #define GTF_IND_FLAGS (GTF_IND_VOLATILE|GTF_IND_REFARR_LAYOUT|GTF_IND_TGTANYWHERE|GTF_IND_NONFAULTING|\
771 GTF_IND_TLS_REF|GTF_IND_UNALIGNED|GTF_IND_INVARIANT|GTF_IND_ARR_INDEX)
773 #define GTF_CLS_VAR_ASG_LHS 0x04000000 // GT_CLS_VAR -- this GT_CLS_VAR node is (the effective val) of the LHS of an assignment; don't evaluate it independently.
775 #define GTF_ADDR_ONSTACK 0x80000000 // GT_ADDR -- this expression is guaranteed to be on the stack
778 #define GTF_ADDRMODE_NO_CSE 0x80000000 // GT_ADD/GT_MUL/GT_LSH -- Do not CSE this node only, forms complex addressing mode
780 #define GTF_MUL_64RSLT 0x40000000 // GT_MUL -- produce 64-bit result
782 #define GTF_MOD_INT_RESULT 0x80000000 // GT_MOD, -- the real tree represented by this
783 // GT_UMOD node evaluates to an int even though
784 // its type is long. The result is
785 // placed in the low member of the
788 #define GTF_RELOP_NAN_UN 0x80000000 // GT_<relop> -- Is branch taken if ops are NaN?
789 #define GTF_RELOP_JMP_USED 0x40000000 // GT_<relop> -- result of compare used for jump or ?:
790 #define GTF_RELOP_QMARK 0x20000000 // GT_<relop> -- the node is the condition for ?:
791 #define GTF_RELOP_SMALL 0x10000000 // GT_<relop> -- We should use a byte or short sized compare (op1->gtType is the small type)
792 #define GTF_RELOP_ZTT 0x08000000 // GT_<relop> -- Loop test cloned for converting while-loops into do-while with explicit "loop test" in the header block.
794 #define GTF_QMARK_CAST_INSTOF 0x80000000 // GT_QMARK -- Is this a top (not nested) level qmark created for castclass or instanceof?
796 #define GTF_BOX_VALUE 0x80000000 // GT_BOX -- "box" is on a value type
798 #define GTF_ICON_HDL_MASK 0xF0000000 // Bits used by handle types below
800 #define GTF_ICON_SCOPE_HDL 0x10000000 // GT_CNS_INT -- constant is a scope handle
801 #define GTF_ICON_CLASS_HDL 0x20000000 // GT_CNS_INT -- constant is a class handle
802 #define GTF_ICON_METHOD_HDL 0x30000000 // GT_CNS_INT -- constant is a method handle
803 #define GTF_ICON_FIELD_HDL 0x40000000 // GT_CNS_INT -- constant is a field handle
804 #define GTF_ICON_STATIC_HDL 0x50000000 // GT_CNS_INT -- constant is a handle to static data
805 #define GTF_ICON_STR_HDL 0x60000000 // GT_CNS_INT -- constant is a string handle
806 #define GTF_ICON_PSTR_HDL 0x70000000 // GT_CNS_INT -- constant is a ptr to a string handle
807 #define GTF_ICON_PTR_HDL 0x80000000 // GT_CNS_INT -- constant is a ldptr handle
808 #define GTF_ICON_VARG_HDL 0x90000000 // GT_CNS_INT -- constant is a var arg cookie handle
809 #define GTF_ICON_PINVKI_HDL 0xA0000000 // GT_CNS_INT -- constant is a pinvoke calli handle
810 #define GTF_ICON_TOKEN_HDL 0xB0000000 // GT_CNS_INT -- constant is a token handle
811 #define GTF_ICON_TLS_HDL 0xC0000000 // GT_CNS_INT -- constant is a TLS ref with offset
812 #define GTF_ICON_FTN_ADDR 0xD0000000 // GT_CNS_INT -- constant is a function address
813 #define GTF_ICON_CIDMID_HDL 0xE0000000 // GT_CNS_INT -- constant is a class or module ID handle
814 #define GTF_ICON_BBC_PTR 0xF0000000 // GT_CNS_INT -- constant is a basic block count pointer
816 #define GTF_ICON_FIELD_OFF 0x08000000 // GT_CNS_INT -- constant is a field offset
818 #define GTF_BLK_HASGCPTR 0x80000000 // GT_COPYBLK -- This struct copy will copy GC Pointers
819 #define GTF_BLK_VOLATILE 0x40000000 // GT_INITBLK/GT_COPYBLK -- is a volatile block operation
820 #define GTF_BLK_UNALIGNED 0x02000000 // GT_INITBLK/GT_COPYBLK -- is an unaligned block operation
822 #define GTF_OVERFLOW 0x10000000 // GT_ADD, GT_SUB, GT_MUL, - Need overflow check
823 // GT_ASG_ADD, GT_ASG_SUB,
825 // Use gtOverflow(Ex)() to check this flag
827 #define GTF_NO_OP_NO 0x80000000 // GT_NO_OP --Have the codegenerator generate a special nop
829 //----------------------------------------------------------------
831 #define GTF_STMT_CMPADD 0x80000000 // GT_STMT -- added by compiler
832 #define GTF_STMT_HAS_CSE 0x40000000 // GT_STMT -- CSE def or use was subsituted
833 #define GTF_STMT_TOP_LEVEL 0x20000000 // GT_STMT -- Top-level statement - true iff gtStmtList->gtPrev == nullptr
834 // True for all stmts when in FGOrderTree
835 #define GTF_STMT_SKIP_LOWER 0x10000000 // GT_STMT -- Skip lowering if we already lowered an embedded stmt.
837 //----------------------------------------------------------------
840 #define GTF_DEBUG_NONE 0x00000000 // No debug flags.
842 #define GTF_DEBUG_NODE_MORPHED 0x00000001 // the node has been morphed (in the global morphing phase)
843 #define GTF_DEBUG_NODE_SMALL 0x00000002
844 #define GTF_DEBUG_NODE_LARGE 0x00000004
846 #define GTF_DEBUG_NODE_MASK 0x00000007 // These flags are all node (rather than operation) properties.
848 #define GTF_DEBUG_VAR_CSE_REF 0x00800000 // GT_LCL_VAR -- This is a CSE LCL_VAR node
849 #endif // defined(DEBUG)
856 unsigned gtSeqNum; // liveness traversal order within the current statement
860 const unsigned short gtOperKindTable[];
863 unsigned OperKind(unsigned gtOper)
865 assert(gtOper < GT_COUNT);
867 return gtOperKindTable[gtOper];
870 unsigned OperKind() const
872 assert(gtOper < GT_COUNT);
874 return gtOperKindTable[gtOper];
877 static bool IsExOp(unsigned opKind)
879 return (opKind & GTK_EXOP) != 0;
881 // Returns the operKind with the GTK_EX_OP bit removed (the
882 // kind of operator, unary or binary, that is extended).
883 static unsigned StripExOp(unsigned opKind)
885 return opKind & ~GTK_EXOP;
889 bool OperIsConst(genTreeOps gtOper)
891 return (OperKind(gtOper) & GTK_CONST ) != 0;
894 bool OperIsConst() const
896 return (OperKind(gtOper) & GTK_CONST ) != 0;
900 bool OperIsLeaf(genTreeOps gtOper)
902 return (OperKind(gtOper) & GTK_LEAF ) != 0;
905 bool OperIsLeaf() const
907 return (OperKind(gtOper) & GTK_LEAF ) != 0;
911 bool OperIsCompare(genTreeOps gtOper)
913 return (OperKind(gtOper) & GTK_RELOP ) != 0;
917 bool OperIsLocal(genTreeOps gtOper)
919 bool result = (OperKind(gtOper) & GTK_LOCAL) != 0;
921 (gtOper == GT_LCL_VAR ||
922 gtOper == GT_PHI_ARG ||
923 gtOper == GT_REG_VAR ||
924 gtOper == GT_LCL_FLD ||
925 gtOper == GT_STORE_LCL_VAR ||
926 gtOper == GT_STORE_LCL_FLD));
931 bool OperIsBlkOp(genTreeOps gtOper)
933 return (gtOper == GT_INITBLK ||
934 gtOper == GT_COPYBLK ||
935 gtOper == GT_COPYOBJ);
939 bool OperIsCopyBlkOp(genTreeOps gtOper)
941 return (gtOper == GT_COPYOBJ || gtOper == GT_COPYBLK);
946 bool OperIsLocalAddr(genTreeOps gtOper)
948 return (gtOper == GT_LCL_VAR_ADDR ||
949 gtOper == GT_LCL_FLD_ADDR);
953 bool OperIsScalarLocal(genTreeOps gtOper)
955 return (gtOper == GT_LCL_VAR ||
956 gtOper == GT_REG_VAR ||
957 gtOper == GT_STORE_LCL_VAR);
961 bool OperIsNonPhiLocal(genTreeOps gtOper)
963 return OperIsLocal(gtOper) && (gtOper != GT_PHI_ARG);
967 bool OperIsLocalRead(genTreeOps gtOper)
969 return (OperIsLocal(gtOper) && !OperIsLocalStore(gtOper));
973 bool OperIsLocalStore(genTreeOps gtOper)
975 return (gtOper == GT_STORE_LCL_VAR ||
976 gtOper == GT_STORE_LCL_FLD);
981 bool OperIsAddrMode(genTreeOps gtOper)
983 return (gtOper == GT_LEA);
986 bool OperIsBlkOp() const
988 return OperIsBlkOp(OperGet());
991 bool OperIsCopyBlkOp() const
993 return OperIsCopyBlkOp(OperGet());
996 bool OperIsPutArgStk() const
998 return gtOper == GT_PUTARG_STK;
1001 bool OperIsAddrMode() const
1003 return OperIsAddrMode(OperGet());
1006 bool OperIsLocal() const
1008 return OperIsLocal(OperGet());
1011 bool OperIsLocalAddr() const
1013 return OperIsLocalAddr(OperGet());
1016 bool OperIsScalarLocal() const
1018 return OperIsScalarLocal(OperGet());
1021 bool OperIsNonPhiLocal() const
1023 return OperIsNonPhiLocal(OperGet());
1026 bool OperIsLocalStore() const
1028 return OperIsLocalStore(OperGet());
1031 bool OperIsLocalRead() const
1033 return OperIsLocalRead(OperGet());
1036 bool OperIsCompare()
1038 return (OperKind(gtOper) & GTK_RELOP ) != 0;
1042 bool OperIsLogical(genTreeOps gtOper)
1044 return (OperKind(gtOper) & GTK_LOGOP ) != 0;
1047 bool OperIsLogical() const
1049 return (OperKind(gtOper) & GTK_LOGOP ) != 0;
1053 bool OperIsShift(genTreeOps gtOper)
1055 return (gtOper == GT_LSH) ||
1056 (gtOper == GT_RSH) ||
1060 bool OperIsShift() const
1062 return OperIsShift(OperGet());
1066 bool OperIsRotate(genTreeOps gtOper)
1068 return (gtOper == GT_ROL) ||
1072 bool OperIsRotate() const
1074 return OperIsRotate(OperGet());
1078 bool OperIsShiftOrRotate(genTreeOps gtOper)
1080 return OperIsShift(gtOper) ||
1081 OperIsRotate(gtOper);
1084 bool OperIsShiftOrRotate() const
1086 return OperIsShiftOrRotate(OperGet());
1089 bool OperIsArithmetic() const
1091 genTreeOps op = OperGet();
1105 || OperIsShiftOrRotate(op);
1108 #if !defined(LEGACY_BACKEND) && !defined(_TARGET_64BIT_)
1110 bool OperIsHigh(genTreeOps gtOper)
1125 bool OperIsHigh() const
1127 return OperIsHigh(OperGet());
1129 #endif // !defined(LEGACY_BACKEND) && !defined(_TARGET_64BIT_)
1132 bool OperIsUnary(genTreeOps gtOper)
1134 return (OperKind(gtOper) & GTK_UNOP ) != 0;
1137 bool OperIsUnary() const
1139 return OperIsUnary(gtOper);
1143 bool OperIsBinary(genTreeOps gtOper)
1145 return (OperKind(gtOper) & GTK_BINOP ) != 0;
1148 bool OperIsBinary() const
1150 return OperIsBinary(gtOper);
1154 bool OperIsSimple(genTreeOps gtOper)
1156 return (OperKind(gtOper) & GTK_SMPOP ) != 0;
1160 bool OperIsSpecial(genTreeOps gtOper)
1162 return ((OperKind(gtOper) & GTK_KINDMASK) == GTK_SPECIAL);
1165 bool OperIsSimple() const
1167 return OperIsSimple(gtOper);
1171 bool isCommutativeSIMDIntrinsic();
1173 bool isCommutativeSIMDIntrinsic()
1177 #endif // FEATURE_SIMD
1180 bool OperIsCommutative(genTreeOps gtOper)
1182 return (OperKind(gtOper) & GTK_COMMUTE) != 0;
1185 bool OperIsCommutative()
1187 return OperIsCommutative(gtOper) || (OperIsSIMD(gtOper) && isCommutativeSIMDIntrinsic());
1191 bool OperIsAssignment(genTreeOps gtOper)
1193 return (OperKind(gtOper) & GTK_ASGOP) != 0;
1196 bool OperIsAssignment() const
1198 return OperIsAssignment(gtOper);
1202 bool OperIsIndir(genTreeOps gtOper)
1204 return gtOper == GT_IND || gtOper == GT_STOREIND || gtOper == GT_NULLCHECK;
1207 bool OperIsIndir() const
1209 return OperIsIndir(gtOper);
1213 bool OperIsImplicitIndir(genTreeOps gtOper)
1234 bool OperIsImplicitIndir() const
1236 return OperIsImplicitIndir(gtOper);
1239 bool OperIsStore() const
1241 return OperIsStore(gtOper);
1245 bool OperIsStore(genTreeOps gtOper)
1247 return (gtOper == GT_STOREIND
1248 || gtOper == GT_STORE_LCL_VAR
1249 || gtOper == GT_STORE_LCL_FLD
1250 || gtOper == GT_STORE_CLS_VAR);
1254 bool OperIsAtomicOp(genTreeOps gtOper)
1256 return (gtOper == GT_XADD
1257 || gtOper == GT_XCHG
1258 || gtOper == GT_LOCKADD
1259 || gtOper == GT_CMPXCHG);
1262 bool OperIsAtomicOp()
1264 return OperIsAtomicOp(gtOper);
1267 // This is basically here for cleaner FEATURE_SIMD #ifdefs.
1269 bool OperIsSIMD(genTreeOps gtOper)
1272 return gtOper == GT_SIMD;
1273 #else // !FEATURE_SIMD
1275 #endif // !FEATURE_SIMD
1280 return OperIsSIMD(gtOper);
1283 // Requires that "op" is an op= operator. Returns
1284 // the corresponding "op".
1286 genTreeOps OpAsgToOper(genTreeOps op);
1289 bool NullOp1Legal() const
1291 assert(OperIsSimple(gtOper));
1294 case GT_PHI: case GT_LEA: case GT_RETFILT: case GT_NOP:
1297 return gtType == TYP_VOID;
1303 bool NullOp2Legal() const
1305 assert(OperIsSimple(gtOper));
1306 if (!OperIsBinary(gtOper))
1321 #endif // !FEATURE_SIMD
1329 inline bool RequiresNonNullOp2(genTreeOps oper);
1330 bool IsListForMultiRegArg();
1333 inline bool IsFPZero();
1334 inline bool IsIntegralConst(ssize_t constVal);
1336 inline bool IsBoxedValue();
1340 return gtOper == GT_LIST;
1343 inline GenTreePtr MoveNext();
1345 inline GenTreePtr Current();
1347 inline GenTreePtr *pCurrent();
1349 inline GenTreePtr gtGetOp1();
1351 inline GenTreePtr gtGetOp2();
1353 // Given a tree node, if this is a child of that node, return the pointer to the child node so that it
1354 // can be modified; otherwise, return null.
1355 GenTreePtr* gtGetChildPointer(GenTreePtr parent);
1357 // Get the parent of this node, and optionally capture the pointer to the child so that it can be modified.
1358 GenTreePtr gtGetParent(GenTreePtr** parentChildPtrPtr);
1360 inline GenTreePtr gtEffectiveVal(bool commaOnly = false);
1362 // Return the child of this node if it is a GT_RELOAD or GT_COPY; otherwise simply return the node itself
1363 inline GenTree* gtSkipReloadOrCopy();
1365 // Returns true if it is a call node returning its value in more than one register
1366 inline bool IsMultiRegCall() const;
1368 // Returns true if it is a GT_COPY or GT_RELOAD node
1369 inline bool IsCopyOrReload() const;
1371 // Returns true if it is a GT_COPY or GT_RELOAD of a multi-reg call node
1372 inline bool IsCopyOrReloadOfMultiRegCall() const;
1374 bool OperMayThrow();
1376 unsigned GetScaleIndexMul();
1377 unsigned GetScaleIndexShf();
1378 unsigned GetScaledIndex();
1380 // Returns true if "addr" is a GT_ADD node, at least one of whose arguments is an integer
1381 // (<= 32 bit) constant. If it returns true, it sets "*offset" to (one of the) constant value(s), and
1382 // "*addr" to the other argument.
1383 bool IsAddWithI32Const(GenTreePtr* addr, int* offset);
1385 // Insert 'node' after this node in execution order.
1386 void InsertAfterSelf(GenTree* node, GenTreeStmt* stmt = nullptr);
1390 #if SMALL_TREE_NODES
1392 unsigned char s_gtNodeSizes[];
1396 void InitNodeSize();
1398 size_t GetNodeSize() const;
1400 bool IsNodeProperlySized() const;
1402 void CopyFrom(const GenTree* src, Compiler* comp);
1405 genTreeOps ReverseRelop(genTreeOps relop);
1408 genTreeOps SwapRelop(genTreeOps relop);
1410 //---------------------------------------------------------------------
1413 bool Compare(GenTreePtr op1, GenTreePtr op2, bool swapOK = false);
1415 //---------------------------------------------------------------------
1417 //---------------------------------------------------------------------
1420 const char * NodeName(genTreeOps op);
1423 const char * OpName(genTreeOps op);
1425 //---------------------------------------------------------------------
1427 //---------------------------------------------------------------------
1429 bool IsNothingNode () const;
1430 void gtBashToNOP ();
1432 // Value number update action enumeration
1433 enum ValueNumberUpdate
1435 CLEAR_VN, // Clear value number
1436 PRESERVE_VN // Preserve value number
1439 void SetOper(genTreeOps oper, ValueNumberUpdate vnUpdate = CLEAR_VN); // set gtOper
1440 void SetOperResetFlags (genTreeOps oper); // set gtOper and reset flags
1442 void ChangeOperConst (genTreeOps oper); // ChangeOper(constOper)
1443 // set gtOper and only keep GTF_COMMON_MASK flags
1444 void ChangeOper(genTreeOps oper, ValueNumberUpdate vnUpdate = CLEAR_VN);
1445 void ChangeOperUnchecked (genTreeOps oper);
1447 bool IsLocal() const
1449 return OperIsLocal(OperGet());
1452 // Returns "true" iff 'this' is a GT_LCL_FLD or GT_STORE_LCL_FLD on which the type
1453 // is not the same size as the type of the GT_LCL_VAR.
1454 bool IsPartialLclFld(Compiler* comp);
1456 // Returns "true" iff "this" defines a local variable. Requires "comp" to be the
1457 // current compilation. If returns "true", sets "*pLclVarTree" to the
1458 // tree for the local that is defined, and, if "pIsEntire" is non-null, sets "*pIsEntire" to
1459 // true or false, depending on whether the assignment writes to the entirety of the local
1460 // variable, or just a portion of it.
1461 bool DefinesLocal(Compiler* comp, GenTreeLclVarCommon** pLclVarTree, bool* pIsEntire = nullptr);
1463 // Returns true if "this" represents the address of a local, or a field of a local. If returns true, sets
1464 // "*pLclVarTree" to the node indicating the local variable. If the address is that of a field of this node,
1465 // sets "*pFldSeq" to the field sequence representing that field, else null.
1466 bool IsLocalAddrExpr(Compiler* comp, GenTreeLclVarCommon** pLclVarTree, FieldSeqNode** pFldSeq);
1468 // Simpler variant of the above which just returns the local node if this is an expression that
1469 // yields an address into a local
1470 GenTreeLclVarCommon* IsLocalAddrExpr();
1472 // Determine whether this is an assignment tree of the form X = X (op) Y,
1473 // where Y is an arbitrary tree, and X is a lclVar.
1474 unsigned IsLclVarUpdateTree(GenTree** otherTree, genTreeOps *updateOper);
1476 // If returns "true", "this" may represent the address of a static or instance field
1477 // (or a field of such a field, in the case of an object field of type struct).
1478 // If returns "true", then either "*pObj" is set to the object reference,
1479 // or "*pStatic" is set to the baseAddr or offset to be added to the "*pFldSeq"
1480 // Only one of "*pObj" or "*pStatic" will be set, the other one will be null.
1481 // The boolean return value only indicates that "this" *may* be a field address
1482 // -- the field sequence must also be checked.
1483 // If it is a field address, the field sequence will be a sequence of length >= 1,
1484 // starting with an instance or static field, and optionally continuing with struct fields.
1485 bool IsFieldAddr(Compiler* comp, GenTreePtr* pObj, GenTreePtr* pStatic, FieldSeqNode** pFldSeq);
1487 // Requires "this" to be the address of an array (the child of a GT_IND labeled with GTF_IND_ARR_INDEX).
1488 // Sets "pArr" to the node representing the array (either an array object pointer, or perhaps a byref to the some element).
1489 // Sets "*pArrayType" to the class handle for the array type.
1490 // Sets "*inxVN" to the value number inferred for the array index.
1491 // Sets "*pFldSeq" to the sequence, if any, of struct fields used to index into the array element.
1492 void ParseArrayAddress(Compiler* comp,
1493 struct ArrayInfo* arrayInfo,
1496 FieldSeqNode** pFldSeq);
1498 // Helper method for the above.
1499 void ParseArrayAddressWork(Compiler* comp, ssize_t inputMul, GenTreePtr* pArr, ValueNum* pInxVN, ssize_t* pOffset, FieldSeqNode** pFldSeq);
1501 // Requires "this" to be a GT_IND. Requires the outermost caller to set "*pFldSeq" to nullptr.
1502 // Returns true if it is an array index expression, or access to a (sequence of) struct field(s)
1503 // within a struct array element. If it returns true, sets *arrayInfo to the array information, and sets *pFldSeq to the sequence
1504 // of struct field accesses.
1505 bool ParseArrayElemForm(Compiler* comp, ArrayInfo* arrayInfo, FieldSeqNode** pFldSeq);
1507 // Requires "this" to be the address of a (possible) array element (or struct field within that).
1508 // If it is, sets "*arrayInfo" to the array access info, "*pFldSeq" to the sequence of struct fields
1509 // accessed within the array element, and returns true. If not, returns "false".
1510 bool ParseArrayElemAddrForm(Compiler* comp, ArrayInfo* arrayInfo, FieldSeqNode** pFldSeq);
1512 // Requires "this" to be an int expression. If it is a sequence of one or more integer constants added together,
1513 // returns true and sets "*pFldSeq" to the sequence of fields with which those constants are annotated.
1514 bool ParseOffsetForm(Compiler* comp, FieldSeqNode** pFldSeq);
1516 // Labels "*this" as an array index expression: label all constants and variables that could contribute, as part of an affine expression, to the value of the
1518 void LabelIndex(Compiler* comp, bool isConst = true);
1520 // Assumes that "this" occurs in a context where it is being dereferenced as the LHS of an assignment-like
1521 // statement (assignment, initblk, or copyblk). The "width" should be the number of bytes copied by the
1522 // operation. Returns "true" if "this" is an address of (or within)
1523 // a local variable; sets "*pLclVarTree" to that local variable instance; and, if "pIsEntire" is non-null,
1524 // sets "*pIsEntire" to true if this assignment writes the full width of the local.
1525 bool DefinesLocalAddr(Compiler* comp, unsigned width, GenTreeLclVarCommon** pLclVarTree, bool* pIsEntire);
1527 bool IsRegVar () const
1529 return OperGet() == GT_REG_VAR?true:false;
1533 return (gtFlags & GTF_REG_VAL)?true:false;
1537 gtFlags |= GTF_REG_VAL;
1540 regNumber GetReg() const
1542 return InReg() ? gtRegNum : REG_NA;
1544 bool IsRegVarDeath () const
1546 assert(OperGet() == GT_REG_VAR);
1547 return (gtFlags & GTF_VAR_DEATH)?true:false;
1549 bool IsRegVarBirth () const
1551 assert(OperGet() == GT_REG_VAR);
1552 return (gtFlags & GTF_REG_BIRTH)?true:false;
1554 bool IsReverseOp() const
1556 return (gtFlags & GTF_REVERSE_OPS)?true:false;
1559 inline bool IsCnsIntOrI () const;
1561 inline bool IsIntegralConst () const;
1563 inline bool IsIntCnsFitsInI32 ();
1565 inline bool IsCnsFltOrDbl() const;
1567 inline bool IsCnsNonZeroFltOrDbl();
1569 bool IsIconHandle () const
1571 assert(gtOper == GT_CNS_INT);
1572 return (gtFlags & GTF_ICON_HDL_MASK) ? true : false;
1575 bool IsIconHandle (unsigned handleType) const
1577 assert(gtOper == GT_CNS_INT);
1578 assert((handleType & GTF_ICON_HDL_MASK) != 0); // check that handleType is one of the valid GTF_ICON_* values
1579 assert((handleType & ~GTF_ICON_HDL_MASK) == 0);
1580 return (gtFlags & GTF_ICON_HDL_MASK) == handleType;
1583 // Return just the part of the flags corresponding to the GTF_ICON_*_HDL flag. For example,
1584 // GTF_ICON_SCOPE_HDL. The tree node must be a const int, but it might not be a handle, in which
1585 // case we'll return zero.
1586 unsigned GetIconHandleFlag () const
1588 assert(gtOper == GT_CNS_INT);
1589 return (gtFlags & GTF_ICON_HDL_MASK);
1592 // Mark this node as no longer being a handle; clear its GTF_ICON_*_HDL bits.
1593 void ClearIconHandleMask()
1595 assert(gtOper == GT_CNS_INT);
1596 gtFlags &= ~GTF_ICON_HDL_MASK;
1599 // Return true if the two GT_CNS_INT trees have the same handle flag (GTF_ICON_*_HDL).
1600 static bool SameIconHandleFlag(GenTree* t1, GenTree* t2)
1602 return t1->GetIconHandleFlag() == t2->GetIconHandleFlag();
1605 bool IsArgPlaceHolderNode() const { return OperGet() == GT_ARGPLACE; }
1606 bool IsCall () const { return OperGet() == GT_CALL; }
1607 bool IsStatement () const { return OperGet() == GT_STMT; }
1608 inline bool IsHelperCall ();
1610 bool IsVarAddr () const;
1611 bool gtOverflow () const;
1612 bool gtOverflowEx () const;
1613 bool gtSetFlags () const;
1614 bool gtRequestSetFlags ();
1616 bool gtIsValid64RsltMul ();
1617 static int gtDispFlags (unsigned flags, unsigned debugFlags);
1621 inline var_types CastFromType();
1622 inline var_types& CastToType();
1624 // Returns "true" iff "*this" is an assignment (GT_ASG) tree that defines an SSA name (lcl = phi(...));
1627 // Returns "true" iff "*this" is a statement containing an assignment that defines an SSA name (lcl = phi(...));
1628 bool IsPhiDefnStmt();
1630 // Can't use an assignment operator, because we need the extra "comp" argument
1631 // (to provide the allocator necessary for the VarSet assignment).
1632 // TODO-Cleanup: Not really needed now, w/o liveset on tree nodes
1633 void CopyTo(class Compiler* comp, const GenTree& gt);
1635 // Like the above, excepts assumes copying from small node to small node.
1636 // (Following the code it replaces, it does *not* copy the GenTree fields,
1637 // which CopyTo does.)
1638 void CopyToSmall(const GenTree& gt);
1640 // Because of the fact that we hid the assignment operator of "BitSet" (in DEBUG),
1641 // we can't synthesize an assignment operator.
1642 // TODO-Cleanup: Could change this w/o liveset on tree nodes
1643 // (This is also necessary for the VTable trick.)
1646 // Returns the number of children of the current node.
1647 unsigned NumChildren();
1649 // Requires "childNum < NumChildren()". Returns the "n"th child of "this."
1650 GenTreePtr GetChild(unsigned childNum);
1652 // The maximum possible # of children of any node.
1653 static const int MAX_CHILDREN = 6;
1655 bool IsReuseRegVal() const
1657 // This can be extended to non-constant nodes, but not to local or indir nodes.
1658 if(OperIsConst() && ((gtFlags & GTF_REUSE_REG_VAL) != 0))
1664 void SetReuseRegVal()
1666 assert(OperIsConst());
1667 gtFlags |= GTF_REUSE_REG_VAL;
1669 void ResetReuseRegVal()
1671 assert(OperIsConst());
1672 gtFlags &= ~GTF_REUSE_REG_VAL;
1677 GenTree& operator=(const GenTree& gt) {
1678 assert(!"Don't copy");
1683 #if DEBUGGABLE_GENTREE
1684 // In DEBUG builds, add a dummy virtual method, to give the debugger run-time type information.
1685 virtual void DummyVirt() {}
1687 typedef void* VtablePtr;
1689 VtablePtr GetVtableForOper(genTreeOps oper);
1690 void SetVtableForOper(genTreeOps oper);
1692 static VtablePtr s_vtablesForOpers[GT_COUNT];
1693 static VtablePtr s_vtableForOp;
1694 #endif // DEBUGGABLE_GENTREE
1697 inline void* operator new(size_t sz, class Compiler*, genTreeOps oper);
1699 inline GenTree(genTreeOps oper, var_types type
1700 DEBUGARG(bool largeNode = false));
1704 /*****************************************************************************/
1705 // In the current design, we never instantiate GenTreeUnOp: it exists only to be
1706 // used as a base class. For unary operators, we instantiate GenTreeOp, with a NULL second
1707 // argument. We check that this is true dynamically. We could tighten this and get static
1708 // checking, but that would entail accessing the first child of a unary operator via something
1709 // like gtUnOp.gtOp1 instead of gtOp.gtOp1.
1710 struct GenTreeUnOp: public GenTree
1715 GenTreeUnOp(genTreeOps oper, var_types type
1716 DEBUGARG(bool largeNode = false)) :
1718 DEBUGARG(largeNode)),
1722 GenTreeUnOp(genTreeOps oper, var_types type, GenTreePtr op1
1723 DEBUGARG(bool largeNode = false)) :
1725 DEBUGARG(largeNode)),
1728 assert(op1 != nullptr || NullOp1Legal());
1729 if (op1 != nullptr) // Propagate effects flags from child.
1730 gtFlags |= op1->gtFlags & GTF_ALL_EFFECT;
1733 #if DEBUGGABLE_GENTREE
1734 GenTreeUnOp() : GenTree(), gtOp1(nullptr) {}
1738 struct GenTreeOp: public GenTreeUnOp
1742 GenTreeOp(genTreeOps oper, var_types type, GenTreePtr op1, GenTreePtr op2
1743 DEBUGARG(bool largeNode = false)) :
1744 GenTreeUnOp(oper, type, op1
1745 DEBUGARG(largeNode)),
1748 // comparisons are always integral types
1749 assert(!GenTree::OperIsCompare(oper) || varTypeIsIntegral(type));
1750 // Binary operators, with a few exceptions, require a non-nullptr
1752 assert(op2 != nullptr || NullOp2Legal());
1753 // Unary operators, on the other hand, require a null second argument.
1754 assert(!OperIsUnary(oper) || op2 == nullptr);
1755 // Propagate effects flags from child. (UnOp handled this for first child.)
1758 gtFlags |= op2->gtFlags & GTF_ALL_EFFECT;
1762 // A small set of types are unary operators with optional arguments. We use
1763 // this constructor to build those.
1764 GenTreeOp(genTreeOps oper, var_types type
1765 DEBUGARG(bool largeNode = false)) :
1766 GenTreeUnOp(oper, type
1767 DEBUGARG(largeNode)),
1770 // Unary operators with optional arguments:
1771 assert(oper == GT_NOP ||
1772 oper == GT_RETURN ||
1773 oper == GT_RETFILT ||
1777 #if DEBUGGABLE_GENTREE
1778 GenTreeOp() : GenTreeUnOp(), gtOp2(nullptr) {}
1783 struct GenTreeVal: public GenTree
1787 GenTreeVal(genTreeOps oper, var_types type, ssize_t val) :
1788 GenTree(oper, type),
1791 #if DEBUGGABLE_GENTREE
1792 GenTreeVal() : GenTree() {}
1796 struct GenTreeIntConCommon: public GenTree
1798 inline INT64 LngValue();
1799 inline void SetLngValue(INT64 val);
1800 inline ssize_t IconValue();
1801 inline void SetIconValue(ssize_t val);
1803 GenTreeIntConCommon(genTreeOps oper, var_types type
1804 DEBUGARG(bool largeNode = false)) :
1806 DEBUGARG(largeNode))
1811 return FitsInI32(IconValue());
1814 static bool FitsInI32(ssize_t val)
1816 #ifdef _TARGET_64BIT_
1817 return (int)val == val;
1823 bool ImmedValNeedsReloc(Compiler* comp);
1824 bool GenTreeIntConCommon::ImmedValCanBeFolded(Compiler* comp, genTreeOps op);
1826 #ifdef _TARGET_XARCH_
1827 bool FitsInAddrBase(Compiler* comp);
1828 bool AddrNeedsReloc(Compiler* comp);
1831 #if DEBUGGABLE_GENTREE
1832 GenTreeIntConCommon() : GenTree() {}
1836 // node representing a read from a physical register
1837 struct GenTreePhysReg: public GenTree
1839 // physregs need a field beyond gtRegNum because
1840 // gtRegNum indicates the destination (and can be changed)
1841 // whereas reg indicates the source
1843 GenTreePhysReg(regNumber r, var_types type=TYP_I_IMPL) :
1844 GenTree(GT_PHYSREG, type), gtSrcReg(r)
1847 #if DEBUGGABLE_GENTREE
1848 GenTreePhysReg() : GenTree() {}
1852 #ifndef LEGACY_BACKEND
1853 // gtJumpTable - Switch Jump Table
1855 // This node stores a DWORD constant that represents the
1856 // absolute address of a jump table for switches. The code
1857 // generator uses this table to code the destination for every case
1858 // in an array of addresses which starting position is stored in
1860 struct GenTreeJumpTable : public GenTreeIntConCommon
1862 ssize_t gtJumpTableAddr;
1864 GenTreeJumpTable(var_types type
1865 DEBUGARG(bool largeNode = false)) :
1866 GenTreeIntConCommon(GT_JMPTABLE, type
1867 DEBUGARG(largeNode))
1869 #if DEBUGGABLE_GENTREE
1870 GenTreeJumpTable() : GenTreeIntConCommon() {}
1873 #endif // !LEGACY_BACKEND
1875 /* gtIntCon -- integer constant (GT_CNS_INT) */
1876 struct GenTreeIntCon: public GenTreeIntConCommon
1879 * This is the GT_CNS_INT struct definition.
1880 * It's used to hold for both int constants and pointer handle constants.
1881 * For the 64-bit targets we will only use GT_CNS_INT as it used to represent all the possible sizes
1882 * For the 32-bit targets we use a GT_CNS_LNG to hold a 64-bit integer constant and GT_CNS_INT for all others.
1883 * In the future when we retarget the JIT for x86 we should consider eliminating GT_CNS_LNG
1885 ssize_t gtIconVal; // Must overlap and have the same offset with the gtIconVal field in GenTreeLngCon below.
1887 /* The InitializeArray intrinsic needs to go back to the newarray statement
1888 to find the class handle of the array so that we can get its size. However,
1889 in ngen mode, the handle in that statement does not correspond to the compile
1890 time handle (rather it lets you get a handle at run-time). In that case, we also
1891 need to store a compile time handle, which goes in this gtCompileTimeHandle field.
1893 ssize_t gtCompileTimeHandle;
1895 // TODO-Cleanup: It's not clear what characterizes the cases where the field
1896 // above is used. It may be that its uses and those of the "gtFieldSeq" field below
1897 // are mutually exclusive, and they could be put in a union. Or else we should separate
1898 // this type into three subtypes.
1900 // If this constant represents the offset of one or more fields, "gtFieldSeq" represents that
1901 // sequence of fields.
1902 FieldSeqNode* gtFieldSeq;
1904 #if defined (LATE_DISASM)
1906 /* If the constant was morphed from some other node,
1907 these fields enable us to get back to what the node
1908 originally represented. See use of gtNewIconHandleNode()
1913 /* Template struct - The significant field of the other
1914 * structs should overlap exactly with this struct
1919 unsigned gtIconHdl1;
1929 CORINFO_CLASS_HANDLE gtIconCls;
1935 GenTreeIntCon(var_types type, ssize_t value
1936 DEBUGARG(bool largeNode = false)) :
1937 GenTreeIntConCommon(GT_CNS_INT, type
1938 DEBUGARG(largeNode)),
1940 gtCompileTimeHandle(0),
1941 gtFieldSeq(FieldSeqStore::NotAField())
1944 GenTreeIntCon(var_types type, ssize_t value, FieldSeqNode* fields
1945 DEBUGARG(bool largeNode = false)) :
1946 GenTreeIntConCommon(GT_CNS_INT, type
1947 DEBUGARG(largeNode)),
1949 gtCompileTimeHandle(0),
1952 assert(fields != NULL);
1955 #ifdef _TARGET_64BIT_
1956 void TruncateOrSignExtend32()
1958 if (gtFlags & GTF_UNSIGNED)
1960 gtIconVal = UINT32(gtIconVal);
1964 gtIconVal = INT32(gtIconVal);
1967 #endif // _TARGET_64BIT_
1969 #if DEBUGGABLE_GENTREE
1970 GenTreeIntCon() : GenTreeIntConCommon() {}
1975 /* gtLngCon -- long constant (GT_CNS_LNG) */
1977 struct GenTreeLngCon: public GenTreeIntConCommon
1979 INT64 gtLconVal; // Must overlap and have the same offset with the gtIconVal field in GenTreeIntCon above.
1982 return (INT32)(gtLconVal & 0xffffffff);
1987 return (INT32)(gtLconVal >> 32);;
1990 GenTreeLngCon(INT64 val) :
1991 GenTreeIntConCommon(GT_CNS_NATIVELONG, TYP_LONG)
1992 { SetLngValue(val); }
1993 #if DEBUGGABLE_GENTREE
1994 GenTreeLngCon() : GenTreeIntConCommon() {}
1999 inline INT64 GenTreeIntConCommon::LngValue()
2001 #ifndef _TARGET_64BIT_
2002 assert(gtOper == GT_CNS_LNG);
2003 return AsLngCon()->gtLconVal;
2009 inline void GenTreeIntConCommon::SetLngValue(INT64 val)
2011 #ifndef _TARGET_64BIT_
2012 assert(gtOper == GT_CNS_LNG);
2013 AsLngCon()->gtLconVal = val;
2015 // Compile time asserts that these two fields overlap and have the same offsets: gtIconVal and gtLconVal
2016 C_ASSERT(offsetof(GenTreeLngCon, gtLconVal) == offsetof(GenTreeIntCon, gtIconVal));
2017 C_ASSERT(sizeof(AsLngCon()->gtLconVal) == sizeof(AsIntCon()->gtIconVal));
2019 SetIconValue(ssize_t(val));
2023 inline ssize_t GenTreeIntConCommon::IconValue()
2025 assert(gtOper == GT_CNS_INT); // We should never see a GT_CNS_LNG for a 64-bit target!
2026 return AsIntCon()->gtIconVal;
2029 inline void GenTreeIntConCommon::SetIconValue(ssize_t val)
2031 assert(gtOper == GT_CNS_INT); // We should never see a GT_CNS_LNG for a 64-bit target!
2032 AsIntCon()->gtIconVal = val;
2035 /* gtDblCon -- double constant (GT_CNS_DBL) */
2037 struct GenTreeDblCon: public GenTree
2041 bool isBitwiseEqual(GenTreeDblCon* other)
2043 unsigned __int64 bits = *(unsigned __int64 *)(>DconVal);
2044 unsigned __int64 otherBits = *(unsigned __int64 *)(&(other->gtDconVal));
2045 return (bits == otherBits);
2048 GenTreeDblCon(double val) :
2049 GenTree(GT_CNS_DBL, TYP_DOUBLE),
2052 #if DEBUGGABLE_GENTREE
2053 GenTreeDblCon() : GenTree() {}
2058 /* gtStrCon -- string constant (GT_CNS_STR) */
2060 struct GenTreeStrCon: public GenTree
2063 CORINFO_MODULE_HANDLE gtScpHnd;
2065 // Because this node can come from an inlined method we need to
2066 // have the scope handle, since it will become a helper call.
2067 GenTreeStrCon(unsigned sconCPX, CORINFO_MODULE_HANDLE mod
2068 DEBUGARG(bool largeNode = false)) :
2069 GenTree(GT_CNS_STR, TYP_REF
2070 DEBUGARG(largeNode)),
2071 gtSconCPX(sconCPX), gtScpHnd(mod)
2073 #if DEBUGGABLE_GENTREE
2074 GenTreeStrCon() : GenTree() {}
2078 // Common supertype of LCL_VAR, LCL_FLD, REG_VAR, PHI_ARG
2079 // This inherits from UnOp because lclvar stores are Unops
2080 struct GenTreeLclVarCommon: public GenTreeUnOp
2083 unsigned _gtLclNum; // The local number. An index into the Compiler::lvaTable array.
2084 unsigned _gtSsaNum; // The SSA number.
2087 GenTreeLclVarCommon(genTreeOps oper, var_types type, unsigned lclNum
2088 DEBUGARG(bool largeNode = false)) :
2089 GenTreeUnOp(oper, type
2090 DEBUGARG(largeNode))
2095 unsigned GetLclNum() const
2099 __declspec(property(get=GetLclNum)) unsigned gtLclNum;
2101 void SetLclNum(unsigned lclNum)
2104 _gtSsaNum = SsaConfig::RESERVED_SSA_NUM;
2107 unsigned GetSsaNum() const
2111 __declspec(property(get=GetSsaNum)) unsigned gtSsaNum;
2113 void SetSsaNum(unsigned ssaNum)
2120 return (gtSsaNum != SsaConfig::RESERVED_SSA_NUM);
2123 #if DEBUGGABLE_GENTREE
2124 GenTreeLclVarCommon() : GenTreeUnOp() {}
2128 // gtLclVar -- load/store/addr of local variable
2130 struct GenTreeLclVar: public GenTreeLclVarCommon
2132 IL_OFFSET gtLclILoffs; // instr offset of ref (only for debug info)
2134 GenTreeLclVar(var_types type, unsigned lclNum, IL_OFFSET ilOffs
2135 DEBUGARG(bool largeNode = false)) :
2136 GenTreeLclVarCommon(GT_LCL_VAR, type, lclNum
2137 DEBUGARG(largeNode)),
2141 GenTreeLclVar(genTreeOps oper, var_types type, unsigned lclNum, IL_OFFSET ilOffs
2142 DEBUGARG(bool largeNode = false)) :
2143 GenTreeLclVarCommon(oper, type, lclNum
2144 DEBUGARG(largeNode)),
2147 assert(OperIsLocal(oper) || OperIsLocalAddr(oper));
2150 #if DEBUGGABLE_GENTREE
2151 GenTreeLclVar() : GenTreeLclVarCommon() {}
2155 // gtLclFld -- load/store/addr of local variable field
2157 struct GenTreeLclFld: public GenTreeLclVarCommon
2159 unsigned gtLclOffs; // offset into the variable to access
2161 FieldSeqNode* gtFieldSeq; // This LclFld node represents some sequences of accesses.
2163 // old/FE style constructor where load/store/addr share same opcode
2164 GenTreeLclFld(var_types type, unsigned lclNum, unsigned lclOffs) :
2165 GenTreeLclVarCommon(GT_LCL_FLD, type, lclNum),
2166 gtLclOffs(lclOffs), gtFieldSeq(NULL)
2168 assert(sizeof(*this) <= s_gtNodeSizes[GT_LCL_FLD]);
2172 GenTreeLclFld(genTreeOps oper, var_types type, unsigned lclNum, unsigned lclOffs) :
2173 GenTreeLclVarCommon(oper, type, lclNum),
2174 gtLclOffs(lclOffs), gtFieldSeq(NULL)
2176 assert(sizeof(*this) <= s_gtNodeSizes[GT_LCL_FLD]);
2178 #if DEBUGGABLE_GENTREE
2179 GenTreeLclFld() : GenTreeLclVarCommon() {}
2183 struct GenTreeRegVar: public GenTreeLclVarCommon
2185 // TODO-Cleanup: Note that the base class GenTree already has a gtRegNum field.
2186 // It's not clear exactly why a GT_REG_VAR has a separate field. When
2187 // GT_REG_VAR is created, the two are identical. It appears that they may
2188 // or may not remain so. In particular, there is a comment in stackfp.cpp
2191 // There used to be an assertion: assert(src->gtRegNum == src->gtRegVar.gtRegNum, ...)
2192 // here, but there's actually no reason to assume that. AFAICT, for FP vars under stack FP,
2193 // src->gtRegVar.gtRegNum is the allocated stack pseudo-register, but src->gtRegNum is the
2194 // FP stack position into which that is loaded to represent a particular use of the variable.
2196 // It might be the case that only for stackfp do they ever differ.
2198 // The following might be possible: the GT_REG_VAR node has a last use prior to a complex
2199 // subtree being evaluated. It could then be spilled from the register. Later,
2200 // it could be unspilled into a different register, which would be recorded at
2201 // the unspill time in the GenTree::gtRegNum, whereas GenTreeRegVar::gtRegNum
2202 // is left alone. It's not clear why that is useful.
2204 // Assuming there is a particular use, like stack fp, that requires it, maybe we
2205 // can get rid of GT_REG_VAR and just leave it as GT_LCL_VAR, using the base class gtRegNum field.
2206 // If we need it for stackfp, we could add a GenTreeStackFPRegVar type, which carries both the
2207 // pieces of information, in a clearer and more specific way (in particular, with
2208 // a different member name).
2213 regNumberSmall _gtRegNum;
2217 GenTreeRegVar(var_types type, unsigned lclNum, regNumber regNum) :
2218 GenTreeLclVarCommon(GT_REG_VAR, type, lclNum
2224 // The register number is stored in a small format (8 bits), but the getters return and the setters take
2225 // a full-size (unsigned) format, to localize the casts here.
2227 __declspec(property(get=GetRegNum,put=SetRegNum))
2230 regNumber GetRegNum() const
2232 return (regNumber) _gtRegNum;
2235 void SetRegNum(regNumber reg)
2237 _gtRegNum = (regNumberSmall) reg;
2238 assert(_gtRegNum == reg);
2241 #if DEBUGGABLE_GENTREE
2242 GenTreeRegVar() : GenTreeLclVarCommon() {}
2246 /* gtCast -- conversion to a different type (GT_CAST) */
2248 struct GenTreeCast: public GenTreeOp
2250 GenTreePtr& CastOp() { return gtOp1; }
2251 var_types gtCastType;
2253 GenTreeCast(var_types type, GenTreePtr op, var_types castType
2254 DEBUGARG(bool largeNode = false)) :
2255 GenTreeOp(GT_CAST, type, op, nullptr
2256 DEBUGARG(largeNode)),
2257 gtCastType(castType)
2259 #if DEBUGGABLE_GENTREE
2260 GenTreeCast() : GenTreeOp() {}
2265 // GT_BOX nodes are place markers for boxed values. The "real" tree
2266 // for most purposes is in gtBoxOp.
2267 struct GenTreeBox: public GenTreeUnOp
2269 // An expanded helper call to implement the "box" if we don't get
2270 // rid of it any other way. Must be in same position as op1.
2272 GenTreePtr& BoxOp() { return gtOp1; }
2273 // This is the statement that contains the assignment tree when the node is an inlined GT_BOX on a value
2275 GenTreePtr gtAsgStmtWhenInlinedBoxValue;
2277 GenTreeBox(var_types type, GenTreePtr boxOp, GenTreePtr asgStmtWhenInlinedBoxValue) :
2278 GenTreeUnOp(GT_BOX, type, boxOp),
2279 gtAsgStmtWhenInlinedBoxValue(asgStmtWhenInlinedBoxValue)
2281 #if DEBUGGABLE_GENTREE
2282 GenTreeBox() : GenTreeUnOp() {}
2288 /* gtField -- data member ref (GT_FIELD) */
2290 struct GenTreeField: public GenTree
2292 GenTreePtr gtFldObj;
2293 CORINFO_FIELD_HANDLE gtFldHnd;
2295 bool gtFldMayOverlap;
2296 #ifdef FEATURE_READYTORUN_COMPILER
2297 CORINFO_CONST_LOOKUP gtFieldLookup;
2300 GenTreeField(var_types type) :
2301 GenTree(GT_FIELD, type
2304 gtFldMayOverlap = false;
2306 #if DEBUGGABLE_GENTREE
2307 GenTreeField() : GenTree() {}
2311 // Represents the Argument list of a call node, as a Lisp-style linked list.
2312 // (Originally I had hoped that this could have *only* the m_arg/m_rest fields, but it turns out
2313 // that enough of the GenTree mechanism is used that it makes sense just to make it a subtype. But
2314 // note that in many ways, this is *not* a "real" node of the tree, but rather a mechanism for
2315 // giving call nodes a flexible number of children. GenTreeArgListNodes never evaluate to registers,
2318 // Note that while this extends GenTreeOp, it is *not* an EXOP. We don't add any new fields, and one
2319 // is free to allocate a GenTreeOp of type GT_LIST. If you use this type, you get the convenient Current/Rest
2320 // method names for the arguments.
2321 struct GenTreeArgList: public GenTreeOp
2323 GenTreePtr& Current() { return gtOp1; }
2324 GenTreeArgList*& Rest() { assert(gtOp2 == NULL || gtOp2->OperGet() == GT_LIST); return *reinterpret_cast<GenTreeArgList**>(>Op2); }
2326 #if DEBUGGABLE_GENTREE
2327 GenTreeArgList() : GenTreeOp() {}
2330 GenTreeArgList(GenTreePtr arg) :
2331 GenTreeArgList(arg, nullptr) {}
2333 GenTreeArgList(GenTreePtr arg, GenTreeArgList* rest) :
2334 GenTreeOp(GT_LIST, TYP_VOID, arg, rest)
2336 // With structs passed in multiple args we could have an arg
2337 // GT_LIST containing a list of LCL_FLDs, see IsListForMultiRegArg()
2339 assert((arg != nullptr) && ((!arg->IsList()) || (arg->IsListForMultiRegArg())));
2340 gtFlags |= arg->gtFlags & GTF_ALL_EFFECT;
2343 gtFlags |= rest->gtFlags & GTF_ALL_EFFECT;
2348 // There was quite a bit of confusion in the code base about which of gtOp1 and gtOp2 was the
2349 // 'then' and 'else' clause of a colon node. Adding these accessors, while not enforcing anything,
2350 // at least *allows* the programmer to be obviously correct.
2351 // However, these conventions seem backward.
2352 // TODO-Cleanup: If we could get these accessors used everywhere, then we could switch them.
2353 struct GenTreeColon: public GenTreeOp
2355 GenTreePtr& ThenNode() { return gtOp2; }
2356 GenTreePtr& ElseNode() { return gtOp1; }
2358 #if DEBUGGABLE_GENTREE
2359 GenTreeColon() : GenTreeOp() {}
2362 GenTreeColon(var_types typ, GenTreePtr thenNode, GenTreePtr elseNode) :
2363 GenTreeOp(GT_COLON, typ, elseNode, thenNode)
2367 // gtCall -- method call (GT_CALL)
2368 typedef class fgArgInfo * fgArgInfoPtr;
2369 enum class InlineObservation;
2371 // Return type descriptor of a GT_CALL node.
2372 // x64 Unix, Arm64, Arm32 and x86 allow a value to be returned in multiple
2373 // registers. For such calls this struct provides the following info
2374 // on their return type
2375 // - type of value returned in each return register
2376 // - ABI return register numbers in which the value is returned
2377 // - count of return registers in which the value is returned
2379 // TODO-ARM: Update this to meet the needs of Arm64 and Arm32
2381 // TODO-AllArch: Right now it is used for describing multi-reg returned types.
2382 // Eventually we would want to use it for describing even single-reg
2383 // returned types (e.g. structs returned in single register x64/arm).
2384 // This would allow us not to lie or normalize single struct return
2385 // values in importer/morph.
2386 struct ReturnTypeDesc
2389 var_types m_regType[MAX_RET_REG_COUNT];
2401 // Initialize the return type descriptor given its type handle
2402 void InitializeReturnType(Compiler* comp, CORINFO_CLASS_HANDLE retClsHnd);
2404 // Reset type descriptor to defaults
2407 for (unsigned i = 0; i < MAX_RET_REG_COUNT; ++i)
2409 m_regType[i] = TYP_UNKNOWN;
2416 //--------------------------------------------------------------------------------------------
2417 // GetReturnRegCount: Get the count of return registers in which the return value is returned.
2423 // Count of return registers.
2424 // Returns 0 if the return type is not returned in registers.
2425 unsigned GetReturnRegCount() const
2430 for (unsigned i = 0; i < MAX_RET_REG_COUNT; ++i)
2432 if (m_regType[i] == TYP_UNKNOWN)
2441 // Any remaining elements in m_regTypes[] should also be TYP_UNKNOWN
2442 for (unsigned i = regCount+1; i < MAX_RET_REG_COUNT; ++i)
2444 assert(m_regType[i] == TYP_UNKNOWN);
2451 //-----------------------------------------------------------------------
2452 // IsMultiRegRetType: check whether the type is returned in multiple
2453 // return registers.
2459 // Returns true if the type is returned in multiple return registers.
2461 // Note that we only have to examine the first two values to determine this
2463 bool IsMultiRegRetType() const
2465 if (MAX_RET_REG_COUNT < 2)
2471 return ((m_regType[0] != TYP_UNKNOWN) &&
2472 (m_regType[1] != TYP_UNKNOWN));
2476 //--------------------------------------------------------------------------
2477 // GetReturnRegType: Get var_type of the return register specified by index.
2480 // index - Index of the return register.
2481 // First return register will have an index 0 and so on.
2484 // var_type of the return register specified by its index.
2485 // asserts if the index does not have a valid register return type.
2487 var_types GetReturnRegType(unsigned index)
2489 var_types result = m_regType[index];
2490 assert(result != TYP_UNKNOWN);
2495 // Get ith ABI return register
2496 regNumber GetABIReturnReg(unsigned idx);
2498 // Get reg mask of ABI return registers
2499 regMaskTP GetABIReturnRegs();
2502 struct GenTreeCall final : public GenTree
2504 GenTreePtr gtCallObjp; // The instance argument ('this' pointer)
2505 GenTreeArgList* gtCallArgs; // The list of arguments in original evaluation order
2506 GenTreeArgList* gtCallLateArgs; // On x86: The register arguments in an optimal order
2507 // On ARM/x64: - also includes any outgoing arg space arguments
2508 // - that were evaluated into a temp LclVar
2509 fgArgInfoPtr fgArgInfo;
2511 #if !FEATURE_FIXED_OUT_ARGS
2512 int regArgListCount;
2516 // TODO-Throughput: Revisit this (this used to be only defined if
2517 // FEATURE_FIXED_OUT_ARGS was enabled, so this makes GenTreeCall 4 bytes bigger on x86).
2518 CORINFO_SIG_INFO* callSig; // Used by tail calls and to register callsites with the EE
2520 #ifdef LEGACY_BACKEND
2521 regMaskTP gtCallRegUsedMask; // mask of registers used to pass parameters
2522 #endif // LEGACY_BACKEND
2524 // State required to support multi-reg returning call nodes.
2525 // For now it is enabled only for x64 unix.
2527 // TODO-AllArch: enable for all call nodes to unify single-reg and multi-reg returns.
2528 #if FEATURE_MULTIREG_RET
2529 ReturnTypeDesc gtReturnTypeDesc;
2531 // gtRegNum would always be the first return reg.
2532 // The following array holds the other reg numbers of multi-reg return.
2533 regNumber gtOtherRegs[MAX_RET_REG_COUNT - 1];
2535 // GTF_SPILL or GTF_SPILLED flag on a multi-reg call node indicates that one or
2536 // more of its result regs are in that state. The spill flag of each of the
2537 // return register is stored in the below array.
2538 unsigned gtSpillFlags[MAX_RET_REG_COUNT];
2541 //-----------------------------------------------------------------------
2542 // GetReturnTypeDesc: get the type descriptor of return value of the call
2548 // Type descriptor of the value returned by call
2551 // Right now implemented only for x64 unix and yet to be
2552 // implemented for other multi-reg target arch (Arm64/Arm32/x86).
2554 // TODO-AllArch: enable for all call nodes to unify single-reg and multi-reg returns.
2555 ReturnTypeDesc* GetReturnTypeDesc()
2557 #if FEATURE_MULTIREG_RET
2558 return >ReturnTypeDesc;
2564 //---------------------------------------------------------------------------
2565 // GetRegNumByIdx: get ith return register allocated to this call node.
2568 // idx - index of the return register
2571 // Return regNumber of ith return register of call node.
2572 // Returns REG_NA if there is no valid return register for the given index.
2574 regNumber GetRegNumByIdx(unsigned idx) const
2576 assert(idx < MAX_RET_REG_COUNT);
2583 #if FEATURE_MULTIREG_RET
2584 return gtOtherRegs[idx-1];
2590 //----------------------------------------------------------------------
2591 // SetRegNumByIdx: set ith return register of this call node
2595 // idx - index of the return register
2600 void SetRegNumByIdx(regNumber reg, unsigned idx)
2602 assert(idx < MAX_RET_REG_COUNT);
2608 #if FEATURE_MULTIREG_RET
2611 gtOtherRegs[idx - 1] = reg;
2612 assert(gtOtherRegs[idx - 1] == reg);
2619 //----------------------------------------------------------------------------
2620 // ClearOtherRegs: clear multi-reg state to indicate no regs are allocated
2628 void ClearOtherRegs()
2630 #if FEATURE_MULTIREG_RET
2631 for (unsigned i = 0; i < MAX_RET_REG_COUNT - 1; ++i)
2633 gtOtherRegs[i] = REG_NA;
2638 //----------------------------------------------------------------------------
2639 // CopyOtherRegs: copy multi-reg state from the given call node to this node
2642 // fromCall - GenTreeCall node from which to copy multi-reg state
2647 void CopyOtherRegs(GenTreeCall* fromCall)
2649 #if FEATURE_MULTIREG_RET
2650 for (unsigned i = 0; i < MAX_RET_REG_COUNT - 1; ++i)
2652 this->gtOtherRegs[i] = fromCall->gtOtherRegs[i];
2657 // Get reg mask of all the valid registers of gtOtherRegs array
2658 regMaskTP GetOtherRegMask() const;
2660 //----------------------------------------------------------------------
2661 // GetRegSpillFlagByIdx: get spill flag associated with the return register
2662 // specified by its index.
2665 // idx - Position or index of the return register
2668 // Returns GTF_* flags associated with.
2669 unsigned GetRegSpillFlagByIdx(unsigned idx) const
2671 assert(idx < MAX_RET_REG_COUNT);
2673 #if FEATURE_MULTIREG_RET
2674 return gtSpillFlags[idx];
2676 assert(!"unreached");
2681 //----------------------------------------------------------------------
2682 // SetRegSpillFlagByIdx: set spill flags for the return register
2683 // specified by its index.
2686 // flags - GTF_* flags
2687 // idx - Position or index of the return register
2691 void SetRegSpillFlagByIdx(unsigned flags, unsigned idx)
2693 assert(idx < MAX_RET_REG_COUNT);
2695 #if FEATURE_MULTIREG_RET
2696 gtSpillFlags[idx] = flags;
2702 //-------------------------------------------------------------------
2703 // clearOtherRegFlags: clear GTF_* flags associated with gtOtherRegs
2710 void ClearOtherRegFlags()
2712 #if FEATURE_MULTIREG_RET
2713 for (unsigned i = 0; i < MAX_RET_REG_COUNT; ++i)
2715 gtSpillFlags[i] = 0;
2720 //-------------------------------------------------------------------------
2721 // CopyOtherRegFlags: copy GTF_* flags associated with gtOtherRegs from
2722 // the given call node.
2725 // fromCall - GenTreeCall node from which to copy
2730 void CopyOtherRegFlags(GenTreeCall* fromCall)
2732 #if FEATURE_MULTIREG_RET
2733 for (unsigned i = 0; i < MAX_RET_REG_COUNT; ++i)
2735 this->gtSpillFlags[i] = fromCall->gtSpillFlags[i];
2740 #define GTF_CALL_M_EXPLICIT_TAILCALL 0x0001 // GT_CALL -- the call is "tail" prefixed and importer has performed tail call checks
2741 #define GTF_CALL_M_TAILCALL 0x0002 // GT_CALL -- the call is a tailcall
2742 #define GTF_CALL_M_VARARGS 0x0004 // GT_CALL -- the call uses varargs ABI
2743 #define GTF_CALL_M_RETBUFFARG 0x0008 // GT_CALL -- first parameter is the return buffer argument
2744 #define GTF_CALL_M_DELEGATE_INV 0x0010 // GT_CALL -- call to Delegate.Invoke
2745 #define GTF_CALL_M_NOGCCHECK 0x0020 // GT_CALL -- not a call for computing full interruptability
2746 #define GTF_CALL_M_SPECIAL_INTRINSIC 0x0040 // GT_CALL -- function that could be optimized as an intrinsic
2747 // in special cases. Used to optimize fast way out in morphing
2748 #define GTF_CALL_M_UNMGD_THISCALL 0x0080 // "this" pointer (first argument) should be enregistered (only for GTF_CALL_UNMANAGED)
2749 #define GTF_CALL_M_VIRTSTUB_REL_INDIRECT 0x0080 // the virtstub is indirected through a relative address (only for GTF_CALL_VIRT_STUB)
2750 #define GTF_CALL_M_NONVIRT_SAME_THIS 0x0080 // callee "this" pointer is equal to caller this pointer (only for GTF_CALL_NONVIRT)
2751 #define GTF_CALL_M_FRAME_VAR_DEATH 0x0100 // GT_CALL -- the compLvFrameListRoot variable dies here (last use)
2753 #ifndef LEGACY_BACKEND
2754 #define GTF_CALL_M_TAILCALL_VIA_HELPER 0x0200 // GT_CALL -- call is a tail call dispatched via tail call JIT helper.
2755 #endif // !LEGACY_BACKEND
2757 #if FEATURE_TAILCALL_OPT
2758 #define GTF_CALL_M_IMPLICIT_TAILCALL 0x0400 // GT_CALL -- call is an opportunistic tail call and importer has performed tail call checks
2759 #define GTF_CALL_M_TAILCALL_TO_LOOP 0x0800 // GT_CALL -- call is a fast recursive tail call that can be converted into a loop
2762 #define GTF_CALL_M_PINVOKE 0x1000 // GT_CALL -- call is a pinvoke. This mirrors VM flag CORINFO_FLG_PINVOKE.
2763 // A call marked as Pinvoke is not necessarily a GT_CALL_UNMANAGED. For e.g.
2764 // an IL Stub dynamically generated for a PInvoke declaration is flagged as
2765 // a Pinvoke but not as an unmanaged call. See impCheckForPInvokeCall() to
2766 // know when these flags are set.
2768 #define GTF_CALL_M_R2R_REL_INDIRECT 0x2000 // GT_CALL -- ready to run call is indirected through a relative address
2770 bool IsUnmanaged() const { return (gtFlags & GTF_CALL_UNMANAGED) != 0; }
2771 bool NeedsNullCheck() const { return (gtFlags & GTF_CALL_NULLCHECK) != 0; }
2772 bool CallerPop() const { return (gtFlags & GTF_CALL_POP_ARGS) != 0; }
2773 bool IsVirtual() const { return (gtFlags & GTF_CALL_VIRT_KIND_MASK) != GTF_CALL_NONVIRT; }
2774 bool IsVirtualStub() const { return (gtFlags & GTF_CALL_VIRT_KIND_MASK) == GTF_CALL_VIRT_STUB; }
2775 bool IsVirtualVtable() const { return (gtFlags & GTF_CALL_VIRT_KIND_MASK) == GTF_CALL_VIRT_VTABLE; }
2776 bool IsInlineCandidate() const { return (gtFlags & GTF_CALL_INLINE_CANDIDATE) != 0; }
2778 #ifndef LEGACY_BACKEND
2779 bool HasNonStandardAddedArgs(Compiler* compiler) const;
2780 int GetNonStandardAddedArgCount(Compiler* compiler) const;
2781 #endif // !LEGACY_BACKEND
2783 // Returns true if this call uses a retBuf argument and its calling convention
2784 bool HasRetBufArg() const
2786 return (gtCallMoreFlags & GTF_CALL_M_RETBUFFARG) != 0;
2789 //-------------------------------------------------------------------------
2790 // TreatAsHasRetBufArg:
2793 // compiler, the compiler instance so that we can call eeGetHelperNum
2796 // Returns true if we treat the call as if it has a retBuf argument
2797 // This method may actually have a retBuf argument
2798 // or it could be a JIT helper that we are still transforming during
2799 // the importer phase.
2802 // On ARM64 marking the method with the GTF_CALL_M_RETBUFFARG flag
2803 // will make HasRetBufArg() return true, but will also force the
2804 // use of register x8 to pass the RetBuf argument.
2806 bool TreatAsHasRetBufArg(Compiler* compiler) const;
2808 //-----------------------------------------------------------------------------------------
2809 // HasMultiRegRetVal: whether the call node returns its value in multiple return registers.
2815 // True if the call is returning a multi-reg return value. False otherwise.
2818 // This is implemented only for x64 Unix and yet to be implemented for
2819 // other multi-reg return target arch (arm64/arm32/x86).
2821 // TODO-ARM: Implement this routine for Arm64 and Arm32
2822 bool HasMultiRegRetVal() const
2824 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
2825 return varTypeIsStruct(gtType) && !HasRetBufArg();
2826 #elif defined(_TARGET_X86_) && !defined(LEGACY_BACKEND)
2827 // LEGACY_BACKEND does not use multi reg returns for calls with long return types
2828 return varTypeIsLong(gtType);
2834 // Returns true if VM has flagged this method as CORINFO_FLG_PINVOKE.
2835 bool IsPInvoke() const { return (gtCallMoreFlags & GTF_CALL_M_PINVOKE) != 0; }
2837 // Note that the distinction of whether tail prefixed or an implicit tail call
2838 // is maintained on a call node till fgMorphCall() after which it will be
2839 // either a tail call (i.e. IsTailCall() is true) or a non-tail call.
2840 bool IsTailPrefixedCall() const { return (gtCallMoreFlags & GTF_CALL_M_EXPLICIT_TAILCALL) != 0; }
2842 // This method returning "true" implies that tail call flowgraph morhphing has
2843 // performed final checks and committed to making a tail call.
2844 bool IsTailCall() const { return (gtCallMoreFlags & GTF_CALL_M_TAILCALL) != 0; }
2846 // This method returning "true" implies that importer has performed tail call checks
2847 // and providing a hint that this can be converted to a tail call.
2848 bool CanTailCall() const { return IsTailPrefixedCall() || IsImplicitTailCall(); }
2850 #ifndef LEGACY_BACKEND
2851 bool IsTailCallViaHelper() const { return IsTailCall() && (gtCallMoreFlags & GTF_CALL_M_TAILCALL_VIA_HELPER); }
2852 #else // LEGACY_BACKEND
2853 bool IsTailCallViaHelper() const { return true; }
2854 #endif // LEGACY_BACKEND
2856 #if FEATURE_FASTTAILCALL
2857 bool IsFastTailCall() const { return IsTailCall() && !(gtCallMoreFlags & GTF_CALL_M_TAILCALL_VIA_HELPER); }
2858 #else // !FEATURE_FASTTAILCALL
2859 bool IsFastTailCall() const { return false; }
2860 #endif // !FEATURE_FASTTAILCALL
2862 #if FEATURE_TAILCALL_OPT
2863 // Returns true if this is marked for opportunistic tail calling.
2864 // That is, can be tail called though not explicitly prefixed with "tail" prefix.
2865 bool IsImplicitTailCall() const { return (gtCallMoreFlags & GTF_CALL_M_IMPLICIT_TAILCALL) != 0; }
2866 bool IsTailCallConvertibleToLoop() const { return (gtCallMoreFlags & GTF_CALL_M_TAILCALL_TO_LOOP) != 0; }
2867 #else // !FEATURE_TAILCALL_OPT
2868 bool IsImplicitTailCall() const { return false; }
2869 bool IsTailCallConvertibleToLoop() const { return false; }
2870 #endif // !FEATURE_TAILCALL_OPT
2872 bool IsSameThis() const { return (gtCallMoreFlags & GTF_CALL_M_NONVIRT_SAME_THIS) != 0; }
2873 bool IsDelegateInvoke() const { return (gtCallMoreFlags & GTF_CALL_M_DELEGATE_INV) != 0; }
2874 bool IsVirtualStubRelativeIndir() const { return (gtCallMoreFlags & GTF_CALL_M_VIRTSTUB_REL_INDIRECT) != 0; }
2876 #ifdef FEATURE_READYTORUN_COMPILER
2877 bool IsR2RRelativeIndir() const { return (gtCallMoreFlags & GTF_CALL_M_R2R_REL_INDIRECT) != 0; }
2878 void setEntryPoint(CORINFO_CONST_LOOKUP entryPoint)
2880 gtEntryPoint = entryPoint;
2881 if (gtEntryPoint.accessType == IAT_PVALUE)
2883 gtCallMoreFlags |= GTF_CALL_M_R2R_REL_INDIRECT;
2886 #endif // FEATURE_READYTORUN_COMPILER
2888 bool IsVarargs() const { return (gtCallMoreFlags & GTF_CALL_M_VARARGS) != 0; }
2890 unsigned short gtCallMoreFlags; // in addition to gtFlags
2892 unsigned char gtCallType :3; // value from the gtCallTypes enumeration
2893 unsigned char gtReturnType :5; // exact return type
2895 CORINFO_CLASS_HANDLE gtRetClsHnd; // The return type handle of the call if it is a struct; always available
2899 // only used for CALLI unmanaged calls (CT_INDIRECT)
2900 GenTreePtr gtCallCookie;
2901 // gtInlineCandidateInfo is only used when inlining methods
2902 InlineCandidateInfo* gtInlineCandidateInfo;
2903 void* gtStubCallStubAddr; // GTF_CALL_VIRT_STUB - these are never inlined
2904 CORINFO_GENERIC_HANDLE compileTimeHelperArgumentHandle; // Used to track type handle argument of dynamic helpers
2905 void* gtDirectCallAddress; // Used to pass direct call address between lower and codegen
2908 // expression evaluated after args are placed which determines the control target
2909 GenTree * gtControlExpr;
2913 CORINFO_METHOD_HANDLE gtCallMethHnd; // CT_USER_FUNC
2914 GenTreePtr gtCallAddr; // CT_INDIRECT
2917 #ifdef FEATURE_READYTORUN_COMPILER
2918 // Call target lookup info for method call from a Ready To Run module
2919 CORINFO_CONST_LOOKUP gtEntryPoint;
2922 #if defined(DEBUG) || defined(INLINE_DATA)
2923 // For non-inline candidates, track the first observation
2924 // that blocks candidacy.
2925 InlineObservation gtInlineObservation;
2927 // IL offset of the call wrt its parent method.
2928 IL_OFFSET gtRawILOffset;
2929 #endif // defined(DEBUG) || defined(INLINE_DATA)
2931 bool IsHelperCall() const
2933 return gtCallType == CT_HELPER;
2936 bool IsHelperCall(CORINFO_METHOD_HANDLE callMethHnd) const
2938 return IsHelperCall() && (callMethHnd == gtCallMethHnd);
2941 bool IsHelperCall(Compiler* compiler, unsigned helper) const;
2943 GenTreeCall(var_types type) :
2944 GenTree(GT_CALL, type)
2947 #if DEBUGGABLE_GENTREE
2948 GenTreeCall() : GenTree()
2954 struct GenTreeCmpXchg: public GenTree
2956 GenTreePtr gtOpLocation;
2957 GenTreePtr gtOpValue;
2958 GenTreePtr gtOpComparand;
2960 GenTreeCmpXchg(var_types type, GenTreePtr loc, GenTreePtr val, GenTreePtr comparand) :
2961 GenTree(GT_CMPXCHG, type),
2962 gtOpLocation(loc), gtOpValue(val), gtOpComparand(comparand)
2964 // There's no reason to do a compare-exchange on a local location, so we'll assume that all of these
2965 // have global effects.
2966 gtFlags |= GTF_GLOB_EFFECT;
2968 #if DEBUGGABLE_GENTREE
2969 GenTreeCmpXchg() : GenTree() {}
2975 struct GenTreeFptrVal: public GenTree
2977 CORINFO_METHOD_HANDLE gtFptrMethod;
2979 #ifdef FEATURE_READYTORUN_COMPILER
2980 CORINFO_CONST_LOOKUP gtEntryPoint;
2981 CORINFO_RESOLVED_TOKEN* gtLdftnResolvedToken;
2984 GenTreeFptrVal(var_types type, CORINFO_METHOD_HANDLE meth) :
2985 GenTree(GT_FTN_ADDR, type),
2988 #if DEBUGGABLE_GENTREE
2989 GenTreeFptrVal() : GenTree() {}
2994 struct GenTreeQmark : public GenTreeOp
2996 // Livesets on entry to then and else subtrees
2997 VARSET_TP gtThenLiveSet;
2998 VARSET_TP gtElseLiveSet;
3000 // The "Compiler*" argument is not a DEBUGARG here because we use it to keep track of the set of
3001 // (possible) QMark nodes.
3002 GenTreeQmark(var_types type, GenTreePtr cond, GenTreePtr colonOp, class Compiler* comp);
3004 #if DEBUGGABLE_GENTREE
3005 GenTreeQmark() : GenTreeOp(GT_QMARK, TYP_INT, NULL, NULL) {}
3009 /* gtIntrinsic -- intrinsic (possibly-binary op [NULL op2 is allowed] with an additional field) */
3011 struct GenTreeIntrinsic: public GenTreeOp
3013 CorInfoIntrinsics gtIntrinsicId;
3014 CORINFO_METHOD_HANDLE gtMethodHandle; // Method handle of the method which is treated as an intrinsic.
3016 #ifdef FEATURE_READYTORUN_COMPILER
3017 // Call target lookup info for method call from a Ready To Run module
3018 CORINFO_CONST_LOOKUP gtEntryPoint;
3021 GenTreeIntrinsic(var_types type, GenTreePtr op1, CorInfoIntrinsics intrinsicId, CORINFO_METHOD_HANDLE methodHandle) :
3022 GenTreeOp(GT_INTRINSIC, type, op1, NULL),
3023 gtIntrinsicId(intrinsicId),
3024 gtMethodHandle(methodHandle)
3027 GenTreeIntrinsic(var_types type, GenTreePtr op1, GenTreePtr op2, CorInfoIntrinsics intrinsicId, CORINFO_METHOD_HANDLE methodHandle) :
3028 GenTreeOp(GT_INTRINSIC, type, op1, op2),
3029 gtIntrinsicId(intrinsicId),
3030 gtMethodHandle(methodHandle)
3033 #if DEBUGGABLE_GENTREE
3034 GenTreeIntrinsic() : GenTreeOp() {}
3040 /* gtSIMD -- SIMD intrinsic (possibly-binary op [NULL op2 is allowed] with additional fields) */
3041 struct GenTreeSIMD: public GenTreeOp
3043 SIMDIntrinsicID gtSIMDIntrinsicID; // operation Id
3044 var_types gtSIMDBaseType; // SIMD vector base type
3045 unsigned gtSIMDSize; // SIMD vector size in bytes
3047 GenTreeSIMD(var_types type, GenTreePtr op1, SIMDIntrinsicID simdIntrinsicID, var_types baseType, unsigned size) :
3048 GenTreeOp(GT_SIMD, type, op1, nullptr),
3049 gtSIMDIntrinsicID(simdIntrinsicID),
3050 gtSIMDBaseType(baseType),
3054 GenTreeSIMD(var_types type, GenTreePtr op1, GenTreePtr op2, SIMDIntrinsicID simdIntrinsicID, var_types baseType, unsigned size) :
3055 GenTreeOp(GT_SIMD, type, op1, op2),
3056 gtSIMDIntrinsicID(simdIntrinsicID),
3057 gtSIMDBaseType(baseType),
3061 #if DEBUGGABLE_GENTREE
3062 GenTreeSIMD() : GenTreeOp() {}
3065 #endif // FEATURE_SIMD
3067 /* gtIndex -- array access */
3069 struct GenTreeIndex: public GenTreeOp
3071 GenTreePtr& Arr() { return gtOp1; }
3072 GenTreePtr& Index() { return gtOp2; }
3074 unsigned gtIndElemSize; // size of elements in the array
3075 CORINFO_CLASS_HANDLE gtStructElemClass; // If the element type is a struct, this is the struct type.
3077 GenTreeIndex(var_types type, GenTreePtr arr, GenTreePtr ind, unsigned indElemSize) :
3078 GenTreeOp(GT_INDEX, type, arr, ind),
3079 gtIndElemSize(indElemSize),
3080 gtStructElemClass(nullptr) // We always initialize this after construction.
3083 if (JitConfig.JitSkipArrayBoundCheck() == 1)
3085 // Skip bounds check
3091 gtFlags |= GTF_INX_RNGCHK;
3094 if (type == TYP_REF)
3096 gtFlags |= GTF_INX_REFARR_LAYOUT;
3099 gtFlags |= GTF_EXCEPT|GTF_GLOB_REF;
3101 #if DEBUGGABLE_GENTREE
3102 GenTreeIndex() : GenTreeOp() {}
3106 /* gtArrLen -- array length (GT_ARR_LENGTH)
3107 GT_ARR_LENGTH is used for "arr.length" */
3109 struct GenTreeArrLen: public GenTreeUnOp
3111 GenTreePtr& ArrRef() { return gtOp1; } // the array address node
3113 int gtArrLenOffset; // constant to add to "gtArrRef" to get the address of the array length.
3116 inline int ArrLenOffset() {
3117 return gtArrLenOffset;
3120 GenTreeArrLen(var_types type, GenTreePtr arrRef, int lenOffset) :
3121 GenTreeUnOp(GT_ARR_LENGTH, type, arrRef),
3122 gtArrLenOffset(lenOffset)
3125 #if DEBUGGABLE_GENTREE
3126 GenTreeArrLen() : GenTreeUnOp() {}
3131 // - a comparison value (generally an array length),
3132 // - an index value, and
3133 // - the label to jump to if the index is out of range.
3134 // - the "kind" of the throw block to branch to on failure
3135 // It generates no result.
3137 struct GenTreeBoundsChk: public GenTree
3139 GenTreePtr gtArrLen; // An expression for the length of the array being indexed.
3140 GenTreePtr gtIndex; // The index expression.
3142 GenTreePtr gtIndRngFailBB; // Label to jump to for array-index-out-of-range
3143 SpecialCodeKind gtThrowKind; // Kind of throw block to branch to on failure
3145 /* Only out-of-ranges at same stack depth can jump to the same label (finding return address is easier)
3146 For delayed calling of fgSetRngChkTarget() so that the
3147 optimizer has a chance of eliminating some of the rng checks */
3148 unsigned gtStkDepth;
3150 GenTreeBoundsChk(genTreeOps oper, var_types type, GenTreePtr arrLen, GenTreePtr index, SpecialCodeKind kind) :
3151 GenTree(oper, type),
3152 gtArrLen(arrLen), gtIndex(index),
3153 gtIndRngFailBB(NULL),
3157 // Effects flags propagate upwards.
3158 gtFlags |= (arrLen->gtFlags & GTF_ALL_EFFECT);
3159 gtFlags |= GTF_EXCEPT;
3161 #if DEBUGGABLE_GENTREE
3162 GenTreeBoundsChk() : GenTree() {}
3165 // If the gtArrLen is really an array length, returns array reference, else "NULL".
3166 GenTreePtr GetArray()
3168 if (gtArrLen->OperGet() == GT_ARR_LENGTH)
3170 return gtArrLen->gtArrLen.ArrRef();
3179 // gtArrElem -- general array element (GT_ARR_ELEM), for non "SZ_ARRAYS"
3180 // -- multidimensional arrays, or 1-d arrays with non-zero lower bounds.
3182 struct GenTreeArrElem: public GenTree
3184 GenTreePtr gtArrObj;
3186 #define GT_ARR_MAX_RANK 3
3187 GenTreePtr gtArrInds[GT_ARR_MAX_RANK]; // Indices
3188 unsigned char gtArrRank; // Rank of the array
3190 unsigned char gtArrElemSize; // !!! Caution, this is an "unsigned char", it is used only
3191 // on the optimization path of array intrisics.
3192 // It stores the size of array elements WHEN it can fit
3193 // into an "unsigned char".
3194 // This has caused VSW 571394.
3195 var_types gtArrElemType; // The array element type
3197 // Requires that "inds" is a pointer to an array of "rank" GenTreePtrs for the indices.
3198 GenTreeArrElem(var_types type, GenTreePtr arr, unsigned char rank, unsigned char elemSize, var_types elemType, GenTreePtr* inds) :
3199 GenTree(GT_ARR_ELEM, type),
3200 gtArrObj(arr), gtArrRank(rank), gtArrElemSize(elemSize), gtArrElemType(elemType)
3202 for (unsigned char i = 0; i < rank; i++) gtArrInds[i] = inds[i];
3203 gtFlags |= GTF_EXCEPT;
3205 #if DEBUGGABLE_GENTREE
3206 GenTreeArrElem() : GenTree() {}
3210 //--------------------------------------------
3212 // GenTreeArrIndex (gtArrIndex): Expression to bounds-check the index for one dimension of a
3213 // multi-dimensional or non-zero-based array., and compute the effective index
3214 // (i.e. subtracting the lower bound).
3217 // This node is similar in some ways to GenTreeBoundsChk, which ONLY performs the check.
3218 // The reason that this node incorporates the check into the effective index computation is
3219 // to avoid duplicating the codegen, as the effective index is required to compute the
3221 // TODO-CQ: Enable optimization of the lower bound and length by replacing this:
3224 // +--* ArrIndex[i, ]
3225 // with something like:
3227 // /--* ArrLowerBound[i, ]
3229 // +--* ArrLen[i, ] (either generalize GT_ARR_LENGTH or add a new node)
3231 // +--* ArrIndex[i, ]
3232 // Which could, for example, be optimized to the following when known to be within bounds:
3233 // /--* TempForLowerBoundDim0
3237 struct GenTreeArrIndex: public GenTreeOp
3239 // The array object - may be any expression producing an Array reference, but is likely to be a lclVar.
3240 GenTreePtr& ArrObj() { return gtOp1; }
3241 // The index expression - may be any integral expression.
3242 GenTreePtr& IndexExpr() { return gtOp2; }
3243 unsigned char gtCurrDim; // The current dimension
3244 unsigned char gtArrRank; // Rank of the array
3245 var_types gtArrElemType; // The array element type
3247 GenTreeArrIndex(var_types type, GenTreePtr arrObj, GenTreePtr indexExpr,
3248 unsigned char currDim, unsigned char arrRank, var_types elemType) :
3249 GenTreeOp(GT_ARR_INDEX, type, arrObj, indexExpr),
3250 gtCurrDim(currDim), gtArrRank(arrRank), gtArrElemType(elemType)
3252 gtFlags |= GTF_EXCEPT;
3254 #if DEBUGGABLE_GENTREE
3257 // Used only for GenTree::GetVtableForOper()
3258 GenTreeArrIndex() : GenTreeOp() {}
3262 // Represents either an InitBlk, InitObj, CpBlk or CpObj
3264 struct GenTreeBlkOp : public GenTreeOp
3267 // The destination for the CpBlk/CpObj/InitBlk/InitObj to copy bits to
3269 assert(gtOp1->gtOper == GT_LIST);
3270 return gtOp1->gtOp.gtOp1;
3273 // True if this BlkOpNode is a volatile memory operation.
3274 bool IsVolatile() const { return (gtFlags & GTF_BLK_VOLATILE) != 0; }
3276 // Instruction selection: during codegen time, what code sequence we will be using
3277 // to encode this operation.
3286 bool gtBlkOpGcUnsafe;
3288 GenTreeBlkOp(genTreeOps oper) :
3289 GenTreeOp(oper, TYP_VOID DEBUGARG(true)),
3290 gtBlkOpKind(BlkOpKindInvalid),
3291 gtBlkOpGcUnsafe(false)
3293 assert(OperIsBlkOp(oper));
3296 #if DEBUGGABLE_GENTREE
3299 GenTreeBlkOp() : GenTreeOp(){}
3300 #endif // DEBUGGABLE_GENTREE
3303 // gtObj -- 'object' (GT_OBJ). */
3305 struct GenTreeObj: public GenTreeUnOp
3307 // The address of the block.
3308 GenTreePtr& Addr() { return gtOp1; }
3310 CORINFO_CLASS_HANDLE gtClass; // the class of the object
3312 GenTreeObj(var_types type, GenTreePtr addr, CORINFO_CLASS_HANDLE cls) :
3313 GenTreeUnOp(GT_OBJ, type, addr),
3316 gtFlags |= GTF_GLOB_REF; // An Obj is always a global reference.
3319 #if DEBUGGABLE_GENTREE
3320 GenTreeObj() : GenTreeUnOp() {}
3324 // Represents a CpObj MSIL Node.
3325 struct GenTreeCpObj : public GenTreeBlkOp
3328 // The source for the CpBlk/CpObj to copy bits from
3329 GenTreePtr Source() {
3330 assert(gtOper == GT_COPYOBJ && gtOp1->gtOper == GT_LIST);
3331 return gtOp1->gtOp.gtOp2;
3334 // In the case of CopyObj, this is the class token that represents the type that is being copied.
3335 GenTreePtr ClsTok() { return gtOp2; }
3337 // If non-null, this array represents the gc-layout of the class that is being copied
3341 // If non-zero, this is the number of slots in the class layout that
3342 // contain gc-pointers.
3343 unsigned gtGcPtrCount;
3345 // If non-zero, the number of pointer-sized slots that constitutes the class token in CpObj.
3348 GenTreeCpObj(unsigned gcPtrCount, unsigned gtSlots, BYTE* gtGcPtrs) :
3349 GenTreeBlkOp(GT_COPYOBJ),
3351 gtGcPtrCount(gcPtrCount),
3354 #if DEBUGGABLE_GENTREE
3357 GenTreeCpObj() : GenTreeBlkOp(),
3361 #endif // DEBUGGABLE_GENTREE
3364 // Represents either an InitBlk or InitObj MSIL OpCode.
3365 struct GenTreeInitBlk : public GenTreeBlkOp
3369 // The value used to fill the destination buffer.
3370 GenTreePtr InitVal() { assert(gtOp1->gtOper == GT_LIST);
3371 return gtOp1->gtOp.gtOp2; }
3373 // The size of the buffer to be copied.
3374 GenTreePtr Size() { return gtOp2; }
3376 GenTreeInitBlk() : GenTreeBlkOp(GT_INITBLK){}
3378 #if DEBUGGABLE_GENTREE
3381 #endif // DEBUGGABLE_GENTREE
3384 // Represents a CpBlk or CpObj with no GC-pointers MSIL OpCode.
3385 struct GenTreeCpBlk : public GenTreeBlkOp
3389 // The value used to fill the destination buffer.
3390 // The source for the CpBlk/CpObj to copy bits from
3391 GenTreePtr Source() { assert(gtOp1->gtOper == GT_LIST);
3392 return gtOp1->gtOp.gtOp2; }
3394 // The size of the buffer to be copied.
3395 GenTreePtr Size() { return gtOp2; }
3397 GenTreeCpBlk() : GenTreeBlkOp(GT_COPYBLK){}
3399 #if DEBUGGABLE_GENTREE
3402 #endif // DEBUGGABLE_GENTREE
3405 //--------------------------------------------
3407 // GenTreeArrOffset (gtArrOffset): Expression to compute the accumulated offset for the address
3408 // of an element of a multi-dimensional or non-zero-based array.
3411 // The result of this expression is (gtOffset * dimSize) + gtIndex
3412 // where dimSize is the length/stride/size of the dimension, and is obtained from gtArrObj.
3413 // This node is generated in conjunction with the GenTreeArrIndex node, which computes the
3414 // effective index for a single dimension. The sub-trees can be separately optimized, e.g.
3415 // within a loop body where the expression for the 0th dimension may be invariant.
3417 // Here is an example of how the tree might look for a two-dimension array reference:
3421 // +--* ArrIndex[i, ]
3423 // /--| arrOffs[i, ]
3426 // +--* ArrIndex[*,j]
3428 // /--| arrOffs[*,j]
3429 // TODO-CQ: see comment on GenTreeArrIndex for how its representation may change. When that
3430 // is done, we will also want to replace the <arrObj> argument to arrOffs with the
3431 // ArrLen as for GenTreeArrIndex.
3433 struct GenTreeArrOffs: public GenTree
3435 GenTreePtr gtOffset; // The accumulated offset for lower dimensions - must be TYP_I_IMPL, and
3436 // will either be a CSE temp, the constant 0, or another GenTreeArrOffs node.
3437 GenTreePtr gtIndex; // The effective index for the current dimension - must be non-negative
3438 // and can be any expression (though it is likely to be either a GenTreeArrIndex,
3439 // node, a lclVar, or a constant).
3440 GenTreePtr gtArrObj; // The array object - may be any expression producing an Array reference,
3441 // but is likely to be a lclVar.
3442 unsigned char gtCurrDim; // The current dimension
3443 unsigned char gtArrRank; // Rank of the array
3444 var_types gtArrElemType; // The array element type
3446 GenTreeArrOffs(var_types type, GenTreePtr offset, GenTreePtr index, GenTreePtr arrObj,
3447 unsigned char currDim, unsigned char rank, var_types elemType) :
3448 GenTree(GT_ARR_OFFSET, type), gtOffset(offset), gtIndex(index), gtArrObj(arrObj),
3449 gtCurrDim(currDim), gtArrRank(rank), gtArrElemType(elemType)
3451 assert(index->gtFlags & GTF_EXCEPT);
3452 gtFlags |= GTF_EXCEPT;
3454 #if DEBUGGABLE_GENTREE
3455 GenTreeArrOffs() : GenTree() {}
3459 /* gtAddrMode -- Target-specific canonicalized addressing expression (GT_LEA) */
3461 struct GenTreeAddrMode: public GenTreeOp
3463 // Address is Base + Index*Scale + Offset.
3464 // These are the legal patterns:
3466 // Base // Base != nullptr && Index == nullptr && Scale == 0 && Offset == 0
3467 // Base + Index*Scale // Base != nullptr && Index != nullptr && Scale != 0 && Offset == 0
3468 // Base + Offset // Base != nullptr && Index == nullptr && Scale == 0 && Offset != 0
3469 // Base + Index*Scale + Offset // Base != nullptr && Index != nullptr && Scale != 0 && Offset != 0
3470 // Index*Scale // Base == nullptr && Index != nullptr && Scale > 1 && Offset == 0
3471 // Index*Scale + Offset // Base == nullptr && Index != nullptr && Scale > 1 && Offset != 0
3472 // Offset // Base == nullptr && Index == nullptr && Scale == 0 && Offset != 0
3475 // 1. Base + Index is legal with Scale==1
3476 // 2. If Index is null, Scale should be zero (or unintialized / unused)
3477 // 3. If Scale==1, then we should have "Base" instead of "Index*Scale", and "Base + Offset" instead of "Index*Scale + Offset".
3479 // First operand is base address/pointer
3480 bool HasBase() const { return gtOp1 != nullptr; }
3481 GenTreePtr& Base() { return gtOp1; }
3483 // Second operand is scaled index value
3484 bool HasIndex() const { return gtOp2 != nullptr; }
3485 GenTreePtr& Index() { return gtOp2; }
3487 unsigned gtScale; // The scale factor
3488 unsigned gtOffset; // The offset to add
3490 GenTreeAddrMode(var_types type, GenTreePtr base, GenTreePtr index,
3491 unsigned scale, unsigned offset) :
3492 GenTreeOp(GT_LEA, type, base, index )
3497 #if DEBUGGABLE_GENTREE
3500 // Used only for GenTree::GetVtableForOper()
3501 GenTreeAddrMode() : GenTreeOp() {}
3505 // Indir is just an op, no additional data, but some additional abstractions
3506 struct GenTreeIndir: public GenTreeOp
3508 // like an assign, op1 is the destination
3509 GenTreePtr& Addr() { return gtOp1; }
3511 // these methods provide an interface to the indirection node which
3519 GenTreeIndir(genTreeOps oper, var_types type, GenTree *addr, GenTree *data) :
3520 GenTreeOp(oper, type, addr, data)
3524 #if DEBUGGABLE_GENTREE
3527 // Used only for GenTree::GetVtableForOper()
3528 GenTreeIndir() : GenTreeOp() {}
3532 // Read-modify-write status of a RMW memory op rooted at a storeInd
3534 STOREIND_RMW_STATUS_UNKNOWN, // RMW status of storeInd unknown
3535 // Default status unless modified by IsRMWMemOpRootedAtStoreInd()
3537 // One of these denote storeind is a RMW memory operation.
3538 STOREIND_RMW_DST_IS_OP1, // StoreInd is known to be a RMW memory op and dst candidate is op1
3539 STOREIND_RMW_DST_IS_OP2, // StoreInd is known to be a RMW memory op and dst candidate is op2
3541 // One of these denote the reason for storeind is marked as non-RMW operation
3542 STOREIND_RMW_UNSUPPORTED_ADDR, // Addr mode is not yet supported for RMW memory
3543 STOREIND_RMW_UNSUPPORTED_OPER, // Operation is not supported for RMW memory
3544 STOREIND_RMW_UNSUPPORTED_TYPE, // Type is not supported for RMW memory
3545 STOREIND_RMW_INDIR_UNEQUAL // Indir to read value is not equivalent to indir that writes the value
3548 // StoreInd is just a BinOp, with additional RMW status
3549 struct GenTreeStoreInd: public GenTreeIndir
3551 #if !CPU_LOAD_STORE_ARCH
3552 // The below flag is set and used during lowering
3553 RMWStatus gtRMWStatus;
3555 bool IsRMWStatusUnknown() { return gtRMWStatus == STOREIND_RMW_STATUS_UNKNOWN; }
3556 bool IsNonRMWMemoryOp() {
3557 return gtRMWStatus == STOREIND_RMW_UNSUPPORTED_ADDR ||
3558 gtRMWStatus == STOREIND_RMW_UNSUPPORTED_OPER ||
3559 gtRMWStatus == STOREIND_RMW_UNSUPPORTED_TYPE ||
3560 gtRMWStatus == STOREIND_RMW_INDIR_UNEQUAL;
3562 bool IsRMWMemoryOp() { return gtRMWStatus == STOREIND_RMW_DST_IS_OP1 || gtRMWStatus == STOREIND_RMW_DST_IS_OP2; }
3563 bool IsRMWDstOp1() { return gtRMWStatus == STOREIND_RMW_DST_IS_OP1; }
3564 bool IsRMWDstOp2() { return gtRMWStatus == STOREIND_RMW_DST_IS_OP2; }
3565 #endif //!CPU_LOAD_STORE_ARCH
3567 RMWStatus GetRMWStatus() {
3568 #if !CPU_LOAD_STORE_ARCH
3571 return STOREIND_RMW_STATUS_UNKNOWN;
3575 void SetRMWStatusDefault()
3577 #if !CPU_LOAD_STORE_ARCH
3578 gtRMWStatus = STOREIND_RMW_STATUS_UNKNOWN;
3582 void SetRMWStatus(RMWStatus status)
3584 #if !CPU_LOAD_STORE_ARCH
3585 gtRMWStatus = status;
3589 GenTreePtr& Data() { return gtOp2; }
3591 GenTreeStoreInd(var_types type, GenTree *destPtr, GenTree *data) :
3592 GenTreeIndir(GT_STOREIND, type, destPtr, data)
3594 SetRMWStatusDefault();
3597 #if DEBUGGABLE_GENTREE
3600 // Used only for GenTree::GetVtableForOper()
3601 GenTreeStoreInd() : GenTreeIndir() { SetRMWStatusDefault(); }
3606 /* gtRetExp -- Place holder for the return expression from an inline candidate (GT_RET_EXPR) */
3608 struct GenTreeRetExpr: public GenTree
3610 GenTreePtr gtInlineCandidate;
3612 CORINFO_CLASS_HANDLE gtRetClsHnd;
3614 GenTreeRetExpr(var_types type) :
3615 GenTree(GT_RET_EXPR, type)
3617 #if DEBUGGABLE_GENTREE
3618 GenTreeRetExpr() : GenTree() {}
3623 /* gtStmt -- 'statement expr' (GT_STMT) */
3625 class InlineContext;
3627 struct GenTreeStmt: public GenTree
3629 GenTreePtr gtStmtExpr; // root of the expression tree
3630 GenTreePtr gtStmtList; // first node (for forward walks)
3631 InlineContext* gtInlineContext; // The inline context for this statement.
3633 #if defined(DEBUGGING_SUPPORT) || defined(DEBUG)
3634 IL_OFFSETX gtStmtILoffsx; // instr offset (if available)
3638 IL_OFFSET gtStmtLastILoffs;// instr offset at end of stmt
3641 bool gtStmtIsTopLevel()
3643 return (gtFlags & GTF_STMT_TOP_LEVEL) != 0;
3646 bool gtStmtIsEmbedded()
3648 return !gtStmtIsTopLevel();
3651 // Return the next statement, if it is embedded, otherwise nullptr
3652 GenTreeStmt* gtStmtNextIfEmbedded()
3654 GenTree* nextStmt = gtNext;
3655 if (nextStmt != nullptr && nextStmt->gtStmt.gtStmtIsEmbedded())
3657 return nextStmt->AsStmt();
3665 GenTree* gtStmtNextTopLevelStmt()
3667 GenTree* nextStmt = gtNext;
3668 while (nextStmt != nullptr && nextStmt->gtStmt.gtStmtIsEmbedded())
3670 nextStmt = nextStmt->gtNext;
3675 __declspec(property(get=getNextStmt))
3676 GenTreeStmt* gtNextStmt;
3678 __declspec(property(get=getPrevStmt))
3679 GenTreeStmt* gtPrevStmt;
3681 GenTreeStmt* getNextStmt()
3683 if (gtNext == nullptr)
3686 return gtNext->AsStmt();
3689 GenTreeStmt* getPrevStmt()
3691 if (gtPrev == nullptr)
3694 return gtPrev->AsStmt();
3697 GenTreeStmt(GenTreePtr expr, IL_OFFSETX offset)
3698 : GenTree(GT_STMT, TYP_VOID)
3700 , gtStmtList(nullptr)
3701 , gtInlineContext(nullptr)
3702 #if defined(DEBUGGING_SUPPORT) || defined(DEBUG)
3703 , gtStmtILoffsx(offset)
3706 , gtStmtLastILoffs(BAD_IL_OFFSET)
3709 // Statements can't have statements as part of their expression tree.
3710 assert(expr->gtOper != GT_STMT);
3712 gtFlags |= GTF_STMT_TOP_LEVEL;
3714 // Set the statement to have the same costs as the top node of the tree.
3715 // This is used long before costs have been assigned, so we need to copy
3720 #if DEBUGGABLE_GENTREE
3721 GenTreeStmt() : GenTree(GT_STMT, TYP_VOID) {}
3728 /* NOTE: Any tree nodes that are larger than 8 bytes (two ints or
3729 pointers) must be flagged as 'large' in GenTree::InitNodeSize().
3733 /* gtClsVar -- 'static data member' (GT_CLS_VAR) */
3735 struct GenTreeClsVar: public GenTree
3737 CORINFO_FIELD_HANDLE gtClsVarHnd;
3738 FieldSeqNode* gtFieldSeq;
3740 GenTreeClsVar(var_types type, CORINFO_FIELD_HANDLE clsVarHnd, FieldSeqNode* fldSeq) :
3741 GenTree(GT_CLS_VAR, type),
3742 gtClsVarHnd(clsVarHnd),
3745 gtFlags |= GTF_GLOB_REF;
3747 #if DEBUGGABLE_GENTREE
3748 GenTreeClsVar() : GenTree() {}
3752 /* gtArgPlace -- 'register argument placeholder' (GT_ARGPLACE) */
3754 struct GenTreeArgPlace: public GenTree
3756 CORINFO_CLASS_HANDLE gtArgPlaceClsHnd; // Needed when we have a TYP_STRUCT argument
3758 GenTreeArgPlace(var_types type, CORINFO_CLASS_HANDLE clsHnd) :
3759 GenTree(GT_ARGPLACE, type),
3760 gtArgPlaceClsHnd(clsHnd)
3762 #if DEBUGGABLE_GENTREE
3763 GenTreeArgPlace() : GenTree() {}
3767 /* gtLabel -- code label target (GT_LABEL) */
3769 struct GenTreeLabel: public GenTree
3771 BasicBlock* gtLabBB;
3773 GenTreeLabel(BasicBlock* bb) :
3774 GenTree(GT_LABEL, TYP_VOID),
3777 #if DEBUGGABLE_GENTREE
3778 GenTreeLabel() : GenTree() {}
3782 /* gtPhiArg -- phi node rhs argument, var = phi(phiarg, phiarg, phiarg...); GT_PHI_ARG */
3783 struct GenTreePhiArg: public GenTreeLclVarCommon
3785 BasicBlock * gtPredBB;
3787 GenTreePhiArg(var_types type, unsigned lclNum, unsigned snum, BasicBlock* block)
3788 : GenTreeLclVarCommon(GT_PHI_ARG, type, lclNum)
3794 #if DEBUGGABLE_GENTREE
3795 GenTreePhiArg() : GenTreeLclVarCommon() {}
3799 /* gtPutArgStk -- Argument passed on stack */
3801 struct GenTreePutArgStk: public GenTreeUnOp
3803 unsigned gtSlotNum; // Slot number of the argument to be passed on stack
3805 #if FEATURE_FASTTAILCALL
3806 bool putInIncomingArgArea; // Whether this arg needs to be placed in incoming arg area.
3807 // By default this is false and will be placed in out-going arg area.
3808 // Fast tail calls set this to true.
3809 // In future if we need to add more such bool fields consider bit fields.
3815 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(unsigned numSlots)
3816 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(bool isStruct),
3817 bool _putInIncomingArgArea = false
3818 DEBUGARG(GenTreePtr callNode = NULL)
3819 DEBUGARG(bool largeNode = false))
3821 GenTreeUnOp(oper, type DEBUGARG(largeNode)),
3823 putInIncomingArgArea(_putInIncomingArgArea)
3824 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
3825 , gtPutArgStkKind(PutArgStkKindInvalid),
3826 gtNumSlots(numSlots),
3827 gtIsStruct(isStruct),
3828 gtNumberReferenceSlots(0),
3830 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
3843 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(unsigned numSlots)
3844 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(bool isStruct),
3845 bool _putInIncomingArgArea = false
3846 DEBUGARG(GenTreePtr callNode = NULL)
3847 DEBUGARG(bool largeNode = false))
3849 GenTreeUnOp(oper, type, op1 DEBUGARG(largeNode)),
3851 putInIncomingArgArea(_putInIncomingArgArea)
3852 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
3853 , gtPutArgStkKind(PutArgStkKindInvalid),
3854 gtNumSlots(numSlots),
3855 gtIsStruct(isStruct),
3856 gtNumberReferenceSlots(0),
3858 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
3865 #else // !FEATURE_FASTTAILCALL
3871 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(unsigned numSlots)
3872 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(bool isStruct)
3873 DEBUGARG(GenTreePtr callNode = NULL)
3874 DEBUGARG(bool largeNode = false))
3876 GenTreeUnOp(oper, type DEBUGARG(largeNode)),
3878 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
3879 , gtPutArgStkKind(PutArgStkKindInvalid),
3880 gtNumSlots(numSlots),
3881 gtIsStruct(isStruct),
3882 gtNumberReferenceSlots(0),
3884 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
3897 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(unsigned numSlots)
3898 FEATURE_UNIX_AMD64_STRUCT_PASSING_ONLY_ARG(bool isStruct)
3899 DEBUGARG(GenTreePtr callNode = NULL)
3900 DEBUGARG(bool largeNode = false))
3902 GenTreeUnOp(oper, type, op1 DEBUGARG(largeNode)),
3904 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
3905 , gtPutArgStkKind(PutArgStkKindInvalid),
3906 gtNumSlots(numSlots),
3907 gtIsStruct(isStruct),
3908 gtNumberReferenceSlots(0),
3910 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
3916 #endif // FEATURE_FASTTAILCALL
3918 unsigned getArgOffset() { return gtSlotNum * TARGET_POINTER_SIZE; }
3920 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
3921 unsigned getArgSize() { return gtNumSlots * TARGET_POINTER_SIZE; }
3922 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
3924 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
3925 //------------------------------------------------------------------------
3926 // setGcPointers: Sets the number of references and the layout of the struct object returned by the VM.
3929 // numPointers - Number of pointer references.
3930 // pointers - layout of the struct (with pointers marked.)
3936 // This data is used in the codegen for GT_PUTARG_STK to decide how to copy the struct to the stack by value.
3937 // If no pointer references are used, block copying instructions are used.
3938 // Otherwise the pointer reference slots are copied atomically in a way that gcinfo is emitted.
3939 // Any non pointer references between the pointer reference slots are copied in block fashion.
3941 void setGcPointers(unsigned numPointers, BYTE* pointers)
3943 gtNumberReferenceSlots = numPointers;
3944 gtGcPtrs = pointers;
3946 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
3949 GenTreePtr gtCall; // the call node to which this argument belongs
3952 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
3953 // Instruction selection: during codegen time, what code sequence we will be using
3954 // to encode this operation.
3956 enum PutArgStkKind : __int8
3958 PutArgStkKindInvalid,
3959 PutArgStkKindRepInstr,
3960 PutArgStkKindUnroll,
3963 PutArgStkKind gtPutArgStkKind;
3965 unsigned gtNumSlots; // Number of slots for the argument to be passed on stack
3966 bool gtIsStruct; // This stack arg is a struct.
3967 unsigned gtNumberReferenceSlots; // Number of reference slots.
3968 BYTE* gtGcPtrs; // gcPointers
3969 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
3971 #if DEBUGGABLE_GENTREE
3972 GenTreePutArgStk() : GenTreeUnOp() {}
3976 // Represents GT_COPY or GT_RELOAD node
3977 struct GenTreeCopyOrReload : public GenTreeUnOp
3979 // State required to support copy/reload of a multi-reg call node.
3980 // First register is is always given by gtRegNum.
3982 #if FEATURE_MULTIREG_RET
3983 regNumber gtOtherRegs[MAX_RET_REG_COUNT - 1];
3986 //----------------------------------------------------------
3987 // ClearOtherRegs: set gtOtherRegs to REG_NA.
3995 void ClearOtherRegs()
3997 #if FEATURE_MULTIREG_RET
3998 for (unsigned i = 0; i < MAX_RET_REG_COUNT - 1; ++i)
4000 gtOtherRegs[i] = REG_NA;
4005 //-----------------------------------------------------------
4006 // GetRegNumByIdx: Get regNumber of ith position.
4009 // idx - register position.
4012 // Returns regNumber assigned to ith position.
4014 regNumber GetRegNumByIdx(unsigned idx) const
4016 assert(idx < MAX_RET_REG_COUNT);
4023 #if FEATURE_MULTIREG_RET
4024 return gtOtherRegs[idx - 1];
4030 //-----------------------------------------------------------
4031 // SetRegNumByIdx: Set the regNumber for ith position.
4035 // idx - register position.
4040 void SetRegNumByIdx(regNumber reg, unsigned idx)
4042 assert(idx < MAX_RET_REG_COUNT);
4048 #if FEATURE_MULTIREG_RET
4051 gtOtherRegs[idx - 1] = reg;
4052 assert(gtOtherRegs[idx - 1] == reg);
4062 //----------------------------------------------------------------------------
4063 // CopyOtherRegs: copy multi-reg state from the given copy/reload node to this
4067 // from - GenTree node from which to copy multi-reg state
4072 // TODO-ARM: Implement this routine for Arm64 and Arm32
4073 // TODO-X86: Implement this routine for x86
4074 void CopyOtherRegs(GenTreeCopyOrReload* from)
4076 assert(OperGet() == from->OperGet());
4078 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
4079 for (unsigned i = 0; i < MAX_RET_REG_COUNT - 1; ++i)
4081 gtOtherRegs[i] = from->gtOtherRegs[i];
4086 GenTreeCopyOrReload(genTreeOps oper,
4088 GenTree* op1) : GenTreeUnOp(oper, type, op1)
4094 #if DEBUGGABLE_GENTREE
4095 GenTreeCopyOrReload() : GenTreeUnOp() {}
4099 //------------------------------------------------------------------------
4100 // Deferred inline functions of GenTree -- these need the subtypes above to
4101 // be defined already.
4102 //------------------------------------------------------------------------
4104 //------------------------------------------------------------------------
4105 // IsFPZero: Checks whether this is a floating point constant with value 0.0
4108 // Returns true iff the tree is an GT_CNS_DBL, with value of 0.0.
4110 inline bool GenTree::IsFPZero()
4112 if ((gtOper == GT_CNS_DBL) && (gtDblCon.gtDconVal == 0.0))
4117 //------------------------------------------------------------------------
4118 // IsIntegralConst: Checks whether this is a constant node with the given value
4121 // constVal - the value of interest
4124 // Returns true iff the tree is an integral constant opcode, with
4128 // Like gtIconVal, the argument is of ssize_t, so cannot check for
4129 // long constants in a target-independent way.
4131 inline bool GenTree::IsIntegralConst(ssize_t constVal)
4134 if ((gtOper == GT_CNS_INT) && (gtIntConCommon.IconValue() == constVal))
4137 if ((gtOper == GT_CNS_LNG) && (gtIntConCommon.LngValue() == constVal))
4143 inline bool GenTree::IsBoxedValue()
4145 assert(gtOper != GT_BOX || gtBox.BoxOp() != NULL);
4146 return (gtOper == GT_BOX) && (gtFlags & GTF_BOX_VALUE);
4149 inline GenTreePtr GenTree::MoveNext()
4156 //------------------------------------------------------------------------
4157 // IsListForMultiRegArg: Given an GenTree node that represents an argument
4158 // enforce (or don't enforce) the following invariant.
4160 // For LEGACY_BACKEND or architectures that don't support MultiReg args
4161 // we don't allow a GT_LIST at all.
4163 // Currently for AMD64 UNIX we allow a limited case where a GT_LIST is
4164 // allowed but every element must be a GT_LCL_FLD.
4166 // For the future targets that allow for Multireg args (and this includes
4167 // the current ARM64 target) we allow a GT_LIST of arbitrary nodes, these
4168 // would typically start out as GT_LCL_VARs or GT_LCL_FLDS or GT_INDs,
4169 // but could be changed into constants or GT_COMMA trees by the later
4170 // optimization phases.
4173 // instance method for a GenTree node
4176 // true: the GenTree node is accepted as a valid argument
4177 // false: the GenTree node is not accepted as a valid argumeny
4179 inline bool GenTree::IsListForMultiRegArg()
4183 // We don't have a GT_LIST, so just return true.
4186 else // We do have a GT_LIST
4188 #if defined(LEGACY_BACKEND) || !FEATURE_MULTIREG_ARGS
4190 // Not allowed to have a GT_LIST for an argument
4191 // unless we have a RyuJIT backend and FEATURE_MULTIREG_ARGS
4195 #else // we have RyuJIT backend and FEATURE_MULTIREG_ARGS
4197 #ifdef FEATURE_UNIX_AMD64_STRUCT_PASSING
4198 // For UNIX ABI we currently only allow a GT_LIST of GT_LCL_FLDs nodes
4199 GenTree* gtListPtr = this;
4200 while (gtListPtr != nullptr)
4202 // ToDo: fix UNIX_AMD64 so that we do not generate this kind of a List
4203 // Note the list as currently created is malformed, as the last entry is a nullptr
4204 if (gtListPtr->Current() == nullptr)
4207 // Only a list of GT_LCL_FLDs is allowed
4208 if (gtListPtr->Current()->OperGet() != GT_LCL_FLD)
4212 gtListPtr = gtListPtr->MoveNext();
4214 #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING
4216 // Note that for non-UNIX ABI the GT_LIST may contain any node
4218 // We allow this GT_LIST as an argument
4221 #endif // RyuJIT backend and FEATURE_MULTIREG_ARGS
4226 inline GenTreePtr GenTree::Current()
4232 inline GenTreePtr *GenTree::pCurrent()
4235 return &(gtOp.gtOp1);
4238 inline GenTreePtr GenTree::gtGetOp1()
4245 inline bool GenTree::RequiresNonNullOp2(genTreeOps oper)
4298 inline GenTreePtr GenTree::gtGetOp2()
4300 /* gtOp.gtOp2 is only valid for GTK_BINOP nodes. */
4302 GenTreePtr op2 = OperIsBinary() ? gtOp.gtOp2 : nullptr;
4304 // This documents the genTreeOps for which gtOp.gtOp2 cannot be nullptr.
4305 // This helps prefix in its analyis of code which calls gtGetOp2()
4307 assert((op2 != nullptr) || !RequiresNonNullOp2(gtOper));
4312 inline GenTreePtr GenTree::gtEffectiveVal(bool commaOnly)
4317 return gtOp.gtOp2->gtEffectiveVal(commaOnly);
4320 if (!commaOnly && gtOp.gtOp1 != NULL)
4321 return gtOp.gtOp1->gtEffectiveVal();
4331 inline GenTree* GenTree::gtSkipReloadOrCopy()
4333 // There can be only one reload or copy (we can't have a reload/copy of a reload/copy)
4334 if (gtOper == GT_RELOAD || gtOper == GT_COPY)
4336 assert(gtGetOp1()->OperGet() != GT_RELOAD && gtGetOp1()->OperGet() != GT_COPY);
4342 //-----------------------------------------------------------------------------------
4343 // IsMultiRegCall: whether a call node returning its value in more than one register
4349 // Returns true if this GenTree is a multi register returning call
4350 inline bool GenTree::IsMultiRegCall() const
4354 // We cannot use AsCall() as it is not declared const
4355 const GenTreeCall* call = reinterpret_cast<const GenTreeCall *>(this);
4356 return call->HasMultiRegRetVal();
4362 //-------------------------------------------------------------------------
4363 // IsCopyOrReload: whether this is a GT_COPY or GT_RELOAD node.
4369 // Returns true if this GenTree is a copy or reload node.
4370 inline bool GenTree::IsCopyOrReload() const
4372 return (gtOper == GT_COPY || gtOper == GT_RELOAD);
4375 //-----------------------------------------------------------------------------------
4376 // IsCopyOrReloadOfMultiRegCall: whether this is a GT_COPY or GT_RELOAD of a multi-reg
4383 // Returns true if this GenTree is a copy or reload of multi-reg call node.
4384 inline bool GenTree::IsCopyOrReloadOfMultiRegCall() const
4386 if (IsCopyOrReload())
4388 GenTree* t = const_cast<GenTree*>(this);
4389 return t->gtGetOp1()->IsMultiRegCall();
4395 inline bool GenTree::IsCnsIntOrI() const
4397 return (gtOper == GT_CNS_INT);
4400 inline bool GenTree::IsIntegralConst() const
4402 #ifdef _TARGET_64BIT_
4403 return IsCnsIntOrI();
4404 #else // !_TARGET_64BIT_
4405 return ((gtOper == GT_CNS_INT) || (gtOper == GT_CNS_LNG));
4406 #endif // !_TARGET_64BIT_
4409 inline bool GenTree::IsIntCnsFitsInI32()
4411 #ifdef _TARGET_64BIT_
4412 return IsCnsIntOrI() && ((int)gtIntConCommon.IconValue() == gtIntConCommon.IconValue());
4413 #else // !_TARGET_64BIT_
4414 return IsCnsIntOrI();
4415 #endif // !_TARGET_64BIT_
4418 inline bool GenTree::IsCnsFltOrDbl() const
4420 return OperGet() == GT_CNS_DBL;
4423 inline bool GenTree::IsCnsNonZeroFltOrDbl()
4425 if (OperGet() == GT_CNS_DBL)
4427 double constValue = gtDblCon.gtDconVal;
4428 return *(__int64*)&constValue != 0;
4434 inline bool GenTree::IsHelperCall() { return OperGet() == GT_CALL && gtCall.gtCallType == CT_HELPER; }
4436 inline var_types GenTree::CastFromType() { return this->gtCast.CastOp()->TypeGet(); }
4437 inline var_types& GenTree::CastToType() { return this->gtCast.gtCastType; }
4440 /*****************************************************************************/
4442 #ifndef _HOST_64BIT_
4443 #include <poppack.h>
4446 /*****************************************************************************/
4448 #if SMALL_TREE_NODES
4450 // In debug, on some platforms (e.g., when LATE_DISASM is defined), GenTreeIntCon is bigger than GenTreeLclFld.
4452 size_t TREE_NODE_SZ_SMALL = max(sizeof(GenTreeIntCon), sizeof(GenTreeLclFld));
4454 #endif // SMALL_TREE_NODES
4457 size_t TREE_NODE_SZ_LARGE = sizeof(GenTreeCall);
4459 /*****************************************************************************
4460 * Types returned by GenTree::lvaLclVarRefs()
4465 VR_INVARIANT = 0x00, // an invariant value
4467 VR_IND_REF = 0x01, // an object reference
4468 VR_IND_SCL = 0x02, // a non-object reference
4469 VR_GLB_VAR = 0x04, // a global (clsVar)
4471 // Add a temp define to avoid merge conflict.
4472 #define VR_IND_PTR VR_IND_REF
4474 /*****************************************************************************/
4475 #endif // !GENTREE_H
4476 /*****************************************************************************/