TargetInfo.cpp source code [clang/lib/Basic/TargetInfo.cpp]

1	//===--- TargetInfo.cpp - Information about Target machine ----------------===//
2	//
3	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4	// See https://llvm.org/LICENSE.txt for license information.
5	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6	//
7	//===----------------------------------------------------------------------===//
8	//
9	// This file implements the TargetInfo interface.
10	//
11	//===----------------------------------------------------------------------===//
12
13	#include "clang/Basic/TargetInfo.h"
14	#include "clang/Basic/AddressSpaces.h"
15	#include "clang/Basic/CharInfo.h"
16	#include "clang/Basic/Diagnostic.h"
17	#include "clang/Basic/DiagnosticFrontend.h"
18	#include "clang/Basic/LangOptions.h"
19	#include "llvm/ADT/APFloat.h"
20	#include "llvm/ADT/STLExtras.h"
21	#include "llvm/Support/ErrorHandling.h"
22	#include "llvm/TargetParser/TargetParser.h"
23	#include <cstdlib>
24	using namespace clang;
25
26	static const LangASMap DefaultAddrSpaceMap = {`0`};
27	// The fake address space map must have a distinct entry for each
28	// language-specific address space.
29	static const LangASMap FakeAddrSpaceMap = {
30	`0`, // Default
31	`1`, // opencl_global
32	`3`, // opencl_local
33	`2`, // opencl_constant
34	`0`, // opencl_private
35	`4`, // opencl_generic
36	`5`, // opencl_global_device
37	`6`, // opencl_global_host
38	`7`, // cuda_device
39	`8`, // cuda_constant
40	`9`, // cuda_shared
41	`1`, // sycl_global
42	`5`, // sycl_global_device
43	`6`, // sycl_global_host
44	`3`, // sycl_local
45	`0`, // sycl_private
46	`10`, // ptr32_sptr
47	`11`, // ptr32_uptr
48	`12`, // ptr64
49	`13`, // hlsl_groupshared
50	`20`, // wasm_funcref
51	};
52
53	// TargetInfo Constructor.
54	TargetInfo::TargetInfo(const llvm::Triple &T) : Triple (T) {
55	// Set defaults. Defaults are set for a 32-bit RISC platform, like PPC or
56	// SPARC. These should be overridden by concrete targets as needed.
57	BigEndian = !T.isLittleEndian();
58	TLSSupported = true;
59	VLASupported = true;
60	NoAsmVariants = false;
61	HasLegalHalfType = false;
62	HalfArgsAndReturns = false;
63	HasFloat128 = false;
64	HasIbm128 = false;
65	HasFloat16 = false;
66	HasBFloat16 = false;
67	HasFullBFloat16 = false;
68	HasLongDouble = true;
69	HasFPReturn = true;
70	HasStrictFP = false;
71	PointerWidth = PointerAlign = `32`;
72	BoolWidth = BoolAlign = `8`;
73	IntWidth = IntAlign = `32`;
74	LongWidth = LongAlign = `32`;
75	LongLongWidth = LongLongAlign = `64`;
76	Int128Align = `128`;
77
78	// Fixed point default bit widths
79	ShortAccumWidth = ShortAccumAlign = `16`;
80	AccumWidth = AccumAlign = `32`;
81	LongAccumWidth = LongAccumAlign = `64`;
82	ShortFractWidth = ShortFractAlign = `8`;
83	FractWidth = FractAlign = `16`;
84	LongFractWidth = LongFractAlign = `32`;
85
86	// Fixed point default integral and fractional bit sizes
87	// We give the _Accum 1 fewer fractional bits than their corresponding _Fract
88	// types by default to have the same number of fractional bits between _Accum
89	// and _Fract types.
90	PaddingOnUnsignedFixedPoint = false;
91	ShortAccumScale = `7`;
92	AccumScale = `15`;
93	LongAccumScale = `31`;
94
95	SuitableAlign = `64`;
96	DefaultAlignForAttributeAligned = `128`;
97	MinGlobalAlign = `0`;
98	// From the glibc documentation, on GNU systems, malloc guarantees 16-byte
99	// alignment on 64-bit systems and 8-byte alignment on 32-bit systems. See
100	// https://www.gnu.org/software/libc/manual/html_node/Malloc-Examples.html.
101	// This alignment guarantee also applies to Windows and Android. On Darwin
102	// and OpenBSD, the alignment is 16 bytes on both 64-bit and 32-bit systems.
103	if (T.isGNUEnvironment() \|\| T.isWindowsMSVCEnvironment() \|\| T.isAndroid() \|\|
104	T.isOHOSFamily())
105	NewAlign = Triple.isArch64Bit() ? `128` : Triple.isArch32Bit() ? `64` : `0`;
106	else if (T.isOSDarwin() \|\| T.isOSOpenBSD())
107	NewAlign = `128`;
108	else
109	NewAlign = `0`; // Infer from basic type alignment.
110	HalfWidth = `16`;
111	HalfAlign = `16`;
112	FloatWidth = `32`;
113	FloatAlign = `32`;
114	DoubleWidth = `64`;
115	DoubleAlign = `64`;
116	LongDoubleWidth = `64`;
117	LongDoubleAlign = `64`;
118	Float128Align = `128`;
119	Ibm128Align = `128`;
120	LargeArrayMinWidth = `0`;
121	LargeArrayAlign = `0`;
122	MaxAtomicPromoteWidth = MaxAtomicInlineWidth = `0`;
123	MaxVectorAlign = `0`;
124	MaxTLSAlign = `0`;
125	SizeType = UnsignedLong;
126	PtrDiffType = SignedLong;
127	IntMaxType = SignedLongLong;
128	IntPtrType = SignedLong;
129	WCharType = SignedInt;
130	WIntType = SignedInt;
131	Char16Type = UnsignedShort;
132	Char32Type = UnsignedInt;
133	Int64Type = SignedLongLong;
134	Int16Type = SignedShort;
135	SigAtomicType = SignedInt;
136	ProcessIDType = SignedInt;
137	UseSignedCharForObjCBool = true;
138	UseBitFieldTypeAlignment = true;
139	UseZeroLengthBitfieldAlignment = false;
140	UseLeadingZeroLengthBitfield = true;
141	UseExplicitBitFieldAlignment = true;
142	ZeroLengthBitfieldBoundary = `0`;
143	MaxAlignedAttribute = `0`;
144	HalfFormat = &llvm::APFloat::IEEEhalf();
145	FloatFormat = &llvm::APFloat::IEEEsingle();
146	DoubleFormat = &llvm::APFloat::IEEEdouble();
147	LongDoubleFormat = &llvm::APFloat::IEEEdouble();
148	Float128Format = &llvm::APFloat::IEEEquad();
149	Ibm128Format = &llvm::APFloat::PPCDoubleDouble();
150	MCountName = "mcount";
151	UserLabelPrefix = "_";
152	RegParmMax = `0`;
153	SSERegParmMax = `0`;
154	HasAlignMac68kSupport = false;
155	HasBuiltinMSVaList = false;
156	IsRenderScriptTarget = false;
157	HasAArch64SVETypes = false;
158	HasRISCVVTypes = false;
159	AllowAMDGPUUnsafeFPAtomics = false;
160	HasUnalignedAccess = false;
161	ARMCDECoprocMask = `0`;
162
163	// Default to no types using fpret.
164	RealTypeUsesObjCFPRetMask = `0`;
165
166	// Default to not using fp2ret for __Complex long double
167	ComplexLongDoubleUsesFP2Ret = false;
168
169	// Set the C++ ABI based on the triple.
170	TheCXXABI.set(Triple.isKnownWindowsMSVCEnvironment()
171	? TargetCXXABI::Microsoft
172	: TargetCXXABI::GenericItanium);
173
174	// Default to an empty address space map.
175	AddrSpaceMap = &DefaultAddrSpaceMap;
176	UseAddrSpaceMapMangling = false;
177
178	// Default to an unknown platform name.
179	PlatformName = "unknown";
180	PlatformMinVersion = VersionTuple();
181
182	MaxOpenCLWorkGroupSize = `1024`;
183
184	MaxBitIntWidth.reset();
185	}
186
187	// Out of line virtual dtor for TargetInfo.
188	TargetInfo::~TargetInfo() {}
189
190	void TargetInfo::resetDataLayout(StringRef DL, const char *ULP) {
191	DataLayoutString = DL.str();
192	UserLabelPrefix = ULP;
193	}
194
195	bool
196	TargetInfo::checkCFProtectionBranchSupported(DiagnosticsEngine &Diags) const {
197	Diags.Report(diag::err_opt_not_valid_on_target) << "cf-protection=branch";
198	return false;
199	}
200
201	bool
202	TargetInfo::checkCFProtectionReturnSupported(DiagnosticsEngine &Diags) const {
203	Diags.Report(diag::err_opt_not_valid_on_target) << "cf-protection=return";
204	return false;
205	}
206
207	/// getTypeName - Return the user string for the specified integer type enum.
208	/// For example, SignedShort -> "short".
209	const char *TargetInfo::getTypeName(IntType T) {
210	switch (T) {
211	default: llvm_unreachable("not an integer!");
212	case SignedChar: return "signed char";
213	case UnsignedChar: return "unsigned char";
214	case SignedShort: return "short";
215	case UnsignedShort: return "unsigned short";
216	case SignedInt: return "int";
217	case UnsignedInt: return "unsigned int";
218	case SignedLong: return "long int";
219	case UnsignedLong: return "long unsigned int";
220	case SignedLongLong: return "long long int";
221	case UnsignedLongLong: return "long long unsigned int";
222	}
223	}
224
225	/// getTypeConstantSuffix - Return the constant suffix for the specified
226	/// integer type enum. For example, SignedLong -> "L".
227	const char TargetInfo::getTypeConstantSuffix(IntType T) const* {
228	switch (T) {
229	default: llvm_unreachable("not an integer!");
230	case SignedChar:
231	case SignedShort:
232	case SignedInt: return "";
233	case SignedLong: return "L";
234	case SignedLongLong: return "LL";
235	case UnsignedChar:
236	if (getCharWidth() < getIntWidth())
237	return "";
238	[[fallthrough]];
239	case UnsignedShort:
240	if (getShortWidth() < getIntWidth())
241	return "";
242	[[fallthrough]];
243	case UnsignedInt: return "U";
244	case UnsignedLong: return "UL";
245	case UnsignedLongLong: return "ULL";
246	}
247	}
248
249	/// getTypeFormatModifier - Return the printf format modifier for the
250	/// specified integer type enum. For example, SignedLong -> "l".
251
252	const char *TargetInfo::getTypeFormatModifier(IntType T) {
253	switch (T) {
254	default: llvm_unreachable("not an integer!");
255	case SignedChar:
256	case UnsignedChar: return "hh";
257	case SignedShort:
258	case UnsignedShort: return "h";
259	case SignedInt:
260	case UnsignedInt: return "";
261	case SignedLong:
262	case UnsignedLong: return "l";
263	case SignedLongLong:
264	case UnsignedLongLong: return "ll";
265	}
266	}
267
268	/// getTypeWidth - Return the width (in bits) of the specified integer type
269	/// enum. For example, SignedInt -> getIntWidth().
270	unsigned TargetInfo::getTypeWidth(IntType T) const {
271	switch (T) {
272	default: llvm_unreachable("not an integer!");
273	case SignedChar:
274	case UnsignedChar: return getCharWidth();
275	case SignedShort:
276	case UnsignedShort: return getShortWidth();
277	case SignedInt:
278	case UnsignedInt: return getIntWidth();
279	case SignedLong:
280	case UnsignedLong: return getLongWidth();
281	case SignedLongLong:
282	case UnsignedLongLong: return getLongLongWidth();
283	};
284	}
285
286	TargetInfo::IntType TargetInfo::getIntTypeByWidth(
287	unsigned BitWidth, bool IsSigned) const {
288	if (getCharWidth() == BitWidth)
289	return IsSigned ? SignedChar : UnsignedChar;
290	if (getShortWidth() == BitWidth)
291	return IsSigned ? SignedShort : UnsignedShort;
292	if (getIntWidth() == BitWidth)
293	return IsSigned ? SignedInt : UnsignedInt;
294	if (getLongWidth() == BitWidth)
295	return IsSigned ? SignedLong : UnsignedLong;
296	if (getLongLongWidth() == BitWidth)
297	return IsSigned ? SignedLongLong : UnsignedLongLong;
298	return NoInt;
299	}
300
301	TargetInfo::IntType TargetInfo::getLeastIntTypeByWidth(unsigned BitWidth,
302	bool IsSigned) const {
303	if (getCharWidth() >= BitWidth)
304	return IsSigned ? SignedChar : UnsignedChar;
305	if (getShortWidth() >= BitWidth)
306	return IsSigned ? SignedShort : UnsignedShort;
307	if (getIntWidth() >= BitWidth)
308	return IsSigned ? SignedInt : UnsignedInt;
309	if (getLongWidth() >= BitWidth)
310	return IsSigned ? SignedLong : UnsignedLong;
311	if (getLongLongWidth() >= BitWidth)
312	return IsSigned ? SignedLongLong : UnsignedLongLong;
313	return NoInt;
314	}
315
316	FloatModeKind TargetInfo::getRealTypeByWidth(unsigned BitWidth,
317	FloatModeKind ExplicitType) const {
318	if (getHalfWidth() == BitWidth)
319	return FloatModeKind::Half;
320	if (getFloatWidth() == BitWidth)
321	return FloatModeKind::Float;
322	if (getDoubleWidth() == BitWidth)
323	return FloatModeKind::Double;
324
325	switch (BitWidth) {
326	case `96`:
327	if (&getLongDoubleFormat() == &llvm::APFloat::x87DoubleExtended())
328	return FloatModeKind::LongDouble;
329	break;
330	case `128`:
331	// The caller explicitly asked for an IEEE compliant type but we still
332	// have to check if the target supports it.
333	if (ExplicitType == FloatModeKind::Float128)
334	return hasFloat128Type() ? FloatModeKind::Float128
335	: FloatModeKind::NoFloat;
336	if (ExplicitType == FloatModeKind::Ibm128)
337	return hasIbm128Type() ? FloatModeKind::Ibm128
338	: FloatModeKind::NoFloat;
339	if (&getLongDoubleFormat() == &llvm::APFloat::PPCDoubleDouble() \|\|
340	&getLongDoubleFormat() == &llvm::APFloat::IEEEquad())
341	return FloatModeKind::LongDouble;
342	if (hasFloat128Type())
343	return FloatModeKind::Float128;
344	break;
345	}
346
347	return FloatModeKind::NoFloat;
348	}
349
350	/// getTypeAlign - Return the alignment (in bits) of the specified integer type
351	/// enum. For example, SignedInt -> getIntAlign().
352	unsigned TargetInfo::getTypeAlign(IntType T) const {
353	switch (T) {
354	default: llvm_unreachable("not an integer!");
355	case SignedChar:
356	case UnsignedChar: return getCharAlign();
357	case SignedShort:
358	case UnsignedShort: return getShortAlign();
359	case SignedInt:
360	case UnsignedInt: return getIntAlign();
361	case SignedLong:
362	case UnsignedLong: return getLongAlign();
363	case SignedLongLong:
364	case UnsignedLongLong: return getLongLongAlign();
365	};
366	}
367
368	/// isTypeSigned - Return whether an integer types is signed. Returns true if
369	/// the type is signed; false otherwise.
370	bool TargetInfo::isTypeSigned(IntType T) {
371	switch (T) {
372	default: llvm_unreachable("not an integer!");
373	case SignedChar:
374	case SignedShort:
375	case SignedInt:
376	case SignedLong:
377	case SignedLongLong:
378	return true;
379	case UnsignedChar:
380	case UnsignedShort:
381	case UnsignedInt:
382	case UnsignedLong:
383	case UnsignedLongLong:
384	return false;
385	};
386	}
387
388	/// adjust - Set forced language options.
389	/// Apply changes to the target information with respect to certain
390	/// language options which change the target configuration and adjust
391	/// the language based on the target options where applicable.
392	void TargetInfo::adjust(DiagnosticsEngine &Diags, LangOptions &Opts) {
393	if (Opts.NoBitFieldTypeAlign)
394	UseBitFieldTypeAlignment = false;
395
396	switch (Opts.WCharSize) {
397	default: llvm_unreachable("invalid wchar_t width");
398	case `0`: break;
399	case `1`: WCharType = Opts.WCharIsSigned ? SignedChar : UnsignedChar; break;
400	case `2`: WCharType = Opts.WCharIsSigned ? SignedShort : UnsignedShort; break;
401	case `4`: WCharType = Opts.WCharIsSigned ? SignedInt : UnsignedInt; break;
402	}
403
404	if (Opts.AlignDouble) {
405	DoubleAlign = LongLongAlign = `64`;
406	LongDoubleAlign = `64`;
407	}
408
409	if (Opts.OpenCL) {
410	// OpenCL C requires specific widths for types, irrespective of
411	// what these normally are for the target.
412	// We also define long long and long double here, although the
413	// OpenCL standard only mentions these as "reserved".
414	IntWidth = IntAlign = `32`;
415	LongWidth = LongAlign = `64`;
416	LongLongWidth = LongLongAlign = `128`;
417	HalfWidth = HalfAlign = `16`;
418	FloatWidth = FloatAlign = `32`;
419
420	// Embedded 32-bit targets (OpenCL EP) might have double C type
421	// defined as float. Let's not override this as it might lead
422	// to generating illegal code that uses 64bit doubles.
423	if (DoubleWidth != FloatWidth) {
424	DoubleWidth = DoubleAlign = `64`;
425	DoubleFormat = &llvm::APFloat::IEEEdouble();
426	}
427	LongDoubleWidth = LongDoubleAlign = `128`;
428
429	unsigned MaxPointerWidth = getMaxPointerWidth();
430	assert(MaxPointerWidth == `32` \|\| MaxPointerWidth == `64`);
431	bool Is32BitArch = MaxPointerWidth == `32`;
432	SizeType = Is32BitArch ? UnsignedInt : UnsignedLong;
433	PtrDiffType = Is32BitArch ? SignedInt : SignedLong;
434	IntPtrType = Is32BitArch ? SignedInt : SignedLong;
435
436	IntMaxType = SignedLongLong;
437	Int64Type = SignedLong;
438
439	HalfFormat = &llvm::APFloat::IEEEhalf();
440	FloatFormat = &llvm::APFloat::IEEEsingle();
441	LongDoubleFormat = &llvm::APFloat::IEEEquad();
442
443	// OpenCL C v3.0 s6.7.5 - The generic address space requires support for
444	// OpenCL C 2.0 or OpenCL C 3.0 with the __opencl_c_generic_address_space
445	// feature
446	// OpenCL C v3.0 s6.2.1 - OpenCL pipes require support of OpenCL C 2.0
447	// or later and __opencl_c_pipes feature
448	// FIXME: These language options are also defined in setLangDefaults()
449	// for OpenCL C 2.0 but with no access to target capabilities. Target
450	// should be immutable once created and thus these language options need
451	// to be defined only once.
452	if (Opts.getOpenCLCompatibleVersion() == `300`) {
453	const auto &OpenCLFeaturesMap = getSupportedOpenCLOpts();
454	Opts.OpenCLGenericAddressSpace = hasFeatureEnabled(
455	Features: OpenCLFeaturesMap, Name: "__opencl_c_generic_address_space");
456	Opts.OpenCLPipes =
457	hasFeatureEnabled(Features: OpenCLFeaturesMap, Name: "__opencl_c_pipes");
458	Opts.Blocks =
459	hasFeatureEnabled(Features: OpenCLFeaturesMap, Name: "__opencl_c_device_enqueue");
460	}
461	}
462
463	if (Opts.DoubleSize) {
464	if (Opts.DoubleSize == `32`) {
465	DoubleWidth = `32`;
466	LongDoubleWidth = `32`;
467	DoubleFormat = &llvm::APFloat::IEEEsingle();
468	LongDoubleFormat = &llvm::APFloat::IEEEsingle();
469	} else if (Opts.DoubleSize == `64`) {
470	DoubleWidth = `64`;
471	LongDoubleWidth = `64`;
472	DoubleFormat = &llvm::APFloat::IEEEdouble();
473	LongDoubleFormat = &llvm::APFloat::IEEEdouble();
474	}
475	}
476
477	if (Opts.LongDoubleSize) {
478	if (Opts.LongDoubleSize == DoubleWidth) {
479	LongDoubleWidth = DoubleWidth;
480	LongDoubleAlign = DoubleAlign;
481	LongDoubleFormat = DoubleFormat;
482	} else if (Opts.LongDoubleSize == `128`) {
483	LongDoubleWidth = LongDoubleAlign = `128`;
484	LongDoubleFormat = &llvm::APFloat::IEEEquad();
485	} else if (Opts.LongDoubleSize == `80`) {
486	LongDoubleFormat = &llvm::APFloat::x87DoubleExtended();
487	if (getTriple().isWindowsMSVCEnvironment()) {
488	LongDoubleWidth = `128`;
489	LongDoubleAlign = `128`;
490	} else { // Linux
491	if (getTriple().getArch() == llvm::Triple::x86) {
492	LongDoubleWidth = `96`;
493	LongDoubleAlign = `32`;
494	} else {
495	LongDoubleWidth = `128`;
496	LongDoubleAlign = `128`;
497	}
498	}
499	}
500	}
501
502	if (Opts.NewAlignOverride)
503	NewAlign = Opts.NewAlignOverride * getCharWidth();
504
505	// Each unsigned fixed point type has the same number of fractional bits as
506	// its corresponding signed type.
507	PaddingOnUnsignedFixedPoint \|= Opts.PaddingOnUnsignedFixedPoint;
508	CheckFixedPointBits();
509
510	if (Opts.ProtectParens && !checkArithmeticFenceSupported()) {
511	Diags.Report(diag::err_opt_not_valid_on_target) << "-fprotect-parens";
512	Opts.ProtectParens = false;
513	}
514
515	if (Opts.MaxBitIntWidth)
516	MaxBitIntWidth = static_cast<unsigned>(Opts.MaxBitIntWidth);
517
518	if (Opts.FakeAddressSpaceMap)
519	AddrSpaceMap = &FakeAddrSpaceMap;
520	}
521
522	bool TargetInfo::initFeatureMap(
523	llvm::StringMap<bool> &Features, DiagnosticsEngine &Diags, StringRef CPU,
524	const std::vector<std::string> &FeatureVec) const {
525	for (const auto &F : FeatureVec) {
526	StringRef Name = F;
527	if (Name.empty())
528	continue;
529	// Apply the feature via the target.
530	if (Name [`0`] != `'+'` && Name [`0`] != `'-'`)
531	Diags.Report(diag::warn_fe_backend_invalid_feature_flag) << Name;
532	else
533	setFeatureEnabled(Features, Name: Name.substr(Start: `1`), Enabled: Name [`0`] == `'+'`);
534	}
535	return true;
536	}
537
538	ParsedTargetAttr TargetInfo::parseTargetAttr(StringRef Features) const {
539	ParsedTargetAttr Ret;
540	if (Features == "default")
541	return Ret;
542	SmallVector<StringRef, `1`> AttrFeatures;
543	Features.split(A&: AttrFeatures, Separator: ",");
544
545	// Grab the various features and prepend a "+" to turn on the feature to
546	// the backend and add them to our existing set of features.
547	for (auto &Feature : AttrFeatures) {
548	// Go ahead and trim whitespace rather than either erroring or
549	// accepting it weirdly.
550	Feature = Feature.trim();
551
552	// TODO: Support the fpmath option. It will require checking
553	// overall feature validity for the function with the rest of the
554	// attributes on the function.
555	if (Feature.starts_with(Prefix: "fpmath="))
556	continue;
557
558	if (Feature.starts_with(Prefix: "branch-protection=")) {
559	Ret.BranchProtection = Feature.split(Separator: `'='`).second.trim();
560	continue;
561	}
562
563	// While we're here iterating check for a different target cpu.
564	if (Feature.starts_with(Prefix: "arch=")) {
565	if (!Ret.CPU.empty())
566	Ret.Duplicate = "arch=";
567	else
568	Ret.CPU = Feature.split(Separator: "=").second.trim();
569	} else if (Feature.starts_with(Prefix: "tune=")) {
570	if (!Ret.Tune.empty())
571	Ret.Duplicate = "tune=";
572	else
573	Ret.Tune = Feature.split(Separator: "=").second.trim();
574	} else if (Feature.starts_with(Prefix: "no-"))
575	Ret.Features.push_back(x: "-" + Feature.split(Separator: "-").second.str());
576	else
577	Ret.Features.push_back(x: "+" + Feature.str());
578	}
579	return Ret;
580	}
581
582	TargetInfo::CallingConvKind
583	TargetInfo::getCallingConvKind(bool ClangABICompat4) const {
584	if (getCXXABI() != TargetCXXABI::Microsoft &&
585	(ClangABICompat4 \|\| getTriple().isPS4()))
586	return CCK_ClangABI4OrPS4;
587	return CCK_Default;
588	}
589
590	bool TargetInfo::areDefaultedSMFStillPOD(const LangOptions &LangOpts) const {
591	return LangOpts.getClangABICompat() > LangOptions::ClangABI::Ver15;
592	}
593
594	LangAS TargetInfo::getOpenCLTypeAddrSpace(OpenCLTypeKind TK) const {
595	switch (TK) {
596	case OCLTK_Image:
597	case OCLTK_Pipe:
598	return LangAS::opencl_global;
599
600	case OCLTK_Sampler:
601	return LangAS::opencl_constant;
602
603	default:
604	return LangAS::Default;
605	}
606	}
607
608	//===----------------------------------------------------------------------===//
609
610
611	static StringRef removeGCCRegisterPrefix(StringRef Name) {
612	if (Name [`0`] == `'%'` \|\| Name [`0`] == `'#'`)
613	Name = Name.substr(Start: `1`);
614
615	return Name;
616	}
617
618	/// isValidClobber - Returns whether the passed in string is
619	/// a valid clobber in an inline asm statement. This is used by
620	/// Sema.
621	bool TargetInfo::isValidClobber(StringRef Name) const {
622	return (isValidGCCRegisterName(Name) \|\| Name == "memory" \|\| Name == "cc" \|\|
623	Name == "unwind");
624	}
625
626	/// isValidGCCRegisterName - Returns whether the passed in string
627	/// is a valid register name according to GCC. This is used by Sema for
628	/// inline asm statements.
629	bool TargetInfo::isValidGCCRegisterName(StringRef Name) const {
630	if (Name.empty())
631	return false;
632
633	// Get rid of any register prefix.
634	Name = removeGCCRegisterPrefix(Name);
635	if (Name.empty())
636	return false;
637
638	ArrayRef<const char *> Names = getGCCRegNames();
639
640	// If we have a number it maps to an entry in the register name array.
641	if (isDigit(c: Name [`0`])) {
642	unsigned n;
643	if (!Name.getAsInteger(Radix: `0`, Result&: n))
644	return n < Names.size();
645	}
646
647	// Check register names.
648	if (llvm::is_contained(Range&: Names, Element: Name))
649	return true;
650
651	// Check any additional names that we have.
652	for (const AddlRegName &ARN : getGCCAddlRegNames())
653	for (const char *AN : ARN.Names) {
654	if (!AN)
655	break;
656	// Make sure the register that the additional name is for is within
657	// the bounds of the register names from above.
658	if (AN == Name && ARN.RegNum < Names.size())
659	return true;
660	}
661
662	// Now check aliases.
663	for (const GCCRegAlias &GRA : getGCCRegAliases())
664	for (const char *A : GRA.Aliases) {
665	if (!A)
666	break;
667	if (A == Name)
668	return true;
669	}
670
671	return false;
672	}
673
674	StringRef TargetInfo::getNormalizedGCCRegisterName(StringRef Name,
675	bool ReturnCanonical) const {
676	assert(isValidGCCRegisterName(Name) && "Invalid register passed in");
677
678	// Get rid of any register prefix.
679	Name = removeGCCRegisterPrefix(Name);
680
681	ArrayRef<const char *> Names = getGCCRegNames();
682
683	// First, check if we have a number.
684	if (isDigit(c: Name [`0`])) {
685	unsigned n;
686	if (!Name.getAsInteger(Radix: `0`, Result&: n)) {
687	assert(n < Names.size() && "Out of bounds register number!");
688	return Names [n];
689	}
690	}
691
692	// Check any additional names that we have.
693	for (const AddlRegName &ARN : getGCCAddlRegNames())
694	for (const char *AN : ARN.Names) {
695	if (!AN)
696	break;
697	// Make sure the register that the additional name is for is within
698	// the bounds of the register names from above.
699	if (AN == Name && ARN.RegNum < Names.size())
700	return ReturnCanonical ? Names [ARN.RegNum] : Name;
701	}
702
703	// Now check aliases.
704	for (const GCCRegAlias &RA : getGCCRegAliases())
705	for (const char *A : RA.Aliases) {
706	if (!A)
707	break;
708	if (A == Name)
709	return RA.Register;
710	}
711
712	return Name;
713	}
714
715	bool TargetInfo::validateOutputConstraint(ConstraintInfo &Info) const {
716	const char *Name = Info.getConstraintStr().c_str();
717	// An output constraint must start with '=' or '+'
718	if (Name != `'='` && Name != `'+'`)
719	return false;
720
721	if (*Name == `'+'`)
722	Info.setIsReadWrite();
723
724	Name++;
725	while (*Name) {
726	switch (*Name) {
727	default:
728	if (!validateAsmConstraint(Name, info&: Info)) {
729	// FIXME: We temporarily return false
730	// so we can add more constraints as we hit it.
731	// Eventually, an unknown constraint should just be treated as 'g'.
732	return false;
733	}
734	break;
735	case `'&'`: // early clobber.
736	Info.setEarlyClobber();
737	break;
738	case `'%'`: // commutative.
739	// FIXME: Check that there is a another register after this one.
740	break;
741	case `'r'`: // general register.
742	Info.setAllowsRegister();
743	break;
744	case `'m'`: // memory operand.
745	case `'o'`: // offsetable memory operand.
746	case `'V'`: // non-offsetable memory operand.
747	case `'<'`: // autodecrement memory operand.
748	case `'>'`: // autoincrement memory operand.
749	Info.setAllowsMemory();
750	break;
751	case `'g'`: // general register, memory operand or immediate integer.
752	case `'X'`: // any operand.
753	Info.setAllowsRegister();
754	Info.setAllowsMemory();
755	break;
756	case `','`: // multiple alternative constraint. Pass it.
757	// Handle additional optional '=' or '+' modifiers.
758	if (Name[`1`] == `'='` \|\| Name[`1`] == `'+'`)
759	Name++;
760	break;
761	case `'#'`: // Ignore as constraint.
762	while (Name[`1`] && Name[`1`] != `','`)
763	Name++;
764	break;
765	case `'?'`: // Disparage slightly code.
766	case `'!'`: // Disparage severely.
767	case `''`: // Ignore for choosing register preferences.*
768	case `'i'`: // Ignore i,n,E,F as output constraints (match from the other
769	// chars)
770	case `'n'`:
771	case `'E'`:
772	case `'F'`:
773	break; // Pass them.
774	}
775
776	Name++;
777	}
778
779	// Early clobber with a read-write constraint which doesn't permit registers
780	// is invalid.
781	if (Info.earlyClobber() && Info.isReadWrite() && !Info.allowsRegister())
782	return false;
783
784	// If a constraint allows neither memory nor register operands it contains
785	// only modifiers. Reject it.
786	return Info.allowsMemory() \|\| Info.allowsRegister();
787	}
788
789	bool TargetInfo::resolveSymbolicName(const char *&Name,
790	ArrayRef<ConstraintInfo> OutputConstraints,
791	unsigned &Index) const {
792	assert(*Name == `'['` && "Symbolic name did not start with '['");
793	Name++;
794	const char *Start = Name;
795	while (Name && Name != `']'`)
796	Name++;
797
798	if (!*Name) {
799	// Missing ']'
800	return false;
801	}
802
803	std::string SymbolicName(Start, Name - Start);
804
805	for (Index = `0`; Index != OutputConstraints.size(); ++Index)
806	if (SymbolicName == OutputConstraints [Index].getName())
807	return true;
808
809	return false;
810	}
811
812	bool TargetInfo::validateInputConstraint(
813	MutableArrayRef<ConstraintInfo> OutputConstraints,
814	ConstraintInfo &Info) const {
815	const char *Name = Info.ConstraintStr.c_str();
816
817	if (!*Name)
818	return false;
819
820	while (*Name) {
821	switch (*Name) {
822	default:
823	// Check if we have a matching constraint
824	if (Name >= `'0'` && Name <= `'9'`) {
825	const char *DigitStart = Name;
826	while (Name[`1`] >= `'0'` && Name[`1`] <= `'9'`)
827	Name++;
828	const char *DigitEnd = Name;
829	unsigned i;
830	if (StringRef(DigitStart, DigitEnd - DigitStart + `1`)
831	.getAsInteger(Radix: `10`, Result&: i))
832	return false;
833
834	// Check if matching constraint is out of bounds.
835	if (i >= OutputConstraints.size()) return false;
836
837	// A number must refer to an output only operand.
838	if (OutputConstraints [i].isReadWrite())
839	return false;
840
841	// If the constraint is already tied, it must be tied to the
842	// same operand referenced to by the number.
843	if (Info.hasTiedOperand() && Info.getTiedOperand() != i)
844	return false;
845
846	// The constraint should have the same info as the respective
847	// output constraint.
848	Info.setTiedOperand(N: i, Output&: OutputConstraints [i]);
849	} else if (!validateAsmConstraint(Name, info&: Info)) {
850	// FIXME: This error return is in place temporarily so we can
851	// add more constraints as we hit it. Eventually, an unknown
852	// constraint should just be treated as 'g'.
853	return false;
854	}
855	break;
856	case `'['`: {
857	unsigned Index = `0`;
858	if (!resolveSymbolicName(Name, OutputConstraints, Index))
859	return false;
860
861	// If the constraint is already tied, it must be tied to the
862	// same operand referenced to by the number.
863	if (Info.hasTiedOperand() && Info.getTiedOperand() != Index)
864	return false;
865
866	// A number must refer to an output only operand.
867	if (OutputConstraints [Index].isReadWrite())
868	return false;
869
870	Info.setTiedOperand(N: Index, Output&: OutputConstraints [Index]);
871	break;
872	}
873	case `'%'`: // commutative
874	// FIXME: Fail if % is used with the last operand.
875	break;
876	case `'i'`: // immediate integer.
877	break;
878	case `'n'`: // immediate integer with a known value.
879	Info.setRequiresImmediate();
880	break;
881	case `'I'`: // Various constant constraints with target-specific meanings.
882	case `'J'`:
883	case `'K'`:
884	case `'L'`:
885	case `'M'`:
886	case `'N'`:
887	case `'O'`:
888	case `'P'`:
889	if (!validateAsmConstraint(Name, info&: Info))
890	return false;
891	break;
892	case `'r'`: // general register.
893	Info.setAllowsRegister();
894	break;
895	case `'m'`: // memory operand.
896	case `'o'`: // offsettable memory operand.
897	case `'V'`: // non-offsettable memory operand.
898	case `'<'`: // autodecrement memory operand.
899	case `'>'`: // autoincrement memory operand.
900	Info.setAllowsMemory();
901	break;
902	case `'g'`: // general register, memory operand or immediate integer.
903	case `'X'`: // any operand.
904	Info.setAllowsRegister();
905	Info.setAllowsMemory();
906	break;
907	case `'E'`: // immediate floating point.
908	case `'F'`: // immediate floating point.
909	case `'p'`: // address operand.
910	break;
911	case `','`: // multiple alternative constraint. Ignore comma.
912	break;
913	case `'#'`: // Ignore as constraint.
914	while (Name[`1`] && Name[`1`] != `','`)
915	Name++;
916	break;
917	case `'?'`: // Disparage slightly code.
918	case `'!'`: // Disparage severely.
919	case `''`: // Ignore for choosing register preferences.*
920	break; // Pass them.
921	}
922
923	Name++;
924	}
925
926	return true;
927	}
928
929	bool TargetInfo::validatePointerAuthKey(const llvm::APSInt &value) const {
930	return false;
931	}
932
933	void TargetInfo::CheckFixedPointBits() const {
934	// Check that the number of fractional and integral bits (and maybe sign) can
935	// fit into the bits given for a fixed point type.
936	assert(ShortAccumScale + getShortAccumIBits() + `1` <= ShortAccumWidth);
937	assert(AccumScale + getAccumIBits() + `1` <= AccumWidth);
938	assert(LongAccumScale + getLongAccumIBits() + `1` <= LongAccumWidth);
939	assert(getUnsignedShortAccumScale() + getUnsignedShortAccumIBits() <=
940	ShortAccumWidth);
941	assert(getUnsignedAccumScale() + getUnsignedAccumIBits() <= AccumWidth);
942	assert(getUnsignedLongAccumScale() + getUnsignedLongAccumIBits() <=
943	LongAccumWidth);
944
945	assert(getShortFractScale() + `1` <= ShortFractWidth);
946	assert(getFractScale() + `1` <= FractWidth);
947	assert(getLongFractScale() + `1` <= LongFractWidth);
948	assert(getUnsignedShortFractScale() <= ShortFractWidth);
949	assert(getUnsignedFractScale() <= FractWidth);
950	assert(getUnsignedLongFractScale() <= LongFractWidth);
951
952	// Each unsigned fract type has either the same number of fractional bits
953	// as, or one more fractional bit than, its corresponding signed fract type.
954	assert(getShortFractScale() == getUnsignedShortFractScale() \|\|
955	getShortFractScale() == getUnsignedShortFractScale() - `1`);
956	assert(getFractScale() == getUnsignedFractScale() \|\|
957	getFractScale() == getUnsignedFractScale() - `1`);
958	assert(getLongFractScale() == getUnsignedLongFractScale() \|\|
959	getLongFractScale() == getUnsignedLongFractScale() - `1`);
960
961	// When arranged in order of increasing rank (see 6.3.1.3a), the number of
962	// fractional bits is nondecreasing for each of the following sets of
963	// fixed-point types:
964	// - signed fract types
965	// - unsigned fract types
966	// - signed accum types
967	// - unsigned accum types.
968	assert(getLongFractScale() >= getFractScale() &&
969	getFractScale() >= getShortFractScale());
970	assert(getUnsignedLongFractScale() >= getUnsignedFractScale() &&
971	getUnsignedFractScale() >= getUnsignedShortFractScale());
972	assert(LongAccumScale >= AccumScale && AccumScale >= ShortAccumScale);
973	assert(getUnsignedLongAccumScale() >= getUnsignedAccumScale() &&
974	getUnsignedAccumScale() >= getUnsignedShortAccumScale());
975
976	// When arranged in order of increasing rank (see 6.3.1.3a), the number of
977	// integral bits is nondecreasing for each of the following sets of
978	// fixed-point types:
979	// - signed accum types
980	// - unsigned accum types
981	assert(getLongAccumIBits() >= getAccumIBits() &&
982	getAccumIBits() >= getShortAccumIBits());
983	assert(getUnsignedLongAccumIBits() >= getUnsignedAccumIBits() &&
984	getUnsignedAccumIBits() >= getUnsignedShortAccumIBits());
985
986	// Each signed accum type has at least as many integral bits as its
987	// corresponding unsigned accum type.
988	assert(getShortAccumIBits() >= getUnsignedShortAccumIBits());
989	assert(getAccumIBits() >= getUnsignedAccumIBits());
990	assert(getLongAccumIBits() >= getUnsignedLongAccumIBits());
991	}
992
993	void TargetInfo::copyAuxTarget(const TargetInfo *Aux) {
994	auto Target = static_cast<TransferrableTargetInfo>(this);
995	auto Src = static_cast<const* TransferrableTargetInfo*>(Aux);
996	Target = Src;
997	}
998

source code of clang/lib/Basic/TargetInfo.cpp