Twine.h source code [include/llvm-8/llvm/ADT/Twine.h]

1	//===- Twine.h - Fast Temporary String Concatenation ------------- C++ --===//
2	//
3	// The LLVM Compiler Infrastructure
4	//
5	// This file is distributed under the University of Illinois Open Source
6	// License. See LICENSE.TXT for details.
7	//
8	//===----------------------------------------------------------------------===//
9
10	#ifndef LLVM_ADT_TWINE_H
11	#define LLVM_ADT_TWINE_H
12
13	#include "llvm/ADT/SmallVector.h"
14	#include "llvm/ADT/StringRef.h"
15	#include "llvm/Support/ErrorHandling.h"
16	#include <cassert>
17	#include <cstdint>
18	#include <string>
19
20	namespace llvm {
21
22	class formatv_object_base;
23	class raw_ostream;
24
25	/// Twine - A lightweight data structure for efficiently representing the
26	/// concatenation of temporary values as strings.
27	///
28	/// A Twine is a kind of rope, it represents a concatenated string using a
29	/// binary-tree, where the string is the preorder of the nodes. Since the
30	/// Twine can be efficiently rendered into a buffer when its result is used,
31	/// it avoids the cost of generating temporary values for intermediate string
32	/// results -- particularly in cases when the Twine result is never
33	/// required. By explicitly tracking the type of leaf nodes, we can also avoid
34	/// the creation of temporary strings for conversions operations (such as
35	/// appending an integer to a string).
36	///
37	/// A Twine is not intended for use directly and should not be stored, its
38	/// implementation relies on the ability to store pointers to temporary stack
39	/// objects which may be deallocated at the end of a statement. Twines should
40	/// only be used accepted as const references in arguments, when an API wishes
41	/// to accept possibly-concatenated strings.
42	///
43	/// Twines support a special 'null' value, which always concatenates to form
44	/// itself, and renders as an empty string. This can be returned from APIs to
45	/// effectively nullify any concatenations performed on the result.
46	///
47	/// \b Implementation
48	///
49	/// Given the nature of a Twine, it is not possible for the Twine's
50	/// concatenation method to construct interior nodes; the result must be
51	/// represented inside the returned value. For this reason a Twine object
52	/// actually holds two values, the left- and right-hand sides of a
53	/// concatenation. We also have nullary Twine objects, which are effectively
54	/// sentinel values that represent empty strings.
55	///
56	/// Thus, a Twine can effectively have zero, one, or two children. The \see
57	/// isNullary(), \see isUnary(), and \see isBinary() predicates exist for
58	/// testing the number of children.
59	///
60	/// We maintain a number of invariants on Twine objects (FIXME: Why):
61	/// - Nullary twines are always represented with their Kind on the left-hand
62	/// side, and the Empty kind on the right-hand side.
63	/// - Unary twines are always represented with the value on the left-hand
64	/// side, and the Empty kind on the right-hand side.
65	/// - If a Twine has another Twine as a child, that child should always be
66	/// binary (otherwise it could have been folded into the parent).
67	///
68	/// These invariants are check by \see isValid().
69	///
70	/// \b Efficiency Considerations
71	///
72	/// The Twine is designed to yield efficient and small code for common
73	/// situations. For this reason, the concat() method is inlined so that
74	/// concatenations of leaf nodes can be optimized into stores directly into a
75	/// single stack allocated object.
76	///
77	/// In practice, not all compilers can be trusted to optimize concat() fully,
78	/// so we provide two additional methods (and accompanying operator+
79	/// overloads) to guarantee that particularly important cases (cstring plus
80	/// StringRef) codegen as desired.
81	class Twine {
82	/// NodeKind - Represent the type of an argument.
83	enum NodeKind : unsigned char {
84	/// An empty string; the result of concatenating anything with it is also
85	/// empty.
86	NullKind,
87
88	/// The empty string.
89	EmptyKind,
90
91	/// A pointer to a Twine instance.
92	TwineKind,
93
94	/// A pointer to a C string instance.
95	CStringKind,
96
97	/// A pointer to an std::string instance.
98	StdStringKind,
99
100	/// A pointer to a StringRef instance.
101	StringRefKind,
102
103	/// A pointer to a SmallString instance.
104	SmallStringKind,
105
106	/// A pointer to a formatv_object_base instance.
107	FormatvObjectKind,
108
109	/// A char value, to render as a character.
110	CharKind,
111
112	/// An unsigned int value, to render as an unsigned decimal integer.
113	DecUIKind,
114
115	/// An int value, to render as a signed decimal integer.
116	DecIKind,
117
118	/// A pointer to an unsigned long value, to render as an unsigned decimal
119	/// integer.
120	DecULKind,
121
122	/// A pointer to a long value, to render as a signed decimal integer.
123	DecLKind,
124
125	/// A pointer to an unsigned long long value, to render as an unsigned
126	/// decimal integer.
127	DecULLKind,
128
129	/// A pointer to a long long value, to render as a signed decimal integer.
130	DecLLKind,
131
132	/// A pointer to a uint64_t value, to render as an unsigned hexadecimal
133	/// integer.
134	UHexKind
135	};
136
137	union Child
138	{
139	const Twine *twine;
140	const char *cString;
141	const std::string *stdString;
142	const StringRef *stringRef;
143	const SmallVectorImpl<char> *smallString;
144	const formatv_object_base *formatvObject;
145	char character;
146	unsigned int decUI;
147	int decI;
148	const unsigned long *decUL;
149	const long *decL;
150	const unsigned long long *decULL;
151	const long long *decLL;
152	const uint64_t *uHex;
153	};
154
155	/// LHS - The prefix in the concatenation, which may be uninitialized for
156	/// Null or Empty kinds.
157	Child LHS;
158
159	/// RHS - The suffix in the concatenation, which may be uninitialized for
160	/// Null or Empty kinds.
161	Child RHS;
162
163	/// LHSKind - The NodeKind of the left hand side, \see getLHSKind().
164	NodeKind LHSKind = EmptyKind;
165
166	/// RHSKind - The NodeKind of the right hand side, \see getRHSKind().
167	NodeKind RHSKind = EmptyKind;
168
169	/// Construct a nullary twine; the kind must be NullKind or EmptyKind.
170	explicit Twine(NodeKind Kind) : LHSKind(Kind) {
171	assert(isNullary() && "Invalid kind!");
172	}
173
174	/// Construct a binary twine.
175	explicit Twine(const Twine &LHS, const Twine &RHS)
176	: LHSKind(TwineKind), RHSKind(TwineKind) {
177	this->LHS.twine = &LHS;
178	this->RHS.twine = &RHS;
179	assert(isValid() && "Invalid twine!");
180	}
181
182	/// Construct a twine from explicit values.
183	explicit Twine(Child LHS, NodeKind LHSKind, Child RHS, NodeKind RHSKind)
184	: LHS (LHS), RHS (RHS), LHSKind(LHSKind), RHSKind(RHSKind) {
185	assert(isValid() && "Invalid twine!");
186	}
187
188	/// Check for the null twine.
189	bool isNull() const {
190	return getLHSKind() == NullKind;
191	}
192
193	/// Check for the empty twine.
194	bool isEmpty() const {
195	return getLHSKind() == EmptyKind;
196	}
197
198	/// Check if this is a nullary twine (null or empty).
199	bool isNullary() const {
200	return isNull() \|\| isEmpty();
201	}
202
203	/// Check if this is a unary twine.
204	bool isUnary() const {
205	return getRHSKind() == EmptyKind && !isNullary();
206	}
207
208	/// Check if this is a binary twine.
209	bool isBinary() const {
210	return getLHSKind() != NullKind && getRHSKind() != EmptyKind;
211	}
212
213	/// Check if this is a valid twine (satisfying the invariants on
214	/// order and number of arguments).
215	bool isValid() const {
216	// Nullary twines always have Empty on the RHS.
217	if (isNullary() && getRHSKind() != EmptyKind)
218	return false;
219
220	// Null should never appear on the RHS.
221	if (getRHSKind() == NullKind)
222	return false;
223
224	// The RHS cannot be non-empty if the LHS is empty.
225	if (getRHSKind() != EmptyKind && getLHSKind() == EmptyKind)
226	return false;
227
228	// A twine child should always be binary.
229	if (getLHSKind() == TwineKind &&
230	!LHS.twine->isBinary())
231	return false;
232	if (getRHSKind() == TwineKind &&
233	!RHS.twine->isBinary())
234	return false;
235
236	return true;
237	}
238
239	/// Get the NodeKind of the left-hand side.
240	NodeKind getLHSKind() const { return LHSKind; }
241
242	/// Get the NodeKind of the right-hand side.
243	NodeKind getRHSKind() const { return RHSKind; }
244
245	/// Print one child from a twine.
246	void printOneChild(raw_ostream &OS, Child Ptr, NodeKind Kind) const;
247
248	/// Print the representation of one child from a twine.
249	void printOneChildRepr(raw_ostream &OS, Child Ptr,
250	NodeKind Kind) const;
251
252	public:
253	/// @name Constructors
254	/// @{
255
256	/// Construct from an empty string.
257	/implicit/ Twine() {
258	assert(isValid() && "Invalid twine!");
259	}
260
261	Twine(const Twine &) = default;
262
263	/// Construct from a C string.
264	///
265	/// We take care here to optimize "" into the empty twine -- this will be
266	/// optimized out for string constants. This allows Twine arguments have
267	/// default "" values, without introducing unnecessary string constants.
268	/implicit/ Twine(const char *Str) {
269	if (Str[`0`] != `'\0'`) {
270	LHS.cString = Str;
271	LHSKind = CStringKind;
272	} else
273	LHSKind = EmptyKind;
274
275	assert(isValid() && "Invalid twine!");
276	}
277
278	/// Construct from an std::string.
279	/implicit/ Twine(const std::string &Str) : LHSKind(StdStringKind) {
280	LHS.stdString = &Str;
281	assert(isValid() && "Invalid twine!");
282	}
283
284	/// Construct from a StringRef.
285	/implicit/ Twine(const StringRef &Str) : LHSKind(StringRefKind) {
286	LHS.stringRef = &Str;
287	assert(isValid() && "Invalid twine!");
288	}
289
290	/// Construct from a SmallString.
291	/implicit/ Twine(const SmallVectorImpl<char> &Str)
292	: LHSKind(SmallStringKind) {
293	LHS.smallString = &Str;
294	assert(isValid() && "Invalid twine!");
295	}
296
297	/// Construct from a formatv_object_base.
298	/implicit/ Twine(const formatv_object_base &Fmt)
299	: LHSKind(FormatvObjectKind) {
300	LHS.formatvObject = &Fmt;
301	assert(isValid() && "Invalid twine!");
302	}
303
304	/// Construct from a char.
305	explicit Twine(char Val) : LHSKind(CharKind) {
306	LHS.character = Val;
307	}
308
309	/// Construct from a signed char.
310	explicit Twine(signed char Val) : LHSKind(CharKind) {
311	LHS.character = static_cast<char>(Val);
312	}
313
314	/// Construct from an unsigned char.
315	explicit Twine(unsigned char Val) : LHSKind(CharKind) {
316	LHS.character = static_cast<char>(Val);
317	}
318
319	/// Construct a twine to print \p Val as an unsigned decimal integer.
320	explicit Twine(unsigned Val) : LHSKind(DecUIKind) {
321	LHS.decUI = Val;
322	}
323
324	/// Construct a twine to print \p Val as a signed decimal integer.
325	explicit Twine(int Val) : LHSKind(DecIKind) {
326	LHS.decI = Val;
327	}
328
329	/// Construct a twine to print \p Val as an unsigned decimal integer.
330	explicit Twine(const unsigned long &Val) : LHSKind(DecULKind) {
331	LHS.decUL = &Val;
332	}
333
334	/// Construct a twine to print \p Val as a signed decimal integer.
335	explicit Twine(const long &Val) : LHSKind(DecLKind) {
336	LHS.decL = &Val;
337	}
338
339	/// Construct a twine to print \p Val as an unsigned decimal integer.
340	explicit Twine(const unsigned long long &Val) : LHSKind(DecULLKind) {
341	LHS.decULL = &Val;
342	}
343
344	/// Construct a twine to print \p Val as a signed decimal integer.
345	explicit Twine(const long long &Val) : LHSKind(DecLLKind) {
346	LHS.decLL = &Val;
347	}
348
349	// FIXME: Unfortunately, to make sure this is as efficient as possible we
350	// need extra binary constructors from particular types. We can't rely on
351	// the compiler to be smart enough to fold operator+()/concat() down to the
352	// right thing. Yet.
353
354	/// Construct as the concatenation of a C string and a StringRef.
355	/implicit/ Twine(const char LHS, const* StringRef &RHS)
356	: LHSKind(CStringKind), RHSKind(StringRefKind) {
357	this->LHS.cString = LHS;
358	this->RHS.stringRef = &RHS;
359	assert(isValid() && "Invalid twine!");
360	}
361
362	/// Construct as the concatenation of a StringRef and a C string.
363	/implicit/ Twine(const StringRef &LHS, const char *RHS)
364	: LHSKind(StringRefKind), RHSKind(CStringKind) {
365	this->LHS.stringRef = &LHS;
366	this->RHS.cString = RHS;
367	assert(isValid() && "Invalid twine!");
368	}
369
370	/// Since the intended use of twines is as temporary objects, assignments
371	/// when concatenating might cause undefined behavior or stack corruptions
372	Twine &operator=(const Twine &) = delete;
373
374	/// Create a 'null' string, which is an empty string that always
375	/// concatenates to form another empty string.
376	static Twine createNull() {
377	return Twine (NullKind);
378	}
379
380	/// @}
381	/// @name Numeric Conversions
382	/// @{
383
384	// Construct a twine to print \p Val as an unsigned hexadecimal integer.
385	static Twine utohexstr(const uint64_t &Val) {
386	Child LHS, RHS;
387	LHS.uHex = &Val;
388	RHS.twine = nullptr;
389	return Twine (LHS, UHexKind, RHS, EmptyKind);
390	}
391
392	/// @}
393	/// @name Predicate Operations
394	/// @{
395
396	/// Check if this twine is trivially empty; a false return value does not
397	/// necessarily mean the twine is empty.
398	bool isTriviallyEmpty() const {
399	return isNullary();
400	}
401
402	/// Return true if this twine can be dynamically accessed as a single
403	/// StringRef value with getSingleStringRef().
404	bool isSingleStringRef() const {
405	if (getRHSKind() != EmptyKind) return false;
406
407	switch (getLHSKind()) {
408	case EmptyKind:
409	case CStringKind:
410	case StdStringKind:
411	case StringRefKind:
412	case SmallStringKind:
413	return true;
414	default:
415	return false;
416	}
417	}
418
419	/// @}
420	/// @name String Operations
421	/// @{
422
423	Twine concat(const Twine &Suffix) const;
424
425	/// @}
426	/// @name Output & Conversion.
427	/// @{
428
429	/// Return the twine contents as a std::string.
430	std::string str() const;
431
432	/// Append the concatenated string into the given SmallString or SmallVector.
433	void toVector(SmallVectorImpl<char> &Out) const;
434
435	/// This returns the twine as a single StringRef. This method is only valid
436	/// if isSingleStringRef() is true.
437	StringRef getSingleStringRef() const {
438	assert(isSingleStringRef() &&"This cannot be had as a single stringref!");
439	switch (getLHSKind()) {
440	default: llvm_unreachable("Out of sync with isSingleStringRef");
441	case EmptyKind: return StringRef ();
442	case CStringKind: return StringRef (LHS.cString);
443	case StdStringKind: return StringRef (*LHS.stdString);
444	case StringRefKind: return *LHS.stringRef;
445	case SmallStringKind:
446	return StringRef (LHS.smallString->data(), LHS.smallString->size());
447	}
448	}
449
450	/// This returns the twine as a single StringRef if it can be
451	/// represented as such. Otherwise the twine is written into the given
452	/// SmallVector and a StringRef to the SmallVector's data is returned.
453	StringRef toStringRef(SmallVectorImpl<char> &Out) const {
454	if (isSingleStringRef())
455	return getSingleStringRef();
456	toVector(Out);
457	return StringRef (Out.data(), Out.size());
458	}
459
460	/// This returns the twine as a single null terminated StringRef if it
461	/// can be represented as such. Otherwise the twine is written into the
462	/// given SmallVector and a StringRef to the SmallVector's data is returned.
463	///
464	/// The returned StringRef's size does not include the null terminator.
465	StringRef toNullTerminatedStringRef(SmallVectorImpl<char> &Out) const;
466
467	/// Write the concatenated string represented by this twine to the
468	/// stream \p OS.
469	void print(raw_ostream &OS) const;
470
471	/// Dump the concatenated string represented by this twine to stderr.
472	void dump() const;
473
474	/// Write the representation of this twine to the stream \p OS.
475	void printRepr(raw_ostream &OS) const;
476
477	/// Dump the representation of this twine to stderr.
478	void dumpRepr() const;
479
480	/// @}
481	};
482
483	/// @name Twine Inline Implementations
484	/// @{
485
486	inline Twine Twine::concat(const Twine &Suffix) const {
487	// Concatenation with null is null.
488	if (isNull() \|\| Suffix.isNull())
489	return Twine (NullKind);
490
491	// Concatenation with empty yields the other side.
492	if (isEmpty())
493	return Suffix;
494	if (Suffix.isEmpty())
495	return *this;
496
497	// Otherwise we need to create a new node, taking care to fold in unary
498	// twines.
499	Child NewLHS, NewRHS;
500	NewLHS.twine = this;
501	NewRHS.twine = &Suffix;
502	NodeKind NewLHSKind = TwineKind, NewRHSKind = TwineKind;
503	if (isUnary()) {
504	NewLHS = LHS;
505	NewLHSKind = getLHSKind();
506	}
507	if (Suffix.isUnary()) {
508	NewRHS = Suffix.LHS;
509	NewRHSKind = Suffix.getLHSKind();
510	}
511
512	return Twine (NewLHS, NewLHSKind, NewRHS, NewRHSKind);
513	}
514
515	inline Twine operator+(const Twine &LHS, const Twine &RHS) {
516	return LHS.concat(RHS);
517	}
518
519	/// Additional overload to guarantee simplified codegen; this is equivalent to
520	/// concat().
521
522	inline Twine operator+(const char LHS, const* StringRef &RHS) {
523	return Twine (LHS, RHS);
524	}
525
526	/// Additional overload to guarantee simplified codegen; this is equivalent to
527	/// concat().
528
529	inline Twine operator+(const StringRef &LHS, const char *RHS) {
530	return Twine (LHS, RHS);
531	}
532
533	inline raw_ostream &operator<<(raw_ostream &OS, const Twine &RHS) {
534	RHS.print(OS);
535	return OS;
536	}
537
538	/// @}
539
540	} // end namespace llvm
541
542	#endif // LLVM_ADT_TWINE_H
543

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