File Coverage

/usr/local/lib/perl5/site_perl/5.26.1/x86_64-linux/XS/Framework.x/i/xs/Array.h

Criterion	Covered	Total	%
statement	23	28	82.1
branch	9	22	40.9
condition			n/a
subroutine			n/a
pod			n/a
total	32	50	64.0

line	stmt	bran	code
1			#pragma once
2			#include
3			#include
4
5			namespace xs {
6
7			using xs::my_perl;
8
9			struct Simple;
10
11	4		struct Array : Sv {
12			enum create_type_t { ALIAS, COPY };
13
14			static Array create () { return Array(newAV(), NONE); }
15
16			static Array create (size_t cap) {
17			Array ret(newAV(), NONE);
18			ret.reserve(cap);
19			return ret;
20			}
21
22			static Array create (size_t size, SV** content, create_type_t type = ALIAS);
23			static Array create (const std::initializer_list& l, create_type_t type = ALIAS) { return Array(l, type); }
24			static Array create (const Array& from, create_type_t type = ALIAS) { return create(from.size(), from._svlist(), type); }
25
26			static Array noinc (SV* val) { return Array(val, NONE); }
27			static Array noinc (AV* val) { return Array(val, NONE); }
28
29			Array (std::nullptr_t = nullptr) {}
30	2	50	Array (SV* sv, bool policy = INCREMENT) : Sv(sv, policy) { _validate(); }
31	0		Array (AV* sv, bool policy = INCREMENT) : Sv(sv, policy) {}
32
33			Array (const Array& oth) : Sv(oth) {}
34			Array (Array&& oth) : Sv(std::move(oth)) {}
35			Array (const Sv& oth) : Sv(oth) { _validate(); }
36			Array (Sv&& oth) : Sv(std::move(oth)) { _validate(); }
37			Array (const Simple&) = delete;
38			Array (const Hash&) = delete;
39			Array (const Sub&) = delete;
40			Array (const Glob&) = delete;
41			Array (const Io&) = delete;
42
43			Array (const std::initializer_list& l, create_type_t type = ALIAS);
44
45			Array& operator= (SV* val) { Sv::operator=(val); _validate(); return *this; }
46			Array& operator= (AV* val) { Sv::operator=(val); return *this; }
47			Array& operator= (const Array& oth) { Sv::operator=(oth); return *this; }
48			Array& operator= (Array&& oth) { Sv::operator=(std::move(oth)); return *this; }
49			Array& operator= (const Sv& oth) { return operator=(oth.get()); }
50			Array& operator= (Sv&& oth) { Sv::operator=(std::move(oth)); _validate(); return *this; }
51			Array& operator= (const Simple&) = delete;
52			Array& operator= (const Hash&) = delete;
53			Array& operator= (const Sub&) = delete;
54			Array& operator= (const Glob&) = delete;
55			Array& operator= (const Io&) = delete;
56
57			void set (SV* val) { Sv::operator=(val); }
58
59			operator AV* () const { return (AV*)sv; }
60			operator HV* () const = delete;
61			operator CV* () const = delete;
62			operator GV* () const = delete;
63			operator IO* () const = delete;
64
65			AV* operator-> () const { return (AV*)sv; }
66
67			template panda::enable_if_one_of_t* get () const { return (T*)sv; }
68
69			Scalar fetch (size_t key) const {
70			if (!sv) return Scalar();
71			if (key >= _size()) return Scalar();
72			Scalar ret;
73			ret.set(_svlist()[key]);
74			return ret;
75			}
76
77			Scalar front () const { return fetch(0); }
78			Scalar back () const { return sv && _size() ? fetch(_topi()) : Scalar(); }
79
80			Scalar at (size_t key) const {
81			Scalar ret = fetch(key);
82			if (!ret) throw std::out_of_range("at: no key");
83			return ret;
84			}
85
86			template >
87			Scalar operator[] (T key) const {
88			Scalar ret;
89			ret.set(_svlist()[key]);
90			return ret;
91			}
92
93			void store (size_t key, const Scalar& val);
94			void store (size_t key, std::nullptr_t) { store(key, Scalar()); }
95			void store (size_t key, SV* v) { store(key, Scalar(v)); }
96			void store (size_t key, const Sv& v) { store(key, Scalar(v)); }
97			void store (size_t key, const Array&) = delete;
98			void store (size_t key, const Hash&) = delete;
99			void store (size_t key, const Sub&) = delete;
100			void store (size_t key, const Io&) = delete;
101
102			template >
103			KeyProxy operator[] (T key) { return KeyProxy(_svlist() + key, true); }
104
105			bool exists (size_t key) const {
106			if (key >= size()) return false;
107			return _svlist()[key];
108			}
109
110			Scalar del (size_t key) {
111			Scalar ret = fetch(key);
112			if (ret) (*this)[key] = nullptr;
113			return ret;
114			}
115
116	4	50	size_t size () const { return sv ? _size() : 0; }
117			size_t capacity () const { return sv ? _cap() : 0; }
118			SSize_t top_index () const { return sv ? _topi() : -1; }
119
120			void resize (size_t newsz) { av_fill((AV*)sv, (SSize_t)newsz - 1); }
121			void reserve (size_t newcap) { av_extend((AV*)sv, (SSize_t)newcap - 1); }
122
123			Scalar shift () {
124			if (!sv) return Scalar();
125			SV* retsv = av_shift((AV*)sv);
126			if (retsv == &PL_sv_undef) return Scalar();
127			Scalar ret;
128			ret.set(retsv);
129			SvREFCNT_dec(retsv); // because av_shift does not decrement, just transfers ownership
130			return ret;
131			}
132
133			Scalar pop () {
134			if (!sv) return Scalar();
135			SV* retsv = av_pop((AV*)sv);
136			if (retsv == &PL_sv_undef) return Scalar();
137			Scalar ret;
138			ret.set(retsv);
139			SvREFCNT_dec(retsv); // because av_pop does not decrement, just transfers ownership
140			return ret;
141			}
142
143			void push (const std::initializer_list& l);
144			void push (const List& l);
145			void push (const Scalar& v);
146			void push (const Array&) = delete;
147			void push (const Hash&) = delete;
148			void push (const Sub&) = delete;
149			void push (const Io&) = delete;
150			void push (SV* v) { push(Scalar(v)); }
151			void push (const Sv& v) { push(Scalar(v)); }
152
153			void unshift (const std::initializer_list& l);
154			void unshift (const List& l);
155			void unshift (const Scalar& v);
156			void unshift (const Array&) = delete;
157			void unshift (const Hash&) = delete;
158			void unshift (const Sub&) = delete;
159			void unshift (const Io&) = delete;
160			void unshift (SV* v) { unshift(Scalar(v)); }
161			void unshift (const Sv& v) { unshift(Scalar(v)); }
162
163			void undef () { if (sv) av_undef((AV*)sv); }
164			void clear () { if (sv) av_clear((AV*)sv); }
165
166			struct const_iterator : private std::iterator {
167	0		const_iterator () : cur(nullptr) {}
168	8		const_iterator (SV** avfirst) : cur(avfirst) {}
169
170	16		const_iterator& operator++ () { ++cur; return *this; }
171			const_iterator& operator-- () { --cur; return *this; }
172
173			const_iterator operator++ (int) { const_iterator ret = *this; operator++(); return ret; }
174			const_iterator operator-- (int) { const_iterator ret = *this; operator--(); return ret; }
175
176			const_iterator& operator+= (ptrdiff_t n) { cur += n; return *this; }
177			const_iterator& operator-= (ptrdiff_t n) { cur -= n; return *this; }
178
179			bool operator== (const const_iterator& oth) const { return cur == oth.cur; }
180	20		bool operator!= (const const_iterator& oth) const { return cur != oth.cur; }
181
182			const Scalar* operator-> () { return (const Scalar*)cur; }
183			const Scalar& operator* () { return ((const Scalar)cur); }
184
185			ptrdiff_t operator- (const const_iterator& rh) { return cur - rh.cur; }
186
187			bool operator< (const const_iterator& rh) { return cur < rh.cur; }
188			bool operator<= (const const_iterator& rh) { return cur <= rh.cur; }
189			bool operator> (const const_iterator& rh) { return cur > rh.cur; }
190			bool operator>= (const const_iterator& rh) { return cur >= rh.cur; }
191
192			const Scalar& operator[] (size_t key) { return ((const Scalar)(cur+key)); }
193
194			protected:
195			SV** cur;
196			};
197
198	0		struct iterator : private std::iterator, const_iterator {
199	8		using const_iterator::const_iterator;
200
201	16		iterator& operator++ () { const_iterator::operator++(); return *this; }
202			iterator& operator-- () { const_iterator::operator--(); return *this; }
203
204			iterator operator++ (int) { iterator ret = *this; const_iterator::operator++(); return ret; }
205			iterator operator-- (int) { iterator ret = *this; const_iterator::operator--(); return ret; }
206
207			iterator& operator+= (ptrdiff_t n) { const_iterator::operator+=(n); return *this; }
208			iterator& operator-= (ptrdiff_t n) { const_iterator::operator-=(n); return *this; }
209
210			Scalar* operator-> () { return (Scalar*)cur; }
211	16		KeyProxy operator* () { return KeyProxy(cur, true); }
212			KeyProxy operator[] (size_t key) { return KeyProxy(cur+key, true); }
213			};
214
215			const_iterator cbegin () const { return sv ? const_iterator(_svlist()) : const_iterator(); }
216			const_iterator cend () const { return sv ? const_iterator(_svlist()+_size()) : const_iterator(); }
217			const_iterator begin () const { return cbegin(); }
218			const_iterator end () const { return cend(); }
219	4	50	iterator begin () { return sv ? iterator(_svlist()) : iterator(); }
220	4	50	iterator end () { return sv ? iterator(_svlist()+_size()) : iterator(); }
221
222			U32 push_on_stack (SV** sp, U32 max = 0) const;
223
224			private:
225	8		inline SV** _svlist () const { return AvARRAY((AV*)sv); }
226	8		inline size_t _size () const { return (size_t)(_topi()+1); }
227			inline void _size (size_t i) { AvFILLp((AV*)sv) = (SSize_t)i-1; }
228			inline size_t _cap () const { return (size_t)(AvMAX((AV*)sv)+1); }
229	8		inline SSize_t _topi () const { return AvFILLp((AV*)sv); }
230
231	2		void _validate () {
232	2	50	if (!sv) return;
233	2	50	if (SvTYPE(sv) == SVt_PVAV) return;
234	2	50	if (SvROK(sv)) { // reference to array?
235	2		SV* val = SvRV(sv);
236	2	50	if (SvTYPE(val) == SVt_PVAV) {
237	2	50	Sv::operator=(val);
238	2		return;
239			}
240			}
241	0	0	if (is_undef()) return reset();
242	0		reset();
243	2	0	throw std::invalid_argument("SV is not an Array or Array reference");
244			}
245			};
246
247			inline xs::Array::const_iterator operator+ (const xs::Array::const_iterator& lh, ptrdiff_t rh) { return xs::Array::const_iterator(lh) += rh; }
248			inline xs::Array::const_iterator operator+ (ptrdiff_t lh, const xs::Array::const_iterator& rh) { return xs::Array::const_iterator(rh) += lh; }
249			inline xs::Array::const_iterator operator- (const xs::Array::const_iterator& lh, ptrdiff_t rh) { return xs::Array::const_iterator(lh) -= rh; }
250			inline xs::Array::iterator operator+ (const xs::Array::iterator& lh, ptrdiff_t rh) { return xs::Array::iterator(lh) += rh; }
251			inline xs::Array::iterator operator+ (ptrdiff_t lh, const xs::Array::iterator& rh) { return xs::Array::iterator(rh) += lh; }
252			inline xs::Array::iterator operator- (const xs::Array::iterator& lh, ptrdiff_t rh) { return xs::Array::iterator(lh) -= rh; }
253
254			struct List : public Array {
255			List () {}
256			List (SV* sv, bool policy = INCREMENT) : Array(sv, policy) {}
257			List (AV* sv, bool policy = INCREMENT) : Array(sv, policy) {}
258
259			List (const Array& oth) : Array(oth) {}
260			List (Array&& oth) : Array(std::move(oth)) {}
261			List (const Sv& oth) : Array(oth) {}
262			List (Sv&& oth) : Array(std::move(oth)) {}
263
264			List (const Simple&) = delete;
265			List (const Hash&) = delete;
266			List (const Sub&) = delete;
267			List (const Glob&) = delete;
268			List (const Io&) = delete;
269
270			List& operator= (SV* val) { Array::operator=(val); return *this; }
271			List& operator= (AV* val) { Array::operator=(val); return *this; }
272			List& operator= (const Array& oth) { Array::operator=(oth); return *this; }
273			List& operator= (Array&& oth) { Array::operator=(std::move(oth)); return *this; }
274			List& operator= (const Sv& oth) { Array::operator=(oth); return *this; }
275			List& operator= (Sv&& oth) { Array::operator=(std::move(oth)); return *this; }
276
277			List& operator= (const Simple&) = delete;
278			List& operator= (const Hash&) = delete;
279			List& operator= (const Sub&) = delete;
280			List& operator= (const Glob&) = delete;
281			List& operator= (const Io&) = delete;
282			};
283
284			}
285
286			// DEPRECATED, will be removed, use Array.begin()/end() instead
287			#define XS_AV_ITER(av,code) { \
288			SV** list = AvARRAY(av); \
289			SSize_t fillp = AvFILLp(av); \
290			for (SSize_t i = 0; i <= fillp; ++i) { SV* elem = *list++; code } \
291			}
292			#define XS_AV_ITER_NE(av,code) XS_AV_ITER(av,{if(!elem) continue; code})
293			#define XS_AV_ITER_NU(av,code) XS_AV_ITER(av,{if(!elem \|\| !SvOK(elem)) continue; code})
294