File Coverage

xs/meta.c

Criterion	Covered	Total	%
statement	126	130	96.9
branch	34	42	80.9
condition			n/a
subroutine			n/a
pod			n/a
total	160	172	93.0

line	stmt	bran	code
1			#include "EXTERN.h"
2			#include "perl.h"
3			#include "XSUB.h"
4			#include "ppport.h"
5			#include "ffi_platypus.h"
6
7			/*
8			* - negative shift is undefined, so while it may work somewheree we make an explicit check for the
9			* 0 size.
10			* - We will eventually migrate fixed strings to be internally of record type, for now we have to
11			* check the platypus type when we have a type_code == FFI_PL_BASE_RECORD
12			*/
13			#define unit_size(self) \
14			((self->type_code & FFI_PL_BASE_MASK) == FFI_PL_BASE_RECORD \
15			? (self->extra[0].record.size) \
16			: ((self->type_code & FFI_PL_SIZE_MASK) == FFI_PL_SIZE_0 \
17			? 0 \
18			: 1 << ((self->type_code & FFI_PL_SIZE_MASK)-1) \
19			) \
20			)
21
22			size_t
23	719		ffi_pl_sizeof_new(ffi_pl_type *self)
24			{
25	719		switch( self->type_code & FFI_PL_SHAPE_MASK )
26			{
27			case FFI_PL_SHAPE_SCALAR:
28			case FFI_PL_SHAPE_CUSTOM_PERL:
29	459	50	return unit_size(self);
		100
30			case FFI_PL_SHAPE_POINTER:
31	42		return sizeof(void*);
32			case FFI_PL_SHAPE_ARRAY:
33	218	50	return unit_size(self) * self->extra[0].array.element_count;
		50
34			default:
35	0		return 0;
36			}
37			}
38
39			size_t
40	817		ffi_pl_sizeof(ffi_pl_type *self)
41			{
42	817	100	if(self->type_code == FFI_PL_TYPE_RECORD
43	732	100	\|\| self->type_code == FFI_PL_TYPE_RECORD_VALUE
44	725	100	\|\| self->type_code == (FFI_PL_TYPE_RECORD \| FFI_PL_SHAPE_CUSTOM_PERL)
45	721	100	\|\| self->type_code == (FFI_PL_TYPE_RECORD_VALUE \| FFI_PL_SHAPE_CUSTOM_PERL))
46			{
47	98		return self->extra[0].record.size;
48			}
49			else
50			{
51	719		return ffi_pl_sizeof_new(self);
52			}
53			}
54
55			HV *
56	511		ffi_pl_get_type_meta(ffi_pl_type *self)
57			{
58			HV *meta;
59			const char *string;
60
61	511		meta = newHV();
62
63	511		hv_store(meta, "size", 4, newSViv(ffi_pl_sizeof(self)), 0);
64	511		hv_store(meta, "type_code", 9, newSViv(self->type_code), 0);
65
66	511		switch(self->type_code & FFI_PL_SHAPE_MASK)
67			{
68			case FFI_PL_SHAPE_SCALAR:
69			{
70	310		switch(self->type_code)
71			{
72
73			case FFI_PL_TYPE_STRING:
74	44		hv_store(meta, "element_size", 12, newSViv(sizeof(void*)), 0);
75	44		hv_store(meta, "type", 4, newSVpv("string",0),0);
76	44		switch(self->sub_type)
77			{
78			case FFI_PL_TYPE_STRING_RO:
79	22		hv_store(meta, "access", 6, newSVpv("ro",0), 0);
80	22		break;
81			case FFI_PL_TYPE_STRING_RW:
82	22		hv_store(meta, "access", 6, newSVpv("rw",0), 0);
83	22		break;
84			}
85	44		break;
86
87			case FFI_PL_TYPE_CLOSURE:
88			{
89			AV *signature;
90			AV *argument_types;
91			HV *subtype;
92			int i;
93			int number_of_arguments;
94
95	5		number_of_arguments = self->extra[0].closure.ffi_cif.nargs;
96
97	5		signature = newAV();
98	5		argument_types = newAV();
99
100	20	100	for(i=0; i < number_of_arguments; i++)
101			{
102	15		subtype = ffi_pl_get_type_meta(self->extra[0].closure.argument_types[i]);
103	15		av_store(argument_types, i, newRV_noinc((SV*)subtype));
104			}
105	5		av_store(signature, 0, newRV_noinc((SV*)argument_types));
106
107	5		subtype = ffi_pl_get_type_meta(self->extra[0].closure.return_type);
108	5		av_store(signature, 1, newRV_noinc((SV*)subtype));
109
110	5		hv_store(meta, "signature", 9, newRV_noinc((SV*)signature), 0);
111
112	5		hv_store(meta, "element_size", 12, newSViv(sizeof(void*)), 0);
113	5		hv_store(meta, "type", 4, newSVpv("closure",0),0);
114			}
115	5		break;
116
117			case FFI_PL_TYPE_RECORD:
118	72		hv_store(meta, "type", 4, newSVpv("record",0),0);
119	72		hv_store(meta, "ref", 3, newSViv(self->extra[0].record.class != NULL ? 1 : 0),0);
120	72	100	if(self->extra[0].record.class != NULL)
121	8		hv_store(meta, "class", 5, newSVpv(self->extra[0].record.class,0), 0);
122	72		break;
123
124			case FFI_PL_TYPE_RECORD_VALUE:
125	6		hv_store(meta, "type", 4, newSVpv("record_value",0),0);
126	6		hv_store(meta, "ref", 3, newSViv(self->extra[0].record.class != NULL ? 1 : 0),0);
127	6		hv_store(meta, "class", 5, newSVpv(self->extra[0].record.class,0), 0);
128	6		break;
129
130			default:
131	183	50	hv_store(meta, "element_size", 12, newSViv(unit_size(self)), 0);
		100
132	183		hv_store(meta, "type", 4, newSVpv("scalar",0),0);
133	183		break;
134			}
135			}
136	310		break;
137
138			case FFI_PL_SHAPE_POINTER:
139	30	50	hv_store(meta, "element_size", 12, newSViv(unit_size(self)), 0);
		50
140	30		hv_store(meta, "type", 4, newSVpv("pointer",0),0);
141	30		break;
142
143			case FFI_PL_SHAPE_ARRAY:
144	90	50	hv_store(meta, "element_size", 12, newSViv(unit_size(self)), 0);
		50
145	90		hv_store(meta, "type", 4, newSVpv("array",0),0);
146	90		hv_store(meta, "element_count", 13, newSViv(self->extra[0].array.element_count), 0);
147	90		break;
148
149			case FFI_PL_SHAPE_CUSTOM_PERL:
150	81		hv_store(meta, "type", 4, newSVpv("custom_perl",0),0);
151
152	81	100	if(self->extra[0].custom_perl.perl_to_native != NULL)
153	48		hv_store(meta, "custom_perl_to_native", 18, newRV_inc((SV*)self->extra[0].custom_perl.perl_to_native), 0);
154
155	81	100	if(self->extra[0].custom_perl.perl_to_native_post != NULL)
156	37		hv_store(meta, "custom_perl_to_native_post", 23, newRV_inc((SV*)self->extra[0].custom_perl.perl_to_native_post), 0);
157
158	81	100	if(self->extra[0].custom_perl.native_to_perl != NULL)
159	59		hv_store(meta, "custom_native_to_perl", 18, newRV_inc((SV*)self->extra[0].custom_perl.native_to_perl), 0);
160
161	81	100	if(self->type_code == (FFI_PL_TYPE_RECORD \| FFI_PL_SHAPE_CUSTOM_PERL))
162			{
163	2		hv_store(meta, "sub_type", 8, newSVpv("record",0),0);
164	2		hv_store(meta, "ref", 3, newSViv(self->extra[0].record.class != NULL ? 1 : 0),0);
165	2	100	if(self->extra[0].record.class != NULL)
166	1		hv_store(meta, "class", 5, newSVpv(self->extra[0].record.class,0), 0);
167			}
168	81		break;
169			}
170
171	511		switch(self->type_code & (FFI_PL_SIZE_MASK \| FFI_PL_BASE_MASK))
172			{
173			case FFI_PL_TYPE_VOID:
174	3		hv_store(meta, "element_type", 12, newSVpv("void",0),0);
175	3		break;
176			case FFI_PL_TYPE_FLOAT:
177			case FFI_PL_TYPE_DOUBLE:
178			#ifdef FFI_PL_PROBE_LONGDOUBLE
179			case FFI_PL_TYPE_LONG_DOUBLE:
180			#endif
181			#ifdef FFI_TARGET_HAS_COMPLEX_TYPE
182			case FFI_PL_TYPE_COMPLEX_FLOAT:
183			case FFI_PL_TYPE_COMPLEX_DOUBLE:
184			#endif
185	57		hv_store(meta, "element_type", 12, newSVpv("float",0),0);
186	57		break;
187			case FFI_PL_TYPE_UINT8:
188			case FFI_PL_TYPE_UINT16:
189			case FFI_PL_TYPE_UINT32:
190			case FFI_PL_TYPE_UINT64:
191	96		hv_store(meta, "element_type", 12, newSVpv("int",0),0);
192	96		hv_store(meta, "sign", 4, newSViv(0),0);
193	96		break;
194			case FFI_PL_TYPE_SINT8:
195			case FFI_PL_TYPE_SINT16:
196			case FFI_PL_TYPE_SINT32:
197			case FFI_PL_TYPE_SINT64:
198	191		hv_store(meta, "element_type", 12, newSVpv("int",0),0);
199	191		hv_store(meta, "sign", 4, newSViv(1),0);
200	191		break;
201			case FFI_PL_TYPE_OPAQUE:
202	30		hv_store(meta, "element_type", 12, newSVpv("opaque",0),0);
203	30		break;
204			}
205	511		switch(self->type_code & (FFI_PL_SIZE_MASK \| FFI_PL_BASE_MASK))
206			{
207			case FFI_PL_TYPE_VOID:
208	3		string = "void";
209	3		break;
210			case FFI_PL_TYPE_FLOAT:
211	19		string = "float";
212	19		break;
213			case FFI_PL_TYPE_DOUBLE:
214	19		string = "double";
215	19		break;
216			#ifdef FFI_PL_PROBE_LONGDOUBLE
217			case FFI_PL_TYPE_LONG_DOUBLE:
218	7		string = "longdouble";
219	7		break;
220			#endif
221			case FFI_PL_TYPE_UINT8:
222	27		string = "uint8";
223	27		break;
224			case FFI_PL_TYPE_SINT8:
225	92		string = "sint8";
226	92		break;
227			case FFI_PL_TYPE_UINT16:
228	21		string = "uint16";
229	21		break;
230			case FFI_PL_TYPE_SINT16:
231	21		string = "sint16";
232	21		break;
233			case FFI_PL_TYPE_UINT32:
234	25		string = "uint32";
235	25		break;
236			case FFI_PL_TYPE_SINT32:
237	57		string = "sint32";
238	57		break;
239			case FFI_PL_TYPE_UINT64:
240	23		string = "uint64";
241	23		break;
242			case FFI_PL_TYPE_SINT64:
243	21		string = "sint64";
244	21		break;
245			case FFI_PL_TYPE_OPAQUE:
246			case FFI_PL_TYPE_STRING:
247			case FFI_PL_TYPE_CLOSURE:
248			case FFI_PL_TYPE_RECORD:
249	157		string = "pointer";
250	157		break;
251			case FFI_PL_TYPE_RECORD_VALUE:
252	7		string = "struct";
253	7		break;
254			#ifdef FFI_TARGET_HAS_COMPLEX_TYPE
255			case FFI_PL_TYPE_COMPLEX_FLOAT:
256	6		string = "complex_float";
257	6		break;
258			case FFI_PL_TYPE_COMPLEX_DOUBLE:
259	6		string = "complex_double";
260	6		break;
261			#endif
262			default:
263	0		warn("bad type: %04x\n", self->type_code & (FFI_PL_SIZE_MASK \| FFI_PL_BASE_MASK));
264	0		string = NULL;
265	0		break;
266			}
267	511		hv_store(meta, "ffi_type", 8, newSVpv(string,0),0);
268
269	511		return meta;
270			}
271
272	2437		ffi_pl_type *ffi_pl_type_new(size_t size)
273			{
274			char *buffer;
275			ffi_pl_type *self;
276
277	2437		Newx(buffer, sizeof(ffi_pl_type) + size, char);
278	2437		self = (ffi_pl_type*) buffer;
279	2437		self->type_code = 0;
280	2437		self->sub_type = 0;
281
282	2437		return self;
283			}