1 /* $NetBSD: prop_number.c,v 1.22 2009/03/15 22:29:11 cegger Exp $ */
4 * Copyright (c) 2006 The NetBSD Foundation, Inc.
7 * This code is derived from software contributed to The NetBSD Foundation
10 * Redistribution and use in source and binary forms, with or without
11 * modification, are permitted provided that the following conditions
13 * 1. Redistributions of source code must retain the above copyright
14 * notice, this list of conditions and the following disclaimer.
15 * 2. Redistributions in binary form must reproduce the above copyright
16 * notice, this list of conditions and the following disclaimer in the
17 * documentation and/or other materials provided with the distribution.
19 * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
20 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
21 * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
22 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
23 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
24 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
25 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
26 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
27 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
28 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
29 * POSSIBILITY OF SUCH DAMAGE.
32 #include <libprop/prop_number.h>
33 #include "prop_object_impl.h"
34 #include "prop_rb_impl.h"
37 #include <sys/systm.h>
38 #define strtoll strtoq
39 #define strtoull strtouq
40 #define sprintf ksprintf
41 #elif defined(_STANDALONE)
42 #include <sys/param.h>
43 #include <lib/libkern/libkern.h>
50 struct _prop_object pn_obj
;
51 struct rb_node pn_link
;
52 struct _prop_number_value
{
55 uint64_t pnu_unsigned
;
57 #define pnv_signed pnv_un.pnu_signed
58 #define pnv_unsigned pnv_un.pnu_unsigned
59 unsigned int pnv_is_unsigned
:1,
64 _PROP_POOL_INIT(_prop_number_pool
, sizeof(struct _prop_number
), "propnmbr")
66 static _prop_object_free_rv_t
67 _prop_number_free(prop_stack_t
, prop_object_t
*);
68 static bool _prop_number_externalize(
69 struct _prop_object_externalize_context
*,
71 static _prop_object_equals_rv_t
72 _prop_number_equals(prop_object_t
, prop_object_t
,
74 prop_object_t
*, prop_object_t
*);
76 static void _prop_number_lock(void);
77 static void _prop_number_unlock(void);
79 static const struct _prop_object_type _prop_object_type_number
= {
80 .pot_type
= PROP_TYPE_NUMBER
,
81 .pot_free
= _prop_number_free
,
82 .pot_extern
= _prop_number_externalize
,
83 .pot_equals
= _prop_number_equals
,
84 .pot_lock
= _prop_number_lock
,
85 .pot_unlock
= _prop_number_unlock
,
88 #define prop_object_is_number(x) \
89 ((x) != NULL && (x)->pn_obj.po_type == &_prop_object_type_number)
92 * Number objects are immutable, and we are likely to have many number
93 * objects that have the same value. So, to save memory, we unique'ify
94 * numbers so we only have one copy of each.
98 _prop_number_compare_values(const struct _prop_number_value
*pnv1
,
99 const struct _prop_number_value
*pnv2
)
102 /* Signed numbers are sorted before unsigned numbers. */
104 if (pnv1
->pnv_is_unsigned
) {
105 if (! pnv2
->pnv_is_unsigned
)
107 if (pnv1
->pnv_unsigned
< pnv2
->pnv_unsigned
)
109 if (pnv1
->pnv_unsigned
> pnv2
->pnv_unsigned
)
114 if (pnv2
->pnv_is_unsigned
)
116 if (pnv1
->pnv_signed
< pnv2
->pnv_signed
)
118 if (pnv1
->pnv_signed
> pnv2
->pnv_signed
)
125 _prop_number_rb_compare_nodes(void *ctx __unused
,
126 const void *n1
, const void *n2
)
128 const struct _prop_number
*pn1
= n1
;
129 const struct _prop_number
*pn2
= n2
;
131 return _prop_number_compare_values(&pn1
->pn_value
, &pn2
->pn_value
);
136 _prop_number_rb_compare_key(void *ctx __unused
, const void *n
, const void *v
)
138 const struct _prop_number
*pn
= n
;
139 const struct _prop_number_value
*pnv
= v
;
141 return _prop_number_compare_values(&pn
->pn_value
, pnv
);
144 static const rb_tree_ops_t _prop_number_rb_tree_ops
= {
145 .rbto_compare_nodes
= _prop_number_rb_compare_nodes
,
146 .rbto_compare_key
= _prop_number_rb_compare_key
,
147 .rbto_node_offset
= offsetof(struct _prop_number
, pn_link
),
151 static struct rb_tree _prop_number_tree
;
152 _PROP_MUTEX_DECL_STATIC(_prop_number_tree_mutex
)
155 static _prop_object_free_rv_t
156 _prop_number_free(prop_stack_t stack
, prop_object_t
*obj
)
158 prop_number_t pn
= *obj
;
160 _prop_rb_tree_remove_node(&_prop_number_tree
, pn
);
162 _PROP_POOL_PUT(_prop_number_pool
, pn
);
164 return (_PROP_OBJECT_FREE_DONE
);
167 _PROP_ONCE_DECL(_prop_number_init_once
)
170 _prop_number_init(void)
173 _PROP_MUTEX_INIT(_prop_number_tree_mutex
);
174 _prop_rb_tree_init(&_prop_number_tree
, &_prop_number_rb_tree_ops
);
179 _prop_number_lock(void)
181 /* XXX: init necessary? */
182 _PROP_ONCE_RUN(_prop_number_init_once
, _prop_number_init
);
183 _PROP_MUTEX_LOCK(_prop_number_tree_mutex
);
187 _prop_number_unlock(void)
189 _PROP_MUTEX_UNLOCK(_prop_number_tree_mutex
);
193 _prop_number_externalize(struct _prop_object_externalize_context
*ctx
,
196 prop_number_t pn
= v
;
200 * For unsigned numbers, we output in hex. For signed numbers,
201 * we output in decimal.
203 if (pn
->pn_value
.pnv_is_unsigned
)
204 sprintf(tmpstr
, "0x%" PRIx64
, pn
->pn_value
.pnv_unsigned
);
206 sprintf(tmpstr
, "%" PRIi64
, pn
->pn_value
.pnv_signed
);
208 if (_prop_object_externalize_start_tag(ctx
, "integer") == false ||
209 _prop_object_externalize_append_cstring(ctx
, tmpstr
) == false ||
210 _prop_object_externalize_end_tag(ctx
, "integer") == false)
217 static _prop_object_equals_rv_t
218 _prop_number_equals(prop_object_t v1
, prop_object_t v2
,
219 void **stored_pointer1
, void **stored_pointer2
,
220 prop_object_t
*next_obj1
, prop_object_t
*next_obj2
)
222 prop_number_t num1
= v1
;
223 prop_number_t num2
= v2
;
226 * There is only ever one copy of a number object at any given
227 * time, so we can reduce this to a simple pointer equality check
228 * in the common case.
231 return (_PROP_OBJECT_EQUALS_TRUE
);
234 * If the numbers are the same signed-ness, then we know they
235 * cannot be equal because they would have had pointer equality.
237 if (num1
->pn_value
.pnv_is_unsigned
== num2
->pn_value
.pnv_is_unsigned
)
238 return (_PROP_OBJECT_EQUALS_FALSE
);
241 * We now have one signed value and one unsigned value. We can
243 * - The unsigned value is not larger than the signed value
245 * - The signed value is not smaller than the unsigned value
248 if (num1
->pn_value
.pnv_is_unsigned
) {
250 * num1 is unsigned and num2 is signed.
252 if (num1
->pn_value
.pnv_unsigned
> INT64_MAX
)
253 return (_PROP_OBJECT_EQUALS_FALSE
);
254 if (num2
->pn_value
.pnv_signed
< 0)
255 return (_PROP_OBJECT_EQUALS_FALSE
);
258 * num1 is signed and num2 is unsigned.
260 if (num1
->pn_value
.pnv_signed
< 0)
261 return (_PROP_OBJECT_EQUALS_FALSE
);
262 if (num2
->pn_value
.pnv_unsigned
> INT64_MAX
)
263 return (_PROP_OBJECT_EQUALS_FALSE
);
266 if (num1
->pn_value
.pnv_signed
== num2
->pn_value
.pnv_signed
)
267 return _PROP_OBJECT_EQUALS_TRUE
;
269 return _PROP_OBJECT_EQUALS_FALSE
;
273 _prop_number_alloc(const struct _prop_number_value
*pnv
)
275 prop_number_t opn
, pn
, rpn
;
277 _PROP_ONCE_RUN(_prop_number_init_once
, _prop_number_init
);
280 * Check to see if this already exists in the tree. If it does,
281 * we just retain it and return it.
283 _PROP_MUTEX_LOCK(_prop_number_tree_mutex
);
284 opn
= _prop_rb_tree_find(&_prop_number_tree
, pnv
);
286 prop_object_retain(opn
);
287 _PROP_MUTEX_UNLOCK(_prop_number_tree_mutex
);
290 _PROP_MUTEX_UNLOCK(_prop_number_tree_mutex
);
293 * Not in the tree. Create it now.
296 pn
= _PROP_POOL_GET(_prop_number_pool
);
300 _prop_object_init(&pn
->pn_obj
, &_prop_object_type_number
);
305 * We dropped the mutex when we allocated the new object, so
306 * we have to check again if it is in the tree.
308 _PROP_MUTEX_LOCK(_prop_number_tree_mutex
);
309 opn
= _prop_rb_tree_find(&_prop_number_tree
, pnv
);
311 prop_object_retain(opn
);
312 _PROP_MUTEX_UNLOCK(_prop_number_tree_mutex
);
313 _PROP_POOL_PUT(_prop_number_pool
, pn
);
316 rpn
= _prop_rb_tree_insert_node(&_prop_number_tree
, pn
);
317 _PROP_ASSERT(rpn
== pn
);
318 _PROP_MUTEX_UNLOCK(_prop_number_tree_mutex
);
323 * prop_number_create_integer --
324 * Create a prop_number_t and initialize it with the
325 * provided integer value.
328 prop_number_create_integer(int64_t val
)
330 struct _prop_number_value pnv
;
332 memset(&pnv
, 0, sizeof(pnv
));
333 pnv
.pnv_signed
= val
;
334 pnv
.pnv_is_unsigned
= false;
336 return (_prop_number_alloc(&pnv
));
340 * prop_number_create_unsigned_integer --
341 * Create a prop_number_t and initialize it with the
342 * provided unsigned integer value.
345 prop_number_create_unsigned_integer(uint64_t val
)
347 struct _prop_number_value pnv
;
349 memset(&pnv
, 0, sizeof(pnv
));
350 pnv
.pnv_unsigned
= val
;
351 pnv
.pnv_is_unsigned
= true;
353 return (_prop_number_alloc(&pnv
));
357 * prop_number_copy --
358 * Copy a prop_number_t.
361 prop_number_copy(prop_number_t opn
)
364 if (! prop_object_is_number(opn
))
368 * Because we only ever allocate one object for any given
369 * value, this can be reduced to a simple retain operation.
371 prop_object_retain(opn
);
376 * prop_number_unsigned --
377 * Returns true if the prop_number_t has an unsigned value.
380 prop_number_unsigned(prop_number_t pn
)
383 return (pn
->pn_value
.pnv_is_unsigned
);
387 * prop_number_size --
388 * Return the size, in bits, required to hold the value of
389 * the specified number.
392 prop_number_size(prop_number_t pn
)
394 struct _prop_number_value
*pnv
;
396 if (! prop_object_is_number(pn
))
401 if (pnv
->pnv_is_unsigned
) {
402 if (pnv
->pnv_unsigned
> UINT32_MAX
)
404 if (pnv
->pnv_unsigned
> UINT16_MAX
)
406 if (pnv
->pnv_unsigned
> UINT8_MAX
)
411 if (pnv
->pnv_signed
> INT32_MAX
|| pnv
->pnv_signed
< INT32_MIN
)
413 if (pnv
->pnv_signed
> INT16_MAX
|| pnv
->pnv_signed
< INT16_MIN
)
415 if (pnv
->pnv_signed
> INT8_MAX
|| pnv
->pnv_signed
< INT8_MIN
)
421 * prop_number_integer_value --
422 * Get the integer value of a prop_number_t.
425 prop_number_integer_value(prop_number_t pn
)
429 * XXX Impossible to distinguish between "not a prop_number_t"
430 * XXX and "prop_number_t has a value of 0".
432 if (! prop_object_is_number(pn
))
435 return (pn
->pn_value
.pnv_signed
);
439 * prop_number_unsigned_integer_value --
440 * Get the unsigned integer value of a prop_number_t.
443 prop_number_unsigned_integer_value(prop_number_t pn
)
447 * XXX Impossible to distinguish between "not a prop_number_t"
448 * XXX and "prop_number_t has a value of 0".
450 if (! prop_object_is_number(pn
))
453 return (pn
->pn_value
.pnv_unsigned
);
457 * prop_number_equals --
458 * Return true if two numbers are equivalent.
461 prop_number_equals(prop_number_t num1
, prop_number_t num2
)
463 if (!prop_object_is_number(num1
) || !prop_object_is_number(num2
))
466 return (prop_object_equals(num1
, num2
));
470 * prop_number_equals_integer --
471 * Return true if the number is equivalent to the specified integer.
474 prop_number_equals_integer(prop_number_t pn
, int64_t val
)
477 if (! prop_object_is_number(pn
))
480 if (pn
->pn_value
.pnv_is_unsigned
&&
481 (pn
->pn_value
.pnv_unsigned
> INT64_MAX
|| val
< 0))
484 return (pn
->pn_value
.pnv_signed
== val
);
488 * prop_number_equals_unsigned_integer --
489 * Return true if the number is equivalent to the specified
493 prop_number_equals_unsigned_integer(prop_number_t pn
, uint64_t val
)
496 if (! prop_object_is_number(pn
))
499 if (! pn
->pn_value
.pnv_is_unsigned
&&
500 (pn
->pn_value
.pnv_signed
< 0 || val
> INT64_MAX
))
503 return (pn
->pn_value
.pnv_unsigned
== val
);
507 _prop_number_internalize_unsigned(struct _prop_object_internalize_context
*ctx
,
508 struct _prop_number_value
*pnv
)
512 _PROP_ASSERT(/*CONSTCOND*/sizeof(unsigned long long) ==
518 pnv
->pnv_unsigned
= (uint64_t) strtoull(ctx
->poic_cp
, &cp
, 0);
519 #ifndef _KERNEL /* XXX can't check for ERANGE in the kernel */
520 if (pnv
->pnv_unsigned
== UINT64_MAX
&& errno
== ERANGE
)
523 pnv
->pnv_is_unsigned
= true;
530 _prop_number_internalize_signed(struct _prop_object_internalize_context
*ctx
,
531 struct _prop_number_value
*pnv
)
535 _PROP_ASSERT(/*CONSTCOND*/sizeof(long long) == sizeof(int64_t));
540 pnv
->pnv_signed
= (int64_t) strtoll(ctx
->poic_cp
, &cp
, 0);
541 #ifndef _KERNEL /* XXX can't check for ERANGE in the kernel */
542 if ((pnv
->pnv_signed
== INT64_MAX
|| pnv
->pnv_signed
== INT64_MIN
) &&
546 pnv
->pnv_is_unsigned
= false;
553 * _prop_number_internalize --
554 * Parse a <number>...</number> and return the object created from
555 * the external representation.
559 _prop_number_internalize(prop_stack_t stack
, prop_object_t
*obj
,
560 struct _prop_object_internalize_context
*ctx
)
562 struct _prop_number_value pnv
;
564 memset(&pnv
, 0, sizeof(pnv
));
566 /* No attributes, no empty elements. */
567 if (ctx
->poic_tagattr
!= NULL
|| ctx
->poic_is_empty_element
)
571 * If the first character is '-', then we treat as signed.
572 * If the first two characters are "0x" (i.e. the number is
573 * in hex), then we treat as unsigned. Otherwise, we try
574 * signed first, and if that fails (presumably due to ERANGE),
575 * then we switch to unsigned.
577 if (ctx
->poic_cp
[0] == '-') {
578 if (_prop_number_internalize_signed(ctx
, &pnv
) == false)
580 } else if (ctx
->poic_cp
[0] == '0' && ctx
->poic_cp
[1] == 'x') {
581 if (_prop_number_internalize_unsigned(ctx
, &pnv
) == false)
584 if (_prop_number_internalize_signed(ctx
, &pnv
) == false &&
585 _prop_number_internalize_unsigned(ctx
, &pnv
) == false)
589 if (_prop_object_internalize_find_tag(ctx
, "integer",
590 _PROP_TAG_TYPE_END
) == false)
593 *obj
= _prop_number_alloc(&pnv
);