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Last change on this file since 1433ecda was 1433ecda, checked in by Jiri Svoboda <jiri@…>, 7 years ago
Fix cstyle: make ccheck-fix and commit only files where all the changes are good.
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[09ababb7]	1	/*
[051b3db8]	2	* Copyright (c) 2011 Jiri Svoboda
[09ababb7]	3	* All rights reserved.
	4	*
	5	* Redistribution and use in source and binary forms, with or without
	6	* modification, are permitted provided that the following conditions
	7	* are met:
	8	*
	9	* - Redistributions of source code must retain the above copyright
	10	* notice, this list of conditions and the following disclaimer.
	11	* - Redistributions in binary form must reproduce the above copyright
	12	* notice, this list of conditions and the following disclaimer in the
	13	* documentation and/or other materials provided with the distribution.
	14	* - The name of the author may not be used to endorse or promote products
	15	* derived from this software without specific prior written permission.
	16	*
	17	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
	18	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
	19	* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
	20	* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
	21	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
	22	* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	23	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	24	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	25	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
	26	* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	27	*/
	28
[23de644]	29	/** @file Run-time data representation.
	30	*
	31	* At run time SBI represents all data as a graph of interconnected @c var
	32	* nodes (variable nodes). Any piece of memory addressable by the program
	33	* (i.e. all variables) are stored in var nodes. However, var nodes are also
	34	* used internally to implement value items. (I.e. values in value items
	35	* have exactly the same structure as program variables).
	36	*
	37	* Unlike byte- or word-oriented memory on a real machine, var nodes provide
	38	* structured and typed storage. (This typing is dynamic, however and has
	39	* nothing to do with the static type system).
	40	*
	41	* There are several types of var nodes, one for each primitive type,
	42	* reference, delegate, array, and object. A reference var node contains
	43	* a pointer to another var node. Delegate var node points to some stree
	44	* declaration. Array and object var nodes refer to a collection of child
	45	* nodes (fields, elements).
	46	*/
[09ababb7]	47
	48	#include <stdlib.h>
	49	#include <assert.h>
[23de644]	50	#include "bigint.h"
[051b3db8]	51	#include "list.h"
[09ababb7]	52	#include "mytypes.h"
[94d484a]	53	#include "stree.h"
[074444f]	54	#include "symbol.h"
[051bc69a]	55	#include "strtab.h"
[09ababb7]	56
	57	#include "rdata.h"
	58
[074444f]	59	static void rdata_bool_copy(rdata_bool_t src, rdata_bool_t *dest);
	60	static void rdata_char_copy(rdata_char_t src, rdata_char_t *dest);
[09ababb7]	61	static void rdata_int_copy(rdata_int_t src, rdata_int_t *dest);
	62	static void rdata_string_copy(rdata_string_t src, rdata_string_t *dest);
	63	static void rdata_ref_copy(rdata_ref_t src, rdata_ref_t *dest);
	64	static void rdata_deleg_copy(rdata_deleg_t src, rdata_deleg_t *dest);
[051bc69a]	65	static void rdata_enum_copy(rdata_enum_t src, rdata_enum_t *dest);
[94d484a]	66	static void rdata_array_copy(rdata_array_t src, rdata_array_t *dest);
[09ababb7]	67	static void rdata_object_copy(rdata_object_t src, rdata_object_t *dest);
[37f527b]	68	static void rdata_resource_copy(rdata_resource_t *src,
	69	rdata_resource_t **dest);
[051bc69a]	70	static void rdata_symbol_copy(rdata_symbol_t src, rdata_symbol_t *dest);
[09ababb7]	71
[051b3db8]	72	static void rdata_var_destroy_inner(rdata_var_t *var);
	73
	74	static void rdata_bool_destroy(rdata_bool_t *bool_v);
	75	static void rdata_char_destroy(rdata_char_t *char_v);
	76	static void rdata_int_destroy(rdata_int_t *int_v);
	77	static void rdata_string_destroy(rdata_string_t *string_v);
	78	static void rdata_ref_destroy(rdata_ref_t *ref_v);
	79	static void rdata_deleg_destroy(rdata_deleg_t *deleg_v);
	80	static void rdata_enum_destroy(rdata_enum_t *enum_v);
	81	static void rdata_array_destroy(rdata_array_t *array_v);
	82	static void rdata_object_destroy(rdata_object_t *object_v);
	83	static void rdata_resource_destroy(rdata_resource_t *resource_v);
	84	static void rdata_symbol_destroy(rdata_symbol_t *symbol_v);
	85
[94d484a]	86	static int rdata_array_get_dim(rdata_array_t *array);
[051b3db8]	87	static void rdata_var_copy_to(rdata_var_t src, rdata_var_t dest);
[94d484a]	88
[09ababb7]	89	static void rdata_address_print(rdata_address_t *address);
	90	static void rdata_var_print(rdata_var_t *var);
	91
[23de644]	92	/** Allocate new data item.
	93	*
	94	* @param ic Item class.
	95	* @return New item.
	96	*/
[09ababb7]	97	rdata_item_t *rdata_item_new(item_class_t ic)
	98	{
	99	rdata_item_t *item;
	100
	101	item = calloc(1, sizeof(rdata_item_t));
	102	if (item == NULL) {
	103	printf("Memory allocation failed.\n");
	104	exit(1);
	105	}
	106
	107	item->ic = ic;
	108	return item;
	109	}
	110
[23de644]	111	/** Allocate new address.
	112	*
	113	* @return New address.
	114	*/
[d0febca]	115	rdata_addr_var_t *rdata_addr_var_new(void)
	116	{
	117	rdata_addr_var_t *addr_var;
	118
	119	addr_var = calloc(1, sizeof(rdata_addr_var_t));
	120	if (addr_var == NULL) {
	121	printf("Memory allocation failed.\n");
	122	exit(1);
	123	}
	124
	125	return addr_var;
	126	}
	127
[23de644]	128	/** Allocate new named property address.
	129	*
	130	* @return New named property address.
	131	*/
[d0febca]	132	rdata_aprop_named_t *rdata_aprop_named_new(void)
	133	{
	134	rdata_aprop_named_t *aprop_named;
	135
	136	aprop_named = calloc(1, sizeof(rdata_aprop_named_t));
	137	if (aprop_named == NULL) {
	138	printf("Memory allocation failed.\n");
	139	exit(1);
	140	}
	141
	142	return aprop_named;
	143	}
	144
[23de644]	145	/** Allocate new indexed property address.
	146	*
	147	* @return New indexed property address.
	148	*/
[d0febca]	149	rdata_aprop_indexed_t *rdata_aprop_indexed_new(void)
	150	{
	151	rdata_aprop_indexed_t *aprop_indexed;
	152
	153	aprop_indexed = calloc(1, sizeof(rdata_aprop_indexed_t));
	154	if (aprop_indexed == NULL) {
	155	printf("Memory allocation failed.\n");
	156	exit(1);
	157	}
	158
	159	return aprop_indexed;
	160	}
	161
[23de644]	162	/** Allocate new property address.
	163	*
	164	* @param apc Property address class.
	165	* @return New property address.
	166	*/
[d0febca]	167	rdata_addr_prop_t *rdata_addr_prop_new(aprop_class_t apc)
	168	{
	169	rdata_addr_prop_t *addr_prop;
	170
	171	addr_prop = calloc(1, sizeof(rdata_addr_prop_t));
	172	if (addr_prop == NULL) {
	173	printf("Memory allocation failed.\n");
	174	exit(1);
	175	}
	176
	177	addr_prop->apc = apc;
	178	return addr_prop;
	179	}
	180
[23de644]	181	/** Allocate new address.
	182	*
	183	* @param ac Address class.
	184	* @return New address.
	185	*/
[d0febca]	186	rdata_address_t *rdata_address_new(address_class_t ac)
[09ababb7]	187	{
	188	rdata_address_t *address;
	189
	190	address = calloc(1, sizeof(rdata_address_t));
	191	if (address == NULL) {
	192	printf("Memory allocation failed.\n");
	193	exit(1);
	194	}
	195
[d0febca]	196	address->ac = ac;
[09ababb7]	197	return address;
	198	}
	199
[23de644]	200	/** Allocate new value.
	201	*
	202	* @return New value.
	203	*/
[09ababb7]	204	rdata_value_t *rdata_value_new(void)
	205	{
	206	rdata_value_t *value;
	207
	208	value = calloc(1, sizeof(rdata_value_t));
	209	if (value == NULL) {
	210	printf("Memory allocation failed.\n");
	211	exit(1);
	212	}
	213
	214	return value;
	215	}
	216
[23de644]	217	/** Allocate new var node.
	218	*
	219	* @param vc Var node class (varclass).
	220	* @return New var node.
	221	*/
[09ababb7]	222	rdata_var_t *rdata_var_new(var_class_t vc)
	223	{
	224	rdata_var_t *var;
	225
	226	var = calloc(1, sizeof(rdata_var_t));
	227	if (var == NULL) {
	228	printf("Memory allocation failed.\n");
	229	exit(1);
	230	}
	231
	232	var->vc = vc;
	233	return var;
	234	}
	235
[23de644]	236	/** Allocate new reference.
	237	*
	238	* @return New reference.
	239	*/
[fa36f29]	240	rdata_ref_t *rdata_ref_new(void)
	241	{
	242	rdata_ref_t *ref;
	243
	244	ref = calloc(1, sizeof(rdata_ref_t));
	245	if (ref == NULL) {
	246	printf("Memory allocation failed.\n");
	247	exit(1);
	248	}
	249
	250	return ref;
	251	}
	252
[23de644]	253	/** Allocate new delegate.
	254	*
	255	* @return New delegate.
	256	*/
[09ababb7]	257	rdata_deleg_t *rdata_deleg_new(void)
	258	{
	259	rdata_deleg_t *deleg;
	260
	261	deleg = calloc(1, sizeof(rdata_deleg_t));
	262	if (deleg == NULL) {
	263	printf("Memory allocation failed.\n");
	264	exit(1);
	265	}
	266
	267	return deleg;
	268	}
	269
[051bc69a]	270	/** Allocate new enum value.
	271	*
	272	* @return New enum value.
	273	*/
	274	rdata_enum_t *rdata_enum_new(void)
	275	{
	276	rdata_enum_t *enum_v;
	277
	278	enum_v = calloc(1, sizeof(rdata_enum_t));
	279	if (enum_v == NULL) {
	280	printf("Memory allocation failed.\n");
	281	exit(1);
	282	}
	283
	284	return enum_v;
	285	}
	286
[23de644]	287	/** Allocate new array.
	288	*
	289	* @return New array.
	290	*/
[94d484a]	291	rdata_array_t *rdata_array_new(int rank)
	292	{
	293	rdata_array_t *array;
	294
	295	array = calloc(1, sizeof(rdata_array_t));
	296	if (array == NULL) {
	297	printf("Memory allocation failed.\n");
	298	exit(1);
	299	}
	300
	301	array->rank = rank;
	302	array->extent = calloc(rank, sizeof(int));
	303	if (array == NULL) {
	304	printf("Memory allocation failed.\n");
	305	exit(1);
	306	}
	307
	308	return array;
	309	}
	310
[23de644]	311	/** Allocate new object.
	312	*
	313	* @return New object.
	314	*/
[fa36f29]	315	rdata_object_t *rdata_object_new(void)
	316	{
	317	rdata_object_t *object;
	318
	319	object = calloc(1, sizeof(rdata_object_t));
	320	if (object == NULL) {
	321	printf("Memory allocation failed.\n");
	322	exit(1);
	323	}
	324
	325	return object;
	326	}
	327
[074444f]	328	/** Allocate new boolean.
	329	*
	330	* @return New boolean.
	331	*/
	332	rdata_bool_t *rdata_bool_new(void)
	333	{
	334	rdata_bool_t *bool_v;
	335
	336	bool_v = calloc(1, sizeof(rdata_bool_t));
	337	if (bool_v == NULL) {
	338	printf("Memory allocation failed.\n");
	339	exit(1);
	340	}
	341
	342	return bool_v;
	343	}
	344
	345	/** Allocate new character.
	346	*
	347	* @return New character.
	348	*/
	349	rdata_char_t *rdata_char_new(void)
	350	{
	351	rdata_char_t *char_v;
	352
	353	char_v = calloc(1, sizeof(rdata_char_t));
	354	if (char_v == NULL) {
	355	printf("Memory allocation failed.\n");
	356	exit(1);
	357	}
	358
	359	return char_v;
	360	}
	361
[23de644]	362	/** Allocate new integer.
	363	*
	364	* @return New integer.
	365	*/
[09ababb7]	366	rdata_int_t *rdata_int_new(void)
	367	{
	368	rdata_int_t *int_v;
	369
	370	int_v = calloc(1, sizeof(rdata_int_t));
	371	if (int_v == NULL) {
	372	printf("Memory allocation failed.\n");
	373	exit(1);
	374	}
	375
	376	return int_v;
	377	}
	378
[23de644]	379	/** Allocate new string.
	380	*
	381	* @return New string.
	382	*/
[09ababb7]	383	rdata_string_t *rdata_string_new(void)
	384	{
	385	rdata_string_t *string_v;
	386
	387	string_v = calloc(1, sizeof(rdata_string_t));
	388	if (string_v == NULL) {
	389	printf("Memory allocation failed.\n");
	390	exit(1);
	391	}
	392
	393	return string_v;
	394	}
	395
[23de644]	396	/** Allocate new resource.
	397	*
	398	* @return New resource.
	399	*/
[37f527b]	400	rdata_resource_t *rdata_resource_new(void)
	401	{
	402	rdata_resource_t *resource_v;
	403
	404	resource_v = calloc(1, sizeof(rdata_resource_t));
	405	if (resource_v == NULL) {
	406	printf("Memory allocation failed.\n");
	407	exit(1);
	408	}
	409
	410	return resource_v;
	411	}
	412
[051bc69a]	413	/** Allocate new symbol reference.
	414	*
	415	* @return New symbol reference.
	416	*/
	417	rdata_symbol_t *rdata_symbol_new(void)
	418	{
	419	rdata_symbol_t *symbol_v;
	420
	421	symbol_v = calloc(1, sizeof(rdata_symbol_t));
	422	if (symbol_v == NULL) {
	423	printf("Memory allocation failed.\n");
	424	exit(1);
	425	}
	426
	427	return symbol_v;
	428	}
	429
[23de644]	430	/** Allocate array elements.
	431	*
[051b3db8]	432	* Allocates element array of @a array.
[23de644]	433	*
	434	* @param array Array.
	435	*/
[94d484a]	436	void rdata_array_alloc_element(rdata_array_t *array)
	437	{
[051b3db8]	438	int dim;
[94d484a]	439
	440	dim = rdata_array_get_dim(array);
	441
	442	array->element = calloc(dim, sizeof(rdata_var_t *));
	443	if (array->element == NULL) {
	444	printf("Memory allocation failed.\n");
	445	exit(1);
	446	}
	447	}
	448
	449	/** Get array dimension.
	450	*
	451	* Dimension is the total number of elements in an array, in other words,
	452	* the product of all extents.
[23de644]	453	*
	454	* @param array Array.
[94d484a]	455	*/
	456	static int rdata_array_get_dim(rdata_array_t *array)
	457	{
	458	int didx, dim;
	459
	460	dim = 1;
	461	for (didx = 0; didx < array->rank; ++didx)
	462	dim = dim * array->extent[didx];
	463
	464	return dim;
	465	}
	466
[051b3db8]	467	/** Deallocate item.
	468	*
	469	* @param item Item node
	470	*/
	471	void rdata_item_delete(rdata_item_t *item)
	472	{
	473	assert(item != NULL);
	474	free(item);
	475	}
	476
	477	/** Deallocate variable address.
	478	*
	479	* @param addr_var Variable address node
	480	*/
	481	void rdata_addr_var_delete(rdata_addr_var_t *addr_var)
	482	{
	483	assert(addr_var != NULL);
	484	free(addr_var);
	485	}
	486
	487	/** Deallocate property address.
	488	*
	489	* @param addr_prop Variable address node
	490	*/
	491	void rdata_addr_prop_delete(rdata_addr_prop_t *addr_prop)
	492	{
	493	assert(addr_prop != NULL);
	494	free(addr_prop);
	495	}
	496
	497	/** Deallocate named property address.
	498	*
	499	* @param aprop_named Variable address node
	500	*/
	501	void rdata_aprop_named_delete(rdata_aprop_named_t *aprop_named)
	502	{
	503	assert(aprop_named != NULL);
	504	free(aprop_named);
	505	}
	506
	507	/** Deallocate indexed property address.
	508	*
	509	* @param aprop_indexed Variable address node
	510	*/
	511	void rdata_aprop_indexed_delete(rdata_aprop_indexed_t *aprop_indexed)
	512	{
	513	assert(aprop_indexed != NULL);
	514	free(aprop_indexed);
	515	}
	516
	517	/** Deallocate address.
	518	*
	519	* @param address Address node
	520	*/
	521	void rdata_address_delete(rdata_address_t *address)
	522	{
	523	assert(address != NULL);
	524	free(address);
	525	}
	526
	527	/** Deallocate value.
	528	*
	529	* @param value Value node
	530	*/
	531	void rdata_value_delete(rdata_value_t *value)
	532	{
	533	assert(value != NULL);
	534	free(value);
	535	}
	536
	537	/** Deallocate var node.
	538	*
	539	* @param var Var node
	540	*/
	541	void rdata_var_delete(rdata_var_t *var)
	542	{
	543	assert(var != NULL);
	544	free(var);
	545	}
	546
	547	/** Deallocate boolean.
	548	*
	549	* @param bool_v Boolean
	550	*/
	551	void rdata_bool_delete(rdata_bool_t *bool_v)
	552	{
	553	assert(bool_v != NULL);
	554	free(bool_v);
	555	}
	556
	557	/** Deallocate character.
	558	*
	559	* @param char_v Character
	560	*/
	561	void rdata_char_delete(rdata_char_t *char_v)
	562	{
	563	assert(char_v != NULL);
	564	free(char_v);
	565	}
	566
	567	/** Deallocate integer.
	568	*
	569	* @param int_v Integer
	570	*/
	571	void rdata_int_delete(rdata_int_t *int_v)
	572	{
	573	assert(int_v != NULL);
	574	free(int_v);
	575	}
	576
	577	/** Deallocate string.
	578	*
	579	* @param string_v String
	580	*/
	581	void rdata_string_delete(rdata_string_t *string_v)
	582	{
	583	assert(string_v != NULL);
	584	free(string_v);
	585	}
	586
	587	/** Deallocate reference.
	588	*
	589	* @param ref_v Reference
	590	*/
	591	void rdata_ref_delete(rdata_ref_t *ref_v)
	592	{
	593	assert(ref_v != NULL);
	594	free(ref_v);
	595	}
	596
	597	/** Deallocate delegate.
	598	*
	599	* @param deleg_v Reference
	600	*/
	601	void rdata_deleg_delete(rdata_deleg_t *deleg_v)
	602	{
	603	assert(deleg_v != NULL);
	604	free(deleg_v);
	605	}
	606
	607	/** Deallocate enum.
	608	*
	609	* @param enum_v Reference
	610	*/
	611	void rdata_enum_delete(rdata_enum_t *enum_v)
	612	{
	613	assert(enum_v != NULL);
	614	free(enum_v);
	615	}
	616
	617	/** Deallocate array.
	618	*
	619	* @param array_v Array
	620	*/
	621	void rdata_array_delete(rdata_array_t *array_v)
	622	{
	623	assert(array_v != NULL);
	624	free(array_v);
	625	}
	626
	627	/** Deallocate object.
	628	*
	629	* @param object_v Object
	630	*/
	631	void rdata_object_delete(rdata_object_t *object_v)
	632	{
	633	assert(object_v != NULL);
	634	free(object_v);
	635	}
	636
	637	/** Deallocate resource.
	638	*
	639	* @param resource_v Resource
	640	*/
	641	void rdata_resource_delete(rdata_resource_t *resource_v)
	642	{
	643	assert(resource_v != NULL);
	644	free(resource_v);
	645	}
	646
	647	/** Deallocate symbol.
	648	*
	649	* @param symbol_v Symbol
	650	*/
	651	void rdata_symbol_delete(rdata_symbol_t *symbol_v)
	652	{
	653	assert(symbol_v != NULL);
	654	free(symbol_v);
	655	}
	656
	657	/** Copy value.
	658	*
	659	* @param src Input value
	660	* @param dest Place to store pointer to new value
	661	*/
	662	void rdata_value_copy(rdata_value_t src, rdata_value_t *dest)
	663	{
	664	assert(src != NULL);
	665
	666	*dest = rdata_value_new();
	667	rdata_var_copy(src->var, &(*dest)->var);
	668	}
	669
[23de644]	670	/** Make copy of a variable.
	671	*
	672	* Creates a new var node that is an exact copy of an existing var node.
	673	* This can be thought of as a shallow copy.
	674	*
	675	* @param src Source var node.
	676	* @param dest Place to store pointer to new var node.
	677	*/
[09ababb7]	678	void rdata_var_copy(rdata_var_t src, rdata_var_t *dest)
	679	{
	680	rdata_var_t *nvar;
	681
	682	nvar = rdata_var_new(src->vc);
[051b3db8]	683	rdata_var_copy_to(src, nvar);
	684
	685	*dest = nvar;
	686	}
	687
	688	/** Copy variable content to another variable.
	689	*
	690	* Writes an exact copy of an existing var node to another var node.
	691	* The varclass of @a src and @a dest must match. The content of
	692	* @a dest.u must be invalid.
	693	*
	694	* @param src Source var node.
	695	* @param dest Destination var node.
	696	*/
	697	static void rdata_var_copy_to(rdata_var_t src, rdata_var_t dest)
	698	{
	699	dest->vc = src->vc;
[09ababb7]	700
	701	switch (src->vc) {
[074444f]	702	case vc_bool:
[051b3db8]	703	rdata_bool_copy(src->u.bool_v, &dest->u.bool_v);
[074444f]	704	break;
	705	case vc_char:
[051b3db8]	706	rdata_char_copy(src->u.char_v, &dest->u.char_v);
[074444f]	707	break;
[09ababb7]	708	case vc_int:
[051b3db8]	709	rdata_int_copy(src->u.int_v, &dest->u.int_v);
[09ababb7]	710	break;
	711	case vc_string:
[051b3db8]	712	rdata_string_copy(src->u.string_v, &dest->u.string_v);
[09ababb7]	713	break;
	714	case vc_ref:
[051b3db8]	715	rdata_ref_copy(src->u.ref_v, &dest->u.ref_v);
[09ababb7]	716	break;
	717	case vc_deleg:
[051b3db8]	718	rdata_deleg_copy(src->u.deleg_v, &dest->u.deleg_v);
[09ababb7]	719	break;
[051bc69a]	720	case vc_enum:
[051b3db8]	721	rdata_enum_copy(src->u.enum_v, &dest->u.enum_v);
[051bc69a]	722	break;
[94d484a]	723	case vc_array:
[051b3db8]	724	rdata_array_copy(src->u.array_v, &dest->u.array_v);
[94d484a]	725	break;
[09ababb7]	726	case vc_object:
[051b3db8]	727	rdata_object_copy(src->u.object_v, &dest->u.object_v);
[09ababb7]	728	break;
[37f527b]	729	case vc_resource:
[051b3db8]	730	rdata_resource_copy(src->u.resource_v, &dest->u.resource_v);
[37f527b]	731	break;
[051bc69a]	732	case vc_symbol:
[051b3db8]	733	rdata_symbol_copy(src->u.symbol_v, &dest->u.symbol_v);
[051bc69a]	734	break;
[09ababb7]	735	}
	736	}
	737
[051b3db8]	738
[074444f]	739	/** Copy boolean.
	740	*
[051b3db8]	741	* @param src Source boolean
	742	* @param dest Place to store pointer to new boolean
[074444f]	743	*/
	744	static void rdata_bool_copy(rdata_bool_t src, rdata_bool_t *dest)
	745	{
	746	*dest = rdata_bool_new();
	747	(*dest)->value = src->value;
	748	}
	749
	750	/** Copy character.
	751	*
[051b3db8]	752	* @param src Source character
	753	* @param dest Place to store pointer to new character
[074444f]	754	*/
	755	static void rdata_char_copy(rdata_char_t src, rdata_char_t *dest)
	756	{
	757	*dest = rdata_char_new();
	758	bigint_clone(&src->value, &(*dest)->value);
	759	}
	760
[23de644]	761	/** Copy integer.
	762	*
[051b3db8]	763	* @param src Source integer
	764	* @param dest Place to store pointer to new integer
[23de644]	765	*/
[09ababb7]	766	static void rdata_int_copy(rdata_int_t src, rdata_int_t *dest)
	767	{
	768	*dest = rdata_int_new();
[23de644]	769	bigint_clone(&src->value, &(*dest)->value);
[09ababb7]	770	}
	771
[23de644]	772	/** Copy string.
	773	*
	774	* @param src Source string.
	775	* @param dest Place to store pointer to new string.
	776	*/
[09ababb7]	777	static void rdata_string_copy(rdata_string_t src, rdata_string_t *dest)
	778	{
	779	*dest = rdata_string_new();
	780	(*dest)->value = src->value;
	781	}
	782
[23de644]	783	/** Copy reference.
	784	*
	785	* @param src Source reference.
	786	* @param dest Place to store pointer to new reference.
	787	*/
[09ababb7]	788	static void rdata_ref_copy(rdata_ref_t src, rdata_ref_t *dest)
	789	{
[fa36f29]	790	*dest = rdata_ref_new();
	791	(*dest)->vref = src->vref;
[09ababb7]	792	}
	793
[23de644]	794	/** Copy delegate.
	795	*
	796	* @param src Source delegate.
	797	* @param dest Place to store pointer to new delegate.
	798	*/
[09ababb7]	799	static void rdata_deleg_copy(rdata_deleg_t src, rdata_deleg_t *dest)
	800	{
[38aaacc2]	801	*dest = rdata_deleg_new();
	802	(*dest)->obj = src->obj;
	803	(*dest)->sym = src->sym;
[09ababb7]	804	}
	805
[051bc69a]	806	/** Copy enum value.
	807	*
	808	* @param src Source enum value.
	809	* @param dest Place to store pointer to new enum value.
	810	*/
	811	static void rdata_enum_copy(rdata_enum_t src, rdata_enum_t *dest)
	812	{
	813	*dest = rdata_enum_new();
	814	(*dest)->value = src->value;
	815	}
	816
[23de644]	817	/** Copy array.
	818	*
	819	* @param src Source array.
	820	* @param dest Place to store pointer to new array.
	821	*/
[94d484a]	822	static void rdata_array_copy(rdata_array_t src, rdata_array_t *dest)
	823	{
[1433ecda]	824	(void) src;
	825	(void) dest;
[94d484a]	826	printf("Unimplemented: Copy array.\n");
	827	exit(1);
	828	}
	829
[23de644]	830	/** Copy object.
	831	*
	832	* @param src Source object.
	833	* @param dest Place to store pointer to new object.
	834	*/
[09ababb7]	835	static void rdata_object_copy(rdata_object_t src, rdata_object_t *dest)
	836	{
[1433ecda]	837	(void) src;
	838	(void) dest;
[09ababb7]	839	printf("Unimplemented: Copy object.\n");
[c5cb943d]	840	abort();
[09ababb7]	841	}
	842
[23de644]	843	/** Copy resource.
	844	*
	845	* @param src Source resource.
	846	* @param dest Place to store pointer to new resource.
	847	*/
[37f527b]	848	static void rdata_resource_copy(rdata_resource_t src, rdata_resource_t *dest)
	849	{
	850	*dest = rdata_resource_new();
	851	(*dest)->data = src->data;
	852	}
	853
[051bc69a]	854	/** Copy symbol.
	855	*
	856	* @param src Source symbol.
	857	* @param dest Place to store pointer to new symbol.
	858	*/
	859	static void rdata_symbol_copy(rdata_symbol_t src, rdata_symbol_t *dest)
	860	{
	861	*dest = rdata_symbol_new();
	862	(*dest)->sym = src->sym;
	863	}
	864
[051b3db8]	865	/** Destroy var node.
	866	*
	867	* @param var Var node
	868	*/
	869	void rdata_var_destroy(rdata_var_t *var)
	870	{
	871	/* First destroy class-specific part */
	872	rdata_var_destroy_inner(var);
	873
	874	/* Deallocate var node */
	875	rdata_var_delete(var);
	876	}
	877
	878	/** Destroy inside of var node.
	879	*
	880	* Destroy content of var node, but do not deallocate the var node
	881	* itself.
	882	*
	883	* @param var Var node
	884	*/
	885	static void rdata_var_destroy_inner(rdata_var_t *var)
	886	{
	887	/* First destroy class-specific part */
	888
	889	switch (var->vc) {
	890	case vc_bool:
	891	rdata_bool_destroy(var->u.bool_v);
	892	break;
	893	case vc_char:
	894	rdata_char_destroy(var->u.char_v);
	895	break;
	896	case vc_int:
	897	rdata_int_destroy(var->u.int_v);
	898	break;
	899	case vc_string:
	900	rdata_string_destroy(var->u.string_v);
	901	break;
	902	case vc_ref:
	903	rdata_ref_destroy(var->u.ref_v);
	904	break;
	905	case vc_deleg:
	906	rdata_deleg_destroy(var->u.deleg_v);
	907	break;
	908	case vc_enum:
	909	rdata_enum_destroy(var->u.enum_v);
	910	break;
	911	case vc_array:
	912	rdata_array_destroy(var->u.array_v);
	913	break;
	914	case vc_object:
	915	rdata_object_destroy(var->u.object_v);
	916	break;
	917	case vc_resource:
	918	rdata_resource_destroy(var->u.resource_v);
	919	break;
	920	case vc_symbol:
	921	rdata_symbol_destroy(var->u.symbol_v);
	922	break;
	923	}
	924	}
	925
	926	/** Destroy item.
	927	*
	928	* Destroy an item including the value or address within.
	929	*
	930	* @param item Item
	931	*/
	932	void rdata_item_destroy(rdata_item_t *item)
	933	{
	934	/* First destroy class-specific part */
	935
	936	switch (item->ic) {
	937	case ic_address:
	938	rdata_address_destroy(item->u.address);
	939	break;
	940	case ic_value:
	941	rdata_value_destroy(item->u.value);
	942	break;
	943	}
	944
	945	/* Deallocate item node */
	946	rdata_item_delete(item);
	947	}
	948
	949	/** Destroy address.
	950	*
	951	* Destroy an address node.
	952	*
	953	* @param address Address
	954	*/
	955	void rdata_address_destroy(rdata_address_t *address)
	956	{
	957	switch (address->ac) {
	958	case ac_var:
	959	rdata_addr_var_destroy(address->u.var_a);
	960	break;
	961	case ac_prop:
	962	rdata_addr_prop_destroy(address->u.prop_a);
	963	break;
	964	}
	965
	966	/* Deallocate address node */
	967	rdata_address_delete(address);
	968	}
	969
	970	/** Destroy variable address.
	971	*
	972	* Destroy a variable address node.
	973	*
	974	* @param addr_var Variable address
	975	*/
	976	void rdata_addr_var_destroy(rdata_addr_var_t *addr_var)
	977	{
	978	addr_var->vref = NULL;
	979
	980	/* Deallocate variable address node */
	981	rdata_addr_var_delete(addr_var);
	982	}
	983
	984	/** Destroy property address.
	985	*
	986	* Destroy a property address node.
	987	*
	988	* @param addr_prop Property address
	989	*/
	990	void rdata_addr_prop_destroy(rdata_addr_prop_t *addr_prop)
	991	{
	992	switch (addr_prop->apc) {
	993	case apc_named:
	994	rdata_aprop_named_destroy(addr_prop->u.named);
	995	break;
	996	case apc_indexed:
	997	rdata_aprop_indexed_destroy(addr_prop->u.indexed);
	998	break;
	999	}
	1000
	1001	if (addr_prop->tvalue != NULL) {
	1002	rdata_value_destroy(addr_prop->tvalue);
	1003	addr_prop->tvalue = NULL;
	1004	}
	1005
	1006	addr_prop->tpos = NULL;
	1007
	1008	/* Deallocate property address node */
	1009	rdata_addr_prop_delete(addr_prop);
	1010	}
	1011
	1012	/** Destroy named property address.
	1013	*
	1014	* Destroy a named property address node.
	1015	*
	1016	* @param aprop_named Named property address
	1017	*/
	1018	void rdata_aprop_named_destroy(rdata_aprop_named_t *aprop_named)
	1019	{
	1020	rdata_deleg_destroy(aprop_named->prop_d);
	1021
	1022	/* Deallocate named property address node */
	1023	rdata_aprop_named_delete(aprop_named);
	1024	}
	1025
	1026	/** Destroy indexed property address.
	1027	*
	1028	* Destroy a indexed property address node.
	1029	*
	1030	* @param aprop_indexed Indexed property address
	1031	*/
	1032	void rdata_aprop_indexed_destroy(rdata_aprop_indexed_t *aprop_indexed)
	1033	{
	1034	list_node_t *arg_node;
	1035	rdata_item_t *arg_i;
	1036
	1037	/* Destroy the object delegate. */
	1038	rdata_deleg_destroy(aprop_indexed->object_d);
	1039
	1040	/*
	1041	* Walk through all argument items (indices) and destroy them,
	1042	* removing them from the list as well.
	1043	*/
	1044	while (!list_is_empty(&aprop_indexed->args)) {
	1045	arg_node = list_first(&aprop_indexed->args);
	1046	arg_i = list_node_data(arg_node, rdata_item_t *);
	1047
	1048	rdata_item_destroy(arg_i);
	1049	list_remove(&aprop_indexed->args, arg_node);
	1050	}
	1051
	1052	/* Destroy the now empty list */
	1053	list_fini(&aprop_indexed->args);
	1054
	1055	/* Deallocate indexed property address node */
	1056	rdata_aprop_indexed_delete(aprop_indexed);
	1057	}
	1058
	1059	/** Destroy value.
	1060	*
	1061	* Destroy a value node.
	1062	*
	1063	* @param value Value
	1064	*/
	1065	void rdata_value_destroy(rdata_value_t *value)
	1066	{
	1067	/* Assumption: Var nodes in values are not shared. */
	1068	rdata_var_destroy(value->var);
	1069
	1070	/* Deallocate value node */
	1071	rdata_value_delete(value);
	1072	}
	1073
	1074	/** Destroy boolean.
	1075	*
	1076	* @param bool_v Boolean
	1077	*/
	1078	static void rdata_bool_destroy(rdata_bool_t *bool_v)
	1079	{
	1080	rdata_bool_delete(bool_v);
	1081	}
	1082
	1083	/** Destroy character.
	1084	*
	1085	* @param char_v Character
	1086	*/
	1087	static void rdata_char_destroy(rdata_char_t *char_v)
	1088	{
	1089	bigint_destroy(&char_v->value);
	1090	rdata_char_delete(char_v);
	1091	}
	1092
	1093	/** Destroy integer.
	1094	*
	1095	* @param int_v Integer
	1096	*/
	1097	static void rdata_int_destroy(rdata_int_t *int_v)
	1098	{
	1099	bigint_destroy(&int_v->value);
	1100	rdata_int_delete(int_v);
	1101	}
	1102
	1103	/** Destroy string.
	1104	*
	1105	* @param string_v String
	1106	*/
	1107	static void rdata_string_destroy(rdata_string_t *string_v)
	1108	{
	1109	/*
	1110	* String values are shared so we cannot free them. Just deallocate
	1111	* the node.
	1112	*/
	1113	rdata_string_delete(string_v);
	1114	}
	1115
	1116	/** Destroy reference.
	1117	*
	1118	* @param ref_v Reference
	1119	*/
	1120	static void rdata_ref_destroy(rdata_ref_t *ref_v)
	1121	{
	1122	ref_v->vref = NULL;
	1123	rdata_ref_delete(ref_v);
	1124	}
	1125
	1126	/** Destroy delegate.
	1127	*
	1128	* @param deleg_v Reference
	1129	*/
	1130	static void rdata_deleg_destroy(rdata_deleg_t *deleg_v)
	1131	{
	1132	deleg_v->obj = NULL;
	1133	deleg_v->sym = NULL;
	1134	rdata_deleg_delete(deleg_v);
	1135	}
	1136
	1137	/** Destroy enum.
	1138	*
	1139	* @param enum_v Reference
	1140	*/
	1141	static void rdata_enum_destroy(rdata_enum_t *enum_v)
	1142	{
	1143	enum_v->value = NULL;
	1144	rdata_enum_delete(enum_v);
	1145	}
	1146
	1147	/** Destroy array.
	1148	*
	1149	* @param array_v Array
	1150	*/
	1151	static void rdata_array_destroy(rdata_array_t *array_v)
	1152	{
	1153	int d;
	1154	size_t n_elems, p;
	1155
	1156	/*
	1157	* Compute total number of elements in array.
	1158	* At the same time zero out the extent array.
	1159	*/
	1160	n_elems = 1;
	1161	for (d = 0; d < array_v->rank; d++) {
	1162	n_elems = n_elems * array_v->extent[d];
	1163	array_v->extent[d] = 0;
	1164	}
	1165
	1166	/* Destroy all elements and zero out the array */
	1167	for (p = 0; p < n_elems; p++) {
	1168	rdata_var_delete(array_v->element[p]);
	1169	array_v->element[p] = NULL;
	1170	}
	1171
	1172	/* Free the arrays */
	1173	free(array_v->element);
	1174	free(array_v->extent);
	1175
	1176	array_v->rank = 0;
	1177
	1178	/* Deallocate the node */
	1179	rdata_array_delete(array_v);
	1180	}
	1181
	1182	/** Destroy object.
	1183	*
	1184	* @param object_v Object
	1185	*/
	1186	static void rdata_object_destroy(rdata_object_t *object_v)
	1187	{
	1188	/* XXX TODO */
	1189	rdata_object_delete(object_v);
	1190	}
	1191
	1192	/** Destroy resource.
	1193	*
	1194	* @param resource_v Resource
	1195	*/
	1196	static void rdata_resource_destroy(rdata_resource_t *resource_v)
	1197	{
	1198	/*
	1199	* XXX Presumably this should be handled by the appropriate
	1200	* built-in module, so, some call-back function would be required.
	1201	*/
	1202	resource_v->data = NULL;
	1203	rdata_resource_delete(resource_v);
	1204	}
	1205
	1206	/** Destroy symbol.
	1207	*
	1208	* @param symbol_v Symbol
	1209	*/
	1210	static void rdata_symbol_destroy(rdata_symbol_t *symbol_v)
	1211	{
	1212	symbol_v->sym = NULL;
	1213	rdata_symbol_delete(symbol_v);
	1214	}
	1215
[d0febca]	1216	/** Read data from a variable.
[fa36f29]	1217	*
[23de644]	1218	* This copies data from the variable to a value item. Ideally any read access
	1219	* to a program variable should go through this function. (Keep in mind
	1220	* that although values are composed of var nodes internally, but are not
	1221	* variables per se. Therefore this function is not used to read from values)
	1222	*
	1223	* @param var Variable to read from (var node where it is stored).
	1224	* @param ritem Place to store pointer to new value item read from
	1225	* the variable.
[fa36f29]	1226	*/
[d0febca]	1227	void rdata_var_read(rdata_var_t var, rdata_item_t *ritem)
[fa36f29]	1228	{
	1229	rdata_value_t *value;
	1230	rdata_var_t *rvar;
	1231
[d0febca]	1232	/* Perform a shallow copy of @a var. */
	1233	rdata_var_copy(var, &rvar);
[fa36f29]	1234
	1235	value = rdata_value_new();
	1236	value->var = rvar;
	1237	*ritem = rdata_item_new(ic_value);
	1238	(*ritem)->u.value = value;
	1239	}
	1240
[94d484a]	1241	/** Write data to a variable.
	1242	*
[23de644]	1243	* This copies data to the variable from a value. Ideally any write access
	1244	* to a program variable should go through this function. (Keep in mind
	1245	* that even though values are composed of var nodes internally, but are not
	1246	* variables per se. Therefore this function is not used to write to values)
	1247	*
	1248	* @param var Variable to write to (var node where it is stored).
	1249	* @param value The value to write.
[94d484a]	1250	*/
	1251	void rdata_var_write(rdata_var_t var, rdata_value_t value)
[fa36f29]	1252	{
[051b3db8]	1253	/* Free old content of var->u */
	1254	rdata_var_destroy_inner(var);
[fa36f29]	1255
	1256	/* Perform a shallow copy of @c value->var. */
[051b3db8]	1257	rdata_var_copy_to(value->var, var);
[fa36f29]	1258	}
	1259
[23de644]	1260	/** Print data item in human-readable form.
	1261	*
	1262	* @param item Item to print.
	1263	*/
[09ababb7]	1264	void rdata_item_print(rdata_item_t *item)
	1265	{
	1266	if (item == NULL) {
	1267	printf("none");
	1268	return;
	1269	}
	1270
	1271	switch (item->ic) {
	1272	case ic_address:
	1273	printf("address:");
	1274	rdata_address_print(item->u.address);
	1275	break;
	1276	case ic_value:
	1277	printf("value:");
	1278	rdata_value_print(item->u.value);
	1279	break;
	1280	}
	1281	}
	1282
[23de644]	1283	/** Print address in human-readable form.
	1284	*
	1285	* Actually this displays contents of the var node that is being addressed.
	1286	*
	1287	* XXX Maybe we should really rather print the address and not the data
	1288	* it is pointing to?
	1289	*
	1290	* @param item Address to print.
	1291	*/
[09ababb7]	1292	static void rdata_address_print(rdata_address_t *address)
	1293	{
[d0febca]	1294	switch (address->ac) {
	1295	case ac_var:
	1296	rdata_var_print(address->u.var_a->vref);
	1297	break;
	1298	case ac_prop:
	1299	printf("Warning: Unimplemented: Print property address.\n");
	1300	break;
	1301	}
[09ababb7]	1302	}
	1303
[23de644]	1304	/** Print value in human-readable form.
	1305	*
	1306	* @param value Value to print.
	1307	*/
[1ebc1a62]	1308	void rdata_value_print(rdata_value_t *value)
[09ababb7]	1309	{
	1310	rdata_var_print(value->var);
	1311	}
	1312
[23de644]	1313	/** Print contents of var node in human-readable form.
	1314	*
	1315	* @param item Var node to print.
	1316	*/
[09ababb7]	1317	static void rdata_var_print(rdata_var_t *var)
	1318	{
[074444f]	1319	int val;
	1320
[09ababb7]	1321	switch (var->vc) {
[074444f]	1322	case vc_bool:
	1323	printf("bool(%s)", var->u.bool_v->value ? "true" : "false");
	1324	break;
	1325	case vc_char:
	1326	printf("char(");
	1327	if (bigint_get_value_int(&var->u.char_v->value, &val) == EOK)
	1328	printf("'%c'", val);
	1329	else
	1330	printf("???:x%x\n", (unsigned) val);
	1331	printf(")");
	1332	break;
[09ababb7]	1333	case vc_int:
[23de644]	1334	printf("int(");
	1335	bigint_print(&var->u.int_v->value);
	1336	printf(")");
[09ababb7]	1337	break;
[fa36f29]	1338	case vc_string:
	1339	printf("string(\"%s\")", var->u.string_v->value);
	1340	break;
[09ababb7]	1341	case vc_ref:
[38aaacc2]	1342	if (var->u.ref_v->vref != NULL) {
	1343	printf("ref(");
	1344	rdata_var_print(var->u.ref_v->vref);
	1345	printf(")");
	1346	} else {
	1347	printf("nil");
	1348	}
[09ababb7]	1349	break;
	1350	case vc_deleg:
[074444f]	1351	printf("deleg(");
[38aaacc2]	1352	if (var->u.deleg_v->sym != NULL) {
	1353	if (var->u.deleg_v->obj != NULL) {
	1354	rdata_var_print(var->u.deleg_v->obj);
	1355	printf(",");
	1356	}
	1357	symbol_print_fqn(var->u.deleg_v->sym);
	1358	} else {
	1359	printf("nil");
[074444f]	1360	}
	1361	printf(")");
	1362	break;
[051bc69a]	1363	case vc_enum:
	1364	symbol_print_fqn(
	1365	enum_to_symbol(var->u.enum_v->value->outer_enum));
	1366	printf(".%s",
	1367	strtab_get_str(var->u.enum_v->value->name->sid));
	1368	break;
[074444f]	1369	case vc_array:
	1370	printf("array");
[09ababb7]	1371	break;
	1372	case vc_object:
	1373	printf("object");
	1374	break;
[074444f]	1375	case vc_resource:
	1376	printf("resource(%p)", var->u.resource_v->data);
	1377	break;
[051bc69a]	1378	case vc_symbol:
	1379	printf("symbol(");
	1380	if (var->u.symbol_v->sym != NULL) {
	1381	symbol_print_fqn(var->u.symbol_v->sym);
	1382	} else {
	1383	printf("nil");
	1384	}
	1385	printf(")");
	1386	break;
[09ababb7]	1387	}
	1388	}

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