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a47ca06502461b36e6e86c57d472ba7184328698
blender-archive/source/blender/makesrna/intern/makesrna.c
Nathan Letwory a47ca06502 doxygen: blender/makesrna tagged.
2011-02-27 20:20:01 +00:00

2859 lines
87 KiB
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/*
* $Id$
*
* ***** BEGIN GPL LICENSE BLOCK *****
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* Contributor(s): Blender Foundation (2008).
*
* ***** END GPL LICENSE BLOCK *****
*/
/** \file blender/makesrna/intern/makesrna.c
* \ingroup RNA
*/
#include <float.h>
#include <limits.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include "MEM_guardedalloc.h"
#include "RNA_access.h"
#include "RNA_define.h"
#include "RNA_types.h"
#include "rna_internal.h"
#define RNA_VERSION_DATE "$Id$"
#ifdef _WIN32
#ifndef snprintf
#define snprintf _snprintf
#endif
#endif
/* Replace if different */
#define TMP_EXT ".tmp"
/* copied from BLI_file_older */
#include <sys/stat.h>
static int file_older(const char *file1, const char *file2)
{
struct stat st1, st2;
// printf("compare: %s %s\n", file1, file2);
if(stat(file1, &st1)) return 0;
if(stat(file2, &st2)) return 0;
return (st1.st_mtime < st2.st_mtime);
}
const char *makesrna_path= NULL;
static int replace_if_different(char *tmpfile, const char *dep_files[])
{
// return 0; // use for testing had edited rna
#define REN_IF_DIFF \
{ \
FILE *file_test= fopen(orgfile, "rb"); \
if(file_test) { \
fclose(file_test); \
if(fp_org) fclose(fp_org); \
if(fp_new) fclose(fp_new); \
if(remove(orgfile) != 0) { \
fprintf(stderr, "%s:%d, Remove Error (%s): \"%s\"\n", __FILE__, __LINE__, strerror(errno), orgfile); \
return -1; \
} \
} \
} \
if(rename(tmpfile, orgfile) != 0) { \
fprintf(stderr, "%s:%d, Rename Error (%s): \"%s\" -> \"%s\"\n", __FILE__, __LINE__, strerror(errno), tmpfile, orgfile); \
return -1; \
} \
remove(tmpfile); \
return 1; \
/* end REN_IF_DIFF */
FILE *fp_new= NULL, *fp_org= NULL;
int len_new, len_org;
char *arr_new, *arr_org;
int cmp;
char orgfile[4096];
strcpy(orgfile, tmpfile);
orgfile[strlen(orgfile) - strlen(TMP_EXT)] = '\0'; /* strip '.tmp' */
fp_org= fopen(orgfile, "rb");
if(fp_org==NULL) {
REN_IF_DIFF;
}
/* XXX, trick to work around dependancy problem
* assumes dep_files is in the same dir as makesrna.c, which is true for now. */
if(1) {
/* first check if makesrna.c is newer then generated files
* for development on makesrna.c you may want to disable this */
if(file_older(orgfile, __FILE__)) {
REN_IF_DIFF;
}
if(file_older(orgfile, makesrna_path)) {
REN_IF_DIFF;
}
/* now check if any files we depend on are newer then any generated files */
if(dep_files) {
int pass;
for(pass=0; dep_files[pass]; pass++) {
char from_path[4096]= __FILE__;
char *p1, *p2;
/* dir only */
p1= strrchr(from_path, '/');
p2= strrchr(from_path, '\\');
strcpy((p1 > p2 ? p1 : p2)+1, dep_files[pass]);
/* account for build deps, if makesrna.c (this file) is newer */
if(file_older(orgfile, from_path)) {
REN_IF_DIFF;
}
}
}
}
/* XXX end dep trick */
fp_new= fopen(tmpfile, "rb");
if(fp_new==NULL) {
/* shouldn't happen, just to be safe */
fprintf(stderr, "%s:%d, open error: \"%s\"\n", __FILE__, __LINE__, tmpfile);
fclose(fp_org);
return -1;
}
fseek(fp_new, 0L, SEEK_END); len_new = ftell(fp_new); fseek(fp_new, 0L, SEEK_SET);
fseek(fp_org, 0L, SEEK_END); len_org = ftell(fp_org); fseek(fp_org, 0L, SEEK_SET);
if(len_new != len_org) {
fclose(fp_new);
fclose(fp_org);
REN_IF_DIFF;
}
/* now compare the files... */
arr_new= MEM_mallocN(sizeof(char)*len_new, "rna_cmp_file_new");
arr_org= MEM_mallocN(sizeof(char)*len_org, "rna_cmp_file_org");
if(fread(arr_new, sizeof(char), len_new, fp_new) != len_new)
fprintf(stderr, "%s:%d, error reading file %s for comparison.\n", __FILE__, __LINE__, tmpfile);
if(fread(arr_org, sizeof(char), len_org, fp_org) != len_org)
fprintf(stderr, "%s:%d, error reading file %s for comparison.\n", __FILE__, __LINE__, orgfile);
fclose(fp_new);
fclose(fp_org);
cmp= memcmp(arr_new, arr_org, len_new);
MEM_freeN(arr_new);
MEM_freeN(arr_org);
if(cmp) {
REN_IF_DIFF;
}
else {
remove(tmpfile);
return 0;
}
#undef REN_IF_DIFF
}
/* Sorting */
static int cmp_struct(const void *a, const void *b)
{
const StructRNA *structa= *(const StructRNA**)a;
const StructRNA *structb= *(const StructRNA**)b;
return strcmp(structa->identifier, structb->identifier);
}
static int cmp_property(const void *a, const void *b)
{
const PropertyRNA *propa= *(const PropertyRNA**)a;
const PropertyRNA *propb= *(const PropertyRNA**)b;
if(strcmp(propa->identifier, "rna_type") == 0) return -1;
else if(strcmp(propb->identifier, "rna_type") == 0) return 1;
if(strcmp(propa->identifier, "name") == 0) return -1;
else if(strcmp(propb->identifier, "name") == 0) return 1;
return strcmp(propa->name, propb->name);
}
static int cmp_def_struct(const void *a, const void *b)
{
const StructDefRNA *dsa= *(const StructDefRNA**)a;
const StructDefRNA *dsb= *(const StructDefRNA**)b;
return cmp_struct(&dsa->srna, &dsb->srna);
}
static int cmp_def_property(const void *a, const void *b)
{
const PropertyDefRNA *dpa= *(const PropertyDefRNA**)a;
const PropertyDefRNA *dpb= *(const PropertyDefRNA**)b;
return cmp_property(&dpa->prop, &dpb->prop);
}
static void rna_sortlist(ListBase *listbase, int(*cmp)(const void*, const void*))
{
Link *link;
void **array;
int a, size;
if(listbase->first == listbase->last)
return;
for(size=0, link=listbase->first; link; link=link->next)
size++;
array= MEM_mallocN(sizeof(void*)*size, "rna_sortlist");
for(a=0, link=listbase->first; link; link=link->next, a++)
array[a]= link;
qsort(array, size, sizeof(void*), cmp);
listbase->first= listbase->last= NULL;
for(a=0; a<size; a++) {
link= array[a];
link->next= link->prev= NULL;
rna_addtail(listbase, link);
}
MEM_freeN(array);
}
/* Preprocessing */
static void rna_print_c_string(FILE *f, const char *str)
{
static const char *escape[] = {"\''", "\"\"", "\??", "\\\\","\aa", "\bb", "\ff", "\nn", "\rr", "\tt", "\vv", NULL};
int i, j;
if(!str) {
fprintf(f, "NULL");
return;
}
fprintf(f, "\"");
for(i=0; str[i]; i++) {
for(j=0; escape[j]; j++)
if(str[i] == escape[j][0])
break;
if(escape[j]) fprintf(f, "\\%c", escape[j][1]);
else fprintf(f, "%c", str[i]);
}
fprintf(f, "\"");
}
static void rna_print_data_get(FILE *f, PropertyDefRNA *dp)
{
if(dp->dnastructfromname && dp->dnastructfromprop)
fprintf(f, " %s *data= (%s*)(((%s*)ptr->data)->%s);\n", dp->dnastructname, dp->dnastructname, dp->dnastructfromname, dp->dnastructfromprop);
else
fprintf(f, " %s *data= (%s*)(ptr->data);\n", dp->dnastructname, dp->dnastructname);
}
static void rna_print_id_get(FILE *f, PropertyDefRNA *dp)
{
fprintf(f, " ID *id= ptr->id.data;\n");
}
static char *rna_alloc_function_name(const char *structname, const char *propname, const char *type)
{
AllocDefRNA *alloc;
char buffer[2048];
char *result;
snprintf(buffer, sizeof(buffer), "%s_%s_%s", structname, propname, type);
result= MEM_callocN(sizeof(char)*strlen(buffer)+1, "rna_alloc_function_name");
strcpy(result, buffer);
alloc= MEM_callocN(sizeof(AllocDefRNA), "AllocDefRNA");
alloc->mem= result;
rna_addtail(&DefRNA.allocs, alloc);
return result;
}
static StructRNA *rna_find_struct(const char *identifier)
{
StructDefRNA *ds;
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
if(strcmp(ds->srna->identifier, identifier)==0)
return ds->srna;
return NULL;
}
static const char *rna_find_type(const char *type)
{
StructDefRNA *ds;
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
if(ds->dnaname && strcmp(ds->dnaname, type)==0)
return ds->srna->identifier;
return NULL;
}
static const char *rna_find_dna_type(const char *type)
{
StructDefRNA *ds;
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
if(strcmp(ds->srna->identifier, type)==0)
return ds->dnaname;
return NULL;
}
static const char *rna_type_type_name(PropertyRNA *prop)
{
switch(prop->type) {
case PROP_BOOLEAN:
case PROP_INT:
case PROP_ENUM:
return "int";
case PROP_FLOAT:
return "float";
case PROP_STRING:
if(prop->flag & PROP_THICK_WRAP) {
return "char*";
}
else {
return "const char*";
}
default:
return NULL;
}
}
static const char *rna_type_type(PropertyRNA *prop)
{
const char *type;
type= rna_type_type_name(prop);
if(type)
return type;
return "PointerRNA";
}
static const char *rna_type_struct(PropertyRNA *prop)
{
const char *type;
type= rna_type_type_name(prop);
if(type)
return "";
return "struct ";
}
static const char *rna_parameter_type_name(PropertyRNA *parm)
{
const char *type;
type= rna_type_type_name(parm);
if(type)
return type;
switch(parm->type) {
case PROP_POINTER: {
PointerPropertyRNA *pparm= (PointerPropertyRNA*)parm;
if(parm->flag & PROP_RNAPTR)
return "PointerRNA";
else
return rna_find_dna_type((const char *)pparm->type);
}
case PROP_COLLECTION: {
return "ListBase";
}
default:
return "<error, no type specified>";
}
}
static int rna_enum_bitmask(PropertyRNA *prop)
{
EnumPropertyRNA *eprop= (EnumPropertyRNA*)prop;
int a, mask= 0;
if(eprop->item) {
for(a=0; a<eprop->totitem; a++)
if(eprop->item[a].identifier[0])
mask |= eprop->item[a].value;
}
return mask;
}
static int rna_color_quantize(PropertyRNA *prop, PropertyDefRNA *dp)
{
if(prop->type == PROP_FLOAT && (prop->subtype==PROP_COLOR || prop->subtype==PROP_COLOR_GAMMA))
if(strcmp(dp->dnatype, "float") != 0 && strcmp(dp->dnatype, "double") != 0)
return 1;
return 0;
}
static const char *rna_function_string(void *func)
{
return (func)? (const char*)func: "NULL";
}
static void rna_float_print(FILE *f, float num)
{
if(num == -FLT_MAX) fprintf(f, "-FLT_MAX");
else if(num == FLT_MAX) fprintf(f, "FLT_MAX");
else if((int)num == num) fprintf(f, "%.1ff", num);
else fprintf(f, "%.10ff", num);
}
static void rna_int_print(FILE *f, int num)
{
if(num == INT_MIN) fprintf(f, "INT_MIN");
else if(num == INT_MAX) fprintf(f, "INT_MAX");
else fprintf(f, "%d", num);
}
static char *rna_def_property_get_func(FILE *f, StructRNA *srna, PropertyRNA *prop, PropertyDefRNA *dp, const char *manualfunc)
{
char *func;
if(prop->flag & PROP_IDPROPERTY && manualfunc==NULL)
return NULL;
if(!manualfunc) {
if(!dp->dnastructname || !dp->dnaname) {
fprintf(stderr, "rna_def_property_get_func: %s.%s has no valid dna info.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
return NULL;
}
/* typecheck, */
if(dp->dnatype && *dp->dnatype) {
if(prop->type == PROP_FLOAT) {
if(IS_DNATYPE_FLOAT_COMPAT(dp->dnatype) == 0) {
if(prop->subtype != PROP_COLOR_GAMMA) { /* colors are an exception. these get translated */
fprintf(stderr, "rna_def_property_get_func1: %s.%s is a '%s' but wrapped as type '%s'.\n", srna->identifier, prop->identifier, dp->dnatype, RNA_property_typename(prop->type));
DefRNA.error= 1;
return NULL;
}
}
}
else if(prop->type == PROP_INT || prop->type == PROP_BOOLEAN || prop->type == PROP_ENUM) {
if(IS_DNATYPE_INT_COMPAT(dp->dnatype) == 0) {
fprintf(stderr, "rna_def_property_get_func2: %s.%s is a '%s' but wrapped as type '%s'.\n", srna->identifier, prop->identifier, dp->dnatype, RNA_property_typename(prop->type));
DefRNA.error= 1;
return NULL;
}
}
}
}
func= rna_alloc_function_name(srna->identifier, prop->identifier, "get");
switch(prop->type) {
case PROP_STRING: {
StringPropertyRNA *sprop= (StringPropertyRNA*)prop;
fprintf(f, "void %s(PointerRNA *ptr, char *value)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " %s(ptr, value);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(sprop->maxlength)
fprintf(f, " BLI_strncpy(value, data->%s, %d);\n", dp->dnaname, sprop->maxlength);
else
fprintf(f, " BLI_strncpy(value, data->%s, sizeof(data->%s));\n", dp->dnaname, dp->dnaname);
}
fprintf(f, "}\n\n");
break;
}
case PROP_POINTER: {
fprintf(f, "PointerRNA %s(PointerRNA *ptr)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " return %s(ptr);\n", manualfunc);
}
else {
PointerPropertyRNA *pprop= (PointerPropertyRNA*)prop;
rna_print_data_get(f, dp);
if(dp->dnapointerlevel == 0)
fprintf(f, " return rna_pointer_inherit_refine(ptr, &RNA_%s, &data->%s);\n", (char*)pprop->type, dp->dnaname);
else
fprintf(f, " return rna_pointer_inherit_refine(ptr, &RNA_%s, data->%s);\n", (char*)pprop->type, dp->dnaname);
}
fprintf(f, "}\n\n");
break;
}
case PROP_COLLECTION: {
CollectionPropertyRNA *cprop= (CollectionPropertyRNA*)prop;
fprintf(f, "static PointerRNA %s(CollectionPropertyIterator *iter)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
if(strcmp(manualfunc, "rna_iterator_listbase_get") == 0 ||
strcmp(manualfunc, "rna_iterator_array_get") == 0 ||
strcmp(manualfunc, "rna_iterator_array_dereference_get") == 0)
fprintf(f, " return rna_pointer_inherit_refine(&iter->parent, &RNA_%s, %s(iter));\n", (cprop->item_type)? (char*)cprop->item_type: "UnknownType", manualfunc);
else
fprintf(f, " return %s(iter);\n", manualfunc);
}
fprintf(f, "}\n\n");
break;
}
default:
if(prop->arraydimension) {
if(prop->flag & PROP_DYNAMIC)
fprintf(f, "void %s(PointerRNA *ptr, %s values[])\n", func, rna_type_type(prop));
else
fprintf(f, "void %s(PointerRNA *ptr, %s values[%d])\n", func, rna_type_type(prop), prop->totarraylength);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " %s(ptr, values);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(prop->flag & PROP_DYNAMIC) {
char *lenfunc= rna_alloc_function_name(srna->identifier, prop->identifier, "get_length");
fprintf(f, " int i, arraylen[RNA_MAX_ARRAY_DIMENSION];\n");
fprintf(f, " int len= %s(ptr, arraylen);\n\n", lenfunc);
fprintf(f, " for(i=0; i<len; i++) {\n");
MEM_freeN(lenfunc);
}
else {
fprintf(f, " int i;\n\n");
fprintf(f, " for(i=0; i<%d; i++) {\n", prop->totarraylength);
}
if(dp->dnaarraylength == 1) {
if(prop->type == PROP_BOOLEAN && dp->booleanbit)
fprintf(f, " values[i]= %s((data->%s & (%d<<i)) != 0);\n", (dp->booleannegative)? "!": "", dp->dnaname, dp->booleanbit);
else
fprintf(f, " values[i]= (%s)%s((&data->%s)[i]);\n", rna_type_type(prop), (dp->booleannegative)? "!": "", dp->dnaname);
}
else {
if(prop->type == PROP_BOOLEAN && dp->booleanbit) {
fprintf(f, " values[i]= %s((data->%s[i] & ", (dp->booleannegative)? "!": "", dp->dnaname);
rna_int_print(f, dp->booleanbit);
fprintf(f, ") != 0);\n");
}
else if(rna_color_quantize(prop, dp))
fprintf(f, " values[i]= (%s)(data->%s[i]*(1.0f/255.0f));\n", rna_type_type(prop), dp->dnaname);
else if(dp->dnatype)
fprintf(f, " values[i]= (%s)%s(((%s*)data->%s)[i]);\n", rna_type_type(prop), (dp->booleannegative)? "!": "", dp->dnatype, dp->dnaname);
else
fprintf(f, " values[i]= (%s)%s((data->%s)[i]);\n", rna_type_type(prop), (dp->booleannegative)? "!": "", dp->dnaname);
}
fprintf(f, " }\n");
}
fprintf(f, "}\n\n");
}
else {
fprintf(f, "%s %s(PointerRNA *ptr)\n", rna_type_type(prop), func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " return %s(ptr);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(prop->type == PROP_BOOLEAN && dp->booleanbit) {
fprintf(f, " return %s(((data->%s) & ", (dp->booleannegative)? "!": "", dp->dnaname);
rna_int_print(f, dp->booleanbit);
fprintf(f, ") != 0);\n");
}
else if(prop->type == PROP_ENUM && dp->enumbitflags) {
fprintf(f, " return ((data->%s) & ", dp->dnaname);
rna_int_print(f, rna_enum_bitmask(prop));
fprintf(f, ");\n");
}
else
fprintf(f, " return (%s)%s(data->%s);\n", rna_type_type(prop), (dp->booleannegative)? "!": "", dp->dnaname);
}
fprintf(f, "}\n\n");
}
break;
}
return func;
}
static void rna_clamp_value(FILE *f, PropertyRNA *prop, int array)
{
if(prop->type == PROP_INT) {
IntPropertyRNA *iprop= (IntPropertyRNA*)prop;
if(iprop->hardmin != INT_MIN || iprop->hardmax != INT_MAX) {
if(array) fprintf(f, "CLAMPIS(values[i], ");
else fprintf(f, "CLAMPIS(value, ");
rna_int_print(f, iprop->hardmin); fprintf(f, ", ");
rna_int_print(f, iprop->hardmax); fprintf(f, ");\n");
return;
}
}
else if(prop->type == PROP_FLOAT) {
FloatPropertyRNA *fprop= (FloatPropertyRNA*)prop;
if(fprop->hardmin != -FLT_MAX || fprop->hardmax != FLT_MAX) {
if(array) fprintf(f, "CLAMPIS(values[i], ");
else fprintf(f, "CLAMPIS(value, ");
rna_float_print(f, fprop->hardmin); fprintf(f, ", ");
rna_float_print(f, fprop->hardmax); fprintf(f, ");\n");
return;
}
}
if(array)
fprintf(f, "values[i];\n");
else
fprintf(f, "value;\n");
}
static char *rna_def_property_set_func(FILE *f, StructRNA *srna, PropertyRNA *prop, PropertyDefRNA *dp, char *manualfunc)
{
char *func;
if(!(prop->flag & PROP_EDITABLE))
return NULL;
if(prop->flag & PROP_IDPROPERTY && manualfunc==NULL)
return NULL;
if(!manualfunc) {
if(!dp->dnastructname || !dp->dnaname) {
if(prop->flag & PROP_EDITABLE) {
fprintf(stderr, "rna_def_property_set_func: %s.%s has no valid dna info.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
}
return NULL;
}
}
func= rna_alloc_function_name(srna->identifier, prop->identifier, "set");
switch(prop->type) {
case PROP_STRING: {
StringPropertyRNA *sprop= (StringPropertyRNA*)prop;
fprintf(f, "void %s(PointerRNA *ptr, const char *value)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " %s(ptr, value);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(sprop->maxlength)
fprintf(f, " BLI_strncpy(data->%s, value, %d);\n", dp->dnaname, sprop->maxlength);
else
fprintf(f, " BLI_strncpy(data->%s, value, sizeof(data->%s));\n", dp->dnaname, dp->dnaname);
}
fprintf(f, "}\n\n");
break;
}
case PROP_POINTER: {
fprintf(f, "void %s(PointerRNA *ptr, PointerRNA value)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " %s(ptr, value);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(prop->flag & PROP_ID_SELF_CHECK) {
rna_print_id_get(f, dp);
fprintf(f, " if(id==value.data) return;\n\n");
}
if(prop->flag & PROP_ID_REFCOUNT) {
fprintf(f, "\n if(data->%s)\n", dp->dnaname);
fprintf(f, " id_us_min((ID*)data->%s);\n", dp->dnaname);
fprintf(f, " if(value.data)\n");
fprintf(f, " id_us_plus((ID*)value.data);\n\n");
}
else {
PointerPropertyRNA *pprop= (PointerPropertyRNA*)dp->prop;
StructRNA *type= rna_find_struct((char*)pprop->type);
if(type && (type->flag & STRUCT_ID)) {
fprintf(f, " if(value.data)\n");
fprintf(f, " id_lib_extern((ID*)value.data);\n\n");
}
}
fprintf(f, " data->%s= value.data;\n", dp->dnaname);
}
fprintf(f, "}\n\n");
break;
}
default:
if(prop->arraydimension) {
if(prop->flag & PROP_DYNAMIC)
fprintf(f, "void %s(PointerRNA *ptr, const %s values[])\n", func, rna_type_type(prop));
else
fprintf(f, "void %s(PointerRNA *ptr, const %s values[%d])\n", func, rna_type_type(prop), prop->totarraylength);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " %s(ptr, values);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(prop->flag & PROP_DYNAMIC) {
char *lenfunc= rna_alloc_function_name(srna->identifier, prop->identifier, "set_length");
fprintf(f, " int i, arraylen[RNA_MAX_ARRAY_DIMENSION];\n");
fprintf(f, " int len= %s(ptr, arraylen);\n\n", lenfunc);
fprintf(f, " for(i=0; i<len; i++) {\n");
MEM_freeN(lenfunc);
}
else {
fprintf(f, " int i;\n\n");
fprintf(f, " for(i=0; i<%d; i++) {\n", prop->totarraylength);
}
if(dp->dnaarraylength == 1) {
if(prop->type == PROP_BOOLEAN && dp->booleanbit) {
fprintf(f, " if(%svalues[i]) data->%s |= (%d<<i);\n", (dp->booleannegative)? "!": "", dp->dnaname, dp->booleanbit);
fprintf(f, " else data->%s &= ~(%d<<i);\n", dp->dnaname, dp->booleanbit);
}
else {
fprintf(f, " (&data->%s)[i]= %s", dp->dnaname, (dp->booleannegative)? "!": "");
rna_clamp_value(f, prop, 1);
}
}
else {
if(prop->type == PROP_BOOLEAN && dp->booleanbit) {
fprintf(f, " if(%svalues[i]) data->%s[i] |= ", (dp->booleannegative)? "!": "", dp->dnaname);
rna_int_print(f, dp->booleanbit);
fprintf(f, ";\n");
fprintf(f, " else data->%s[i] &= ~", dp->dnaname);
rna_int_print(f, dp->booleanbit);
fprintf(f, ";\n");
}
else if(rna_color_quantize(prop, dp)) {
fprintf(f, " data->%s[i]= FTOCHAR(values[i]);\n", dp->dnaname);
}
else {
if(dp->dnatype)
fprintf(f, " ((%s*)data->%s)[i]= %s", dp->dnatype, dp->dnaname, (dp->booleannegative)? "!": "");
else
fprintf(f, " (data->%s)[i]= %s", dp->dnaname, (dp->booleannegative)? "!": "");
rna_clamp_value(f, prop, 1);
}
}
fprintf(f, " }\n");
}
fprintf(f, "}\n\n");
}
else {
fprintf(f, "void %s(PointerRNA *ptr, %s value)\n", func, rna_type_type(prop));
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " %s(ptr, value);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(prop->type == PROP_BOOLEAN && dp->booleanbit) {
fprintf(f, " if(%svalue) data->%s |= ", (dp->booleannegative)? "!": "", dp->dnaname);
rna_int_print(f, dp->booleanbit);
fprintf(f, ";\n");
fprintf(f, " else data->%s &= ~", dp->dnaname);
rna_int_print(f, dp->booleanbit);
fprintf(f, ";\n");
}
else if(prop->type == PROP_ENUM && dp->enumbitflags) {
fprintf(f, " data->%s &= ~", dp->dnaname);
rna_int_print(f, rna_enum_bitmask(prop));
fprintf(f, ";\n");
fprintf(f, " data->%s |= value;\n", dp->dnaname);
}
else {
fprintf(f, " data->%s= %s", dp->dnaname, (dp->booleannegative)? "!": "");
rna_clamp_value(f, prop, 0);
}
}
fprintf(f, "}\n\n");
}
break;
}
return func;
}
static char *rna_def_property_length_func(FILE *f, StructRNA *srna, PropertyRNA *prop, PropertyDefRNA *dp, char *manualfunc)
{
char *func= NULL;
if(prop->flag & PROP_IDPROPERTY && manualfunc==NULL)
return NULL;
if(prop->type == PROP_STRING) {
if(!manualfunc) {
if(!dp->dnastructname || !dp->dnaname) {
fprintf(stderr, "rna_def_property_length_func: %s.%s has no valid dna info.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
return NULL;
}
}
func= rna_alloc_function_name(srna->identifier, prop->identifier, "length");
fprintf(f, "int %s(PointerRNA *ptr)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " return %s(ptr);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
fprintf(f, " return strlen(data->%s);\n", dp->dnaname);
}
fprintf(f, "}\n\n");
}
else if(prop->type == PROP_COLLECTION) {
if(!manualfunc) {
if(prop->type == PROP_COLLECTION && (!(dp->dnalengthname || dp->dnalengthfixed)|| !dp->dnaname)) {
fprintf(stderr, "rna_def_property_length_func: %s.%s has no valid dna info.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
return NULL;
}
}
func= rna_alloc_function_name(srna->identifier, prop->identifier, "length");
fprintf(f, "int %s(PointerRNA *ptr)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, " return %s(ptr);\n", manualfunc);
}
else {
rna_print_data_get(f, dp);
if(dp->dnalengthname)
fprintf(f, " return (data->%s == NULL)? 0: data->%s;\n", dp->dnaname, dp->dnalengthname);
else
fprintf(f, " return (data->%s == NULL)? 0: %d;\n", dp->dnaname, dp->dnalengthfixed);
}
fprintf(f, "}\n\n");
}
return func;
}
static char *rna_def_property_begin_func(FILE *f, StructRNA *srna, PropertyRNA *prop, PropertyDefRNA *dp, char *manualfunc)
{
char *func, *getfunc;
if(prop->flag & PROP_IDPROPERTY && manualfunc==NULL)
return NULL;
if(!manualfunc) {
if(!dp->dnastructname || !dp->dnaname) {
fprintf(stderr, "rna_def_property_begin_func: %s.%s has no valid dna info.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
return NULL;
}
}
func= rna_alloc_function_name(srna->identifier, prop->identifier, "begin");
fprintf(f, "void %s(CollectionPropertyIterator *iter, PointerRNA *ptr)\n", func);
fprintf(f, "{\n");
if(!manualfunc)
rna_print_data_get(f, dp);
fprintf(f, "\n memset(iter, 0, sizeof(*iter));\n");
fprintf(f, " iter->parent= *ptr;\n");
fprintf(f, " iter->prop= (PropertyRNA*)&rna_%s_%s;\n", srna->identifier, prop->identifier);
if(dp->dnalengthname || dp->dnalengthfixed) {
if(manualfunc) {
fprintf(f, "\n %s(iter, ptr);\n", manualfunc);
}
else {
if(dp->dnalengthname)
fprintf(f, "\n rna_iterator_array_begin(iter, data->%s, sizeof(data->%s[0]), data->%s, 0, NULL);\n", dp->dnaname, dp->dnaname, dp->dnalengthname);
else
fprintf(f, "\n rna_iterator_array_begin(iter, data->%s, sizeof(data->%s[0]), %d, 0, NULL);\n", dp->dnaname, dp->dnaname, dp->dnalengthfixed);
}
}
else {
if(manualfunc)
fprintf(f, "\n %s(iter, ptr);\n", manualfunc);
else if(dp->dnapointerlevel == 0)
fprintf(f, "\n rna_iterator_listbase_begin(iter, &data->%s, NULL);\n", dp->dnaname);
else
fprintf(f, "\n rna_iterator_listbase_begin(iter, data->%s, NULL);\n", dp->dnaname);
}
getfunc= rna_alloc_function_name(srna->identifier, prop->identifier, "get");
fprintf(f, "\n if(iter->valid)\n");
fprintf(f, " iter->ptr= %s(iter);\n", getfunc);
fprintf(f, "}\n\n");
return func;
}
static char *rna_def_property_lookup_int_func(FILE *f, StructRNA *srna, PropertyRNA *prop, PropertyDefRNA *dp, char *manualfunc, char *nextfunc)
{
/* note on indices, this is for external functions and ignores skipped values.
* so the the index can only be checked against the length when there is no 'skip' funcion. */
char *func;
if(prop->flag & PROP_IDPROPERTY && manualfunc==NULL)
return NULL;
if(!manualfunc) {
if(!dp->dnastructname || !dp->dnaname)
return NULL;
/* only supported in case of standard next functions */
if(strcmp(nextfunc, "rna_iterator_array_next") == 0);
else if(strcmp(nextfunc, "rna_iterator_listbase_next") == 0);
else return NULL;
}
func= rna_alloc_function_name(srna->identifier, prop->identifier, "lookup_int");
fprintf(f, "int %s(PointerRNA *ptr, int index, PointerRNA *r_ptr)\n", func);
fprintf(f, "{\n");
if(manualfunc) {
fprintf(f, "\n return %s(ptr, index, r_ptr);\n", manualfunc);
fprintf(f, "}\n\n");
return func;
}
fprintf(f, " int found= 0;\n");
fprintf(f, " CollectionPropertyIterator iter;\n\n");
fprintf(f, " %s_%s_begin(&iter, ptr);\n\n", srna->identifier, prop->identifier);
fprintf(f, " if(iter.valid){\n");
if(strcmp(nextfunc, "rna_iterator_array_next") == 0) {
fprintf(f, " ArrayIterator *internal= iter.internal;\n");
fprintf(f, " if(index < 0 || index >= internal->length) {\n");
fprintf(f, "#ifdef __GNUC__\n");
fprintf(f, " printf(\"Array iterator out of range: %%s (index %%d)\\n\", __func__, index);\n");
fprintf(f, "#else\n");
fprintf(f, " printf(\"Array iterator out of range: (index %%d)\\n\", index);\n");
fprintf(f, "#endif\n");
fprintf(f, " }\n");
fprintf(f, " else if(internal->skip) {\n");
fprintf(f, " while(index-- > 0 && iter.valid) {\n");
fprintf(f, " rna_iterator_array_next(&iter);\n");
fprintf(f, " }\n");
fprintf(f, " found= (index == -1 && iter.valid);\n");
fprintf(f, " }\n");
fprintf(f, " else {\n");
fprintf(f, " internal->ptr += internal->itemsize*index;\n");
fprintf(f, " found= 1;\n");
fprintf(f, " }\n");
}
else if(strcmp(nextfunc, "rna_iterator_listbase_next") == 0) {
fprintf(f, " ListBaseIterator *internal= iter.internal;\n");
fprintf(f, " if(internal->skip) {\n");
fprintf(f, " while(index-- > 0 && iter.valid) {\n");
fprintf(f, " rna_iterator_listbase_next(&iter);\n");
fprintf(f, " }\n");
fprintf(f, " found= (index == -1 && iter.valid);\n");
fprintf(f, " }\n");
fprintf(f, " else {\n");
fprintf(f, " while(index-- > 0 && internal->link)\n");
fprintf(f, " internal->link= internal->link->next;\n");
fprintf(f, " found= (index == -1 && internal->link);\n");
fprintf(f, " }\n");
}
fprintf(f, " if(found) *r_ptr = %s_%s_get(&iter);\n", srna->identifier, prop->identifier);
fprintf(f, " }\n\n");
fprintf(f, " %s_%s_end(&iter);\n\n", srna->identifier, prop->identifier);
fprintf(f, " return found;\n");
#if 0
rna_print_data_get(f, dp);
item_type= (cprop->item_type)? (char*)cprop->item_type: "UnknownType";
if(dp->dnalengthname || dp->dnalengthfixed) {
if(dp->dnalengthname)
fprintf(f, "\n rna_array_lookup_int(ptr, &RNA_%s, data->%s, sizeof(data->%s[0]), data->%s, index);\n", item_type, dp->dnaname, dp->dnaname, dp->dnalengthname);
else
fprintf(f, "\n rna_array_lookup_int(ptr, &RNA_%s, data->%s, sizeof(data->%s[0]), %d, index);\n", item_type, dp->dnaname, dp->dnaname, dp->dnalengthfixed);
}
else {
if(dp->dnapointerlevel == 0)
fprintf(f, "\n return rna_listbase_lookup_int(ptr, &RNA_%s, &data->%s, index);\n", item_type, dp->dnaname);
else
fprintf(f, "\n return rna_listbase_lookup_int(ptr, &RNA_%s, data->%s, index);\n", item_type, dp->dnaname);
}
#endif
fprintf(f, "}\n\n");
return func;
}
static char *rna_def_property_next_func(FILE *f, StructRNA *srna, PropertyRNA *prop, PropertyDefRNA *dp, char *manualfunc)
{
char *func, *getfunc;
if(prop->flag & PROP_IDPROPERTY && manualfunc==NULL)
return NULL;
if(!manualfunc)
return NULL;
func= rna_alloc_function_name(srna->identifier, prop->identifier, "next");
fprintf(f, "void %s(CollectionPropertyIterator *iter)\n", func);
fprintf(f, "{\n");
fprintf(f, " %s(iter);\n", manualfunc);
getfunc= rna_alloc_function_name(srna->identifier, prop->identifier, "get");
fprintf(f, "\n if(iter->valid)\n");
fprintf(f, " iter->ptr= %s(iter);\n", getfunc);
fprintf(f, "}\n\n");
return func;
}
static char *rna_def_property_end_func(FILE *f, StructRNA *srna, PropertyRNA *prop, PropertyDefRNA *dp, char *manualfunc)
{
char *func;
if(prop->flag & PROP_IDPROPERTY && manualfunc==NULL)
return NULL;
func= rna_alloc_function_name(srna->identifier, prop->identifier, "end");
fprintf(f, "void %s(CollectionPropertyIterator *iter)\n", func);
fprintf(f, "{\n");
if(manualfunc)
fprintf(f, " %s(iter);\n", manualfunc);
fprintf(f, "}\n\n");
return func;
}
static void rna_set_raw_property(PropertyDefRNA *dp, PropertyRNA *prop)
{
if(dp->dnapointerlevel != 0)
return;
if(!dp->dnatype || !dp->dnaname || !dp->dnastructname)
return;
if(strcmp(dp->dnatype, "char") == 0) {
prop->rawtype= PROP_RAW_CHAR;
prop->flag |= PROP_RAW_ACCESS;
}
else if(strcmp(dp->dnatype, "short") == 0) {
prop->rawtype= PROP_RAW_SHORT;
prop->flag |= PROP_RAW_ACCESS;
}
else if(strcmp(dp->dnatype, "int") == 0) {
prop->rawtype= PROP_RAW_INT;
prop->flag |= PROP_RAW_ACCESS;
}
else if(strcmp(dp->dnatype, "float") == 0) {
prop->rawtype= PROP_RAW_FLOAT;
prop->flag |= PROP_RAW_ACCESS;
}
else if(strcmp(dp->dnatype, "double") == 0) {
prop->rawtype= PROP_RAW_DOUBLE;
prop->flag |= PROP_RAW_ACCESS;
}
}
static void rna_set_raw_offset(FILE *f, StructRNA *srna, PropertyRNA *prop)
{
PropertyDefRNA *dp= rna_find_struct_property_def(srna, prop);
fprintf(f, "\toffsetof(%s, %s), %d", dp->dnastructname, dp->dnaname, prop->rawtype);
}
static void rna_def_property_funcs(FILE *f, StructRNA *srna, PropertyDefRNA *dp)
{
PropertyRNA *prop;
prop= dp->prop;
switch(prop->type) {
case PROP_BOOLEAN: {
BooleanPropertyRNA *bprop= (BooleanPropertyRNA*)prop;
if(!prop->arraydimension) {
if(!bprop->get && !bprop->set && !dp->booleanbit)
rna_set_raw_property(dp, prop);
bprop->get= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)bprop->get);
bprop->set= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)bprop->set);
}
else {
bprop->getarray= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)bprop->getarray);
bprop->setarray= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)bprop->setarray);
}
break;
}
case PROP_INT: {
IntPropertyRNA *iprop= (IntPropertyRNA*)prop;
if(!prop->arraydimension) {
if(!iprop->get && !iprop->set)
rna_set_raw_property(dp, prop);
iprop->get= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)iprop->get);
iprop->set= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)iprop->set);
}
else {
if(!iprop->getarray && !iprop->setarray)
rna_set_raw_property(dp, prop);
iprop->getarray= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)iprop->getarray);
iprop->setarray= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)iprop->setarray);
}
break;
}
case PROP_FLOAT: {
FloatPropertyRNA *fprop= (FloatPropertyRNA*)prop;
if(!prop->arraydimension) {
if(!fprop->get && !fprop->set)
rna_set_raw_property(dp, prop);
fprop->get= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)fprop->get);
fprop->set= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)fprop->set);
}
else {
if(!fprop->getarray && !fprop->setarray)
rna_set_raw_property(dp, prop);
fprop->getarray= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)fprop->getarray);
fprop->setarray= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)fprop->setarray);
}
break;
}
case PROP_ENUM: {
EnumPropertyRNA *eprop= (EnumPropertyRNA*)prop;
eprop->get= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)eprop->get);
eprop->set= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)eprop->set);
break;
}
case PROP_STRING: {
StringPropertyRNA *sprop= (StringPropertyRNA*)prop;
sprop->get= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)sprop->get);
sprop->length= (void*)rna_def_property_length_func(f, srna, prop, dp, (char*)sprop->length);
sprop->set= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)sprop->set);
break;
}
case PROP_POINTER: {
PointerPropertyRNA *pprop= (PointerPropertyRNA*)prop;
pprop->get= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)pprop->get);
pprop->set= (void*)rna_def_property_set_func(f, srna, prop, dp, (char*)pprop->set);
if(!pprop->type) {
fprintf(stderr, "rna_def_property_funcs: %s.%s, pointer must have a struct type.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
}
break;
}
case PROP_COLLECTION: {
CollectionPropertyRNA *cprop= (CollectionPropertyRNA*)prop;
char *nextfunc= (char*)cprop->next;
if(dp->dnatype && strcmp(dp->dnatype, "ListBase")==0);
else if(dp->dnalengthname || dp->dnalengthfixed)
cprop->length= (void*)rna_def_property_length_func(f, srna, prop, dp, (char*)cprop->length);
/* test if we can allow raw array access, if it is using our standard
* array get/next function, we can be sure it is an actual array */
if(cprop->next && cprop->get)
if(strcmp((char*)cprop->next, "rna_iterator_array_next") == 0 &&
strcmp((char*)cprop->get, "rna_iterator_array_get") == 0)
prop->flag |= PROP_RAW_ARRAY;
cprop->get= (void*)rna_def_property_get_func(f, srna, prop, dp, (char*)cprop->get);
cprop->begin= (void*)rna_def_property_begin_func(f, srna, prop, dp, (char*)cprop->begin);
cprop->next= (void*)rna_def_property_next_func(f, srna, prop, dp, (char*)cprop->next);
cprop->end= (void*)rna_def_property_end_func(f, srna, prop, dp, (char*)cprop->end);
cprop->lookupint= (void*)rna_def_property_lookup_int_func(f, srna, prop, dp, (char*)cprop->lookupint, nextfunc);
if(!(prop->flag & PROP_IDPROPERTY)) {
if(!cprop->begin) {
fprintf(stderr, "rna_def_property_funcs: %s.%s, collection must have a begin function.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
}
if(!cprop->next) {
fprintf(stderr, "rna_def_property_funcs: %s.%s, collection must have a next function.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
}
if(!cprop->get) {
fprintf(stderr, "rna_def_property_funcs: %s.%s, collection must have a get function.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
}
}
if(!cprop->item_type) {
fprintf(stderr, "rna_def_property_funcs: %s.%s, collection must have a struct type.\n", srna->identifier, prop->identifier);
DefRNA.error= 1;
}
break;
}
}
}
static void rna_def_property_funcs_header(FILE *f, StructRNA *srna, PropertyDefRNA *dp)
{
PropertyRNA *prop;
char *func;
prop= dp->prop;
if(prop->flag & (PROP_IDPROPERTY|PROP_BUILTIN))
return;
func= rna_alloc_function_name(srna->identifier, prop->identifier, "");
switch(prop->type) {
case PROP_BOOLEAN:
case PROP_INT: {
if(!prop->arraydimension) {
fprintf(f, "int %sget(PointerRNA *ptr);\n", func);
//fprintf(f, "void %sset(PointerRNA *ptr, int value);\n", func);
}
else {
fprintf(f, "void %sget(PointerRNA *ptr, int values[%d]);\n", func, prop->totarraylength);
//fprintf(f, "void %sset(PointerRNA *ptr, const int values[%d]);\n", func, prop->arraylength);
}
break;
}
case PROP_FLOAT: {
if(!prop->arraydimension) {
fprintf(f, "float %sget(PointerRNA *ptr);\n", func);
//fprintf(f, "void %sset(PointerRNA *ptr, float value);\n", func);
}
else {
fprintf(f, "void %sget(PointerRNA *ptr, float values[%d]);\n", func, prop->totarraylength);
//fprintf(f, "void %sset(PointerRNA *ptr, const float values[%d]);\n", func, prop->arraylength);
}
break;
}
case PROP_ENUM: {
EnumPropertyRNA *eprop= (EnumPropertyRNA*)prop;
int i;
if(eprop->item) {
fprintf(f, "enum {\n");
for(i=0; i<eprop->totitem; i++)
if(eprop->item[i].identifier[0])
fprintf(f, "\t%s_%s_%s = %d,\n", srna->identifier, prop->identifier, eprop->item[i].identifier, eprop->item[i].value);
fprintf(f, "};\n\n");
}
fprintf(f, "int %sget(PointerRNA *ptr);\n", func);
//fprintf(f, "void %sset(PointerRNA *ptr, int value);\n", func);
break;
}
case PROP_STRING: {
StringPropertyRNA *sprop= (StringPropertyRNA*)prop;
if(sprop->maxlength) {
fprintf(f, "#define %s_%s_MAX %d\n\n", srna->identifier, prop->identifier, sprop->maxlength);
}
fprintf(f, "void %sget(PointerRNA *ptr, char *value);\n", func);
fprintf(f, "int %slength(PointerRNA *ptr);\n", func);
//fprintf(f, "void %sset(PointerRNA *ptr, const char *value);\n", func);
break;
}
case PROP_POINTER: {
fprintf(f, "PointerRNA %sget(PointerRNA *ptr);\n", func);
//fprintf(f, "void %sset(PointerRNA *ptr, PointerRNA value);\n", func);
break;
}
case PROP_COLLECTION: {
fprintf(f, "void %sbegin(CollectionPropertyIterator *iter, PointerRNA *ptr);\n", func);
fprintf(f, "void %snext(CollectionPropertyIterator *iter);\n", func);
fprintf(f, "void %send(CollectionPropertyIterator *iter);\n", func);
//fprintf(f, "int %slength(PointerRNA *ptr);\n", func);
//fprintf(f, "void %slookup_int(PointerRNA *ptr, int key, StructRNA **type);\n", func);
//fprintf(f, "void %slookup_string(PointerRNA *ptr, const char *key, StructRNA **type);\n", func);
break;
}
}
fprintf(f, "\n");
}
static void rna_def_property_funcs_header_cpp(FILE *f, StructRNA *srna, PropertyDefRNA *dp)
{
PropertyRNA *prop;
prop= dp->prop;
if(prop->flag & (PROP_IDPROPERTY|PROP_BUILTIN))
return;
if(prop->name && prop->description && strcmp(prop->description, "") != 0)
fprintf(f, "\t/* %s: %s */\n", prop->name, prop->description);
else if(prop->name)
fprintf(f, "\t/* %s */\n", prop->name);
else
fprintf(f, "\t/* */\n");
switch(prop->type) {
case PROP_BOOLEAN: {
if(!prop->arraydimension)
fprintf(f, "\tbool %s(void);", prop->identifier);
else
fprintf(f, "\tArray<int, %d> %s(void);", prop->totarraylength, prop->identifier);
break;
}
case PROP_INT: {
if(!prop->arraydimension)
fprintf(f, "\tint %s(void);", prop->identifier);
else
fprintf(f, "\tArray<int, %d> %s(void);", prop->totarraylength, prop->identifier);
break;
}
case PROP_FLOAT: {
if(!prop->arraydimension)
fprintf(f, "\tfloat %s(void);", prop->identifier);
else
fprintf(f, "\tArray<float, %d> %s(void);", prop->totarraylength, prop->identifier);
break;
}
case PROP_ENUM: {
EnumPropertyRNA *eprop= (EnumPropertyRNA*)prop;
int i;
if(eprop->item) {
fprintf(f, "\tenum %s_enum {\n", prop->identifier);
for(i=0; i<eprop->totitem; i++)
if(eprop->item[i].identifier[0])
fprintf(f, "\t\t%s_%s = %d,\n", prop->identifier, eprop->item[i].identifier, eprop->item[i].value);
fprintf(f, "\t};\n");
}
fprintf(f, "\t%s_enum %s(void);", prop->identifier, prop->identifier);
break;
}
case PROP_STRING: {
fprintf(f, "\tstd::string %s(void);", prop->identifier);
break;
}
case PROP_POINTER: {
PointerPropertyRNA *pprop= (PointerPropertyRNA*)dp->prop;
if(pprop->type)
fprintf(f, "\t%s %s(void);", (char*)pprop->type, prop->identifier);
else
fprintf(f, "\t%s %s(void);", "UnknownType", prop->identifier);
break;
}
case PROP_COLLECTION: {
CollectionPropertyRNA *cprop= (CollectionPropertyRNA*)dp->prop;
if(cprop->item_type)
fprintf(f, "\tCOLLECTION_PROPERTY(%s, %s, %s)", (char*)cprop->item_type, srna->identifier, prop->identifier);
else
fprintf(f, "\tCOLLECTION_PROPERTY(%s, %s, %s)", "UnknownType", srna->identifier, prop->identifier);
break;
}
}
fprintf(f, "\n");
}
static void rna_def_property_funcs_impl_cpp(FILE *f, StructRNA *srna, PropertyDefRNA *dp)
{
PropertyRNA *prop;
prop= dp->prop;
if(prop->flag & (PROP_IDPROPERTY|PROP_BUILTIN))
return;
switch(prop->type) {
case PROP_BOOLEAN: {
if(!prop->arraydimension)
fprintf(f, "\tBOOLEAN_PROPERTY(%s, %s)", srna->identifier, prop->identifier);
else
fprintf(f, "\tBOOLEAN_ARRAY_PROPERTY(%s, %d, %s)", srna->identifier, prop->totarraylength, prop->identifier);
break;
}
case PROP_INT: {
if(!prop->arraydimension)
fprintf(f, "\tINT_PROPERTY(%s, %s)", srna->identifier, prop->identifier);
else
fprintf(f, "\tINT_ARRAY_PROPERTY(%s, %d, %s)", srna->identifier, prop->totarraylength, prop->identifier);
break;
}
case PROP_FLOAT: {
if(!prop->arraydimension)
fprintf(f, "\tFLOAT_PROPERTY(%s, %s)", srna->identifier, prop->identifier);
else
fprintf(f, "\tFLOAT_ARRAY_PROPERTY(%s, %d, %s)", srna->identifier, prop->totarraylength, prop->identifier);
break;
}
case PROP_ENUM: {
fprintf(f, "\tENUM_PROPERTY(%s_enum, %s, %s)", prop->identifier, srna->identifier, prop->identifier);
break;
}
case PROP_STRING: {
fprintf(f, "\tSTRING_PROPERTY(%s, %s)", srna->identifier, prop->identifier);
break;
}
case PROP_POINTER: {
PointerPropertyRNA *pprop= (PointerPropertyRNA*)dp->prop;
if(pprop->type)
fprintf(f, "\tPOINTER_PROPERTY(%s, %s, %s)", (char*)pprop->type, srna->identifier, prop->identifier);
else
fprintf(f, "\tPOINTER_PROPERTY(%s, %s, %s)", "UnknownType", srna->identifier, prop->identifier);
break;
}
case PROP_COLLECTION: {
/*CollectionPropertyRNA *cprop= (CollectionPropertyRNA*)dp->prop;
if(cprop->type)
fprintf(f, "\tCOLLECTION_PROPERTY(%s, %s, %s)", (char*)cprop->type, srna->identifier, prop->identifier);
else
fprintf(f, "\tCOLLECTION_PROPERTY(%s, %s, %s)", "UnknownType", srna->identifier, prop->identifier);*/
break;
}
}
fprintf(f, "\n");
}
static void rna_def_function_funcs(FILE *f, StructDefRNA *dsrna, FunctionDefRNA *dfunc)
{
StructRNA *srna;
FunctionRNA *func;
PropertyDefRNA *dparm;
PropertyType type;
const char *funcname, *valstr;
const char *ptrstr;
const short has_data= (dfunc->cont.properties.first != NULL);
int flag, pout, cptr, first;
srna= dsrna->srna;
func= dfunc->func;
if(!dfunc->call)
return;
funcname= rna_alloc_function_name(srna->identifier, func->identifier, "call");
/* function definition */
fprintf(f, "void %s(bContext *C, ReportList *reports, PointerRNA *_ptr, ParameterList *_parms)", funcname);
fprintf(f, "\n{\n");
/* variable definitions */
if(func->flag & FUNC_USE_SELF_ID) {
fprintf(f, "\tstruct ID *_selfid;\n");
}
if((func->flag & FUNC_NO_SELF)==0) {
if(dsrna->dnaname) fprintf(f, "\tstruct %s *_self;\n", dsrna->dnaname);
else fprintf(f, "\tstruct %s *_self;\n", srna->identifier);
}
dparm= dfunc->cont.properties.first;
for(; dparm; dparm= dparm->next) {
type = dparm->prop->type;
flag = dparm->prop->flag;
pout = (flag & PROP_OUTPUT);
cptr = ((type == PROP_POINTER) && !(flag & PROP_RNAPTR));
if(dparm->prop==func->c_ret)
ptrstr= cptr || dparm->prop->arraydimension ? "*" : "";
/* XXX only arrays and strings are allowed to be dynamic, is this checked anywhere? */
else if (cptr || (flag & PROP_DYNAMIC))
ptrstr= pout ? "**" : "*";
/* fixed size arrays and RNA pointers are pre-allocated on the ParameterList stack, pass a pointer to it */
else if (type == PROP_POINTER || dparm->prop->arraydimension)
ptrstr= "*";
/* PROP_THICK_WRAP strings are pre-allocated on the ParameterList stack, but type name for string props is already char*, so leave empty */
else if (type == PROP_STRING && (flag & PROP_THICK_WRAP))
ptrstr= "";
else
ptrstr= pout ? "*" : "";
/* for dynamic parameters we pass an additional int for the length of the parameter */
if (flag & PROP_DYNAMIC)
fprintf(f, "\tint %s%s_len;\n", pout ? "*" : "", dparm->prop->identifier);
fprintf(f, "\t%s%s %s%s;\n", rna_type_struct(dparm->prop), rna_parameter_type_name(dparm->prop), ptrstr, dparm->prop->identifier);
}
if(has_data) {
fprintf(f, "\tchar *_data");
if(func->c_ret) fprintf(f, ", *_retdata");
fprintf(f, ";\n");
fprintf(f, "\t\n");
}
/* assign self */
if(func->flag & FUNC_USE_SELF_ID) {
fprintf(f, "\t_selfid= (struct ID*)_ptr->id.data;\n");
}
if((func->flag & FUNC_NO_SELF)==0) {
if(dsrna->dnaname) fprintf(f, "\t_self= (struct %s *)_ptr->data;\n", dsrna->dnaname);
else fprintf(f, "\t_self= (struct %s *)_ptr->data;\n", srna->identifier);
}
if(has_data) {
fprintf(f, "\t_data= (char *)_parms->data;\n");
}
dparm= dfunc->cont.properties.first;
for(; dparm; dparm= dparm->next) {
type = dparm->prop->type;
flag = dparm->prop->flag;
pout = (flag & PROP_OUTPUT);
cptr = ((type == PROP_POINTER) && !(flag & PROP_RNAPTR));
if(dparm->prop==func->c_ret)
fprintf(f, "\t_retdata= _data;\n");
else {
const char *data_str;
if (cptr || (flag & PROP_DYNAMIC)) {
ptrstr= "**";
valstr= "*";
}
else if (type == PROP_POINTER || dparm->prop->arraydimension) {
ptrstr= "*";
valstr= "";
}
else if (type == PROP_STRING && (flag & PROP_THICK_WRAP)) {
ptrstr= "";
valstr= "";
}
else {
ptrstr= "*";
valstr= "*";
}
/* this must be kept in sync with RNA_parameter_length_get_data, we could just call the function directly, but this is faster */
if (flag & PROP_DYNAMIC) {
fprintf(f, "\t%s_len= %s((int *)_data);\n", dparm->prop->identifier, pout ? "" : "*");
data_str= "(&(((char *)_data)[sizeof(void *)]))";
}
else {
data_str= "_data";
}
fprintf(f, "\t%s= ", dparm->prop->identifier);
if (!pout)
fprintf(f, "%s", valstr);
fprintf(f, "((%s%s%s)%s);\n", rna_type_struct(dparm->prop), rna_parameter_type_name(dparm->prop), ptrstr, data_str);
}
if(dparm->next)
fprintf(f, "\t_data+= %d;\n", rna_parameter_size_alloc(dparm->prop));
}
if(dfunc->call) {
fprintf(f, "\t\n");
fprintf(f, "\t");
if(func->c_ret) fprintf(f, "%s= ", func->c_ret->identifier);
fprintf(f, "%s(", dfunc->call);
first= 1;
if(func->flag & FUNC_USE_SELF_ID) {
fprintf(f, "_selfid");
first= 0;
}
if((func->flag & FUNC_NO_SELF)==0) {
if(!first) fprintf(f, ", ");
fprintf(f, "_self");
first= 0;
}
if(func->flag & FUNC_USE_CONTEXT) {
if(!first) fprintf(f, ", ");
first= 0;
fprintf(f, "C");
}
if(func->flag & FUNC_USE_REPORTS) {
if(!first) fprintf(f, ", ");
first= 0;
fprintf(f, "reports");
}
dparm= dfunc->cont.properties.first;
for(; dparm; dparm= dparm->next) {
if(dparm->prop==func->c_ret)
continue;
if(!first) fprintf(f, ", ");
first= 0;
if (dparm->prop->flag & PROP_DYNAMIC)
fprintf(f, "%s_len, %s", dparm->prop->identifier, dparm->prop->identifier);
else
fprintf(f, "%s", dparm->prop->identifier);
}
fprintf(f, ");\n");
if(func->c_ret) {
dparm= rna_find_parameter_def(func->c_ret);
ptrstr= (((dparm->prop->type == PROP_POINTER) && !(dparm->prop->flag & PROP_RNAPTR)) || (dparm->prop->arraydimension))? "*": "";
fprintf(f, "\t*((%s%s%s*)_retdata)= %s;\n", rna_type_struct(dparm->prop), rna_parameter_type_name(dparm->prop), ptrstr, func->c_ret->identifier);
}
}
fprintf(f, "}\n\n");
dfunc->gencall= funcname;
}
static void rna_auto_types(void)
{
StructDefRNA *ds;
PropertyDefRNA *dp;
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next) {
/* DNA name for Screen is patched in 2.5, we do the reverse here .. */
if(ds->dnaname && strcmp(ds->dnaname, "Screen") == 0)
ds->dnaname= "bScreen";
for(dp=ds->cont.properties.first; dp; dp=dp->next) {
if(dp->dnastructname && strcmp(dp->dnastructname, "Screen") == 0)
dp->dnastructname= "bScreen";
if(dp->dnatype) {
if(dp->prop->type == PROP_POINTER) {
PointerPropertyRNA *pprop= (PointerPropertyRNA*)dp->prop;
StructRNA *type;
if(!pprop->type && !pprop->get)
pprop->type= (StructRNA*)rna_find_type(dp->dnatype);
if(pprop->type) {
type= rna_find_struct((char*)pprop->type);
if(type && (type->flag & STRUCT_ID_REFCOUNT))
pprop->property.flag |= PROP_ID_REFCOUNT;
}
}
else if(dp->prop->type== PROP_COLLECTION) {
CollectionPropertyRNA *cprop= (CollectionPropertyRNA*)dp->prop;
if(!cprop->item_type && !cprop->get && strcmp(dp->dnatype, "ListBase")==0)
cprop->item_type= (StructRNA*)rna_find_type(dp->dnatype);
}
}
}
}
}
static void rna_sort(BlenderRNA *brna)
{
StructDefRNA *ds;
StructRNA *srna;
rna_sortlist(&brna->structs, cmp_struct);
rna_sortlist(&DefRNA.structs, cmp_def_struct);
for(srna=brna->structs.first; srna; srna=srna->cont.next)
rna_sortlist(&srna->cont.properties, cmp_property);
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
rna_sortlist(&ds->cont.properties, cmp_def_property);
}
static const char *rna_property_structname(PropertyType type)
{
switch(type) {
case PROP_BOOLEAN: return "BooleanPropertyRNA";
case PROP_INT: return "IntPropertyRNA";
case PROP_FLOAT: return "FloatPropertyRNA";
case PROP_STRING: return "StringPropertyRNA";
case PROP_ENUM: return "EnumPropertyRNA";
case PROP_POINTER: return "PointerPropertyRNA";
case PROP_COLLECTION: return "CollectionPropertyRNA";
default: return "UnknownPropertyRNA";
}
}
static const char *rna_property_subtypename(PropertySubType type)
{
switch(type) {
case PROP_NONE: return "PROP_NONE";
case PROP_FILEPATH: return "PROP_FILEPATH";
case PROP_FILENAME: return "PROP_FILENAME";
case PROP_DIRPATH: return "PROP_DIRPATH";
case PROP_UNSIGNED: return "PROP_UNSIGNED";
case PROP_PERCENTAGE: return "PROP_PERCENTAGE";
case PROP_FACTOR: return "PROP_FACTOR";
case PROP_ANGLE: return "PROP_ANGLE";
case PROP_TIME: return "PROP_TIME";
case PROP_DISTANCE: return "PROP_DISTANCE";
case PROP_COLOR: return "PROP_COLOR";
case PROP_TRANSLATION: return "PROP_TRANSLATION";
case PROP_DIRECTION: return "PROP_DIRECTION";
case PROP_MATRIX: return "PROP_MATRIX";
case PROP_EULER: return "PROP_EULER";
case PROP_QUATERNION: return "PROP_QUATERNION";
case PROP_AXISANGLE: return "PROP_AXISANGLE";
case PROP_VELOCITY: return "PROP_VELOCITY";
case PROP_ACCELERATION: return "PROP_ACCELERATION";
case PROP_XYZ: return "PROP_XYZ";
case PROP_COLOR_GAMMA: return "PROP_COLOR_GAMMA";
case PROP_LAYER: return "PROP_LAYER";
case PROP_LAYER_MEMBER: return "PROP_LAYER_MEMBER";
default: {
/* incase we dont have a type preset that includes the subtype */
if(RNA_SUBTYPE_UNIT(type)) {
return rna_property_subtypename(type & ~RNA_SUBTYPE_UNIT(type));
}
else {
return "PROP_SUBTYPE_UNKNOWN";
}
}
}
}
static const char *rna_property_subtype_unit(PropertyType type)
{
switch(RNA_SUBTYPE_UNIT(type)) {
case PROP_UNIT_NONE: return "PROP_UNIT_NONE";
case PROP_UNIT_LENGTH: return "PROP_UNIT_LENGTH";
case PROP_UNIT_AREA: return "PROP_UNIT_AREA";
case PROP_UNIT_VOLUME: return "PROP_UNIT_VOLUME";
case PROP_UNIT_MASS: return "PROP_UNIT_MASS";
case PROP_UNIT_ROTATION: return "PROP_UNIT_ROTATION";
case PROP_UNIT_TIME: return "PROP_UNIT_TIME";
case PROP_UNIT_VELOCITY: return "PROP_UNIT_VELOCITY";
case PROP_UNIT_ACCELERATION:return "PROP_UNIT_ACCELERATION";
default: return "PROP_UNIT_UNKNOWN";
}
}
static void rna_generate_prototypes(BlenderRNA *brna, FILE *f)
{
StructRNA *srna;
for(srna=brna->structs.first; srna; srna=srna->cont.next)
fprintf(f, "extern StructRNA RNA_%s;\n", srna->identifier);
fprintf(f, "\n");
}
static void rna_generate_blender(BlenderRNA *brna, FILE *f)
{
StructRNA *srna;
fprintf(f, "BlenderRNA BLENDER_RNA = {");
srna= brna->structs.first;
if(srna) fprintf(f, "{&RNA_%s, ", srna->identifier);
else fprintf(f, "{NULL, ");
srna= brna->structs.last;
if(srna) fprintf(f, "&RNA_%s}", srna->identifier);
else fprintf(f, "NULL}");
fprintf(f, "};\n\n");
}
static void rna_generate_property_prototypes(BlenderRNA *brna, StructRNA *srna, FILE *f)
{
PropertyRNA *prop;
StructRNA *base;
base= srna->base;
while (base) {
fprintf(f, "\n");
for(prop=base->cont.properties.first; prop; prop=prop->next)
fprintf(f, "%s%s rna_%s_%s;\n", "extern ", rna_property_structname(prop->type), base->identifier, prop->identifier);
base= base->base;
}
if(srna->cont.properties.first)
fprintf(f, "\n");
for(prop=srna->cont.properties.first; prop; prop=prop->next)
fprintf(f, "%s%s rna_%s_%s;\n", (prop->flag & PROP_EXPORT)? "": "", rna_property_structname(prop->type), srna->identifier, prop->identifier);
fprintf(f, "\n");
}
static void rna_generate_parameter_prototypes(BlenderRNA *brna, StructRNA *srna, FunctionRNA *func, FILE *f)
{
PropertyRNA *parm;
for(parm= func->cont.properties.first; parm; parm= parm->next)
fprintf(f, "%s%s rna_%s_%s_%s;\n", "extern ", rna_property_structname(parm->type), srna->identifier, func->identifier, parm->identifier);
if(func->cont.properties.first)
fprintf(f, "\n");
}
static void rna_generate_function_prototypes(BlenderRNA *brna, StructRNA *srna, FILE *f)
{
FunctionRNA *func;
StructRNA *base;
base= srna->base;
while (base) {
for(func= base->functions.first; func; func= func->cont.next) {
fprintf(f, "%s%s rna_%s_%s_func;\n", "extern ", "FunctionRNA", base->identifier, func->identifier);
rna_generate_parameter_prototypes(brna, base, func, f);
}
if(base->functions.first)
fprintf(f, "\n");
base= base->base;
}
for(func= srna->functions.first; func; func= func->cont.next) {
fprintf(f, "%s%s rna_%s_%s_func;\n", "extern ", "FunctionRNA", srna->identifier, func->identifier);
rna_generate_parameter_prototypes(brna, srna, func, f);
}
if(srna->functions.first)
fprintf(f, "\n");
}
static void rna_generate_static_parameter_prototypes(BlenderRNA *brna, StructRNA *srna, FunctionDefRNA *dfunc, FILE *f)
{
FunctionRNA *func;
PropertyDefRNA *dparm;
StructDefRNA *dsrna;
PropertyType type;
int flag, pout, cptr, first;
const char *ptrstr;
dsrna= rna_find_struct_def(srna);
func= dfunc->func;
/* return type */
for(dparm= dfunc->cont.properties.first; dparm; dparm= dparm->next) {
if(dparm->prop==func->c_ret) {
if(dparm->prop->arraydimension)
fprintf(f, "XXX no array return types yet"); /* XXX not supported */
else if(dparm->prop->type == PROP_POINTER && !(dparm->prop->flag & PROP_RNAPTR))
fprintf(f, "%s%s *", rna_type_struct(dparm->prop), rna_parameter_type_name(dparm->prop));
else
fprintf(f, "%s%s ", rna_type_struct(dparm->prop), rna_parameter_type_name(dparm->prop));
break;
}
}
/* void if nothing to return */
if(!dparm)
fprintf(f, "void ");
/* function name */
fprintf(f, "%s(", dfunc->call);
first= 1;
/* self, context and reports parameters */
if(func->flag & FUNC_USE_SELF_ID) {
fprintf(f, "struct ID *_selfid");
first= 0;
}
if((func->flag & FUNC_NO_SELF)==0) {
if(!first) fprintf(f, ", ");
if(dsrna->dnaname) fprintf(f, "struct %s *_self", dsrna->dnaname);
else fprintf(f, "struct %s *_self", srna->identifier);
first= 0;
}
if(func->flag & FUNC_USE_CONTEXT) {
if(!first) fprintf(f, ", ");
first= 0;
fprintf(f, "bContext *C");
}
if(func->flag & FUNC_USE_REPORTS) {
if(!first) fprintf(f, ", ");
first= 0;
fprintf(f, "ReportList *reports");
}
/* defined parameters */
for(dparm= dfunc->cont.properties.first; dparm; dparm= dparm->next) {
type = dparm->prop->type;
flag = dparm->prop->flag;
pout = (flag & PROP_OUTPUT);
cptr = ((type == PROP_POINTER) && !(flag & PROP_RNAPTR));
if(dparm->prop==func->c_ret)
continue;
if (cptr || (flag & PROP_DYNAMIC))
ptrstr= pout ? "**" : "*";
else if (type == PROP_POINTER || dparm->prop->arraydimension)
ptrstr= "*";
else if (type == PROP_STRING && (flag & PROP_THICK_WRAP))
ptrstr= "";
else
ptrstr= pout ? "*" : "";
if(!first) fprintf(f, ", ");
first= 0;
if (flag & PROP_DYNAMIC)
fprintf(f, "int %s%s_len, ", pout ? "*" : "", dparm->prop->identifier);
if(!(flag & PROP_DYNAMIC) && dparm->prop->arraydimension)
fprintf(f, "%s%s %s[%d]", rna_type_struct(dparm->prop), rna_parameter_type_name(dparm->prop), dparm->prop->identifier, dparm->prop->totarraylength);
else
fprintf(f, "%s%s %s%s", rna_type_struct(dparm->prop), rna_parameter_type_name(dparm->prop), ptrstr, dparm->prop->identifier);
}
fprintf(f, ");\n");
}
static void rna_generate_static_function_prototypes(BlenderRNA *brna, StructRNA *srna, FILE *f)
{
FunctionRNA *func;
FunctionDefRNA *dfunc;
int first= 1;
for(func= srna->functions.first; func; func= func->cont.next) {
dfunc= rna_find_function_def(func);
if(dfunc->call) {
if(first) {
fprintf(f, "/* Repeated prototypes to detect errors */\n\n");
first= 0;
}
rna_generate_static_parameter_prototypes(brna, srna, dfunc, f);
}
}
fprintf(f, "\n");
}
static void rna_generate_property(FILE *f, StructRNA *srna, const char *nest, PropertyRNA *prop)
{
char *strnest= "", *errnest= "";
int len, freenest= 0;
if(nest != NULL) {
len= strlen(nest);
strnest= MEM_mallocN(sizeof(char)*(len+2), "rna_generate_property -> strnest");
errnest= MEM_mallocN(sizeof(char)*(len+2), "rna_generate_property -> errnest");
strcpy(strnest, "_"); strcat(strnest, nest);
strcpy(errnest, "."); strcat(errnest, nest);
freenest= 1;
}
switch(prop->type) {
case PROP_ENUM: {
EnumPropertyRNA *eprop= (EnumPropertyRNA*)prop;
int i, defaultfound= 0, totflag= 0;
if(eprop->item) {
fprintf(f, "static EnumPropertyItem rna_%s%s_%s_items[%d] = {\n\t", srna->identifier, strnest, prop->identifier, eprop->totitem+1);
for(i=0; i<eprop->totitem; i++) {
fprintf(f, "{%d, ", eprop->item[i].value);
rna_print_c_string(f, eprop->item[i].identifier); fprintf(f, ", ");
fprintf(f, "%d, ", eprop->item[i].icon);
rna_print_c_string(f, eprop->item[i].name); fprintf(f, ", ");
rna_print_c_string(f, eprop->item[i].description); fprintf(f, "},\n\t");
if(eprop->item[i].identifier[0]) {
if(prop->flag & PROP_ENUM_FLAG) {
totflag |= eprop->item[i].value;
}
else {
if(eprop->defaultvalue == eprop->item[i].value) {
defaultfound= 1;
}
}
}
}
fprintf(f, "{0, NULL, 0, NULL, NULL}\n};\n\n");
if(prop->flag & PROP_ENUM_FLAG) {
if(eprop->defaultvalue & ~totflag) {
fprintf(stderr, "rna_generate_structs: %s%s.%s, enum default includes unused bits (%d).\n", srna->identifier, errnest, prop->identifier, eprop->defaultvalue & ~totflag);
DefRNA.error= 1;
}
}
else {
if(!defaultfound) {
fprintf(stderr, "rna_generate_structs: %s%s.%s, enum default is not in items.\n", srna->identifier, errnest, prop->identifier);
DefRNA.error= 1;
}
}
}
else {
fprintf(stderr, "rna_generate_structs: %s%s.%s, enum must have items defined.\n", srna->identifier, errnest, prop->identifier);
DefRNA.error= 1;
}
break;
}
case PROP_BOOLEAN: {
BooleanPropertyRNA *bprop= (BooleanPropertyRNA*)prop;
unsigned int i;
if(prop->arraydimension && prop->totarraylength) {
fprintf(f, "static int rna_%s%s_%s_default[%d] = {\n\t", srna->identifier, strnest, prop->identifier, prop->totarraylength);
for(i=0; i<prop->totarraylength; i++) {
if(bprop->defaultarray)
fprintf(f, "%d", bprop->defaultarray[i]);
else
fprintf(f, "%d", bprop->defaultvalue);
if(i != prop->totarraylength-1)
fprintf(f, ",\n\t");
}
fprintf(f, "\n};\n\n");
}
break;
}
case PROP_INT: {
IntPropertyRNA *iprop= (IntPropertyRNA*)prop;
unsigned int i;
if(prop->arraydimension && prop->totarraylength) {
fprintf(f, "static int rna_%s%s_%s_default[%d] = {\n\t", srna->identifier, strnest, prop->identifier, prop->totarraylength);
for(i=0; i<prop->totarraylength; i++) {
if(iprop->defaultarray)
fprintf(f, "%d", iprop->defaultarray[i]);
else
fprintf(f, "%d", iprop->defaultvalue);
if(i != prop->totarraylength-1)
fprintf(f, ",\n\t");
}
fprintf(f, "\n};\n\n");
}
break;
}
case PROP_FLOAT: {
FloatPropertyRNA *fprop= (FloatPropertyRNA*)prop;
unsigned int i;
if(prop->arraydimension && prop->totarraylength) {
fprintf(f, "static float rna_%s%s_%s_default[%d] = {\n\t", srna->identifier, strnest, prop->identifier, prop->totarraylength);
for(i=0; i<prop->totarraylength; i++) {
if(fprop->defaultarray)
rna_float_print(f, fprop->defaultarray[i]);
else
rna_float_print(f, fprop->defaultvalue);
if(i != prop->totarraylength-1)
fprintf(f, ",\n\t");
}
fprintf(f, "\n};\n\n");
}
break;
}
default:
break;
}
fprintf(f, "%s%s rna_%s%s_%s = {\n", (prop->flag & PROP_EXPORT)? "": "", rna_property_structname(prop->type), srna->identifier, strnest, prop->identifier);
if(prop->next) fprintf(f, "\t{(PropertyRNA*)&rna_%s%s_%s, ", srna->identifier, strnest, prop->next->identifier);
else fprintf(f, "\t{NULL, ");
if(prop->prev) fprintf(f, "(PropertyRNA*)&rna_%s%s_%s,\n", srna->identifier, strnest, prop->prev->identifier);
else fprintf(f, "NULL,\n");
fprintf(f, "\t%d, ", prop->magic);
rna_print_c_string(f, prop->identifier);
fprintf(f, ", %d, ", prop->flag);
rna_print_c_string(f, prop->name); fprintf(f, ",\n\t");
rna_print_c_string(f, prop->description); fprintf(f, ",\n\t");
fprintf(f, "%d,\n", prop->icon);
fprintf(f, "\t%s, %s|%s, %s, %d, {%d, %d, %d}, %d,\n", RNA_property_typename(prop->type), rna_property_subtypename(prop->subtype), rna_property_subtype_unit(prop->subtype), rna_function_string(prop->getlength), prop->arraydimension, prop->arraylength[0], prop->arraylength[1], prop->arraylength[2], prop->totarraylength);
fprintf(f, "\t%s%s, %d, %s, %s,\n", (prop->flag & PROP_CONTEXT_UPDATE)? "(UpdateFunc)": "", rna_function_string(prop->update), prop->noteflag, rna_function_string(prop->editable), rna_function_string(prop->itemeditable));
if(prop->flag & PROP_RAW_ACCESS) rna_set_raw_offset(f, srna, prop);
else fprintf(f, "\t0, -1");
/* our own type - collections/arrays only */
if(prop->srna) fprintf(f, ", &RNA_%s", (char*)prop->srna);
else fprintf(f, ", NULL");
fprintf(f, "},\n");
switch(prop->type) {
case PROP_BOOLEAN: {
BooleanPropertyRNA *bprop= (BooleanPropertyRNA*)prop;
fprintf(f, "\t%s, %s, %s, %s, %d, ", rna_function_string(bprop->get), rna_function_string(bprop->set), rna_function_string(bprop->getarray), rna_function_string(bprop->setarray), bprop->defaultvalue);
if(prop->arraydimension && prop->totarraylength) fprintf(f, "rna_%s%s_%s_default\n", srna->identifier, strnest, prop->identifier);
else fprintf(f, "NULL\n");
break;
}
case PROP_INT: {
IntPropertyRNA *iprop= (IntPropertyRNA*)prop;
fprintf(f, "\t%s, %s, %s, %s, %s,\n\t", rna_function_string(iprop->get), rna_function_string(iprop->set), rna_function_string(iprop->getarray), rna_function_string(iprop->setarray), rna_function_string(iprop->range));
rna_int_print(f, iprop->softmin); fprintf(f, ", ");
rna_int_print(f, iprop->softmax); fprintf(f, ", ");
rna_int_print(f, iprop->hardmin); fprintf(f, ", ");
rna_int_print(f, iprop->hardmax); fprintf(f, ", ");
rna_int_print(f, iprop->step); fprintf(f, ", ");
rna_int_print(f, iprop->defaultvalue); fprintf(f, ", ");
if(prop->arraydimension && prop->totarraylength) fprintf(f, "rna_%s%s_%s_default\n", srna->identifier, strnest, prop->identifier);
else fprintf(f, "NULL\n");
break;
}
case PROP_FLOAT: {
FloatPropertyRNA *fprop= (FloatPropertyRNA*)prop;
fprintf(f, "\t%s, %s, %s, %s, %s, ", rna_function_string(fprop->get), rna_function_string(fprop->set), rna_function_string(fprop->getarray), rna_function_string(fprop->setarray), rna_function_string(fprop->range));
rna_float_print(f, fprop->softmin); fprintf(f, ", ");
rna_float_print(f, fprop->softmax); fprintf(f, ", ");
rna_float_print(f, fprop->hardmin); fprintf(f, ", ");
rna_float_print(f, fprop->hardmax); fprintf(f, ", ");
rna_float_print(f, fprop->step); fprintf(f, ", ");
rna_int_print(f, (int)fprop->precision); fprintf(f, ", ");
rna_float_print(f, fprop->defaultvalue); fprintf(f, ", ");
if(prop->arraydimension && prop->totarraylength) fprintf(f, "rna_%s%s_%s_default\n", srna->identifier, strnest, prop->identifier);
else fprintf(f, "NULL\n");
break;
}
case PROP_STRING: {
StringPropertyRNA *sprop= (StringPropertyRNA*)prop;
fprintf(f, "\t%s, %s, %s, %d, ", rna_function_string(sprop->get), rna_function_string(sprop->length), rna_function_string(sprop->set), sprop->maxlength);
rna_print_c_string(f, sprop->defaultvalue); fprintf(f, "\n");
break;
}
case PROP_ENUM: {
EnumPropertyRNA *eprop= (EnumPropertyRNA*)prop;
fprintf(f, "\t%s, %s, %s, ", rna_function_string(eprop->get), rna_function_string(eprop->set), rna_function_string(eprop->itemf));
if(eprop->item)
fprintf(f, "rna_%s%s_%s_items, ", srna->identifier, strnest, prop->identifier);
else
fprintf(f, "NULL, ");
fprintf(f, "%d, %d\n", eprop->totitem, eprop->defaultvalue);
break;
}
case PROP_POINTER: {
PointerPropertyRNA *pprop= (PointerPropertyRNA*)prop;
fprintf(f, "\t%s, %s, %s, %s,", rna_function_string(pprop->get), rna_function_string(pprop->set), rna_function_string(pprop->typef), rna_function_string(pprop->poll));
if(pprop->type) fprintf(f, "&RNA_%s\n", (char*)pprop->type);
else fprintf(f, "NULL\n");
break;
}
case PROP_COLLECTION: {
CollectionPropertyRNA *cprop= (CollectionPropertyRNA*)prop;
fprintf(f, "\t%s, %s, %s, %s, %s, %s, %s, ", rna_function_string(cprop->begin), rna_function_string(cprop->next), rna_function_string(cprop->end), rna_function_string(cprop->get), rna_function_string(cprop->length), rna_function_string(cprop->lookupint), rna_function_string(cprop->lookupstring));
if(cprop->item_type) fprintf(f, "&RNA_%s\n", (char*)cprop->item_type);
else fprintf(f, "NULL\n");
break;
}
}
fprintf(f, "};\n\n");
if(freenest) {
MEM_freeN(strnest);
MEM_freeN(errnest);
}
}
static void rna_generate_struct(BlenderRNA *brna, StructRNA *srna, FILE *f)
{
FunctionRNA *func;
FunctionDefRNA *dfunc;
PropertyRNA *prop, *parm;
StructRNA *base;
fprintf(f, "/* %s */\n", srna->name);
for(prop= srna->cont.properties.first; prop; prop= prop->next)
rna_generate_property(f, srna, NULL, prop);
for(func= srna->functions.first; func; func= func->cont.next) {
for(parm= func->cont.properties.first; parm; parm= parm->next)
rna_generate_property(f, srna, func->identifier, parm);
fprintf(f, "%s%s rna_%s_%s_func = {\n", "", "FunctionRNA", srna->identifier, func->identifier);
if(func->cont.next) fprintf(f, "\t{(FunctionRNA*)&rna_%s_%s_func, ", srna->identifier, ((FunctionRNA*)func->cont.next)->identifier);
else fprintf(f, "\t{NULL, ");
if(func->cont.prev) fprintf(f, "(FunctionRNA*)&rna_%s_%s_func,\n", srna->identifier, ((FunctionRNA*)func->cont.prev)->identifier);
else fprintf(f, "NULL,\n");
fprintf(f, "\tNULL,\n");
parm= func->cont.properties.first;
if(parm) fprintf(f, "\t{(PropertyRNA*)&rna_%s_%s_%s, ", srna->identifier, func->identifier, parm->identifier);
else fprintf(f, "\t{NULL, ");
parm= func->cont.properties.last;
if(parm) fprintf(f, "(PropertyRNA*)&rna_%s_%s_%s}},\n", srna->identifier, func->identifier, parm->identifier);
else fprintf(f, "NULL}},\n");
fprintf(f, "\t");
rna_print_c_string(f, func->identifier);
fprintf(f, ", %d, ", func->flag);
rna_print_c_string(f, func->description); fprintf(f, ",\n");
dfunc= rna_find_function_def(func);
if(dfunc->gencall) fprintf(f, "\t%s,\n", dfunc->gencall);
else fprintf(f, "\tNULL,\n");
if(func->c_ret) fprintf(f, "\t(PropertyRNA*)&rna_%s_%s_%s\n", srna->identifier, func->identifier, func->c_ret->identifier);
else fprintf(f, "\tNULL\n");
fprintf(f, "};\n");
fprintf(f, "\n");
}
fprintf(f, "StructRNA RNA_%s = {\n", srna->identifier);
if(srna->cont.next) fprintf(f, "\t{(ContainerRNA *)&RNA_%s, ", ((StructRNA*)srna->cont.next)->identifier);
else fprintf(f, "\t{NULL, ");
if(srna->cont.prev) fprintf(f, "(ContainerRNA *)&RNA_%s,\n", ((StructRNA*)srna->cont.prev)->identifier);
else fprintf(f, "NULL,\n");
fprintf(f, "\tNULL,\n");
prop= srna->cont.properties.first;
if(prop) fprintf(f, "\t{(PropertyRNA*)&rna_%s_%s, ", srna->identifier, prop->identifier);
else fprintf(f, "\t{NULL, ");
prop= srna->cont.properties.last;
if(prop) fprintf(f, "(PropertyRNA*)&rna_%s_%s}},\n", srna->identifier, prop->identifier);
else fprintf(f, "NULL}},\n");
fprintf(f, "\t");
rna_print_c_string(f, srna->identifier);
fprintf(f, "\t, NULL,NULL\n"); /* PyType - Cant initialize here */
fprintf(f, ", %d, ", srna->flag);
rna_print_c_string(f, srna->name);
fprintf(f, ", ");
rna_print_c_string(f, srna->description);
fprintf(f, ",\n\t%d,\n", srna->icon);
prop= srna->nameproperty;
if(prop) {
base= srna;
while (base->base && base->base->nameproperty==prop)
base= base->base;
fprintf(f, "\t(PropertyRNA*)&rna_%s_%s, ", base->identifier, prop->identifier);
}
else fprintf(f, "\tNULL, ");
prop= srna->iteratorproperty;
base= srna;
while (base->base && base->base->iteratorproperty==prop)
base= base->base;
fprintf(f, "(PropertyRNA*)&rna_%s_rna_properties,\n", base->identifier);
if(srna->base) fprintf(f, "\t&RNA_%s,\n", srna->base->identifier);
else fprintf(f, "\tNULL,\n");
if(srna->nested) fprintf(f, "\t&RNA_%s,\n", srna->nested->identifier);
else fprintf(f, "\tNULL,\n");
fprintf(f, "\t%s,\n", rna_function_string(srna->refine));
fprintf(f, "\t%s,\n", rna_function_string(srna->path));
fprintf(f, "\t%s,\n", rna_function_string(srna->reg));
fprintf(f, "\t%s,\n", rna_function_string(srna->unreg));
fprintf(f, "\t%s,\n", rna_function_string(srna->idproperties));
if(srna->reg && !srna->refine) {
fprintf(stderr, "rna_generate_struct: %s has a register function, must also have refine function.\n", srna->identifier);
DefRNA.error= 1;
}
func= srna->functions.first;
if(func) fprintf(f, "\t{(FunctionRNA*)&rna_%s_%s_func, ", srna->identifier, func->identifier);
else fprintf(f, "\t{NULL, ");
func= srna->functions.last;
if(func) fprintf(f, "(FunctionRNA*)&rna_%s_%s_func}\n", srna->identifier, func->identifier);
else fprintf(f, "NULL}\n");
fprintf(f, "};\n");
fprintf(f, "\n");
}
typedef struct RNAProcessItem {
const char *filename;
const char *api_filename;
void (*define)(BlenderRNA *brna);
} RNAProcessItem;
static RNAProcessItem PROCESS_ITEMS[]= {
{"rna_rna.c", NULL, RNA_def_rna},
{"rna_ID.c", NULL, RNA_def_ID},
{"rna_texture.c", NULL, RNA_def_texture},
{"rna_action.c", "rna_action_api.c", RNA_def_action},
{"rna_animation.c", "rna_animation_api.c", RNA_def_animation},
{"rna_animviz.c", NULL, RNA_def_animviz},
{"rna_actuator.c", "rna_actuator_api.c", RNA_def_actuator},
{"rna_armature.c", "rna_armature_api.c", RNA_def_armature},
{"rna_boid.c", NULL, RNA_def_boid},
{"rna_brush.c", NULL, RNA_def_brush},
{"rna_camera.c", NULL, RNA_def_camera},
{"rna_cloth.c", NULL, RNA_def_cloth},
{"rna_color.c", NULL, RNA_def_color},
{"rna_constraint.c", NULL, RNA_def_constraint},
{"rna_context.c", NULL, RNA_def_context},
{"rna_controller.c", "rna_controller_api.c", RNA_def_controller},
{"rna_curve.c", NULL, RNA_def_curve},
{"rna_fcurve.c", "rna_fcurve_api.c", RNA_def_fcurve},
{"rna_fluidsim.c", NULL, RNA_def_fluidsim},
{"rna_gpencil.c", NULL, RNA_def_gpencil},
{"rna_group.c", NULL, RNA_def_group},
{"rna_image.c", "rna_image_api.c", RNA_def_image},
{"rna_key.c", NULL, RNA_def_key},
{"rna_lamp.c", NULL, RNA_def_lamp},
{"rna_lattice.c", NULL, RNA_def_lattice},
{"rna_main.c", "rna_main_api.c", RNA_def_main},
{"rna_material.c", "rna_material_api.c", RNA_def_material},
{"rna_mesh.c", "rna_mesh_api.c", RNA_def_mesh},
{"rna_meta.c", NULL, RNA_def_meta},
{"rna_modifier.c", NULL, RNA_def_modifier},
{"rna_nla.c", NULL, RNA_def_nla},
{"rna_nodetree.c", NULL, RNA_def_nodetree},
{"rna_object.c", "rna_object_api.c", RNA_def_object},
{"rna_object_force.c", NULL, RNA_def_object_force},
{"rna_packedfile.c", NULL, RNA_def_packedfile},
{"rna_particle.c", NULL, RNA_def_particle},
{"rna_pose.c", "rna_pose_api.c", RNA_def_pose},
{"rna_property.c", NULL, RNA_def_gameproperty},
{"rna_render.c", NULL, RNA_def_render},
{"rna_scene.c", "rna_scene_api.c", RNA_def_scene},
{"rna_screen.c", NULL, RNA_def_screen},
{"rna_sculpt_paint.c", NULL, RNA_def_sculpt_paint},
{"rna_sensor.c", "rna_sensor_api.c", RNA_def_sensor},
{"rna_sequencer.c", "rna_sequencer_api.c", RNA_def_sequencer},
{"rna_smoke.c", NULL, RNA_def_smoke},
{"rna_space.c", NULL, RNA_def_space},
{"rna_test.c", NULL, RNA_def_test},
{"rna_text.c", NULL, RNA_def_text},
{"rna_timeline.c", NULL, RNA_def_timeline_marker},
{"rna_sound.c", NULL, RNA_def_sound},
{"rna_ui.c", "rna_ui_api.c", RNA_def_ui},
{"rna_userdef.c", NULL, RNA_def_userdef},
{"rna_vfont.c", NULL, RNA_def_vfont},
{"rna_wm.c", "rna_wm_api.c", RNA_def_wm},
{"rna_world.c", NULL, RNA_def_world},
{NULL, NULL}};
static void rna_generate(BlenderRNA *brna, FILE *f, const char *filename, const char *api_filename)
{
StructDefRNA *ds;
PropertyDefRNA *dp;
FunctionDefRNA *dfunc;
fprintf(f, "\n/* Automatically generated struct definitions for the Data API.\n"
" Do not edit manually, changes will be overwritten. */\n\n"
"#define RNA_RUNTIME\n\n");
fprintf(f, "#include <float.h>\n");
fprintf(f, "#include <stdio.h>\n");
fprintf(f, "#include <limits.h>\n");
fprintf(f, "#include <string.h>\n\n");
fprintf(f, "#include <stddef.h>\n\n");
fprintf(f, "#include \"DNA_ID.h\"\n");
fprintf(f, "#include \"DNA_scene_types.h\"\n");
fprintf(f, "#include \"BLI_blenlib.h\"\n\n");
fprintf(f, "#include \"BLI_utildefines.h\"\n\n");
fprintf(f, "#include \"BKE_context.h\"\n");
fprintf(f, "#include \"BKE_library.h\"\n");
fprintf(f, "#include \"BKE_main.h\"\n");
fprintf(f, "#include \"BKE_report.h\"\n");
fprintf(f, "#include \"RNA_define.h\"\n");
fprintf(f, "#include \"RNA_types.h\"\n");
fprintf(f, "#include \"rna_internal.h\"\n\n");
rna_generate_prototypes(brna, f);
fprintf(f, "#include \"%s\"\n", filename);
if(api_filename)
fprintf(f, "#include \"%s\"\n", api_filename);
fprintf(f, "\n");
fprintf(f, "/* Autogenerated Functions */\n\n");
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next) {
if(!filename || ds->filename == filename) {
rna_generate_property_prototypes(brna, ds->srna, f);
rna_generate_function_prototypes(brna, ds->srna, f);
}
}
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
if(!filename || ds->filename == filename)
for(dp=ds->cont.properties.first; dp; dp=dp->next)
rna_def_property_funcs(f, ds->srna, dp);
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next) {
if(!filename || ds->filename == filename) {
for(dfunc=ds->functions.first; dfunc; dfunc= dfunc->cont.next)
rna_def_function_funcs(f, ds, dfunc);
rna_generate_static_function_prototypes(brna, ds->srna, f);
}
}
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
if(!filename || ds->filename == filename)
rna_generate_struct(brna, ds->srna, f);
if(strcmp(filename, "rna_ID.c") == 0) {
/* this is ugly, but we cannot have c files compiled for both
* makesrna and blender with some build systems at the moment */
fprintf(f, "#include \"rna_define.c\"\n\n");
rna_generate_blender(brna, f);
}
}
static void rna_generate_header(BlenderRNA *brna, FILE *f)
{
StructDefRNA *ds;
PropertyDefRNA *dp;
StructRNA *srna;
fprintf(f, "\n#ifndef __RNA_BLENDER_H__\n");
fprintf(f, "#define __RNA_BLENDER_H__\n\n");
fprintf(f, "/* Automatically generated function declarations for the Data API.\n"
" Do not edit manually, changes will be overwritten. */\n\n");
fprintf(f, "#include \"RNA_types.h\"\n\n");
fprintf(f, "#ifdef __cplusplus\nextern \"C\" {\n#endif\n\n");
fprintf(f, "#define FOREACH_BEGIN(property, sptr, itemptr) \\\n");
fprintf(f, " { \\\n");
fprintf(f, " CollectionPropertyIterator rna_macro_iter; \\\n");
fprintf(f, " for(property##_begin(&rna_macro_iter, sptr); rna_macro_iter.valid; property##_next(&rna_macro_iter)) { \\\n");
fprintf(f, " itemptr= rna_macro_iter.ptr;\n\n");
fprintf(f, "#define FOREACH_END(property) \\\n");
fprintf(f, " } \\\n");
fprintf(f, " property##_end(&rna_macro_iter); \\\n");
fprintf(f, " }\n\n");
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next) {
srna= ds->srna;
fprintf(f, "/**************** %s ****************/\n\n", srna->name);
while(srna) {
fprintf(f, "extern StructRNA RNA_%s;\n", srna->identifier);
srna= srna->base;
}
fprintf(f, "\n");
for(dp=ds->cont.properties.first; dp; dp=dp->next)
rna_def_property_funcs_header(f, ds->srna, dp);
}
fprintf(f, "#ifdef __cplusplus\n}\n#endif\n\n");
fprintf(f, "#endif /* __RNA_BLENDER_H__ */\n\n");
}
static const char *cpp_classes = ""
"\n"
"#include <string>\n"
"\n"
"namespace RNA {\n"
"\n"
"#define BOOLEAN_PROPERTY(sname, identifier) \\\n"
" bool sname::identifier(void) { return (bool)sname##_##identifier##_get(&ptr); }\n"
"\n"
"#define BOOLEAN_ARRAY_PROPERTY(sname, size, identifier) \\\n"
" Array<int,size> sname::identifier(void) \\\n"
" { Array<int, size> ar; sname##_##identifier##_get(&ptr, ar.data); return ar; }\n"
"\n"
"#define INT_PROPERTY(sname, identifier) \\\n"
" int sname::identifier(void) { return sname##_##identifier##_get(&ptr); }\n"
"\n"
"#define INT_ARRAY_PROPERTY(sname, size, identifier) \\\n"
" Array<int,size> sname::identifier(void) \\\n"
" { Array<int, size> ar; sname##_##identifier##_get(&ptr, ar.data); return ar; }\n"
"\n"
"#define FLOAT_PROPERTY(sname, identifier) \\\n"
" float sname::identifier(void) { return sname##_##identifier##_get(&ptr); }\n"
"\n"
"#define FLOAT_ARRAY_PROPERTY(sname, size, identifier) \\\n"
" Array<float,size> sname::identifier(void) \\\n"
" { Array<float, size> ar; sname##_##identifier##_get(&ptr, ar.data); return ar; }\n"
"\n"
"#define ENUM_PROPERTY(type, sname, identifier) \\\n"
" sname::type sname::identifier(void) { return (type)sname##_##identifier##_get(&ptr); }\n"
"\n"
"#define STRING_PROPERTY(sname, identifier) \\\n"
" std::string sname::identifier(void) { \\\n"
" int len= sname##_##identifier##_length(&ptr); \\\n"
" std::string str; str.resize(len); \\\n"
" sname##_##identifier##_get(&ptr, &str[0]); return str; } \\\n"
"\n"
"#define POINTER_PROPERTY(type, sname, identifier) \\\n"
" type sname::identifier(void) { return type(sname##_##identifier##_get(&ptr)); }\n"
"\n"
"#define COLLECTION_PROPERTY(type, sname, identifier) \\\n"
" typedef CollectionIterator<type, sname##_##identifier##_begin, \\\n"
" sname##_##identifier##_next, sname##_##identifier##_end> identifier##_iterator; \\\n"
" Collection<sname, type, sname##_##identifier##_begin, \\\n"
" sname##_##identifier##_next, sname##_##identifier##_end> identifier;\n"
"\n"
"class Pointer {\n"
"public:\n"
" Pointer(const PointerRNA& p) : ptr(p) { }\n"
" operator const PointerRNA&() { return ptr; }\n"
" bool is_a(StructRNA *type) { return RNA_struct_is_a(&ptr, type); }\n"
" operator void*() { return ptr.data; }\n"
" operator bool() { return ptr.data != NULL; }\n"
"\n"
" PointerRNA ptr;\n"
"};\n"
"\n"
"\n"
"template<typename T, int Tsize>\n"
"class Array {\n"
"public:\n"
" T data[Tsize];\n"
" operator T*() { return data; }\n"
"};\n"
"\n"
"typedef void (*TBeginFunc)(CollectionPropertyIterator *iter, PointerRNA *ptr);\n"
"typedef void (*TNextFunc)(CollectionPropertyIterator *iter);\n"
"typedef void (*TEndFunc)(CollectionPropertyIterator *iter);\n"
"\n"
"template<typename T, TBeginFunc Tbegin, TNextFunc Tnext, TEndFunc Tend>\n"
"class CollectionIterator {\n"
"public:\n"
" CollectionIterator() : t(iter.ptr), init(false) { iter.valid= false; }\n"
" ~CollectionIterator(void) { if(init) Tend(&iter); };\n"
" const CollectionIterator<T, Tbegin, Tnext, Tend>& operator=(const CollectionIterator<T, Tbegin, Tnext, Tend>& copy)\n"
" { if(init) Tend(&iter); iter= copy.iter; if(iter.internal) iter.internal= MEM_dupallocN(iter.internal); t= copy.t; init= copy.init; return *this; }\n"
"\n"
" operator bool(void)\n"
" { return iter.valid != 0; }\n"
" const CollectionIterator<T, Tbegin, Tnext, Tend>& operator++() { Tnext(&iter); t = T(iter.ptr); return *this; }\n"
" T& operator*(void) { return t; }\n"
" T* operator->(void) { return &t; }\n"
" bool operator==(const CollectionIterator<T, Tbegin, Tnext, Tend>& other) { return iter.valid == other.iter.valid; }\n"
" bool operator!=(const CollectionIterator<T, Tbegin, Tnext, Tend>& other) { return iter.valid != other.iter.valid; }\n"
"\n"
" void begin(const Pointer& ptr)\n"
" { if(init) Tend(&iter); Tbegin(&iter, (PointerRNA*)&ptr.ptr); t = T(iter.ptr); init = true; }\n"
"\n"
"private:\n"
" CollectionPropertyIterator iter;\n"
" T t;\n"
" bool init;\n"
"};\n"
"\n"
"template<typename Tp, typename T, TBeginFunc Tbegin, TNextFunc Tnext, TEndFunc Tend>\n"
"class Collection {\n"
"public:\n"
" Collection(const PointerRNA& p) : ptr(p) {}\n"
"\n"
" CollectionIterator<T, Tbegin, Tnext, Tend> begin()\n"
" { CollectionIterator<T, Tbegin, Tnext, Tend> iter; iter.begin(ptr); return iter; }\n"
" CollectionIterator<T, Tbegin, Tnext, Tend> end()\n"
" { return CollectionIterator<T, Tbegin, Tnext, Tend>(); } /* test */ \n"
"\n"
"private:\n"
" PointerRNA ptr;\n"
"};\n"
"\n";
static void rna_generate_header_cpp(BlenderRNA *brna, FILE *f)
{
StructDefRNA *ds;
PropertyDefRNA *dp;
StructRNA *srna;
fprintf(f, "\n#ifndef __RNA_BLENDER_CPP_H__\n");
fprintf(f, "#define __RNA_BLENDER_CPP_H__\n\n");
fprintf(f, "/* Automatically generated classes for the Data API.\n"
" Do not edit manually, changes will be overwritten. */\n\n");
fprintf(f, "#include \"RNA_blender.h\"\n");
fprintf(f, "#include \"RNA_types.h\"\n");
fprintf(f, "%s", cpp_classes);
fprintf(f, "/**************** Declarations ****************/\n\n");
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
fprintf(f, "class %s;\n", ds->srna->identifier);
fprintf(f, "\n");
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next) {
srna= ds->srna;
fprintf(f, "/**************** %s ****************/\n\n", srna->name);
fprintf(f, "class %s : public %s {\n", srna->identifier, (srna->base)? srna->base->identifier: "Pointer");
fprintf(f, "public:\n");
fprintf(f, "\t%s(const PointerRNA& ptr) :\n\t\t%s(ptr)", srna->identifier, (srna->base)? srna->base->identifier: "Pointer");
for(dp=ds->cont.properties.first; dp; dp=dp->next)
if(!(dp->prop->flag & (PROP_IDPROPERTY|PROP_BUILTIN)))
if(dp->prop->type == PROP_COLLECTION)
fprintf(f, ",\n\t\t%s(ptr)", dp->prop->identifier);
fprintf(f, "\n\t\t{}\n\n");
for(dp=ds->cont.properties.first; dp; dp=dp->next)
rna_def_property_funcs_header_cpp(f, ds->srna, dp);
fprintf(f, "};\n\n");
}
fprintf(f, "/**************** Implementation ****************/\n");
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next) {
for(dp=ds->cont.properties.first; dp; dp=dp->next)
rna_def_property_funcs_impl_cpp(f, ds->srna, dp);
fprintf(f, "\n");
}
fprintf(f, "}\n\n#endif /* __RNA_BLENDER_CPP_H__ */\n\n");
}
static void make_bad_file(char *file, int line)
{
FILE *fp= fopen(file, "w");
fprintf(fp, "#error \"Error! can't make correct RNA file from %s:%d, STUPID!\"\n", __FILE__, line);
fclose(fp);
}
static int rna_preprocess(char *outfile)
{
BlenderRNA *brna;
StructDefRNA *ds;
FILE *file;
char deffile[4096];
int i, status;
const char *deps[3]; /* expand as needed */
/* define rna */
brna= RNA_create();
for(i=0; PROCESS_ITEMS[i].filename; i++) {
if(PROCESS_ITEMS[i].define) {
PROCESS_ITEMS[i].define(brna);
for(ds=DefRNA.structs.first; ds; ds=ds->cont.next)
if(!ds->filename)
ds->filename= PROCESS_ITEMS[i].filename;
}
}
rna_auto_types();
/* create RNA_blender_cpp.h */
strcpy(deffile, outfile);
strcat(deffile, "RNA_blender_cpp.h" TMP_EXT);
status= (DefRNA.error != 0);
if(status) {
make_bad_file(deffile, __LINE__);
}
else {
file = fopen(deffile, "w");
if(!file) {
printf ("Unable to open file: %s\n", deffile);
status = 1;
}
else {
rna_generate_header_cpp(brna, file);
fclose(file);
status= (DefRNA.error != 0);
}
}
replace_if_different(deffile, NULL);
rna_sort(brna);
/* create rna_gen_*.c files */
for(i=0; PROCESS_ITEMS[i].filename; i++) {
strcpy(deffile, outfile);
strcat(deffile, PROCESS_ITEMS[i].filename);
deffile[strlen(deffile)-2] = '\0';
strcat(deffile, "_gen.c" TMP_EXT);
if(status) {
make_bad_file(deffile, __LINE__);
}
else {
file = fopen(deffile, "w");
if(!file) {
printf ("Unable to open file: %s\n", deffile);
status = 1;
}
else {
rna_generate(brna, file, PROCESS_ITEMS[i].filename, PROCESS_ITEMS[i].api_filename);
fclose(file);
status= (DefRNA.error != 0);
}
}
/* avoid unneeded rebuilds */
deps[0]= PROCESS_ITEMS[i].filename;
deps[1]= PROCESS_ITEMS[i].api_filename;
deps[2]= NULL;
replace_if_different(deffile, deps);
}
/* create RNA_blender.h */
strcpy(deffile, outfile);
strcat(deffile, "RNA_blender.h" TMP_EXT);
if(status) {
make_bad_file(deffile, __LINE__);
}
else {
file = fopen(deffile, "w");
if(!file) {
printf ("Unable to open file: %s\n", deffile);
status = 1;
}
else {
rna_generate_header(brna, file);
fclose(file);
status= (DefRNA.error != 0);
}
}
replace_if_different(deffile, NULL);
/* free RNA */
RNA_define_free(brna);
RNA_free(brna);
return status;
}
static void mem_error_cb(const char *errorStr)
{
fprintf(stderr, "%s", errorStr);
fflush(stderr);
}
int main(int argc, char **argv)
{
int totblock, return_status = 0;
if(argc<2) {
printf("Usage: %s outdirectory/\n", argv[0]);
return_status = 1;
}
else {
printf("Running makesrna, program versions %s\n", RNA_VERSION_DATE);
makesrna_path= argv[0];
return_status= rna_preprocess(argv[1]);
}
totblock= MEM_get_memory_blocks_in_use();
if(totblock!=0) {
printf("Error Totblock: %d\n",totblock);
MEM_set_error_callback(mem_error_cb);
MEM_printmemlist();
}
return return_status;
}
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