#include "edje_private.h" static void _edje_part_make_rtl(Edje_Part_Description_Common *desc); static Edje_Part_Description_Common *_edje_get_description_by_orientation(Edje *ed, Edje_Part_Description_Common *src, Edje_Part_Description_Common **dst, unsigned char type); static void _edje_part_recalc_single(Edje *ed, Edje_Real_Part *ep, Edje_Part_Description_Common *desc, Edje_Part_Description_Common *chosen_desc, Edje_Real_Part *center, Edje_Real_Part *light, Edje_Real_Part *persp, Edje_Real_Part *rel1_to_x, Edje_Real_Part *rel1_to_y, Edje_Real_Part *rel2_to_x, Edje_Real_Part *rel2_to_y, Edje_Real_Part *confine_to, Edje_Real_Part *threshold, Edje_Calc_Params *params, Edje_Real_Part_Set *set, Evas_Coord mmw, Evas_Coord mmh, FLOAT_T pos); #define EINA_COW_CALC_PHYSICS_BEGIN(Calc, Write) \ EINA_COW_WRITE_BEGIN(_edje_calc_params_physics_cow, Calc->physics, Edje_Calc_Params_Physics, Write) #define EINA_COW_CALC_PHYSICS_END(Calc, Write) \ EINA_COW_WRITE_END(_edje_calc_params_physics_cow, Calc->physics, Write) #define EINA_COW_CALC_MAP_BEGIN(Calc, Write) \ EINA_COW_WRITE_BEGIN(_edje_calc_params_map_cow, Calc->map, Edje_Calc_Params_Map, Write) #define EINA_COW_CALC_MAP_END(Calc, Write) \ EINA_COW_WRITE_END(_edje_calc_params_map_cow, Calc->map, Write); void _edje_part_pos_set(Edje *ed, Edje_Real_Part *ep, int mode, FLOAT_T pos, FLOAT_T v1, FLOAT_T v2) { FLOAT_T fp_pos; FLOAT_T npos; pos = CLAMP(pos, ZERO, FROM_INT(1)); fp_pos = pos; #if 0 // old code - easy to enable for comparing float vs fixed point /* take linear pos along timescale and use interpolation method */ switch (mode) { case EDJE_TWEEN_MODE_SINUSOIDAL: /* npos = (1.0 - cos(pos * PI)) / 2.0; */ npos = DIV2(SUB(FROM_INT(1), COS(MUL(fp_pos, PI)))); break; case EDJE_TWEEN_MODE_ACCELERATE: /* npos = 1.0 - sin((PI / 2.0) + (pos * PI / 2.0)); */ npos = SUB(FROM_INT(1), SIN(ADD(DIV2(PI), MUL(fp_pos, DIV2(PI))))); break; case EDJE_TWEEN_MODE_DECELERATE: /* npos = sin(pos * PI / 2.0); */ npos = SIN(MUL(fp_pos, DIV2(PI))); break; case EDJE_TWEEN_MODE_LINEAR: npos = fp_pos; break; default: npos = fp_pos; break; } #else switch (mode & EDJE_TWEEN_MODE_MASK) { case EDJE_TWEEN_MODE_SINUSOIDAL: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_SINUSOIDAL, 0.0, 0.0)); break; case EDJE_TWEEN_MODE_ACCELERATE: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_ACCELERATE, 0.0, 0.0)); break; case EDJE_TWEEN_MODE_DECELERATE: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_DECELERATE, 0.0, 0.0)); break; case EDJE_TWEEN_MODE_LINEAR: npos = fp_pos; /* npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_LINEAR, 0.0, 0.0)); */ break; case EDJE_TWEEN_MODE_ACCELERATE_FACTOR: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_ACCELERATE_FACTOR, TO_DOUBLE(v1), 0.0)); break; case EDJE_TWEEN_MODE_DECELERATE_FACTOR: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_DECELERATE_FACTOR, TO_DOUBLE(v1), 0.0)); break; case EDJE_TWEEN_MODE_SINUSOIDAL_FACTOR: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_SINUSOIDAL_FACTOR, TO_DOUBLE(v1), 0.0)); break; case EDJE_TWEEN_MODE_DIVISOR_INTERP: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_DIVISOR_INTERP, TO_DOUBLE(v1), TO_DOUBLE(v2))); break; case EDJE_TWEEN_MODE_BOUNCE: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_BOUNCE, TO_DOUBLE(v1), TO_DOUBLE(v2))); break; case EDJE_TWEEN_MODE_SPRING: npos = FROM_DOUBLE(ecore_animator_pos_map(TO_DOUBLE(pos), ECORE_POS_MAP_SPRING, TO_DOUBLE(v1), TO_DOUBLE(v2))); break; default: npos = fp_pos; break; } #endif if (npos == ep->description_pos) return; ep->description_pos = npos; ed->dirty = EINA_TRUE; ed->recalc_call = EINA_TRUE; #ifdef EDJE_CALC_CACHE ep->invalidate = EINA_TRUE; #endif } /** * Returns part description * * @internal * * Converts part description to RTL-desc. * * @param desc Pointer to desc buffer. * **/ static void _edje_part_make_rtl(Edje_Part_Description_Common *desc) { double t; int i; if(!desc) return; /* This makes alignment right-oriented */ desc->align.x = 1.0 - desc->align.x; /* same as above for relative components */ t = desc->rel1.relative_x; desc->rel1.relative_x = 1.0 - desc->rel2.relative_x; desc->rel2.relative_x = 1.0 - t; /* +1 and +1 are because how edje works with right * side borders - nothing is printed beyond that limit * * rel2 is now to the left of rel1, and Edje assumes * the opposite so we switch corners on x-axis to define * offset from right to left */ i = desc->rel1.offset_x; desc->rel1.offset_x = -(desc->rel2.offset_x + 1); desc->rel2.offset_x = -(i + 1); i = desc->rel1.id_x; desc->rel1.id_x = desc->rel2.id_x; desc->rel2.id_x = i; } /** * Returns part description * * @internal * * Returns part description according to object orientation. * When object is in RTL-orientation (RTL flag is set) * this returns the RTL-desc of it. * RTL-desc would be allocated if was not created by a previous call. * The dst pointer is updated in case of an allocation. * * @param ed Edje object. * @param src The Left To Right (LTR), original desc. * @param dst Pointer to Right To Left (RTL) desc-list. * @param type name of dec type. Example: "default". * * @return Edje part description. * **/ static Edje_Part_Description_Common * _edje_get_description_by_orientation(Edje *ed, Edje_Part_Description_Common *src, Edje_Part_Description_Common **dst, unsigned char type) { Edje_Part_Description_Common *desc_rtl = NULL; Edje_Part_Collection_Directory_Entry *ce; size_t memsize = 0; /* RTL flag is not set, return original description */ if(!edje_object_mirrored_get(ed->obj)) return src; if(*dst) return *dst; /* Was allocated before and we should use it */ #define EDIT_ALLOC_POOL_RTL(Short, Type, Name) \ case EDJE_PART_TYPE_##Short: \ { \ Edje_Part_Description_##Type *Name; \ Name = eina_mempool_malloc(ce->mp_rtl.Short, \ sizeof (Edje_Part_Description_##Type)); \ memset(Name, 0, sizeof(Edje_Part_Description_##Type)); \ desc_rtl = &Name->common; \ memsize = sizeof(Edje_Part_Description_##Type); \ break; \ } ce = eina_hash_find(ed->file->collection, ed->group); switch (type) { case EDJE_PART_TYPE_RECTANGLE: desc_rtl = eina_mempool_malloc(ce->mp_rtl.RECTANGLE, sizeof (Edje_Part_Description_Common)); ce->count.RECTANGLE++; memsize = sizeof(Edje_Part_Description_Common); break; case EDJE_PART_TYPE_SWALLOW: desc_rtl = eina_mempool_malloc(ce->mp_rtl.SWALLOW, sizeof (Edje_Part_Description_Common)); ce->count.SWALLOW++; memsize = sizeof(Edje_Part_Description_Common); break; case EDJE_PART_TYPE_GROUP: desc_rtl = eina_mempool_malloc(ce->mp_rtl.GROUP, sizeof (Edje_Part_Description_Common)); ce->count.GROUP++; memsize = sizeof(Edje_Part_Description_Common); break; case EDJE_PART_TYPE_SPACER: desc_rtl = eina_mempool_malloc(ce->mp_rtl.SPACER, sizeof (Edje_Part_Description_Common)); ce->count.SPACER++; memsize = sizeof(Edje_Part_Description_Common); break; EDIT_ALLOC_POOL_RTL(TEXT, Text, text); EDIT_ALLOC_POOL_RTL(TEXTBLOCK, Text, text); EDIT_ALLOC_POOL_RTL(IMAGE, Image, image); EDIT_ALLOC_POOL_RTL(PROXY, Proxy, proxy); EDIT_ALLOC_POOL_RTL(BOX, Box, box); EDIT_ALLOC_POOL_RTL(TABLE, Table, table); EDIT_ALLOC_POOL_RTL(EXTERNAL, External, external_params); } if (desc_rtl) memcpy(desc_rtl, src, memsize); _edje_part_make_rtl(desc_rtl); *dst = desc_rtl; return desc_rtl; } Edje_Part_Description_Common * _edje_part_description_find(Edje *ed, Edje_Real_Part *rp, const char *name, double val) { Edje_Part *ep = rp->part; Edje_Part_Description_Common *ret = NULL; Edje_Part_Description_Common *d; double min_dst = 99999.0; unsigned int i; /* RTL flag is set, return RTL description */ if(edje_object_mirrored_get(ed->obj)) if(!ep->other.desc_rtl) ep->other.desc_rtl = (Edje_Part_Description_Common **) calloc(ep->other.desc_count, sizeof (Edje_Part_Description_Common *)); if (!strcmp(name, "default") && val == 0.0) return _edje_get_description_by_orientation(ed, ep->default_desc, &ep->default_desc_rtl, ep->type); if (!strcmp(name, "custom")) return rp->custom ? _edje_get_description_by_orientation(ed, rp->custom->description, &rp->custom->description_rtl, ep->type) : NULL; if (!strcmp(name, "default")) { ret = _edje_get_description_by_orientation(ed, ep->default_desc, &ep->default_desc_rtl, ep->type); min_dst = ABS(ep->default_desc->state.value - val); } for (i = 0; i < ep->other.desc_count; ++i) { d = ep->other.desc[i]; if (d->state.name && (d->state.name == name || !strcmp(d->state.name, name))) { double dst; dst = ABS(d->state.value - val); if (dst < min_dst) { ret = _edje_get_description_by_orientation(ed, d, &ep->other.desc_rtl[i], ep->type); min_dst = dst; } } } return ret; } static int _edje_image_find(Evas_Object *obj, Edje *ed, Edje_Real_Part_Set **eps, Edje_Part_Description_Image *st, Edje_Part_Image_Id *imid) { Edje_Image_Directory_Set_Entry *entry; Edje_Image_Directory_Set *set = NULL; Eina_List *l; int w = 0, h = 0, id; if (!st && !imid) return -1; if (st && !st->image.set) return st->image.id; if (imid && !imid->set) return imid->id; if (imid) id = imid->id; else id = st->image.id; evas_object_geometry_get(obj, NULL, NULL, &w, &h); if (eps && *eps) { if ((*eps)->id == id) set = (*eps)->set; if (set) { if (((*eps)->entry->size.min.w <= w) && (w <= (*eps)->entry->size.max.w)) { if (((*eps)->entry->size.min.h <= h) && (h <= (*eps)->entry->size.max.h)) { return (*eps)->entry->id; } } } } if (!set) set = ed->file->image_dir->sets + id; EINA_LIST_FOREACH(set->entries, l, entry) { if ((entry->size.min.w <= w) && (w <= entry->size.max.w)) { if ((entry->size.min.h <= h) && (h <= entry->size.max.h)) { if (eps) { if (!*eps) *eps = calloc(1, sizeof(Edje_Real_Part_Set)); if (*eps) { (*eps)->entry = entry; (*eps)->set = set; (*eps)->id = id; } } return entry->id; } } } return -1; } static void _edje_real_part_image_set(Edje *ed, Edje_Real_Part *ep, FLOAT_T pos) { int image_id; int image_count, image_num; image_id = _edje_image_find(ep->object, ed, &ep->param1.set, (Edje_Part_Description_Image*) ep->param1.description, NULL); if (image_id < 0) { Edje_Image_Directory_Entry *ie; if (!ed->file->image_dir) ie = NULL; else ie = ed->file->image_dir->entries + (-image_id) - 1; if ((ie) && (ie->source_type == EDJE_IMAGE_SOURCE_TYPE_EXTERNAL) && (ie->entry)) { evas_object_image_file_set(ep->object, ie->entry, NULL); } } else { image_count = 2; if (ep->param2) image_count += ((Edje_Part_Description_Image*) ep->param2->description)->image.tweens_count; image_num = TO_INT(MUL(pos, SUB(FROM_INT(image_count), FROM_DOUBLE(0.5)))); if (image_num > (image_count - 1)) image_num = image_count - 1; if (image_num <= 0) { image_id = _edje_image_find(ep->object, ed, &ep->param1.set, (Edje_Part_Description_Image*) ep->param1.description, NULL); } else if (ep->param2) { if (image_num == (image_count - 1)) { image_id = _edje_image_find(ep->object, ed, &ep->param2->set, (Edje_Part_Description_Image*) ep->param2->description, NULL); } else { Edje_Part_Image_Id *imid; imid = ((Edje_Part_Description_Image*) ep->param2->description)->image.tweens[image_num - 1]; image_id = _edje_image_find(ep->object, ed, NULL, NULL, imid); } } if (image_id < 0) { ERR("¨Part \"%s\" description, " "\"%s\" %3.3f with image %i index has a missing image id in a set of %i !!!", ep->part->name, ep->param1.description->state.name, ep->param1.description->state.value, image_num, image_count); } else { char buf[1024] = "edje/images/"; /* Replace snprint("edje/images/%i") == memcpy + itoa */ eina_convert_itoa(image_id, buf + 12); /* No need to check length as 2³² need only 10 characteres. */ evas_object_image_mmap_set(ep->object, ed->file->f, buf); if (evas_object_image_load_error_get(ep->object) != EVAS_LOAD_ERROR_NONE) { ERR("Error loading image collection \"%s\" from " "file \"%s\". Missing EET Evas loader module?", buf, ed->file->path); switch (evas_object_image_load_error_get(ep->object)) { case EVAS_LOAD_ERROR_GENERIC: ERR("Error type: EVAS_LOAD_ERROR_GENERIC"); break; case EVAS_LOAD_ERROR_DOES_NOT_EXIST: ERR("Error type: EVAS_LOAD_ERROR_DOES_NOT_EXIST"); break; case EVAS_LOAD_ERROR_PERMISSION_DENIED: ERR("Error type: EVAS_LOAD_ERROR_PERMISSION_DENIED"); break; case EVAS_LOAD_ERROR_RESOURCE_ALLOCATION_FAILED: ERR("Error type: EVAS_LOAD_ERROR_RESOURCE_ALLOCATION_FAILED"); break; case EVAS_LOAD_ERROR_CORRUPT_FILE: ERR("Error type: EVAS_LOAD_ERROR_CORRUPT_FILE"); break; case EVAS_LOAD_ERROR_UNKNOWN_FORMAT: ERR("Error type: EVAS_LOAD_ERROR_UNKNOWN_FORMAT"); break; default: ERR("Error type: ???"); break; } } } } } static void _edje_real_part_rel_to_apply(Edje *ed EINA_UNUSED, Edje_Real_Part *ep, Edje_Real_Part_State *state) { if (state->description) { if (ep->part->type == EDJE_PART_TYPE_EXTERNAL) { Edje_Part_Description_External *external; if ((ep->type != EDJE_RP_TYPE_SWALLOW) || (!ep->typedata.swallow)) return; external = (Edje_Part_Description_External*)state->description; if (state->external_params) _edje_external_parsed_params_free(ep->typedata.swallow->swallowed_object, state->external_params); state->external_params = _edje_external_params_parse(ep->typedata.swallow->swallowed_object, external->external_params); } } } void _edje_part_description_apply(Edje *ed, Edje_Real_Part *ep, const char *d1, double v1, const char *d2, double v2) { Edje_Part_Description_Common *epd1; Edje_Part_Description_Common *epd2 = NULL; Edje_Part_Description_Common *chosen_desc; Edje_Part_Description_Image *epdi; if (!d1) d1 = "default"; epd1 = _edje_part_description_find(ed, ep, d1, v1); if (!epd1) epd1 = ep->part->default_desc; /* never NULL */ if (d2) epd2 = _edje_part_description_find(ed, ep, d2, v2); epdi = (Edje_Part_Description_Image*) epd2; /* There is an animation if both description are different or if description is an image with tweens */ if (epd2 && (epd1 != epd2 || (ep->part->type == EDJE_PART_TYPE_IMAGE && epdi->image.tweens_count))) { if (!ep->param2) { ep->param2 = eina_mempool_malloc(_edje_real_part_state_mp, sizeof(Edje_Real_Part_State)); memset(ep->param2, 0, sizeof(Edje_Real_Part_State)); ep->param2->p.map = eina_cow_alloc(_edje_calc_params_map_cow); #ifdef HAVE_EPHYSICS ep->param2->p.physics = eina_cow_alloc(_edje_calc_params_physics_cow); #endif } else if (ep->part->type == EDJE_PART_TYPE_EXTERNAL) { if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) _edje_external_parsed_params_free(ep->typedata.swallow->swallowed_object, ep->param2->external_params); } ep->param2->external_params = NULL; } else if (ep->param2) { if (ep->part->type == EDJE_PART_TYPE_EXTERNAL) { if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) _edje_external_parsed_params_free(ep->typedata.swallow->swallowed_object, ep->param2->external_params); } if (ep->param2) { free(ep->param2->set); eina_cow_free(_edje_calc_params_map_cow, (const Eina_Cow_Data **) &ep->param2->p.map); #ifdef HAVE_EPHYSICS eina_cow_free(_edje_calc_params_physics_cow, (const Eina_Cow_Data **) &ep->param2->p.physics); #endif } eina_mempool_free(_edje_real_part_state_mp, ep->param2); ep->param2 = NULL; } chosen_desc = ep->chosen_description; ep->param1.description = epd1; ep->chosen_description = epd1; _edje_real_part_rel_to_apply(ed, ep, &ep->param1); if (ep->param2) { ep->param2->description = epd2; _edje_real_part_rel_to_apply(ed, ep, ep->param2); if (ep->description_pos > FROM_DOUBLE(0.0)) ep->chosen_description = epd2; } if (chosen_desc != ep->chosen_description && ep->part->type == EDJE_PART_TYPE_EXTERNAL) _edje_external_recalc_apply(ed, ep, NULL, chosen_desc); ed->recalc_hints = EINA_TRUE; ed->dirty = EINA_TRUE; ed->recalc_call = EINA_TRUE; #ifdef EDJE_CALC_CACHE ep->invalidate = EINA_TRUE; #endif } void _edje_recalc(Edje *ed) { if ((ed->freeze > 0) || (_edje_freeze_val > 0)) { ed->recalc = EINA_TRUE; if (!ed->calc_only) { if (_edje_freeze_val > 0) { if (!ed->freeze_calc) { _edje_freeze_calc_count++; _edje_freeze_calc_list = eina_list_append(_edje_freeze_calc_list, ed); ed->freeze_calc = EINA_TRUE; } } return; } } // XXX: dont need this with current smart calc infra. remove me later // if (ed->postponed) return; // if (!ed->calc_only) evas_object_smart_changed(ed->obj); // XXX: dont need this with current smart calc infra. remove me later // ed->postponed = EINA_TRUE; } void _edje_recalc_do(Edje *ed) { unsigned int i; Eina_Bool need_calc; // XXX: dont need this with current smart calc infra. remove me later // ed->postponed = EINA_FALSE; need_calc = evas_object_smart_need_recalculate_get(ed->obj); evas_object_smart_need_recalculate_set(ed->obj, 0); if (!ed->dirty) return; ed->dirty = EINA_FALSE; ed->state++; for (i = 0; i < ed->table_parts_size; i++) { Edje_Real_Part *ep; ep = ed->table_parts[i]; ep->calculated = FLAG_NONE; ep->calculating = FLAG_NONE; } for (i = 0; i < ed->table_parts_size; i++) { Edje_Real_Part *ep; ep = ed->table_parts[i]; if (ep->calculated != FLAG_XY) _edje_part_recalc(ed, ep, (~ep->calculated) & FLAG_XY, NULL); } if (!ed->calc_only) ed->recalc = EINA_FALSE; #ifdef EDJE_CALC_CACHE ed->all_part_change = EINA_FALSE; ed->text_part_change = EINA_FALSE; #endif if (!ed->calc_only) { if (ed->recalc_call) evas_object_smart_callback_call(ed->obj, "recalc", NULL); } else evas_object_smart_need_recalculate_set(ed->obj, need_calc); ed->recalc_call = EINA_FALSE; if (ed->update_hints && ed->recalc_hints && !ed->calc_only) { Evas_Coord w, h; ed->recalc_hints = EINA_FALSE; eo_do(ed->obj, edje_obj_size_min_calc(&w, &h)); eo_do(ed->obj, evas_obj_size_hint_min_set(w, h)); } if (!ed->collection) return; for (i = 0; i < ed->collection->limits.parts_count; i++) { const char *name; unsigned char limit; int part; part = ed->collection->limits.parts[i].part; name = ed->collection->parts[part]->name; limit = ed->table_parts[part]->chosen_description->limit; switch (limit) { case 0: ed->collection->limits.parts[i].width = EDJE_PART_LIMIT_UNKNOWN; ed->collection->limits.parts[i].height = EDJE_PART_LIMIT_UNKNOWN; break; case 1: ed->collection->limits.parts[i].height = EDJE_PART_LIMIT_UNKNOWN; break; case 2: ed->collection->limits.parts[i].width = EDJE_PART_LIMIT_UNKNOWN; break; case 3: break; } if ((limit & 1) == 1) { if (ed->table_parts[part]->w > 0 && (ed->collection->limits.parts[i].width != EDJE_PART_LIMIT_OVER)) { ed->collection->limits.parts[i].width = EDJE_PART_LIMIT_OVER; _edje_emit(ed, "limit,width,over", name); } else if (ed->table_parts[part]->w < 0 && ed->collection->limits.parts[i].width != EDJE_PART_LIMIT_BELOW) { ed->collection->limits.parts[i].width = EDJE_PART_LIMIT_BELOW; _edje_emit(ed, "limit,width,below", name); } else if (ed->table_parts[part]->w == 0 && ed->collection->limits.parts[i].width != EDJE_PART_LIMIT_ZERO) { ed->collection->limits.parts[i].width = EDJE_PART_LIMIT_ZERO; _edje_emit(ed, "limit,width,zero", name); } } if ((limit & 2) == 2) { if (ed->table_parts[part]->h > 0 && (ed->collection->limits.parts[i].height != EDJE_PART_LIMIT_OVER)) { ed->collection->limits.parts[i].height = EDJE_PART_LIMIT_OVER; _edje_emit(ed, "limit,height,over", name); } else if (ed->table_parts[part]->h < 0 && ed->collection->limits.parts[i].height != EDJE_PART_LIMIT_BELOW) { ed->collection->limits.parts[i].height = EDJE_PART_LIMIT_BELOW; _edje_emit(ed, "limit,height,below", name); } else if (ed->table_parts[part]->h == 0 && ed->collection->limits.parts[i].height != EDJE_PART_LIMIT_ZERO) { ed->collection->limits.parts[i].height = EDJE_PART_LIMIT_ZERO; _edje_emit(ed, "limit,height,zero", name); } } } } int _edje_part_dragable_calc(Edje *ed EINA_UNUSED, Edje_Real_Part *ep, FLOAT_T *x, FLOAT_T *y) { if (ep->drag) { Eina_Bool tx = EINA_FALSE; Eina_Bool ty = EINA_FALSE; if (ep->drag->threshold) { // Check if we are in the threshold or not and cancel the movement. tx = ep->drag->threshold_x && ep->drag->threshold_started_x; ty = ep->drag->threshold_y && ep->drag->threshold_started_y; } if (ep->drag->confine_to) { FLOAT_T dx, dy, dw, dh; int ret = 0; if ((ep->part->dragable.x != 0) && (ep->part->dragable.y != 0 )) ret = 3; else if (ep->part->dragable.x != 0) ret = 1; else if (ep->part->dragable.y != 0) ret = 2; dx = FROM_INT(ep->x - ep->drag->confine_to->x); dw = FROM_INT(ep->drag->confine_to->w - ep->w); if (dw != ZERO) dx = DIV(dx, dw); else dx = ZERO; dy = FROM_INT(ep->y - ep->drag->confine_to->y); dh = FROM_INT(ep->drag->confine_to->h - ep->h); if (dh != ZERO) dy = DIV(dy, dh); else dy = ZERO; if (x) *x = tx ? ep->drag->x : dx; if (y) *y = ty ? ep->drag->y : dy; return ret; } else { if (x) *x = tx ? ep->drag->x : ADD(FROM_INT(ep->drag->tmp.x), ep->drag->x); if (y) *y = ty ? ep->drag->y : ADD(FROM_INT(ep->drag->tmp.y), ep->drag->y); return 0; } } if (x) *x = ZERO; if (y) *y = ZERO; return 0; } void _edje_dragable_pos_set(Edje *ed, Edje_Real_Part *ep, FLOAT_T x, FLOAT_T y) { /* check whether this part is dragable at all */ if (!ep->drag) return; /* instead of checking for equality, we really should check that * the difference is greater than foo, but I have no idea what * value we would set foo to, because it would depend on the * size of the dragable... */ if (ep->drag->x != x || ep->drag->tmp.x) { ep->drag->x = x; ep->drag->tmp.x = 0; ep->drag->need_reset = 0; ed->dirty = EINA_TRUE; ed->recalc_call = EINA_TRUE; } if (ep->drag->y != y || ep->drag->tmp.y) { ep->drag->y = y; ep->drag->tmp.y = 0; ep->drag->need_reset = 0; ed->dirty = EINA_TRUE; ed->recalc_call = EINA_TRUE; } #ifdef EDJE_CALC_CACHE ep->invalidate = EINA_TRUE; #endif _edje_recalc(ed); /* won't do anything if dirty flag isn't set */ } static void _edje_part_recalc_single_rel(Edje *ed, Edje_Real_Part *ep EINA_UNUSED, Edje_Part_Description_Common *desc, Edje_Real_Part *rel1_to_x, Edje_Real_Part *rel1_to_y, Edje_Real_Part *rel2_to_x, Edje_Real_Part *rel2_to_y, Edje_Calc_Params *params) { FLOAT_T x, w; FLOAT_T y, h; if (rel1_to_x) x = ADD(FROM_INT(desc->rel1.offset_x + rel1_to_x->x), SCALE(desc->rel1.relative_x, rel1_to_x->w)); else x = ADD(FROM_INT(desc->rel1.offset_x), SCALE(desc->rel1.relative_x, ed->w)); params->eval.x = x; if (rel2_to_x) w = ADD(SUB(ADD(FROM_INT(desc->rel2.offset_x + rel2_to_x->x), SCALE(desc->rel2.relative_x, rel2_to_x->w)), x), FROM_INT(1)); else w = ADD(SUB(ADD(FROM_INT(desc->rel2.offset_x), SCALE(desc->rel2.relative_x, ed->w)), x), FROM_INT(1)); params->eval.w = w; if (rel1_to_y) y = ADD(FROM_INT(desc->rel1.offset_y + rel1_to_y->y), SCALE(desc->rel1.relative_y, rel1_to_y->h)); else y = ADD(FROM_INT(desc->rel1.offset_y), SCALE(desc->rel1.relative_y, ed->h)); params->eval.y = y; if (rel2_to_y) h = ADD(SUB(ADD(FROM_INT(desc->rel2.offset_y + rel2_to_y->y), SCALE(desc->rel2.relative_y, rel2_to_y->h)), y), FROM_INT(1)); else h = ADD(SUB(ADD(FROM_INT(desc->rel2.offset_y), SCALE(desc->rel2.relative_y, ed->h)), y), FROM_INT(1)); params->eval.h = h; } static Edje_Internal_Aspect _edje_part_recalc_single_aspect(Edje *ed, Edje_Real_Part *ep, Edje_Part_Description_Common *desc, Edje_Calc_Params *params, int *minw, int *minh, int *maxw, int *maxh, FLOAT_T pos) { Edje_Internal_Aspect apref = EDJE_ASPECT_PREFER_NONE; FLOAT_T aspect, amax, amin; FLOAT_T new_w = ZERO, new_h = ZERO, want_x, want_y, want_w, want_h; if (params->eval.h <= ZERO) aspect = FROM_INT(999999); else aspect = DIV(params->eval.w, params->eval.h); amax = desc->aspect.max; amin = desc->aspect.min; if (desc->aspect.prefer == EDJE_ASPECT_PREFER_SOURCE && ep->part->type == EDJE_PART_TYPE_IMAGE) { Evas_Coord w, h; /* We only need pose to find the right image that would be displayed, and the right aspect ratio in that case */ _edje_real_part_image_set(ed, ep, pos); evas_object_image_size_get(ep->object, &w, &h); amin = amax = DIV(FROM_INT(w), FROM_INT(h)); } if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) { if ((ep->typedata.swallow->swallow_params.aspect.w > 0) && (ep->typedata.swallow->swallow_params.aspect.h > 0)) amin = amax = DIV(FROM_INT(ep->typedata.swallow->swallow_params.aspect.w), FROM_INT(ep->typedata.swallow->swallow_params.aspect.h)); } want_x = params->eval.x; want_w = new_w = params->eval.w; want_y = params->eval.y; want_h = new_h = params->eval.h; if ((amin > ZERO) && (amax > ZERO)) { apref = desc->aspect.prefer; if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) { if (ep->typedata.swallow->swallow_params.aspect.mode > EDJE_ASPECT_CONTROL_NONE) { switch (ep->typedata.swallow->swallow_params.aspect.mode) { case EDJE_ASPECT_CONTROL_NEITHER: apref = EDJE_ASPECT_PREFER_NONE; break; case EDJE_ASPECT_CONTROL_HORIZONTAL: apref = EDJE_ASPECT_PREFER_HORIZONTAL; break; case EDJE_ASPECT_CONTROL_VERTICAL: apref = EDJE_ASPECT_PREFER_VERTICAL; break; case EDJE_ASPECT_CONTROL_BOTH: apref = EDJE_ASPECT_PREFER_BOTH; break; default: break; } } } switch (apref) { case EDJE_ASPECT_PREFER_NONE: /* keep both dimensions in check */ /* adjust for min aspect (width / height) */ if ((amin > ZERO) && (aspect < amin)) { new_h = DIV(params->eval.w, amin); new_w = MUL(amin, params->eval.h); } /* adjust for max aspect (width / height) */ if ((amax > ZERO) && (aspect > amax)) { new_h = DIV(params->eval.w, amax); new_w = MUL(amax, params->eval.h); } if ((amax > ZERO) && (new_w < params->eval.w)) { new_w = params->eval.w; new_h = DIV(params->eval.w, amax); } if ((amax > ZERO) && (new_h < params->eval.h)) { new_w = MUL(amax, params->eval.h); new_h = params->eval.h; } break; /* prefer vertical size as determiner */ case EDJE_ASPECT_PREFER_VERTICAL: /* keep both dimensions in check */ /* adjust for max aspect (width / height) */ if ((amax > ZERO) && (aspect > amax)) new_w = MUL(amax, params->eval.h); /* adjust for min aspect (width / height) */ if ((amin > ZERO) && (aspect < amin)) new_w = MUL(amin, params->eval.h); break; /* prefer horizontal size as determiner */ case EDJE_ASPECT_PREFER_HORIZONTAL: /* keep both dimensions in check */ /* adjust for max aspect (width / height) */ if ((amax > ZERO) && (aspect > amax)) new_h = DIV(params->eval.w, amax); /* adjust for min aspect (width / height) */ if ((amin > ZERO) && (aspect < amin)) new_h = DIV(params->eval.w, amin); break; case EDJE_ASPECT_PREFER_SOURCE: case EDJE_ASPECT_PREFER_BOTH: /* keep both dimensions in check */ /* adjust for max aspect (width / height) */ if ((amax > ZERO) && (aspect > amax)) { new_w = MUL(amax, params->eval.h); new_h = DIV(params->eval.w, amax); } /* adjust for min aspect (width / height) */ if ((amin > ZERO) && (aspect < amin)) { new_w = MUL(amin, params->eval.h); new_h = DIV(params->eval.w, amin); } break; default: break; } if (!((amin > ZERO) && (amax > ZERO) && (apref == EDJE_ASPECT_PREFER_NONE))) { if ((*maxw >= 0) && (new_w > FROM_INT(*maxw))) new_w = FROM_INT(*maxw); if (new_w < FROM_INT(*minw)) new_w = FROM_INT(*minw); if ((FROM_INT(*maxh) >= 0) && (new_h > FROM_INT(*maxh))) new_h = FROM_INT(*maxh); if (new_h < FROM_INT(*minh)) new_h = FROM_INT(*minh); } /* do real adjustment */ if (apref == EDJE_ASPECT_PREFER_BOTH) { if (amin == ZERO) amin = amax; if (amin != ZERO) { /* fix h and vary w */ if (new_w > params->eval.w) { // params->w = new_w; // EXCEEDS BOUNDS in W new_h = DIV(params->eval.w, amin); new_w = params->eval.w; if (new_h > params->eval.h) { new_h = params->eval.h; new_w = MUL(amin, params->eval.h); } } /* fix w and vary h */ else { // params->h = new_h; // EXCEEDS BOUNDS in H new_h = params->eval.h; new_w = MUL(amin, params->eval.h); if (new_w > params->eval.w) { new_h = DIV(params->eval.w, amin); new_w = params->eval.w; } } params->eval.w = new_w; params->eval.h = new_h; } } } if (apref != EDJE_ASPECT_PREFER_BOTH) { if ((amin > 0.0) && (amax > ZERO) && (apref == EDJE_ASPECT_PREFER_NONE)) { params->eval.w = new_w; params->eval.h = new_h; } else if (SUB(params->eval.h, new_h) > SUB(params->eval.w, new_w)) { if (params->eval.h < new_h) params->eval.h = new_h; else if (params->eval.h > new_h) params->eval.h = new_h; if (apref == EDJE_ASPECT_PREFER_VERTICAL) params->eval.w = new_w; } else { if (params->eval.w < new_w) params->eval.w = new_w; else if (params->eval.w > new_w) params->eval.w = new_w; if (apref == EDJE_ASPECT_PREFER_HORIZONTAL) params->eval.h = new_h; } } params->eval.x = ADD(want_x, MUL(SUB(want_w, params->eval.w), desc->align.x)); params->eval.y = ADD(want_y, MUL(SUB(want_h, params->eval.h), desc->align.y)); return apref; } static void _edje_part_recalc_single_step(Edje_Part_Description_Common *desc, Edje_Calc_Params *params) { if (desc->step.x > 0) { int steps; int new_w; steps = TO_INT(params->eval.w) / desc->step.x; new_w = desc->step.x * steps; if (params->eval.w > FROM_INT(new_w)) { params->eval.x = ADD(params->eval.x, SCALE(desc->align.x, SUB(params->eval.w, FROM_INT(new_w)))); params->eval.w = FROM_INT(new_w); } } if (desc->step.y > 0) { int steps; int new_h; steps = TO_INT(params->eval.h) / desc->step.y; new_h = desc->step.y * steps; if (params->eval.h > FROM_INT(new_h)) { params->eval.y = ADD(params->eval.y, SCALE(desc->align.y, SUB(params->eval.h, FROM_INT(new_h)))); params->eval.h = FROM_INT(new_h); } } } static double _edje_part_recalc_single_textblock_scale_range_adjust(Edje_Part_Description_Text *chosen_desc, double base_scale, double scale) { double size, min, max; if (chosen_desc->text.size == 0) return scale; min = base_scale * chosen_desc->text.size_range_min; max = chosen_desc->text.size_range_max * base_scale; size = chosen_desc->text.size * scale; if ((size > max) && (max > 0)) scale = max / (double) chosen_desc->text.size; else if (size < min) scale = min / (double) chosen_desc->text.size; return scale; } static void _edje_part_recalc_single_textblock(FLOAT_T sc, Edje *ed, Edje_Real_Part *ep, Edje_Part_Description_Text *chosen_desc, Edje_Calc_Params *params, int *minw, int *minh, int *maxw, int *maxh) { if ((ep->type != EDJE_RP_TYPE_TEXT) || (!ep->typedata.text)) return; if (chosen_desc) { Evas_Coord tw, th, ins_l, ins_r, ins_t, ins_b; const char *text = ""; const char *style = ""; Edje_Style *stl = NULL; const char *tmp; Eina_List *l; if (chosen_desc->text.id_source >= 0) { ep->typedata.text->source = ed->table_parts[chosen_desc->text.id_source % ed->table_parts_size]; tmp = edje_string_get(&((Edje_Part_Description_Text *)ep->typedata.text->source->chosen_description)->text.style); if (tmp) style = tmp; } else { ep->typedata.text->source = NULL; tmp = edje_string_get(&chosen_desc->text.style); if (tmp) style = tmp; } if (chosen_desc->text.id_text_source >= 0) { ep->typedata.text->text_source = ed->table_parts[chosen_desc->text.id_text_source % ed->table_parts_size]; text = edje_string_get(&((Edje_Part_Description_Text*)ep->typedata.text->text_source->chosen_description)->text.text); if (ep->typedata.text->text_source->typedata.text->text) text = ep->typedata.text->text_source->typedata.text->text; } else { ep->typedata.text->text_source = NULL; text = edje_string_get(&chosen_desc->text.text); if (ep->typedata.text->text) text = ep->typedata.text->text; } EINA_LIST_FOREACH(ed->file->styles, l, stl) { if ((stl->name) && (!strcmp(stl->name, style))) break; stl = NULL; } if (ep->part->scale) evas_object_scale_set(ep->object, TO_DOUBLE(sc)); if ((chosen_desc->text.fit_x) || (chosen_desc->text.fit_y)) { double base_s = 1.0; double orig_s; double s = base_s; if (ep->part->scale) base_s = TO_DOUBLE(sc); eo_do(ep->object, evas_obj_scale_set(base_s), evas_obj_textblock_size_native_get(&tw, &th)); orig_s = base_s; /* Now make it bigger so calculations will be more accurate * and less influenced by hinting... */ { orig_s = _edje_part_recalc_single_textblock_scale_range_adjust(chosen_desc, base_s, orig_s * TO_INT(params->eval.w) / tw); eo_do(ep->object, evas_obj_scale_set(orig_s), evas_obj_textblock_size_native_get(&tw, &th)); } if (chosen_desc->text.fit_x) { if (tw > 0) { s = _edje_part_recalc_single_textblock_scale_range_adjust(chosen_desc, base_s, orig_s * TO_INT(params->eval.w) / tw); eo_do(ep->object, evas_obj_scale_set(s), evas_obj_textblock_size_native_get(NULL, NULL)); } } if (chosen_desc->text.fit_y) { if (th > 0) { double tmp_s = _edje_part_recalc_single_textblock_scale_range_adjust(chosen_desc, base_s, orig_s * TO_INT(params->eval.h) / th); /* If we already have X fit, restrict Y to be no bigger * than what we got with X. */ if (!((chosen_desc->text.fit_x) && (tmp_s > s))) { s = tmp_s; } eo_do(ep->object, evas_obj_scale_set(s), evas_obj_textblock_size_native_get(NULL, NULL)); } } /* Final tuning, try going down 90% at a time, hoping it'll * actually end up being correct. */ { int i = 5; /* Tries before we give up. */ Evas_Coord fw, fh; eo_do(ep->object, evas_obj_textblock_size_native_get(&fw, &fh)); /* If we are still too big, try reducing the size to * 95% each try. */ while ((i > 0) && ((chosen_desc->text.fit_x && (fw > TO_INT(params->eval.w))) || (chosen_desc->text.fit_y && (fh > TO_INT(params->eval.h))))) { double tmp_s = _edje_part_recalc_single_textblock_scale_range_adjust(chosen_desc, base_s, s * 0.95); /* Break if we are not making any progress. */ if (tmp_s == s) break; s = tmp_s; eo_do(ep->object, evas_obj_scale_set(s), evas_obj_textblock_size_native_get(&fw, &fh)); i--; } } } if (stl) { const char *ptxt; if (evas_object_textblock_style_get(ep->object) != stl->style) evas_object_textblock_style_set(ep->object, stl->style); // FIXME: need to account for editing if (ep->part->entry_mode > EDJE_ENTRY_EDIT_MODE_NONE) { // do nothing - should be done elsewhere } else { ptxt = evas_object_textblock_text_markup_get(ep->object); if (((!ptxt) && (text)) || ((ptxt) && (text) && (strcmp(ptxt, text))) || ((ptxt) && (!text))) evas_object_textblock_text_markup_set(ep->object, text); } if ((chosen_desc->text.min_x) || (chosen_desc->text.min_y)) { int mw = 0, mh = 0; tw = th = 0; if (!chosen_desc->text.min_x) { eo_do(ep->object, evas_obj_size_set(TO_INT(params->eval.w), TO_INT(params->eval.h)), evas_obj_textblock_size_formatted_get(&tw, &th)); } else evas_object_textblock_size_native_get(ep->object, &tw, &th); evas_object_textblock_style_insets_get(ep->object, &ins_l, &ins_r, &ins_t, &ins_b); mw = ins_l + tw + ins_r; mh = ins_t + th + ins_b; if (minw && chosen_desc->text.min_x) { if (mw > *minw) *minw = mw; } if (minh && chosen_desc->text.min_y) { if (mh > *minh) *minh = mh; } } } if ((chosen_desc->text.max_x) || (chosen_desc->text.max_y)) { int mw = 0, mh = 0; tw = th = 0; if (!chosen_desc->text.max_x) { eo_do(ep->object, evas_obj_size_set(TO_INT(params->eval.w), TO_INT(params->eval.h)), evas_obj_textblock_size_formatted_get(&tw, &th)); } else evas_object_textblock_size_native_get(ep->object, &tw, &th); evas_object_textblock_style_insets_get(ep->object, &ins_l, &ins_r, &ins_t, &ins_b); mw = ins_l + tw + ins_r; mh = ins_t + th + ins_b; if (maxw && chosen_desc->text.max_x) { if (mw > *maxw) *maxw = mw; if (minw && (*maxw < *minw)) *maxw = *minw; } if (maxh && chosen_desc->text.max_y) { if (mh > *maxh) *maxh = mh; if (minh && (*maxh < *minh)) *maxh = *minh; } } evas_object_textblock_valign_set(ep->object, TO_DOUBLE(chosen_desc->text.align.y)); } } static void _edje_textblock_recalc_apply(Edje *ed, Edje_Real_Part *ep, Edje_Calc_Params *params, Edje_Part_Description_Text *chosen_desc) { /* FIXME: this is just an hack. */ FLOAT_T sc; sc = ed->scale; if (sc == ZERO) sc = _edje_scale; if (chosen_desc->text.fit_x || chosen_desc->text.fit_y) { _edje_part_recalc_single_textblock(sc, ed, ep, chosen_desc, params, NULL, NULL, NULL, NULL); } } static void _edje_part_recalc_single_text(FLOAT_T sc EINA_UNUSED, Edje *ed, Edje_Real_Part *ep, Edje_Part_Description_Text *desc, Edje_Part_Description_Text *chosen_desc, Edje_Calc_Params *params, int *minw, int *minh, int *maxw, int *maxh) #define RECALC_SINGLE_TEXT_USING_APPLY 1 #if RECALC_SINGLE_TEXT_USING_APPLY /* * XXX TODO NOTE: * * Original _edje_part_recalc_single_text() was not working as * expected since it was not doing size fit, range, ellipsis and so * on. * * The purpose of this function compared with * _edje_text_recalc_apply() is to be faster, not calling Evas update * functions. However for text this is quite difficult given that to * fit we need to set the font, size, style, etc. If it was done * correctly, we'd save some calls to move and some color sets, * however those shouldn't matter much in the overall picture. * * I've changed this to force applying the value, it should be more * correct and not so slow. The previous code is kept below for * reference but should be removed before next release! * * -- Gustavo Barbieri at 20-Aug-2011 */ { int tw, th, mw, mh, l, r, t, b, size; char *sfont = NULL; _edje_text_class_font_get(ed, desc, &size, &sfont); free(sfont); params->type.text.size = size; /* XXX TODO used by further calcs, go inside recalc_apply? */ _edje_text_recalc_apply(ed, ep, params, chosen_desc, EINA_TRUE); if ((!chosen_desc) || ((!chosen_desc->text.min_x) && (!chosen_desc->text.min_y) && (!chosen_desc->text.max_x) && (!chosen_desc->text.max_y))) return; eo_do(ep->object, evas_obj_size_get(&tw, &th), evas_obj_text_style_pad_get(&l, &r, &t, &b)); mw = tw + l + r; mh = th + t + b; if (chosen_desc->text.max_x) { if ((*maxw < 0) || (mw < *maxw)) *maxw = mw; } if (chosen_desc->text.max_y) { if ((*maxh < 0) || (mh < *maxh)) *maxh = mh; } if (chosen_desc->text.min_x) { if (mw > *minw) *minw = mw; } if (chosen_desc->text.min_y) { if (mh > *minh) *minh = mh; } } #else { char *sfont = NULL; int size; if (chosen_desc) { const char *text; const char *font; Evas_Coord tw, th; int inlined_font = 0; /* Update a object_text part */ if (chosen_desc->text.id_source >= 0) ep->text.source = ed->table_parts[chosen_desc->text.id_source % ed->table_parts_size]; else ep->text.source = NULL; if (chosen_desc->text.id_text_source >= 0) ep->text.text_source = ed->table_parts[chosen_desc->text.id_text_source % ed->table_parts_size]; else ep->text.text_source = NULL; if (ep->text.text_source) text = edje_string_get(&(((Edje_Part_Description_Text*)ep->text.text_source->chosen_description)->text.text)); else text = edje_string_get(&chosen_desc->text.text); if (ep->text.source) font = _edje_text_class_font_get(ed, ((Edje_Part_Description_Text*)ep->text.source->chosen_description), &size, &sfont); else font = _edje_text_class_font_get(ed, chosen_desc, &size, &sfont); if (!font) font = ""; if (ep->text.text_source) { if (ep->text.text_source->text.text) text = ep->text.text_source->text.text; } else { if (ep->text.text) text = ep->text.text; } if (ep->text.source) { if (ep->text.source->text.font) font = ep->text.source->text.font; if (ep->text.source->text.size > 0) size = ep->text.source->text.size; } else { if (ep->text.font) font = ep->text.font; if (ep->text.size > 0) size = ep->text.size; } if (!text) text = ""; /* check if the font is embedded in the .eet */ if (ed->file->fonts) { Edje_Font_Directory_Entry *fnt; fnt = eina_hash_find(ed->file->fonts, font); if (fnt) { char *font2; size_t len = strlen(font) + sizeof("edje/fonts/") + 1; font2 = alloca(len); sprintf(font2, "edje/fonts/%s", font); font = font2; inlined_font = 1; } } if (ep->part->scale) evas_object_scale_set(ep->object, TO_DOUBLE(sc)); if (inlined_font) { evas_object_text_font_source_set(ep->object, ed->path); } else evas_object_text_font_source_set(ep->object, NULL); if ((_edje_fontset_append) && (font)) { char *font2; font2 = malloc(strlen(font) + 1 + strlen(_edje_fontset_append) + 1); if (font2) { strcpy(font2, font); strcat(font2, ","); strcat(font2, _edje_fontset_append); evas_object_text_font_set(ep->object, font2, size); free(font2); } } else evas_object_text_font_set(ep->object, font, size); if ((chosen_desc->text.min_x) || (chosen_desc->text.min_y) || (chosen_desc->text.max_x) || (chosen_desc->text.max_y)) { int mw, mh; Evas_Text_Style_Type style = EVAS_TEXT_STYLE_PLAIN, shadow = EVAS_TEXT_STYLE_SHADOW_DIRECTION_BOTTOM_RIGHT; const Evas_Text_Style_Type styles[] = { EVAS_TEXT_STYLE_PLAIN, EVAS_TEXT_STYLE_PLAIN, EVAS_TEXT_STYLE_OUTLINE, EVAS_TEXT_STYLE_SOFT_OUTLINE, EVAS_TEXT_STYLE_SHADOW, EVAS_TEXT_STYLE_SOFT_SHADOW, EVAS_TEXT_STYLE_OUTLINE_SHADOW, EVAS_TEXT_STYLE_OUTLINE_SOFT_SHADOW, EVAS_TEXT_STYLE_FAR_SHADOW, EVAS_TEXT_STYLE_FAR_SOFT_SHADOW, EVAS_TEXT_STYLE_GLOW }; const Evas_Text_Style_Type shadows[] = { EVAS_TEXT_STYLE_SHADOW_DIRECTION_BOTTOM_RIGHT, EVAS_TEXT_STYLE_SHADOW_DIRECTION_BOTTOM, EVAS_TEXT_STYLE_SHADOW_DIRECTION_BOTTOM_LEFT, EVAS_TEXT_STYLE_SHADOW_DIRECTION_LEFT, EVAS_TEXT_STYLE_SHADOW_DIRECTION_TOP_LEFT, EVAS_TEXT_STYLE_SHADOW_DIRECTION_TOP, EVAS_TEXT_STYLE_SHADOW_DIRECTION_TOP_RIGHT, EVAS_TEXT_STYLE_SHADOW_DIRECTION_RIGHT }; if ((ep->part->effect & EVAS_TEXT_STYLE_MASK_BASIC) < EDJE_TEXT_EFFECT_LAST) style = styles[ep->part->effect]; shadow = shadows [(ep->part->effect & EDJE_TEXT_EFFECT_MASK_SHADOW_DIRECTION) >> 4]; EVAS_TEXT_STYLE_SHADOW_DIRECTION_SET(style, shadow); eo_do(ep->object, evas_obj_text_style_set(style), evas_obj_text_text_set(text), evas_obj_size_get(&tw, &th)); if (chosen_desc->text.max_x) { int l, r; evas_object_text_style_pad_get(ep->object, &l, &r, NULL, NULL); mw = tw + l + r; if ((*maxw < 0) || (mw < *maxw)) *maxw = mw; } if (chosen_desc->text.max_y) { int t, b; evas_object_text_style_pad_get(ep->object, NULL, NULL, &t, &b); mh = th + t + b; if ((*maxh < 0) || (mh < *maxh)) *maxh = mh; } if (chosen_desc->text.min_x) { int l, r; evas_object_text_style_pad_get(ep->object, &l, &r, NULL, NULL); mw = tw + l + r; if (mw > *minw) *minw = mw; } if (chosen_desc->text.min_y) { int t, b; evas_object_text_style_pad_get(ep->object, NULL, NULL, &t, &b); mh = th + t + b; if (mh > *minh) *minh = mh; } } if (sfont) free(sfont); } /* FIXME: Do we really need to call it twice if chosen_desc ? */ sfont = NULL; _edje_text_class_font_get(ed, desc, &size, &sfont); free(sfont); params->type.text.size = size; } #endif static void _edje_part_recalc_single_min_length(FLOAT_T align, FLOAT_T *start, FLOAT_T *length, int min) { if (min >= 0) { if (*length < FROM_INT(min)) { *start = ADD(*start, (SCALE(align, (*length - min)))); *length = FROM_INT(min); } } } static void _edje_part_recalc_single_min(Edje_Part_Description_Common *desc, Edje_Calc_Params *params, int minw, int minh, Edje_Internal_Aspect aspect) { FLOAT_T tmp; FLOAT_T w; FLOAT_T h; w = params->eval.w ? params->eval.w : FROM_INT(99999); h = params->eval.h ? params->eval.h : 99999; switch (aspect) { case EDJE_ASPECT_PREFER_NONE: break; case EDJE_ASPECT_PREFER_VERTICAL: tmp = DIV(SCALE(params->eval.w, minh), h); if (tmp >= FROM_INT(minw)) { minw = TO_INT(tmp); break; } case EDJE_ASPECT_PREFER_HORIZONTAL: tmp = DIV(SCALE(params->eval.h, minw), w); if (tmp >= FROM_INT(minh)) { minh = TO_INT(tmp); break; } case EDJE_ASPECT_PREFER_SOURCE: case EDJE_ASPECT_PREFER_BOTH: tmp = DIV(SCALE(params->eval.w, minh), h); if (tmp >= FROM_INT(minw)) { minw = TO_INT(tmp); break; } tmp = DIV(SCALE(params->eval.h, minw), w); if (tmp >= FROM_INT(minh)) { minh = TO_INT(tmp); break; } break; } _edje_part_recalc_single_min_length(desc->align.x, ¶ms->eval.x, ¶ms->eval.w, minw); _edje_part_recalc_single_min_length(desc->align.y, ¶ms->eval.y, ¶ms->eval.h, minh); } static void _edje_part_recalc_single_max_length(FLOAT_T align, FLOAT_T *start, FLOAT_T *length, int max) { if (max >= 0) { if (*length > max) { *start = ADD(*start, SCALE(align, (*length - max))); *length = max; } } } static void _edje_part_recalc_single_max(Edje_Part_Description_Common *desc, Edje_Calc_Params *params, int maxw, int maxh, Edje_Internal_Aspect aspect) { FLOAT_T tmp; FLOAT_T w; FLOAT_T h; w = params->eval.w ? params->eval.w : FROM_INT(99999); h = params->eval.h ? params->eval.h : FROM_INT(99999); switch (aspect) { case EDJE_ASPECT_PREFER_NONE: break; case EDJE_ASPECT_PREFER_VERTICAL: tmp = DIV(SCALE(params->eval.w, maxh), h); if (tmp <= FROM_INT(maxw)) { maxw = TO_INT(tmp); break; } case EDJE_ASPECT_PREFER_HORIZONTAL: tmp = DIV(SCALE(params->eval.h, maxw), w); if (tmp <= FROM_INT(maxh)) { maxh = TO_INT(tmp); break; } case EDJE_ASPECT_PREFER_SOURCE: case EDJE_ASPECT_PREFER_BOTH: tmp = DIV(SCALE(params->eval.w, maxh), h); if (tmp <= FROM_INT(maxw)) { maxw = TO_INT(tmp); break; } tmp = DIV(SCALE(params->eval.h, maxw), w); if (tmp <= FROM_INT(maxh)) { maxh = TO_INT(tmp); break; } break; } _edje_part_recalc_single_max_length(desc->align.x, ¶ms->eval.x, ¶ms->eval.w, maxw); _edje_part_recalc_single_max_length(desc->align.y, ¶ms->eval.y, ¶ms->eval.h, maxh); } static void _edje_part_recalc_single_drag_threshold(Edje_Real_Part *ep, Edje_Real_Part *threshold, Edje_Calc_Params *params) { if (threshold) { if (ep->drag->threshold_started_x && threshold->x < TO_INT(params->eval.x) && TO_INT(params->eval.x) + TO_INT(params->eval.w) < threshold->x + threshold->w) { // Cancel movement to previous position due to our presence inside the threshold params->eval.x = FROM_INT(params->req_drag.x); params->eval.w = FROM_INT(params->req_drag.w); ep->drag->threshold_x = EINA_TRUE; } else { params->req_drag.x = TO_INT(params->eval.x); params->req_drag.w = TO_INT(params->eval.w); ep->drag->threshold_started_x = EINA_FALSE; } if (ep->drag->threshold_started_y && threshold->y < TO_INT(params->eval.y) && TO_INT(params->eval.y) + TO_INT(params->eval.h) < threshold->y + threshold->h) { // Cancel movement to previous position due to our presence inside the threshold params->eval.y = FROM_INT(params->req_drag.y); params->eval.h = FROM_INT(params->req_drag.h); ep->drag->threshold_y = EINA_TRUE; } else { params->req_drag.y = TO_INT(params->eval.y); params->req_drag.h = TO_INT(params->eval.h); ep->drag->threshold_started_y = EINA_FALSE; } } else { params->req_drag.x = TO_INT(params->eval.x); params->req_drag.w = TO_INT(params->eval.w); params->req_drag.y = TO_INT(params->eval.y); params->req_drag.h = TO_INT(params->eval.h); } } static void _edje_part_recalc_single_drag(Edje_Real_Part *ep, Edje_Real_Part *confine_to, Edje_Real_Part *threshold, Edje_Calc_Params *params, int minw, int minh, int maxw, int maxh) { /* confine */ if (confine_to) { int offset; int step; FLOAT_T v; /* complex dragable params */ v = SCALE(ep->drag->size.x, confine_to->w); if ((minw > 0) && (TO_INT(v) < minw)) params->eval.w = FROM_INT(minw); else if ((maxw >= 0) && (TO_INT(v) > maxw)) params->eval.w = FROM_INT(maxw); else params->eval.w = v; offset = TO_INT(SCALE(ep->drag->x, (confine_to->w - TO_INT(params->eval.w)))) + ep->drag->tmp.x; if (ep->part->dragable.step_x > 0) { params->eval.x = FROM_INT(confine_to->x + ((offset / ep->part->dragable.step_x) * ep->part->dragable.step_x)); } else if (ep->part->dragable.count_x > 0) { step = (confine_to->w - TO_INT(params->eval.w)) / ep->part->dragable.count_x; if (step < 1) step = 1; params->eval.x = FROM_INT(confine_to->x + ((offset / step) * step)); } v = SCALE(ep->drag->size.y, confine_to->h); if ((minh > 0) && (TO_INT(v) < minh)) params->eval.h = FROM_INT(minh); else if ((maxh >= 0) && (TO_INT(v) > maxh)) params->eval.h = FROM_INT(maxh); else params->eval.h = v; offset = TO_INT(SCALE(ep->drag->y, (confine_to->h - TO_INT(params->eval.h)))) + ep->drag->tmp.y; if (ep->part->dragable.step_y > 0) { params->eval.y = FROM_INT(confine_to->y + ((offset / ep->part->dragable.step_y) * ep->part->dragable.step_y)); } else if (ep->part->dragable.count_y > 0) { step = (confine_to->h - TO_INT(params->eval.h)) / ep->part->dragable.count_y; if (step < 1) step = 1; params->eval.y = FROM_INT(confine_to->y + ((offset / step) * step)); } _edje_part_recalc_single_drag_threshold(ep, threshold, params); /* limit to confine */ if (params->eval.x < FROM_INT(confine_to->x)) { params->eval.x = FROM_INT(confine_to->x); } if ((ADD(params->eval.x, params->eval.w)) > FROM_INT(confine_to->x + confine_to->w)) { params->eval.x = SUB(FROM_INT(confine_to->x + confine_to->w), params->eval.w); } if (params->eval.y < FROM_INT(confine_to->y)) { params->eval.y = FROM_INT(confine_to->y); } if ((ADD(params->eval.y, params->eval.h)) > FROM_INT(confine_to->y + confine_to->h)) { params->eval.y = SUB(FROM_INT(confine_to->y + confine_to->h), params->eval.h); } } else { /* simple dragable params */ params->eval.x = ADD(ADD(params->eval.x, ep->drag->x), FROM_INT(ep->drag->tmp.x)); params->eval.y = ADD(ADD(params->eval.y, ep->drag->y), FROM_INT(ep->drag->tmp.y)); _edje_part_recalc_single_drag_threshold(ep, threshold, params); } } static void _edje_part_recalc_single_fill(Edje_Real_Part *ep, Edje_Part_Description_Spec_Fill *fill, Edje_Calc_Params *params) { int fw; int fh; params->smooth = fill->smooth; if (fill->type == EDJE_FILL_TYPE_TILE) evas_object_image_size_get(ep->object, &fw, NULL); else fw = params->final.w; params->type.common.fill.x = fill->pos_abs_x + TO_INT(SCALE(fill->pos_rel_x, fw)); params->type.common.fill.w = fill->abs_x + TO_INT(SCALE(fill->rel_x, fw)); if (fill->type == EDJE_FILL_TYPE_TILE) evas_object_image_size_get(ep->object, NULL, &fh); else fh = params->final.h; params->type.common.fill.y = fill->pos_abs_y + TO_INT(SCALE(fill->pos_rel_y, fh)); params->type.common.fill.h = fill->abs_y + TO_INT(SCALE(fill->rel_y, fh)); params->type.common.fill.angle = fill->angle; params->type.common.fill.spread = fill->spread; } static void _edje_part_recalc_single_min_max(FLOAT_T sc, Edje *ed, Edje_Real_Part *ep, Edje_Part_Description_Common *desc, int *minw, int *minh, int *maxw, int *maxh) { *minw = desc->min.w; if (ep->part->scale) *minw = TO_INT(SCALE(sc, *minw)); if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) { if (ep->typedata.swallow->swallow_params.min.w > desc->min.w) *minw = ep->typedata.swallow->swallow_params.min.w; } if (ed->calc_only) { if (desc->minmul.have) { FLOAT_T mmw = desc->minmul.w; if (mmw != FROM_INT(1)) *minw = TO_INT(SCALE(mmw, *minw)); } } if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) { /* XXX TODO: remove need of EDJE_INF_MAX_W, see edje_util.c */ if ((ep->typedata.swallow->swallow_params.max.w <= 0) || (ep->typedata.swallow->swallow_params.max.w == EDJE_INF_MAX_W)) { *maxw = desc->max.w; if (*maxw > 0) { if (ep->part->scale) *maxw = TO_INT(SCALE(sc, *maxw)); if (*maxw < 1) *maxw = 1; } } else { if (desc->max.w <= 0) *maxw = ep->typedata.swallow->swallow_params.max.w; else { *maxw = desc->max.w; if (*maxw > 0) { if (ep->part->scale) *maxw = TO_INT(SCALE(sc, *maxw)); if (*maxw < 1) *maxw = 1; } if (ep->typedata.swallow->swallow_params.max.w < *maxw) *maxw = ep->typedata.swallow->swallow_params.max.w; } } } else { *maxw = desc->max.w; if (*maxw > 0) { if (ep->part->scale) *maxw = TO_INT(SCALE(sc, *maxw)); if (*maxw < 1) *maxw = 1; } } if ((ed->calc_only) && (desc->minmul.have) && (desc->minmul.w != FROM_INT(1))) *maxw = *minw; if (*maxw >= 0) { if (*maxw < *minw) *maxw = *minw; } *minh = desc->min.h; if (ep->part->scale) *minh = TO_INT(SCALE(sc, *minh)); if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) { if (ep->typedata.swallow->swallow_params.min.h > desc->min.h) *minh = ep->typedata.swallow->swallow_params.min.h; } if (ed->calc_only) { if (desc->minmul.have) { FLOAT_T mmh = desc->minmul.h; if (mmh != FROM_INT(1)) *minh = TO_INT(SCALE(mmh, *minh)); } } if ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) { /* XXX TODO: remove need of EDJE_INF_MAX_H, see edje_util.c */ if ((ep->typedata.swallow->swallow_params.max.h <= 0) || (ep->typedata.swallow->swallow_params.max.h == EDJE_INF_MAX_H)) { *maxh = desc->max.h; if (*maxh > 0) { if (ep->part->scale) *maxh = TO_INT(SCALE(sc, *maxh)); if (*maxh < 1) *maxh = 1; } } else { if (desc->max.h <= 0) *maxh = ep->typedata.swallow->swallow_params.max.h; else { *maxh = desc->max.h; if (*maxh > 0) { if (ep->part->scale) *maxh = TO_INT(SCALE(sc, *maxh)); if (*maxh < 1) *maxh = 1; } if (ep->typedata.swallow->swallow_params.max.h < *maxh) *maxh = ep->typedata.swallow->swallow_params.max.h; } } } else { *maxh = desc->max.h; if (*maxh > 0) { if (ep->part->scale) *maxh = TO_INT(SCALE(sc, *maxh)); if (*maxh < 1) *maxh = 1; } } if ((ed->calc_only) && (desc->minmul.have) && (desc->minmul.h != FROM_INT(1))) *maxh = *minh; if (*maxh >= 0) { if (*maxh < *minh) *maxh = *minh; } } static void _edje_part_recalc_single_map(Edje *ed, Edje_Real_Part *ep EINA_UNUSED, Edje_Real_Part *center, Edje_Real_Part *light, Edje_Real_Part *persp, Edje_Part_Description_Common *desc, Edje_Part_Description_Common *chosen_desc, Edje_Calc_Params *params) { params->mapped = chosen_desc->map.on; params->lighted = params->mapped ? !!light : 0; params->persp_on = params->mapped ? !!persp : 0; if (!params->mapped) return; EINA_COW_CALC_MAP_BEGIN(params, params_write) { if (center) { params_write->center.x = ed->x + center->x + (center->w / 2); params_write->center.y = ed->y + center->y + (center->h / 2); } else { params_write->center.x = ed->x + params->final.x + (params->final.w / 2); params_write->center.y = ed->y + params->final.y + (params->final.h / 2); } params_write->center.z = 0; params_write->rotation.x = desc->map.rot.x; params_write->rotation.y = desc->map.rot.y; params_write->rotation.z = desc->map.rot.z; if (light) { Edje_Part_Description_Common *light_desc2; FLOAT_T pos, pos2; params_write->light.x = ed->x + light->x + (light->w / 2); params_write->light.y = ed->y + light->y + (light->h / 2); pos = light->description_pos; pos2 = (pos < ZERO) ? ZERO : ((pos > FROM_INT(1)) ? FROM_INT(1) : pos); light_desc2 = light->param2 ? light->param2->description : NULL; /* take into account CURRENT state also */ if (pos != ZERO && light_desc2) { params_write->light.z = light->param1.description->persp.zplane + TO_INT(SCALE(pos, light_desc2->persp.zplane - light->param1.description->persp.zplane)); params_write->light.r = light->param1.description->color.r + TO_INT(SCALE(pos2, light_desc2->color.r - light->param1.description->color.r)); params_write->light.g = light->param1.description->color.g + TO_INT(SCALE(pos2, light_desc2->color.g - light->param1.description->color.g)); params_write->light.b = light->param1.description->color.b + TO_INT(SCALE(pos2, light_desc2->color.b - light->param1.description->color.b)); params_write->light.ar = light->param1.description->color2.r + TO_INT(SCALE(pos2, light_desc2->color2.r - light->param1.description->color2.r)); params_write->light.ag = light->param1.description->color2.g + TO_INT(SCALE(pos2, light_desc2->color2.g - light->param1.description->color2.g)); params_write->light.ab = light->param1.description->color2.b + TO_INT(SCALE(pos2, light_desc2->color2.b - light->param1.description->color2.b)); } else { params_write->light.z = light->param1.description->persp.zplane; params_write->light.r = light->param1.description->color.r; params_write->light.g = light->param1.description->color.g; params_write->light.b = light->param1.description->color.b; params_write->light.ar = light->param1.description->color2.r; params_write->light.ag = light->param1.description->color2.g; params_write->light.ab = light->param1.description->color2.b; } } if (persp) { FLOAT_T pos; params_write->persp.x = ed->x + persp->x + (persp->w / 2); params_write->persp.y = ed->y + persp->y + (persp->h / 2); pos = persp->description_pos; if (pos != 0 && persp->param2) { params_write->persp.z = persp->param1.description->persp.zplane + TO_INT(SCALE(pos, persp->param2->description->persp.zplane - persp->param1.description->persp.zplane)); params_write->persp.focal = persp->param1.description->persp.focal + TO_INT(SCALE(pos, persp->param2->description->persp.focal - persp->param1.description->persp.focal)); } else { params_write->persp.z = persp->param1.description->persp.zplane; params_write->persp.focal = persp->param1.description->persp.focal; } } params_write->colors = desc->map.colors; params_write->colors_count = desc->map.colors_count; } EINA_COW_CALC_MAP_END(params, params_write); } static void _edje_part_recalc_single(Edje *ed, Edje_Real_Part *ep, Edje_Part_Description_Common *desc, Edje_Part_Description_Common *chosen_desc, Edje_Real_Part *center, Edje_Real_Part *light, Edje_Real_Part *persp, Edje_Real_Part *rel1_to_x, Edje_Real_Part *rel1_to_y, Edje_Real_Part *rel2_to_x, Edje_Real_Part *rel2_to_y, Edje_Real_Part *confine_to, Edje_Real_Part *threshold, Edje_Calc_Params *params, Edje_Real_Part_Set *set, Evas_Coord mmw, Evas_Coord mmh, FLOAT_T pos) { Edje_Color_Class *cc = NULL; Edje_Internal_Aspect apref; int minw = 0, minh = 0, maxw = 0, maxh = 0; FLOAT_T sc; sc = ed->scale; if (sc == ZERO) sc = _edje_scale; _edje_part_recalc_single_min_max(sc, ed, ep, desc, &minw, &minh, &maxw, &maxh); if (minw < mmw) minw = mmw; if (minh < mmh) minh = mmh; /* relative coords of top left & bottom right */ _edje_part_recalc_single_rel(ed, ep, desc, rel1_to_x, rel1_to_y, rel2_to_x, rel2_to_y, params); /* aspect */ apref = _edje_part_recalc_single_aspect(ed, ep, desc, params, &minw, &minh, &maxw, &maxh, pos); /* size step */ _edje_part_recalc_single_step(desc, params); /* if we have text that wants to make the min size the text size... */ if (ep->part->type == EDJE_PART_TYPE_TEXTBLOCK) _edje_part_recalc_single_textblock(sc, ed, ep, (Edje_Part_Description_Text*) chosen_desc, params, &minw, &minh, &maxw, &maxh); else if (ep->part->type == EDJE_PART_TYPE_TEXT) _edje_part_recalc_single_text(sc, ed, ep, (Edje_Part_Description_Text*) desc, (Edje_Part_Description_Text*) chosen_desc, params, &minw, &minh, &maxw, &maxh); if ((ep->part->type == EDJE_PART_TYPE_TABLE) && (((((Edje_Part_Description_Table *)chosen_desc)->table.min.h) || (((Edje_Part_Description_Table *)chosen_desc)->table.min.v)))) { Evas_Coord lminw = 0, lminh = 0; eo_do(ep->object, evas_obj_smart_need_recalculate_set(1), evas_obj_smart_calculate(), evas_obj_size_hint_min_get(&lminw, &lminh)); if (((Edje_Part_Description_Table *)chosen_desc)->table.min.h) { if (lminw > minw) minw = lminw; } if (((Edje_Part_Description_Table *)chosen_desc)->table.min.v) { if (lminh > minh) minh = lminh; } } else if ((ep->part->type == EDJE_PART_TYPE_BOX) && ((((Edje_Part_Description_Box *)chosen_desc)->box.min.h) || (((Edje_Part_Description_Box *)chosen_desc)->box.min.v))) { Evas_Coord lminw = 0, lminh = 0; eo_do(ep->object, evas_obj_smart_need_recalculate_set(1), evas_obj_smart_calculate(), evas_obj_size_hint_min_get(&lminw, &lminh)); if (((Edje_Part_Description_Box *)chosen_desc)->box.min.h) { if (lminw > minw) minw = lminw; } if (((Edje_Part_Description_Box *)chosen_desc)->box.min.v) { if (lminh > minh) minh = lminh; } } else if ((ep->part->type == EDJE_PART_TYPE_IMAGE) && (chosen_desc->min.limit || chosen_desc->max.limit)) { Evas_Coord w, h; /* We only need pos to find the right image that would be displayed */ /* Yes, if someone set aspect preference to SOURCE and also max,min to SOURCE, it will be under efficient, but who cares at the moment. */ _edje_real_part_image_set(ed, ep, pos); evas_object_image_size_get(ep->object, &w, &h); if (chosen_desc->min.limit) { if (w > minw) minw = w; if (h > minh) minh = h; } if (chosen_desc->max.limit) { if ((maxw <= 0) || (w < maxw)) maxw = w; if ((maxh <= 0) || (h < maxh)) maxh = h; } } /* remember what our size is BEFORE we go limit it */ params->req.x = TO_INT(params->eval.x); params->req.y = TO_INT(params->eval.y); params->req.w = TO_INT(params->eval.w); params->req.h = TO_INT(params->eval.h); /* adjust for min size */ _edje_part_recalc_single_min(desc, params, minw, minh, apref); /* adjust for max size */ _edje_part_recalc_single_max(desc, params, maxw, maxh, apref); /* take care of dragable part */ if (ep->drag) _edje_part_recalc_single_drag(ep, confine_to, threshold, params, minw, minh, maxw, maxh); /* Update final size after last change to its position */ params->final.x = TO_INT(params->eval.x); params->final.y = TO_INT(params->eval.y); params->final.w = TO_INT(params->eval.w); params->final.h = TO_INT(params->eval.h); /* Adjust rounding to not loose one pixels compared to float information only when rendering to avoid infinite adjustement when doing min restricted calc */ if (ABS(params->final.x) + params->final.w < TO_INT(ADD(ABS(params->eval.x), params->eval.w))) { if (!ed->calc_only) { params->final.w += 1; } else { ep->invalidate = EINA_TRUE; } } else if (ABS(params->final.x) + params->final.w > TO_INT(ADD(ABS(params->eval.x), params->eval.w))) { if (!ed->calc_only) { params->final.w -= 1; } else { ep->invalidate = EINA_TRUE; } } if (ABS(params->final.y) + params->final.h < TO_INT(ADD(ABS(params->eval.y), params->eval.h))) { if (!ed->calc_only) { params->final.h += 1; } else { ep->invalidate = EINA_TRUE; } } else if (ABS(params->final.y) + params->final.h > TO_INT(ADD(ABS(params->eval.y), params->eval.h))) { if (!ed->calc_only) { params->final.h -= 1; } else { ep->invalidate = EINA_TRUE; } } /* fill */ if (ep->part->type == EDJE_PART_TYPE_IMAGE) _edje_part_recalc_single_fill(ep, &((Edje_Part_Description_Image *)desc)->image.fill, params); else if (ep->part->type == EDJE_PART_TYPE_PROXY) _edje_part_recalc_single_fill(ep, &((Edje_Part_Description_Proxy *)desc)->proxy.fill, params); if (ep->part->type != EDJE_PART_TYPE_SPACER) { /* colors */ if ((desc->color_class) && (*desc->color_class)) cc = _edje_color_class_find(ed, desc->color_class); if (cc) { params->color.r = (((int)cc->r + 1) * desc->color.r) >> 8; params->color.g = (((int)cc->g + 1) * desc->color.g) >> 8; params->color.b = (((int)cc->b + 1) * desc->color.b) >> 8; params->color.a = (((int)cc->a + 1) * desc->color.a) >> 8; } else { params->color.r = desc->color.r; params->color.g = desc->color.g; params->color.b = desc->color.b; params->color.a = desc->color.a; } } /* visible */ params->visible = desc->visible; switch (ep->part->type) { case EDJE_PART_TYPE_IMAGE: { Edje_Part_Description_Image *img_desc = (Edje_Part_Description_Image*) desc; /* border */ params->type.common.spec.image.l = img_desc->image.border.l; params->type.common.spec.image.r = img_desc->image.border.r; params->type.common.spec.image.t = img_desc->image.border.t; params->type.common.spec.image.b = img_desc->image.border.b; params->type.common.spec.image.border_scale_by = img_desc->image.border.scale_by; if (set && set->set) { #define SET_BORDER_DEFINED(Result, Value) Result = Value ? Value : Result; SET_BORDER_DEFINED(params->type.common.spec.image.l, set->entry->border.l); SET_BORDER_DEFINED(params->type.common.spec.image.r, set->entry->border.r); SET_BORDER_DEFINED(params->type.common.spec.image.t, set->entry->border.t); SET_BORDER_DEFINED(params->type.common.spec.image.b, set->entry->border.b); SET_BORDER_DEFINED(params->type.common.spec.image.border_scale_by, set->entry->border.scale_by); } break; } case EDJE_PART_TYPE_TEXT: case EDJE_PART_TYPE_TEXTBLOCK: { Edje_Part_Description_Text *text_desc = (Edje_Part_Description_Text*) desc; /* text.align */ params->type.text.align.x = text_desc->text.align.x; params->type.text.align.y = text_desc->text.align.y; params->type.text.elipsis = text_desc->text.elipsis; /* text colors */ if (cc) { params->type.text.color2.r = (((int)cc->r2 + 1) * text_desc->common.color2.r) >> 8; params->type.text.color2.g = (((int)cc->g2 + 1) * text_desc->common.color2.g) >> 8; params->type.text.color2.b = (((int)cc->b2 + 1) * text_desc->common.color2.b) >> 8; params->type.text.color2.a = (((int)cc->a2 + 1) * text_desc->common.color2.a) >> 8; params->type.text.color3.r = (((int)cc->r3 + 1) * text_desc->text.color3.r) >> 8; params->type.text.color3.g = (((int)cc->g3 + 1) * text_desc->text.color3.g) >> 8; params->type.text.color3.b = (((int)cc->b3 + 1) * text_desc->text.color3.b) >> 8; params->type.text.color3.a = (((int)cc->a3 + 1) * text_desc->text.color3.a) >> 8; } else { params->type.text.color2.r = text_desc->common.color2.r; params->type.text.color2.g = text_desc->common.color2.g; params->type.text.color2.b = text_desc->common.color2.b; params->type.text.color2.a = text_desc->common.color2.a; params->type.text.color3.r = text_desc->text.color3.r; params->type.text.color3.g = text_desc->text.color3.g; params->type.text.color3.b = text_desc->text.color3.b; params->type.text.color3.a = text_desc->text.color3.a; } break; } case EDJE_PART_TYPE_SPACER: case EDJE_PART_TYPE_RECTANGLE: case EDJE_PART_TYPE_BOX: case EDJE_PART_TYPE_TABLE: case EDJE_PART_TYPE_SWALLOW: case EDJE_PART_TYPE_GROUP: case EDJE_PART_TYPE_PROXY: break; case EDJE_PART_TYPE_GRADIENT: /* FIXME: THIS ONE SHOULD NEVER BE TRIGGERED. */ break; default: break; } #ifdef HAVE_EPHYSICS if (ep->part->physics_body || ep->body) { EINA_COW_CALC_PHYSICS_BEGIN(params, params_write) { params_write->mass = desc->physics.mass; params_write->restitution = desc->physics.restitution; params_write->friction = desc->physics.friction; params_write->damping.linear = desc->physics.damping.linear; params_write->damping.angular = desc->physics.damping.angular; params_write->sleep.linear = desc->physics.sleep.linear; params_write->sleep.angular = desc->physics.sleep.angular; params_write->material = desc->physics.material; params_write->density = desc->physics.density; params_write->hardness = desc->physics.hardness; params_write->ignore_part_pos = desc->physics.ignore_part_pos; params_write->light_on = desc->physics.light_on; params_write->mov_freedom.lin.x = desc->physics.mov_freedom.lin.x; params_write->mov_freedom.lin.y = desc->physics.mov_freedom.lin.y; params_write->mov_freedom.lin.z = desc->physics.mov_freedom.lin.z; params_write->mov_freedom.ang.x = desc->physics.mov_freedom.ang.x; params_write->mov_freedom.ang.y = desc->physics.mov_freedom.ang.y; params_write->mov_freedom.ang.z = desc->physics.mov_freedom.ang.z; params_write->backcull = desc->physics.backcull; params_write->z = desc->physics.z; params_write->depth = desc->physics.depth; } EINA_COW_CALC_PHYSICS_END(params, params_write); } #endif _edje_part_recalc_single_map(ed, ep, center, light, persp, desc, chosen_desc, params); } static void _edje_table_recalc_apply(Edje *ed EINA_UNUSED, Edje_Real_Part *ep, Edje_Calc_Params *p3 EINA_UNUSED, Edje_Part_Description_Table *chosen_desc) { eo_do(ep->object, evas_obj_table_homogeneous_set(chosen_desc->table.homogeneous), evas_obj_table_align_set(TO_DOUBLE(chosen_desc->table.align.x), TO_DOUBLE(chosen_desc->table.align.y)), evas_obj_table_padding_set(chosen_desc->table.padding.x, chosen_desc->table.padding.y)); if (evas_object_smart_need_recalculate_get(ep->object)) { eo_do(ep->object, evas_obj_smart_need_recalculate_set(0), evas_obj_smart_calculate()); } } static void _edje_proxy_recalc_apply(Edje *ed, Edje_Real_Part *ep, Edje_Calc_Params *p3, Edje_Part_Description_Proxy *chosen_desc, FLOAT_T pos) { Edje_Real_Part *pp; int part_id = -1; if (ep->param2 && (pos >= FROM_DOUBLE(0.5))) part_id = ((Edje_Part_Description_Proxy*) ep->param2->description)->proxy.id; else part_id = chosen_desc->proxy.id; if ((p3->type.common.fill.w == 0) || (p3->type.common.fill.h == 0) || (part_id < 0)) { evas_object_image_source_set(ep->object, NULL); return; } pp = ed->table_parts[part_id % ed->table_parts_size]; if (pp->nested_smart) /* using nested_smart for nested parts */ { evas_object_image_source_set(ep->object, pp->nested_smart); } else { switch (pp->part->type) { case EDJE_PART_TYPE_IMAGE: case EDJE_PART_TYPE_TEXT: case EDJE_PART_TYPE_TEXTBLOCK: case EDJE_PART_TYPE_RECTANGLE: case EDJE_PART_TYPE_BOX: case EDJE_PART_TYPE_TABLE: case EDJE_PART_TYPE_PROXY: evas_object_image_source_set(ep->object, pp->object); break; case EDJE_PART_TYPE_GRADIENT: /* FIXME: THIS ONE SHOULD NEVER BE TRIGGERED. */ break; case EDJE_PART_TYPE_GROUP: case EDJE_PART_TYPE_SWALLOW: case EDJE_PART_TYPE_EXTERNAL: if ((pp->type == EDJE_RP_TYPE_SWALLOW) && (pp->typedata.swallow)) { evas_object_image_source_set(ep->object, pp->typedata.swallow->swallowed_object); } break; case EDJE_PART_TYPE_SPACER: /* FIXME: detect that at compile time and prevent it */ break; } } eo_do(ep->object, evas_obj_image_fill_set(p3->type.common.fill.x, p3->type.common.fill.y, p3->type.common.fill.w, p3->type.common.fill.h), evas_obj_image_smooth_scale_set(p3->smooth), evas_obj_image_source_visible_set(chosen_desc->proxy.source_visible), evas_obj_image_source_clip_set(chosen_desc->proxy.source_clip)); } static void _edje_image_recalc_apply(Edje *ed, Edje_Real_Part *ep, Edje_Calc_Params *p3, Edje_Part_Description_Image *chosen_desc, FLOAT_T pos) { FLOAT_T sc; sc = ed->scale; if (sc == 0.0) sc = _edje_scale; eo_do(ep->object, evas_obj_image_fill_set(p3->type.common.fill.x, p3->type.common.fill.y, p3->type.common.fill.w, p3->type.common.fill.h), evas_obj_image_smooth_scale_set(p3->smooth)); if (chosen_desc->image.border.scale) { if (p3->type.common.spec.image.border_scale_by > FROM_DOUBLE(0.0)) { FLOAT_T sc2 = MUL(sc, p3->type.common.spec.image.border_scale_by); evas_object_image_border_scale_set(ep->object, TO_DOUBLE(sc2)); } else evas_object_image_border_scale_set(ep->object, TO_DOUBLE(sc)); } else { if (p3->type.common.spec.image.border_scale_by > FROM_DOUBLE(0.0)) evas_object_image_border_scale_set (ep->object, TO_DOUBLE(p3->type.common.spec.image.border_scale_by)); else evas_object_image_border_scale_set(ep->object, 1.0); } evas_object_image_border_set(ep->object, p3->type.common.spec.image.l, p3->type.common.spec.image.r, p3->type.common.spec.image.t, p3->type.common.spec.image.b); if (chosen_desc->image.border.no_fill == 0) evas_object_image_border_center_fill_set(ep->object, EVAS_BORDER_FILL_DEFAULT); else if (chosen_desc->image.border.no_fill == 1) evas_object_image_border_center_fill_set(ep->object, EVAS_BORDER_FILL_NONE); else if (chosen_desc->image.border.no_fill == 2) evas_object_image_border_center_fill_set(ep->object, EVAS_BORDER_FILL_SOLID); _edje_real_part_image_set(ed, ep, pos); } static Edje_Real_Part * _edje_real_part_state_get(Edje *ed, Edje_Real_Part *ep, int flags, int id, int *state) { Edje_Real_Part *result = NULL; if (id >= 0 && id != ep->part->id) { result = ed->table_parts[id % ed->table_parts_size]; if (result) { if (!result->calculated) _edje_part_recalc(ed, result, flags, NULL); #ifdef EDJE_CALC_CACHE if (state) *state = result->state; #else (void) state; #endif } } return result; } #ifdef HAVE_EPHYSICS static Eina_Bool _edje_physics_world_geometry_check(EPhysics_World *world) { Evas_Coord w, h, d; ephysics_world_render_geometry_get(world, NULL, NULL, NULL, &w, &h, &d); return (w && h && d); } static void _edje_physics_body_props_update(Edje *ed, Edje_Real_Part *ep, Edje_Calc_Params *pf, Eina_Bool pos_update) { ephysics_body_linear_movement_enable_set(ep->body, pf->physics->mov_freedom.lin.x, pf->physics->mov_freedom.lin.y, pf->physics->mov_freedom.lin.z); ephysics_body_angular_movement_enable_set(ep->body, pf->physics->mov_freedom.ang.x, pf->physics->mov_freedom.ang.y, pf->physics->mov_freedom.ang.z); /* Boundaries geometry and mass shouldn't be changed */ if (ep->part->physics_body < EDJE_PART_PHYSICS_BODY_BOUNDARY_TOP) { Evas_Coord x, y, z, w, h, d; if (pos_update) { ephysics_body_move(ep->body, ed->x + pf->final.x, ed->y + pf->final.y, pf->physics->z); ep->x = pf->final.x; ep->y = pf->final.y; ep->w = pf->final.w; ep->h = pf->final.h; } ephysics_body_geometry_get(ep->body, &x, &y, &z, &w, &h, &d); if ((d) && (d != pf->physics->depth)) ephysics_body_resize(ep->body, w, h, pf->physics->depth); if (z != pf->physics->z) ephysics_body_move(ep->body, x, y, pf->physics->z); ephysics_body_material_set(ep->body, pf->physics->material); if (!pf->physics->material) { if (pf->physics->density) ephysics_body_density_set(ep->body, pf->physics->density); else ephysics_body_mass_set(ep->body, pf->physics->mass); } if ((ep->part->physics_body == EDJE_PART_PHYSICS_BODY_SOFT_BOX) || (ep->part->physics_body == EDJE_PART_PHYSICS_BODY_SOFT_SPHERE) || (ep->part->physics_body == EDJE_PART_PHYSICS_BODY_SOFT_CYLINDER) || (ep->part->physics_body == EDJE_PART_PHYSICS_BODY_CLOTH)) ephysics_body_soft_body_hardness_set(ep->body, pf->physics->hardness * 100); } if (!pf->physics->material) { ephysics_body_restitution_set(ep->body, pf->physics->restitution); ephysics_body_friction_set(ep->body, pf->physics->friction); } ephysics_body_damping_set(ep->body, pf->physics->damping.linear, pf->physics->damping.angular); ephysics_body_sleeping_threshold_set(ep->body, pf->physics->sleep.linear, pf->physics->sleep.angular); ephysics_body_light_set(ep->body, pf->physics->light_on); ephysics_body_back_face_culling_set(ep->body, pf->physics->backcull); } static void _edje_physics_body_update_cb(void *data, EPhysics_Body *body, void *event_info EINA_UNUSED) { Edje_Real_Part *rp = data; Edje *ed = ephysics_body_data_get(body); ephysics_body_geometry_get(body, &(rp->x), &(rp->y), NULL, &(rp->w), &(rp->h), NULL); ephysics_body_evas_object_update(body); ed->dirty = EINA_TRUE; } static void _edje_physics_body_add(Edje *ed, Edje_Real_Part *rp, EPhysics_World *world) { Eina_Bool resize = EINA_TRUE; Edje_Physics_Face *pface; Eina_List *l; switch (rp->part->physics_body) { case EDJE_PART_PHYSICS_BODY_RIGID_BOX: rp->body = ephysics_body_box_add(world); break; case EDJE_PART_PHYSICS_BODY_RIGID_SPHERE: rp->body = ephysics_body_sphere_add(world); break; case EDJE_PART_PHYSICS_BODY_RIGID_CYLINDER: rp->body = ephysics_body_cylinder_add(world); break; case EDJE_PART_PHYSICS_BODY_SOFT_BOX: rp->body = ephysics_body_soft_box_add(world); break; case EDJE_PART_PHYSICS_BODY_SOFT_SPHERE: rp->body = ephysics_body_soft_sphere_add(world, 0); break; case EDJE_PART_PHYSICS_BODY_SOFT_CYLINDER: rp->body = ephysics_body_soft_cylinder_add(world); break; case EDJE_PART_PHYSICS_BODY_CLOTH: rp->body = ephysics_body_cloth_add(world, 0, 0); break; case EDJE_PART_PHYSICS_BODY_BOUNDARY_TOP: rp->body = ephysics_body_top_boundary_add(world); resize = EINA_FALSE; break; case EDJE_PART_PHYSICS_BODY_BOUNDARY_BOTTOM: rp->body = ephysics_body_bottom_boundary_add(world); resize = EINA_FALSE; break; case EDJE_PART_PHYSICS_BODY_BOUNDARY_RIGHT: rp->body = ephysics_body_right_boundary_add(world); resize = EINA_FALSE; break; case EDJE_PART_PHYSICS_BODY_BOUNDARY_LEFT: rp->body = ephysics_body_left_boundary_add(world); resize = EINA_FALSE; break; case EDJE_PART_PHYSICS_BODY_BOUNDARY_FRONT: rp->body = ephysics_body_front_boundary_add(world); resize = EINA_FALSE; break; case EDJE_PART_PHYSICS_BODY_BOUNDARY_BACK: rp->body = ephysics_body_back_boundary_add(world); resize = EINA_FALSE; break; default: ERR("Invalid body: %i", rp->part->physics_body); return; } EINA_LIST_FOREACH(rp->part->default_desc->physics.faces, l, pface) { Evas_Object *edje_obj; Evas *evas; if (!pface->source) continue; evas = evas_object_evas_get(rp->object); edje_obj = edje_object_add(evas); if (!edje_obj) continue; edje_object_file_set(edje_obj, ed->path, pface->source); evas_object_resize(edje_obj, 1, 1); ephysics_body_face_evas_object_set(rp->body, pface->type, edje_obj, EINA_FALSE); rp->body_faces = eina_list_append(rp->body_faces, edje_obj); } ephysics_body_evas_object_set(rp->body, rp->object, resize); ephysics_body_event_callback_add(rp->body, EPHYSICS_CALLBACK_BODY_UPDATE, _edje_physics_body_update_cb, rp); ephysics_body_data_set(rp->body, ed); } #endif #define FINTP(_x1, _x2, _p) \ (((_x1) == (_x2)) \ ? FROM_INT((_x1)) \ : ADD(FROM_INT(_x1), \ SCALE((_p), (_x2) - (_x1)))) #define FFP(_x1, _x2, _p) \ (((_x1) == (_x2)) \ ? (_x1) \ : ADD(_x1, MUL(_p, SUB(_x2, _x1)))); #define INTP(_x1, _x2, _p) TO_INT(FINTP(_x1, _x2, _p)) static void _map_colors_free(Edje_Calc_Params *pf) { Edje_Map_Color **colors = pf->map->colors; int i; for (i = 0; i < (int) pf->map->colors_count; i++) free(colors[i]); free (colors); } static Eina_Bool _map_colors_interp(Edje_Calc_Params *p1, Edje_Calc_Params *p2, Edje_Calc_Params_Map *pmap, FLOAT_T pos) { Edje_Map_Color *col, *col2, *col3; int i, j, idx = 0; Eina_Bool matched = EINA_FALSE; if ((p1->map->colors_count > 0) || (p2->map->colors_count > 0)) { pmap->colors_count = (p1->map->colors_count > p2->map->colors_count ? p1->map->colors_count : p2->map->colors_count); pmap->colors = (Edje_Map_Color **) malloc(sizeof(Edje_Map_Color *) * (int) pmap->colors_count); for (i = 0; i < (int)p1->map->colors_count; i++) { col = p1->map->colors[i]; col3 = malloc(sizeof(Edje_Map_Color)); col3->idx = col->idx; for (j = 0; j < (int)p2->map->colors_count; j++) { col2 = p2->map->colors[j]; if (col->idx != col2->idx) continue; col3->r = INTP(col->r, col2->r, pos); col3->g = INTP(col->g, col2->g, pos); col3->b = INTP(col->b, col2->b, pos); col3->a = INTP(col->a, col2->a, pos); pmap->colors[idx] = col3; matched = EINA_TRUE; break; } if (!matched) { col3->r = INTP(col->r, 255, pos); col3->g = INTP(col->g, 255, pos); col3->b = INTP(col->b, 255, pos); col3->a = INTP(col->a, 255, pos); pmap->colors[idx] = col3; } idx++; matched = EINA_FALSE; } for (i = 0; i < (int)p2->map->colors_count; i++) { col = p2->map->colors[i]; for (j = 0; j < (int)p1->map->colors_count; j++) { col2 = p1->map->colors[j]; if (col->idx != col2->idx) continue; matched = EINA_TRUE; break; } if (!matched) { col3 = malloc(sizeof(Edje_Map_Color)); col3->idx = col->idx; col3->r = INTP(255, col->r, pos); col3->g = INTP(255, col->g, pos); col3->b = INTP(255, col->b, pos); col3->a = INTP(255, col->a, pos); pmap->colors[idx] = col3; } idx++; matched = EINA_FALSE; } return EINA_TRUE; } return EINA_FALSE; } static void _edje_map_prop_set(Evas_Map *map, const Edje_Calc_Params *pf, Edje_Part_Description_Common *chosen_desc, Edje_Real_Part *ep, Evas_Object *mo) { Edje_Map_Color **colors = pf->map->colors; int colors_cnt = pf->map->colors_count; int i; Edje_Map_Color *color; evas_map_util_points_populate_from_object(map, ep->object); if (ep->part->type == EDJE_PART_TYPE_IMAGE || ((ep->part->type == EDJE_PART_TYPE_SWALLOW) && (eo_isa(mo, EVAS_OBJ_IMAGE_CLASS) && (!evas_object_image_source_get(mo)))) ) { int iw = 1, ih = 1; evas_object_image_size_get(mo, &iw, &ih); evas_map_point_image_uv_set(map, 0, 0.0, 0.0); evas_map_point_image_uv_set(map, 1, iw , 0.0); evas_map_point_image_uv_set(map, 2, iw , ih ); evas_map_point_image_uv_set(map, 3, 0.0, ih ); } //map color if (colors_cnt == 0) { evas_map_point_color_set(map, 0, 255, 255, 255, 255); evas_map_point_color_set(map, 1, 255, 255, 255, 255); evas_map_point_color_set(map, 2, 255, 255, 255, 255); evas_map_point_color_set(map, 3, 255, 255, 255, 255); } else { for (i = 0; i < colors_cnt; i++) { color = colors[i]; evas_map_point_color_set(map, color->idx, color->r, color->g, color->b, color->a); } } //rotate evas_map_util_3d_rotate(map, TO_DOUBLE(pf->map->rotation.x), TO_DOUBLE(pf->map->rotation.y), TO_DOUBLE(pf->map->rotation.z), pf->map->center.x, pf->map->center.y, pf->map->center.z); // calculate light color & position etc. if there is one if (pf->lighted) { evas_map_util_3d_lighting(map, pf->map->light.x, pf->map->light.y, pf->map->light.z, pf->map->light.r, pf->map->light.g, pf->map->light.b, pf->map->light.ar, pf->map->light.ag, pf->map->light.ab); } // calculate perspective point if (chosen_desc->map.persp_on) { evas_map_util_3d_perspective(map, pf->map->persp.x, pf->map->persp.y, pf->map->persp.z, pf->map->persp.focal); } // handle backface culling (object is facing away from view if (chosen_desc->map.backcull) { if (pf->visible) { if (evas_map_util_clockwise_get(map)) evas_object_show(mo); else evas_object_hide(mo); } } // handle smooth if (chosen_desc->map.smooth) evas_map_smooth_set(map, EINA_TRUE); else evas_map_smooth_set(map, EINA_FALSE); // handle alpha if (chosen_desc->map.alpha) evas_map_alpha_set(map, EINA_TRUE); else evas_map_alpha_set(map, EINA_FALSE); } #define Rel1X 0 #define Rel1Y 1 #define Rel2X 2 #define Rel2Y 3 void _edje_part_recalc(Edje *ed, Edje_Real_Part *ep, int flags, Edje_Calc_Params *state) { #ifdef EDJE_CALC_CACHE Eina_Bool proxy_invalidate = EINA_FALSE; int state1 = -1; int state2 = -1; int statec = -1; int statet = -1; #else Edje_Calc_Params lp1, lp2; #endif int statec1 = -1; int statec2 = -1; int statel1 = -1; int statel2 = -1; int statep1 = -1; int statep2 = -1; Edje_Real_Part *center[2] = { NULL, NULL }; Edje_Real_Part *light[2] = { NULL, NULL }; Edje_Real_Part *persp[2] = { NULL, NULL }; Edje_Real_Part *rp1[4] = { NULL, NULL, NULL, NULL }; Edje_Real_Part *rp2[4] = { NULL, NULL, NULL, NULL }; Edje_Calc_Params *p1, *pf; Edje_Part_Description_Common *chosen_desc; Edje_Real_Part *confine_to = NULL; Edje_Real_Part *threshold = NULL; FLOAT_T pos = ZERO, pos2; Edje_Calc_Params lp3; Evas_Coord mmw = 0, mmh = 0; Eina_Bool map_colors_free = EINA_FALSE; /* GRADIENT ARE GONE, WE MUST IGNORE IT FROM OLD FILE. */ if (ep->part->type == EDJE_PART_TYPE_GRADIENT) { ERR("GRADIENT spotted during recalc ! That should never happen ! Send your edje file to devel ml."); return; } if ((ep->calculated & FLAG_XY) == FLAG_XY && !state) { return; } if (ep->calculating & flags) { #if 1 const char *axes = "NONE", *faxes = "NONE"; if ((ep->calculating & FLAG_X) && (ep->calculating & FLAG_Y)) axes = "XY"; else if ((ep->calculating & FLAG_X)) axes = "X"; else if ((ep->calculating & FLAG_Y)) axes = "Y"; if ((flags & FLAG_X) && (flags & FLAG_Y)) faxes = "XY"; else if ((flags & FLAG_X)) faxes = "X"; else if ((flags & FLAG_Y)) faxes = "Y"; ERR("Circular dependency when calculating part \"%s\". " "Already calculating %s [%02x] axes. " "Need to calculate %s [%02x] axes", ep->part->name, axes, ep->calculating, faxes, flags); #endif return; } if (ep->part->type == EDJE_PART_TYPE_GROUP && ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) && ep->typedata.swallow->swallowed_object) { edje_object_scale_set(ep->typedata.swallow->swallowed_object, TO_DOUBLE(ed->scale)); if (ep->description_pos > FROM_DOUBLE(0.5) && ep->param2) { edje_object_update_hints_set(ep->typedata.swallow->swallowed_object, ep->param2->description->min.limit); } else { edje_object_update_hints_set(ep->typedata.swallow->swallowed_object, ep->param1.description->min.limit); } if (edje_object_update_hints_get(ep->typedata.swallow->swallowed_object)) { Edje *ted; ted = _edje_fetch(ep->typedata.swallow->swallowed_object); _edje_recalc_do(ted); } } if (ep->part->type == EDJE_PART_TYPE_GROUP && ((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) && ep->typedata.swallow->swallowed_object) { edje_object_size_min_calc(ep->typedata.swallow->swallowed_object, &mmw, &mmh); } #ifdef EDJE_CALC_CACHE if (ep->state == ed->state && !state) return; #endif if (ep->param1.description->rel1.id_x >= 0) rp1[Rel1X] = ed->table_parts[ep->param1.description->rel1.id_x]; if (ep->param1.description->rel2.id_x >= 0) rp1[Rel2X] = ed->table_parts[ep->param1.description->rel2.id_x]; if (ep->param1.description->rel1.id_y >= 0) rp1[Rel1Y] = ed->table_parts[ep->param1.description->rel1.id_y]; if (ep->param1.description->rel2.id_y >= 0) rp1[Rel2Y] = ed->table_parts[ep->param1.description->rel2.id_y]; if (ep->param2) { if (ep->param2->description->rel1.id_x >= 0) rp2[Rel1X] = ed->table_parts[ep->param2->description->rel1.id_x]; if (ep->param2->description->rel2.id_x >= 0) rp2[Rel2X] = ed->table_parts[ep->param2->description->rel2.id_x]; if (ep->param2->description->rel1.id_y >= 0) rp2[Rel1Y] = ed->table_parts[ep->param2->description->rel1.id_y]; if (ep->param2->description->rel2.id_y >= 0) rp2[Rel2Y] = ed->table_parts[ep->param2->description->rel2.id_y]; } if (flags & FLAG_X) { ep->calculating |= flags & FLAG_X; if (rp1[Rel1X]) { _edje_part_recalc(ed, rp1[Rel1X], FLAG_X, NULL); #ifdef EDJE_CALC_CACHE state1 = rp1[Rel1X]->state; #endif } if (rp1[Rel2X]) { _edje_part_recalc(ed, rp1[Rel2X], FLAG_X, NULL); #ifdef EDJE_CALC_CACHE if (state1 < rp1[Rel2X]->state) state1 = rp1[Rel2X]->state; #endif } if (ep->param2) { if (rp2[Rel1X]) { _edje_part_recalc(ed, rp2[Rel1X], FLAG_X, NULL); #ifdef EDJE_CALC_CACHE state2 = rp2[Rel1X]->state; #endif } if (rp2[Rel2X]) { _edje_part_recalc(ed, rp2[Rel2X], FLAG_X, NULL); #ifdef EDJE_CALC_CACHE if (state2 < rp2[Rel2X]->state) state2 = rp2[Rel2X]->state; #endif } } } if (flags & FLAG_Y) { ep->calculating |= flags & FLAG_Y; if (rp1[Rel1Y]) { _edje_part_recalc(ed, rp1[Rel1Y], FLAG_Y, NULL); #ifdef EDJE_CALC_CACHE if (state1 < rp1[Rel1Y]->state) state1 = rp1[Rel1Y]->state; #endif } if (rp1[Rel2Y]) { _edje_part_recalc(ed, rp1[Rel2Y], FLAG_Y, NULL); #ifdef EDJE_CALC_CACHE if (state1 < rp1[Rel2Y]->state) state1 = rp1[Rel2Y]->state; #endif } if (ep->param2) { if (rp2[Rel1Y]) { _edje_part_recalc(ed, rp2[Rel1Y], FLAG_Y, NULL); #ifdef EDJE_CALC_CACHE if (state2 < rp2[Rel1Y]->state) state2 = rp2[Rel1Y]->state; #endif } if (rp2[Rel2Y]) { _edje_part_recalc(ed, rp2[Rel2Y], FLAG_Y, NULL); #ifdef EDJE_CALC_CACHE if (state2 < rp2[Rel2Y]->state) state2 = rp2[Rel2Y]->state; #endif } } } if (ep->drag) { if (ep->drag->confine_to) { confine_to = ep->drag->confine_to; _edje_part_recalc(ed, confine_to, flags, NULL); #ifdef EDJE_CALC_CACHE statec = confine_to->state; #endif } if (ep->drag->threshold) { threshold = ep->drag->threshold; // We shall not recalculate the threshold position as // we use it's previous position to assert the threshold // the one before moving take action. #ifdef EDJE_CALC_CACHE statet = threshold->state; #endif } } // if (ep->text.source) _edje_part_recalc(ed, ep->text.source, flags); // if (ep->text.text_source) _edje_part_recalc(ed, ep->text.text_source, flags); /* actually calculate now */ chosen_desc = ep->chosen_description; if (!chosen_desc) { ep->calculating = FLAG_NONE; ep->calculated |= flags; return; } pos = ep->description_pos; if (ep->part->type == EDJE_PART_TYPE_PROXY) { int part_id = -1; if (ep->param2 && (pos >= FROM_DOUBLE(0.5))) part_id = ((Edje_Part_Description_Proxy*) ep->param2->description)->proxy.id; else part_id = ((Edje_Part_Description_Proxy*) chosen_desc)->proxy.id; #ifdef EDJE_CALC_CACHE Edje_Real_Part *pp; pp = _edje_real_part_state_get(ed, ep, flags, part_id, NULL); if (pp && pp->invalidate) proxy_invalidate = EINA_TRUE; #else _edje_real_part_state_get(ed, ep, flags, part_id, NULL); #endif } /* Recalc if needed the map center && light source */ if (ep->param1.description->map.on) { center[0] = _edje_real_part_state_get(ed, ep, flags, ep->param1.description->map.rot.id_center, &statec1); light[0] = _edje_real_part_state_get(ed, ep, flags, ep->param1.description->map.id_light, &statel1); if (chosen_desc->map.persp_on) { persp[0] = _edje_real_part_state_get(ed, ep, flags, ep->param1.description->map.id_persp, &statep1); } } if (ep->param2 && ep->param2->description->map.on) { center[1] = _edje_real_part_state_get(ed, ep, flags, ep->param2->description->map.rot.id_center, &statec2); light[1] = _edje_real_part_state_get(ed, ep, flags, ep->param2->description->map.id_light, &statel2); if (chosen_desc->map.persp_on) { persp[1] = _edje_real_part_state_get(ed, ep, flags, ep->param2->description->map.id_persp, &statep2); } } #ifndef EDJE_CALC_CACHE p1 = &lp1; p1.map = eina_cow_alloc(_edje_calc_params_map_cow); #ifdef HAVE_EPHYSICS p1.physics = eina_cow_alloc(_edje_calc_params_physics_cow); #endif #else p1 = &ep->param1.p; #endif if (ep->param1.description) { #ifdef EDJE_CALC_CACHE if (ed->all_part_change || ep->invalidate || (state1 >= ep->param1.state) || (statec >= ep->param1.state) || (statet >= ep->param1.state) || (statec1 >= ep->param1.state) || (statel1 >= ep->param1.state) || (statep1 >= ep->param1.state) || proxy_invalidate || state || (ep->map_on && ed->have_mapped_part) || ((ep->part->type == EDJE_PART_TYPE_TEXT || ep->part->type == EDJE_PART_TYPE_TEXTBLOCK) && ed->text_part_change)) #endif { _edje_part_recalc_single(ed, ep, ep->param1.description, chosen_desc, center[0], light[0], persp[0], rp1[Rel1X], rp1[Rel1Y], rp1[Rel2X], rp1[Rel2Y], confine_to, threshold, p1, ep->param1.set, mmw, mmh, pos); #ifdef EDJE_CALC_CACHE if (flags == FLAG_XY) ep->param1.state = ed->state; #endif } } if (ep->param2) { int beginning_pos, part_type; Edje_Calc_Params *p2, *p3; if (ep->current) { const Edje_Calc_Params_Map *map; #ifdef HAVE_EPHYSICS const Edje_Calc_Params_Physics *physics; #endif map = p1->map; #ifdef HAVE_EPHYSICS physics = p1->physics; #endif /* FIXME: except for text, we don't need in that case to recalc p1 at all*/ memcpy(p1, ep->current, sizeof (Edje_Calc_Params)); p1->map = map; #ifdef HAVE_EPHYSICS p1->physics = physics; #endif } p3 = &lp3; lp3.map = eina_cow_alloc(_edje_calc_params_map_cow); #ifdef HAVE_EPHYSICS lp3.physics = eina_cow_alloc(_edje_calc_params_physics_cow); #endif #ifndef EDJE_CALC_CACHE p2 = &lp2; lp2.map = eina_cow_alloc(_edje_calc_params_map_cow); #ifdef HAVE_EPHYSICS lp2.physics = eina_cow_alloc(_edje_calc_params_physics_cow); #endif #else p2 = &ep->param2->p; if (ed->all_part_change || ep->invalidate || (state2 >= ep->param2->state) || (statec >= ep->param2->state) || (statet >= ep->param2->state) || (statec2 >= ep->param2->state) || (statel2 >= ep->param2->state) || (statep2 >= ep->param2->state) || proxy_invalidate || state || (ep->map_on && ed->have_mapped_part) || ((ep->part->type == EDJE_PART_TYPE_TEXT || ep->part->type == EDJE_PART_TYPE_TEXTBLOCK) && ed->text_part_change)) #endif { _edje_part_recalc_single(ed, ep, ep->param2->description, chosen_desc, center[1], light[1], persp[1], rp2[Rel1X], rp2[Rel1Y], rp2[Rel2X], rp2[Rel2Y], confine_to, threshold, p2, ep->param2->set, mmw, mmh, pos); #ifdef EDJE_CALC_CACHE if (flags == FLAG_XY) ep->param2->state = ed->state; #endif } pos2 = pos; if (pos2 < ZERO) pos2 = ZERO; else if (pos2 > FROM_INT(1)) pos2 = FROM_INT(1); beginning_pos = (pos < FROM_DOUBLE(0.5)); part_type = ep->part->type; /* visible is special */ if ((p1->visible) && (!p2->visible)) p3->visible = (pos != FROM_INT(1)); else if ((!p1->visible) && (p2->visible)) p3->visible = (pos != ZERO); else p3->visible = p1->visible; p3->smooth = (beginning_pos) ? p1->smooth : p2->smooth; /* FIXME: do x and y separately base on flag */ p3->final.x = INTP(p1->final.x, p2->final.x, pos); p3->final.y = INTP(p1->final.y, p2->final.y, pos); p3->final.w = INTP(p1->final.w, p2->final.w, pos); p3->final.h = INTP(p1->final.h, p2->final.h, pos); p3->eval.x = FFP(p1->eval.x, p2->eval.x, pos); p3->eval.y = FFP(p1->eval.y, p2->eval.y, pos); p3->eval.w = FFP(p1->eval.w, p2->eval.w, pos); p3->eval.h = FFP(p1->eval.h, p2->eval.h, pos); p3->req.x = INTP(p1->req.x, p2->req.x, pos); p3->req.y = INTP(p1->req.y, p2->req.y, pos); p3->req.w = INTP(p1->req.w, p2->req.w, pos); p3->req.h = INTP(p1->req.h, p2->req.h, pos); if (ep->part->dragable.x) { p3->req_drag.x = INTP(p1->req_drag.x, p2->req_drag.x, pos); p3->req_drag.w = INTP(p1->req_drag.w, p2->req_drag.w, pos); } if (ep->part->dragable.y) { p3->req_drag.y = INTP(p1->req_drag.y, p2->req_drag.y, pos); p3->req_drag.h = INTP(p1->req_drag.h, p2->req_drag.h, pos); } p3->color.r = INTP(p1->color.r, p2->color.r, pos2); p3->color.g = INTP(p1->color.g, p2->color.g, pos2); p3->color.b = INTP(p1->color.b, p2->color.b, pos2); p3->color.a = INTP(p1->color.a, p2->color.a, pos2); #ifdef HAVE_EPHYSICS if (ep->part->physics_body || ep->body) { EINA_COW_CALC_PHYSICS_BEGIN(p3, p3_write) { p3_write->mass = TO_DOUBLE(FINTP(p1->physics->mass, p2->physics->mass, pos)); p3_write->restitution = TO_DOUBLE(FINTP(p1->physics->restitution, p2->physics->restitution, pos)); p3_write->friction = TO_DOUBLE(FINTP(p1->physics->friction, p2->physics->friction, pos)); p3_write->density = TO_DOUBLE(FINTP(p1->physics->density, p2->physics->density, pos)); p3_write->hardness = TO_DOUBLE(FINTP(p1->physics->hardness, p2->physics->hardness, pos)); p3_write->damping.linear = TO_DOUBLE(FINTP(p1->physics->damping.linear, p2->physics->damping.linear, pos)); p3_write->damping.angular = TO_DOUBLE(FINTP(p1->physics->damping.angular, p2->physics->damping.angular, pos)); p3_write->sleep.linear = TO_DOUBLE(FINTP(p1->physics->sleep.linear, p2->physics->sleep.linear, pos)); p3_write->sleep.angular = TO_DOUBLE(FINTP(p1->physics->sleep.angular, p2->physics->sleep.angular, pos)); p3_write->z = INTP(p1->physics->z, p2->physics->z, pos); p3_write->depth = INTP(p1->physics->depth, p2->physics->depth, pos); if ((p1->physics->ignore_part_pos) && (p2->physics->ignore_part_pos)) p3_write->ignore_part_pos = 1; else p3_write->ignore_part_pos = 0; if ((p1->physics->material) && (p2->physics->material)) p3_write->material = p1->physics->material; else p3_write->material = EPHYSICS_BODY_MATERIAL_CUSTOM; p3_write->light_on = p1->physics->light_on || p2->physics->light_on; p3_write->backcull = p1->physics->backcull || p2->physics->backcull; p3_write->mov_freedom.lin.x = p1->physics->mov_freedom.lin.x || p2->physics->mov_freedom.lin.x; p3_write->mov_freedom.lin.y = p1->physics->mov_freedom.lin.y || p2->physics->mov_freedom.lin.y; p3_write->mov_freedom.lin.z = p1->physics->mov_freedom.lin.z || p2->physics->mov_freedom.lin.z; p3_write->mov_freedom.ang.x = p1->physics->mov_freedom.ang.x || p2->physics->mov_freedom.ang.x; p3_write->mov_freedom.ang.y = p1->physics->mov_freedom.ang.y || p2->physics->mov_freedom.ang.y; p3_write->mov_freedom.ang.z = p1->physics->mov_freedom.ang.z || p2->physics->mov_freedom.ang.z; } EINA_COW_CALC_PHYSICS_END(p3, p3_write); } #endif switch (part_type) { case EDJE_PART_TYPE_IMAGE: p3->type.common.spec.image.l = INTP(p1->type.common.spec.image.l, p2->type.common.spec.image.l, pos); p3->type.common.spec.image.r = INTP(p1->type.common.spec.image.r, p2->type.common.spec.image.r, pos); p3->type.common.spec.image.t = INTP(p1->type.common.spec.image.t, p2->type.common.spec.image.t, pos); p3->type.common.spec.image.b = INTP(p1->type.common.spec.image.b, p2->type.common.spec.image.b, pos); p3->type.common.spec.image.border_scale_by = FFP(p1->type.common.spec.image.border_scale_by, p2->type.common.spec.image.border_scale_by, pos); case EDJE_PART_TYPE_PROXY: p3->type.common.fill.x = INTP(p1->type.common.fill.x, p2->type.common.fill.x, pos); p3->type.common.fill.y = INTP(p1->type.common.fill.y, p2->type.common.fill.y, pos); p3->type.common.fill.w = INTP(p1->type.common.fill.w, p2->type.common.fill.w, pos); p3->type.common.fill.h = INTP(p1->type.common.fill.h, p2->type.common.fill.h, pos); break; case EDJE_PART_TYPE_TEXT: p3->type.text.size = INTP(p1->type.text.size, p2->type.text.size, pos); case EDJE_PART_TYPE_TEXTBLOCK: p3->type.text.color2.r = INTP(p1->type.text.color2.r, p2->type.text.color2.r, pos2); p3->type.text.color2.g = INTP(p1->type.text.color2.g, p2->type.text.color2.g, pos2); p3->type.text.color2.b = INTP(p1->type.text.color2.b, p2->type.text.color2.b, pos2); p3->type.text.color2.a = INTP(p1->type.text.color2.a, p2->type.text.color2.a, pos2); p3->type.text.color3.r = INTP(p1->type.text.color3.r, p2->type.text.color3.r, pos2); p3->type.text.color3.g = INTP(p1->type.text.color3.g, p2->type.text.color3.g, pos2); p3->type.text.color3.b = INTP(p1->type.text.color3.b, p2->type.text.color3.b, pos2); p3->type.text.color3.a = INTP(p1->type.text.color3.a, p2->type.text.color3.a, pos2); p3->type.text.align.x = FFP(p1->type.text.align.x, p2->type.text.align.x, pos); p3->type.text.align.y = FFP(p1->type.text.align.y, p2->type.text.align.y, pos); p3->type.text.elipsis = TO_DOUBLE(FINTP(p1->type.text.elipsis, p2->type.text.elipsis, pos2)); break; } p3->mapped = p1->mapped; p3->persp_on = p3->mapped ? p1->persp_on | p2->persp_on : 0; p3->lighted = p3->mapped ? p1->lighted | p2->lighted : 0; if (p1->mapped) { EINA_COW_CALC_MAP_BEGIN(p3, p3_write) { p3_write->center.x = INTP(p1->map->center.x, p2->map->center.x, pos); p3_write->center.y = INTP(p1->map->center.y, p2->map->center.y, pos); p3_write->center.z = INTP(p1->map->center.z, p2->map->center.z, pos); p3_write->rotation.x = FFP(p1->map->rotation.x, p2->map->rotation.x, pos); p3_write->rotation.y = FFP(p1->map->rotation.y, p2->map->rotation.y, pos); p3_write->rotation.z = FFP(p1->map->rotation.z, p2->map->rotation.z, pos); #define MIX(P1, P2, P3, pos, info) \ P3->info = P1->map->info + TO_INT(SCALE(pos, P2->map->info - P1->map->info)); map_colors_free = _map_colors_interp(p1, p2, p3_write, pos); if (p1->lighted && p2->lighted) { MIX(p1, p2, p3_write, pos, light.x); MIX(p1, p2, p3_write, pos, light.y); MIX(p1, p2, p3_write, pos, light.z); MIX(p1, p2, p3_write, pos, light.r); MIX(p1, p2, p3_write, pos, light.g); MIX(p1, p2, p3_write, pos, light.b); MIX(p1, p2, p3_write, pos, light.ar); MIX(p1, p2, p3_write, pos, light.ag); MIX(p1, p2, p3_write, pos, light.ab); } else if (p1->lighted) { memcpy(&p3_write->light, &p1->map->light, sizeof (p1->map->light)); } else if (p2->lighted) { memcpy(&p3_write->light, &p2->map->light, sizeof (p2->map->light)); } if (p1->persp_on && p2->persp_on) { MIX(p1, p2, p3_write, pos, persp.x); MIX(p1, p2, p3_write, pos, persp.y); MIX(p1, p2, p3_write, pos, persp.z); MIX(p1, p2, p3_write, pos, persp.focal); } else if (p1->persp_on) { memcpy(&p3_write->persp, &p1->map->persp, sizeof (p1->map->persp)); } else if (p2->persp_on) { memcpy(&p3_write->persp, &p2->map->persp, sizeof (p2->map->persp)); } } EINA_COW_CALC_MAP_END(p3, p3_write); } #ifndef EDJE_CALC_CACHE eina_cow_free(_edje_calc_params_map_cow, (const Eina_Cow_Data **) &lp2.map); #ifdef HAVE_EPHYSICS eina_cow_free(_edje_calc_params_physics_cow, (const Eina_Cow_Data **) &lp2.physics); #endif #endif pf = p3; } else { pf = p1; } if (!pf->persp_on && chosen_desc->map.persp_on) { if (ed->persp) { EINA_COW_CALC_MAP_BEGIN(pf, pf_write) { pf_write->persp.x = ed->persp->px; pf_write->persp.y = ed->persp->py; pf_write->persp.z = ed->persp->z0; pf_write->persp.focal = ed->persp->foc; } EINA_COW_CALC_MAP_END(pf, pf_write); } else { const Edje_Perspective *ps; // fixme: a tad inefficient as this is a has lookup ps = edje_object_perspective_get(ed->obj); if (!ps) ps = edje_evas_global_perspective_get(evas_object_evas_get(ed->obj)); EINA_COW_CALC_MAP_BEGIN(pf, pf_write) { if (ps) { pf_write->persp.x = ps->px; pf_write->persp.y = ps->py; pf_write->persp.z = ps->z0; pf_write->persp.focal = ps->foc; } else { pf_write->persp.x = ed->x + (ed->w / 2); pf_write->persp.y = ed->y + (ed->h / 2); pf_write->persp.z = 0; pf_write->persp.focal = 1000; } } EINA_COW_CALC_MAP_END(pf, pf_write); } } if (state) { const Edje_Calc_Params_Map *map; #ifdef HAVE_EPHYSICS const Edje_Calc_Params_Physics *physics; #endif map = state->map; #ifdef HAVE_EPHYSICS physics = state->physics; #endif memcpy(state, pf, sizeof (Edje_Calc_Params)); state->map = map; #ifdef HAVE_EPHYSICS state->physics = physics; #endif eina_cow_memcpy(_edje_calc_params_map_cow, (const Eina_Cow_Data **) &state->map, pf->map); #ifdef HAVE_EPHYSICS eina_cow_memcpy(_edje_calc_params_physics_cow, (const Eina_Cow_Data **) &state->physics, pf->physics); #endif } ep->req = pf->req; if (ep->drag && ep->drag->need_reset) { FLOAT_T dx, dy; dx = ZERO; dy = ZERO; _edje_part_dragable_calc(ed, ep, &dx, &dy); ep->drag->x = dx; ep->drag->y = dy; ep->drag->tmp.x = 0; ep->drag->tmp.y = 0; ep->drag->need_reset = 0; } if (!ed->calc_only) { Evas_Object *mo; /* Common move, resize and color_set for all part. */ switch (ep->part->type) { case EDJE_PART_TYPE_IMAGE: { Edje_Part_Description_Image *img_desc = (Edje_Part_Description_Image*) chosen_desc; evas_object_image_scale_hint_set(ep->object, img_desc->image.scale_hint); } case EDJE_PART_TYPE_PROXY: case EDJE_PART_TYPE_RECTANGLE: case EDJE_PART_TYPE_TEXTBLOCK: case EDJE_PART_TYPE_BOX: case EDJE_PART_TYPE_TABLE: evas_object_color_set(ep->object, (pf->color.r * pf->color.a) / 255, (pf->color.g * pf->color.a) / 255, (pf->color.b * pf->color.a) / 255, pf->color.a); #ifdef HAVE_EPHYSICS /* body attributes should be updated for invisible objects */ if (!ep->part->physics_body) { if (!pf->visible) { evas_object_hide(ep->object); break; } evas_object_show(ep->object); } else if (!pf->visible) { Evas_Object *face_obj; Eina_List *l; EINA_LIST_FOREACH(ep->body_faces, l, face_obj) evas_object_hide(face_obj); evas_object_hide(ep->object); } #else if (!pf->visible) { evas_object_hide(ep->object); break; } evas_object_show(ep->object); #endif /* move and resize are needed for all previous object => no break here. */ case EDJE_PART_TYPE_SWALLOW: case EDJE_PART_TYPE_GROUP: case EDJE_PART_TYPE_EXTERNAL: /* visibility and color have no meaning on SWALLOW and GROUP part. */ #ifdef HAVE_EPHYSICS eo_do(ep->object, evas_obj_size_set(pf->final.w, pf->final.h)); if ((ep->part->physics_body) && (!ep->body)) { if (_edje_physics_world_geometry_check(ed->world)) { _edje_physics_body_add(ed, ep, ed->world); _edje_physics_body_props_update(ed, ep, pf, EINA_TRUE); } } else if (ep->body) { if (((ep->prev_description) && (chosen_desc != ep->prev_description)) || (pf != p1)) _edje_physics_body_props_update(ed, ep, pf, !pf->physics->ignore_part_pos); } else eo_do(ep->object, evas_obj_position_set(ed->x + pf->final.x, ed->y + pf->final.y)); #else eo_do(ep->object, evas_obj_position_set(ed->x + pf->final.x, ed->y + pf->final.y), evas_obj_size_set(pf->final.w, pf->final.h)); #endif if (ep->nested_smart) { /* Move, Resize all nested parts */ /* Not really needed but will improve the bounding box evaluation done by Evas */ eo_do(ep->nested_smart, evas_obj_position_set(ed->x + pf->final.x, ed->y + pf->final.y), evas_obj_size_set(pf->final.w, pf->final.h)); } if (ep->part->entry_mode > EDJE_ENTRY_EDIT_MODE_NONE) _edje_entry_real_part_configure(ed, ep); break; case EDJE_PART_TYPE_TEXT: /* This is correctly handle in _edje_text_recalc_apply at the moment. */ break; case EDJE_PART_TYPE_GRADIENT: /* FIXME: definitivly remove this code when we switch to new format. */ abort(); break; case EDJE_PART_TYPE_SPACER: /* We really should do nothing on SPACER part */ break; } /* Some object need special recalc. */ switch (ep->part->type) { case EDJE_PART_TYPE_TEXT: _edje_text_recalc_apply(ed, ep, pf, (Edje_Part_Description_Text*) chosen_desc, EINA_FALSE); break; case EDJE_PART_TYPE_PROXY: _edje_proxy_recalc_apply(ed, ep, pf, (Edje_Part_Description_Proxy*) chosen_desc, pos); break; case EDJE_PART_TYPE_IMAGE: _edje_image_recalc_apply(ed, ep, pf, (Edje_Part_Description_Image*) chosen_desc, pos); break; case EDJE_PART_TYPE_BOX: _edje_box_recalc_apply(ed, ep, pf, (Edje_Part_Description_Box*) chosen_desc); break; case EDJE_PART_TYPE_TABLE: _edje_table_recalc_apply(ed, ep, pf, (Edje_Part_Description_Table*) chosen_desc); break; case EDJE_PART_TYPE_TEXTBLOCK: _edje_textblock_recalc_apply(ed, ep, pf, (Edje_Part_Description_Text*) chosen_desc); break; case EDJE_PART_TYPE_EXTERNAL: case EDJE_PART_TYPE_RECTANGLE: case EDJE_PART_TYPE_SWALLOW: case EDJE_PART_TYPE_GROUP: /* Nothing special to do for this type of object. */ break; case EDJE_PART_TYPE_GRADIENT: /* FIXME: definitivly remove this code when we switch to new format. */ abort(); break; case EDJE_PART_TYPE_SPACER: /* We really should do nothing on SPACER part */ break; } if (((ep->type == EDJE_RP_TYPE_SWALLOW) && (ep->typedata.swallow)) && (ep->typedata.swallow->swallowed_object)) { if (pf->visible) { eo_do(ep->typedata.swallow->swallowed_object, evas_obj_position_set(ed->x + pf->final.x, ed->y + pf->final.y), evas_obj_size_set(pf->final.w, pf->final.h), evas_obj_visibility_set(EINA_TRUE)); } else evas_object_hide(ep->typedata.swallow->swallowed_object); mo = ep->typedata.swallow->swallowed_object; } else mo = ep->object; if (chosen_desc->map.on && ep->part->type != EDJE_PART_TYPE_SPACER) { static Evas_Map *map = NULL; ed->have_mapped_part = EINA_TRUE; ep->map_on = EINA_TRUE; // create map and populate with part geometry if (!map) map = evas_map_new(4); _edje_map_prop_set(map, pf, chosen_desc, ep, mo); if (ep->nested_smart) { /* Apply map to smart obj holding nested parts */ eo_do(ep->nested_smart, evas_obj_map_set(map), evas_obj_map_enable_set(EINA_TRUE)); } else { if (mo) eo_do(mo, evas_obj_map_set(map), evas_obj_map_enable_set(EINA_TRUE)); } } else { ep->map_on = EINA_FALSE; if (ep->nested_smart) { /* Cancel map of smart obj holding nested parts */ eo_do(ep->nested_smart, evas_obj_map_enable_set(EINA_FALSE), evas_obj_map_set(NULL)); } else { #ifdef HAVE_EPHYSICS if (!ep->body) { #endif if (mo) eo_do(mo, evas_obj_map_enable_set(0), evas_obj_map_set(NULL)); #ifdef HAVE_EPHYSICS } #endif } } } if (map_colors_free) _map_colors_free(pf); #ifdef HAVE_EPHYSICS ep->prev_description = chosen_desc; if (!ep->body) { #endif ep->x = pf->final.x; ep->y = pf->final.y; ep->w = pf->final.w; ep->h = pf->final.h; #ifdef HAVE_EPHYSICS } #endif ep->calculated |= flags; ep->calculating = FLAG_NONE; if (pf == &lp3) { eina_cow_free(_edje_calc_params_map_cow, (const Eina_Cow_Data **) &lp3.map); lp3.map = NULL; #ifdef HAVE_EPHYSICS eina_cow_free(_edje_calc_params_physics_cow, (const Eina_Cow_Data **) &lp3.physics); lp3.physics = NULL; #endif } #ifdef EDJE_CALC_CACHE if (ep->calculated == FLAG_XY) { ep->state = ed->state; ep->invalidate = EINA_FALSE; } #else eina_cow_free(_edje_calc_params_map_cow, (const Eina_Cow_Data **) &lp1.map); #ifdef HAVE_EPHYSICS eina_cow_free(_edje_calc_params_physics_cow, (const Eina_Cow_Data **) &lp1.physics); #endif #endif }