/* * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * The Original Code is Copyright (C) 2014, Blender Foundation */ /** \file * \ingroup edgpencil */ #include #include #include #include #include #include "MEM_guardedalloc.h" #include "BLI_math.h" #include "BLI_blenlib.h" #include "BLI_ghash.h" #include "BLI_utildefines.h" #include "BLT_translation.h" #include "BLI_rand.h" #include "DNA_meshdata_types.h" #include "DNA_gpencil_types.h" #include "DNA_brush_types.h" #include "DNA_object_types.h" #include "DNA_scene_types.h" #include "DNA_screen_types.h" #include "DNA_space_types.h" #include "DNA_view3d_types.h" #include "BKE_action.h" #include "BKE_colortools.h" #include "BKE_deform.h" #include "BKE_main.h" #include "BKE_brush.h" #include "BKE_context.h" #include "BKE_gpencil.h" #include "BKE_object.h" #include "BKE_paint.h" #include "BKE_material.h" #include "BKE_tracking.h" #include "WM_api.h" #include "WM_toolsystem.h" #include "RNA_access.h" #include "RNA_define.h" #include "RNA_enum_types.h" #include "UI_resources.h" #include "UI_view2d.h" #include "ED_gpencil.h" #include "ED_clip.h" #include "ED_view3d.h" #include "ED_object.h" #include "ED_screen.h" #include "ED_select_utils.h" #include "GPU_immediate.h" #include "GPU_immediate_util.h" #include "GPU_state.h" #include "DEG_depsgraph.h" #include "DEG_depsgraph_query.h" #include "gpencil_intern.h" /* ******************************************************** */ /* Context Wrangling... */ /** * Get pointer to active Grease Pencil datablock, * and an RNA-pointer to trace back to whatever owns it, * when context info is not available. */ bGPdata **ED_gpencil_data_get_pointers_direct( ID *screen_id, ScrArea *sa, Scene *scene, Object *ob, PointerRNA *r_ptr) { /* if there's an active area, check if the particular editor may * have defined any special Grease Pencil context for editing... */ if (sa) { SpaceLink *sl = sa->spacedata.first; switch (sa->spacetype) { /* XXX: Should we reduce reliance on context.gpencil_data for these cases? */ case SPACE_PROPERTIES: /* properties */ case SPACE_INFO: /* header info (needed after workspaces merge) */ { if (ob && (ob->type == OB_GPENCIL)) { /* GP Object */ if (r_ptr) { RNA_id_pointer_create(&ob->id, r_ptr); } return (bGPdata **)&ob->data; } else { return NULL; } break; } case SPACE_TOPBAR: /* Topbar (needed after topbar merge) */ case SPACE_VIEW3D: /* 3D-View */ { if (ob && (ob->type == OB_GPENCIL)) { /* GP Object */ if (r_ptr) { RNA_id_pointer_create(&ob->id, r_ptr); } return (bGPdata **)&ob->data; } else { /* Annotations */ /* XXX: */ if (r_ptr) { RNA_id_pointer_create(&scene->id, r_ptr); } return &scene->gpd; } break; } case SPACE_NODE: /* Nodes Editor */ { SpaceNode *snode = (SpaceNode *)sl; /* return the GP data for the active node block/node */ if (snode && snode->nodetree) { /* for now, as long as there's an active node tree, * default to using that in the Nodes Editor */ if (r_ptr) { RNA_id_pointer_create(&snode->nodetree->id, r_ptr); } return &snode->nodetree->gpd; } /* even when there is no node-tree, don't allow this to flow to scene */ return NULL; } case SPACE_SEQ: /* Sequencer */ { SpaceSeq *sseq = (SpaceSeq *)sl; /* For now, Grease Pencil data is associated with the space * (actually preview region only). */ /* XXX our convention for everything else is to link to data though... */ if (r_ptr) { RNA_pointer_create(screen_id, &RNA_SpaceSequenceEditor, sseq, r_ptr); } return &sseq->gpd; } case SPACE_IMAGE: /* Image/UV Editor */ { SpaceImage *sima = (SpaceImage *)sl; /* for now, Grease Pencil data is associated with the space... */ /* XXX our convention for everything else is to link to data though... */ if (r_ptr) { RNA_pointer_create(screen_id, &RNA_SpaceImageEditor, sima, r_ptr); } return &sima->gpd; } case SPACE_CLIP: /* Nodes Editor */ { SpaceClip *sc = (SpaceClip *)sl; MovieClip *clip = ED_space_clip_get_clip(sc); if (clip) { if (sc->gpencil_src == SC_GPENCIL_SRC_TRACK) { MovieTrackingTrack *track = BKE_tracking_track_get_active(&clip->tracking); if (!track) { return NULL; } if (r_ptr) { RNA_pointer_create(&clip->id, &RNA_MovieTrackingTrack, track, r_ptr); } return &track->gpd; } else { if (r_ptr) { RNA_id_pointer_create(&clip->id, r_ptr); } return &clip->gpd; } } break; } default: /* unsupported space */ return NULL; } } return NULL; } /* Get pointer to active Grease Pencil datablock, * and an RNA-pointer to trace back to whatever owns it. */ bGPdata **ED_gpencil_data_get_pointers(const bContext *C, PointerRNA *r_ptr) { ID *screen_id = (ID *)CTX_wm_screen(C); Scene *scene = CTX_data_scene(C); ScrArea *sa = CTX_wm_area(C); Object *ob = CTX_data_active_object(C); return ED_gpencil_data_get_pointers_direct(screen_id, sa, scene, ob, r_ptr); } /* -------------------------------------------------------- */ /* Get the active Grease Pencil datablock, when context is not available */ bGPdata *ED_gpencil_data_get_active_direct(ID *screen_id, ScrArea *sa, Scene *scene, Object *ob) { bGPdata **gpd_ptr = ED_gpencil_data_get_pointers_direct(screen_id, sa, scene, ob, NULL); return (gpd_ptr) ? *(gpd_ptr) : NULL; } /** * Get the active Grease Pencil datablock * \note This is the original (bmain) copy of the datablock, stored in files. * Do not use for reading evaluated copies of GP Objects data */ bGPdata *ED_gpencil_data_get_active(const bContext *C) { bGPdata **gpd_ptr = ED_gpencil_data_get_pointers(C, NULL); return (gpd_ptr) ? *(gpd_ptr) : NULL; } /** * Get the evaluated copy of the active Grease Pencil datablock (where applicable) * - For the 3D View (i.e. "GP Objects"), this gives the evaluated copy of the GP datablock * (i.e. a copy of the active GP datablock for the active object, where modifiers have been * applied). This is needed to correctly work with "Copy-on-Write". * - For all other editors (i.e. "GP Annotations"), this just gives the active datablock * like for #ED_gpencil_data_get_active() */ bGPdata *ED_gpencil_data_get_active_evaluated(const bContext *C) { ID *screen_id = (ID *)CTX_wm_screen(C); ScrArea *sa = CTX_wm_area(C); const Depsgraph *depsgraph = CTX_data_ensure_evaluated_depsgraph(C); Scene *scene_eval = DEG_get_evaluated_scene(depsgraph); Object *ob = CTX_data_active_object(C); Object *ob_eval = DEG_get_evaluated_object(depsgraph, ob); #if 0 if (ob && ob->type == OB_GPENCIL) { BLI_assert(ob_eval->data == DEG_get_evaluated_id(ob->data)); } #endif return ED_gpencil_data_get_active_direct(screen_id, sa, scene_eval, ob_eval); } /* -------------------------------------------------------- */ /** * Utility to check whether the r_ptr output of ED_gpencil_data_get_pointers() * is for annotation usage. */ bool ED_gpencil_data_owner_is_annotation(PointerRNA *owner_ptr) { /* Key Assumption: If the pointer is an object, we're dealing with a GP Object's data. * Otherwise, the GP datablock is being used for annotations (i.e. everywhere else) */ return ((owner_ptr) && (owner_ptr->type != &RNA_Object)); } /* ******************************************************** */ /* Keyframe Indicator Checks */ /* Check whether there's an active GP keyframe on the current frame */ bool ED_gpencil_has_keyframe_v3d(Scene *UNUSED(scene), Object *ob, int cfra) { if (ob && ob->data && (ob->type == OB_GPENCIL)) { bGPDlayer *gpl = BKE_gpencil_layer_getactive(ob->data); if (gpl) { if (gpl->actframe) { // XXX: assumes that frame has been fetched already return (gpl->actframe->framenum == cfra); } else { /* XXX: disabled as could be too much of a penalty */ /* return BKE_gpencil_layer_find_frame(gpl, cfra); */ } } } return false; } /* ******************************************************** */ /* Poll Callbacks */ /* poll callback for adding data/layers - special */ bool gp_add_poll(bContext *C) { /* the base line we have is that we have somewhere to add Grease Pencil data */ return ED_gpencil_data_get_pointers(C, NULL) != NULL; } /* poll callback for checking if there is an active layer */ bool gp_active_layer_poll(bContext *C) { bGPdata *gpd = ED_gpencil_data_get_active(C); bGPDlayer *gpl = BKE_gpencil_layer_getactive(gpd); return (gpl != NULL); } /* poll callback for checking if there is an active brush */ bool gp_active_brush_poll(bContext *C) { ToolSettings *ts = CTX_data_tool_settings(C); Paint *paint = &ts->gp_paint->paint; if (paint) { return (paint->brush != NULL); } else { return false; } } /* ******************************************************** */ /* Dynamic Enums of GP Layers */ /* NOTE: These include an option to create a new layer and use that... */ /* Just existing layers */ const EnumPropertyItem *ED_gpencil_layers_enum_itemf(bContext *C, PointerRNA *UNUSED(ptr), PropertyRNA *UNUSED(prop), bool *r_free) { bGPdata *gpd = CTX_data_gpencil_data(C); bGPDlayer *gpl; EnumPropertyItem *item = NULL, item_tmp = {0}; int totitem = 0; int i = 0; if (ELEM(NULL, C, gpd)) { return DummyRNA_DEFAULT_items; } /* Existing layers */ for (gpl = gpd->layers.first; gpl; gpl = gpl->next, i++) { item_tmp.identifier = gpl->info; item_tmp.name = gpl->info; item_tmp.value = i; if (gpl->flag & GP_LAYER_ACTIVE) { item_tmp.icon = ICON_GREASEPENCIL; } else { item_tmp.icon = ICON_NONE; } RNA_enum_item_add(&item, &totitem, &item_tmp); } RNA_enum_item_end(&item, &totitem); *r_free = true; return item; } /* Existing + Option to add/use new layer */ const EnumPropertyItem *ED_gpencil_layers_with_new_enum_itemf(bContext *C, PointerRNA *UNUSED(ptr), PropertyRNA *UNUSED(prop), bool *r_free) { bGPdata *gpd = CTX_data_gpencil_data(C); bGPDlayer *gpl; EnumPropertyItem *item = NULL, item_tmp = {0}; int totitem = 0; int i = 0; if (ELEM(NULL, C, gpd)) { return DummyRNA_DEFAULT_items; } /* Create new layer */ /* TODO: have some way of specifying that we don't want this? */ { /* "New Layer" entry */ item_tmp.identifier = "__CREATE__"; item_tmp.name = "New Layer"; item_tmp.value = -1; item_tmp.icon = ICON_ADD; RNA_enum_item_add(&item, &totitem, &item_tmp); /* separator */ RNA_enum_item_add_separator(&item, &totitem); } const int tot = BLI_listbase_count(&gpd->layers); /* Existing layers */ for (gpl = gpd->layers.last, i = 0; gpl; gpl = gpl->prev, i++) { item_tmp.identifier = gpl->info; item_tmp.name = gpl->info; item_tmp.value = tot - i - 1; if (gpl->flag & GP_LAYER_ACTIVE) { item_tmp.icon = ICON_GREASEPENCIL; } else { item_tmp.icon = ICON_NONE; } RNA_enum_item_add(&item, &totitem, &item_tmp); } RNA_enum_item_end(&item, &totitem); *r_free = true; return item; } /* ******************************************************** */ /* Brush Tool Core */ /** * Check whether a given stroke segment is inside a circular brush * * \param mval: The current screen-space coordinates (midpoint) of the brush * \param mvalo: The previous screen-space coordinates (midpoint) of the brush (NOT CURRENTLY USED) * \param rad: The radius of the brush * * \param x0, y0: The screen-space x and y coordinates of the start of the stroke segment * \param x1, y1: The screen-space x and y coordinates of the end of the stroke segment */ bool gp_stroke_inside_circle( const float mval[2], const float UNUSED(mvalo[2]), int rad, int x0, int y0, int x1, int y1) { /* simple within-radius check for now */ const float screen_co_a[2] = {x0, y0}; const float screen_co_b[2] = {x1, y1}; if (edge_inside_circle(mval, rad, screen_co_a, screen_co_b)) { return true; } /* not inside */ return false; } /* ******************************************************** */ /* Stroke Validity Testing */ /* Check whether given stroke can be edited given the supplied context */ /* TODO: do we need additional flags for screenspace vs dataspace? */ bool ED_gpencil_stroke_can_use_direct(const ScrArea *sa, const bGPDstroke *gps) { /* sanity check */ if (ELEM(NULL, sa, gps)) { return false; } /* filter stroke types by flags + spacetype */ if (gps->flag & GP_STROKE_3DSPACE) { /* 3D strokes - only in 3D view */ return ((sa->spacetype == SPACE_VIEW3D) || (sa->spacetype == SPACE_PROPERTIES)); } else if (gps->flag & GP_STROKE_2DIMAGE) { /* Special "image" strokes - only in Image Editor */ return (sa->spacetype == SPACE_IMAGE); } else if (gps->flag & GP_STROKE_2DSPACE) { /* 2D strokes (dataspace) - for any 2D view (i.e. everything other than 3D view) */ return (sa->spacetype != SPACE_VIEW3D); } else { /* view aligned - anything goes */ return true; } } /* Check whether given stroke can be edited in the current context */ bool ED_gpencil_stroke_can_use(const bContext *C, const bGPDstroke *gps) { ScrArea *sa = CTX_wm_area(C); return ED_gpencil_stroke_can_use_direct(sa, gps); } /* Check whether given stroke can be edited for the current color */ bool ED_gpencil_stroke_color_use(Object *ob, const bGPDlayer *gpl, const bGPDstroke *gps) { /* check if the color is editable */ MaterialGPencilStyle *gp_style = BKE_material_gpencil_settings_get(ob, gps->mat_nr + 1); if (gp_style != NULL) { if (gp_style->flag & GP_STYLE_COLOR_HIDE) { return false; } if (((gpl->flag & GP_LAYER_UNLOCK_COLOR) == 0) && (gp_style->flag & GP_STYLE_COLOR_LOCKED)) { return false; } } return true; } /* ******************************************************** */ /* Space Conversion */ /** * Init settings for stroke point space conversions * * \param r_gsc: [out] The space conversion settings struct, populated with necessary params */ void gp_point_conversion_init(bContext *C, GP_SpaceConversion *r_gsc) { ScrArea *sa = CTX_wm_area(C); ARegion *ar = CTX_wm_region(C); /* zero out the storage (just in case) */ memset(r_gsc, 0, sizeof(GP_SpaceConversion)); unit_m4(r_gsc->mat); /* store settings */ r_gsc->scene = CTX_data_scene(C); r_gsc->ob = CTX_data_active_object(C); r_gsc->sa = sa; r_gsc->ar = ar; r_gsc->v2d = &ar->v2d; /* init region-specific stuff */ if (sa->spacetype == SPACE_VIEW3D) { wmWindow *win = CTX_wm_window(C); Scene *scene = CTX_data_scene(C); struct Depsgraph *depsgraph = CTX_data_ensure_evaluated_depsgraph(C); View3D *v3d = (View3D *)CTX_wm_space_data(C); RegionView3D *rv3d = ar->regiondata; /* init 3d depth buffers */ view3d_operator_needs_opengl(C); view3d_region_operator_needs_opengl(win, ar); ED_view3d_autodist_init(depsgraph, ar, v3d, 0); /* for camera view set the subrect */ if (rv3d->persp == RV3D_CAMOB) { ED_view3d_calc_camera_border(scene, depsgraph, ar, v3d, rv3d, &r_gsc->subrect_data, true); r_gsc->subrect = &r_gsc->subrect_data; } } } /** * Convert point to parent space * * \param pt: Original point * \param diff_mat: Matrix with the difference between original parent matrix * \param[out] r_pt: Pointer to new point after apply matrix */ void gp_point_to_parent_space(const bGPDspoint *pt, const float diff_mat[4][4], bGPDspoint *r_pt) { float fpt[3]; mul_v3_m4v3(fpt, diff_mat, &pt->x); copy_v3_v3(&r_pt->x, fpt); } /** * Change position relative to parent object */ void gp_apply_parent( Depsgraph *depsgraph, Object *obact, bGPdata *gpd, bGPDlayer *gpl, bGPDstroke *gps) { bGPDspoint *pt; int i; /* undo matrix */ float diff_mat[4][4]; float inverse_diff_mat[4][4]; float fpt[3]; ED_gpencil_parent_location(depsgraph, obact, gpd, gpl, diff_mat); invert_m4_m4(inverse_diff_mat, diff_mat); for (i = 0; i < gps->totpoints; i++) { pt = &gps->points[i]; mul_v3_m4v3(fpt, inverse_diff_mat, &pt->x); copy_v3_v3(&pt->x, fpt); } } /** * Change point position relative to parent object */ void gp_apply_parent_point( Depsgraph *depsgraph, Object *obact, bGPdata *gpd, bGPDlayer *gpl, bGPDspoint *pt) { /* undo matrix */ float diff_mat[4][4]; float inverse_diff_mat[4][4]; float fpt[3]; ED_gpencil_parent_location(depsgraph, obact, gpd, gpl, diff_mat); invert_m4_m4(inverse_diff_mat, diff_mat); mul_v3_m4v3(fpt, inverse_diff_mat, &pt->x); copy_v3_v3(&pt->x, fpt); } /** * Convert a Grease Pencil coordinate (i.e. can be 2D or 3D) to screenspace (2D) * * \param[out] r_x The screen-space x-coordinate of the point * \param[out] r_y The screen-space y-coordinate of the point * * \warning This assumes that the caller has already checked * whether the stroke in question can be drawn. */ void gp_point_to_xy( const GP_SpaceConversion *gsc, const bGPDstroke *gps, const bGPDspoint *pt, int *r_x, int *r_y) { const ARegion *ar = gsc->ar; const View2D *v2d = gsc->v2d; const rctf *subrect = gsc->subrect; int xyval[2]; /* sanity checks */ BLI_assert(!(gps->flag & GP_STROKE_3DSPACE) || (gsc->sa->spacetype == SPACE_VIEW3D)); BLI_assert(!(gps->flag & GP_STROKE_2DSPACE) || (gsc->sa->spacetype != SPACE_VIEW3D)); if (gps->flag & GP_STROKE_3DSPACE) { if (ED_view3d_project_int_global(ar, &pt->x, xyval, V3D_PROJ_TEST_NOP) == V3D_PROJ_RET_OK) { *r_x = xyval[0]; *r_y = xyval[1]; } else { *r_x = V2D_IS_CLIPPED; *r_y = V2D_IS_CLIPPED; } } else if (gps->flag & GP_STROKE_2DSPACE) { float vec[3] = {pt->x, pt->y, 0.0f}; mul_m4_v3(gsc->mat, vec); UI_view2d_view_to_region_clip(v2d, vec[0], vec[1], r_x, r_y); } else { if (subrect == NULL) { /* normal 3D view (or view space) */ *r_x = (int)(pt->x / 100 * ar->winx); *r_y = (int)(pt->y / 100 * ar->winy); } else { /* camera view, use subrect */ *r_x = (int)((pt->x / 100) * BLI_rctf_size_x(subrect)) + subrect->xmin; *r_y = (int)((pt->y / 100) * BLI_rctf_size_y(subrect)) + subrect->ymin; } } } /** * Convert a Grease Pencil coordinate (i.e. can be 2D or 3D) to screenspace (2D). * * Just like #gp_point_to_xy(), except the resulting coordinates are floats not ints. * Use this version to solve "stair-step" artifacts which may arise when * roundtripping the calculations. * * \param r_x[out]: The screen-space x-coordinate of the point. * \param r_y[out]: The screen-space y-coordinate of the point. * * \warning This assumes that the caller has already checked * whether the stroke in question can be drawn. */ void gp_point_to_xy_fl(const GP_SpaceConversion *gsc, const bGPDstroke *gps, const bGPDspoint *pt, float *r_x, float *r_y) { const ARegion *ar = gsc->ar; const View2D *v2d = gsc->v2d; const rctf *subrect = gsc->subrect; float xyval[2]; /* sanity checks */ BLI_assert(!(gps->flag & GP_STROKE_3DSPACE) || (gsc->sa->spacetype == SPACE_VIEW3D)); BLI_assert(!(gps->flag & GP_STROKE_2DSPACE) || (gsc->sa->spacetype != SPACE_VIEW3D)); if (gps->flag & GP_STROKE_3DSPACE) { if (ED_view3d_project_float_global(ar, &pt->x, xyval, V3D_PROJ_TEST_NOP) == V3D_PROJ_RET_OK) { *r_x = xyval[0]; *r_y = xyval[1]; } else { *r_x = 0.0f; *r_y = 0.0f; } } else if (gps->flag & GP_STROKE_2DSPACE) { float vec[3] = {pt->x, pt->y, 0.0f}; int t_x, t_y; mul_m4_v3(gsc->mat, vec); UI_view2d_view_to_region_clip(v2d, vec[0], vec[1], &t_x, &t_y); if ((t_x == t_y) && (t_x == V2D_IS_CLIPPED)) { /* XXX: Or should we just always use the values as-is? */ *r_x = 0.0f; *r_y = 0.0f; } else { *r_x = (float)t_x; *r_y = (float)t_y; } } else { if (subrect == NULL) { /* normal 3D view (or view space) */ *r_x = (pt->x / 100.0f * ar->winx); *r_y = (pt->y / 100.0f * ar->winy); } else { /* camera view, use subrect */ *r_x = ((pt->x / 100.0f) * BLI_rctf_size_x(subrect)) + subrect->xmin; *r_y = ((pt->y / 100.0f) * BLI_rctf_size_y(subrect)) + subrect->ymin; } } } /** * generic based on gp_point_to_xy_fl */ void gp_point_3d_to_xy(const GP_SpaceConversion *gsc, const short flag, const float pt[3], float xy[2]) { const ARegion *ar = gsc->ar; const View2D *v2d = gsc->v2d; const rctf *subrect = gsc->subrect; float xyval[2]; /* sanity checks */ BLI_assert((gsc->sa->spacetype == SPACE_VIEW3D)); if (flag & GP_STROKE_3DSPACE) { if (ED_view3d_project_float_global(ar, pt, xyval, V3D_PROJ_TEST_NOP) == V3D_PROJ_RET_OK) { xy[0] = xyval[0]; xy[1] = xyval[1]; } else { xy[0] = 0.0f; xy[1] = 0.0f; } } else if (flag & GP_STROKE_2DSPACE) { float vec[3] = {pt[0], pt[1], 0.0f}; int t_x, t_y; mul_m4_v3(gsc->mat, vec); UI_view2d_view_to_region_clip(v2d, vec[0], vec[1], &t_x, &t_y); if ((t_x == t_y) && (t_x == V2D_IS_CLIPPED)) { /* XXX: Or should we just always use the values as-is? */ xy[0] = 0.0f; xy[1] = 0.0f; } else { xy[0] = (float)t_x; xy[1] = (float)t_y; } } else { if (subrect == NULL) { /* normal 3D view (or view space) */ xy[0] = (pt[0] / 100.0f * ar->winx); xy[1] = (pt[1] / 100.0f * ar->winy); } else { /* camera view, use subrect */ xy[0] = ((pt[0] / 100.0f) * BLI_rctf_size_x(subrect)) + subrect->xmin; xy[1] = ((pt[1] / 100.0f) * BLI_rctf_size_y(subrect)) + subrect->ymin; } } } /** * Project screenspace coordinates to 3D-space * * For use with editing tools where it is easier to perform the operations in 2D, * and then later convert the transformed points back to 3D. * * \param screen_co: The screenspace 2D coordinates to convert to * \param r_out: The resulting 3D coordinates of the input point * * \note We include this as a utility function, since the standard method * involves quite a few steps, which are invariably always the same * for all GPencil operations. So, it's nicer to just centralize these. * * \warning Assumes that it is getting called in a 3D view only. */ bool gp_point_xy_to_3d(const GP_SpaceConversion *gsc, Scene *scene, const float screen_co[2], float r_out[3]) { const RegionView3D *rv3d = gsc->ar->regiondata; float rvec[3]; ED_gp_get_drawing_reference( scene, gsc->ob, gsc->gpl, scene->toolsettings->gpencil_v3d_align, rvec); float zfac = ED_view3d_calc_zfac(rv3d, rvec, NULL); float mval_f[2], mval_prj[2]; float dvec[3]; copy_v2_v2(mval_f, screen_co); if (ED_view3d_project_float_global(gsc->ar, rvec, mval_prj, V3D_PROJ_TEST_NOP) == V3D_PROJ_RET_OK) { sub_v2_v2v2(mval_f, mval_prj, mval_f); ED_view3d_win_to_delta(gsc->ar, mval_f, dvec, zfac); sub_v3_v3v3(r_out, rvec, dvec); return true; } else { zero_v3(r_out); return false; } } /** * Convert tGPspoint (temporary 2D/screenspace point data used by GP modal operators) * to 3D coordinates. * * \param point2D: The screenspace 2D point data to convert. * \param depth: Depth array (via #ED_view3d_autodist_depth()). * \param[out] r_out: The resulting 2D point data. */ void gp_stroke_convertcoords_tpoint(Scene *scene, ARegion *ar, Object *ob, bGPDlayer *gpl, const tGPspoint *point2D, float *depth, float r_out[3]) { ToolSettings *ts = scene->toolsettings; int mval_i[2]; round_v2i_v2fl(mval_i, &point2D->x); if ((depth != NULL) && (ED_view3d_autodist_simple(ar, mval_i, r_out, 0, depth))) { /* projecting onto 3D-Geometry * - nothing more needs to be done here, since view_autodist_simple() has already done it */ } else { float mval_f[2] = {point2D->x, point2D->y}; float mval_prj[2]; float rvec[3], dvec[3]; float zfac; /* Current method just converts each point in screen-coordinates to * 3D-coordinates using the 3D-cursor as reference. */ ED_gp_get_drawing_reference(scene, ob, gpl, ts->gpencil_v3d_align, rvec); zfac = ED_view3d_calc_zfac(ar->regiondata, rvec, NULL); if (ED_view3d_project_float_global(ar, rvec, mval_prj, V3D_PROJ_TEST_NOP) == V3D_PROJ_RET_OK) { sub_v2_v2v2(mval_f, mval_prj, mval_f); ED_view3d_win_to_delta(ar, mval_f, dvec, zfac); sub_v3_v3v3(r_out, rvec, dvec); } else { zero_v3(r_out); } } } /** * Get drawing reference point for conversion or projection of the stroke * \param[out] r_vec : Reference point found */ void ED_gp_get_drawing_reference( const Scene *scene, const Object *ob, bGPDlayer *UNUSED(gpl), char align_flag, float r_vec[3]) { const float *fp = scene->cursor.location; /* if using a gpencil object at cursor mode, can use the location of the object */ if (align_flag & GP_PROJECT_VIEWSPACE) { if (ob && (ob->type == OB_GPENCIL)) { /* fallback (no strokes) - use cursor or object location */ if (align_flag & GP_PROJECT_CURSOR) { /* use 3D-cursor */ copy_v3_v3(r_vec, fp); } else { /* use object location */ copy_v3_v3(r_vec, ob->obmat[3]); } } } else { /* use 3D-cursor */ copy_v3_v3(r_vec, fp); } } void ED_gpencil_project_stroke_to_view(bContext *C, bGPDlayer *gpl, bGPDstroke *gps) { Scene *scene = CTX_data_scene(C); Depsgraph *depsgraph = CTX_data_ensure_evaluated_depsgraph(C); Object *ob = CTX_data_active_object(C); bGPdata *gpd = (bGPdata *)ob->data; GP_SpaceConversion gsc = {NULL}; bGPDspoint *pt; int i; float diff_mat[4][4]; float inverse_diff_mat[4][4]; /* init space conversion stuff */ gp_point_conversion_init(C, &gsc); ED_gpencil_parent_location(depsgraph, ob, gpd, gpl, diff_mat); invert_m4_m4(inverse_diff_mat, diff_mat); /* Adjust each point */ for (i = 0, pt = gps->points; i < gps->totpoints; i++, pt++) { float xy[2]; bGPDspoint pt2; gp_point_to_parent_space(pt, diff_mat, &pt2); gp_point_to_xy_fl(&gsc, gps, &pt2, &xy[0], &xy[1]); /* Planar - All on same plane parallel to the viewplane */ gp_point_xy_to_3d(&gsc, scene, xy, &pt->x); /* Unapply parent corrections */ mul_m4_v3(inverse_diff_mat, &pt->x); } } /** * Reproject all points of the stroke to a plane locked to axis to avoid stroke offset */ void ED_gp_project_stroke_to_plane(const Scene *scene, const Object *ob, const RegionView3D *rv3d, bGPDstroke *gps, const float origin[3], const int axis) { const ToolSettings *ts = scene->toolsettings; const View3DCursor *cursor = &scene->cursor; float plane_normal[3]; float vn[3]; float ray[3]; float rpoint[3]; /* normal vector for a plane locked to axis */ zero_v3(plane_normal); if (axis < 0) { /* if the axis is not locked, need a vector to the view direction * in order to get the right size of the stroke. */ ED_view3d_global_to_vector(rv3d, origin, plane_normal); } else if (axis < 3) { plane_normal[axis] = 1.0f; /* if object, apply object rotation */ if (ob && (ob->type == OB_GPENCIL)) { float mat[4][4]; copy_m4_m4(mat, ob->obmat); /* move origin to cursor */ if (ts->gpencil_v3d_align & GP_PROJECT_CURSOR) { copy_v3_v3(mat[3], cursor->location); } mul_mat3_m4_v3(mat, plane_normal); } } else { float scale[3] = {1.0f, 1.0f, 1.0f}; plane_normal[2] = 1.0f; float mat[4][4]; loc_eul_size_to_mat4(mat, cursor->location, cursor->rotation_euler, scale); /* move origin to object */ if ((ts->gpencil_v3d_align & GP_PROJECT_CURSOR) == 0) { copy_v3_v3(mat[3], ob->obmat[3]); } mul_mat3_m4_v3(mat, plane_normal); } /* Reproject the points in the plane */ for (int i = 0; i < gps->totpoints; i++) { bGPDspoint *pt = &gps->points[i]; /* get a vector from the point with the current view direction of the viewport */ ED_view3d_global_to_vector(rv3d, &pt->x, vn); /* calculate line extreme point to create a ray that cross the plane */ mul_v3_fl(vn, -50.0f); add_v3_v3v3(ray, &pt->x, vn); /* if the line never intersect, the point is not changed */ if (isect_line_plane_v3(rpoint, &pt->x, ray, origin, plane_normal)) { copy_v3_v3(&pt->x, rpoint); } } } /** * Reproject given point to a plane locked to axis to avoid stroke offset * \param[in,out] pt: Point to affect */ void ED_gp_project_point_to_plane(const Scene *scene, const Object *ob, const RegionView3D *rv3d, const float origin[3], const int axis, bGPDspoint *pt) { const ToolSettings *ts = scene->toolsettings; const View3DCursor *cursor = &scene->cursor; float plane_normal[3]; float vn[3]; float ray[3]; float rpoint[3]; /* normal vector for a plane locked to axis */ zero_v3(plane_normal); if (axis < 0) { /* if the axis is not locked, need a vector to the view direction * in order to get the right size of the stroke. */ ED_view3d_global_to_vector(rv3d, origin, plane_normal); } else if (axis < 3) { plane_normal[axis] = 1.0f; /* if object, apply object rotation */ if (ob && (ob->type == OB_GPENCIL)) { float mat[4][4]; copy_m4_m4(mat, ob->obmat); /* move origin to cursor */ if (ts->gpencil_v3d_align & GP_PROJECT_CURSOR) { copy_v3_v3(mat[3], cursor->location); } mul_mat3_m4_v3(mat, plane_normal); } } else { float scale[3] = {1.0f, 1.0f, 1.0f}; plane_normal[2] = 1.0f; float mat[4][4]; loc_eul_size_to_mat4(mat, cursor->location, cursor->rotation_euler, scale); /* move origin to object */ if ((ts->gpencil_v3d_align & GP_PROJECT_CURSOR) == 0) { copy_v3_v3(mat[3], ob->obmat[3]); } mul_mat3_m4_v3(mat, plane_normal); } /* Reproject the points in the plane */ /* get a vector from the point with the current view direction of the viewport */ ED_view3d_global_to_vector(rv3d, &pt->x, vn); /* calculate line extreme point to create a ray that cross the plane */ mul_v3_fl(vn, -50.0f); add_v3_v3v3(ray, &pt->x, vn); /* if the line never intersect, the point is not changed */ if (isect_line_plane_v3(rpoint, &pt->x, ray, origin, plane_normal)) { copy_v3_v3(&pt->x, rpoint); } } /* ******************************************************** */ /* Stroke Operations */ /* XXX: Check if these functions duplicate stuff in blenkernel, * and/or whether we should just deduplicate. */ /** * Subdivide a stroke once, by adding a point half way between each pair of existing points * \param gps: Stroke data * \param subdivide: Number of times to subdivide */ void gp_subdivide_stroke(bGPDstroke *gps, const int subdivide) { bGPDspoint *temp_points; int totnewpoints, oldtotpoints; int i2; /* loop as many times as levels */ for (int s = 0; s < subdivide; s++) { totnewpoints = gps->totpoints - 1; /* duplicate points in a temp area */ temp_points = MEM_dupallocN(gps->points); oldtotpoints = gps->totpoints; /* resize the points arrays */ gps->totpoints += totnewpoints; gps->points = MEM_recallocN(gps->points, sizeof(*gps->points) * gps->totpoints); if (gps->dvert != NULL) { gps->dvert = MEM_recallocN(gps->dvert, sizeof(*gps->dvert) * gps->totpoints); } gps->flag |= GP_STROKE_RECALC_GEOMETRY; /* move points from last to first to new place */ i2 = gps->totpoints - 1; for (int i = oldtotpoints - 1; i > 0; i--) { bGPDspoint *pt = &temp_points[i]; bGPDspoint *pt_final = &gps->points[i2]; copy_v3_v3(&pt_final->x, &pt->x); pt_final->pressure = pt->pressure; pt_final->strength = pt->strength; pt_final->time = pt->time; pt_final->flag = pt->flag; pt_final->uv_fac = pt->uv_fac; pt_final->uv_rot = pt->uv_rot; if (gps->dvert != NULL) { MDeformVert *dvert = &gps->dvert[i]; MDeformVert *dvert_final = &gps->dvert[i2]; dvert_final->totweight = dvert->totweight; dvert_final->dw = dvert->dw; } i2 -= 2; } /* interpolate mid points */ i2 = 1; for (int i = 0; i < oldtotpoints - 1; i++) { bGPDspoint *pt = &temp_points[i]; bGPDspoint *next = &temp_points[i + 1]; bGPDspoint *pt_final = &gps->points[i2]; /* add a half way point */ interp_v3_v3v3(&pt_final->x, &pt->x, &next->x, 0.5f); pt_final->pressure = interpf(pt->pressure, next->pressure, 0.5f); pt_final->strength = interpf(pt->strength, next->strength, 0.5f); CLAMP(pt_final->strength, GPENCIL_STRENGTH_MIN, 1.0f); pt_final->time = interpf(pt->time, next->time, 0.5f); pt_final->uv_fac = interpf(pt->uv_fac, next->uv_fac, 0.5f); pt_final->uv_rot = interpf(pt->uv_rot, next->uv_rot, 0.5f); if (gps->dvert != NULL) { MDeformVert *dvert_final = &gps->dvert[i2]; dvert_final->totweight = 0; dvert_final->dw = NULL; } i2 += 2; } MEM_SAFE_FREE(temp_points); /* move points to smooth stroke */ /* duplicate points in a temp area with the new subdivide data */ temp_points = MEM_dupallocN(gps->points); /* extreme points are not changed */ for (int i = 0; i < gps->totpoints - 2; i++) { bGPDspoint *pt = &temp_points[i]; bGPDspoint *next = &temp_points[i + 1]; bGPDspoint *pt_final = &gps->points[i + 1]; /* move point */ interp_v3_v3v3(&pt_final->x, &pt->x, &next->x, 0.5f); } /* free temp memory */ MEM_SAFE_FREE(temp_points); } } /** * Add randomness to stroke * \param gps: Stroke data * \param brush: Brush data */ void gp_randomize_stroke(bGPDstroke *gps, Brush *brush, RNG *rng) { bGPDspoint *pt1, *pt2, *pt3; float v1[3]; float v2[3]; if (gps->totpoints < 3) { return; } /* get two vectors using 3 points */ pt1 = &gps->points[0]; pt2 = &gps->points[1]; pt3 = &gps->points[(int)(gps->totpoints * 0.75)]; sub_v3_v3v3(v1, &pt2->x, &pt1->x); sub_v3_v3v3(v2, &pt3->x, &pt2->x); normalize_v3(v1); normalize_v3(v2); /* get normal vector to plane created by two vectors */ float normal[3]; cross_v3_v3v3(normal, v1, v2); normalize_v3(normal); /* get orthogonal vector to plane to rotate random effect */ float ortho[3]; cross_v3_v3v3(ortho, v1, normal); normalize_v3(ortho); /* Read all points and apply shift vector (first and last point not modified) */ for (int i = 1; i < gps->totpoints - 1; i++) { bGPDspoint *pt = &gps->points[i]; /* get vector with shift (apply a division because random is too sensitive */ const float fac = BLI_rng_get_float(rng) * (brush->gpencil_settings->draw_random_sub / 10.0f); float svec[3]; copy_v3_v3(svec, ortho); if (BLI_rng_get_float(rng) > 0.5f) { mul_v3_fl(svec, -fac); } else { mul_v3_fl(svec, fac); } /* apply shift */ add_v3_v3(&pt->x, svec); } } /* ******************************************************** */ /* Layer Parenting - Compute Parent Transforms */ /* calculate difference matrix */ void ED_gpencil_parent_location(const Depsgraph *depsgraph, Object *obact, bGPdata *UNUSED(gpd), bGPDlayer *gpl, float diff_mat[4][4]) { Object *ob_eval = depsgraph != NULL ? DEG_get_evaluated_object(depsgraph, obact) : obact; Object *obparent = gpl->parent; Object *obparent_eval = depsgraph != NULL ? DEG_get_evaluated_object(depsgraph, obparent) : obparent; /* if not layer parented, try with object parented */ if (obparent_eval == NULL) { if (ob_eval != NULL) { if (ob_eval->type == OB_GPENCIL) { copy_m4_m4(diff_mat, ob_eval->obmat); return; } } /* not gpencil object */ unit_m4(diff_mat); return; } else { if ((gpl->partype == PAROBJECT) || (gpl->partype == PARSKEL)) { mul_m4_m4m4(diff_mat, obparent_eval->obmat, gpl->inverse); add_v3_v3(diff_mat[3], ob_eval->obmat[3]); return; } else if (gpl->partype == PARBONE) { bPoseChannel *pchan = BKE_pose_channel_find_name(obparent_eval->pose, gpl->parsubstr); if (pchan) { float tmp_mat[4][4]; mul_m4_m4m4(tmp_mat, obparent_eval->obmat, pchan->pose_mat); mul_m4_m4m4(diff_mat, tmp_mat, gpl->inverse); add_v3_v3(diff_mat[3], ob_eval->obmat[3]); } else { /* if bone not found use object (armature) */ mul_m4_m4m4(diff_mat, obparent_eval->obmat, gpl->inverse); add_v3_v3(diff_mat[3], ob_eval->obmat[3]); } return; } else { unit_m4(diff_mat); /* not defined type */ } } } /* reset parent matrix for all layers */ void ED_gpencil_reset_layers_parent(Depsgraph *depsgraph, Object *obact, bGPdata *gpd) { bGPDspoint *pt; int i; float diff_mat[4][4]; float cur_mat[4][4]; float gpl_loc[3]; zero_v3(gpl_loc); for (bGPDlayer *gpl = gpd->layers.first; gpl; gpl = gpl->next) { if (gpl->parent != NULL) { /* calculate new matrix */ if ((gpl->partype == PAROBJECT) || (gpl->partype == PARSKEL)) { invert_m4_m4(cur_mat, gpl->parent->obmat); copy_v3_v3(gpl_loc, obact->obmat[3]); } else if (gpl->partype == PARBONE) { bPoseChannel *pchan = BKE_pose_channel_find_name(gpl->parent->pose, gpl->parsubstr); if (pchan) { float tmp_mat[4][4]; mul_m4_m4m4(tmp_mat, gpl->parent->obmat, pchan->pose_mat); invert_m4_m4(cur_mat, tmp_mat); copy_v3_v3(gpl_loc, obact->obmat[3]); } } /* only redo if any change */ if (!equals_m4m4(gpl->inverse, cur_mat)) { /* first apply current transformation to all strokes */ ED_gpencil_parent_location(depsgraph, obact, gpd, gpl, diff_mat); /* undo local object */ sub_v3_v3(diff_mat[3], gpl_loc); for (bGPDframe *gpf = gpl->frames.first; gpf; gpf = gpf->next) { for (bGPDstroke *gps = gpf->strokes.first; gps; gps = gps->next) { for (i = 0, pt = gps->points; i < gps->totpoints; i++, pt++) { mul_m4_v3(diff_mat, &pt->x); } } } /* set new parent matrix */ copy_m4_m4(gpl->inverse, cur_mat); } } } } /* ******************************************************** */ /* GP Object Stuff */ /* Helper function to create new OB_GPENCIL Object */ Object *ED_gpencil_add_object(bContext *C, Scene *UNUSED(scene), const float loc[3], ushort local_view_bits) { float rot[3] = {0.0f}; Object *ob = ED_object_add_type(C, OB_GPENCIL, NULL, loc, rot, false, local_view_bits); /* create default brushes and colors */ ED_gpencil_add_defaults(C, ob); return ob; } /* Helper function to create default colors and drawing brushes */ void ED_gpencil_add_defaults(bContext *C, Object *ob) { Main *bmain = CTX_data_main(C); ToolSettings *ts = CTX_data_tool_settings(C); BKE_paint_ensure(ts, (Paint **)&ts->gp_paint); Paint *paint = &ts->gp_paint->paint; /* if not exist, create a new one */ if ((paint->brush == NULL) || (paint->brush->gpencil_settings == NULL)) { /* create new brushes */ BKE_brush_gpencil_presets(C); } /* ensure a color exists and is assigned to object */ BKE_gpencil_object_material_ensure_from_active_input_toolsettings(bmain, ob, ts); /* ensure multiframe falloff curve */ if (ts->gp_sculpt.cur_falloff == NULL) { ts->gp_sculpt.cur_falloff = BKE_curvemapping_add(1, 0.0f, 0.0f, 1.0f, 1.0f); CurveMapping *gp_falloff_curve = ts->gp_sculpt.cur_falloff; BKE_curvemapping_initialize(gp_falloff_curve); BKE_curvemap_reset(gp_falloff_curve->cm, &gp_falloff_curve->clipr, CURVE_PRESET_GAUSS, CURVEMAP_SLOPE_POSITIVE); } } /* ******************************************************** */ /* Vertex Groups */ /* assign points to vertex group */ void ED_gpencil_vgroup_assign(bContext *C, Object *ob, float weight) { bGPdata *gpd = (bGPdata *)ob->data; const bool is_multiedit = (bool)GPENCIL_MULTIEDIT_SESSIONS_ON(gpd); const int def_nr = ob->actdef - 1; if (!BLI_findlink(&ob->defbase, def_nr)) { return; } CTX_DATA_BEGIN (C, bGPDlayer *, gpl, editable_gpencil_layers) { bGPDframe *init_gpf = (is_multiedit) ? gpl->frames.first : gpl->actframe; bGPDstroke *gps = NULL; for (bGPDframe *gpf = init_gpf; gpf; gpf = gpf->next) { if ((gpf == gpl->actframe) || ((gpf->flag & GP_FRAME_SELECT) && (is_multiedit))) { if (gpf == NULL) { continue; } for (gps = gpf->strokes.first; gps; gps = gps->next) { /* skip strokes that are invalid for current view */ if (ED_gpencil_stroke_can_use(C, gps) == false) { continue; } if (gps->flag & GP_STROKE_SELECT) { /* verify the weight array is created */ BKE_gpencil_dvert_ensure(gps); for (int i = 0; i < gps->totpoints; i++) { bGPDspoint *pt = &gps->points[i]; MDeformVert *dvert = &gps->dvert[i]; if (pt->flag & GP_SPOINT_SELECT) { MDeformWeight *dw = defvert_verify_index(dvert, def_nr); if (dw) { dw->weight = weight; } } } } } } /* if not multiedit, exit loop*/ if (!is_multiedit) { break; } } } CTX_DATA_END; } /* remove points from vertex group */ void ED_gpencil_vgroup_remove(bContext *C, Object *ob) { bGPdata *gpd = (bGPdata *)ob->data; const bool is_multiedit = (bool)GPENCIL_MULTIEDIT_SESSIONS_ON(gpd); const int def_nr = ob->actdef - 1; if (!BLI_findlink(&ob->defbase, def_nr)) { return; } CTX_DATA_BEGIN (C, bGPDlayer *, gpl, editable_gpencil_layers) { bGPDframe *init_gpf = (is_multiedit) ? gpl->frames.first : gpl->actframe; bGPDstroke *gps = NULL; for (bGPDframe *gpf = init_gpf; gpf; gpf = gpf->next) { if ((gpf == gpl->actframe) || ((gpf->flag & GP_FRAME_SELECT) && (is_multiedit))) { if (gpf == NULL) { continue; } for (gps = gpf->strokes.first; gps; gps = gps->next) { /* skip strokes that are invalid for current view */ if (ED_gpencil_stroke_can_use(C, gps) == false) { continue; } for (int i = 0; i < gps->totpoints; i++) { bGPDspoint *pt = &gps->points[i]; if (gps->dvert == NULL) { continue; } MDeformVert *dvert = &gps->dvert[i]; if ((pt->flag & GP_SPOINT_SELECT) && (dvert->totweight > 0)) { MDeformWeight *dw = defvert_find_index(dvert, def_nr); if (dw != NULL) { defvert_remove_group(dvert, dw); } } } } } /* if not multiedit, exit loop*/ if (!is_multiedit) { break; } } } CTX_DATA_END; } /* select points of vertex group */ void ED_gpencil_vgroup_select(bContext *C, Object *ob) { bGPdata *gpd = (bGPdata *)ob->data; const bool is_multiedit = (bool)GPENCIL_MULTIEDIT_SESSIONS_ON(gpd); const int def_nr = ob->actdef - 1; if (!BLI_findlink(&ob->defbase, def_nr)) { return; } CTX_DATA_BEGIN (C, bGPDlayer *, gpl, editable_gpencil_layers) { bGPDframe *init_gpf = (is_multiedit) ? gpl->frames.first : gpl->actframe; bGPDstroke *gps = NULL; for (bGPDframe *gpf = init_gpf; gpf; gpf = gpf->next) { if ((gpf == gpl->actframe) || ((gpf->flag & GP_FRAME_SELECT) && (is_multiedit))) { if (gpf == NULL) { continue; } for (gps = gpf->strokes.first; gps; gps = gps->next) { /* skip strokes that are invalid for current view */ if (ED_gpencil_stroke_can_use(C, gps) == false) { continue; } for (int i = 0; i < gps->totpoints; i++) { bGPDspoint *pt = &gps->points[i]; if (gps->dvert == NULL) { continue; } MDeformVert *dvert = &gps->dvert[i]; if (defvert_find_index(dvert, def_nr) != NULL) { pt->flag |= GP_SPOINT_SELECT; gps->flag |= GP_STROKE_SELECT; } } } } /* if not multiedit, exit loop*/ if (!is_multiedit) { break; } } } CTX_DATA_END; } /* unselect points of vertex group */ void ED_gpencil_vgroup_deselect(bContext *C, Object *ob) { bGPdata *gpd = (bGPdata *)ob->data; const bool is_multiedit = (bool)GPENCIL_MULTIEDIT_SESSIONS_ON(gpd); const int def_nr = ob->actdef - 1; if (!BLI_findlink(&ob->defbase, def_nr)) { return; } CTX_DATA_BEGIN (C, bGPDlayer *, gpl, editable_gpencil_layers) { bGPDframe *init_gpf = (is_multiedit) ? gpl->frames.first : gpl->actframe; bGPDstroke *gps = NULL; for (bGPDframe *gpf = init_gpf; gpf; gpf = gpf->next) { if ((gpf == gpl->actframe) || ((gpf->flag & GP_FRAME_SELECT) && (is_multiedit))) { if (gpf == NULL) { continue; } for (gps = gpf->strokes.first; gps; gps = gps->next) { /* skip strokes that are invalid for current view */ if (ED_gpencil_stroke_can_use(C, gps) == false) { continue; } for (int i = 0; i < gps->totpoints; i++) { bGPDspoint *pt = &gps->points[i]; if (gps->dvert == NULL) { continue; } MDeformVert *dvert = &gps->dvert[i]; if (defvert_find_index(dvert, def_nr) != NULL) { pt->flag &= ~GP_SPOINT_SELECT; } } } } /* if not multiedit, exit loop*/ if (!is_multiedit) { break; } } } CTX_DATA_END; } /* ******************************************************** */ /* Cursor drawing */ /* check if cursor is in drawing region */ static bool gp_check_cursor_region(bContext *C, int mval_i[2]) { ARegion *ar = CTX_wm_region(C); ScrArea *sa = CTX_wm_area(C); Object *ob = CTX_data_active_object(C); if ((ob == NULL) || (!ELEM(ob->mode, OB_MODE_PAINT_GPENCIL, OB_MODE_SCULPT_GPENCIL, OB_MODE_WEIGHT_GPENCIL))) { return false; } /* TODO: add more spacetypes */ if (!ELEM(sa->spacetype, SPACE_VIEW3D)) { return false; } if ((ar) && (ar->regiontype != RGN_TYPE_WINDOW)) { return false; } else if (ar) { return BLI_rcti_isect_pt_v(&ar->winrct, mval_i); } else { return false; } } /* draw eraser cursor */ void ED_gpencil_brush_draw_eraser(Brush *brush, int x, int y) { short radius = (short)brush->size; GPUVertFormat *format = immVertexFormat(); const uint shdr_pos = GPU_vertformat_attr_add(format, "pos", GPU_COMP_F32, 2, GPU_FETCH_FLOAT); immBindBuiltinProgram(GPU_SHADER_2D_UNIFORM_COLOR); GPU_line_smooth(true); GPU_blend(true); glBlendFuncSeparate(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA, GL_ONE, GL_ONE_MINUS_SRC_ALPHA); immUniformColor4ub(255, 100, 100, 20); imm_draw_circle_fill_2d(shdr_pos, x, y, radius, 40); immUnbindProgram(); immBindBuiltinProgram(GPU_SHADER_2D_LINE_DASHED_UNIFORM_COLOR); float viewport_size[4]; glGetFloatv(GL_VIEWPORT, viewport_size); immUniform2f("viewport_size", viewport_size[2], viewport_size[3]); immUniformColor4f(1.0f, 0.39f, 0.39f, 0.78f); immUniform1i("colors_len", 0); /* "simple" mode */ immUniform1f("dash_width", 12.0f); immUniform1f("dash_factor", 0.5f); imm_draw_circle_wire_2d(shdr_pos, x, y, radius, /* XXX Dashed shader gives bad results with sets of small segments * currently, temp hack around the issue. :( */ max_ii(8, radius / 2)); /* was fixed 40 */ immUnbindProgram(); GPU_blend(false); GPU_line_smooth(false); } static bool gp_brush_cursor_poll(bContext *C) { if (WM_toolsystem_active_tool_is_brush(C)) { return true; } return false; } /* Helper callback for drawing the cursor itself */ static void gp_brush_cursor_draw(bContext *C, int x, int y, void *customdata) { Scene *scene = CTX_data_scene(C); Object *ob = CTX_data_active_object(C); ARegion *ar = CTX_wm_region(C); GP_Sculpt_Settings *gset = &scene->toolsettings->gp_sculpt; bGPdata *gpd = ED_gpencil_data_get_active(C); GP_Sculpt_Data *gp_brush = NULL; Brush *brush = NULL; Material *ma = NULL; MaterialGPencilStyle *gp_style = NULL; float *last_mouse_position = customdata; if ((gpd) && (gpd->flag & GP_DATA_STROKE_WEIGHTMODE)) { gp_brush = &gset->brush[gset->weighttype]; } else { gp_brush = &gset->brush[gset->brushtype]; } /* default radius and color */ float color[3] = {1.0f, 1.0f, 1.0f}; float darkcolor[3]; float radius = 3.0f; int mval_i[2] = {x, y}; /* check if cursor is in drawing region and has valid datablock */ if ((!gp_check_cursor_region(C, mval_i)) || (gpd == NULL)) { return; } /* for paint use paint brush size and color */ if (gpd->flag & GP_DATA_STROKE_PAINTMODE) { brush = scene->toolsettings->gp_paint->paint.brush; if ((brush == NULL) || (brush->gpencil_settings == NULL)) { return; } /* while drawing hide */ if ((gpd->runtime.sbuffer_used > 0) && ((brush->gpencil_settings->flag & GP_BRUSH_STABILIZE_MOUSE) == 0) && ((brush->gpencil_settings->flag & GP_BRUSH_STABILIZE_MOUSE_TEMP) == 0)) { return; } if ((brush->gpencil_settings->flag & GP_BRUSH_ENABLE_CURSOR) == 0) { return; } /* eraser has special shape and use a different shader program */ if (brush->gpencil_tool == GPAINT_TOOL_ERASE) { ED_gpencil_brush_draw_eraser(brush, x, y); return; } /* get current drawing color */ ma = BKE_gpencil_object_material_get_from_brush(ob, brush); if (ma) { gp_style = ma->gp_style; /* after some testing, display the size of the brush is not practical because * is too disruptive and the size of cursor does not change with zoom factor. * The decision was to use a fix size, instead of brush->thickness value. */ if ((gp_style) && (GPENCIL_PAINT_MODE(gpd)) && ((brush->gpencil_settings->flag & GP_BRUSH_STABILIZE_MOUSE) == 0) && ((brush->gpencil_settings->flag & GP_BRUSH_STABILIZE_MOUSE_TEMP) == 0) && (brush->gpencil_tool == GPAINT_TOOL_DRAW)) { radius = 2.0f; copy_v3_v3(color, gp_style->stroke_rgba); } else { radius = 5.0f; copy_v3_v3(color, brush->add_col); } } } /* for sculpt use sculpt brush size */ if (GPENCIL_SCULPT_OR_WEIGHT_MODE(gpd)) { if (gp_brush) { if ((gp_brush->flag & GP_SCULPT_FLAG_ENABLE_CURSOR) == 0) { return; } radius = gp_brush->size; if (gp_brush->flag & (GP_SCULPT_FLAG_INVERT | GP_SCULPT_FLAG_TMP_INVERT)) { copy_v3_v3(color, gp_brush->curcolor_sub); } else { copy_v3_v3(color, gp_brush->curcolor_add); } } } /* draw icon */ GPUVertFormat *format = immVertexFormat(); uint pos = GPU_vertformat_attr_add(format, "pos", GPU_COMP_F32, 2, GPU_FETCH_FLOAT); immBindBuiltinProgram(GPU_SHADER_2D_UNIFORM_COLOR); GPU_line_smooth(true); GPU_blend(true); /* Inner Ring: Color from UI panel */ immUniformColor4f(color[0], color[1], color[2], 0.8f); if ((gp_style) && (GPENCIL_PAINT_MODE(gpd)) && ((brush->gpencil_settings->flag & GP_BRUSH_STABILIZE_MOUSE) == 0) && ((brush->gpencil_settings->flag & GP_BRUSH_STABILIZE_MOUSE_TEMP) == 0) && (brush->gpencil_tool == GPAINT_TOOL_DRAW)) { imm_draw_circle_fill_2d(pos, x, y, radius, 40); } else { imm_draw_circle_wire_2d(pos, x, y, radius, 40); } /* Outer Ring: Dark color for contrast on light backgrounds (e.g. gray on white) */ mul_v3_v3fl(darkcolor, color, 0.40f); immUniformColor4f(darkcolor[0], darkcolor[1], darkcolor[2], 0.8f); imm_draw_circle_wire_2d(pos, x, y, radius + 1, 40); GPU_blend(false); GPU_line_smooth(false); /* Draw line for lazy mouse */ if ((last_mouse_position) && (brush->gpencil_settings->flag & GP_BRUSH_STABILIZE_MOUSE_TEMP)) { GPU_line_smooth(true); GPU_blend(true); copy_v3_v3(color, brush->add_col); immUniformColor4f(color[0], color[1], color[2], 0.8f); immBegin(GPU_PRIM_LINES, 2); immVertex2f(pos, x, y); immVertex2f( pos, last_mouse_position[0] + ar->winrct.xmin, last_mouse_position[1] + ar->winrct.ymin); immEnd(); GPU_blend(false); GPU_line_smooth(false); } immUnbindProgram(); } /* Turn brush cursor in on/off */ void ED_gpencil_toggle_brush_cursor(bContext *C, bool enable, void *customdata) { Scene *scene = CTX_data_scene(C); GP_Sculpt_Settings *gset = &scene->toolsettings->gp_sculpt; float *lastpost = customdata; if (gset->paintcursor && !enable) { /* clear cursor */ WM_paint_cursor_end(CTX_wm_manager(C), gset->paintcursor); gset->paintcursor = NULL; } else if (enable) { /* in some situations cursor could be duplicated, so it is better disable first if exist */ if (gset->paintcursor) { /* clear cursor */ WM_paint_cursor_end(CTX_wm_manager(C), gset->paintcursor); gset->paintcursor = NULL; } /* enable cursor */ gset->paintcursor = WM_paint_cursor_activate(CTX_wm_manager(C), SPACE_TYPE_ANY, RGN_TYPE_ANY, gp_brush_cursor_poll, gp_brush_cursor_draw, (lastpost) ? customdata : NULL); } } /* verify if is using the right brush */ static void gpencil_verify_brush_type(bContext *C, int newmode) { ToolSettings *ts = CTX_data_tool_settings(C); GP_Sculpt_Settings *gset = &ts->gp_sculpt; switch (newmode) { case OB_MODE_SCULPT_GPENCIL: gset->flag &= ~GP_SCULPT_SETT_FLAG_WEIGHT_MODE; if ((gset->brushtype < 0) || (gset->brushtype >= GP_SCULPT_TYPE_WEIGHT)) { gset->brushtype = GP_SCULPT_TYPE_PUSH; } break; case OB_MODE_WEIGHT_GPENCIL: gset->flag |= GP_SCULPT_SETT_FLAG_WEIGHT_MODE; if ((gset->weighttype < GP_SCULPT_TYPE_WEIGHT) || (gset->weighttype >= GP_SCULPT_TYPE_MAX)) { gset->weighttype = GP_SCULPT_TYPE_WEIGHT; } break; default: break; } } /* set object modes */ void ED_gpencil_setup_modes(bContext *C, bGPdata *gpd, int newmode) { if (!gpd) { return; } switch (newmode) { case OB_MODE_EDIT_GPENCIL: gpd->flag |= GP_DATA_STROKE_EDITMODE; gpd->flag &= ~GP_DATA_STROKE_PAINTMODE; gpd->flag &= ~GP_DATA_STROKE_SCULPTMODE; gpd->flag &= ~GP_DATA_STROKE_WEIGHTMODE; ED_gpencil_toggle_brush_cursor(C, false, NULL); break; case OB_MODE_PAINT_GPENCIL: gpd->flag &= ~GP_DATA_STROKE_EDITMODE; gpd->flag |= GP_DATA_STROKE_PAINTMODE; gpd->flag &= ~GP_DATA_STROKE_SCULPTMODE; gpd->flag &= ~GP_DATA_STROKE_WEIGHTMODE; ED_gpencil_toggle_brush_cursor(C, true, NULL); break; case OB_MODE_SCULPT_GPENCIL: gpd->flag &= ~GP_DATA_STROKE_EDITMODE; gpd->flag &= ~GP_DATA_STROKE_PAINTMODE; gpd->flag |= GP_DATA_STROKE_SCULPTMODE; gpd->flag &= ~GP_DATA_STROKE_WEIGHTMODE; gpencil_verify_brush_type(C, OB_MODE_SCULPT_GPENCIL); ED_gpencil_toggle_brush_cursor(C, true, NULL); break; case OB_MODE_WEIGHT_GPENCIL: gpd->flag &= ~GP_DATA_STROKE_EDITMODE; gpd->flag &= ~GP_DATA_STROKE_PAINTMODE; gpd->flag &= ~GP_DATA_STROKE_SCULPTMODE; gpd->flag |= GP_DATA_STROKE_WEIGHTMODE; gpencil_verify_brush_type(C, OB_MODE_WEIGHT_GPENCIL); ED_gpencil_toggle_brush_cursor(C, true, NULL); break; default: gpd->flag &= ~GP_DATA_STROKE_EDITMODE; gpd->flag &= ~GP_DATA_STROKE_PAINTMODE; gpd->flag &= ~GP_DATA_STROKE_SCULPTMODE; gpd->flag &= ~GP_DATA_STROKE_WEIGHTMODE; ED_gpencil_toggle_brush_cursor(C, false, NULL); break; } } /* helper to convert 2d to 3d for simple drawing buffer */ static void gpencil_stroke_convertcoords(ARegion *ar, const tGPspoint *point2D, float origin[3], float out[3]) { float mval_f[2] = {(float)point2D->x, (float)point2D->y}; float mval_prj[2]; float rvec[3], dvec[3]; float zfac; copy_v3_v3(rvec, origin); zfac = ED_view3d_calc_zfac(ar->regiondata, rvec, NULL); if (ED_view3d_project_float_global(ar, rvec, mval_prj, V3D_PROJ_TEST_NOP) == V3D_PROJ_RET_OK) { sub_v2_v2v2(mval_f, mval_prj, mval_f); ED_view3d_win_to_delta(ar, mval_f, dvec, zfac); sub_v3_v3v3(out, rvec, dvec); } else { zero_v3(out); } } /* convert 2d tGPspoint to 3d bGPDspoint */ void ED_gpencil_tpoint_to_point(ARegion *ar, float origin[3], const tGPspoint *tpt, bGPDspoint *pt) { float p3d[3]; /* conversion to 3d format */ gpencil_stroke_convertcoords(ar, tpt, origin, p3d); copy_v3_v3(&pt->x, p3d); pt->pressure = tpt->pressure; pt->strength = tpt->strength; pt->uv_fac = tpt->uv_fac; pt->uv_rot = tpt->uv_rot; } /* texture coordinate utilities */ void ED_gpencil_calc_stroke_uv(Object *ob, bGPDstroke *gps) { if (gps == NULL) { return; } MaterialGPencilStyle *gp_style = BKE_material_gpencil_settings_get(ob, gps->mat_nr + 1); float pixsize; if (gp_style) { pixsize = gp_style->texture_pixsize / 1000000.0f; } else { /* use this value by default */ pixsize = 0.0001f; } pixsize = MAX2(pixsize, 0.0000001f); bGPDspoint *pt = NULL; bGPDspoint *ptb = NULL; int i; float totlen = 0.0f; /* first read all points and calc distance */ for (i = 0; i < gps->totpoints; i++) { pt = &gps->points[i]; /* first point */ if (i == 0) { pt->uv_fac = 0.0f; continue; } ptb = &gps->points[i - 1]; totlen += len_v3v3(&pt->x, &ptb->x) / pixsize; pt->uv_fac = totlen; } /* normalize the distance using a factor */ float factor; /* if image, use texture width */ if ((gp_style) && (gp_style->stroke_style == GP_STYLE_STROKE_STYLE_TEXTURE) && (gp_style->sima)) { factor = gp_style->sima->gen_x; } else if (totlen == 0) { return; } else { factor = totlen; } for (i = 0; i < gps->totpoints; i++) { pt = &gps->points[i]; pt->uv_fac /= factor; } } /* recalc uv for any stroke using the material */ void ED_gpencil_update_color_uv(Main *bmain, Material *mat) { Material *gps_ma = NULL; /* read all strokes */ for (Object *ob = bmain->objects.first; ob; ob = ob->id.next) { if (ob->type == OB_GPENCIL) { bGPdata *gpd = ob->data; if (gpd == NULL) { continue; } for (bGPDlayer *gpl = gpd->layers.first; gpl; gpl = gpl->next) { /* only editable and visible layers are considered */ if (gpencil_layer_is_editable(gpl)) { for (bGPDframe *gpf = gpl->frames.first; gpf; gpf = gpf->next) { for (bGPDstroke *gps = gpf->strokes.first; gps; gps = gps->next) { /* check if it is editable */ if (ED_gpencil_stroke_color_use(ob, gpl, gps) == false) { continue; } gps_ma = give_current_material(ob, gps->mat_nr + 1); /* update */ if ((gps_ma) && (gps_ma == mat)) { ED_gpencil_calc_stroke_uv(ob, gps); } } } } } DEG_id_tag_update(&gpd->id, ID_RECALC_TRANSFORM | ID_RECALC_GEOMETRY); } } } static bool gpencil_check_collision(bGPDstroke *gps, bGPDstroke **gps_array, GHash *all_2d, int totstrokes, float p2d_a1[2], float p2d_a2[2], float r_hit[2]) { bool hit = false; /* check segment with all segments of all strokes */ for (int s = 0; s < totstrokes; s++) { bGPDstroke *gps_iter = gps_array[s]; if (gps_iter->totpoints < 2) { continue; } /* get stroke 2d version */ float(*points2d)[2] = BLI_ghash_lookup(all_2d, gps_iter); for (int i2 = 0; i2 < gps_iter->totpoints - 1; i2++) { float p2d_b1[2], p2d_b2[2]; copy_v2_v2(p2d_b1, points2d[i2]); copy_v2_v2(p2d_b2, points2d[i2 + 1]); /* don't self check */ if (gps == gps_iter) { if (equals_v2v2(p2d_a1, p2d_b1) || equals_v2v2(p2d_a1, p2d_b2)) { continue; } if (equals_v2v2(p2d_a2, p2d_b1) || equals_v2v2(p2d_a2, p2d_b2)) { continue; } } /* check collision */ int check = isect_seg_seg_v2_point(p2d_a1, p2d_a2, p2d_b1, p2d_b2, r_hit); if (check > 0) { hit = true; break; } } if (hit) { break; } } if (!hit) { zero_v2(r_hit); } return hit; } static void gp_copy_points(bGPDstroke *gps, bGPDspoint *pt, bGPDspoint *pt_final, int i, int i2) { /* don't copy same point */ if (i == i2) { return; } copy_v3_v3(&pt_final->x, &pt->x); pt_final->pressure = pt->pressure; pt_final->strength = pt->strength; pt_final->time = pt->time; pt_final->flag = pt->flag; pt_final->uv_fac = pt->uv_fac; pt_final->uv_rot = pt->uv_rot; if (gps->dvert != NULL) { MDeformVert *dvert = &gps->dvert[i]; MDeformVert *dvert_final = &gps->dvert[i2]; MEM_SAFE_FREE(dvert_final->dw); dvert_final->totweight = dvert->totweight; if (dvert->dw == NULL) { dvert_final->dw = NULL; dvert_final->totweight = 0; } else { dvert_final->dw = MEM_dupallocN(dvert->dw); } } } static void gp_insert_point( bGPDstroke *gps, bGPDspoint *a_pt, bGPDspoint *b_pt, float co_a[3], float co_b[3]) { bGPDspoint *temp_points; int totnewpoints, oldtotpoints; totnewpoints = gps->totpoints; if (a_pt) { totnewpoints++; } if (b_pt) { totnewpoints++; } /* duplicate points in a temp area */ temp_points = MEM_dupallocN(gps->points); oldtotpoints = gps->totpoints; /* look index of base points because memory is changed when resize points array */ int a_idx = -1; int b_idx = -1; for (int i = 0; i < oldtotpoints; i++) { bGPDspoint *pt = &gps->points[i]; if (pt == a_pt) { a_idx = i; } if (pt == b_pt) { b_idx = i; } } /* resize the points arrays */ gps->totpoints = totnewpoints; gps->points = MEM_recallocN(gps->points, sizeof(*gps->points) * gps->totpoints); if (gps->dvert != NULL) { gps->dvert = MEM_recallocN(gps->dvert, sizeof(*gps->dvert) * gps->totpoints); } gps->flag |= GP_STROKE_RECALC_GEOMETRY; /* copy all points */ int i2 = 0; for (int i = 0; i < oldtotpoints; i++) { bGPDspoint *pt = &temp_points[i]; bGPDspoint *pt_final = &gps->points[i2]; gp_copy_points(gps, pt, pt_final, i, i2); /* create new point duplicating point and copy location */ if ((i == a_idx) || (i == b_idx)) { i2++; pt_final = &gps->points[i2]; gp_copy_points(gps, pt, pt_final, i, i2); copy_v3_v3(&pt_final->x, (i == a_idx) ? co_a : co_b); /* unselect */ pt_final->flag &= ~GP_SPOINT_SELECT; /* tag to avoid more checking with this point */ pt_final->flag |= GP_SPOINT_TAG; } i2++; } MEM_SAFE_FREE(temp_points); } static float gp_calc_factor(float p2d_a1[2], float p2d_a2[2], float r_hit2d[2]) { float dist1 = len_squared_v2v2(p2d_a1, p2d_a2); float dist2 = len_squared_v2v2(p2d_a1, r_hit2d); float f = dist1 > 0.0f ? dist2 / dist1 : 0.0f; /* apply a correction factor */ float v1[2]; interp_v2_v2v2(v1, p2d_a1, p2d_a2, f); float dist3 = len_squared_v2v2(p2d_a1, v1); float f1 = dist1 > 0.0f ? dist3 / dist1 : 0.0f; f = f + (f - f1); return f; } /* extend selection to stroke intersections */ int ED_gpencil_select_stroke_segment(bGPDlayer *gpl, bGPDstroke *gps, bGPDspoint *pt, bool select, bool insert, const float scale, float r_hita[3], float r_hitb[3]) { const float min_factor = 0.0015f; bGPDspoint *pta1 = NULL; bGPDspoint *pta2 = NULL; float f = 0.0f; int i2 = 0; bGPDframe *gpf = gpl->actframe; if (gpf == NULL) { return 0; } int memsize = BLI_listbase_count(&gpf->strokes); bGPDstroke **gps_array = MEM_callocN(sizeof(bGPDstroke *) * memsize, __func__); /* save points */ bGPDspoint *oldpoints = MEM_dupallocN(gps->points); /* Save list of strokes to check */ int totstrokes = 0; for (bGPDstroke *gps_iter = gpf->strokes.first; gps_iter; gps_iter = gps_iter->next) { if (gps_iter->totpoints < 2) { continue; } gps_array[totstrokes] = gps_iter; totstrokes++; } if (totstrokes == 0) { return 0; } /* look for index of the current point */ int cur_idx = -1; for (int i = 0; i < gps->totpoints; i++) { pta1 = &gps->points[i]; if (pta1 == pt) { cur_idx = i; break; } } if (cur_idx < 0) { return 0; } /* convert all gps points to 2d and save in a hash to avoid recalculation */ int direction = 0; float(*points2d)[2] = MEM_mallocN(sizeof(*points2d) * gps->totpoints, "GP Stroke temp 2d points"); BKE_gpencil_stroke_2d_flat_ref( gps->points, gps->totpoints, gps->points, gps->totpoints, points2d, scale, &direction); GHash *all_2d = BLI_ghash_ptr_new(__func__); for (int s = 0; s < totstrokes; s++) { bGPDstroke *gps_iter = gps_array[s]; float(*points2d_iter)[2] = MEM_mallocN(sizeof(*points2d_iter) * gps_iter->totpoints, __func__); /* the extremes of the stroke are scaled to improve collision detection * for near lines */ BKE_gpencil_stroke_2d_flat_ref(gps->points, gps->totpoints, gps_iter->points, gps_iter->totpoints, points2d_iter, scale, &direction); BLI_ghash_insert(all_2d, gps_iter, points2d_iter); } bool hit_a = false; bool hit_b = false; float p2d_a1[2] = {0.0f, 0.0f}; float p2d_a2[2] = {0.0f, 0.0f}; float r_hit2d[2]; bGPDspoint *hit_pointa = NULL; bGPDspoint *hit_pointb = NULL; /* analyze points before current */ if (cur_idx > 0) { for (int i = cur_idx; i >= 0; i--) { pta1 = &gps->points[i]; copy_v2_v2(p2d_a1, points2d[i]); i2 = i - 1; CLAMP_MIN(i2, 0); pta2 = &gps->points[i2]; copy_v2_v2(p2d_a2, points2d[i2]); hit_a = gpencil_check_collision(gps, gps_array, all_2d, totstrokes, p2d_a1, p2d_a2, r_hit2d); if (select) { pta1->flag |= GP_SPOINT_SELECT; } else { pta1->flag &= ~GP_SPOINT_SELECT; } if (hit_a) { f = gp_calc_factor(p2d_a1, p2d_a2, r_hit2d); interp_v3_v3v3(r_hita, &pta1->x, &pta2->x, f); if (f > min_factor) { hit_pointa = pta2; /* first point is second (inverted loop) */ } else { pta1->flag &= ~GP_SPOINT_SELECT; } break; } } } /* analyze points after current */ for (int i = cur_idx; i < gps->totpoints; i++) { pta1 = &gps->points[i]; copy_v2_v2(p2d_a1, points2d[i]); i2 = i + 1; CLAMP_MAX(i2, gps->totpoints - 1); pta2 = &gps->points[i2]; copy_v2_v2(p2d_a2, points2d[i2]); hit_b = gpencil_check_collision(gps, gps_array, all_2d, totstrokes, p2d_a1, p2d_a2, r_hit2d); if (select) { pta1->flag |= GP_SPOINT_SELECT; } else { pta1->flag &= ~GP_SPOINT_SELECT; } if (hit_b) { f = gp_calc_factor(p2d_a1, p2d_a2, r_hit2d); interp_v3_v3v3(r_hitb, &pta1->x, &pta2->x, f); if (f > min_factor) { hit_pointb = pta1; } else { pta1->flag &= ~GP_SPOINT_SELECT; } break; } } /* insert new point in the collision points */ if (insert) { gp_insert_point(gps, hit_pointa, hit_pointb, r_hita, r_hitb); } /* free memory */ if (all_2d) { GHashIterator gh_iter; GHASH_ITER (gh_iter, all_2d) { float(*p2d)[2] = BLI_ghashIterator_getValue(&gh_iter); MEM_SAFE_FREE(p2d); } BLI_ghash_free(all_2d, NULL, NULL); } /* if no hit, reset selection flag */ if ((!hit_a) && (!hit_b)) { for (int i = 0; i < gps->totpoints; i++) { pta1 = &gps->points[i]; pta2 = &oldpoints[i]; pta1->flag = pta2->flag; } } MEM_SAFE_FREE(points2d); MEM_SAFE_FREE(gps_array); MEM_SAFE_FREE(oldpoints); /* return type of hit */ if ((hit_a) && (hit_b)) { return 3; } else if (hit_a) { return 1; } else if (hit_b) { return 2; } else { return 0; } } void ED_gpencil_select_toggle_all(bContext *C, int action) { /* for "toggle", test for existing selected strokes */ if (action == SEL_TOGGLE) { action = SEL_SELECT; CTX_DATA_BEGIN (C, bGPDstroke *, gps, editable_gpencil_strokes) { if (gps->flag & GP_STROKE_SELECT) { action = SEL_DESELECT; break; // XXX: this only gets out of the inner loop... } } CTX_DATA_END; } /* if deselecting, we need to deselect strokes across all frames * - Currently, an exception is only given for deselection * Selecting and toggling should only affect what's visible, * while deselecting helps clean up unintended/forgotten * stuff on other frames */ if (action == SEL_DESELECT) { /* deselect strokes across editable layers * NOTE: we limit ourselves to editable layers, since once a layer is "locked/hidden * nothing should be able to touch it */ CTX_DATA_BEGIN (C, bGPDlayer *, gpl, editable_gpencil_layers) { bGPDframe *gpf; /* deselect all strokes on all frames */ for (gpf = gpl->frames.first; gpf; gpf = gpf->next) { bGPDstroke *gps; for (gps = gpf->strokes.first; gps; gps = gps->next) { bGPDspoint *pt; int i; /* only edit strokes that are valid in this view... */ if (ED_gpencil_stroke_can_use(C, gps)) { for (i = 0, pt = gps->points; i < gps->totpoints; i++, pt++) { pt->flag &= ~GP_SPOINT_SELECT; } gps->flag &= ~GP_STROKE_SELECT; } } } } CTX_DATA_END; } else { /* select or deselect all strokes */ CTX_DATA_BEGIN (C, bGPDstroke *, gps, editable_gpencil_strokes) { bGPDspoint *pt; int i; bool selected = false; /* Change selection status of all points, then make the stroke match */ for (i = 0, pt = gps->points; i < gps->totpoints; i++, pt++) { switch (action) { case SEL_SELECT: pt->flag |= GP_SPOINT_SELECT; break; // case SEL_DESELECT: // pt->flag &= ~GP_SPOINT_SELECT; // break; case SEL_INVERT: pt->flag ^= GP_SPOINT_SELECT; break; } if (pt->flag & GP_SPOINT_SELECT) { selected = true; } } /* Change status of stroke */ if (selected) { gps->flag |= GP_STROKE_SELECT; } else { gps->flag &= ~GP_STROKE_SELECT; } } CTX_DATA_END; } } /* Ensure the SBuffer (while drawing stroke) size is enough to save all points of the stroke */ tGPspoint *ED_gpencil_sbuffer_ensure(tGPspoint *buffer_array, short *buffer_size, short *buffer_used, const bool clear) { tGPspoint *p = NULL; /* By default a buffer is created with one block with a predefined number of free points, * if the size is not enough, the cache is reallocated adding a new block of free points. * This is done in order to keep cache small and improve speed. */ if (*buffer_used + 1 > *buffer_size) { if ((*buffer_size == 0) || (buffer_array == NULL)) { p = MEM_callocN(sizeof(struct tGPspoint) * GP_STROKE_BUFFER_CHUNK, "GPencil Sbuffer"); *buffer_size = GP_STROKE_BUFFER_CHUNK; } else { *buffer_size += GP_STROKE_BUFFER_CHUNK; p = MEM_recallocN(buffer_array, sizeof(struct tGPspoint) * *buffer_size); } buffer_array = p; } /* clear old data */ if (clear) { *buffer_used = 0; if (buffer_array != NULL) { memset(buffer_array, 0, sizeof(tGPspoint) * *buffer_size); } } return buffer_array; }