author Lukas Treyer Fri, 28 Mar 2014 10:41:56 +0000 (16:41 +0600) committer Sergey Sharybin Fri, 28 Mar 2014 10:44:33 +0000 (16:44 +0600)
Bevel Factor Mapping allows to control the relation between bevel factors
(number between 0 and 1) and the rendered start and end point of a beveled
spline.

There are three options: "Resolution", "Segments", "Spline". "Resolution"
option maps bevel factors as it was done < 2.71, "Spline" and "Segments"
are new.

* "Resolution“: Map the bevel factor to the number of subdivisions of a
spline (U resolution).
* "Segments“: Map the bevel factor to the length of a segment and to the
number of subdivisions of a segment.
* "Spline": Map the bevel factor to the length of a spline.

Reviewers: yakca, sergey, campbellbarton

CC: sanne
Differential Revision: https://developer.blender.org/D294

index 8a3e31d830881b898b89441257d673d668cebb23..acfc4d1e2638235e95e71ebc5b24f50097f1cf49 100644 (file)
@@ -183,13 +183,22 @@ class DATA_PT_geometry_curve(CurveButtonsPanelCurve, Panel):
col.prop(curve, "bevel_object", text="")

col = layout.column(align=True)
col.prop(curve, "bevel_object", text="")

col = layout.column(align=True)
-        col.prop(curve, "bevel_factor_start")
-        col.prop(curve, "bevel_factor_end")
-
row = col.row()
row = col.row()
-        row.active = (curve.bevel_object is not None)
-        row.prop(curve, "use_fill_caps")
+        row.label(text="Bevel Factor:")
+
+        col = layout.column()
+        col.active = (curve.bevel_depth > 0 or curve.bevel_object is not None)
+        row = col.row(align=True)
+        row.prop(curve, "bevel_factor_mapping_start", text="")
+        row.prop(curve, "bevel_factor_start", text="Start")
+        row = col.row(align=True)
+        row.prop(curve, "bevel_factor_mapping_end", text="")
+        row.prop(curve, "bevel_factor_end", text="End")
+
+        row = layout.row()
+        row.active = curve.bevel_object is not None
row.prop(curve, "use_map_taper")
row.prop(curve, "use_map_taper")
+        row.prop(curve, "use_fill_caps")

class DATA_PT_pathanim(CurveButtonsPanelCurve, Panel):

class DATA_PT_pathanim(CurveButtonsPanelCurve, Panel):
index 864682c560712e2ee87638d5a78347c3e62fda4e..44c9bc9ebbe095129fc64513f50e3d2ff0ee08f6 100644 (file)
@@ -182,6 +182,8 @@ Curve *BKE_curve_add(Main *bmain, const char *name, int type)
cu->type = type;
cu->bevfac1 = 0.0f;
cu->bevfac2 = 1.0f;
cu->type = type;
cu->bevfac1 = 0.0f;
cu->bevfac2 = 1.0f;
+       cu->bevfac1_mapping = CU_BEVFAC_MAP_RESOLU;
+       cu->bevfac2_mapping = CU_BEVFAC_MAP_RESOLU;

cu->bb = BKE_boundbox_alloc_unit();

cu->bb = BKE_boundbox_alloc_unit();

index 33cb2c0fb233df837a019400f756cd45e1908815..4b251396376f83cabdd66af6f62d17d6e41a41f2 100644 (file)
@@ -1364,6 +1364,143 @@ static void fillBevelCap(Nurb *nu, DispList *dlb, float *prev_fp, ListBase *disp
}

}

+
+static void calc_bevfac_spline_mapping(BevList *bl, float bevfac, float spline_length, const float *bevp_array,
+                                       int *r_bev, float *r_blend)
+{
+       float len = 0.0f;
+       int i;
+       for (i = 0; i < bl->nr; i++) {
+               *r_bev = i;
+               *r_blend = (bevfac * spline_length - len) / bevp_array[i];
+               if (len + bevp_array[i] > bevfac * spline_length) {
+                       break;
+               }
+               len += bevp_array[i];
+       }
+}
+
+static void calc_bevfac_mapping(Curve *cu, BevList *bl, int *r_start, float *r_firstblend, int *r_steps, float *r_lastblend)
+{
+       BevPoint *bevp, *bevl;
+       float l, startf, endf, tmpf = 0.0, sum = 0.0, total_length = 0.0f;
+       float *bevp_array = NULL;
+       float *segments = NULL;
+       int end = 0, i, j, segcount = (int)(bl->nr / cu->resolu);
+
+       if ((cu->bevfac1_mapping != CU_BEVFAC_MAP_RESOLU) ||
+           (cu->bevfac2_mapping != CU_BEVFAC_MAP_RESOLU))
+       {
+               bevp_array = MEM_mallocN(sizeof(bevp_array) * (bl->nr - 1), "bevp_dists");
+               segments = MEM_callocN(sizeof(segments) * segcount, "bevp_segmentlengths");
+               bevp = (BevPoint *)(bl + 1);
+               bevp++;
+               for (i = 1, j = 0; i < bl->nr; bevp++, i++) {
+                       sum = 0.0f;
+                       bevl = bevp - 1;
+                       bevp_array[i - 1] = len_v3v3(bevp->vec, bevl->vec);
+                       total_length += bevp_array[i - 1];
+                       tmpf += bevp_array[i - 1];
+                       if ((i % cu->resolu) == 0 || (bl->nr - 1) == i) {
+                               segments[j++] = tmpf;
+                               tmpf = 0.0f;
+                       }
+               }
+       }
+
+       switch (cu->bevfac1_mapping) {
+               case CU_BEVFAC_MAP_RESOLU:
+               {
+                       const float start_fl = cu->bevfac1 * (bl->nr - 1);
+                       *r_start = (int)start_fl;
+
+                       *r_firstblend = 1.0f - (start_fl - (*r_start));
+                       break;
+               }
+               case CU_BEVFAC_MAP_SEGMENT:
+               {
+                       const float start_fl = cu->bevfac1 * (bl->nr - 1);
+                       *r_start = (int)start_fl;
+
+                       for (i = 0; i < segcount; i++) {
+                               l = segments[i] / total_length;
+                               if (sum + l > cu->bevfac1) {
+                                       startf = i * cu->resolu + (cu->bevfac1 - sum) / l * cu->resolu;
+                                       *r_start = (int) startf;
+                                       *r_firstblend = 1.0f - (startf - *r_start);
+                                       break;
+                               }
+                               sum += l;
+                       }
+                       break;
+               }
+               case CU_BEVFAC_MAP_SPLINE:
+               {
+                       calc_bevfac_spline_mapping(bl, cu->bevfac1, total_length, bevp_array, r_start, r_firstblend);
+                       *r_firstblend = 1.0f - *r_firstblend;
+                       break;
+               }
+       }
+
+       sum = 0.0f;
+       switch (cu->bevfac2_mapping) {
+               case CU_BEVFAC_MAP_RESOLU:
+               {
+                       const float end_fl = cu->bevfac2 * (bl->nr - 1);
+                       end = (int)end_fl;
+
+                       *r_steps = 2 + end - *r_start;
+                       *r_lastblend = end_fl - end;
+                       break;
+               }
+               case CU_BEVFAC_MAP_SEGMENT:
+               {
+                       const float end_fl = cu->bevfac2 * (bl->nr - 1);
+                       end = (int)end_fl;
+
+                       *r_steps = end - *r_start + 2;
+                       for (i = 0; i < segcount; i++) {
+                               l = segments[i] / total_length;
+                               if (sum + l > cu->bevfac2) {
+                                       endf = i * cu->resolu + (cu->bevfac2 - sum) / l * cu->resolu;
+                                       end = (int)endf;
+                                       *r_lastblend = (endf - end);
+                                       *r_steps = end - *r_start + 2;
+                                       break;
+                               }
+                               sum += l;
+                       }
+                       break;
+               }
+               case CU_BEVFAC_MAP_SPLINE:
+               {
+                       calc_bevfac_spline_mapping(bl, cu->bevfac2, total_length, bevp_array, &end, r_lastblend);
+                       *r_steps = end - *r_start + 2;
+                       break;
+               }
+       }
+
+       if (end < *r_start) {
+               SWAP(int, *r_start, end);
+               tmpf = *r_lastblend;
+               *r_lastblend = 1.0f - *r_firstblend;
+               *r_firstblend = 1.0f - tmpf;
+               *r_steps = end - *r_start + 2;
+       }
+
+       if (*r_start + *r_steps > bl->nr) {
+               *r_steps = bl->nr - *r_start;
+               *r_lastblend = 1.0f;
+       }
+
+       if (bevp_array) {
+               MEM_freeN(bevp_array);
+       }
+       if (segments) {
+               MEM_freeN(segments);
+       }
+}
+
static void do_makeDispListCurveTypes(Scene *scene, Object *ob, ListBase *dispbase,
DerivedMesh **r_dm_final,
const bool for_render, const bool for_orco, const bool use_render_resolution)
static void do_makeDispListCurveTypes(Scene *scene, Object *ob, ListBase *dispbase,
DerivedMesh **r_dm_final,
const bool for_render, const bool for_orco, const bool use_render_resolution)
@@ -1460,25 +1597,12 @@ static void do_makeDispListCurveTypes(Scene *scene, Object *ob, ListBase *dispba
ListBase top_capbase = {NULL, NULL};
float bottom_no[3] = {0.0f};
float top_no[3] = {0.0f};
ListBase top_capbase = {NULL, NULL};
float bottom_no[3] = {0.0f};
float top_no[3] = {0.0f};
+                                               float firstblend = 0.0f, lastblend = 0.0f;
+                                               int i, start, steps;
+
+                                               calc_bevfac_mapping(cu, bl, &start, &firstblend, &steps, &lastblend);

for (dlb = dlbev.first; dlb; dlb = dlb->next) {

for (dlb = dlbev.first; dlb; dlb = dlb->next) {
-                                                       const float bevfac1 = min_ff(cu->bevfac1, cu->bevfac2);
-                                                       const float bevfac2 = max_ff(cu->bevfac1, cu->bevfac2);
-                                                       float firstblend = 0.0f, lastblend = 0.0f;
-                                                       int i, start, steps;
-
-                                                       if (bevfac2 - bevfac1 == 0.0f)
-                                                               continue;
-
-                                                       start = (int)(bevfac1 * (bl->nr - 1));
-                                                       steps = 2 + (int)((bevfac2) * (bl->nr - 1)) - start;
-                                                       firstblend = 1.0f - (bevfac1 * (bl->nr - 1) - (int)(bevfac1 * (bl->nr - 1)));
-                                                       lastblend  =         bevfac2 * (bl->nr - 1) - (int)(bevfac2 * (bl->nr - 1));
-
-                                                       if (start + steps > bl->nr) {
-                                                               steps = bl->nr - start;
-                                                               lastblend = 1.0f;
-                                                       }

/* for each part of the bevel use a separate displblock */
dl = MEM_callocN(sizeof(DispList), "makeDispListbev1");

/* for each part of the bevel use a separate displblock */
dl = MEM_callocN(sizeof(DispList), "makeDispListbev1");
index 30d8bf429f013000b3806039fa7f202a6165462f..8fadfa69facec159d9222a54df6b9841e0254119 100644 (file)
@@ -34,6 +34,7 @@
/* allow readfile to use deprecated functionality */
#define DNA_DEPRECATED_ALLOW

/* allow readfile to use deprecated functionality */
#define DNA_DEPRECATED_ALLOW

+#include "DNA_curve_types.h"
#include "DNA_sdna_types.h"
#include "DNA_space_types.h"
#include "DNA_screen_types.h"
#include "DNA_sdna_types.h"
#include "DNA_space_types.h"
#include "DNA_screen_types.h"
index ebba59ec7857c665aacc106a67a62f1f9ddd692f..0c9e9b01a76c5a58e5c3115ef3dbeb2a370d86a2 100644 (file)
@@ -257,8 +257,10 @@ typedef struct Curve {

float ctime;                    /* current evaltime - for use by Objects parented to curves */
float bevfac1, bevfac2;

float ctime;                    /* current evaltime - for use by Objects parented to curves */
float bevfac1, bevfac2;
+       char bevfac1_mapping, bevfac2_mapping;
+

} Curve;

/* **************** CURVE ********************* */
} Curve;

/* **************** CURVE ********************* */
@@ -295,6 +297,13 @@ typedef struct Curve {
#define CU_TWIST_MINIMUM               3
#define CU_TWIST_TANGENT               4

#define CU_TWIST_MINIMUM               3
#define CU_TWIST_TANGENT               4

+/* bevel factor mapping */
+enum {
+       CU_BEVFAC_MAP_RESOLU = 0,
+       CU_BEVFAC_MAP_SEGMENT = 1,
+       CU_BEVFAC_MAP_SPLINE = 2
+};
+
/* spacemode */
#define CU_LEFT                        0
#define CU_MIDDLE              1
/* spacemode */
#define CU_LEFT                        0
#define CU_MIDDLE              1
index ee6d9df1726ba79d86020f47c204815f3e89addd..31709f902493847e91fe6bb4648dfbe159a7b3ef 100644 (file)
@@ -1326,7 +1326,14 @@ static void rna_def_curve(BlenderRNA *brna)
"Allow editing on the Z axis of this curve, also allows tilt and curve radius to be used"},
{0, NULL, 0, NULL, NULL}
};
"Allow editing on the Z axis of this curve, also allows tilt and curve radius to be used"},
{0, NULL, 0, NULL, NULL}
};
-
+
+       static EnumPropertyItem bevfac_mapping_items[] = {
+               {CU_BEVFAC_MAP_RESOLU, "RESOLUTION", 0, "Resolution", "Map the bevel factor to the number of subdivisions of a spline (U resolution)"},
+               {CU_BEVFAC_MAP_SEGMENT, "SEGMENTS", 0, "Segments", "Map the bevel factor to the length of a segment and to the number of subdivisions of a segment"},
+               {CU_BEVFAC_MAP_SPLINE, "SPLINE", 0, "Spline", "Map the bevel factor to the length of a spline"},
+               {0, NULL, 0, NULL, NULL}
+       };
+
srna = RNA_def_struct(brna, "Curve", "ID");
RNA_def_struct_ui_text(srna, "Curve", "Curve datablock storing curves, splines and NURBS");
RNA_def_struct_ui_icon(srna, ICON_CURVE_DATA);
srna = RNA_def_struct(brna, "Curve", "ID");
RNA_def_struct_ui_text(srna, "Curve", "Curve datablock storing curves, splines and NURBS");
RNA_def_struct_ui_icon(srna, ICON_CURVE_DATA);
@@ -1469,6 +1476,18 @@ static void rna_def_curve(BlenderRNA *brna)
RNA_def_property_ui_text(prop, "Twist Method", "The type of tilt calculation for 3D Curves");
RNA_def_property_update(prop, 0, "rna_Curve_update_data");

RNA_def_property_ui_text(prop, "Twist Method", "The type of tilt calculation for 3D Curves");
RNA_def_property_update(prop, 0, "rna_Curve_update_data");

+       prop = RNA_def_property(srna, "bevel_factor_mapping_start", PROP_ENUM, PROP_NONE);
+       RNA_def_property_enum_sdna(prop, NULL, "bevfac1_mapping");
+       RNA_def_property_enum_items(prop, bevfac_mapping_items);
+       RNA_def_property_ui_text(prop, "Start Mapping Type", "Determines how the start bevel factor is mappend to a spline");
+       RNA_def_property_update(prop, 0, "rna_Curve_update_data");
+
+       prop = RNA_def_property(srna, "bevel_factor_mapping_end", PROP_ENUM, PROP_NONE);
+       RNA_def_property_enum_sdna(prop, NULL, "bevfac2_mapping");
+       RNA_def_property_enum_items(prop, bevfac_mapping_items);
+       RNA_def_property_ui_text(prop, "End Mapping Type", "Determines how the end bevel factor is mappend to a spline");
+       RNA_def_property_update(prop, 0, "rna_Curve_update_data");
+
/* XXX - would be nice to have a better way to do this, only add for testing. */
prop = RNA_def_property(srna, "twist_smooth", PROP_FLOAT, PROP_NONE);
RNA_def_property_float_sdna(prop, NULL, "twist_smooth");
/* XXX - would be nice to have a better way to do this, only add for testing. */
prop = RNA_def_property(srna, "twist_smooth", PROP_FLOAT, PROP_NONE);
RNA_def_property_float_sdna(prop, NULL, "twist_smooth");