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192a28bb32e8888c4477f724bfab036a466458be
blender-archive/source/blender/blenkernel/intern/fcurve.c
Joshua Leung 240babf074 Graph Editor - View All/Selected now includes handles for calculating extents of 
F-Curves

It is possible to get the old behaviour (handles excluded) by bringing up the
Operator Properties (F6) while in the Graph Editor (this doesn't work elsewhere
due to the context requirements of this stuff).
2012-05-24 13:52:25 +00:00

2143 lines
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/*
* ***** BEGIN GPL LICENSE BLOCK *****
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* The Original Code is Copyright (C) 2009 Blender Foundation, Joshua Leung
* All rights reserved.
*
* The Original Code is: all of this file.
*
* Contributor(s): Joshua Leung (full recode)
*
* ***** END GPL LICENSE BLOCK *****
*/
/** \file blender/blenkernel/intern/fcurve.c
* \ingroup bke
*/
#include <math.h>
#include <stdio.h>
#include <stddef.h>
#include <string.h>
#include <float.h>
#include "MEM_guardedalloc.h"
#include "DNA_anim_types.h"
#include "DNA_constraint_types.h"
#include "DNA_object_types.h"
#include "BLI_blenlib.h"
#include "BLI_math.h"
#include "BLI_utildefines.h"
#include "BKE_fcurve.h"
#include "BKE_animsys.h"
#include "BKE_action.h"
#include "BKE_armature.h"
#include "BKE_constraint.h"
#include "BKE_curve.h"
#include "BKE_global.h"
#include "BKE_object.h"
#include "BKE_utildefines.h"
#include "RNA_access.h"
#ifdef WITH_PYTHON
#include "BPY_extern.h"
#endif
#define SMALL -1.0e-10
#define SELECT 1
/* ************************** Data-Level Functions ************************* */
/* ---------------------- Freeing --------------------------- */
/* Frees the F-Curve itself too, so make sure BLI_remlink is called before calling this... */
void free_fcurve(FCurve *fcu)
{
if (fcu == NULL)
return;
/* free curve data */
if (fcu) {
if (fcu->bezt) MEM_freeN(fcu->bezt);
if (fcu->fpt) MEM_freeN(fcu->fpt);
}
/* free RNA-path, as this were allocated when getting the path string */
if (fcu->rna_path)
MEM_freeN(fcu->rna_path);
/* free extra data - i.e. modifiers, and driver */
fcurve_free_driver(fcu);
free_fmodifiers(&fcu->modifiers);
/* free f-curve itself */
MEM_freeN(fcu);
}
/* Frees a list of F-Curves */
void free_fcurves(ListBase *list)
{
FCurve *fcu, *fcn;
/* sanity check */
if (list == NULL)
return;
/* free data - no need to call remlink before freeing each curve,
* as we store reference to next, and freeing only touches the curve
* it's given
*/
for (fcu = list->first; fcu; fcu = fcn) {
fcn = fcu->next;
free_fcurve(fcu);
}
/* clear pointers just in case */
list->first = list->last = NULL;
}
/* ---------------------- Copy --------------------------- */
/* duplicate an F-Curve */
FCurve *copy_fcurve(FCurve *fcu)
{
FCurve *fcu_d;
/* sanity check */
if (fcu == NULL)
return NULL;
/* make a copy */
fcu_d = MEM_dupallocN(fcu);
fcu_d->next = fcu_d->prev = NULL;
fcu_d->grp = NULL;
/* copy curve data */
fcu_d->bezt = MEM_dupallocN(fcu_d->bezt);
fcu_d->fpt = MEM_dupallocN(fcu_d->fpt);
/* copy rna-path */
fcu_d->rna_path = MEM_dupallocN(fcu_d->rna_path);
/* copy driver */
fcu_d->driver = fcurve_copy_driver(fcu_d->driver);
/* copy modifiers */
copy_fmodifiers(&fcu_d->modifiers, &fcu->modifiers);
/* return new data */
return fcu_d;
}
/* duplicate a list of F-Curves */
void copy_fcurves(ListBase *dst, ListBase *src)
{
FCurve *dfcu, *sfcu;
/* sanity checks */
if (ELEM(NULL, dst, src))
return;
/* clear destination list first */
dst->first = dst->last = NULL;
/* copy one-by-one */
for (sfcu = src->first; sfcu; sfcu = sfcu->next) {
dfcu = copy_fcurve(sfcu);
BLI_addtail(dst, dfcu);
}
}
/* ----------------- Finding F-Curves -------------------------- */
/* high level function to get an fcurve from C without having the rna */
FCurve *id_data_find_fcurve(ID *id, void *data, StructRNA *type, const char *prop_name, int index, char *driven)
{
/* anim vars */
AnimData *adt = BKE_animdata_from_id(id);
FCurve *fcu = NULL;
/* rna vars */
PointerRNA ptr;
PropertyRNA *prop;
char *path;
if (driven)
*driven = FALSE;
/* only use the current action ??? */
if (ELEM(NULL, adt, adt->action))
return NULL;
RNA_pointer_create(id, type, data, &ptr);
prop = RNA_struct_find_property(&ptr, prop_name);
if (prop) {
path = RNA_path_from_ID_to_property(&ptr, prop);
if (path) {
/* animation takes priority over drivers */
if ((adt->action) && (adt->action->curves.first))
fcu = list_find_fcurve(&adt->action->curves, path, index);
/* if not animated, check if driven */
if ((fcu == NULL) && (adt->drivers.first)) {
fcu = list_find_fcurve(&adt->drivers, path, index);
if (fcu && driven)
*driven = TRUE;
fcu = NULL;
}
MEM_freeN(path);
}
}
return fcu;
}
/* Find the F-Curve affecting the given RNA-access path + index, in the list of F-Curves provided */
FCurve *list_find_fcurve(ListBase *list, const char rna_path[], const int array_index)
{
FCurve *fcu;
/* sanity checks */
if (ELEM(NULL, list, rna_path) || (array_index < 0) )
return NULL;
/* check paths of curves, then array indices... */
for (fcu = list->first; fcu; fcu = fcu->next) {
/* simple string-compare (this assumes that they have the same root...) */
if (fcu->rna_path && !strcmp(fcu->rna_path, rna_path)) {
/* now check indices */
if (fcu->array_index == array_index)
return fcu;
}
}
/* return */
return NULL;
}
/* quick way to loop over all fcurves of a given 'path' */
FCurve *iter_step_fcurve(FCurve *fcu_iter, const char rna_path[])
{
FCurve *fcu;
/* sanity checks */
if (ELEM(NULL, fcu_iter, rna_path))
return NULL;
/* check paths of curves, then array indices... */
for (fcu = fcu_iter; fcu; fcu = fcu->next) {
/* simple string-compare (this assumes that they have the same root...) */
if (fcu->rna_path && !strcmp(fcu->rna_path, rna_path)) {
return fcu;
}
}
/* return */
return NULL;
}
/* Get list of LinkData's containing pointers to the F-Curves which control the types of data indicated
* Lists...
* - dst: list of LinkData's matching the criteria returned.
* List must be freed after use, and is assumed to be empty when passed.
* - src: list of F-Curves to search through
* Filters...
* - dataPrefix: i.e. 'pose.bones[' or 'nodes['
* - dataName: name of entity within "" immediately following the prefix
*/
int list_find_data_fcurves(ListBase *dst, ListBase *src, const char *dataPrefix, const char *dataName)
{
FCurve *fcu;
int matches = 0;
/* sanity checks */
if (ELEM4(NULL, dst, src, dataPrefix, dataName))
return 0;
else if ((dataPrefix[0] == 0) || (dataName[0] == 0))
return 0;
/* search each F-Curve one by one */
for (fcu = src->first; fcu; fcu = fcu->next) {
/* check if quoted string matches the path */
if ((fcu->rna_path) && strstr(fcu->rna_path, dataPrefix)) {
char *quotedName = BLI_getQuotedStr(fcu->rna_path, dataPrefix);
if (quotedName) {
/* check if the quoted name matches the required name */
if (strcmp(quotedName, dataName) == 0) {
LinkData *ld = MEM_callocN(sizeof(LinkData), "list_find_data_fcurves");
ld->data = fcu;
BLI_addtail(dst, ld);
matches++;
}
/* always free the quoted string, since it needs freeing */
MEM_freeN(quotedName);
}
}
}
/* return the number of matches */
return matches;
}
FCurve *rna_get_fcurve(PointerRNA *ptr, PropertyRNA *prop, int rnaindex, bAction **action, int *driven)
{
FCurve *fcu = NULL;
*driven = 0;
/* there must be some RNA-pointer + property combon */
if (prop && ptr->id.data && RNA_property_animateable(ptr, prop)) {
AnimData *adt = BKE_animdata_from_id(ptr->id.data);
char *path;
if (adt) {
if ((adt->action && adt->action->curves.first) || (adt->drivers.first)) {
/* XXX this function call can become a performance bottleneck */
path = RNA_path_from_ID_to_property(ptr, prop);
if (path) {
/* animation takes priority over drivers */
if (adt->action && adt->action->curves.first)
fcu = list_find_fcurve(&adt->action->curves, path, rnaindex);
/* if not animated, check if driven */
if (!fcu && (adt->drivers.first)) {
fcu = list_find_fcurve(&adt->drivers, path, rnaindex);
if (fcu)
*driven = 1;
}
if (fcu && action)
*action = adt->action;
MEM_freeN(path);
}
}
}
}
return fcu;
}
/* ----------------- Finding Keyframes/Extents -------------------------- */
/* threshold for binary-searching keyframes - threshold here should be good enough for now, but should become userpref */
#define BEZT_BINARYSEARCH_THRESH 0.01f /* was 0.00001, but giving errors */
/* Binary search algorithm for finding where to insert BezTriple. (for use by insert_bezt_fcurve)
* Returns the index to insert at (data already at that index will be offset if replace is 0)
*/
int binarysearch_bezt_index(BezTriple array[], float frame, int arraylen, short *replace)
{
int start = 0, end = arraylen;
int loopbreaker = 0, maxloop = arraylen * 2;
/* initialize replace-flag first */
*replace = 0;
/* sneaky optimisations (don't go through searching process if...):
* - keyframe to be added is to be added out of current bounds
* - keyframe to be added would replace one of the existing ones on bounds
*/
if ((arraylen <= 0) || (array == NULL)) {
printf("Warning: binarysearch_bezt_index() encountered invalid array\n");
return 0;
}
else {
/* check whether to add before/after/on */
float framenum;
/* 'First' Keyframe (when only one keyframe, this case is used) */
framenum = array[0].vec[1][0];
if (IS_EQT(frame, framenum, BEZT_BINARYSEARCH_THRESH)) {
*replace = 1;
return 0;
}
else if (frame < framenum)
return 0;
/* 'Last' Keyframe */
framenum = array[(arraylen - 1)].vec[1][0];
if (IS_EQT(frame, framenum, BEZT_BINARYSEARCH_THRESH)) {
*replace = 1;
return (arraylen - 1);
}
else if (frame > framenum)
return arraylen;
}
/* most of the time, this loop is just to find where to put it
* 'loopbreaker' is just here to prevent infinite loops
*/
for (loopbreaker = 0; (start <= end) && (loopbreaker < maxloop); loopbreaker++) {
/* compute and get midpoint */
int mid = start + ((end - start) / 2); /* we calculate the midpoint this way to avoid int overflows... */
float midfra = array[mid].vec[1][0];
/* check if exactly equal to midpoint */
if (IS_EQT(frame, midfra, BEZT_BINARYSEARCH_THRESH)) {
*replace = 1;
return mid;
}
/* repeat in upper/lower half */
if (frame > midfra)
start = mid + 1;
else if (frame < midfra)
end = mid - 1;
}
/* print error if loop-limit exceeded */
if (loopbreaker == (maxloop - 1)) {
printf("Error: binarysearch_bezt_index() was taking too long\n");
// include debug info
printf("\tround = %d: start = %d, end = %d, arraylen = %d\n", loopbreaker, start, end, arraylen);
}
/* not found, so return where to place it */
return start;
}
/* ...................................... */
/* helper for calc_fcurve_* functions -> find first and last BezTriple to be used */
static void get_fcurve_end_keyframes(FCurve *fcu, BezTriple **first, BezTriple **last,
const short do_sel_only)
{
/* init outputs */
*first = NULL;
*last = NULL;
/* sanity checks */
if (fcu->bezt == NULL)
return;
/* only include selected items? */
if (do_sel_only) {
BezTriple *bezt;
unsigned int i;
/* find first selected */
bezt = fcu->bezt;
for (i = 0; i < fcu->totvert; bezt++, i++) {
if (BEZSELECTED(bezt)) {
*first = bezt;
break;
}
}
/* find last selected */
bezt = ARRAY_LAST_ITEM(fcu->bezt, BezTriple, sizeof(BezTriple), fcu->totvert);
for (i = 0; i < fcu->totvert; bezt--, i++) {
if (BEZSELECTED(bezt)) {
*last = bezt;
break;
}
}
}
else {
/* just full array */
*first = fcu->bezt;
*last = ARRAY_LAST_ITEM(fcu->bezt, BezTriple, sizeof(BezTriple), fcu->totvert);
}
}
/* Calculate the extents of F-Curve's data */
void calc_fcurve_bounds(FCurve *fcu, float *xmin, float *xmax, float *ymin, float *ymax,
const short do_sel_only, const short include_handles)
{
float xminv = 999999999.0f, xmaxv = -999999999.0f;
float yminv = 999999999.0f, ymaxv = -999999999.0f;
short foundvert = FALSE;
unsigned int i;
if (fcu->totvert) {
if (fcu->bezt) {
BezTriple *bezt_first = NULL, *bezt_last = NULL;
if (xmin || xmax) {
/* get endpoint keyframes */
get_fcurve_end_keyframes(fcu, &bezt_first, &bezt_last, do_sel_only);
if (bezt_first) {
BLI_assert(bezt_last != NULL);
if (include_handles) {
xminv = MIN3(xminv, bezt_first->vec[0][0], bezt_first->vec[1][0]);
xmaxv = MAX3(xmaxv, bezt_last->vec[1][0], bezt_last->vec[2][0]);
}
else {
xminv = MIN2(xminv, bezt_first->vec[1][0]);
xmaxv = MAX2(xmaxv, bezt_last->vec[1][0]);
}
}
}
/* only loop over keyframes to find extents for values if needed */
if (ymin || ymax) {
BezTriple *bezt;
for (bezt = fcu->bezt, i = 0; i < fcu->totvert; bezt++, i++) {
if ((do_sel_only == FALSE) || BEZSELECTED(bezt)) {
if (include_handles) {
yminv = MIN4(yminv, bezt->vec[1][1], bezt->vec[0][1], bezt->vec[2][1]);
ymaxv = MAX4(ymaxv, bezt->vec[1][1], bezt->vec[0][1], bezt->vec[2][1]);
}
else {
yminv = MIN2(yminv, bezt->vec[1][1]);
ymaxv = MAX2(ymaxv, bezt->vec[1][1]);
}
foundvert = TRUE;
}
}
}
}
else if (fcu->fpt) {
/* frame range can be directly calculated from end verts */
if (xmin || xmax) {
xminv = MIN2(xminv, fcu->fpt[0].vec[0]);
xmaxv = MAX2(xmaxv, fcu->fpt[fcu->totvert - 1].vec[0]);
}
/* only loop over keyframes to find extents for values if needed */
if (ymin || ymax) {
FPoint *fpt;
for (fpt = fcu->fpt, i = 0; i < fcu->totvert; fpt++, i++) {
if (fpt->vec[1] < yminv)
yminv = fpt->vec[1];
if (fpt->vec[1] > ymaxv)
ymaxv = fpt->vec[1];
foundvert = TRUE;
}
}
}
}
if (foundvert) {
if (xmin) *xmin = xminv;
if (xmax) *xmax = xmaxv;
if (ymin) *ymin = yminv;
if (ymax) *ymax = ymaxv;
}
else {
if (G.debug & G_DEBUG)
printf("F-Curve calc bounds didn't find anything, so assuming minimum bounds of 1.0\n");
if (xmin) *xmin = 0.0f;
if (xmax) *xmax = 1.0f;
if (ymin) *ymin = 0.0f;
if (ymax) *ymax = 1.0f;
}
}
/* Calculate the extents of F-Curve's keyframes */
void calc_fcurve_range(FCurve *fcu, float *start, float *end,
const short do_sel_only, const short do_min_length)
{
float min = 999999999.0f, max = -999999999.0f;
short foundvert = FALSE;
if (fcu->totvert) {
if (fcu->bezt) {
BezTriple *bezt_first = NULL, *bezt_last = NULL;
/* get endpoint keyframes */
get_fcurve_end_keyframes(fcu, &bezt_first, &bezt_last, do_sel_only);
if (bezt_first) {
BLI_assert(bezt_last != NULL);
min = MIN2(min, bezt_first->vec[1][0]);
max = MAX2(max, bezt_last->vec[1][0]);
foundvert = TRUE;
}
}
else if (fcu->fpt) {
min = MIN2(min, fcu->fpt[0].vec[0]);
max = MAX2(max, fcu->fpt[fcu->totvert - 1].vec[0]);
foundvert = TRUE;
}
}
if (foundvert == FALSE) {
min = max = 0.0f;
}
if (do_min_length) {
/* minimum length is 1 frame */
if (min == max) {
max += 1.0f;
}
}
*start = min;
*end = max;
}
/* ----------------- Status Checks -------------------------- */
/* Are keyframes on F-Curve of any use?
* Usability of keyframes refers to whether they should be displayed,
* and also whether they will have any influence on the final result.
*/
short fcurve_are_keyframes_usable(FCurve *fcu)
{
/* F-Curve must exist */
if (fcu == NULL)
return 0;
/* F-Curve must not have samples - samples are mutually exclusive of keyframes */
if (fcu->fpt)
return 0;
/* if it has modifiers, none of these should "drastically" alter the curve */
if (fcu->modifiers.first) {
FModifier *fcm;
/* check modifiers from last to first, as last will be more influential */
// TODO: optionally, only check modifier if it is the active one...
for (fcm = fcu->modifiers.last; fcm; fcm = fcm->prev) {
/* ignore if muted/disabled */
if (fcm->flag & (FMODIFIER_FLAG_DISABLED | FMODIFIER_FLAG_MUTED))
continue;
/* type checks */
switch (fcm->type) {
/* clearly harmless - do nothing */
case FMODIFIER_TYPE_CYCLES:
case FMODIFIER_TYPE_STEPPED:
case FMODIFIER_TYPE_NOISE:
break;
/* sometimes harmful - depending on whether they're "additive" or not */
case FMODIFIER_TYPE_GENERATOR:
{
FMod_Generator *data = (FMod_Generator *)fcm->data;
if ((data->flag & FCM_GENERATOR_ADDITIVE) == 0)
return 0;
}
break;
case FMODIFIER_TYPE_FN_GENERATOR:
{
FMod_FunctionGenerator *data = (FMod_FunctionGenerator *)fcm->data;
if ((data->flag & FCM_GENERATOR_ADDITIVE) == 0)
return 0;
}
break;
/* always harmful - cannot allow */
default:
return 0;
}
}
}
/* keyframes are usable */
return 1;
}
/* Can keyframes be added to F-Curve?
* Keyframes can only be added if they are already visible
*/
short fcurve_is_keyframable(FCurve *fcu)
{
/* F-Curve's keyframes must be "usable" (i.e. visible + have an effect on final result) */
if (fcurve_are_keyframes_usable(fcu) == 0)
return 0;
/* F-Curve must currently be editable too */
if ( (fcu->flag & FCURVE_PROTECTED) || ((fcu->grp) && (fcu->grp->flag & AGRP_PROTECTED)) )
return 0;
/* F-Curve is keyframable */
return 1;
}
/* ***************************** Keyframe Column Tools ********************************* */
/* add a BezTriple to a column */
void bezt_add_to_cfra_elem(ListBase *lb, BezTriple *bezt)
{
CfraElem *ce, *cen;
for (ce = lb->first; ce; ce = ce->next) {
/* double key? */
if (ce->cfra == bezt->vec[1][0]) {
if (bezt->f2 & SELECT) ce->sel = bezt->f2;
return;
}
/* should key be inserted before this column? */
else if (ce->cfra > bezt->vec[1][0]) break;
}
/* create a new column */
cen = MEM_callocN(sizeof(CfraElem), "add_to_cfra_elem");
if (ce) BLI_insertlinkbefore(lb, ce, cen);
else BLI_addtail(lb, cen);
cen->cfra = bezt->vec[1][0];
cen->sel = bezt->f2;
}
/* ***************************** Samples Utilities ******************************* */
/* Some utilities for working with FPoints (i.e. 'sampled' animation curve data, such as
* data imported from BVH/Mocap files), which are specialized for use with high density datasets,
* which BezTriples/Keyframe data are ill equipped to do.
*/
/* Basic sampling callback which acts as a wrapper for evaluate_fcurve()
* 'data' arg here is unneeded here...
*/
float fcurve_samplingcb_evalcurve(FCurve *fcu, void *UNUSED(data), float evaltime)
{
/* assume any interference from drivers on the curve is intended... */
return evaluate_fcurve(fcu, evaltime);
}
/* Main API function for creating a set of sampled curve data, given some callback function
* used to retrieve the values to store.
*/
void fcurve_store_samples(FCurve *fcu, void *data, int start, int end, FcuSampleFunc sample_cb)
{
FPoint *fpt, *new_fpt;
int cfra;
/* sanity checks */
// TODO: make these tests report errors using reports not printf's
if (ELEM(NULL, fcu, sample_cb)) {
printf("Error: No F-Curve with F-Curve Modifiers to Bake\n");
return;
}
if (start >= end) {
printf("Error: Frame range for Sampled F-Curve creation is inappropriate\n");
return;
}
/* set up sample data */
fpt = new_fpt = MEM_callocN(sizeof(FPoint) * (end - start + 1), "FPoint Samples");
/* use the sampling callback at 1-frame intervals from start to end frames */
for (cfra = start; cfra <= end; cfra++, fpt++) {
fpt->vec[0] = (float)cfra;
fpt->vec[1] = sample_cb(fcu, data, (float)cfra);
}
/* free any existing sample/keyframe data on curve */
if (fcu->bezt) MEM_freeN(fcu->bezt);
if (fcu->fpt) MEM_freeN(fcu->fpt);
/* store the samples */
fcu->bezt = NULL;
fcu->fpt = new_fpt;
fcu->totvert = end - start + 1;
}
/* ***************************** F-Curve Sanity ********************************* */
/* The functions here are used in various parts of Blender, usually after some editing
* of keyframe data has occurred. They ensure that keyframe data is properly ordered and
* that the handles are correctly
*/
/* This function recalculates the handles of an F-Curve
* If the BezTriples have been rearranged, sort them first before using this.
*/
void calchandles_fcurve(FCurve *fcu)
{
BezTriple *bezt, *prev, *next;
int a = fcu->totvert;
/* Error checking:
* - need at least two points
* - need bezier keys
* - only bezier-interpolation has handles (for now)
*/
if (ELEM(NULL, fcu, fcu->bezt) || (a < 2) /*|| ELEM(fcu->ipo, BEZT_IPO_CONST, BEZT_IPO_LIN)*/)
return;
/* get initial pointers */
bezt = fcu->bezt;
prev = NULL;
next = (bezt + 1);
/* loop over all beztriples, adjusting handles */
while (a--) {
/* clamp timing of handles to be on either side of beztriple */
if (bezt->vec[0][0] > bezt->vec[1][0]) bezt->vec[0][0] = bezt->vec[1][0];
if (bezt->vec[2][0] < bezt->vec[1][0]) bezt->vec[2][0] = bezt->vec[1][0];
/* calculate auto-handles */
BKE_nurb_handle_calc(bezt, prev, next, 1); /* 1==special autohandle */
/* for automatic ease in and out */
if (ELEM(bezt->h1, HD_AUTO, HD_AUTO_ANIM) && ELEM(bezt->h2, HD_AUTO, HD_AUTO_ANIM)) {
/* only do this on first or last beztriple */
if ((a == 0) || (a == fcu->totvert - 1)) {
/* set both handles to have same horizontal value as keyframe */
if (fcu->extend == FCURVE_EXTRAPOLATE_CONSTANT) {
bezt->vec[0][1] = bezt->vec[2][1] = bezt->vec[1][1];
}
}
}
/* advance pointers for next iteration */
prev = bezt;
if (a == 1) next = NULL;
else next++;
bezt++;
}
}
/* Use when F-Curve with handles has changed
* It treats all BezTriples with the following rules:
* - PHASE 1: do types have to be altered?
* -> Auto handles: become aligned when selection status is NOT(000 || 111)
* -> Vector handles: become 'nothing' when (one half selected AND other not)
* - PHASE 2: recalculate handles
*/
void testhandles_fcurve(FCurve *fcu, const short use_handle)
{
BezTriple *bezt;
unsigned int a;
/* only beztriples have handles (bpoints don't though) */
if (ELEM(NULL, fcu, fcu->bezt))
return;
/* loop over beztriples */
for (a = 0, bezt = fcu->bezt; a < fcu->totvert; a++, bezt++) {
short flag = 0;
/* flag is initialized as selection status
* of beztriple control-points (labelled 0,1,2)
*/
if (bezt->f2 & SELECT) flag |= (1 << 1); // == 2
if (use_handle == FALSE) {
if (flag & 2) {
flag |= (1 << 0) | (1 << 2);
}
}
else {
if (bezt->f1 & SELECT) flag |= (1 << 0); // == 1
if (bezt->f3 & SELECT) flag |= (1 << 2); // == 4
}
/* one or two handles selected only */
if (ELEM(flag, 0, 7) == 0) {
/* auto handles become aligned */
if (ELEM(bezt->h1, HD_AUTO, HD_AUTO_ANIM))
bezt->h1 = HD_ALIGN;
if (ELEM(bezt->h2, HD_AUTO, HD_AUTO_ANIM))
bezt->h2 = HD_ALIGN;
/* vector handles become 'free' when only one half selected */
if (bezt->h1 == HD_VECT) {
/* only left half (1 or 2 or 1+2) */
if (flag < 4)
bezt->h1 = 0;
}
if (bezt->h2 == HD_VECT) {
/* only right half (4 or 2+4) */
if (flag > 3)
bezt->h2 = 0;
}
}
}
/* recalculate handles */
calchandles_fcurve(fcu);
}
/* This function sorts BezTriples so that they are arranged in chronological order,
* as tools working on F-Curves expect that the BezTriples are in order.
*/
void sort_time_fcurve(FCurve *fcu)
{
short ok = 1;
/* keep adjusting order of beztriples until nothing moves (bubble-sort) */
while (ok) {
ok = 0;
/* currently, will only be needed when there are beztriples */
if (fcu->bezt) {
BezTriple *bezt;
unsigned int a;
/* loop over ALL points to adjust position in array and recalculate handles */
for (a = 0, bezt = fcu->bezt; a < fcu->totvert; a++, bezt++) {
/* check if thee's a next beztriple which we could try to swap with current */
if (a < (fcu->totvert - 1)) {
/* swap if one is after the other (and indicate that order has changed) */
if (bezt->vec[1][0] > (bezt + 1)->vec[1][0]) {
SWAP(BezTriple, *bezt, *(bezt + 1));
ok = 1;
}
/* if either one of both of the points exceeds crosses over the keyframe time... */
if ( (bezt->vec[0][0] > bezt->vec[1][0]) && (bezt->vec[2][0] < bezt->vec[1][0]) ) {
/* swap handles if they have switched sides for some reason */
SWAP(float, bezt->vec[0][0], bezt->vec[2][0]);
SWAP(float, bezt->vec[0][1], bezt->vec[2][1]);
}
else {
/* clamp handles */
if (bezt->vec[0][0] > bezt->vec[1][0])
bezt->vec[0][0] = bezt->vec[1][0];
if (bezt->vec[2][0] < bezt->vec[1][0])
bezt->vec[2][0] = bezt->vec[1][0];
}
}
}
}
}
}
/* This function tests if any BezTriples are out of order, thus requiring a sort */
short test_time_fcurve(FCurve *fcu)
{
unsigned int a;
/* sanity checks */
if (fcu == NULL)
return 0;
/* currently, only need to test beztriples */
if (fcu->bezt) {
BezTriple *bezt;
/* loop through all BezTriples, stopping when one exceeds the one after it */
for (a = 0, bezt = fcu->bezt; a < (fcu->totvert - 1); a++, bezt++) {
if (bezt->vec[1][0] > (bezt + 1)->vec[1][0])
return 1;
}
}
else if (fcu->fpt) {
FPoint *fpt;
/* loop through all FPoints, stopping when one exceeds the one after it */
for (a = 0, fpt = fcu->fpt; a < (fcu->totvert - 1); a++, fpt++) {
if (fpt->vec[0] > (fpt + 1)->vec[0])
return 1;
}
}
/* none need any swapping */
return 0;
}
/* ***************************** Drivers ********************************* */
/* Driver Variables --------------------------- */
/* TypeInfo for Driver Variables (dvti) */
typedef struct DriverVarTypeInfo {
/* evaluation callback */
float (*get_value)(ChannelDriver *driver, DriverVar *dvar);
/* allocation of target slots */
int num_targets; /* number of target slots required */
const char *target_names[MAX_DRIVER_TARGETS]; /* UI names that should be given to the slots */
int target_flags[MAX_DRIVER_TARGETS]; /* flags defining the requirements for each slot */
} DriverVarTypeInfo;
/* Macro to begin definitions */
#define BEGIN_DVAR_TYPEDEF(type) \
{
/* Macro to end definitions */
#define END_DVAR_TYPEDEF \
}
/* ......... */
static ID *dtar_id_ensure_proxy_from(ID *id)
{
if (id && GS(id->name) == ID_OB && ((Object *)id)->proxy_from)
return (ID *)(((Object *)id)->proxy_from);
return id;
}
/* Helper function to obtain a value using RNA from the specified source (for evaluating drivers) */
static float dtar_get_prop_val(ChannelDriver *driver, DriverTarget *dtar)
{
PointerRNA id_ptr, ptr;
PropertyRNA *prop;
ID *id;
int index;
float value = 0.0f;
/* sanity check */
if (ELEM(NULL, driver, dtar))
return 0.0f;
id = dtar_id_ensure_proxy_from(dtar->id);
/* error check for missing pointer... */
// TODO: tag the specific target too as having issues
if (id == NULL) {
printf("Error: driver has an invalid target to use\n");
if (G.debug & G_DEBUG) printf("\tpath = %s\n", dtar->rna_path);
driver->flag |= DRIVER_FLAG_INVALID;
return 0.0f;
}
/* get RNA-pointer for the ID-block given in target */
RNA_id_pointer_create(id, &id_ptr);
/* get property to read from, and get value as appropriate */
if (RNA_path_resolve_full(&id_ptr, dtar->rna_path, &ptr, &prop, &index)) {
if (RNA_property_array_check(prop)) {
/* array */
if (index < RNA_property_array_length(&ptr, prop)) {
switch (RNA_property_type(prop)) {
case PROP_BOOLEAN:
value = (float)RNA_property_boolean_get_index(&ptr, prop, index);
break;
case PROP_INT:
value = (float)RNA_property_int_get_index(&ptr, prop, index);
break;
case PROP_FLOAT:
value = RNA_property_float_get_index(&ptr, prop, index);
break;
default:
break;
}
}
}
else {
/* not an array */
switch (RNA_property_type(prop)) {
case PROP_BOOLEAN:
value = (float)RNA_property_boolean_get(&ptr, prop);
break;
case PROP_INT:
value = (float)RNA_property_int_get(&ptr, prop);
break;
case PROP_FLOAT:
value = RNA_property_float_get(&ptr, prop);
break;
case PROP_ENUM:
value = (float)RNA_property_enum_get(&ptr, prop);
break;
default:
break;
}
}
}
else {
if (G.debug & G_DEBUG)
printf("Driver Evaluation Error: cannot resolve target for %s -> %s\n", id->name, dtar->rna_path);
driver->flag |= DRIVER_FLAG_INVALID;
return 0.0f;
}
return value;
}
/* Helper function to obtain a pointer to a Pose Channel (for evaluating drivers) */
static bPoseChannel *dtar_get_pchan_ptr(ChannelDriver *driver, DriverTarget *dtar)
{
ID *id;
/* sanity check */
if (ELEM(NULL, driver, dtar))
return NULL;
id = dtar_id_ensure_proxy_from(dtar->id);
/* check if the ID here is a valid object */
if (id && GS(id->name)) {
Object *ob = (Object *)id;
/* get pose, and subsequently, posechannel */
return BKE_pose_channel_find_name(ob->pose, dtar->pchan_name);
}
else {
/* cannot find a posechannel this way */
return NULL;
}
}
/* ......... */
/* evaluate 'single prop' driver variable */
static float dvar_eval_singleProp(ChannelDriver *driver, DriverVar *dvar)
{
/* just evaluate the first target slot */
return dtar_get_prop_val(driver, &dvar->targets[0]);
}
/* evaluate 'rotation difference' driver variable */
static float dvar_eval_rotDiff(ChannelDriver *driver, DriverVar *dvar)
{
bPoseChannel *pchan, *pchan2;
float q1[4], q2[4], quat[4], angle;
/* get pose channels, and check if we've got two */
pchan = dtar_get_pchan_ptr(driver, &dvar->targets[0]);
pchan2 = dtar_get_pchan_ptr(driver, &dvar->targets[1]);
if (ELEM(NULL, pchan, pchan2)) {
/* disable this driver, since it doesn't work correctly... */
driver->flag |= DRIVER_FLAG_INVALID;
/* check what the error was */
if ((pchan == NULL) && (pchan2 == NULL))
printf("Driver Evaluation Error: Rotational difference failed - first 2 targets invalid\n");
else if (pchan == NULL)
printf("Driver Evaluation Error: Rotational difference failed - first target not valid PoseChannel\n");
else if (pchan2 == NULL)
printf("Driver Evaluation Error: Rotational difference failed - second target not valid PoseChannel\n");
/* stop here... */
return 0.0f;
}
/* use the final posed locations */
mat4_to_quat(q1, pchan->pose_mat);
mat4_to_quat(q2, pchan2->pose_mat);
invert_qt(q1);
mul_qt_qtqt(quat, q1, q2);
angle = 2.0f * (saacos(quat[0]));
angle = ABS(angle);
return (angle > (float)M_PI) ? (float)((2.0f * (float)M_PI) - angle) : (float)(angle);
}
/* evaluate 'location difference' driver variable */
// TODO: this needs to take into account space conversions...
static float dvar_eval_locDiff(ChannelDriver *driver, DriverVar *dvar)
{
float loc1[3] = {0.0f, 0.0f, 0.0f};
float loc2[3] = {0.0f, 0.0f, 0.0f};
/* get two location values */
// NOTE: for now, these are all just worldspace
DRIVER_TARGETS_USED_LOOPER(dvar)
{
/* get pointer to loc values to store in */
Object *ob = (Object *)dtar_id_ensure_proxy_from(dtar->id);
bPoseChannel *pchan;
float tmp_loc[3];
/* check if this target has valid data */
if ((ob == NULL) || (GS(ob->id.name) != ID_OB)) {
/* invalid target, so will not have enough targets */
driver->flag |= DRIVER_FLAG_INVALID;
return 0.0f;
}
/* try to get posechannel */
pchan = BKE_pose_channel_find_name(ob->pose, dtar->pchan_name);
/* check if object or bone */
if (pchan) {
/* bone */
if (dtar->flag & DTAR_FLAG_LOCALSPACE) {
if (dtar->flag & DTAR_FLAG_LOCAL_CONSTS) {
float mat[4][4];
/* extract transform just like how the constraints do it! */
copy_m4_m4(mat, pchan->pose_mat);
constraint_mat_convertspace(ob, pchan, mat, CONSTRAINT_SPACE_POSE, CONSTRAINT_SPACE_LOCAL);
/* ... and from that, we get our transform */
copy_v3_v3(tmp_loc, mat[3]);
}
else {
/* transform space (use transform values directly) */
copy_v3_v3(tmp_loc, pchan->loc);
}
}
else {
/* convert to worldspace */
copy_v3_v3(tmp_loc, pchan->pose_head);
mul_m4_v3(ob->obmat, tmp_loc);
}
}
else {
/* object */
if (dtar->flag & DTAR_FLAG_LOCALSPACE) {
if (dtar->flag & DTAR_FLAG_LOCAL_CONSTS) {
// XXX: this should practically be the same as transform space...
float mat[4][4];
/* extract transform just like how the constraints do it! */
copy_m4_m4(mat, ob->obmat);
constraint_mat_convertspace(ob, NULL, mat, CONSTRAINT_SPACE_WORLD, CONSTRAINT_SPACE_LOCAL);
/* ... and from that, we get our transform */
copy_v3_v3(tmp_loc, mat[3]);
}
else {
/* transform space (use transform values directly) */
copy_v3_v3(tmp_loc, ob->loc);
}
}
else {
/* worldspace */
copy_v3_v3(tmp_loc, ob->obmat[3]);
}
}
/* copy the location to the right place */
if (tarIndex) {
copy_v3_v3(loc2, tmp_loc);
}
else {
copy_v3_v3(loc1, tmp_loc);
}
}
DRIVER_TARGETS_LOOPER_END
/* if we're still here, there should now be two targets to use,
* so just take the length of the vector between these points
*/
return len_v3v3(loc1, loc2);
}
/* evaluate 'transform channel' driver variable */
static float dvar_eval_transChan(ChannelDriver *driver, DriverVar *dvar)
{
DriverTarget *dtar = &dvar->targets[0];
Object *ob = (Object *)dtar_id_ensure_proxy_from(dtar->id);
bPoseChannel *pchan;
float mat[4][4];
float oldEul[3] = {0.0f, 0.0f, 0.0f};
short use_eulers = FALSE, rot_order = ROT_MODE_EUL;
/* check if this target has valid data */
if ((ob == NULL) || (GS(ob->id.name) != ID_OB)) {
/* invalid target, so will not have enough targets */
driver->flag |= DRIVER_FLAG_INVALID;
return 0.0f;
}
/* try to get posechannel */
pchan = BKE_pose_channel_find_name(ob->pose, dtar->pchan_name);
/* check if object or bone, and get transform matrix accordingly
* - "useEulers" code is used to prevent the problems associated with non-uniqueness
* of euler decomposition from matrices [#20870]
* - localspace is for [#21384], where parent results are not wanted
* but local-consts is for all the common "corrective-shapes-for-limbs" situations
*/
if (pchan) {
/* bone */
if (pchan->rotmode > 0) {
copy_v3_v3(oldEul, pchan->eul);
rot_order = pchan->rotmode;
use_eulers = TRUE;
}
if (dtar->flag & DTAR_FLAG_LOCALSPACE) {
if (dtar->flag & DTAR_FLAG_LOCAL_CONSTS) {
/* just like how the constraints do it! */
copy_m4_m4(mat, pchan->pose_mat);
constraint_mat_convertspace(ob, pchan, mat, CONSTRAINT_SPACE_POSE, CONSTRAINT_SPACE_LOCAL);
}
else {
/* specially calculate local matrix, since chan_mat is not valid
* since it stores delta transform of pose_mat so that deforms work
* so it cannot be used here for "transform" space
*/
BKE_pchan_to_mat4(pchan, mat);
}
}
else {
/* worldspace matrix */
mult_m4_m4m4(mat, ob->obmat, pchan->pose_mat);
}
}
else {
/* object */
if (ob->rotmode > 0) {
copy_v3_v3(oldEul, ob->rot);
rot_order = ob->rotmode;
use_eulers = TRUE;
}
if (dtar->flag & DTAR_FLAG_LOCALSPACE) {
if (dtar->flag & DTAR_FLAG_LOCAL_CONSTS) {
/* just like how the constraints do it! */
copy_m4_m4(mat, ob->obmat);
constraint_mat_convertspace(ob, NULL, mat, CONSTRAINT_SPACE_WORLD, CONSTRAINT_SPACE_LOCAL);
}
else {
/* transforms to matrix */
BKE_object_to_mat4(ob, mat);
}
}
else {
/* worldspace matrix - just the good-old one */
copy_m4_m4(mat, ob->obmat);
}
}
/* check which transform */
if (dtar->transChan >= MAX_DTAR_TRANSCHAN_TYPES) {
/* not valid channel */
return 0.0f;
}
else if (dtar->transChan >= DTAR_TRANSCHAN_SCALEX) {
/* extract scale, and choose the right axis */
float scale[3];
mat4_to_size(scale, mat);
return scale[dtar->transChan - DTAR_TRANSCHAN_SCALEX];
}
else if (dtar->transChan >= DTAR_TRANSCHAN_ROTX) {
/* extract rotation as eulers (if needed)
* - definitely if rotation order isn't eulers already
* - if eulers, then we have 2 options:
* a) decompose transform matrix as required, then try to make eulers from
* there compatible with original values
* b) [NOT USED] directly use the original values (no decomposition)
* - only an option for "transform space", if quality is really bad with a)
*/
float eul[3];
mat4_to_eulO(eul, rot_order, mat);
if (use_eulers) {
compatible_eul(eul, oldEul);
}
return eul[dtar->transChan - DTAR_TRANSCHAN_ROTX];
}
else {
/* extract location and choose right axis */
return mat[3][dtar->transChan];
}
}
/* ......... */
/* Table of Driver Varaiable Type Info Data */
static DriverVarTypeInfo dvar_types[MAX_DVAR_TYPES] = {
BEGIN_DVAR_TYPEDEF(DVAR_TYPE_SINGLE_PROP)
dvar_eval_singleProp, /* eval callback */
1, /* number of targets used */
{"Property"}, /* UI names for targets */
{0} /* flags */
END_DVAR_TYPEDEF,
BEGIN_DVAR_TYPEDEF(DVAR_TYPE_ROT_DIFF)
dvar_eval_rotDiff, /* eval callback */
2, /* number of targets used */
{"Bone 1", "Bone 2"}, /* UI names for targets */
{DTAR_FLAG_STRUCT_REF | DTAR_FLAG_ID_OB_ONLY, DTAR_FLAG_STRUCT_REF | DTAR_FLAG_ID_OB_ONLY} /* flags */
END_DVAR_TYPEDEF,
BEGIN_DVAR_TYPEDEF(DVAR_TYPE_LOC_DIFF)
dvar_eval_locDiff, /* eval callback */
2, /* number of targets used */
{"Object/Bone 1", "Object/Bone 2"}, /* UI names for targets */
{DTAR_FLAG_STRUCT_REF | DTAR_FLAG_ID_OB_ONLY, DTAR_FLAG_STRUCT_REF | DTAR_FLAG_ID_OB_ONLY} /* flags */
END_DVAR_TYPEDEF,
BEGIN_DVAR_TYPEDEF(DVAR_TYPE_TRANSFORM_CHAN)
dvar_eval_transChan, /* eval callback */
1, /* number of targets used */
{"Object/Bone"}, /* UI names for targets */
{DTAR_FLAG_STRUCT_REF | DTAR_FLAG_ID_OB_ONLY} /* flags */
END_DVAR_TYPEDEF,
};
/* Get driver variable typeinfo */
static DriverVarTypeInfo *get_dvar_typeinfo(int type)
{
/* check if valid type */
if ((type >= 0) && (type < MAX_DVAR_TYPES))
return &dvar_types[type];
else
return NULL;
}
/* Driver API --------------------------------- */
/* This frees the driver variable itself */
void driver_free_variable(ChannelDriver *driver, DriverVar *dvar)
{
/* sanity checks */
if (dvar == NULL)
return;
/* free target vars
* - need to go over all of them, not just up to the ones that are used
* currently, since there may be some lingering RNA paths from
* previous users needing freeing
*/
DRIVER_TARGETS_LOOPER(dvar)
{
/* free RNA path if applicable */
if (dtar->rna_path)
MEM_freeN(dtar->rna_path);
}
DRIVER_TARGETS_LOOPER_END
/* remove the variable from the driver */
BLI_freelinkN(&driver->variables, dvar);
#ifdef WITH_PYTHON
/* since driver variables are cached, the expression needs re-compiling too */
if (driver->type == DRIVER_TYPE_PYTHON)
driver->flag |= DRIVER_FLAG_RENAMEVAR;
#endif
}
/* Change the type of driver variable */
void driver_change_variable_type(DriverVar *dvar, int type)
{
DriverVarTypeInfo *dvti = get_dvar_typeinfo(type);
/* sanity check */
if (ELEM(NULL, dvar, dvti))
return;
/* set the new settings */
dvar->type = type;
dvar->num_targets = dvti->num_targets;
/* make changes to the targets based on the defines for these types
* NOTE: only need to make sure the ones we're using here are valid...
*/
DRIVER_TARGETS_USED_LOOPER(dvar)
{
int flags = dvti->target_flags[tarIndex];
/* store the flags */
dtar->flag = flags;
/* object ID types only, or idtype not yet initialized*/
if ((flags & DTAR_FLAG_ID_OB_ONLY) || (dtar->idtype == 0))
dtar->idtype = ID_OB;
}
DRIVER_TARGETS_LOOPER_END
}
/* Add a new driver variable */
DriverVar *driver_add_new_variable(ChannelDriver *driver)
{
DriverVar *dvar;
/* sanity checks */
if (driver == NULL)
return NULL;
/* make a new variable */
dvar = MEM_callocN(sizeof(DriverVar), "DriverVar");
BLI_addtail(&driver->variables, dvar);
/* give the variable a 'unique' name */
strcpy(dvar->name, "var");
BLI_uniquename(&driver->variables, dvar, "var", '_', offsetof(DriverVar, name), sizeof(dvar->name));
/* set the default type to 'single prop' */
driver_change_variable_type(dvar, DVAR_TYPE_SINGLE_PROP);
#ifdef WITH_PYTHON
/* since driver variables are cached, the expression needs re-compiling too */
if (driver->type == DRIVER_TYPE_PYTHON)
driver->flag |= DRIVER_FLAG_RENAMEVAR;
#endif
/* return the target */
return dvar;
}
/* This frees the driver itself */
void fcurve_free_driver(FCurve *fcu)
{
ChannelDriver *driver;
DriverVar *dvar, *dvarn;
/* sanity checks */
if (ELEM(NULL, fcu, fcu->driver))
return;
driver = fcu->driver;
/* free driver targets */
for (dvar = driver->variables.first; dvar; dvar = dvarn) {
dvarn = dvar->next;
driver_free_variable(driver, dvar);
}
#ifdef WITH_PYTHON
/* free compiled driver expression */
if (driver->expr_comp)
BPY_DECREF(driver->expr_comp);
#endif
/* free driver itself, then set F-Curve's point to this to NULL (as the curve may still be used) */
MEM_freeN(driver);
fcu->driver = NULL;
}
/* This makes a copy of the given driver */
ChannelDriver *fcurve_copy_driver(ChannelDriver *driver)
{
ChannelDriver *ndriver;
DriverVar *dvar;
/* sanity checks */
if (driver == NULL)
return NULL;
/* copy all data */
ndriver = MEM_dupallocN(driver);
ndriver->expr_comp = NULL;
/* copy variables */
ndriver->variables.first = ndriver->variables.last = NULL;
BLI_duplicatelist(&ndriver->variables, &driver->variables);
for (dvar = ndriver->variables.first; dvar; dvar = dvar->next) {
/* need to go over all targets so that we don't leave any dangling paths */
DRIVER_TARGETS_LOOPER(dvar)
{
/* make a copy of target's rna path if available */
if (dtar->rna_path)
dtar->rna_path = MEM_dupallocN(dtar->rna_path);
}
DRIVER_TARGETS_LOOPER_END
}
/* return the new driver */
return ndriver;
}
/* Driver Evaluation -------------------------- */
/* Evaluate a Driver Variable to get a value that contributes to the final */
float driver_get_variable_value(ChannelDriver *driver, DriverVar *dvar)
{
DriverVarTypeInfo *dvti;
/* sanity check */
if (ELEM(NULL, driver, dvar))
return 0.0f;
/* call the relevant callbacks to get the variable value
* using the variable type info, storing the obtained value
* in dvar->curval so that drivers can be debugged
*/
dvti = get_dvar_typeinfo(dvar->type);
if (dvti && dvti->get_value)
dvar->curval = dvti->get_value(driver, dvar);
else
dvar->curval = 0.0f;
return dvar->curval;
}
/* Evaluate an Channel-Driver to get a 'time' value to use instead of "evaltime"
* - "evaltime" is the frame at which F-Curve is being evaluated
* - has to return a float value
*/
static float evaluate_driver(ChannelDriver *driver, const float evaltime)
{
DriverVar *dvar;
/* check if driver can be evaluated */
if (driver->flag & DRIVER_FLAG_INVALID)
return 0.0f;
switch (driver->type) {
case DRIVER_TYPE_AVERAGE: /* average values of driver targets */
case DRIVER_TYPE_SUM: /* sum values of driver targets */
{
/* check how many variables there are first (i.e. just one?) */
if (driver->variables.first == driver->variables.last) {
/* just one target, so just use that */
dvar = driver->variables.first;
driver->curval = driver_get_variable_value(driver, dvar);
}
else {
/* more than one target, so average the values of the targets */
float value = 0.0f;
int tot = 0;
/* loop through targets, adding (hopefully we don't get any overflow!) */
for (dvar = driver->variables.first; dvar; dvar = dvar->next) {
value += driver_get_variable_value(driver, dvar);
tot++;
}
/* perform operations on the total if appropriate */
if (driver->type == DRIVER_TYPE_AVERAGE)
driver->curval = (value / (float)tot);
else
driver->curval = value;
}
}
break;
case DRIVER_TYPE_MIN: /* smallest value */
case DRIVER_TYPE_MAX: /* largest value */
{
float value = 0.0f;
/* loop through the variables, getting the values and comparing them to existing ones */
for (dvar = driver->variables.first; dvar; dvar = dvar->next) {
/* get value */
float tmp_val = driver_get_variable_value(driver, dvar);
/* store this value if appropriate */
if (dvar->prev) {
/* check if greater/smaller than the baseline */
if (driver->type == DRIVER_TYPE_MAX) {
/* max? */
if (tmp_val > value)
value = tmp_val;
}
else {
/* min? */
if (tmp_val < value)
value = tmp_val;
}
}
else {
/* first item - make this the baseline for comparisons */
value = tmp_val;
}
}
/* store value in driver */
driver->curval = value;
}
break;
case DRIVER_TYPE_PYTHON: /* expression */
{
#ifdef WITH_PYTHON
/* check for empty or invalid expression */
if ( (driver->expression[0] == '\0') ||
(driver->flag & DRIVER_FLAG_INVALID) )
{
driver->curval = 0.0f;
}
else {
/* this evaluates the expression using Python, and returns its result:
* - on errors it reports, then returns 0.0f
*/
driver->curval = BPY_driver_exec(driver, evaltime);
}
#else /* WITH_PYTHON*/
(void)evaltime;
#endif /* WITH_PYTHON*/
}
break;
default:
{
/* special 'hack' - just use stored value
* This is currently used as the mechanism which allows animated settings to be able
* to be changed via the UI.
*/
}
}
/* return value for driver */
return driver->curval;
}
/* ***************************** Curve Calculations ********************************* */
/* The total length of the handles is not allowed to be more
* than the horizontal distance between (v1-v4).
* This is to prevent curve loops.
*/
void correct_bezpart(float v1[2], float v2[2], float v3[2], float v4[2])
{
float h1[2], h2[2], len1, len2, len, fac;
/* calculate handle deltas */
h1[0] = v1[0] - v2[0];
h1[1] = v1[1] - v2[1];
h2[0] = v4[0] - v3[0];
h2[1] = v4[1] - v3[1];
/* calculate distances:
* - len = span of time between keyframes
* - len1 = length of handle of start key
* - len2 = length of handle of end key
*/
len = v4[0] - v1[0];
len1 = fabsf(h1[0]);
len2 = fabsf(h2[0]);
/* if the handles have no length, no need to do any corrections */
if ((len1 + len2) == 0.0f)
return;
/* the two handles cross over each other, so force them
* apart using the proportion they overlap
*/
if ((len1 + len2) > len) {
fac = len / (len1 + len2);
v2[0] = (v1[0] - fac * h1[0]);
v2[1] = (v1[1] - fac * h1[1]);
v3[0] = (v4[0] - fac * h2[0]);
v3[1] = (v4[1] - fac * h2[1]);
}
}
/* find root ('zero') */
static int findzero(float x, float q0, float q1, float q2, float q3, float *o)
{
double c0, c1, c2, c3, a, b, c, p, q, d, t, phi;
int nr = 0;
c0 = q0 - x;
c1 = 3.0f * (q1 - q0);
c2 = 3.0f * (q0 - 2.0f * q1 + q2);
c3 = q3 - q0 + 3.0f * (q1 - q2);
if (c3 != 0.0) {
a = c2 / c3;
b = c1 / c3;
c = c0 / c3;
a = a / 3;
p = b / 3 - a * a;
q = (2 * a * a * a - a * b + c) / 2;
d = q * q + p * p * p;
if (d > 0.0) {
t = sqrt(d);
o[0] = (float)(sqrt3d(-q + t) + sqrt3d(-q - t) - a);
if ((o[0] >= (float)SMALL) && (o[0] <= 1.000001f)) return 1;
else return 0;
}
else if (d == 0.0) {
t = sqrt3d(-q);
o[0] = (float)(2 * t - a);
if ((o[0] >= (float)SMALL) && (o[0] <= 1.000001f)) nr++;
o[nr] = (float)(-t - a);
if ((o[nr] >= (float)SMALL) && (o[nr] <= 1.000001f)) return nr + 1;
else return nr;
}
else {
phi = acos(-q / sqrt(-(p * p * p)));
t = sqrt(-p);
p = cos(phi / 3);
q = sqrt(3 - 3 * p * p);
o[0] = (float)(2 * t * p - a);
if ((o[0] >= (float)SMALL) && (o[0] <= 1.000001f)) nr++;
o[nr] = (float)(-t * (p + q) - a);
if ((o[nr] >= (float)SMALL) && (o[nr] <= 1.000001f)) nr++;
o[nr] = (float)(-t * (p - q) - a);
if ((o[nr] >= (float)SMALL) && (o[nr] <= 1.000001f)) return nr + 1;
else return nr;
}
}
else {
a = c2;
b = c1;
c = c0;
if (a != 0.0) {
// discriminant
p = b * b - 4 * a * c;
if (p > 0) {
p = sqrt(p);
o[0] = (float)((-b - p) / (2 * a));
if ((o[0] >= (float)SMALL) && (o[0] <= 1.000001f)) nr++;
o[nr] = (float)((-b + p) / (2 * a));
if ((o[nr] >= (float)SMALL) && (o[nr] <= 1.000001f)) return nr + 1;
else return nr;
}
else if (p == 0) {
o[0] = (float)(-b / (2 * a));
if ((o[0] >= (float)SMALL) && (o[0] <= 1.000001f)) return 1;
else return 0;
}
}
else if (b != 0.0) {
o[0] = (float)(-c / b);
if ((o[0] >= (float)SMALL) && (o[0] <= 1.000001f)) return 1;
else return 0;
}
else if (c == 0.0) {
o[0] = 0.0;
return 1;
}
return 0;
}
}
static void berekeny(float f1, float f2, float f3, float f4, float *o, int b)
{
float t, c0, c1, c2, c3;
int a;
c0 = f1;
c1 = 3.0f * (f2 - f1);
c2 = 3.0f * (f1 - 2.0f * f2 + f3);
c3 = f4 - f1 + 3.0f * (f2 - f3);
for (a = 0; a < b; a++) {
t = o[a];
o[a] = c0 + t * c1 + t * t * c2 + t * t * t * c3;
}
}
#if 0
static void berekenx(float *f, float *o, int b)
{
float t, c0, c1, c2, c3;
int a;
c0 = f[0];
c1 = 3.0f * (f[3] - f[0]);
c2 = 3.0f * (f[0] - 2.0f * f[3] + f[6]);
c3 = f[9] - f[0] + 3.0f * (f[3] - f[6]);
for (a = 0; a < b; a++) {
t = o[a];
o[a] = c0 + t * c1 + t * t * c2 + t * t * t * c3;
}
}
#endif
/* -------------------------- */
/* Calculate F-Curve value for 'evaltime' using BezTriple keyframes */
static float fcurve_eval_keyframes(FCurve *fcu, BezTriple *bezts, float evaltime)
{
BezTriple *bezt, *prevbezt, *lastbezt;
float v1[2], v2[2], v3[2], v4[2], opl[32], dx, fac;
unsigned int a;
int b;
float cvalue = 0.0f;
/* get pointers */
a = fcu->totvert - 1;
prevbezt = bezts;
bezt = prevbezt + 1;
lastbezt = prevbezt + a;
/* evaluation time at or past endpoints? */
if (prevbezt->vec[1][0] >= evaltime) {
/* before or on first keyframe */
if ( (fcu->extend == FCURVE_EXTRAPOLATE_LINEAR) && (prevbezt->ipo != BEZT_IPO_CONST) &&
!(fcu->flag & FCURVE_DISCRETE_VALUES) )
{
/* linear or bezier interpolation */
if (prevbezt->ipo == BEZT_IPO_LIN) {
/* Use the next center point instead of our own handle for
* linear interpolated extrapolate
*/
if (fcu->totvert == 1) {
cvalue = prevbezt->vec[1][1];
}
else {
bezt = prevbezt + 1;
dx = prevbezt->vec[1][0] - evaltime;
fac = bezt->vec[1][0] - prevbezt->vec[1][0];
/* prevent division by zero */
if (fac) {
fac = (bezt->vec[1][1] - prevbezt->vec[1][1]) / fac;
cvalue = prevbezt->vec[1][1] - (fac * dx);
}
else {
cvalue = prevbezt->vec[1][1];
}
}
}
else {
/* Use the first handle (earlier) of first BezTriple to calculate the
* gradient and thus the value of the curve at evaltime
*/
dx = prevbezt->vec[1][0] - evaltime;
fac = prevbezt->vec[1][0] - prevbezt->vec[0][0];
/* prevent division by zero */
if (fac) {
fac = (prevbezt->vec[1][1] - prevbezt->vec[0][1]) / fac;
cvalue = prevbezt->vec[1][1] - (fac * dx);
}
else {
cvalue = prevbezt->vec[1][1];
}
}
}
else {
/* constant (BEZT_IPO_HORIZ) extrapolation or constant interpolation,
* so just extend first keyframe's value
*/
cvalue = prevbezt->vec[1][1];
}
}
else if (lastbezt->vec[1][0] <= evaltime) {
/* after or on last keyframe */
if ( (fcu->extend == FCURVE_EXTRAPOLATE_LINEAR) && (lastbezt->ipo != BEZT_IPO_CONST) &&
!(fcu->flag & FCURVE_DISCRETE_VALUES) )
{
/* linear or bezier interpolation */
if (lastbezt->ipo == BEZT_IPO_LIN) {
/* Use the next center point instead of our own handle for
* linear interpolated extrapolate
*/
if (fcu->totvert == 1) {
cvalue = lastbezt->vec[1][1];
}
else {
prevbezt = lastbezt - 1;
dx = evaltime - lastbezt->vec[1][0];
fac = lastbezt->vec[1][0] - prevbezt->vec[1][0];
/* prevent division by zero */
if (fac) {
fac = (lastbezt->vec[1][1] - prevbezt->vec[1][1]) / fac;
cvalue = lastbezt->vec[1][1] + (fac * dx);
}
else {
cvalue = lastbezt->vec[1][1];
}
}
}
else {
/* Use the gradient of the second handle (later) of last BezTriple to calculate the
* gradient and thus the value of the curve at evaltime
*/
dx = evaltime - lastbezt->vec[1][0];
fac = lastbezt->vec[2][0] - lastbezt->vec[1][0];
/* prevent division by zero */
if (fac) {
fac = (lastbezt->vec[2][1] - lastbezt->vec[1][1]) / fac;
cvalue = lastbezt->vec[1][1] + (fac * dx);
}
else {
cvalue = lastbezt->vec[1][1];
}
}
}
else {
/* constant (BEZT_IPO_HORIZ) extrapolation or constant interpolation,
* so just extend last keyframe's value
*/
cvalue = lastbezt->vec[1][1];
}
}
else {
/* evaltime occurs somewhere in the middle of the curve */
for (a = 0; prevbezt && bezt && (a < fcu->totvert - 1); a++, prevbezt = bezt, bezt++) {
/* use if the key is directly on the frame, rare cases this is needed else we get 0.0 instead. */
if (fabsf(bezt->vec[1][0] - evaltime) < SMALL_NUMBER) {
cvalue = bezt->vec[1][1];
}
/* evaltime occurs within the interval defined by these two keyframes */
else if ((prevbezt->vec[1][0] <= evaltime) && (bezt->vec[1][0] >= evaltime)) {
/* value depends on interpolation mode */
if ((prevbezt->ipo == BEZT_IPO_CONST) || (fcu->flag & FCURVE_DISCRETE_VALUES)) {
/* constant (evaltime not relevant, so no interpolation needed) */
cvalue = prevbezt->vec[1][1];
}
else if (prevbezt->ipo == BEZT_IPO_LIN) {
/* linear - interpolate between values of the two keyframes */
fac = bezt->vec[1][0] - prevbezt->vec[1][0];
/* prevent division by zero */
if (fac) {
fac = (evaltime - prevbezt->vec[1][0]) / fac;
cvalue = prevbezt->vec[1][1] + (fac * (bezt->vec[1][1] - prevbezt->vec[1][1]));
}
else {
cvalue = prevbezt->vec[1][1];
}
}
else {
/* bezier interpolation */
/* v1,v2 are the first keyframe and its 2nd handle */
v1[0] = prevbezt->vec[1][0];
v1[1] = prevbezt->vec[1][1];
v2[0] = prevbezt->vec[2][0];
v2[1] = prevbezt->vec[2][1];
/* v3,v4 are the last keyframe's 1st handle + the last keyframe */
v3[0] = bezt->vec[0][0];
v3[1] = bezt->vec[0][1];
v4[0] = bezt->vec[1][0];
v4[1] = bezt->vec[1][1];
/* adjust handles so that they don't overlap (forming a loop) */
correct_bezpart(v1, v2, v3, v4);
/* try to get a value for this position - if failure, try another set of points */
b = findzero(evaltime, v1[0], v2[0], v3[0], v4[0], opl);
if (b) {
berekeny(v1[1], v2[1], v3[1], v4[1], opl, 1);
cvalue = opl[0];
break;
}
}
}
}
}
/* return value */
return cvalue;
}
/* Calculate F-Curve value for 'evaltime' using FPoint samples */
static float fcurve_eval_samples(FCurve *fcu, FPoint *fpts, float evaltime)
{
FPoint *prevfpt, *lastfpt, *fpt;
float cvalue = 0.0f;
/* get pointers */
prevfpt = fpts;
lastfpt = prevfpt + fcu->totvert - 1;
/* evaluation time at or past endpoints? */
if (prevfpt->vec[0] >= evaltime) {
/* before or on first sample, so just extend value */
cvalue = prevfpt->vec[1];
}
else if (lastfpt->vec[0] <= evaltime) {
/* after or on last sample, so just extend value */
cvalue = lastfpt->vec[1];
}
else {
float t = (float)abs(evaltime - (int)evaltime);
/* find the one on the right frame (assume that these are spaced on 1-frame intervals) */
fpt = prevfpt + (int)(evaltime - prevfpt->vec[0]);
/* if not exactly on the frame, perform linear interpolation with the next one */
if (t != 0.0f)
cvalue = interpf(fpt->vec[1], (fpt + 1)->vec[1], t);
else
cvalue = fpt->vec[1];
}
/* return value */
return cvalue;
}
/* ***************************** F-Curve - Evaluation ********************************* */
/* Evaluate and return the value of the given F-Curve at the specified frame ("evaltime")
* Note: this is also used for drivers
*/
float evaluate_fcurve(FCurve *fcu, float evaltime)
{
float cvalue = 0.0f;
float devaltime;
/* if there is a driver (only if this F-Curve is acting as 'driver'), evaluate it to find value to use as "evaltime"
* since drivers essentially act as alternative input (i.e. in place of 'time') for F-Curves
* - this value will also be returned as the value of the 'curve', if there are no keyframes
*/
if (fcu->driver) {
/* evaltime now serves as input for the curve */
evaltime = cvalue = evaluate_driver(fcu->driver, evaltime);
}
/* evaluate modifiers which modify time to evaluate the base curve at */
devaltime = evaluate_time_fmodifiers(&fcu->modifiers, fcu, cvalue, evaltime);
/* evaluate curve-data
* - 'devaltime' instead of 'evaltime', as this is the time that the last time-modifying
* F-Curve modifier on the stack requested the curve to be evaluated at
*/
if (fcu->bezt)
cvalue = fcurve_eval_keyframes(fcu, fcu->bezt, devaltime);
else if (fcu->fpt)
cvalue = fcurve_eval_samples(fcu, fcu->fpt, devaltime);
/* evaluate modifiers */
evaluate_value_fmodifiers(&fcu->modifiers, fcu, &cvalue, evaltime);
/* if curve can only have integral values, perform truncation (i.e. drop the decimal part)
* here so that the curve can be sampled correctly
*/
if (fcu->flag & FCURVE_INT_VALUES)
cvalue = floorf(cvalue + 0.5f);
/* return evaluated value */
return cvalue;
}
/* Calculate the value of the given F-Curve at the given frame, and set its curval */
void calculate_fcurve(FCurve *fcu, float ctime)
{
/* only calculate + set curval (overriding the existing value) if curve has
* any data which warrants this...
*/
if ((fcu->totvert) || (fcu->driver && !(fcu->driver->flag & DRIVER_FLAG_INVALID)) ||
list_has_suitable_fmodifier(&fcu->modifiers, 0, FMI_TYPE_GENERATE_CURVE))
{
/* calculate and set curval (evaluates driver too if necessary) */
fcu->curval = evaluate_fcurve(fcu, ctime);
}
}
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