2.5

12k lines of sequencer back! Only seqaudio.c skipped for now.
Notes:

- it only draws now, nothing refreshes or edits.
- fixed bug in view2d.c with vertical grid step being 0.0f
- render code and fileselect code is #ifdeffed out
- sequence evaluation code moved to blenkernel, so it can
  be used for render without bad level calls

General note; sequencer code is very untidy, mixing styles too
much. Tried to clean it some, but it would be nice if formatting
is kept consistant from now on.

1 files changed, 3145 insertions, 0 deletions

diff --git a/source/blender/blenkernel/intern/seqeffects.c b/source/blender/blenkernel/intern/seqeffects.c
new file mode 100644
index 00000000000..9036156d6b6
--- /dev/null
+++ b/source/blender/blenkernel/intern/seqeffects.c
@@ -0,0 +1,3145 @@
+/**
+ * $Id$
+ *
+ * ***** BEGIN GPL LICENSE BLOCK *****
+ *
+ * This program is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU General Public License
+ * as published by the Free Software Foundation; either version 2
+ * of the License, or (at your option) any later version.
+ *
+ * This program is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
+ * GNU General Public License for more details.
+ *
+ * You should have received a copy of the GNU General Public License
+ * along with this program; if not, write to the Free Software Foundation,
+ * Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.
+ *
+ * The Original Code is Copyright (C) 2001-2002 by NaN Holding BV.
+ * All rights reserved.
+ *
+ * Contributor(s): 
+ * - Blender Foundation, 2003-2009
+ * - Peter Schlaile <peter [at] schlaile [dot] de> 2005/2006
+ *
+ * ***** END GPL LICENSE BLOCK *****
+ */
+
+#include <string.h>
+#include <math.h>
+#include <stdlib.h>
+
+#include "MEM_guardedalloc.h"
+#include "PIL_dynlib.h"
+
+#include "DNA_scene_types.h"
+#include "DNA_sequence_types.h"
+
+#include "BLI_blenlib.h"
+#include "BLI_arithb.h"
+
+#include "BKE_global.h"
+#include "BKE_ipo.h"
+#include "BKE_plugin_types.h"
+#include "BKE_sequence.h"
+#include "BKE_texture.h"
+#include "BKE_utildefines.h"
+
+#include "IMB_imbuf_types.h"
+#include "IMB_imbuf.h"
+
+/* **** XXX **** */
+static void error() {}
+
+#define INT	96
+#define FLO	128
+
+/* **** XXX **** */
+
+/* Glow effect */
+enum {
+	GlowR=0,
+	GlowG=1,
+	GlowB=2,
+	GlowA=3
+};
+
+
+/* **********************************************************************
+   PLUGINS
+   ********************************************************************** */
+
+static void open_plugin_seq(PluginSeq *pis, const char *seqname)
+{
+	int (*version)();
+	void* (*alloc_private)();
+	char *cp;
+
+	/* to be sure: (is tested for) */
+	pis->doit= 0;
+	pis->pname= 0;
+	pis->varstr= 0;
+	pis->cfra= 0;
+	pis->version= 0;
+	pis->instance_private_data = 0;
+
+	/* clear the error list */
+	PIL_dynlib_get_error_as_string(NULL);
+
+	/* if(pis->handle) PIL_dynlib_close(pis->handle); */
+	/* pis->handle= 0; */
+
+	/* open the needed object */
+	pis->handle= PIL_dynlib_open(pis->name);
+	if(test_dlerr(pis->name, pis->name)) return;
+
+	if (pis->handle != 0) {
+		/* find the address of the version function */
+		version= (int (*)())PIL_dynlib_find_symbol(pis->handle, "plugin_seq_getversion");
+		if (test_dlerr(pis->name, "plugin_seq_getversion")) return;
+
+		if (version != 0) {
+			pis->version= version();
+			if (pis->version >= 2 && pis->version <= 6) {
+				int (*info_func)(PluginInfo *);
+				PluginInfo *info= (PluginInfo*) MEM_mallocN(sizeof(PluginInfo), "plugin_info");
+
+				info_func= (int (*)(PluginInfo *))PIL_dynlib_find_symbol(pis->handle, "plugin_getinfo");
+
+				if(info_func == NULL) error("No info func");
+				else {
+					info_func(info);
+
+					pis->pname= info->name;
+					pis->vars= info->nvars;
+					pis->cfra= info->cfra;
+
+					pis->varstr= info->varstr;
+
+					pis->doit= (void(*)(void))info->seq_doit;
+					if (info->init)
+						info->init();
+				}
+				MEM_freeN(info);
+
+				cp= PIL_dynlib_find_symbol(pis->handle, "seqname");
+				if(cp) strncpy(cp, seqname, 21);
+			} else {
+				printf ("Plugin returned unrecognized version number\n");
+				return;
+			}
+		}
+		alloc_private = (void* (*)())PIL_dynlib_find_symbol(
+			pis->handle, "plugin_seq_alloc_private_data");
+		if (alloc_private) {
+			pis->instance_private_data = alloc_private();
+		}
+		
+		pis->current_private_data = (void**) 
+			PIL_dynlib_find_symbol(
+				pis->handle, "plugin_private_data");
+	}
+}
+
+static PluginSeq *add_plugin_seq(const char *str, const char *seqname)
+{
+	PluginSeq *pis;
+	VarStruct *varstr;
+	int a;
+
+	pis= MEM_callocN(sizeof(PluginSeq), "PluginSeq");
+
+	strncpy(pis->name, str, FILE_MAXDIR+FILE_MAXFILE);
+	open_plugin_seq(pis, seqname);
+
+	if(pis->doit==0) {
+		if(pis->handle==0) error("no plugin: %s", str);
+		else error("in plugin: %s", str);
+		MEM_freeN(pis);
+		return 0;
+	}
+
+	/* default values */
+	varstr= pis->varstr;
+	for(a=0; a<pis->vars; a++, varstr++) {
+		if( (varstr->type & FLO)==FLO)
+			pis->data[a]= varstr->def;
+		else if( (varstr->type & INT)==INT)
+			*((int *)(pis->data+a))= (int) varstr->def;
+	}
+
+	return pis;
+}
+
+static void free_plugin_seq(PluginSeq *pis)
+{
+	if(pis==0) return;
+
+	/* no PIL_dynlib_close: same plugin can be opened multiple times with 1 handle */
+
+	if (pis->instance_private_data) {
+		void (*free_private)(void *);
+
+		free_private = (void (*)(void *))PIL_dynlib_find_symbol(
+			pis->handle, "plugin_seq_free_private_data");
+		if (free_private) {
+			free_private(pis->instance_private_data);
+		}
+	}
+
+	MEM_freeN(pis);
+}
+
+static void init_plugin(Sequence * seq, const char * fname)
+{
+	seq->plugin= (PluginSeq *)add_plugin_seq(fname, seq->name+2);
+}
+
+/* 
+ * FIXME: should query plugin! Could be generator, that needs zero inputs...
+ */
+static int num_inputs_plugin()
+{
+	return 1;
+}
+
+static void load_plugin(Sequence * seq)
+{
+	if (seq) {
+		open_plugin_seq(seq->plugin, seq->name+2);
+	}
+}
+
+static void copy_plugin(Sequence * dst, Sequence * src)
+{
+	if(src->plugin) {
+		dst->plugin= MEM_dupallocN(src->plugin);
+		open_plugin_seq(dst->plugin, dst->name+2);
+	}
+}
+
+static ImBuf * IMB_cast_away_list(ImBuf * i)
+{
+	if (!i) {
+		return 0;
+	}
+	return (ImBuf*) (((void**) i) + 2);
+}
+
+static void do_plugin_effect(Sequence * seq,int cfra,
+			     float facf0, float facf1, int x, int y, 
+			     struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			     struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	char *cp;
+	int float_rendering;
+	int use_temp_bufs = 0; /* Are needed since blur.c (and maybe some other
+				  old plugins) do very bad stuff
+				  with imbuf-internals */
+
+	if(seq->plugin && seq->plugin->doit) {
+		
+		if(seq->plugin->cfra) 
+			*(seq->plugin->cfra)= cfra;
+// XXX			*(seq->plugin->cfra)= frame_to_float(scene, cfra);
+		
+		cp = PIL_dynlib_find_symbol(
+			seq->plugin->handle, "seqname");
+
+		if(cp) strncpy(cp, seq->name+2, 22);
+
+		if (seq->plugin->current_private_data) {
+			*seq->plugin->current_private_data 
+				= seq->plugin->instance_private_data;
+		}
+
+		float_rendering = (out->rect_float != NULL);
+
+		if (seq->plugin->version<=3 && float_rendering) {
+			use_temp_bufs = 1;
+
+			if (ibuf1) {
+				ibuf1 = IMB_dupImBuf(ibuf1);
+				IMB_rect_from_float(ibuf1);
+				imb_freerectfloatImBuf(ibuf1);
+				ibuf1->flags &= ~IB_rectfloat;
+			}
+			if (ibuf2) {
+				ibuf2 = IMB_dupImBuf(ibuf2);
+				IMB_rect_from_float(ibuf2);
+				imb_freerectfloatImBuf(ibuf2);
+				ibuf2->flags &= ~IB_rectfloat;
+			} 
+			if (ibuf3) {
+				ibuf3 = IMB_dupImBuf(ibuf3);
+				IMB_rect_from_float(ibuf3);
+				imb_freerectfloatImBuf(ibuf3);
+				ibuf3->flags &= ~IB_rectfloat;
+			} 
+			if (!out->rect) imb_addrectImBuf(out);
+			imb_freerectfloatImBuf(out);
+			out->flags &= ~IB_rectfloat;
+		}
+
+		if (seq->plugin->version<=2) {
+			if(ibuf1) IMB_convert_rgba_to_abgr(ibuf1);
+			if(ibuf2) IMB_convert_rgba_to_abgr(ibuf2);
+			if(ibuf3) IMB_convert_rgba_to_abgr(ibuf3);
+		}
+
+		if (seq->plugin->version<=4) {
+			((SeqDoit)seq->plugin->doit)(
+				seq->plugin->data, facf0, facf1, x, y,
+				IMB_cast_away_list(ibuf1), 
+				IMB_cast_away_list(ibuf2), 
+				IMB_cast_away_list(out), 
+				IMB_cast_away_list(ibuf3));
+		} else {
+			((SeqDoit)seq->plugin->doit)(
+				seq->plugin->data, facf0, facf1, x, y,
+				ibuf1, ibuf2, out, ibuf3);
+		}
+
+		if (seq->plugin->version<=2) {
+			if (!use_temp_bufs) {
+				if(ibuf1) IMB_convert_rgba_to_abgr(ibuf1);
+				if(ibuf2) IMB_convert_rgba_to_abgr(ibuf2);
+				if(ibuf3) IMB_convert_rgba_to_abgr(ibuf3);
+			}
+			IMB_convert_rgba_to_abgr(out);
+		}
+		if (seq->plugin->version<=3 && float_rendering) {
+			IMB_float_from_rect(out);
+		}
+
+		if (use_temp_bufs) {
+			if (ibuf1) IMB_freeImBuf(ibuf1);
+			if (ibuf2) IMB_freeImBuf(ibuf2);
+			if (ibuf3) IMB_freeImBuf(ibuf3);
+		}
+	}
+}
+
+static int do_plugin_early_out(struct Sequence *seq,
+			       float facf0, float facf1)
+{
+	return 0;
+}
+
+static void free_plugin(struct Sequence * seq)
+{
+	free_plugin_seq(seq->plugin);
+	seq->plugin = 0;
+}
+
+/* **********************************************************************
+   ALPHA OVER
+   ********************************************************************** */
+
+static void init_alpha_over_or_under(Sequence * seq)
+{
+	Sequence * seq1 = seq->seq1;
+	Sequence * seq2 = seq->seq2;
+
+	seq->seq2= seq1;
+	seq->seq1= seq2;
+}
+
+static void do_alphaover_effect_byte(float facf0, float facf1, int x, int y, 
+				     char * rect1, char *rect2, char *out)
+{
+	int fac2, mfac, fac, fac4;
+	int xo, tempc;
+	char *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= (char *)rect1;
+	rt2= (char *)rect2;
+	rt= (char *)out;
+
+	fac2= (int)(256.0*facf0);
+	fac4= (int)(256.0*facf1);
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			/* rt = rt1 over rt2  (alpha from rt1) */
+
+			fac= fac2;
+			mfac= 256 - ( (fac2*rt1[3])>>8 );
+
+			if(fac==0) *( (unsigned int *)rt) = *( (unsigned int *)rt2);
+			else if(mfac==0) *( (unsigned int *)rt) = *( (unsigned int *)rt1);
+			else {
+				tempc= ( fac*rt1[0] + mfac*rt2[0])>>8;
+				if(tempc>255) rt[0]= 255; else rt[0]= tempc;
+				tempc= ( fac*rt1[1] + mfac*rt2[1])>>8;
+				if(tempc>255) rt[1]= 255; else rt[1]= tempc;
+				tempc= ( fac*rt1[2] + mfac*rt2[2])>>8;
+				if(tempc>255) rt[2]= 255; else rt[2]= tempc;
+				tempc= ( fac*rt1[3] + mfac*rt2[3])>>8;
+				if(tempc>255) rt[3]= 255; else rt[3]= tempc;
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			fac= fac4;
+			mfac= 256 - ( (fac4*rt1[3])>>8 );
+
+			if(fac==0) *( (unsigned int *)rt) = *( (unsigned int *)rt2);
+			else if(mfac==0) *( (unsigned int *)rt) = *( (unsigned int *)rt1);
+			else {
+				tempc= ( fac*rt1[0] + mfac*rt2[0])>>8;
+				if(tempc>255) rt[0]= 255; else rt[0]= tempc;
+				tempc= ( fac*rt1[1] + mfac*rt2[1])>>8;
+				if(tempc>255) rt[1]= 255; else rt[1]= tempc;
+				tempc= ( fac*rt1[2] + mfac*rt2[2])>>8;
+				if(tempc>255) rt[2]= 255; else rt[2]= tempc;
+				tempc= ( fac*rt1[3] + mfac*rt2[3])>>8;
+				if(tempc>255) rt[3]= 255; else rt[3]= tempc;
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+static void do_alphaover_effect_float(float facf0, float facf1, int x, int y, 
+				      float * rect1, float *rect2, float *out)
+{
+	float fac2, mfac, fac, fac4;
+	int xo;
+	float *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac2= facf0;
+	fac4= facf1;
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			/* rt = rt1 over rt2  (alpha from rt1) */
+
+			fac= fac2;
+			mfac= 1.0 - (fac2*rt1[3]) ;
+
+			if(fac <= 0.0) {
+				memcpy(rt, rt2, 4 * sizeof(float));
+			} else if(mfac <=0) {
+				memcpy(rt, rt1, 4 * sizeof(float));
+			} else {
+				rt[0] = fac*rt1[0] + mfac*rt2[0];
+				rt[1] = fac*rt1[1] + mfac*rt2[1];
+				rt[2] = fac*rt1[2] + mfac*rt2[2];
+				rt[3] = fac*rt1[3] + mfac*rt2[3];
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			fac= fac4;
+			mfac= 1.0 - (fac4*rt1[3]);
+
+			if(fac <= 0.0) {
+				memcpy(rt, rt2, 4 * sizeof(float));
+			} else if(mfac <= 0.0) {
+				memcpy(rt, rt1, 4 * sizeof(float));
+			} else {
+				rt[0] = fac*rt1[0] + mfac*rt2[0];
+				rt[1] = fac*rt1[1] + mfac*rt2[1];
+				rt[2] = fac*rt1[2] + mfac*rt2[2];
+				rt[3] = fac*rt1[3] + mfac*rt2[3];
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+static void do_alphaover_effect(Sequence * seq,int cfra,
+				float facf0, float facf1, int x, int y, 
+				struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+				struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_alphaover_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_alphaover_effect_byte(
+			facf0, facf1, x, y,
+			(char*) ibuf1->rect, (char*) ibuf2->rect,
+			(char*) out->rect);
+	}
+}
+
+
+/* **********************************************************************
+   ALPHA UNDER
+   ********************************************************************** */
+
+void do_alphaunder_effect_byte(
+	float facf0, float facf1, int x, int y, char *rect1, 
+	char *rect2, char *out)
+{
+	int fac2, mfac, fac, fac4;
+	int xo;
+	char *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac2= (int)(256.0*facf0);
+	fac4= (int)(256.0*facf1);
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			/* rt = rt1 under rt2  (alpha from rt2) */
+
+			/* this complex optimalisation is because the
+			 * 'skybuf' can be crossed in
+			 */
+			if(rt2[3]==0 && fac2==256) *( (unsigned int *)rt) = *( (unsigned int *)rt1);
+			else if(rt2[3]==255) *( (unsigned int *)rt) = *( (unsigned int *)rt2);
+			else {
+				mfac= rt2[3];
+				fac= (fac2*(256-mfac))>>8;
+
+				if(fac==0) *( (unsigned int *)rt) = *( (unsigned int *)rt2);
+				else {
+					rt[0]= ( fac*rt1[0] + mfac*rt2[0])>>8;
+					rt[1]= ( fac*rt1[1] + mfac*rt2[1])>>8;
+					rt[2]= ( fac*rt1[2] + mfac*rt2[2])>>8;
+					rt[3]= ( fac*rt1[3] + mfac*rt2[3])>>8;
+				}
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			if(rt2[3]==0 && fac4==256) *( (unsigned int *)rt) = *( (unsigned int *)rt1);
+			else if(rt2[3]==255) *( (unsigned int *)rt) = *( (unsigned int *)rt2);
+			else {
+				mfac= rt2[3];
+				fac= (fac4*(256-mfac))>>8;
+
+				if(fac==0) *( (unsigned int *)rt) = *( (unsigned int *)rt2);
+				else {
+					rt[0]= ( fac*rt1[0] + mfac*rt2[0])>>8;
+					rt[1]= ( fac*rt1[1] + mfac*rt2[1])>>8;
+					rt[2]= ( fac*rt1[2] + mfac*rt2[2])>>8;
+					rt[3]= ( fac*rt1[3] + mfac*rt2[3])>>8;
+				}
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+
+static void do_alphaunder_effect_float(float facf0, float facf1, int x, int y, 
+				       float *rect1, float *rect2, 
+				       float *out)
+{
+	float fac2, mfac, fac, fac4;
+	int xo;
+	float *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac2= facf0;
+	fac4= facf1;
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			/* rt = rt1 under rt2  (alpha from rt2) */
+
+			/* this complex optimalisation is because the
+			 * 'skybuf' can be crossed in
+			 */
+			if( rt2[3]<=0 && fac2>=1.0) {
+				memcpy(rt, rt1, 4 * sizeof(float));
+			} else if(rt2[3]>=1.0) {
+				memcpy(rt, rt2, 4 * sizeof(float));
+			} else {
+				mfac = rt2[3];
+				fac = fac2 * (1.0 - mfac);
+
+				if(fac == 0) {
+					memcpy(rt, rt2, 4 * sizeof(float));
+				} else {
+					rt[0]= fac*rt1[0] + mfac*rt2[0];
+					rt[1]= fac*rt1[1] + mfac*rt2[1];
+					rt[2]= fac*rt1[2] + mfac*rt2[2];
+					rt[3]= fac*rt1[3] + mfac*rt2[3];
+				}
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			if(rt2[3]<=0 && fac4 >= 1.0) {
+				memcpy(rt, rt1, 4 * sizeof(float));
+ 
+			} else if(rt2[3]>=1.0) {
+				memcpy(rt, rt2, 4 * sizeof(float));
+			} else {
+				mfac= rt2[3];
+				fac= fac4*(1.0-mfac);
+
+				if(fac == 0) {
+					memcpy(rt, rt2, 4 * sizeof(float));
+				} else {
+					rt[0]= fac * rt1[0] + mfac * rt2[0];
+					rt[1]= fac * rt1[1] + mfac * rt2[1];
+					rt[2]= fac * rt1[2] + mfac * rt2[2];
+					rt[3]= fac * rt1[3] + mfac * rt2[3];
+				}
+			}
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+static void do_alphaunder_effect(Sequence * seq,int cfra,
+				float facf0, float facf1, int x, int y, 
+				struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+				struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_alphaunder_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_alphaunder_effect_byte(
+			facf0, facf1, x, y,
+			(char*) ibuf1->rect, (char*) ibuf2->rect,
+			(char*) out->rect);
+	}
+}
+
+
+/* **********************************************************************
+   CROSS
+   ********************************************************************** */
+
+void do_cross_effect_byte(float facf0, float facf1, int x, int y, 
+			  char *rect1, char *rect2, 
+			  char *out)
+{
+	int fac1, fac2, fac3, fac4;
+	int xo;
+	char *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac2= (int)(256.0*facf0);
+	fac1= 256-fac2;
+	fac4= (int)(256.0*facf1);
+	fac3= 256-fac4;
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= (fac1*rt1[0] + fac2*rt2[0])>>8;
+			rt[1]= (fac1*rt1[1] + fac2*rt2[1])>>8;
+			rt[2]= (fac1*rt1[2] + fac2*rt2[2])>>8;
+			rt[3]= (fac1*rt1[3] + fac2*rt2[3])>>8;
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= (fac3*rt1[0] + fac4*rt2[0])>>8;
+			rt[1]= (fac3*rt1[1] + fac4*rt2[1])>>8;
+			rt[2]= (fac3*rt1[2] + fac4*rt2[2])>>8;
+			rt[3]= (fac3*rt1[3] + fac4*rt2[3])>>8;
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+	}
+}
+
+void do_cross_effect_float(float facf0, float facf1, int x, int y, 
+			   float *rect1, float *rect2, float *out)
+{
+	float fac1, fac2, fac3, fac4;
+	int xo;
+	float *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac2= facf0;
+	fac1= 1.0 - fac2;
+	fac4= facf1;
+	fac3= 1.0 - fac4;
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= fac1*rt1[0] + fac2*rt2[0];
+			rt[1]= fac1*rt1[1] + fac2*rt2[1];
+			rt[2]= fac1*rt1[2] + fac2*rt2[2];
+			rt[3]= fac1*rt1[3] + fac2*rt2[3];
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= fac3*rt1[0] + fac4*rt2[0];
+			rt[1]= fac3*rt1[1] + fac4*rt2[1];
+			rt[2]= fac3*rt1[2] + fac4*rt2[2];
+			rt[3]= fac3*rt1[3] + fac4*rt2[3];
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+	}
+}
+
+/* carefull: also used by speed effect! */
+
+static void do_cross_effect(Sequence * seq,int cfra,
+			    float facf0, float facf1, int x, int y, 
+			    struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			    struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_cross_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_cross_effect_byte(
+			facf0, facf1, x, y,
+			(char*) ibuf1->rect, (char*) ibuf2->rect,
+			(char*) out->rect);
+	}
+}
+
+
+/* **********************************************************************
+   GAMMA CROSS
+   ********************************************************************** */
+
+/* copied code from initrender.c */
+static unsigned short gamtab[65536];
+static unsigned short igamtab1[256];
+static int gamma_tabs_init = FALSE;
+
+#define RE_GAMMA_TABLE_SIZE 400
+
+static float gamma_range_table[RE_GAMMA_TABLE_SIZE + 1];
+static float gamfactor_table[RE_GAMMA_TABLE_SIZE];
+static float inv_gamma_range_table[RE_GAMMA_TABLE_SIZE + 1];
+static float inv_gamfactor_table[RE_GAMMA_TABLE_SIZE];
+static float color_domain_table[RE_GAMMA_TABLE_SIZE + 1]; 
+static float color_step;
+static float inv_color_step;
+static float valid_gamma;
+static float valid_inv_gamma;
+
+static void makeGammaTables(float gamma)
+{
+	/* we need two tables: one forward, one backward */
+	int i;
+
+	valid_gamma        = gamma;
+	valid_inv_gamma    = 1.0 / gamma;
+	color_step        = 1.0 / RE_GAMMA_TABLE_SIZE;
+	inv_color_step    = (float) RE_GAMMA_TABLE_SIZE; 
+
+	/* We could squeeze out the two range tables to gain some memory.        */	
+	for (i = 0; i < RE_GAMMA_TABLE_SIZE; i++) {
+		color_domain_table[i]   = i * color_step;
+		gamma_range_table[i]     = pow(color_domain_table[i],
+										valid_gamma);
+		inv_gamma_range_table[i] = pow(color_domain_table[i],
+										valid_inv_gamma);
+	}
+
+	/* The end of the table should match 1.0 carefully. In order to avoid    */
+	/* rounding errors, we just set this explicitly. The last segment may    */
+	/* have a different lenght than the other segments, but our              */
+	/* interpolation is insensitive to that.                                 */
+	color_domain_table[RE_GAMMA_TABLE_SIZE]   = 1.0;
+	gamma_range_table[RE_GAMMA_TABLE_SIZE]     = 1.0;
+	inv_gamma_range_table[RE_GAMMA_TABLE_SIZE] = 1.0;
+
+	/* To speed up calculations, we make these calc factor tables. They are  */
+	/* multiplication factors used in scaling the interpolation.             */
+	for (i = 0; i < RE_GAMMA_TABLE_SIZE; i++ ) {
+		gamfactor_table[i] = inv_color_step
+			* (gamma_range_table[i + 1] - gamma_range_table[i]) ;
+		inv_gamfactor_table[i] = inv_color_step
+			* (inv_gamma_range_table[i + 1] - inv_gamma_range_table[i]) ;
+	}
+
+} /* end of void makeGammaTables(float gamma) */
+
+
+static float gammaCorrect(float c)
+{
+	int i;
+	float res = 0.0;
+	
+	i = floor(c * inv_color_step);
+	/* Clip to range [0,1]: outside, just do the complete calculation.       */
+	/* We may have some performance problems here. Stretching up the LUT     */
+	/* may help solve that, by exchanging LUT size for the interpolation.    */
+	/* Negative colors are explicitly handled.                              */
+	if (i < 0) res = -pow(abs(c), valid_gamma);
+	else if (i >= RE_GAMMA_TABLE_SIZE ) res = pow(c, valid_gamma);
+	else res = gamma_range_table[i] + 
+  			 ( (c - color_domain_table[i]) * gamfactor_table[i]); 
+	
+	return res;
+} /* end of float gammaCorrect(float col) */
+
+/* ------------------------------------------------------------------------- */
+
+static float invGammaCorrect(float col)
+{
+	int i;
+	float res = 0.0;
+
+	i = floor(col*inv_color_step);
+	/* Negative colors are explicitly handled.                              */
+	if (i < 0) res = -pow(abs(col), valid_inv_gamma);
+	else if (i >= RE_GAMMA_TABLE_SIZE) res = pow(col, valid_inv_gamma);
+	else res = inv_gamma_range_table[i] + 
+  			 ( (col - color_domain_table[i]) * inv_gamfactor_table[i]);
+ 
+	return res;
+} /* end of float invGammaCorrect(float col) */
+
+
+static void gamtabs(float gamma)
+{
+	float val, igamma= 1.0f/gamma;
+	int a;
+	
+	/* gamtab: in short, out short */
+	for(a=0; a<65536; a++) {
+		val= a;
+		val/= 65535.0;
+		
+		if(gamma==2.0) val= sqrt(val);
+		else if(gamma!=1.0) val= pow(val, igamma);
+		
+		gamtab[a]= (65535.99*val);
+	}
+	/* inverse gamtab1 : in byte, out short */
+	for(a=1; a<=256; a++) {
+		if(gamma==2.0) igamtab1[a-1]= a*a-1;
+		else if(gamma==1.0) igamtab1[a-1]= 256*a-1;
+		else {
+			val= a/256.0;
+			igamtab1[a-1]= (65535.0*pow(val, gamma)) -1 ;
+		}
+	}
+
+}
+
+static void build_gammatabs()
+{
+	if (gamma_tabs_init == FALSE) {
+		gamtabs(2.0f);
+		makeGammaTables(2.0f);
+		gamma_tabs_init = TRUE;
+	}
+}
+
+static void init_gammacross(Sequence * seq)
+{
+}
+
+static void load_gammacross(Sequence * seq)
+{
+}
+
+static void free_gammacross(Sequence * seq)
+{
+}
+
+static void do_gammacross_effect_byte(float facf0, float facf1, 
+				      int x, int y, 
+				      char *rect1, 
+				      char *rect2, 
+				      char *out)
+{
+	int fac1, fac2, col;
+	int xo;
+	char *rt1, *rt2, *rt;
+	
+	xo= x;
+	rt1= (char *)rect1;
+	rt2= (char *)rect2;
+	rt= (char *)out;
+
+	fac2= (int)(256.0*facf0);
+	fac1= 256-fac2;
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			col= (fac1*igamtab1[rt1[0]] + fac2*igamtab1[rt2[0]])>>8;
+			if(col>65535) rt[0]= 255; else rt[0]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+			col=(fac1*igamtab1[rt1[1]] + fac2*igamtab1[rt2[1]])>>8;
+			if(col>65535) rt[1]= 255; else rt[1]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+			col= (fac1*igamtab1[rt1[2]] + fac2*igamtab1[rt2[2]])>>8;
+			if(col>65535) rt[2]= 255; else rt[2]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+			col= (fac1*igamtab1[rt1[3]] + fac2*igamtab1[rt2[3]])>>8;
+			if(col>65535) rt[3]= 255; else rt[3]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			col= (fac1*igamtab1[rt1[0]] + fac2*igamtab1[rt2[0]])>>8;
+			if(col>65535) rt[0]= 255; else rt[0]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+			col= (fac1*igamtab1[rt1[1]] + fac2*igamtab1[rt2[1]])>>8;
+			if(col>65535) rt[1]= 255; else rt[1]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+			col= (fac1*igamtab1[rt1[2]] + fac2*igamtab1[rt2[2]])>>8;
+			if(col>65535) rt[2]= 255; else rt[2]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+			col= (fac1*igamtab1[rt1[3]] + fac2*igamtab1[rt2[3]])>>8;
+			if(col>65535) rt[3]= 255; else rt[3]= ( (char *)(gamtab+col))[MOST_SIG_BYTE];
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+
+}
+
+static void do_gammacross_effect_float(float facf0, float facf1, 
+				       int x, int y, 
+				       float *rect1, float *rect2, 
+				       float *out)
+{
+	float fac1, fac2;
+	int xo;
+	float *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac2= facf0;
+	fac1= 1.0 - fac2;
+
+	while(y--) {
+
+		x= xo * 4;
+		while(x--) {
+
+			*rt= gammaCorrect(
+				fac1 * invGammaCorrect(*rt1) 
+				+ fac2 * invGammaCorrect(*rt2));
+			rt1++; rt2++; rt++;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo * 4;
+		while(x--) {
+
+			*rt= gammaCorrect(
+				fac1*invGammaCorrect(*rt1) 
+				+ fac2*invGammaCorrect(*rt2));
+
+			rt1++; rt2++; rt++;
+		}
+	}
+}
+
+static void do_gammacross_effect(Sequence * seq,int cfra,
+				 float facf0, float facf1, int x, int y, 
+				 struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+				 struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	build_gammatabs();
+
+	if (out->rect_float) {
+		do_gammacross_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_gammacross_effect_byte(
+			facf0, facf1, x, y,
+			(char*) ibuf1->rect, (char*) ibuf2->rect,
+			(char*) out->rect);
+	}
+}
+
+
+/* **********************************************************************
+   ADD
+   ********************************************************************** */
+
+static void do_add_effect_byte(float facf0, float facf1, int x, int y, 
+			       unsigned char *rect1, unsigned char *rect2, 
+			       unsigned char *out)
+{
+	int col, xo, fac1, fac3;
+	char *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= (char *)rect1;
+	rt2= (char *)rect2;
+	rt= (char *)out;
+
+	fac1= (int)(256.0*facf0);
+	fac3= (int)(256.0*facf1);
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			col= rt1[0]+ ((fac1*rt2[0])>>8);
+			if(col>255) rt[0]= 255; else rt[0]= col;
+			col= rt1[1]+ ((fac1*rt2[1])>>8);
+			if(col>255) rt[1]= 255; else rt[1]= col;
+			col= rt1[2]+ ((fac1*rt2[2])>>8);
+			if(col>255) rt[2]= 255; else rt[2]= col;
+			col= rt1[3]+ ((fac1*rt2[3])>>8);
+			if(col>255) rt[3]= 255; else rt[3]= col;
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			col= rt1[0]+ ((fac3*rt2[0])>>8);
+			if(col>255) rt[0]= 255; else rt[0]= col;
+			col= rt1[1]+ ((fac3*rt2[1])>>8);
+			if(col>255) rt[1]= 255; else rt[1]= col;
+			col= rt1[2]+ ((fac3*rt2[2])>>8);
+			if(col>255) rt[2]= 255; else rt[2]= col;
+			col= rt1[3]+ ((fac3*rt2[3])>>8);
+			if(col>255) rt[3]= 255; else rt[3]= col;
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+static void do_add_effect_float(float facf0, float facf1, int x, int y, 
+				float *rect1, float *rect2, 
+				float *out)
+{
+	int xo;
+	float fac1, fac3;
+	float *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac1= facf0;
+	fac3= facf1;
+
+	while(y--) {
+
+		x= xo * 4;
+		while(x--) {
+			*rt = *rt1 + fac1 * (*rt2);
+
+			rt1++; rt2++; rt++;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo * 4;
+		while(x--) {
+			*rt = *rt1 + fac3 * (*rt2);
+
+			rt1++; rt2++; rt++;
+		}
+	}
+}
+
+static void do_add_effect(Sequence * seq,int cfra,
+			  float facf0, float facf1, int x, int y, 
+			  struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			  struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_add_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_add_effect_byte(
+			facf0, facf1, x, y,
+			(unsigned char*) ibuf1->rect, (unsigned char*) ibuf2->rect,
+			(unsigned char*) out->rect);
+	}
+}
+
+
+/* **********************************************************************
+   SUB
+   ********************************************************************** */
+
+static void do_sub_effect_byte(float facf0, float facf1, 
+			       int x, int y, 
+			       char *rect1, char *rect2, char *out)
+{
+	int col, xo, fac1, fac3;
+	char *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= (char *)rect1;
+	rt2= (char *)rect2;
+	rt= (char *)out;
+
+	fac1= (int)(256.0*facf0);
+	fac3= (int)(256.0*facf1);
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			col= rt1[0]- ((fac1*rt2[0])>>8);
+			if(col<0) rt[0]= 0; else rt[0]= col;
+			col= rt1[1]- ((fac1*rt2[1])>>8);
+			if(col<0) rt[1]= 0; else rt[1]= col;
+			col= rt1[2]- ((fac1*rt2[2])>>8);
+			if(col<0) rt[2]= 0; else rt[2]= col;
+			col= rt1[3]- ((fac1*rt2[3])>>8);
+			if(col<0) rt[3]= 0; else rt[3]= col;
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			col= rt1[0]- ((fac3*rt2[0])>>8);
+			if(col<0) rt[0]= 0; else rt[0]= col;
+			col= rt1[1]- ((fac3*rt2[1])>>8);
+			if(col<0) rt[1]= 0; else rt[1]= col;
+			col= rt1[2]- ((fac3*rt2[2])>>8);
+			if(col<0) rt[2]= 0; else rt[2]= col;
+			col= rt1[3]- ((fac3*rt2[3])>>8);
+			if(col<0) rt[3]= 0; else rt[3]= col;
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+static void do_sub_effect_float(float facf0, float facf1, int x, int y, 
+				float *rect1, float *rect2, 
+				float *out)
+{
+	int xo;
+	float fac1, fac3;
+	float *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac1= facf0;
+	fac3= facf1;
+
+	while(y--) {
+
+		x= xo * 4;
+		while(x--) {
+			*rt = *rt1 - fac1 * (*rt2);
+
+			rt1++; rt2++; rt++;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo * 4;
+		while(x--) {
+			*rt = *rt1 - fac3 * (*rt2);
+
+			rt1++; rt2++; rt++;
+		}
+	}
+}
+
+static void do_sub_effect(Sequence * seq,int cfra,
+			  float facf0, float facf1, int x, int y, 
+			  struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			  struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_sub_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_sub_effect_byte(
+			facf0, facf1, x, y,
+			(char*) ibuf1->rect, (char*) ibuf2->rect,
+			(char*) out->rect);
+	}
+}
+
+/* **********************************************************************
+   DROP
+   ********************************************************************** */
+
+/* Must be > 0 or add precopy, etc to the function */
+#define XOFF	8
+#define YOFF	8
+
+static void do_drop_effect_byte(float facf0, float facf1, int x, int y, 
+				unsigned char *rect2i, unsigned char *rect1i, 
+				unsigned char *outi)
+{
+	int height, width, temp, fac, fac1, fac2;
+	char *rt1, *rt2, *out;
+	int field= 1;
+
+	width= x;
+	height= y;
+
+	fac1= (int)(70.0*facf0);
+	fac2= (int)(70.0*facf1);
+
+	rt2= (char*) (rect2i + YOFF*width);
+	rt1= (char*) rect1i;
+	out= (char*) outi;
+	for (y=0; y<height-YOFF; y++) {
+		if(field) fac= fac1;
+		else fac= fac2;
+		field= !field;
+
+		memcpy(out, rt1, sizeof(int)*XOFF);
+		rt1+= XOFF*4;
+		out+= XOFF*4;
+
+		for (x=XOFF; x<width; x++) {
+			temp= ((fac*rt2[3])>>8);
+
+			*(out++)= MAX2(0, *rt1 - temp); rt1++;
+			*(out++)= MAX2(0, *rt1 - temp); rt1++;
+			*(out++)= MAX2(0, *rt1 - temp); rt1++;
+			*(out++)= MAX2(0, *rt1 - temp); rt1++;
+			rt2+=4;
+		}
+		rt2+=XOFF*4;
+	}
+	memcpy(out, rt1, sizeof(int)*YOFF*width);
+}
+
+static void do_drop_effect_float(float facf0, float facf1, int x, int y, 
+				 float *rect2i, float *rect1i, 
+				 float *outi)
+{
+	int height, width;
+	float temp, fac, fac1, fac2;
+	float *rt1, *rt2, *out;
+	int field= 1;
+
+	width= x;
+	height= y;
+
+	fac1= 70.0*facf0;
+	fac2= 70.0*facf1;
+
+	rt2=  (rect2i + YOFF*width);
+	rt1=  rect1i;
+	out=  outi;
+	for (y=0; y<height-YOFF; y++) {
+		if(field) fac= fac1;
+		else fac= fac2;
+		field= !field;
+
+		memcpy(out, rt1, 4 * sizeof(float)*XOFF);
+		rt1+= XOFF*4;
+		out+= XOFF*4;
+
+		for (x=XOFF; x<width; x++) {
+			temp= fac * rt2[3];
+
+			*(out++)= MAX2(0.0, *rt1 - temp); rt1++;
+			*(out++)= MAX2(0.0, *rt1 - temp); rt1++;
+			*(out++)= MAX2(0.0, *rt1 - temp); rt1++;
+			*(out++)= MAX2(0.0, *rt1 - temp); rt1++;
+			rt2+=4;
+		}
+		rt2+=XOFF*4;
+	}
+	memcpy(out, rt1, 4 * sizeof(float)*YOFF*width);
+}
+
+
+static void do_drop_effect(Sequence * seq,int cfra,
+			   float facf0, float facf1, int x, int y, 
+			   struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			   struct ImBuf * ibuf3,
+			   struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_drop_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_drop_effect_byte(
+			facf0, facf1, x, y,
+			(unsigned char*) ibuf1->rect, (unsigned char*) ibuf2->rect,
+			(unsigned char*) out->rect);
+	}
+}
+
+/* **********************************************************************
+   MUL
+   ********************************************************************** */
+
+static void do_mul_effect_byte(float facf0, float facf1, int x, int y, 
+			       unsigned char *rect1, unsigned char *rect2, 
+			       unsigned char *out)
+{
+	int xo, fac1, fac3;
+	char *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= (char *)rect1;
+	rt2= (char *)rect2;
+	rt= (char *)out;
+
+	fac1= (int)(256.0*facf0);
+	fac3= (int)(256.0*facf1);
+
+	/* formula:
+	 *		fac*(a*b) + (1-fac)*a  => fac*a*(b-1)+axaux= c*px + py*s ;//+centx
+			yaux= -s*px + c*py;//+centy
+	 */
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= rt1[0] + ((fac1*rt1[0]*(rt2[0]-256))>>16);
+			rt[1]= rt1[1] + ((fac1*rt1[1]*(rt2[1]-256))>>16);
+			rt[2]= rt1[2] + ((fac1*rt1[2]*(rt2[2]-256))>>16);
+			rt[3]= rt1[3] + ((fac1*rt1[3]*(rt2[3]-256))>>16);
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= rt1[0] + ((fac3*rt1[0]*(rt2[0]-256))>>16);
+			rt[1]= rt1[1] + ((fac3*rt1[1]*(rt2[1]-256))>>16);
+			rt[2]= rt1[2] + ((fac3*rt1[2]*(rt2[2]-256))>>16);
+			rt[3]= rt1[3] + ((fac3*rt1[3]*(rt2[3]-256))>>16);
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+static void do_mul_effect_float(float facf0, float facf1, int x, int y, 
+			        float *rect1, float *rect2, 
+			        float *out)
+{
+	int xo;
+	float fac1, fac3;
+	float *rt1, *rt2, *rt;
+
+	xo= x;
+	rt1= rect1;
+	rt2= rect2;
+	rt= out;
+
+	fac1= facf0;
+	fac3= facf1;
+
+	/* formula:
+	 *		fac*(a*b) + (1-fac)*a  => fac*a*(b-1)+a
+	 */
+
+	while(y--) {
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= rt1[0] + fac1*rt1[0]*(rt2[0]-1.0);
+			rt[1]= rt1[1] + fac1*rt1[1]*(rt2[1]-1.0);
+			rt[2]= rt1[2] + fac1*rt1[2]*(rt2[2]-1.0);
+			rt[3]= rt1[3] + fac1*rt1[3]*(rt2[3]-1.0);
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+
+		if(y==0) break;
+		y--;
+
+		x= xo;
+		while(x--) {
+
+			rt[0]= rt1[0] + fac3*rt1[0]*(rt2[0]-1.0);
+			rt[1]= rt1[1] + fac3*rt1[1]*(rt2[1]-1.0);
+			rt[2]= rt1[2] + fac3*rt1[2]*(rt2[2]-1.0);
+			rt[3]= rt1[3] + fac3*rt1[3]*(rt2[3]-1.0);
+
+			rt1+= 4; rt2+= 4; rt+= 4;
+		}
+	}
+}
+
+static void do_mul_effect(Sequence * seq,int cfra,
+			  float facf0, float facf1, int x, int y, 
+			  struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			  struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_mul_effect_float(
+			facf0, facf1, x, y,
+			ibuf1->rect_float, ibuf2->rect_float,
+			out->rect_float);
+	} else {
+		do_mul_effect_byte(
+			facf0, facf1, x, y,
+			(unsigned char*) ibuf1->rect, (unsigned char*) ibuf2->rect,
+			(unsigned char*) out->rect);
+	}
+}
+
+/* **********************************************************************
+   WIPE
+   ********************************************************************** */
+
+typedef struct WipeZone {
+	float angle;
+	int flip;
+	int xo, yo;
+	int width;
+	float invwidth;
+	float pythangle;
+} WipeZone;
+
+static void precalc_wipe_zone(WipeZone *wipezone, WipeVars *wipe, int xo, int yo)
+{
+	wipezone->flip = (wipe->angle < 0);
+	wipezone->angle = pow(fabs(wipe->angle)/45.0f, log(xo)/log(2.0f));
+	wipezone->xo = xo;
+	wipezone->yo = yo;
+	wipezone->width = (int)(wipe->edgeWidth*((xo+yo)/2.0f));
+	wipezone->pythangle = 1.0f/sqrt(wipe->angle*wipe->angle + 1.0f);
+
+	if(wipe->wipetype == DO_SINGLE_WIPE)
+		wipezone->invwidth = 1.0f/wipezone->width;
+	else
+		wipezone->invwidth = 1.0f/(0.5f*wipezone->width);
+}
+
+// This function calculates the blur band for the wipe effects
+static float in_band(WipeZone *wipezone,float width,float dist,float perc,int side,int dir)
+{
+	float t1,t2,alpha,percwidth;
+
+	if(width == 0)
+		return (float)side;
+
+	if(side == 1)
+		percwidth = width * perc;
+	else
+		percwidth = width * (1 - perc);
+	
+	if(width < dist)
+		return side;
+	
+	t1 = dist * wipezone->invwidth;  //percentange of width that is
+	t2 = wipezone->invwidth;  //amount of alpha per % point
+	
+	if(side == 1)
+		alpha = (t1*t2*100) + (1-perc); // add point's alpha contrib to current position in wipe
+	else
+		alpha = (1-perc) - (t1*t2*100);
+	
+	if(dir == 0)
+		alpha = 1-alpha;
+
+	return alpha;
+}
+
+static float check_zone(WipeZone *wipezone, int x, int y,
+	Sequence *seq, float facf0) 
+{
+	float posx, posy,hyp,hyp2,angle,hwidth,b1,b2,b3,pointdist;
+/*some future stuff
+float hyp3,hyp4,b4,b5	   
+*/
+	float temp1,temp2,temp3,temp4; //some placeholder variables
+	int xo = wipezone->xo;
+	int yo = wipezone->yo;
+	float halfx = xo*0.5f;
+	float halfy = yo*0.5f;
+	float widthf,output=0;
+	WipeVars *wipe = (WipeVars *)seq->effectdata;
+	int width;
+
+	if(wipezone->flip) x = xo - x;
+	angle = wipezone->angle;
+
+	posy = facf0 * yo;
+
+	if(wipe->forward){
+		posx = facf0 * xo;
+		posy = facf0 * yo;
+	} else{
+		posx = xo - facf0 * xo;
+		posy = yo - facf0 * yo;
+	}
+
+	switch (wipe->wipetype) {
+		case DO_SINGLE_WIPE:
+			width = wipezone->width;
+			hwidth = width*0.5f;
+
+			if(angle == 0.0f) {
+				b1 = posy;
+				b2 = y;
+				hyp = fabs(y - posy);
+			}
+			else {
+				b1 = posy - (-angle)*posx;
+				b2 = y - (-angle)*x;
+				hyp = fabs(angle*x+y+(-posy-angle*posx))*wipezone->pythangle;
+			}
+
+			if(angle < 0) {
+				temp1 = b1;
+				b1 = b2;
+				b2 = temp1;
+			}
+
+			if(wipe->forward) {
+				if(b1 < b2)
+					output = in_band(wipezone,width,hyp,facf0,1,1);
+				else
+					output = in_band(wipezone,width,hyp,facf0,0,1);
+		 	}
+			else {
+				if(b1 < b2)
+					output = in_band(wipezone,width,hyp,facf0,0,1);
+				else
+					output = in_band(wipezone,width,hyp,facf0,1,1);
+		 	}
+		break;
+	 
+		case DO_DOUBLE_WIPE:
+			if(!wipe->forward)
+				facf0 = 1.0f-facf0;   // Go the other direction
+
+			width = wipezone->width;  // calculate the blur width
+			hwidth = width*0.5f;
+			if (angle == 0) {
+				b1 = posy*0.5f;
+				b3 = yo-posy*0.5f;
+				b2 = y;
+
+				hyp = abs(y - posy*0.5f);
+				hyp2 = abs(y - (yo-posy*0.5f));
+			}
+			else {
+				b1 = posy*0.5f - (-angle)*posx*0.5f;
+				b3 = (yo-posy*0.5f) - (-angle)*(xo-posx*0.5f);
+				b2 = y - (-angle)*x;
+
+				hyp = abs(angle*x+y+(-posy*0.5f-angle*posx*0.5f))*wipezone->pythangle;
+				hyp2 = abs(angle*x+y+(-(yo-posy*0.5f)-angle*(xo-posx*0.5f)))*wipezone->pythangle;
+			}
+
+			temp1 = xo*(1-facf0*0.5f)-xo*facf0*0.5f;
+			temp2 = yo*(1-facf0*0.5f)-yo*facf0*0.5f;
+			pointdist = sqrt(temp1*temp1 + temp2*temp2);
+
+			if(b2 < b1 && b2 < b3 ){
+				if(hwidth < pointdist)
+					output = in_band(wipezone,hwidth,hyp,facf0,0,1);
+			} else if(b2 > b1 && b2 > b3 ){
+				if(hwidth < pointdist)
+					output = in_band(wipezone,hwidth,hyp2,facf0,0,1);	
+			} else {
+				if(  hyp < hwidth && hyp2 > hwidth )
+					output = in_band(wipezone,hwidth,hyp,facf0,1,1);
+				else if( hyp > hwidth && hyp2 < hwidth )
+				 	 output = in_band(wipezone,hwidth,hyp2,facf0,1,1);
+				else
+				 	 output = in_band(wipezone,hwidth,hyp2,facf0,1,1) * in_band(wipezone,hwidth,hyp,facf0,1,1);
+			}
+			if(!wipe->forward)output = 1-output;
+	 	break;
+	 	case DO_CLOCK_WIPE:
+	 	 	/*
+	 	 		temp1: angle of effect center in rads
+	 	 		temp2: angle of line through (halfx,halfy) and (x,y) in rads
+	 	 		temp3: angle of low side of blur
+	 	 		temp4: angle of high side of blur
+	 	 	*/
+		 	output = 1.0f - facf0;
+	 		widthf = wipe->edgeWidth*2.0f*(float)M_PI;
+ 	 		temp1 = 2.0f * (float)M_PI * facf0;
+	 	 	
+ 			if(wipe->forward){
+ 				temp1 = 2.0f*(float)M_PI - temp1;
+ 			}
+ 	 		
+ 	 		x = x - halfx;
+ 	 		y = y - halfy;
+
+ 	 		temp2 = asin(abs(y)/sqrt(x*x + y*y));
+ 	 		if(x <= 0 && y >= 0) temp2 = (float)M_PI - temp2;
+ 	 		else if(x<=0 && y <= 0) temp2 += (float)M_PI;
+ 	 		else if(x >= 0 && y <= 0) temp2 = 2.0f*(float)M_PI - temp2;
+
+ 	 		if(wipe->forward){
+	 	 		temp3 = temp1-(widthf*0.5f)*facf0;
+	 	 		temp4 = temp1+(widthf*0.5f)*(1-facf0);
+ 	 		} else{
+	 	 		temp3 = temp1-(widthf*0.5f)*(1-facf0);
+	 	 		temp4 = temp1+(widthf*0.5f)*facf0;
+			}
+ 	 		if (temp3 < 0) temp3 = 0;
+ 	 		if (temp4 > 2.0f*(float)M_PI) temp4 = 2.0f*(float)M_PI;
+ 	 		
+ 	 		
+ 	 		if(temp2 < temp3) output = 0;
+ 	 		else if (temp2 > temp4) output = 1;
+ 	 		else output = (temp2-temp3)/(temp4-temp3);
+	 	 	if(x == 0 && y == 0) output = 1;
+			if(output != output) output = 1;
+			if(wipe->forward) output = 1 - output;
+		break;
+	/* BOX WIPE IS NOT WORKING YET */
+	/* case DO_CROSS_WIPE: */
+	/* BOX WIPE IS NOT WORKING YET */
+	/* 
+		case DO_BOX_WIPE: 
+			if(invert)facf0 = 1-facf0;
+
+			width = (int)(wipe->edgeWidth*((xo+yo)/2.0));
+			hwidth = (float)width/2.0;
+			if (angle == 0)angle = 0.000001;
+			b1 = posy/2 - (-angle)*posx/2;
+			b3 = (yo-posy/2) - (-angle)*(xo-posx/2);
+			b2 = y - (-angle)*x;
+
+			hyp = abs(angle*x+y+(-posy/2-angle*posx/2))*wipezone->pythangle;
+			hyp2 = abs(angle*x+y+(-(yo-posy/2)-angle*(xo-posx/2)))*wipezone->pythangle;
+
+			temp1 = xo*(1-facf0/2)-xo*facf0/2;
+			temp2 = yo*(1-facf0/2)-yo*facf0/2;
+			pointdist = sqrt(temp1*temp1 + temp2*temp2);
+
+			if(b2 < b1 && b2 < b3 ){
+				if(hwidth < pointdist)
+					output = in_band(wipezone,hwidth,hyp,facf0,0,1);
+			} else if(b2 > b1 && b2 > b3 ){
+				if(hwidth < pointdist)
+					output = in_band(wipezone,hwidth,hyp2,facf0,0,1);	
+			} else {
+				if( hyp < hwidth && hyp2 > hwidth )
+					output = in_band(wipezone,hwidth,hyp,facf0,1,1);
+				else if( hyp > hwidth && hyp2 < hwidth )
+				 	output = in_band(wipezone,hwidth,hyp2,facf0,1,1);
+				else
+				 	output = in_band(wipezone,hwidth,hyp2,facf0,1,1) * in_band(wipezone,hwidth,hyp,facf0,1,1);
+			}
+
+			if(invert)facf0 = 1-facf0;
+			angle = -1/angle;
+			b1 = posy/2 - (-angle)*posx/2;
+			b3 = (yo-posy/2) - (-angle)*(xo-posx/2);
+			b2 = y - (-angle)*x;
+
+			hyp = abs(angle*x+y+(-posy/2-angle*posx/2))*wipezone->pythangle;
+			hyp2 = abs(angle*x+y+(-(yo-posy/2)-angle*(xo-posx/2)))*wipezone->pythangle;
+
+			if(b2 < b1 && b2 < b3 ){
+				if(hwidth < pointdist)
+					output *= in_band(wipezone,hwidth,hyp,facf0,0,1);
+			} else if(b2 > b1 && b2 > b3 ){
+				if(hwidth < pointdist)
+					output *= in_band(wipezone,hwidth,hyp2,facf0,0,1);	
+			} else {
+				if( hyp < hwidth && hyp2 > hwidth )
+					output *= in_band(wipezone,hwidth,hyp,facf0,1,1);
+				else if( hyp > hwidth && hyp2 < hwidth )
+					output *= in_band(wipezone,hwidth,hyp2,facf0,1,1);
+				else
+					output *= in_band(wipezone,hwidth,hyp2,facf0,1,1) * in_band(wipezone,hwidth,hyp,facf0,1,1);
+			}
+
+		break;
+*/
+		case DO_IRIS_WIPE:
+			if(xo > yo) yo = xo;
+			else xo = yo;
+
+			if(!wipe->forward) facf0 = 1-facf0;
+
+			width = wipezone->width;
+			hwidth = width*0.5f;
+
+			temp1 = (halfx-(halfx)*facf0);
+		 	pointdist = sqrt(temp1*temp1 + temp1*temp1);
+		 
+		 	temp2 = sqrt((halfx-x)*(halfx-x) + (halfy-y)*(halfy-y));
+		 	if(temp2 > pointdist) output = in_band(wipezone,hwidth,fabs(temp2-pointdist),facf0,0,1);
+		 	else output = in_band(wipezone,hwidth,fabs(temp2-pointdist),facf0,1,1);
+		 
+			if(!wipe->forward) output = 1-output;
+			
+		break;
+	}
+	if (output < 0) output = 0;
+	else if(output > 1) output = 1;
+	return output;
+}
+
+static void init_wipe_effect(Sequence *seq)
+{
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = MEM_callocN(sizeof(struct WipeVars), "wipevars");
+}
+
+static int num_inputs_wipe()
+{
+	return 1;
+}
+
+static void free_wipe_effect(Sequence *seq)
+{
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = 0;
+}
+
+static void copy_wipe_effect(Sequence *dst, Sequence *src)
+{
+	dst->effectdata = MEM_dupallocN(src->effectdata);
+}
+
+static void do_wipe_effect_byte(Sequence *seq, float facf0, float facf1, 
+				int x, int y, 
+				unsigned char *rect1, 
+				unsigned char *rect2, unsigned char *out)
+{
+	WipeZone wipezone;
+	WipeVars *wipe = (WipeVars *)seq->effectdata;
+	int xo, yo;
+	char *rt1, *rt2, *rt;
+
+	precalc_wipe_zone(&wipezone, wipe, x, y);
+
+	rt1 = (char *)rect1;
+	rt2 = (char *)rect2;
+	rt = (char *)out;
+
+	xo = x;
+	yo = y;
+	for(y=0;y<yo;y++) {
+		for(x=0;x<xo;x++) {
+			float check = check_zone(&wipezone,x,y,seq,facf0);
+			if (check) {
+				if (rt1) {
+					rt[0] = (int)(rt1[0]*check)+ (int)(rt2[0]*(1-check));
+					rt[1] = (int)(rt1[1]*check)+ (int)(rt2[1]*(1-check));
+					rt[2] = (int)(rt1[2]*check)+ (int)(rt2[2]*(1-check));
+					rt[3] = (int)(rt1[3]*check)+ (int)(rt2[3]*(1-check));
+				} else {
+					rt[0] = 0;
+					rt[1] = 0;
+					rt[2] = 0;
+					rt[3] = 255;
+				}
+			} else {
+				if (rt2) {
+					rt[0] = rt2[0];
+					rt[1] = rt2[1];
+					rt[2] = rt2[2];
+					rt[3] = rt2[3];
+				} else {
+					rt[0] = 0;
+					rt[1] = 0;
+					rt[2] = 0;
+					rt[3] = 255;
+				}
+			}
+
+			rt+=4;
+			if(rt1 !=NULL){
+				rt1+=4;
+			}
+			if(rt2 !=NULL){
+				rt2+=4;
+			}
+		}
+	}
+}
+
+static void do_wipe_effect_float(Sequence *seq, float facf0, float facf1, 
+				 int x, int y, 
+				 float *rect1, 
+				 float *rect2, float *out)
+{
+	WipeZone wipezone;
+	WipeVars *wipe = (WipeVars *)seq->effectdata;
+	int xo, yo;
+	float *rt1, *rt2, *rt;
+
+	precalc_wipe_zone(&wipezone, wipe, x, y);
+
+	rt1 = rect1;
+	rt2 = rect2;
+	rt = out;
+
+	xo = x;
+	yo = y;
+	for(y=0;y<yo;y++) {
+		for(x=0;x<xo;x++) {
+			float check = check_zone(&wipezone,x,y,seq,facf0);
+			if (check) {
+				if (rt1) {
+					rt[0] = rt1[0]*check+ rt2[0]*(1-check);
+					rt[1] = rt1[1]*check+ rt2[1]*(1-check);
+					rt[2] = rt1[2]*check+ rt2[2]*(1-check);
+					rt[3] = rt1[3]*check+ rt2[3]*(1-check);
+				} else {
+					rt[0] = 0;
+					rt[1] = 0;
+					rt[2] = 0;
+					rt[3] = 1.0;
+				}
+			} else {
+				if (rt2) {
+					rt[0] = rt2[0];
+					rt[1] = rt2[1];
+					rt[2] = rt2[2];
+					rt[3] = rt2[3];
+				} else {
+					rt[0] = 0;
+					rt[1] = 0;
+					rt[2] = 0;
+					rt[3] = 1.0;
+				}
+			}
+
+			rt+=4;
+			if(rt1 !=NULL){
+				rt1+=4;
+			}
+			if(rt2 !=NULL){
+				rt2+=4;
+			}
+		}
+	}
+}
+
+static void do_wipe_effect(Sequence * seq,int cfra,
+			   float facf0, float facf1, int x, int y, 
+			   struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			   struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_wipe_effect_float(seq,
+				     facf0, facf1, x, y,
+				     ibuf1->rect_float, ibuf2->rect_float,
+				     out->rect_float);
+	} else {
+		do_wipe_effect_byte(seq,
+				    facf0, facf1, x, y,
+				    (unsigned char*) ibuf1->rect, (unsigned char*) ibuf2->rect,
+				    (unsigned char*) out->rect);
+	}
+}
+/* **********************************************************************
+   TRANSFORM
+   ********************************************************************** */
+static void init_transform_effect(Sequence *seq)
+{
+	TransformVars *scale;
+
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = MEM_callocN(sizeof(struct TransformVars), "transformvars");
+
+	scale = (TransformVars *)seq->effectdata;
+	scale->ScalexIni = 1;
+	scale->ScaleyIni = 1;
+	scale->ScalexFin = 1;
+	scale->ScaleyFin = 1;
+	
+	scale->xIni=0;
+	scale->xFin=0;
+	scale->yIni=0;
+	scale->yFin=0;
+	
+	scale->rotIni=0;
+	scale->rotFin=0;
+	
+	scale->interpolation=1;
+	scale->percent=1;
+}
+
+static int num_inputs_transform()
+{
+	return 1;
+}
+
+static void free_transform_effect(Sequence *seq)
+{
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = 0;
+}
+
+static void copy_transform_effect(Sequence *dst, Sequence *src)
+{
+	dst->effectdata = MEM_dupallocN(src->effectdata);
+}
+
+static void do_transform(Sequence * seq,float facf0, int x, int y, 
+			  struct ImBuf *ibuf1,struct ImBuf *out)
+{
+	int xo, yo, xi, yi;
+	float xs,ys,factxScale,factyScale,tx,ty,rad,s,c,xaux,yaux,factRot,px,py;
+	TransformVars *scale;
+	
+	scale = (TransformVars *)seq->effectdata;
+	xo = x;
+	yo = y;
+
+	//factor scale
+	factxScale = scale->ScalexIni + (scale->ScalexFin - scale->ScalexIni) * facf0;
+	factyScale = scale->ScaleyIni + (scale->ScaleyFin - scale->ScaleyIni) * facf0;
+
+	//Factor translate
+	if(!scale->percent){
+		tx = scale->xIni+(xo / 2.0f) + (scale->xFin-(xo / 2.0f) - scale->xIni+(xo / 2.0f)) * facf0;
+		ty = scale->yIni+(yo / 2.0f) + (scale->yFin-(yo / 2.0f) - scale->yIni+(yo / 2.0f)) * facf0;
+	}else{
+		tx = xo*(scale->xIni/100.0f)+(xo / 2.0f) + (xo*(scale->xFin/100.0f)-(xo / 2.0f) - xo*(scale->xIni/100.0f)+(xo / 2.0f)) * facf0;
+		ty = yo*(scale->yIni/100.0f)+(yo / 2.0f) + (yo*(scale->yFin/100.0f)-(yo / 2.0f) - yo*(scale->yIni/100.0f)+(yo / 2.0f)) * facf0;
+	}
+
+	//factor Rotate
+	factRot = scale->rotIni + (scale->rotFin - scale->rotIni) * facf0;
+	rad = (M_PI * factRot) / 180.0f;
+	s= sin(rad);
+	c= cos(rad);
+
+	for (yi = 0; yi < yo; yi++) {
+		for (xi = 0; xi < xo; xi++) {
+			//tranlate point
+			px = xi-tx;
+			py = yi-ty;
+
+			//rotate point with center ref
+			xaux = c*px + py*s ;
+			yaux = -s*px + c*py;
+
+			//scale point with center ref
+			xs = xaux / factxScale;
+			ys = yaux / factyScale;
+
+			//undo reference center point 
+			xs += (xo / 2.0f);
+			ys += (yo / 2.0f);
+
+			//interpolate
+			switch(scale->interpolation) {
+			case 0:
+				neareast_interpolation(ibuf1,out, xs,ys,xi,yi);
+				break;
+			case 1:
+				bilinear_interpolation(ibuf1,out, xs,ys,xi,yi);
+				break;
+			case 2:
+				bicubic_interpolation(ibuf1,out, xs,ys,xi,yi);
+				break;
+			}
+		}
+	}	
+
+}
+static void do_transform_effect(Sequence * seq,int cfra,
+			   float facf0, float facf1, int x, int y, 
+			   struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			   struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	do_transform(seq, facf0, x, y, ibuf1, out);
+}
+
+
+/* **********************************************************************
+   GLOW
+   ********************************************************************** */
+
+static void RVBlurBitmap2_byte ( unsigned char* map, int width,int height,
+				 float blur,
+				 int quality)
+/*	MUUUCCH better than the previous blur. */
+/*	We do the blurring in two passes which is a whole lot faster. */
+/*	I changed the math arount to implement an actual Gaussian */
+/*	distribution. */
+/* */
+/*	Watch out though, it tends to misbehaven with large blur values on */
+/*	a small bitmap.  Avoid avoid avoid. */
+/*=============================== */
+{
+	unsigned char*	temp=NULL,*swap;
+	float	*filter=NULL;
+	int	x,y,i,fx,fy;
+	int	index, ix, halfWidth;
+	float	fval, k, curColor[3], curColor2[3], weight=0;
+
+	/*	If we're not really blurring, bail out */
+	if (blur<=0)
+		return;
+
+	/*	Allocate memory for the tempmap and the blur filter matrix */
+	temp= MEM_mallocN( (width*height*4), "blurbitmaptemp");
+	if (!temp)
+		return;
+
+	/*	Allocate memory for the filter elements */
+	halfWidth = ((quality+1)*blur);
+	filter = (float *)MEM_mallocN(sizeof(float)*halfWidth*2, "blurbitmapfilter");
+	if (!filter){
+		MEM_freeN (temp);
+		return;
+	}
+
+	/*	Apparently we're calculating a bell curve */
+	/*	based on the standard deviation (or radius) */
+	/*	This code is based on an example */
+	/*	posted to comp.graphics.algorithms by */
+	/*	Blancmange (bmange@airdmhor.gen.nz) */
+
+	k = -1.0/(2.0*3.14159*blur*blur);
+	fval=0;
+	for (ix = 0;ix< halfWidth;ix++){
+		weight = (float)exp(k*(ix*ix));
+		filter[halfWidth - ix] = weight;
+		filter[halfWidth + ix] = weight;
+	}
+	filter[0] = weight;
+
+	/*	Normalize the array */
+	fval=0;
+	for (ix = 0;ix< halfWidth*2;ix++)
+		fval+=filter[ix];
+
+	for (ix = 0;ix< halfWidth*2;ix++)
+		filter[ix]/=fval;
+
+	/*	Blur the rows */
+	for (y=0;y<height;y++){
+		/*	Do the left & right strips */
+		for (x=0;x<halfWidth;x++){
+			index=(x+y*width)*4;
+			fx=0;
+			curColor[0]=curColor[1]=curColor[2]=0;
+			curColor2[0]=curColor2[1]=curColor2[2]=0;
+
+			for (i=x-halfWidth;i<x+halfWidth;i++){
+				if ((i>=0)&&(i<width)){
+					curColor[0]+=map[(i+y*width)*4+GlowR]*filter[fx];
+					curColor[1]+=map[(i+y*width)*4+GlowG]*filter[fx];
+					curColor[2]+=map[(i+y*width)*4+GlowB]*filter[fx];
+
+					curColor2[0]+=map[(width-1-i+y*width)*4+GlowR] *
+						filter[fx];
+					curColor2[1]+=map[(width-1-i+y*width)*4+GlowG] *
+						filter[fx];
+					curColor2[2]+=map[(width-1-i+y*width)*4+GlowB] *
+						filter[fx];
+				}
+				fx++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+
+			temp[((width-1-x+y*width)*4)+GlowR]=curColor2[0];
+			temp[((width-1-x+y*width)*4)+GlowG]=curColor2[1];
+			temp[((width-1-x+y*width)*4)+GlowB]=curColor2[2];
+
+		}
+		/*	Do the main body */
+		for (x=halfWidth;x<width-halfWidth;x++){
+			index=(x+y*width)*4;
+			fx=0;
+			curColor[0]=curColor[1]=curColor[2]=0;
+			for (i=x-halfWidth;i<x+halfWidth;i++){
+				curColor[0]+=map[(i+y*width)*4+GlowR]*filter[fx];
+				curColor[1]+=map[(i+y*width)*4+GlowG]*filter[fx];
+				curColor[2]+=map[(i+y*width)*4+GlowB]*filter[fx];
+				fx++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+		}
+	}
+
+	/*	Swap buffers */
+	swap=temp;temp=map;map=swap;
+
+
+	/*	Blur the columns */
+	for (x=0;x<width;x++){
+		/*	Do the top & bottom strips */
+		for (y=0;y<halfWidth;y++){
+			index=(x+y*width)*4;
+			fy=0;
+			curColor[0]=curColor[1]=curColor[2]=0;
+			curColor2[0]=curColor2[1]=curColor2[2]=0;
+			for (i=y-halfWidth;i<y+halfWidth;i++){
+				if ((i>=0)&&(i<height)){
+					/*	Bottom */
+					curColor[0]+=map[(x+i*width)*4+GlowR]*filter[fy];
+					curColor[1]+=map[(x+i*width)*4+GlowG]*filter[fy];
+					curColor[2]+=map[(x+i*width)*4+GlowB]*filter[fy];
+
+					/*	Top */
+					curColor2[0]+=map[(x+(height-1-i)*width) *
+						4+GlowR]*filter[fy];
+					curColor2[1]+=map[(x+(height-1-i)*width) *
+						4+GlowG]*filter[fy];
+					curColor2[2]+=map[(x+(height-1-i)*width) *
+						4+GlowB]*filter[fy];
+				}
+				fy++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+			temp[((x+(height-1-y)*width)*4)+GlowR]=curColor2[0];
+			temp[((x+(height-1-y)*width)*4)+GlowG]=curColor2[1];
+			temp[((x+(height-1-y)*width)*4)+GlowB]=curColor2[2];
+		}
+		/*	Do the main body */
+		for (y=halfWidth;y<height-halfWidth;y++){
+			index=(x+y*width)*4;
+			fy=0;
+			curColor[0]=curColor[1]=curColor[2]=0;
+			for (i=y-halfWidth;i<y+halfWidth;i++){
+				curColor[0]+=map[(x+i*width)*4+GlowR]*filter[fy];
+				curColor[1]+=map[(x+i*width)*4+GlowG]*filter[fy];
+				curColor[2]+=map[(x+i*width)*4+GlowB]*filter[fy];
+				fy++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+		}
+	}
+
+
+	/*	Swap buffers */
+	swap=temp;temp=map;map=swap;
+
+	/*	Tidy up	 */
+	MEM_freeN (filter);
+	MEM_freeN (temp);
+}
+
+static void RVBlurBitmap2_float ( float* map, int width,int height,
+				  float blur,
+				  int quality)
+/*	MUUUCCH better than the previous blur. */
+/*	We do the blurring in two passes which is a whole lot faster. */
+/*	I changed the math arount to implement an actual Gaussian */
+/*	distribution. */
+/* */
+/*	Watch out though, it tends to misbehaven with large blur values on */
+/*	a small bitmap.  Avoid avoid avoid. */
+/*=============================== */
+{
+	float*	temp=NULL,*swap;
+	float	*filter=NULL;
+	int	x,y,i,fx,fy;
+	int	index, ix, halfWidth;
+	float	fval, k, curColor[3], curColor2[3], weight=0;
+
+	/*	If we're not really blurring, bail out */
+	if (blur<=0)
+		return;
+
+	/*	Allocate memory for the tempmap and the blur filter matrix */
+	temp= MEM_mallocN( (width*height*4*sizeof(float)), "blurbitmaptemp");
+	if (!temp)
+		return;
+
+	/*	Allocate memory for the filter elements */
+	halfWidth = ((quality+1)*blur);
+	filter = (float *)MEM_mallocN(sizeof(float)*halfWidth*2, "blurbitmapfilter");
+	if (!filter){
+		MEM_freeN (temp);
+		return;
+	}
+
+	/*	Apparently we're calculating a bell curve */
+	/*	based on the standard deviation (or radius) */
+	/*	This code is based on an example */
+	/*	posted to comp.graphics.algorithms by */
+	/*	Blancmange (bmange@airdmhor.gen.nz) */
+
+	k = -1.0/(2.0*3.14159*blur*blur);
+	fval=0;
+	for (ix = 0;ix< halfWidth;ix++){
+		weight = (float)exp(k*(ix*ix));
+		filter[halfWidth - ix] = weight;
+		filter[halfWidth + ix] = weight;
+	}
+	filter[0] = weight;
+
+	/*	Normalize the array */
+	fval=0;
+	for (ix = 0;ix< halfWidth*2;ix++)
+		fval+=filter[ix];
+
+	for (ix = 0;ix< halfWidth*2;ix++)
+		filter[ix]/=fval;
+
+	/*	Blur the rows */
+	for (y=0;y<height;y++){
+		/*	Do the left & right strips */
+		for (x=0;x<halfWidth;x++){
+			index=(x+y*width)*4;
+			fx=0;
+			curColor[0]=curColor[1]=curColor[2]=0.0f;
+			curColor2[0]=curColor2[1]=curColor2[2]=0.0f;
+
+			for (i=x-halfWidth;i<x+halfWidth;i++){
+				if ((i>=0)&&(i<width)){
+					curColor[0]+=map[(i+y*width)*4+GlowR]*filter[fx];
+					curColor[1]+=map[(i+y*width)*4+GlowG]*filter[fx];
+					curColor[2]+=map[(i+y*width)*4+GlowB]*filter[fx];
+
+					curColor2[0]+=map[(width-1-i+y*width)*4+GlowR] *
+						filter[fx];
+					curColor2[1]+=map[(width-1-i+y*width)*4+GlowG] *
+						filter[fx];
+					curColor2[2]+=map[(width-1-i+y*width)*4+GlowB] *
+						filter[fx];
+				}
+				fx++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+
+			temp[((width-1-x+y*width)*4)+GlowR]=curColor2[0];
+			temp[((width-1-x+y*width)*4)+GlowG]=curColor2[1];
+			temp[((width-1-x+y*width)*4)+GlowB]=curColor2[2];
+
+		}
+		/*	Do the main body */
+		for (x=halfWidth;x<width-halfWidth;x++){
+			index=(x+y*width)*4;
+			fx=0;
+			curColor[0]=curColor[1]=curColor[2]=0;
+			for (i=x-halfWidth;i<x+halfWidth;i++){
+				curColor[0]+=map[(i+y*width)*4+GlowR]*filter[fx];
+				curColor[1]+=map[(i+y*width)*4+GlowG]*filter[fx];
+				curColor[2]+=map[(i+y*width)*4+GlowB]*filter[fx];
+				fx++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+		}
+	}
+
+	/*	Swap buffers */
+	swap=temp;temp=map;map=swap;
+
+
+	/*	Blur the columns */
+	for (x=0;x<width;x++){
+		/*	Do the top & bottom strips */
+		for (y=0;y<halfWidth;y++){
+			index=(x+y*width)*4;
+			fy=0;
+			curColor[0]=curColor[1]=curColor[2]=0;
+			curColor2[0]=curColor2[1]=curColor2[2]=0;
+			for (i=y-halfWidth;i<y+halfWidth;i++){
+				if ((i>=0)&&(i<height)){
+					/*	Bottom */
+					curColor[0]+=map[(x+i*width)*4+GlowR]*filter[fy];
+					curColor[1]+=map[(x+i*width)*4+GlowG]*filter[fy];
+					curColor[2]+=map[(x+i*width)*4+GlowB]*filter[fy];
+
+					/*	Top */
+					curColor2[0]+=map[(x+(height-1-i)*width) *
+						4+GlowR]*filter[fy];
+					curColor2[1]+=map[(x+(height-1-i)*width) *
+						4+GlowG]*filter[fy];
+					curColor2[2]+=map[(x+(height-1-i)*width) *
+						4+GlowB]*filter[fy];
+				}
+				fy++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+			temp[((x+(height-1-y)*width)*4)+GlowR]=curColor2[0];
+			temp[((x+(height-1-y)*width)*4)+GlowG]=curColor2[1];
+			temp[((x+(height-1-y)*width)*4)+GlowB]=curColor2[2];
+		}
+		/*	Do the main body */
+		for (y=halfWidth;y<height-halfWidth;y++){
+			index=(x+y*width)*4;
+			fy=0;
+			curColor[0]=curColor[1]=curColor[2]=0;
+			for (i=y-halfWidth;i<y+halfWidth;i++){
+				curColor[0]+=map[(x+i*width)*4+GlowR]*filter[fy];
+				curColor[1]+=map[(x+i*width)*4+GlowG]*filter[fy];
+				curColor[2]+=map[(x+i*width)*4+GlowB]*filter[fy];
+				fy++;
+			}
+			temp[index+GlowR]=curColor[0];
+			temp[index+GlowG]=curColor[1];
+			temp[index+GlowB]=curColor[2];
+		}
+	}
+
+
+	/*	Swap buffers */
+	swap=temp;temp=map;map=swap;
+
+	/*	Tidy up	 */
+	MEM_freeN (filter);
+	MEM_freeN (temp);
+}
+
+
+/*	Adds two bitmaps and puts the results into a third map. */
+/*	C must have been previously allocated but it may be A or B. */
+/*	We clamp values to 255 to prevent weirdness */
+/*=============================== */
+static void RVAddBitmaps_byte (unsigned char* a, unsigned char* b, unsigned char* c, int width, int height)
+{
+	int	x,y,index;
+
+	for (y=0;y<height;y++){
+		for (x=0;x<width;x++){
+			index=(x+y*width)*4;
+			c[index+GlowR]=MIN2(255,a[index+GlowR]+b[index+GlowR]);
+			c[index+GlowG]=MIN2(255,a[index+GlowG]+b[index+GlowG]);
+			c[index+GlowB]=MIN2(255,a[index+GlowB]+b[index+GlowB]);
+			c[index+GlowA]=MIN2(255,a[index+GlowA]+b[index+GlowA]);
+		}
+	}
+}
+
+static void RVAddBitmaps_float (float* a, float* b, float* c, 
+				int width, int height)
+{
+	int	x,y,index;
+
+	for (y=0;y<height;y++){
+		for (x=0;x<width;x++){
+			index=(x+y*width)*4;
+			c[index+GlowR]=MIN2(1.0,a[index+GlowR]+b[index+GlowR]);
+			c[index+GlowG]=MIN2(1.0,a[index+GlowG]+b[index+GlowG]);
+			c[index+GlowB]=MIN2(1.0,a[index+GlowB]+b[index+GlowB]);
+			c[index+GlowA]=MIN2(1.0,a[index+GlowA]+b[index+GlowA]);
+		}
+	}
+}
+
+/*	For each pixel whose total luminance exceeds the threshold, */
+/*	Multiply it's value by BOOST and add it to the output map */
+static void RVIsolateHighlights_byte (unsigned char* in, unsigned char* out, 
+				      int width, int height, int threshold, 
+				      float boost, float clamp)
+{
+	int x,y,index;
+	int	intensity;
+
+
+	for(y=0;y< height;y++) {
+		for (x=0;x< width;x++) {
+	 		index= (x+y*width)*4;
+
+			/*	Isolate the intensity */
+			intensity=(in[index+GlowR]+in[index+GlowG]+in[index+GlowB]-threshold);
+			if (intensity>0){
+				out[index+GlowR]=MIN2(255*clamp, (in[index+GlowR]*boost*intensity)/255);
+				out[index+GlowG]=MIN2(255*clamp, (in[index+GlowG]*boost*intensity)/255);
+				out[index+GlowB]=MIN2(255*clamp, (in[index+GlowB]*boost*intensity)/255);
+				out[index+GlowA]=MIN2(255*clamp, (in[index+GlowA]*boost*intensity)/255);
+			} else{
+				out[index+GlowR]=0;
+				out[index+GlowG]=0;
+				out[index+GlowB]=0;
+				out[index+GlowA]=0;
+			}
+		}
+	}
+}
+
+static void RVIsolateHighlights_float (float* in, float* out, 
+				      int width, int height, float threshold, 
+				      float boost, float clamp)
+{
+	int x,y,index;
+	float	intensity;
+
+
+	for(y=0;y< height;y++) {
+		for (x=0;x< width;x++) {
+	 		index= (x+y*width)*4;
+
+			/*	Isolate the intensity */
+			intensity=(in[index+GlowR]+in[index+GlowG]+in[index+GlowB]-threshold);
+			if (intensity>0){
+				out[index+GlowR]=MIN2(clamp, (in[index+GlowR]*boost*intensity));
+				out[index+GlowG]=MIN2(clamp, (in[index+GlowG]*boost*intensity));
+				out[index+GlowB]=MIN2(clamp, (in[index+GlowB]*boost*intensity));
+				out[index+GlowA]=MIN2(clamp, (in[index+GlowA]*boost*intensity));
+			} else{
+				out[index+GlowR]=0;
+				out[index+GlowG]=0;
+				out[index+GlowB]=0;
+				out[index+GlowA]=0;
+			}
+		}
+	}
+}
+
+static void init_glow_effect(Sequence *seq)
+{
+	GlowVars *glow;
+
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = MEM_callocN(sizeof(struct GlowVars), "glowvars");
+
+	glow = (GlowVars *)seq->effectdata;
+	glow->fMini = 0.25;
+	glow->fClamp = 1.0;
+	glow->fBoost = 0.5;
+	glow->dDist = 3.0;
+	glow->dQuality = 3;
+	glow->bNoComp = 0;
+}
+
+static int num_inputs_glow()
+{
+	return 1;
+}
+
+static void free_glow_effect(Sequence *seq)
+{
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = 0;
+}
+
+static void copy_glow_effect(Sequence *dst, Sequence *src)
+{
+	dst->effectdata = MEM_dupallocN(src->effectdata);
+}
+
+//void do_glow_effect(Cast *cast, float facf0, float facf1, int xo, int yo, ImBuf *ibuf1, ImBuf *ibuf2, ImBuf *outbuf, ImBuf *use)
+static void do_glow_effect_byte(Sequence *seq, float facf0, float facf1, 
+				int x, int y, char *rect1, 
+				char *rect2, char *out)
+{
+	unsigned char *outbuf=(unsigned char *)out;
+	unsigned char *inbuf=(unsigned char *)rect1;
+	GlowVars *glow = (GlowVars *)seq->effectdata;
+	int size= 100; // renderdata XXX
+	
+	RVIsolateHighlights_byte(inbuf, outbuf , x, y, glow->fMini*765, glow->fBoost * facf0, glow->fClamp);
+	RVBlurBitmap2_byte (outbuf, x, y, glow->dDist * (size / 100.0f),glow->dQuality);
+	if (!glow->bNoComp)
+		RVAddBitmaps_byte (inbuf , outbuf, outbuf, x, y);
+}
+
+static void do_glow_effect_float(Sequence *seq, float facf0, float facf1, 
+				 int x, int y, 
+				 float *rect1, float *rect2, float *out)
+{
+	float *outbuf = out;
+	float *inbuf = rect1;
+	GlowVars *glow = (GlowVars *)seq->effectdata;
+	int size= 100; // renderdata XXX
+
+	RVIsolateHighlights_float(inbuf, outbuf , x, y, glow->fMini*3.0f, glow->fBoost * facf0, glow->fClamp);
+	RVBlurBitmap2_float (outbuf, x, y, glow->dDist * (size / 100.0f),glow->dQuality);
+	if (!glow->bNoComp)
+		RVAddBitmaps_float (inbuf , outbuf, outbuf, x, y);
+}
+
+static void do_glow_effect(Sequence * seq,int cfra,
+			   float facf0, float facf1, int x, int y, 
+			   struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			   struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	if (out->rect_float) {
+		do_glow_effect_float(seq,
+				     facf0, facf1, x, y,
+				     ibuf1->rect_float, ibuf2->rect_float,
+				     out->rect_float);
+	} else {
+		do_glow_effect_byte(seq,
+				    facf0, facf1, x, y,
+				    (char*) ibuf1->rect, (char*) ibuf2->rect,
+				    (char*) out->rect);
+	}
+}
+
+/* **********************************************************************
+   SOLID COLOR
+   ********************************************************************** */
+
+static void init_solid_color(Sequence *seq)
+{
+	SolidColorVars *cv;
+	
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = MEM_callocN(sizeof(struct SolidColorVars), "solidcolor");
+	
+	cv = (SolidColorVars *)seq->effectdata;
+	cv->col[0] = cv->col[1] = cv->col[2] = 0.5;
+}
+
+static int num_inputs_color()
+{
+	return 0;
+}
+
+static void free_solid_color(Sequence *seq)
+{
+	if(seq->effectdata)MEM_freeN(seq->effectdata);
+	seq->effectdata = 0;
+}
+
+static void copy_solid_color(Sequence *dst, Sequence *src)
+{
+	dst->effectdata = MEM_dupallocN(src->effectdata);
+}
+
+static int early_out_color(struct Sequence *seq,
+			   float facf0, float facf1)
+{
+	return -1;
+}
+
+static void do_solid_color(Sequence * seq,int cfra,
+			   float facf0, float facf1, int x, int y, 
+			   struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			   struct ImBuf *ibuf3, struct ImBuf *out)
+{
+	SolidColorVars *cv = (SolidColorVars *)seq->effectdata;
+
+	unsigned char *rect;
+	float *rect_float;
+
+	if (out->rect) {
+		unsigned char col0[3];
+		unsigned char col1[3];
+
+		col0[0] = facf0 * cv->col[0] * 255;
+		col0[1] = facf0 * cv->col[1] * 255;
+		col0[2] = facf0 * cv->col[2] * 255;
+
+		col1[0] = facf1 * cv->col[0] * 255;
+		col1[1] = facf1 * cv->col[1] * 255;
+		col1[2] = facf1 * cv->col[2] * 255;
+
+		rect = (unsigned char *)out->rect;
+		
+		for(y=0; y<out->y; y++) {	
+			for(x=0; x<out->x; x++, rect+=4) {
+				rect[0]= col0[0];
+				rect[1]= col0[1];
+				rect[2]= col0[2];
+				rect[3]= 255;
+			}
+			y++;
+			if (y<out->y) {
+				for(x=0; x<out->x; x++, rect+=4) {
+					rect[0]= col1[0];
+					rect[1]= col1[1];
+					rect[2]= col1[2];
+					rect[3]= 255;
+				}	
+			}
+		}
+
+	} else if (out->rect_float) {
+		float col0[3];
+		float col1[3];
+
+		col0[0] = facf0 * cv->col[0];
+		col0[1] = facf0 * cv->col[1];
+		col0[2] = facf0 * cv->col[2];
+
+		col1[0] = facf1 * cv->col[0];
+		col1[1] = facf1 * cv->col[1];
+		col1[2] = facf1 * cv->col[2];
+
+		rect_float = out->rect_float;
+		
+		for(y=0; y<out->y; y++) {	
+			for(x=0; x<out->x; x++, rect_float+=4) {
+				rect_float[0]= col0[0];
+				rect_float[1]= col0[1];
+				rect_float[2]= col0[2];
+				rect_float[3]= 1.0;
+			}
+			y++;
+			if (y<out->y) {
+				for(x=0; x<out->x; x++, rect_float+=4) {
+					rect_float[0]= col1[0];
+					rect_float[1]= col1[1];
+					rect_float[2]= col1[2];
+					rect_float[3]= 1.0;
+				}
+			}
+		}
+	}
+}
+
+/* **********************************************************************
+   SPEED
+   ********************************************************************** */
+static void init_speed_effect(Sequence *seq)
+{
+	SpeedControlVars * v;
+
+	if(seq->effectdata) MEM_freeN(seq->effectdata);
+	seq->effectdata = MEM_callocN(sizeof(struct SpeedControlVars), 
+				      "speedcontrolvars");
+
+	v = (SpeedControlVars *)seq->effectdata;
+	v->globalSpeed = 1.0;
+	v->frameMap = 0;
+	v->flags = SEQ_SPEED_COMPRESS_IPO_Y;
+	v->length = 0;
+}
+
+static void load_speed_effect(Sequence * seq)
+{
+	SpeedControlVars * v = (SpeedControlVars *)seq->effectdata;
+
+	v->frameMap = 0;
+	v->length = 0;
+}
+
+static int num_inputs_speed()
+{
+	return 1;
+}
+
+static void free_speed_effect(Sequence *seq)
+{
+	SpeedControlVars * v = (SpeedControlVars *)seq->effectdata;
+	if(v->frameMap) MEM_freeN(v->frameMap);
+	if(seq->effectdata) MEM_freeN(seq->effectdata);
+	seq->effectdata = 0;
+}
+
+static void copy_speed_effect(Sequence *dst, Sequence *src)
+{
+	SpeedControlVars * v;
+	dst->effectdata = MEM_dupallocN(src->effectdata);
+	v = (SpeedControlVars *)dst->effectdata;
+	v->frameMap = 0;
+	v->length = 0;
+}
+
+static int early_out_speed(struct Sequence *seq,
+			  float facf0, float facf1)
+{
+	return 1;
+}
+
+static void store_icu_yrange_speed(struct Sequence * seq,
+				   short adrcode, float * ymin, float * ymax)
+{
+	SpeedControlVars * v = (SpeedControlVars *)seq->effectdata;
+
+	/* if not already done, load / initialize data */
+	get_sequence_effect(seq);
+
+	if ((v->flags & SEQ_SPEED_INTEGRATE) != 0) {
+		*ymin = -100.0;
+		*ymax = 100.0;
+	} else {
+		if (v->flags & SEQ_SPEED_COMPRESS_IPO_Y) {
+			*ymin = 0.0;
+			*ymax = 1.0;
+		} else {
+			*ymin = 0.0;
+			*ymax = seq->len;
+		}
+	}	
+}
+
+void sequence_effect_speed_rebuild_map(Scene *scene, Sequence * seq, int force)
+{
+	float facf0 = seq->facf0;
+	float ctime, div;
+	int cfra;
+	float fallback_fac;
+	SpeedControlVars * v = (SpeedControlVars *)seq->effectdata;
+
+	/* if not already done, load / initialize data */
+	get_sequence_effect(seq);
+
+	if (!(force || seq->len != v->length || !v->frameMap)) {
+		return;
+	}
+
+	if (!v->frameMap || v->length != seq->len) {
+		if (v->frameMap) MEM_freeN(v->frameMap);
+
+		v->length = seq->len;
+
+		v->frameMap = MEM_callocN(sizeof(float) * v->length, 
+					  "speedcontrol frameMap");
+	}
+
+	fallback_fac = 1.0;
+	
+	/* if there is no IPO, try to make retiming easy by stretching the
+	   strip */
+
+	if (!seq->ipo && seq->seq1 && seq->seq1->enddisp != seq->seq1->start
+	    && seq->seq1->len != 0) {
+		fallback_fac = (float) seq->seq1->len / 
+			(float) (seq->seq1->enddisp - seq->seq1->start);
+		/* FIXME: this strip stretching gets screwed by stripdata
+		   handling one layer up.
+		   
+		   So it currently works by enlarging, never by shrinking!
+
+		   (IPOs still work, if used correctly)
+		*/
+		if (fallback_fac > 1.0) {
+			fallback_fac = 1.0;
+		}
+	}
+
+	if ((v->flags & SEQ_SPEED_INTEGRATE) != 0) {
+		float cursor = 0;
+
+		v->frameMap[0] = 0;
+		v->lastValidFrame = 0;
+
+		for (cfra = 1; cfra < v->length; cfra++) {
+			if(seq->ipo) {
+				if((seq->flag & SEQ_IPO_FRAME_LOCKED) != 0) {
+					ctime = frame_to_float(scene, seq->startdisp + cfra);
+					div = 1.0;
+				} else {
+					ctime= frame_to_float(scene, cfra);
+					div= v->length / 100.0f;
+					if(div==0.0) return;
+				}
+		
+				calc_ipo(seq->ipo, ctime/div);
+				execute_ipo((ID *)seq, seq->ipo);
+			} else {
+				seq->facf0 = fallback_fac;
+			}
+			seq->facf0 *= v->globalSpeed;
+
+			cursor += seq->facf0;
+
+			if (cursor >= v->length) {
+				v->frameMap[cfra] = v->length - 1;
+			} else {
+				v->frameMap[cfra] = cursor;
+				v->lastValidFrame = cfra;
+			}
+		}
+	} else {
+		v->lastValidFrame = 0;
+		for (cfra = 0; cfra < v->length; cfra++) {
+			if(seq->ipo) {
+				if((seq->flag & SEQ_IPO_FRAME_LOCKED) != 0) {
+					ctime = frame_to_float(scene, seq->startdisp + cfra);
+					div = 1.0;
+				} else {
+					ctime= frame_to_float(scene, cfra);
+					div= v->length / 100.0f;
+					if(div==0.0) return;
+				}
+		
+				calc_ipo(seq->ipo, ctime/div);
+				execute_ipo((ID *)seq, seq->ipo);
+			}
+			
+			if (v->flags & SEQ_SPEED_COMPRESS_IPO_Y) {
+				seq->facf0 *= v->length;
+			}
+			if (!seq->ipo) {
+				seq->facf0 = (float) cfra * fallback_fac;
+			}
+			seq->facf0 *= v->globalSpeed;
+			if (seq->facf0 >= v->length) {
+				seq->facf0 = v->length - 1;
+			} else {
+				v->lastValidFrame = cfra;
+			}
+			v->frameMap[cfra] = seq->facf0;
+		}
+	}
+	seq->facf0 = facf0;
+}
+
+/*
+  simply reuse do_cross_effect for blending...
+
+static void do_speed_effect(Sequence * seq,int cfra,
+			   float facf0, float facf1, int x, int y, 
+			   struct ImBuf *ibuf1, struct ImBuf *ibuf2, 
+			   struct ImBuf *ibuf3, struct ImBuf *out)
+{
+
+}
+*/
+
+
+/* **********************************************************************
+   sequence effect factory
+   ********************************************************************** */
+
+
+static void init_noop(struct Sequence *seq)
+{
+
+}
+
+static void load_noop(struct Sequence *seq)
+{
+
+}
+
+static void init_plugin_noop(struct Sequence *seq, const char * fname)
+{
+
+}
+
+static void free_noop(struct Sequence *seq)
+{
+
+}
+
+static int num_inputs_default()
+{
+	return 2;
+}
+
+static int early_out_noop(struct Sequence *seq,
+			  float facf0, float facf1)
+{
+	return 0;
+}
+
+static int early_out_fade(struct Sequence *seq,
+			  float facf0, float facf1)
+{
+	if (facf0 == 0.0 && facf1 == 0.0) {
+		return 1;
+	} else if (facf0 == 1.0 && facf1 == 1.0) {
+		return 2;
+	}
+	return 0;
+}
+
+static int early_out_mul_input2(struct Sequence *seq,
+				float facf0, float facf1)
+{
+	if (facf0 == 0.0 && facf1 == 0.0) {
+		return 1;
+	}
+	return 0;
+}
+
+static void store_icu_yrange_noop(struct Sequence * seq,
+				  short adrcode, float * ymin, float * ymax)
+{
+	/* defaults are fine */
+}
+
+static void get_default_fac_noop(struct Sequence *seq, int cfra,
+				 float * facf0, float * facf1)
+{
+	*facf0 = *facf1 = 1.0;
+}
+
+static void get_default_fac_fade(struct Sequence *seq, int cfra,
+				 float * facf0, float * facf1)
+{
+	*facf0 = (float)(cfra - seq->startdisp);
+	*facf1 = (float)(*facf0 + 0.5);
+	*facf0 /= seq->len;
+	*facf1 /= seq->len;
+}
+
+static void do_overdrop_effect(struct Sequence * seq, int cfra,
+			       float fac, float facf, 
+			       int x, int y, struct ImBuf * ibuf1, 
+			       struct ImBuf * ibuf2, 
+			       struct ImBuf * ibuf3, 
+			       struct ImBuf * out)
+{
+	do_drop_effect(seq, cfra, fac, facf, x, y, 
+		       ibuf1, ibuf2, ibuf3, out);
+	do_alphaover_effect(seq, cfra, fac, facf, x, y, 
+			    ibuf1, ibuf2, ibuf3, out);
+}
+
+static struct SeqEffectHandle get_sequence_effect_impl(int seq_type)
+{
+	struct SeqEffectHandle rval;
+	int sequence_type = seq_type;
+
+	rval.init = init_noop;
+	rval.init_plugin = init_plugin_noop;
+	rval.num_inputs = num_inputs_default;
+	rval.load = load_noop;
+	rval.free = free_noop;
+	rval.early_out = early_out_noop;
+	rval.get_default_fac = get_default_fac_noop;
+	rval.store_icu_yrange = store_icu_yrange_noop;
+	rval.execute = NULL;
+	rval.copy = NULL;
+
+	switch (sequence_type) {
+	case SEQ_CROSS:
+		rval.execute = do_cross_effect;
+		rval.early_out = early_out_fade;
+		rval.get_default_fac = get_default_fac_fade;
+		break;
+	case SEQ_GAMCROSS:
+		rval.init = init_gammacross;
+		rval.load = load_gammacross;
+		rval.free = free_gammacross;
+		rval.early_out = early_out_fade;
+		rval.get_default_fac = get_default_fac_fade;
+		rval.execute = do_gammacross_effect;
+		break;
+	case SEQ_ADD:
+		rval.execute = do_add_effect;
+		rval.early_out = early_out_mul_input2;
+		break;
+	case SEQ_SUB:
+		rval.execute = do_sub_effect;
+		rval.early_out = early_out_mul_input2;
+		break;
+	case SEQ_MUL:
+		rval.execute = do_mul_effect;
+		rval.early_out = early_out_mul_input2;
+		break;
+	case SEQ_ALPHAOVER:
+		rval.init = init_alpha_over_or_under;
+		rval.execute = do_alphaover_effect;
+		break;
+	case SEQ_OVERDROP:
+		rval.execute = do_overdrop_effect;
+		break;
+	case SEQ_ALPHAUNDER:
+		rval.init = init_alpha_over_or_under;
+		rval.execute = do_alphaunder_effect;
+		break;
+	case SEQ_WIPE:
+		rval.init = init_wipe_effect;
+		rval.num_inputs = num_inputs_wipe;
+		rval.free = free_wipe_effect;
+		rval.copy = copy_wipe_effect;
+		rval.early_out = early_out_fade;
+		rval.get_default_fac = get_default_fac_fade;
+		rval.execute = do_wipe_effect;
+		break;
+	case SEQ_GLOW:
+		rval.init = init_glow_effect;
+		rval.num_inputs = num_inputs_glow;
+		rval.free = free_glow_effect;
+		rval.copy = copy_glow_effect;
+		rval.execute = do_glow_effect;
+		break;
+	case SEQ_TRANSFORM:
+		rval.init = init_transform_effect;
+		rval.num_inputs = num_inputs_transform;
+		rval.free = free_transform_effect;
+		rval.copy = copy_transform_effect;
+		rval.execute = do_transform_effect;
+		break;
+	case SEQ_SPEED:
+		rval.init = init_speed_effect;
+		rval.num_inputs = num_inputs_speed;
+		rval.load = load_speed_effect;
+		rval.free = free_speed_effect;
+		rval.copy = copy_speed_effect;
+		rval.execute = do_cross_effect;
+		rval.early_out = early_out_speed;
+		rval.store_icu_yrange = store_icu_yrange_speed;
+		break;
+	case SEQ_COLOR:
+		rval.init = init_solid_color;
+		rval.num_inputs = num_inputs_color;
+		rval.early_out = early_out_color;
+		rval.free = free_solid_color;
+		rval.copy = copy_solid_color;
+		rval.execute = do_solid_color;
+		break;
+	case SEQ_PLUGIN:
+		rval.init_plugin = init_plugin;
+		rval.num_inputs = num_inputs_plugin;
+		rval.load = load_plugin;
+		rval.free = free_plugin;
+		rval.copy = copy_plugin;
+		rval.execute = do_plugin_effect;
+		rval.early_out = do_plugin_early_out;
+		rval.get_default_fac = get_default_fac_fade;
+		break;
+	}
+
+	return rval;
+}
+
+
+struct SeqEffectHandle get_sequence_effect(Sequence * seq)
+{
+	struct SeqEffectHandle rval;
+
+	memset(&rval, 0, sizeof(struct SeqEffectHandle));
+
+	if (seq->type & SEQ_EFFECT) {
+		rval = get_sequence_effect_impl(seq->type);
+		if ((seq->flag & SEQ_EFFECT_NOT_LOADED) != 0) {
+			rval.load(seq);
+			seq->flag &= ~SEQ_EFFECT_NOT_LOADED;
+		}
+	}
+
+	return rval;
+}
+
+struct SeqEffectHandle get_sequence_blend(Sequence * seq)
+{
+	struct SeqEffectHandle rval;
+
+	memset(&rval, 0, sizeof(struct SeqEffectHandle));
+
+	if (seq->blend_mode != 0) {
+		rval = get_sequence_effect_impl(seq->blend_mode);
+		if ((seq->flag & SEQ_EFFECT_NOT_LOADED) != 0) {
+			rval.load(seq);
+			seq->flag &= ~SEQ_EFFECT_NOT_LOADED;
+		}
+	}
+
+	return rval;
+}
+
+int get_sequence_effect_num_inputs(int seq_type)
+{
+	struct SeqEffectHandle rval = get_sequence_effect_impl(seq_type);
+
+	int cnt = rval.num_inputs();
+	if (rval.execute) {
+		return cnt;
+	}
+	return 0;
+}