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blender-archive/source/blender/blenkernel/intern/seqmodifier.c
Campbell Barton a30c9f710a Partial revert '#if 0' cleanup 
Partially revert 41216d5ad4

Some of this code had comments to be left as is for readability,
or comment the code should be kept.
Other functions were only for debugging.
2018-10-19 09:18:22 +11:00

1035 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) 2012 Blender Foundation.
* All rights reserved.
*
* Contributor(s): Blender Foundation,
* Sergey Sharybin
*
* ***** END GPL LICENSE BLOCK *****
*/
/** \file blender/blenkernel/intern/seqmodifier.c
* \ingroup bke
*/
#include <stddef.h>
#include <string.h>
#include "MEM_guardedalloc.h"
#include "BLI_listbase.h"
#include "BLI_string.h"
#include "BLI_string_utils.h"
#include "BLI_utildefines.h"
#include "BLI_math.h"
#include "BLT_translation.h"
#include "DNA_sequence_types.h"
#include "DNA_scene_types.h"
#include "BKE_colortools.h"
#include "BKE_sequencer.h"
#include "IMB_imbuf.h"
#include "IMB_imbuf_types.h"
#include "IMB_colormanagement.h"
static SequenceModifierTypeInfo *modifiersTypes[NUM_SEQUENCE_MODIFIER_TYPES];
static bool modifierTypesInit = false;
/*********************** Modifiers *************************/
typedef void (*modifier_apply_threaded_cb) (int width, int height, unsigned char *rect, float *rect_float,
unsigned char *mask_rect, float *mask_rect_float, void *data_v);
typedef struct ModifierInitData {
ImBuf *ibuf;
ImBuf *mask;
void *user_data;
modifier_apply_threaded_cb apply_callback;
} ModifierInitData;
typedef struct ModifierThread {
int width, height;
unsigned char *rect, *mask_rect;
float *rect_float, *mask_rect_float;
void *user_data;
modifier_apply_threaded_cb apply_callback;
} ModifierThread;
static ImBuf *modifier_mask_get(SequenceModifierData *smd, const SeqRenderData *context, int cfra, int fra_offset, bool make_float)
{
return BKE_sequencer_render_mask_input(context, smd->mask_input_type, smd->mask_sequence, smd->mask_id, cfra, fra_offset, make_float);
}
static void modifier_init_handle(void *handle_v, int start_line, int tot_line, void *init_data_v)
{
ModifierThread *handle = (ModifierThread *) handle_v;
ModifierInitData *init_data = (ModifierInitData *) init_data_v;
ImBuf *ibuf = init_data->ibuf;
ImBuf *mask = init_data->mask;
int offset = 4 * start_line * ibuf->x;
memset(handle, 0, sizeof(ModifierThread));
handle->width = ibuf->x;
handle->height = tot_line;
handle->apply_callback = init_data->apply_callback;
handle->user_data = init_data->user_data;
if (ibuf->rect)
handle->rect = (unsigned char *) ibuf->rect + offset;
if (ibuf->rect_float)
handle->rect_float = ibuf->rect_float + offset;
if (mask) {
if (mask->rect)
handle->mask_rect = (unsigned char *) mask->rect + offset;
if (mask->rect_float)
handle->mask_rect_float = mask->rect_float + offset;
}
else {
handle->mask_rect = NULL;
handle->mask_rect_float = NULL;
}
}
static void *modifier_do_thread(void *thread_data_v)
{
ModifierThread *td = (ModifierThread *) thread_data_v;
td->apply_callback(td->width, td->height, td->rect, td->rect_float, td->mask_rect, td->mask_rect_float, td->user_data);
return NULL;
}
static void modifier_apply_threaded(ImBuf *ibuf, ImBuf *mask, modifier_apply_threaded_cb apply_callback, void *user_data)
{
ModifierInitData init_data;
init_data.ibuf = ibuf;
init_data.mask = mask;
init_data.user_data = user_data;
init_data.apply_callback = apply_callback;
IMB_processor_apply_threaded(ibuf->y, sizeof(ModifierThread), &init_data,
modifier_init_handle, modifier_do_thread);
}
/* **** Color Balance Modifier **** */
static void colorBalance_init_data(SequenceModifierData *smd)
{
ColorBalanceModifierData *cbmd = (ColorBalanceModifierData *) smd;
int c;
cbmd->color_multiply = 1.0f;
for (c = 0; c < 3; c++) {
cbmd->color_balance.lift[c] = 1.0f;
cbmd->color_balance.gamma[c] = 1.0f;
cbmd->color_balance.gain[c] = 1.0f;
}
}
static void colorBalance_apply(SequenceModifierData *smd, ImBuf *ibuf, ImBuf *mask)
{
ColorBalanceModifierData *cbmd = (ColorBalanceModifierData *) smd;
BKE_sequencer_color_balance_apply(&cbmd->color_balance, ibuf, cbmd->color_multiply, false, mask);
}
static SequenceModifierTypeInfo seqModifier_ColorBalance = {
CTX_N_(BLT_I18NCONTEXT_ID_SEQUENCE, "Color Balance"), /* name */
"ColorBalanceModifierData", /* struct_name */
sizeof(ColorBalanceModifierData), /* struct_size */
colorBalance_init_data, /* init_data */
NULL, /* free_data */
NULL, /* copy_data */
colorBalance_apply /* apply */
};
/* **** White Balance Modifier **** */
static void whiteBalance_init_data(SequenceModifierData *smd)
{
WhiteBalanceModifierData *cbmd = (WhiteBalanceModifierData *) smd;
copy_v3_fl(cbmd->white_value, 1.0f);
}
typedef struct WhiteBalanceThreadData {
float white[3];
} WhiteBalanceThreadData;
static void whiteBalance_apply_threaded(int width, int height, unsigned char *rect, float *rect_float,
unsigned char *mask_rect, float *mask_rect_float, void *data_v)
{
int x, y;
float multiplier[3];
WhiteBalanceThreadData *data = (WhiteBalanceThreadData *) data_v;
multiplier[0] = (data->white[0] != 0.0f) ? 1.0f / data->white[0] : FLT_MAX;
multiplier[1] = (data->white[1] != 0.0f) ? 1.0f / data->white[1] : FLT_MAX;
multiplier[2] = (data->white[2] != 0.0f) ? 1.0f / data->white[2] : FLT_MAX;
for (y = 0; y < height; y++) {
for (x = 0; x < width; x++) {
int pixel_index = (y * width + x) * 4;
float rgba[4], result[4], mask[3] = {1.0f, 1.0f, 1.0f};
if (rect_float) {
copy_v3_v3(rgba, rect_float + pixel_index);
}
else {
straight_uchar_to_premul_float(rgba, rect + pixel_index);
}
copy_v4_v4(result, rgba);
#if 0
mul_v3_v3(result, multiplier);
#else
/* similar to division without the clipping */
for (int i = 0; i < 3; i++) {
result[i] = 1.0f - powf(1.0f - rgba[i], multiplier[i]);
}
#endif
if (mask_rect_float) {
copy_v3_v3(mask, mask_rect_float + pixel_index);
}
else if (mask_rect) {
rgb_uchar_to_float(mask, mask_rect + pixel_index);
}
result[0] = rgba[0] * (1.0f - mask[0]) + result[0] * mask[0];
result[1] = rgba[1] * (1.0f - mask[1]) + result[1] * mask[1];
result[2] = rgba[2] * (1.0f - mask[2]) + result[2] * mask[2];
if (rect_float) {
copy_v3_v3(rect_float + pixel_index, result);
}
else {
premul_float_to_straight_uchar(rect + pixel_index, result);
}
}
}
}
static void whiteBalance_apply(SequenceModifierData *smd, ImBuf *ibuf, ImBuf *mask)
{
WhiteBalanceThreadData data;
WhiteBalanceModifierData *wbmd = (WhiteBalanceModifierData *) smd;
copy_v3_v3(data.white, wbmd->white_value);
modifier_apply_threaded(ibuf, mask, whiteBalance_apply_threaded, &data);
}
static SequenceModifierTypeInfo seqModifier_WhiteBalance = {
CTX_N_(BLT_I18NCONTEXT_ID_SEQUENCE, "White Balance"), /* name */
"WhiteBalanceModifierData", /* struct_name */
sizeof(WhiteBalanceModifierData), /* struct_size */
whiteBalance_init_data, /* init_data */
NULL, /* free_data */
NULL, /* copy_data */
whiteBalance_apply /* apply */
};
/* **** Curves Modifier **** */
static void curves_init_data(SequenceModifierData *smd)
{
CurvesModifierData *cmd = (CurvesModifierData *) smd;
curvemapping_set_defaults(&cmd->curve_mapping, 4, 0.0f, 0.0f, 1.0f, 1.0f);
}
static void curves_free_data(SequenceModifierData *smd)
{
CurvesModifierData *cmd = (CurvesModifierData *) smd;
curvemapping_free_data(&cmd->curve_mapping);
}
static void curves_copy_data(SequenceModifierData *target, SequenceModifierData *smd)
{
CurvesModifierData *cmd = (CurvesModifierData *) smd;
CurvesModifierData *cmd_target = (CurvesModifierData *) target;
curvemapping_copy_data(&cmd_target->curve_mapping, &cmd->curve_mapping);
}
static void curves_apply_threaded(int width, int height, unsigned char *rect, float *rect_float,
unsigned char *mask_rect, float *mask_rect_float, void *data_v)
{
CurveMapping *curve_mapping = (CurveMapping *) data_v;
int x, y;
for (y = 0; y < height; y++) {
for (x = 0; x < width; x++) {
int pixel_index = (y * width + x) * 4;
if (rect_float) {
float *pixel = rect_float + pixel_index;
float result[3];
curvemapping_evaluate_premulRGBF(curve_mapping, result, pixel);
if (mask_rect_float) {
const float *m = mask_rect_float + pixel_index;
pixel[0] = pixel[0] * (1.0f - m[0]) + result[0] * m[0];
pixel[1] = pixel[1] * (1.0f - m[1]) + result[1] * m[1];
pixel[2] = pixel[2] * (1.0f - m[2]) + result[2] * m[2];
}
else {
pixel[0] = result[0];
pixel[1] = result[1];
pixel[2] = result[2];
}
}
if (rect) {
unsigned char *pixel = rect + pixel_index;
float result[3], tempc[4];
straight_uchar_to_premul_float(tempc, pixel);
curvemapping_evaluate_premulRGBF(curve_mapping, result, tempc);
if (mask_rect) {
float t[3];
rgb_uchar_to_float(t, mask_rect + pixel_index);
tempc[0] = tempc[0] * (1.0f - t[0]) + result[0] * t[0];
tempc[1] = tempc[1] * (1.0f - t[1]) + result[1] * t[1];
tempc[2] = tempc[2] * (1.0f - t[2]) + result[2] * t[2];
}
else {
tempc[0] = result[0];
tempc[1] = result[1];
tempc[2] = result[2];
}
premul_float_to_straight_uchar(pixel, tempc);
}
}
}
}
static void curves_apply(struct SequenceModifierData *smd, ImBuf *ibuf, ImBuf *mask)
{
CurvesModifierData *cmd = (CurvesModifierData *) smd;
float black[3] = {0.0f, 0.0f, 0.0f};
float white[3] = {1.0f, 1.0f, 1.0f};
curvemapping_initialize(&cmd->curve_mapping);
curvemapping_premultiply(&cmd->curve_mapping, 0);
curvemapping_set_black_white(&cmd->curve_mapping, black, white);
modifier_apply_threaded(ibuf, mask, curves_apply_threaded, &cmd->curve_mapping);
curvemapping_premultiply(&cmd->curve_mapping, 1);
}
static SequenceModifierTypeInfo seqModifier_Curves = {
CTX_N_(BLT_I18NCONTEXT_ID_SEQUENCE, "Curves"), /* name */
"CurvesModifierData", /* struct_name */
sizeof(CurvesModifierData), /* struct_size */
curves_init_data, /* init_data */
curves_free_data, /* free_data */
curves_copy_data, /* copy_data */
curves_apply /* apply */
};
/* **** Hue Correct Modifier **** */
static void hue_correct_init_data(SequenceModifierData *smd)
{
HueCorrectModifierData *hcmd = (HueCorrectModifierData *) smd;
int c;
curvemapping_set_defaults(&hcmd->curve_mapping, 1, 0.0f, 0.0f, 1.0f, 1.0f);
hcmd->curve_mapping.preset = CURVE_PRESET_MID9;
for (c = 0; c < 3; c++) {
CurveMap *cuma = &hcmd->curve_mapping.cm[c];
curvemap_reset(cuma, &hcmd->curve_mapping.clipr, hcmd->curve_mapping.preset, CURVEMAP_SLOPE_POSITIVE);
}
/* default to showing Saturation */
hcmd->curve_mapping.cur = 1;
}
static void hue_correct_free_data(SequenceModifierData *smd)
{
HueCorrectModifierData *hcmd = (HueCorrectModifierData *) smd;
curvemapping_free_data(&hcmd->curve_mapping);
}
static void hue_correct_copy_data(SequenceModifierData *target, SequenceModifierData *smd)
{
HueCorrectModifierData *hcmd = (HueCorrectModifierData *) smd;
HueCorrectModifierData *hcmd_target = (HueCorrectModifierData *) target;
curvemapping_copy_data(&hcmd_target->curve_mapping, &hcmd->curve_mapping);
}
static void hue_correct_apply_threaded(int width, int height, unsigned char *rect, float *rect_float,
unsigned char *mask_rect, float *mask_rect_float, void *data_v)
{
CurveMapping *curve_mapping = (CurveMapping *) data_v;
int x, y;
for (y = 0; y < height; y++) {
for (x = 0; x < width; x++) {
int pixel_index = (y * width + x) * 4;
float pixel[3], result[3], mask[3] = {1.0f, 1.0f, 1.0f};
float hsv[3], f;
if (rect_float)
copy_v3_v3(pixel, rect_float + pixel_index);
else
rgb_uchar_to_float(pixel, rect + pixel_index);
rgb_to_hsv(pixel[0], pixel[1], pixel[2], hsv, hsv + 1, hsv + 2);
/* adjust hue, scaling returned default 0.5 up to 1 */
f = curvemapping_evaluateF(curve_mapping, 0, hsv[0]);
hsv[0] += f - 0.5f;
/* adjust saturation, scaling returned default 0.5 up to 1 */
f = curvemapping_evaluateF(curve_mapping, 1, hsv[0]);
hsv[1] *= (f * 2.0f);
/* adjust value, scaling returned default 0.5 up to 1 */
f = curvemapping_evaluateF(curve_mapping, 2, hsv[0]);
hsv[2] *= (f * 2.f);
hsv[0] = hsv[0] - floorf(hsv[0]); /* mod 1.0 */
CLAMP(hsv[1], 0.0f, 1.0f);
/* convert back to rgb */
hsv_to_rgb(hsv[0], hsv[1], hsv[2], result, result + 1, result + 2);
if (mask_rect_float)
copy_v3_v3(mask, mask_rect_float + pixel_index);
else if (mask_rect)
rgb_uchar_to_float(mask, mask_rect + pixel_index);
result[0] = pixel[0] * (1.0f - mask[0]) + result[0] * mask[0];
result[1] = pixel[1] * (1.0f - mask[1]) + result[1] * mask[1];
result[2] = pixel[2] * (1.0f - mask[2]) + result[2] * mask[2];
if (rect_float)
copy_v3_v3(rect_float + pixel_index, result);
else
rgb_float_to_uchar(rect + pixel_index, result);
}
}
}
static void hue_correct_apply(struct SequenceModifierData *smd, ImBuf *ibuf, ImBuf *mask)
{
HueCorrectModifierData *hcmd = (HueCorrectModifierData *) smd;
curvemapping_initialize(&hcmd->curve_mapping);
modifier_apply_threaded(ibuf, mask, hue_correct_apply_threaded, &hcmd->curve_mapping);
}
static SequenceModifierTypeInfo seqModifier_HueCorrect = {
CTX_N_(BLT_I18NCONTEXT_ID_SEQUENCE, "Hue Correct"), /* name */
"HueCorrectModifierData", /* struct_name */
sizeof(HueCorrectModifierData), /* struct_size */
hue_correct_init_data, /* init_data */
hue_correct_free_data, /* free_data */
hue_correct_copy_data, /* copy_data */
hue_correct_apply /* apply */
};
/* **** Bright/Contrast Modifier **** */
typedef struct BrightContrastThreadData {
float bright;
float contrast;
} BrightContrastThreadData;
static void brightcontrast_apply_threaded(int width, int height, unsigned char *rect, float *rect_float,
unsigned char *mask_rect, float *mask_rect_float, void *data_v)
{
BrightContrastThreadData *data = (BrightContrastThreadData *) data_v;
int x, y;
float i;
int c;
float a, b, v;
float brightness = data->bright / 100.0f;
float contrast = data->contrast;
float delta = contrast / 200.0f;
a = 1.0f - delta * 2.0f;
/*
* The algorithm is by Werner D. Streidt
* (http://visca.com/ffactory/archives/5-99/msg00021.html)
* Extracted of OpenCV demhist.c
*/
if (contrast > 0) {
a = 1.0f / a;
b = a * (brightness - delta);
}
else {
delta *= -1;
b = a * (brightness + delta);
}
for (y = 0; y < height; y++) {
for (x = 0; x < width; x++) {
int pixel_index = (y * width + x) * 4;
if (rect) {
unsigned char *pixel = rect + pixel_index;
for (c = 0; c < 3; c++) {
i = (float) pixel[c] / 255.0f;
v = a * i + b;
if (mask_rect) {
unsigned char *m = mask_rect + pixel_index;
float t = (float) m[c] / 255.0f;
v = (float) pixel[c] / 255.0f * (1.0f - t) + v * t;
}
pixel[c] = unit_float_to_uchar_clamp(v);
}
}
else if (rect_float) {
float *pixel = rect_float + pixel_index;
for (c = 0; c < 3; c++) {
i = pixel[c];
v = a * i + b;
if (mask_rect_float) {
const float *m = mask_rect_float + pixel_index;
pixel[c] = pixel[c] * (1.0f - m[c]) + v * m[c];
}
else
pixel[c] = v;
}
}
}
}
}
static void brightcontrast_apply(struct SequenceModifierData *smd, ImBuf *ibuf, ImBuf *mask)
{
BrightContrastModifierData *bcmd = (BrightContrastModifierData *) smd;
BrightContrastThreadData data;
data.bright = bcmd->bright;
data.contrast = bcmd->contrast;
modifier_apply_threaded(ibuf, mask, brightcontrast_apply_threaded, &data);
}
static SequenceModifierTypeInfo seqModifier_BrightContrast = {
CTX_N_(BLT_I18NCONTEXT_ID_SEQUENCE, "Bright/Contrast"), /* name */
"BrightContrastModifierData", /* struct_name */
sizeof(BrightContrastModifierData), /* struct_size */
NULL, /* init_data */
NULL, /* free_data */
NULL, /* copy_data */
brightcontrast_apply /* apply */
};
/* **** Mask Modifier **** */
static void maskmodifier_apply_threaded(int width, int height, unsigned char *rect, float *rect_float,
unsigned char *mask_rect, float *mask_rect_float, void *UNUSED(data_v))
{
int x, y;
if (rect && !mask_rect)
return;
if (rect_float && !mask_rect_float)
return;
for (y = 0; y < height; y++) {
for (x = 0; x < width; x++) {
int pixel_index = (y * width + x) * 4;
if (rect) {
unsigned char *pixel = rect + pixel_index;
unsigned char *mask_pixel = mask_rect + pixel_index;
unsigned char mask = min_iii(mask_pixel[0], mask_pixel[1], mask_pixel[2]);
/* byte buffer is straight, so only affect on alpha itself,
* this is the only way to alpha-over byte strip after
* applying mask modifier.
*/
pixel[3] = (float)(pixel[3] * mask) / 255.0f;
}
else if (rect_float) {
int c;
float *pixel = rect_float + pixel_index;
const float *mask_pixel = mask_rect_float + pixel_index;
float mask = min_fff(mask_pixel[0], mask_pixel[1], mask_pixel[2]);
/* float buffers are premultiplied, so need to premul color
* as well to make it easy to alpha-over masted strip.
*/
for (c = 0; c < 4; c++)
pixel[c] = pixel[c] * mask;
}
}
}
}
static void maskmodifier_apply(struct SequenceModifierData *UNUSED(smd), ImBuf *ibuf, ImBuf *mask)
{
// SequencerMaskModifierData *bcmd = (SequencerMaskModifierData *)smd;
modifier_apply_threaded(ibuf, mask, maskmodifier_apply_threaded, NULL);
}
static SequenceModifierTypeInfo seqModifier_Mask = {
CTX_N_(BLT_I18NCONTEXT_ID_SEQUENCE, "Mask"), /* name */
"SequencerMaskModifierData", /* struct_name */
sizeof(SequencerMaskModifierData), /* struct_size */
NULL, /* init_data */
NULL, /* free_data */
NULL, /* copy_data */
maskmodifier_apply /* apply */
};
/* **** Tonemap Modifier **** */
typedef struct AvgLogLum {
SequencerTonemapModifierData *tmmd;
struct ColorSpace *colorspace;
float al;
float auto_key;
float lav;
float cav[4];
float igm;
} AvgLogLum;
static void tonemapmodifier_init_data(SequenceModifierData *smd)
{
SequencerTonemapModifierData *tmmd = (SequencerTonemapModifierData *) smd;
/* Same as tonemap compositor node. */
tmmd->type = SEQ_TONEMAP_RD_PHOTORECEPTOR;
tmmd->key = 0.18f;
tmmd->offset = 1.0f;
tmmd->gamma = 1.0f;
tmmd->intensity = 0.0f;
tmmd->contrast = 0.0f;
tmmd->adaptation = 1.0f;
tmmd->correction = 0.0f;
}
static void tonemapmodifier_apply_threaded_simple(int width,
int height,
unsigned char *rect,
float *rect_float,
unsigned char *mask_rect,
float *mask_rect_float,
void *data_v)
{
AvgLogLum *avg = (AvgLogLum *)data_v;
for (int y = 0; y < height; y++) {
for (int x = 0; x < width; x++) {
int pixel_index = (y * width + x) * 4;
float input[4], output[4], mask[3] = {1.0f, 1.0f, 1.0f};
/* Get input value. */
if (rect_float) {
copy_v4_v4(input, &rect_float[pixel_index]);
}
else {
straight_uchar_to_premul_float(input, &rect[pixel_index]);
}
IMB_colormanagement_colorspace_to_scene_linear_v3(input, avg->colorspace);
copy_v4_v4(output, input);
/* Get mask value. */
if (mask_rect_float) {
copy_v3_v3(mask, mask_rect_float + pixel_index);
}
else if (mask_rect) {
rgb_uchar_to_float(mask, mask_rect + pixel_index);
}
/* Apply correction. */
mul_v3_fl(output, avg->al);
float dr = output[0] + avg->tmmd->offset;
float dg = output[1] + avg->tmmd->offset;
float db = output[2] + avg->tmmd->offset;
output[0] /= ((dr == 0.0f) ? 1.0f : dr);
output[1] /= ((dg == 0.0f) ? 1.0f : dg);
output[2] /= ((db == 0.0f) ? 1.0f : db);
const float igm = avg->igm;
if (igm != 0.0f) {
output[0] = powf(max_ff(output[0], 0.0f), igm);
output[1] = powf(max_ff(output[1], 0.0f), igm);
output[2] = powf(max_ff(output[2], 0.0f), igm);
}
/* Apply mask. */
output[0] = input[0] * (1.0f - mask[0]) + output[0] * mask[0];
output[1] = input[1] * (1.0f - mask[1]) + output[1] * mask[1];
output[2] = input[2] * (1.0f - mask[2]) + output[2] * mask[2];
/* Copy result back. */
IMB_colormanagement_scene_linear_to_colorspace_v3(output, avg->colorspace);
if (rect_float) {
copy_v4_v4(&rect_float[pixel_index], output);
}
else {
premul_float_to_straight_uchar(&rect[pixel_index], output);
}
}
}
}
static void tonemapmodifier_apply_threaded_photoreceptor(int width,
int height,
unsigned char *rect,
float *rect_float,
unsigned char *mask_rect,
float *mask_rect_float,
void *data_v)
{
AvgLogLum *avg = (AvgLogLum *)data_v;
const float f = expf(-avg->tmmd->intensity);
const float m = (avg->tmmd->contrast > 0.0f) ? avg->tmmd->contrast : (0.3f + 0.7f * powf(avg->auto_key, 1.4f));
const float ic = 1.0f - avg->tmmd->correction, ia = 1.0f - avg->tmmd->adaptation;
for (int y = 0; y < height; y++) {
for (int x = 0; x < width; x++) {
int pixel_index = (y * width + x) * 4;
float input[4], output[4], mask[3] = {1.0f, 1.0f, 1.0f};
/* Get input value. */
if (rect_float) {
copy_v4_v4(input, &rect_float[pixel_index]);
}
else {
straight_uchar_to_premul_float(input, &rect[pixel_index]);
}
IMB_colormanagement_colorspace_to_scene_linear_v3(input, avg->colorspace);
copy_v4_v4(output, input);
/* Get mask value. */
if (mask_rect_float) {
copy_v3_v3(mask, mask_rect_float + pixel_index);
}
else if (mask_rect) {
rgb_uchar_to_float(mask, mask_rect + pixel_index);
}
/* Apply correction. */
const float L = IMB_colormanagement_get_luminance(output);
float I_l = output[0] + ic * (L - output[0]);
float I_g = avg->cav[0] + ic * (avg->lav - avg->cav[0]);
float I_a = I_l + ia * (I_g - I_l);
output[0] /= (output[0] + powf(f * I_a, m));
I_l = output[1] + ic * (L - output[1]);
I_g = avg->cav[1] + ic * (avg->lav - avg->cav[1]);
I_a = I_l + ia * (I_g - I_l);
output[1] /= (output[1] + powf(f * I_a, m));
I_l = output[2] + ic * (L - output[2]);
I_g = avg->cav[2] + ic * (avg->lav - avg->cav[2]);
I_a = I_l + ia * (I_g - I_l);
output[2] /= (output[2] + powf(f * I_a, m));
/* Apply mask. */
output[0] = input[0] * (1.0f - mask[0]) + output[0] * mask[0];
output[1] = input[1] * (1.0f - mask[1]) + output[1] * mask[1];
output[2] = input[2] * (1.0f - mask[2]) + output[2] * mask[2];
/* Copy result back. */
IMB_colormanagement_scene_linear_to_colorspace_v3(output, avg->colorspace);
if (rect_float) {
copy_v4_v4(&rect_float[pixel_index], output);
}
else {
premul_float_to_straight_uchar(&rect[pixel_index], output);
}
}
}
}
static void tonemapmodifier_apply(struct SequenceModifierData *smd,
ImBuf *ibuf,
ImBuf *mask)
{
SequencerTonemapModifierData *tmmd = (SequencerTonemapModifierData *) smd;
AvgLogLum data;
data.tmmd = tmmd;
data.colorspace = (ibuf->rect_float != NULL)
? ibuf->float_colorspace
: ibuf->rect_colorspace;
float lsum = 0.0f;
int p = ibuf->x * ibuf->y;
float *fp = ibuf->rect_float;
unsigned char *cp = (unsigned char *)ibuf->rect;
float avl, maxl = -FLT_MAX, minl = FLT_MAX;
const float sc = 1.0f / p;
float Lav = 0.f;
float cav[4] = {0.0f, 0.0f, 0.0f, 0.0f};
while (p--) {
float pixel[4];
if (fp != NULL) {
copy_v4_v4(pixel, fp);
}
else {
straight_uchar_to_premul_float(pixel, cp);
}
IMB_colormanagement_colorspace_to_scene_linear_v3(pixel, data.colorspace);
float L = IMB_colormanagement_get_luminance(pixel);
Lav += L;
add_v3_v3(cav, pixel);
lsum += logf(max_ff(L, 0.0f) + 1e-5f);
maxl = (L > maxl) ? L : maxl;
minl = (L < minl) ? L : minl;
if (fp != NULL) {
fp += 4;
}
else {
cp += 4;
}
}
data.lav = Lav * sc;
mul_v3_v3fl(data.cav, cav, sc);
maxl = logf(maxl + 1e-5f);
minl = logf(minl + 1e-5f);
avl = lsum * sc;
data.auto_key = (maxl > minl) ? ((maxl - avl) / (maxl - minl)) : 1.0f;
float al = expf(avl);
data.al = (al == 0.0f) ? 0.0f : (tmmd->key / al);
data.igm = (tmmd->gamma == 0.0f) ? 1.0f : (1.0f / tmmd->gamma);
if (tmmd->type == SEQ_TONEMAP_RD_PHOTORECEPTOR) {
modifier_apply_threaded(ibuf,
mask,
tonemapmodifier_apply_threaded_photoreceptor,
&data);
}
else /* if (tmmd->type == SEQ_TONEMAP_RD_SIMPLE) */ {
modifier_apply_threaded(ibuf,
mask,
tonemapmodifier_apply_threaded_simple,
&data);
}
}
static SequenceModifierTypeInfo seqModifier_Tonemap = {
CTX_N_(BLT_I18NCONTEXT_ID_SEQUENCE, "Tonemap"), /* name */
"SequencerTonemapModifierData", /* struct_name */
sizeof(SequencerTonemapModifierData), /* struct_size */
tonemapmodifier_init_data, /* init_data */
NULL, /* free_data */
NULL, /* copy_data */
tonemapmodifier_apply /* apply */
};
/*********************** Modifier functions *************************/
static void sequence_modifier_type_info_init(void)
{
#define INIT_TYPE(typeName) (modifiersTypes[seqModifierType_##typeName] = &seqModifier_##typeName)
INIT_TYPE(ColorBalance);
INIT_TYPE(Curves);
INIT_TYPE(HueCorrect);
INIT_TYPE(BrightContrast);
INIT_TYPE(Mask);
INIT_TYPE(WhiteBalance);
INIT_TYPE(Tonemap);
#undef INIT_TYPE
}
const SequenceModifierTypeInfo *BKE_sequence_modifier_type_info_get(int type)
{
if (!modifierTypesInit) {
sequence_modifier_type_info_init();
modifierTypesInit = true;
}
return modifiersTypes[type];
}
SequenceModifierData *BKE_sequence_modifier_new(Sequence *seq, const char *name, int type)
{
SequenceModifierData *smd;
const SequenceModifierTypeInfo *smti = BKE_sequence_modifier_type_info_get(type);
smd = MEM_callocN(smti->struct_size, "sequence modifier");
smd->type = type;
smd->flag |= SEQUENCE_MODIFIER_EXPANDED;
if (!name || !name[0])
BLI_strncpy(smd->name, smti->name, sizeof(smd->name));
else
BLI_strncpy(smd->name, name, sizeof(smd->name));
BLI_addtail(&seq->modifiers, smd);
BKE_sequence_modifier_unique_name(seq, smd);
if (smti->init_data)
smti->init_data(smd);
return smd;
}
bool BKE_sequence_modifier_remove(Sequence *seq, SequenceModifierData *smd)
{
if (BLI_findindex(&seq->modifiers, smd) == -1)
return false;
BLI_remlink(&seq->modifiers, smd);
BKE_sequence_modifier_free(smd);
return true;
}
void BKE_sequence_modifier_clear(Sequence *seq)
{
SequenceModifierData *smd, *smd_next;
for (smd = seq->modifiers.first; smd; smd = smd_next) {
smd_next = smd->next;
BKE_sequence_modifier_free(smd);
}
BLI_listbase_clear(&seq->modifiers);
}
void BKE_sequence_modifier_free(SequenceModifierData *smd)
{
const SequenceModifierTypeInfo *smti = BKE_sequence_modifier_type_info_get(smd->type);
if (smti && smti->free_data) {
smti->free_data(smd);
}
MEM_freeN(smd);
}
void BKE_sequence_modifier_unique_name(Sequence *seq, SequenceModifierData *smd)
{
const SequenceModifierTypeInfo *smti = BKE_sequence_modifier_type_info_get(smd->type);
BLI_uniquename(&seq->modifiers, smd, CTX_DATA_(BLT_I18NCONTEXT_ID_SEQUENCE, smti->name), '.',
offsetof(SequenceModifierData, name), sizeof(smd->name));
}
SequenceModifierData *BKE_sequence_modifier_find_by_name(Sequence *seq, const char *name)
{
return BLI_findstring(&(seq->modifiers), name, offsetof(SequenceModifierData, name));
}
ImBuf *BKE_sequence_modifier_apply_stack(const SeqRenderData *context, Sequence *seq, ImBuf *ibuf, int cfra)
{
SequenceModifierData *smd;
ImBuf *processed_ibuf = ibuf;
if (seq->modifiers.first && (seq->flag & SEQ_USE_LINEAR_MODIFIERS)) {
processed_ibuf = IMB_dupImBuf(ibuf);
BKE_sequencer_imbuf_from_sequencer_space(context->scene, processed_ibuf);
}
for (smd = seq->modifiers.first; smd; smd = smd->next) {
const SequenceModifierTypeInfo *smti = BKE_sequence_modifier_type_info_get(smd->type);
/* could happen if modifier is being removed or not exists in current version of blender */
if (!smti)
continue;
/* modifier is muted, do nothing */
if (smd->flag & SEQUENCE_MODIFIER_MUTE)
continue;
if (smti->apply) {
int frame_offset;
if (smd->mask_time == SEQUENCE_MASK_TIME_RELATIVE) {
frame_offset = seq->start;
}
else /*if (smd->mask_time == SEQUENCE_MASK_TIME_ABSOLUTE)*/ {
frame_offset = 0;
}
ImBuf *mask = modifier_mask_get(smd,
context,
cfra,
frame_offset,
ibuf->rect_float != NULL);
if (processed_ibuf == ibuf)
processed_ibuf = IMB_dupImBuf(ibuf);
smti->apply(smd, processed_ibuf, mask);
if (mask)
IMB_freeImBuf(mask);
}
}
if (seq->modifiers.first && (seq->flag & SEQ_USE_LINEAR_MODIFIERS)) {
BKE_sequencer_imbuf_to_sequencer_space(context->scene, processed_ibuf, false);
}
return processed_ibuf;
}
void BKE_sequence_modifier_list_copy(Sequence *seqn, Sequence *seq)
{
SequenceModifierData *smd;
for (smd = seq->modifiers.first; smd; smd = smd->next) {
SequenceModifierData *smdn;
const SequenceModifierTypeInfo *smti = BKE_sequence_modifier_type_info_get(smd->type);
smdn = MEM_dupallocN(smd);
if (smti && smti->copy_data)
smti->copy_data(smdn, smd);
smdn->next = smdn->prev = NULL;
BLI_addtail(&seqn->modifiers, smdn);
}
}
int BKE_sequence_supports_modifiers(Sequence *seq)
{
return !ELEM(seq->type, SEQ_TYPE_SOUND_RAM, SEQ_TYPE_SOUND_HD);
}
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