obs-StreamFX/source/filters/filter-dynamic-mask.cpp
2023-03-28 12:52:22 +02:00

486 lines
17 KiB
C++

/*
* Modern effects for a modern Streamer
* Copyright (C) 2019 Michael Fabian Dirks
*
* 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
*/
#include "filter-dynamic-mask.hpp"
#include "strings.hpp"
#include <sstream>
#include <stdexcept>
#include <vector>
#include "obs/gs/gs-helper.hpp"
// Filter to allow dynamic masking
// Allow any channel to affect any other channel
//
// Red/Green/Blue/Alpha Mask Input
// - Red Mask Output
// - Blue Mask Output
// - Green Mask Output
// - Alpha Mask Output
#define ST "Filter.DynamicMask"
#define ST_INPUT "Filter.DynamicMask.Input"
#define ST_CHANNEL "Filter.DynamicMask.Channel"
#define ST_CHANNEL_VALUE "Filter.DynamicMask.Channel.Value"
#define ST_CHANNEL_MULTIPLIER "Filter.DynamicMask.Channel.Multiplier"
#define ST_CHANNEL_INPUT "Filter.DynamicMask.Channel.Input"
using namespace streamfx::filter::dynamic_mask;
static std::pair<channel, const char*> channel_translations[] = {
{channel::Red, S_CHANNEL_RED},
{channel::Green, S_CHANNEL_GREEN},
{channel::Blue, S_CHANNEL_BLUE},
{channel::Alpha, S_CHANNEL_ALPHA},
};
dynamic_mask_instance::dynamic_mask_instance(obs_data_t* settings, obs_source_t* self)
: obs::source_instance(settings, self), _translation_map(), _effect(), _have_filter_texture(false), _filter_rt(),
_filter_texture(), _have_input_texture(false), _input(), _input_capture(), _input_texture(),
_have_final_texture(false), _final_rt(), _final_texture(), _channels(), _precalc()
{
_filter_rt = std::make_shared<gs::rendertarget>(GS_RGBA, GS_ZS_NONE);
_final_rt = std::make_shared<gs::rendertarget>(GS_RGBA, GS_ZS_NONE);
{
char* file = obs_module_file("effects/channel-mask.effect");
try {
_effect = gs::effect::create(file);
} catch (const std::exception& ex) {
DLOG_ERROR("Loading channel mask effect failed with error(s):\n%s", ex.what());
}
assert(_effect != nullptr);
bfree(file);
}
update(settings);
}
dynamic_mask_instance::~dynamic_mask_instance() {}
void dynamic_mask_instance::load(obs_data_t* settings)
{
update(settings);
}
void dynamic_mask_instance::migrate(obs_data_t* data, uint64_t version) {}
void dynamic_mask_instance::update(obs_data_t* settings)
{
// Update source.
try {
_input = std::make_shared<obs::deprecated_source>(obs_data_get_string(settings, ST_INPUT));
_input_capture = std::make_shared<gfx::source_texture>(_input, _self);
_input->events.rename += std::bind(&dynamic_mask_instance::input_renamed, this, std::placeholders::_1,
std::placeholders::_2, std::placeholders::_3);
} catch (...) {
_input.reset();
_input_capture.reset();
_input_texture.reset();
}
// Update data store
for (auto kv1 : channel_translations) {
auto found = _channels.find(kv1.first);
if (found == _channels.end()) {
_channels.insert({kv1.first, channel_data()});
found = _channels.find(kv1.first);
if (found == _channels.end()) {
assert(found != _channels.end());
throw std::runtime_error("Unable to insert element into data _store.");
}
}
std::string chv_key = std::string(ST_CHANNEL_VALUE) + "." + kv1.second;
found->second.value = static_cast<float_t>(obs_data_get_double(settings, chv_key.c_str()));
_precalc.base.ptr[static_cast<size_t>(kv1.first)] = found->second.value;
std::string chm_key = std::string(ST_CHANNEL_MULTIPLIER) + "." + kv1.second;
found->second.scale = static_cast<float_t>(obs_data_get_double(settings, chm_key.c_str()));
_precalc.scale.ptr[static_cast<size_t>(kv1.first)] = found->second.scale;
vec4* ch = &_precalc.matrix.x;
switch (kv1.first) {
case channel::Red:
ch = &_precalc.matrix.x;
break;
case channel::Green:
ch = &_precalc.matrix.y;
break;
case channel::Blue:
ch = &_precalc.matrix.z;
break;
case channel::Alpha:
ch = &_precalc.matrix.t;
break;
default:
break;
}
for (auto kv2 : channel_translations) {
std::string ab_key = std::string(ST_CHANNEL_INPUT) + "." + kv1.second + "." + kv2.second;
found->second.values.ptr[static_cast<size_t>(kv2.first)] =
static_cast<float_t>(obs_data_get_double(settings, ab_key.c_str()));
ch->ptr[static_cast<size_t>(kv2.first)] = found->second.values.ptr[static_cast<size_t>(kv2.first)];
}
}
}
void dynamic_mask_instance::save(obs_data_t* settings)
{
if (_input) {
obs_data_set_string(settings, ST_INPUT, obs_source_get_name(_input->get()));
}
for (auto kv1 : channel_translations) {
auto found = _channels.find(kv1.first);
if (found == _channels.end()) {
_channels.insert({kv1.first, channel_data()});
found = _channels.find(kv1.first);
if (found == _channels.end()) {
assert(found != _channels.end());
throw std::runtime_error("Unable to insert element into data _store.");
}
}
std::string chv_key = std::string(ST_CHANNEL_VALUE) + "." + kv1.second;
obs_data_set_double(settings, chv_key.c_str(), static_cast<double_t>(found->second.value));
std::string chm_key = std::string(ST_CHANNEL_MULTIPLIER) + "." + kv1.second;
obs_data_set_double(settings, chm_key.c_str(), static_cast<double_t>(found->second.scale));
for (auto kv2 : channel_translations) {
std::string ab_key = std::string(ST_CHANNEL_INPUT) + "." + kv1.second + "." + kv2.second;
obs_data_set_double(settings, ab_key.c_str(),
static_cast<double_t>(found->second.values.ptr[static_cast<size_t>(kv2.first)]));
}
}
}
void dynamic_mask_instance::input_renamed(obs::deprecated_source*, std::string old_name, std::string new_name)
{
obs_data_t* settings = obs_source_get_settings(_self);
obs_data_set_string(settings, ST_INPUT, new_name.c_str());
obs_source_update(_self, settings);
}
void dynamic_mask_instance::video_tick(float)
{
_have_input_texture = false;
_have_filter_texture = false;
_have_final_texture = false;
}
void dynamic_mask_instance::video_render(gs_effect_t* in_effect)
{
obs_source_t* parent = obs_filter_get_parent(_self);
obs_source_t* target = obs_filter_get_target(_self);
uint32_t width = obs_source_get_base_width(target);
uint32_t height = obs_source_get_base_height(target);
if (!_self || !parent || !target || !width || !height || !_input || !_input_capture || !_effect) {
obs_source_skip_video_filter(_self);
return;
} else if (!_input->width() || !_input->height()) {
obs_source_skip_video_filter(_self);
return;
}
#ifdef ENABLE_PROFILING
gs::debug_marker gdmp{gs::debug_color_source, "Dynamic Mask '%s' on '%s'", obs_source_get_name(_self),
obs_source_get_name(obs_filter_get_parent(_self))};
#endif
gs_effect_t* default_effect = obs_get_base_effect(obs_base_effect::OBS_EFFECT_DEFAULT);
try { // Capture filter and input
if (!_have_filter_texture) {
#ifdef ENABLE_PROFILING
gs::debug_marker gdm{gs::debug_color_cache, "Cache"};
#endif
if (obs_source_process_filter_begin(_self, GS_RGBA, OBS_ALLOW_DIRECT_RENDERING)) {
auto op = _filter_rt->render(width, height);
gs_blend_state_push();
gs_reset_blend_state();
gs_enable_blending(false);
gs_blend_function(GS_BLEND_ONE, GS_BLEND_ZERO);
gs_set_cull_mode(GS_NEITHER);
gs_enable_color(true, true, true, true);
gs_enable_depth_test(false);
gs_depth_function(GS_ALWAYS);
gs_enable_stencil_test(false);
gs_enable_stencil_write(false);
gs_stencil_function(GS_STENCIL_BOTH, GS_ALWAYS);
gs_stencil_op(GS_STENCIL_BOTH, GS_KEEP, GS_KEEP, GS_KEEP);
gs_ortho(0, static_cast<float>(width), 0, static_cast<float>(height), -1., 1.);
obs_source_process_filter_end(_self, default_effect, width, height);
gs_blend_state_pop();
} else {
throw std::runtime_error("Failed to render filter.");
}
_filter_texture = _filter_rt->get_texture();
_have_filter_texture = true;
}
if (!_have_input_texture) {
#ifdef ENABLE_PROFILING
gs::debug_marker gdm{gs::debug_color_capture, "Capture '%s'",
obs_source_get_name(_input_capture->get_object())};
#endif
_input_texture = _input_capture->render(_input->width(), _input->height());
_have_input_texture = true;
}
// Draw source
if (!_have_final_texture) {
#ifdef ENABLE_PROFILING
gs::debug_marker gdm{gs::debug_color_convert, "Masking"};
#endif
{
auto op = _final_rt->render(width, height);
gs_blend_state_push();
gs_reset_blend_state();
gs_enable_blending(false);
gs_blend_function(GS_BLEND_ONE, GS_BLEND_ZERO);
gs_set_cull_mode(GS_NEITHER);
gs_enable_color(true, true, true, true);
gs_enable_depth_test(false);
gs_depth_function(GS_ALWAYS);
gs_enable_stencil_test(false);
gs_enable_stencil_write(false);
gs_stencil_function(GS_STENCIL_BOTH, GS_ALWAYS);
gs_stencil_op(GS_STENCIL_BOTH, GS_KEEP, GS_KEEP, GS_KEEP);
gs_ortho(0, 1, 0, 1, -1., 1.);
_effect.get_parameter("pMaskInputA").set_texture(_filter_texture);
_effect.get_parameter("pMaskInputB").set_texture(_input_texture);
_effect.get_parameter("pMaskBase").set_float4(_precalc.base);
_effect.get_parameter("pMaskMatrix").set_matrix(_precalc.matrix);
_effect.get_parameter("pMaskMultiplier").set_float4(_precalc.scale);
while (gs_effect_loop(_effect.get(), "Mask")) {
streamfx::gs_draw_fullscreen_tri();
}
gs_blend_state_pop();
}
_final_texture = _final_rt->get_texture();
_have_final_texture = true;
}
} catch (...) {
obs_source_skip_video_filter(_self);
return;
}
if (!_have_filter_texture || !_have_input_texture || !_have_final_texture) {
obs_source_skip_video_filter(_self);
return;
}
if (!_filter_texture->get_object() || !_input_texture->get_object() || !_final_texture->get_object()) {
obs_source_skip_video_filter(_self);
return;
}
// Draw source
{
#ifdef ENABLE_PROFILING
gs::debug_marker gdm{gs::debug_color_render, "Render"};
#endif
// It is important that we do not modify the blend state here, as it is set correctly by OBS
gs_set_cull_mode(GS_NEITHER);
gs_enable_color(true, true, true, true);
gs_enable_depth_test(false);
gs_depth_function(GS_ALWAYS);
gs_enable_stencil_test(false);
gs_enable_stencil_write(false);
gs_stencil_function(GS_STENCIL_BOTH, GS_ALWAYS);
gs_stencil_op(GS_STENCIL_BOTH, GS_ZERO, GS_ZERO, GS_ZERO);
gs_effect_t* final_effect = in_effect ? in_effect : default_effect;
gs_eparam_t* param = gs_effect_get_param_by_name(final_effect, "image");
if (!param) {
DLOG_ERROR("<filter-dynamic-mask:%s> Failed to set image param.", obs_source_get_name(_self));
obs_source_skip_video_filter(_self);
return;
} else {
gs_effect_set_texture(param, _final_texture->get_object());
}
while (gs_effect_loop(final_effect, "Draw")) {
gs_draw_sprite(0, 0, width, height);
}
}
}
dynamic_mask_factory::dynamic_mask_factory()
{
_info.id = PREFIX "filter-dynamic-mask";
_info.type = OBS_SOURCE_TYPE_FILTER;
_info.output_flags = OBS_SOURCE_VIDEO;
set_resolution_enabled(false);
finish_setup();
register_proxy("obs-stream-effects-filter-dynamic-mask");
}
dynamic_mask_factory::~dynamic_mask_factory() {}
const char* dynamic_mask_factory::get_name()
{
return D_TRANSLATE(ST);
}
void dynamic_mask_factory::get_defaults2(obs_data_t* data)
{
obs_data_set_default_int(data, ST_CHANNEL, static_cast<int64_t>(channel::Red));
for (auto kv : channel_translations) {
obs_data_set_default_double(data, (std::string(ST_CHANNEL_VALUE) + "." + kv.second).c_str(), 1.0);
obs_data_set_default_double(data, (std::string(ST_CHANNEL_MULTIPLIER) + "." + kv.second).c_str(), 1.0);
for (auto kv2 : channel_translations) {
obs_data_set_default_double(
data, (std::string(ST_CHANNEL_INPUT) + "." + kv.second + "." + kv2.second).c_str(), 0.0);
}
}
}
obs_properties_t* dynamic_mask_factory::get_properties2(dynamic_mask_instance* data)
{
obs_properties_t* props = obs_properties_create();
obs_property_t* p;
_translation_cache.clear();
{ // Input
p = obs_properties_add_list(props, ST_INPUT, D_TRANSLATE(ST_INPUT), OBS_COMBO_TYPE_LIST,
OBS_COMBO_FORMAT_STRING);
obs_property_set_long_description(p, D_TRANSLATE(D_DESC(ST_INPUT)));
obs_property_list_add_string(p, "", "");
obs::source_tracker::get()->enumerate(
[&p](std::string name, obs_source_t*) {
std::stringstream sstr;
sstr << name << " (" << D_TRANSLATE(S_SOURCETYPE_SOURCE) << ")";
obs_property_list_add_string(p, sstr.str().c_str(), name.c_str());
return false;
},
obs::source_tracker::filter_video_sources);
obs::source_tracker::get()->enumerate(
[&p](std::string name, obs_source_t*) {
std::stringstream sstr;
sstr << name << " (" << D_TRANSLATE(S_SOURCETYPE_SCENE) << ")";
obs_property_list_add_string(p, sstr.str().c_str(), name.c_str());
return false;
},
obs::source_tracker::filter_scenes);
}
const char* pri_chs[] = {S_CHANNEL_RED, S_CHANNEL_GREEN, S_CHANNEL_BLUE, S_CHANNEL_ALPHA};
for (auto pri_ch : pri_chs) {
auto grp = obs_properties_create();
{
_translation_cache.push_back(translate_string(D_TRANSLATE(ST_CHANNEL_VALUE), D_TRANSLATE(pri_ch)));
std::string buf = std::string(ST_CHANNEL_VALUE) + "." + pri_ch;
p = obs_properties_add_float_slider(grp, buf.c_str(), _translation_cache.back().c_str(), -100.0, 100.0,
0.01);
_translation_cache.push_back(translate_string(D_TRANSLATE(D_DESC(ST_CHANNEL_VALUE)), D_TRANSLATE(pri_ch),
D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch),
D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch),
D_TRANSLATE(pri_ch)));
obs_property_set_long_description(p, _translation_cache.back().c_str());
}
const char* sec_chs[] = {S_CHANNEL_RED, S_CHANNEL_GREEN, S_CHANNEL_BLUE, S_CHANNEL_ALPHA};
for (auto sec_ch : sec_chs) {
_translation_cache.push_back(translate_string(D_TRANSLATE(ST_CHANNEL_INPUT), D_TRANSLATE(sec_ch)));
std::string buf = std::string(ST_CHANNEL_INPUT) + "." + pri_ch + "." + sec_ch;
p = obs_properties_add_float_slider(grp, buf.c_str(), _translation_cache.back().c_str(), -100.0, 100.0,
0.01);
_translation_cache.push_back(translate_string(D_TRANSLATE(D_DESC(ST_CHANNEL_INPUT)), D_TRANSLATE(sec_ch),
D_TRANSLATE(pri_ch), D_TRANSLATE(sec_ch), D_TRANSLATE(pri_ch),
D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch),
D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch)));
obs_property_set_long_description(p, _translation_cache.back().c_str());
}
{
_translation_cache.push_back(translate_string(D_TRANSLATE(ST_CHANNEL_MULTIPLIER), D_TRANSLATE(pri_ch)));
std::string buf = std::string(ST_CHANNEL_MULTIPLIER) + "." + pri_ch;
p = obs_properties_add_float_slider(grp, buf.c_str(), _translation_cache.back().c_str(), -100.0, 100.0,
0.01);
_translation_cache.push_back(translate_string(D_TRANSLATE(D_DESC(ST_CHANNEL_MULTIPLIER)),
D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch),
D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch),
D_TRANSLATE(pri_ch), D_TRANSLATE(pri_ch)));
obs_property_set_long_description(p, _translation_cache.back().c_str());
}
{
_translation_cache.push_back(translate_string(D_TRANSLATE(ST_CHANNEL), D_TRANSLATE(pri_ch)));
std::string buf = std::string(ST_CHANNEL) + "." + pri_ch;
obs_properties_add_group(props, buf.c_str(), _translation_cache.back().c_str(),
obs_group_type::OBS_GROUP_NORMAL, grp);
}
}
return props;
}
std::string dynamic_mask_factory::translate_string(const char* format, ...)
{
va_list vargs;
va_start(vargs, format);
std::vector<char> buffer(2048);
std::size_t len = static_cast<size_t>(vsnprintf(buffer.data(), buffer.size(), format, vargs));
va_end(vargs);
return std::string(buffer.data(), buffer.data() + len);
}
std::shared_ptr<dynamic_mask_factory> _filter_dynamic_mask_factory_instance = nullptr;
void streamfx::filter::dynamic_mask::dynamic_mask_factory::initialize()
{
if (!_filter_dynamic_mask_factory_instance)
_filter_dynamic_mask_factory_instance = std::make_shared<dynamic_mask_factory>();
}
void streamfx::filter::dynamic_mask::dynamic_mask_factory::finalize()
{
_filter_dynamic_mask_factory_instance.reset();
}
std::shared_ptr<dynamic_mask_factory> streamfx::filter::dynamic_mask::dynamic_mask_factory::get()
{
return _filter_dynamic_mask_factory_instance;
}