for (unsigned i = 0; i < phase->effects.size(); ++i) {
Node *node = phase->effects[i];
const string effect_id = phase->effect_ids[make_pair(node, IN_SAME_PHASE)];
- if (node->incoming_links.size() == 1) {
- Node *input = node->incoming_links[0];
- NodeLinkType link_type = node->incoming_link_type[0];
- if (i != 0 && input->effect->is_compute_shader()) {
- // First effect after the compute shader reads the value
- // that cs_output() wrote to a global variable.
- frag_shader += string("#define INPUT(tc) CS_OUTPUT_VAL\n");
+ for (unsigned j = 0; j < node->incoming_links.size(); ++j) {
+ if (node->incoming_links.size() == 1) {
+ frag_shader += "#define INPUT";
} else {
- frag_shader += string("#define INPUT ") + phase->effect_ids[make_pair(input, link_type)] + "\n";
- }
- } else {
- for (unsigned j = 0; j < node->incoming_links.size(); ++j) {
- assert(!node->incoming_links[j]->effect->is_compute_shader());
char buf[256];
- string effect_id = phase->effect_ids[make_pair(node->incoming_links[j], node->incoming_link_type[j])];
- sprintf(buf, "#define INPUT%d %s\n", j + 1, effect_id.c_str());
+ sprintf(buf, "#define INPUT%d", j + 1);
frag_shader += buf;
}
+
+ Node *input = node->incoming_links[j];
+ NodeLinkType link_type = node->incoming_link_type[j];
+ if (i != 0 &&
+ input->effect->is_compute_shader() &&
+ node->incoming_link_type[j] == IN_SAME_PHASE) {
+ // First effect after the compute shader reads the value
+ // that cs_output() wrote to a global variable,
+ // ignoring the tc (since all such effects have to be
+ // strong one-to-one).
+ frag_shader += "(tc) CS_OUTPUT_VAL\n";
+ } else {
+ assert(phase->effect_ids.count(make_pair(input, link_type)));
+ frag_shader += string(" ") + phase->effect_ids[make_pair(input, link_type)] + "\n";
+ }
}
frag_shader += "\n";
frag_shader += "\n";
}
if (phase->is_compute_shader) {
+ assert(phase->effect_ids.count(make_pair(phase->compute_shader_node, IN_SAME_PHASE)));
frag_shader += string("#define INPUT ") + phase->effect_ids[make_pair(phase->compute_shader_node, IN_SAME_PHASE)] + "\n";
if (phase->compute_shader_node == phase->effects.back()) {
// No postprocessing.
frag_shader += string("#define CS_POSTPROC ") + phase->effect_ids[make_pair(phase->effects.back(), IN_SAME_PHASE)] + "\n";
}
} else {
+ assert(phase->effect_ids.count(make_pair(phase->effects.back(), IN_SAME_PHASE)));
frag_shader += string("#define INPUT ") + phase->effect_ids[make_pair(phase->effects.back(), IN_SAME_PHASE)] + "\n";
}
phase->effects.push_back(node);
if (node->effect->is_compute_shader()) {
+ assert(phase->compute_shader_node == nullptr ||
+ phase->compute_shader_node == node);
phase->is_compute_shader = true;
phase->compute_shader_node = node;
}
// Find all the dependencies of this effect, and add them to the stack.
- vector<Node *> deps = node->incoming_links;
- assert(node->effect->num_inputs() == deps.size());
- for (unsigned i = 0; i < deps.size(); ++i) {
+ assert(node->effect->num_inputs() == node->incoming_links.size());
+ for (Node *dep : node->incoming_links) {
bool start_new_phase = false;
+ Effect::MipmapRequirements save_needs_mipmaps = dep->needs_mipmaps;
+
if (node->effect->needs_texture_bounce() &&
- !deps[i]->effect->is_single_texture() &&
- !deps[i]->effect->override_disable_bounce()) {
+ !dep->effect->is_single_texture() &&
+ !dep->effect->override_disable_bounce()) {
start_new_phase = true;
}
// if we have diamonds in the graph; if so, choose that.
// If not, the effect on the node can also decide (this is the
// more common case).
- Effect::MipmapRequirements dep_mipmaps = deps[i]->needs_mipmaps;
+ Effect::MipmapRequirements dep_mipmaps = dep->needs_mipmaps;
if (dep_mipmaps == Effect::DOES_NOT_NEED_MIPMAPS) {
- if (deps[i]->effect->num_inputs() == 0) {
- Input *input = static_cast<Input *>(deps[i]->effect);
+ if (dep->effect->num_inputs() == 0) {
+ Input *input = static_cast<Input *>(dep->effect);
dep_mipmaps = input->can_supply_mipmaps() ? Effect::DOES_NOT_NEED_MIPMAPS : Effect::CANNOT_ACCEPT_MIPMAPS;
} else {
- dep_mipmaps = deps[i]->effect->needs_mipmaps();
+ dep_mipmaps = dep->effect->needs_mipmaps();
}
}
if (dep_mipmaps == Effect::DOES_NOT_NEED_MIPMAPS) {
- deps[i]->needs_mipmaps = node->needs_mipmaps;
+ dep->needs_mipmaps = node->needs_mipmaps;
} else if (dep_mipmaps != node->needs_mipmaps) {
// The dependency cannot supply our mipmap demands
// (either because it's an input that can't do mipmaps,
}
}
- if (deps[i]->outgoing_links.size() > 1) {
- if (!deps[i]->effect->is_single_texture()) {
+ if (dep->outgoing_links.size() > 1) {
+ if (!dep->effect->is_single_texture()) {
// More than one effect uses this as the input,
// and it is not a texture itself.
// The easiest thing to do (and probably also the safest
// and then let the next passes read from that.
start_new_phase = true;
} else {
- assert(deps[i]->effect->num_inputs() == 0);
+ assert(dep->effect->num_inputs() == 0);
// For textures, we try to be slightly more clever;
// if none of our outputs need a bounce, we don't bounce
// Strictly speaking, we could bounce it for some outputs
// and use it directly for others, but the processing becomes
// somewhat simpler if the effect is only used in one such way.
- for (unsigned j = 0; j < deps[i]->outgoing_links.size(); ++j) {
- Node *rdep = deps[i]->outgoing_links[j];
+ for (unsigned j = 0; j < dep->outgoing_links.size(); ++j) {
+ Node *rdep = dep->outgoing_links[j];
start_new_phase |= rdep->effect->needs_texture_bounce();
}
}
}
- if (deps[i]->effect->is_compute_shader()) {
- // Only one compute shader per phase; we should have been stopped
- // already due to the fact that compute shaders are not one-to-one.
- assert(!phase->is_compute_shader);
-
- // If all nodes so far are strong one-to-one, we can put them after
- // the compute shader (ie., process them on the output).
- start_new_phase = !node->strong_one_to_one_sampling;
- } else if (deps[i]->effect->sets_virtual_output_size()) {
- assert(deps[i]->effect->changes_output_size());
+ if (dep->effect->is_compute_shader()) {
+ if (phase->is_compute_shader) {
+ // Only one compute shader per phase.
+ start_new_phase = true;
+ } else if (!node->strong_one_to_one_sampling) {
+ // If all nodes so far are strong one-to-one, we can put them after
+ // the compute shader (ie., process them on the output).
+ start_new_phase = true;
+ } else if (!start_new_phase) {
+ phase->is_compute_shader = true;
+ phase->compute_shader_node = dep;
+ }
+ } else if (dep->effect->sets_virtual_output_size()) {
+ assert(dep->effect->changes_output_size());
// If the next effect sets a virtual size to rely on OpenGL's
// bilinear sampling, we'll really need to break the phase here.
start_new_phase = true;
- } else if (deps[i]->effect->changes_output_size() && !node->one_to_one_sampling) {
+ } else if (dep->effect->changes_output_size() && !node->one_to_one_sampling) {
// If the next effect changes size and we don't have one-to-one sampling,
// we also need to break here.
start_new_phase = true;
}
if (start_new_phase) {
- phase->inputs.push_back(construct_phase(deps[i], completed_effects));
+ // Since we're starting a new phase here, we don't need to impose any
+ // new demands on this effect. Restore the status we had before we
+ // started looking at it.
+ dep->needs_mipmaps = save_needs_mipmaps;
+
+ phase->inputs.push_back(construct_phase(dep, completed_effects));
} else {
- effects_todo_this_phase.push(deps[i]);
+ effects_todo_this_phase.push(dep);
// Propagate the one-to-one status down through the dependency.
- deps[i]->one_to_one_sampling = node->one_to_one_sampling &&
- deps[i]->effect->one_to_one_sampling();
- deps[i]->strong_one_to_one_sampling = node->strong_one_to_one_sampling &&
- deps[i]->effect->strong_one_to_one_sampling();
+ dep->one_to_one_sampling = node->one_to_one_sampling &&
+ dep->effect->one_to_one_sampling();
+ dep->strong_one_to_one_sampling = node->strong_one_to_one_sampling &&
+ dep->effect->strong_one_to_one_sampling();
}
node->incoming_link_type.push_back(start_new_phase ? IN_ANOTHER_PHASE : IN_SAME_PHASE);
dither_effect = dither->effect;
}
+namespace {
+
+// Whether this effect will cause the phase it is in to become a compute shader phase.
+bool induces_compute_shader(Node *node)
+{
+ if (node->effect->is_compute_shader()) {
+ return true;
+ }
+ if (!node->effect->strong_one_to_one_sampling()) {
+ // This effect can't be chained after a compute shader.
+ return false;
+ }
+ // If at least one of the effects we depend on is a compute shader,
+ // one of them will be put in the same phase as us (the other ones,
+ // if any, will be bounced).
+ for (Node *dep : node->incoming_links) {
+ if (induces_compute_shader(dep)) {
+ return true;
+ }
+ }
+ return false;
+}
+
+} // namespace
+
// Compute shaders can't output to the framebuffer, so if the last
// phase ends in a compute shader, add a dummy phase at the end that
// only blits directly from the temporary texture.
void EffectChain::add_dummy_effect_if_needed()
{
Node *output = find_output_node();
-
- // See if the last effect that's not strong one-to-one is a compute shader.
- Node *last_effect = output;
- while (last_effect->effect->num_inputs() == 1 &&
- last_effect->effect->strong_one_to_one_sampling()) {
- last_effect = last_effect->incoming_links[0];
- }
- if (last_effect->effect->is_compute_shader()) {
+ if (induces_compute_shader(output)) {
Node *dummy = add_node(new ComputeShaderOutputDisplayEffect());
connect_nodes(output, dummy);
has_dummy_effect = true;
output_dot("step21-split-to-phases.dot");
+ // There are some corner cases where we thought we needed to add a dummy
+ // effect, but then it turned out later we didn't (e.g. induces_compute_shader()
+ // didn't see a mipmap conflict coming, which would cause the compute shader
+ // to be split off from the inal phase); if so, remove the extra phase
+ // at the end, since it will give us some trouble during execution.
+ //
+ // TODO: Remove induces_compute_shader() and replace it with precise tracking.
+ if (has_dummy_effect && !phases[phases.size() - 2]->is_compute_shader) {
+ resource_pool->release_glsl_program(phases.back()->glsl_program_num);
+ delete phases.back();
+ phases.pop_back();
+ has_dummy_effect = false;
+ }
+
+ output_dot("step22-dummy-phase-removal.dot");
+
assert(phases[0]->inputs.empty());
finalized = true;
assert(y == 0);
assert(num_phases >= 2);
assert(!phases.back()->is_compute_shader);
+ assert(phases[phases.size() - 2]->is_compute_shader);
assert(phases.back()->effects.size() == 1);
assert(phases.back()->effects[0]->effect->effect_type_id() == "ComputeShaderOutputDisplayEffect");
phase->timer_query_objects_running.push_back(timer_query_object);
}
bool last_phase = (phase_num == num_phases - 1);
- if (phase_num == num_phases - 1) {
+ if (last_phase) {
// Last phase goes to the output the user specified.
if (!phase->is_compute_shader) {
+ assert(dest_fbo != (GLuint)-1);
glBindFramebuffer(GL_FRAMEBUFFER, dest_fbo);
check_error();
GLenum status = glCheckFramebufferStatusEXT(GL_FRAMEBUFFER_EXT);