/* rasterizer.cpp */ #include "rasterizer.h" #include "core/os/os.h" #include "core/string/print_string.h" Rasterizer *(*Rasterizer::_create_func)() = nullptr; Rasterizer *Rasterizer::create() { return _create_func(); } RasterizerStorage *RasterizerStorage::base_singleton = nullptr; RasterizerStorage::RasterizerStorage() { base_singleton = this; } bool RasterizerStorage::material_uses_tangents(RID p_material) { return false; } bool RasterizerStorage::material_uses_ensure_correct_normals(RID p_material) { return false; } void RasterizerStorage::InterpolationData::notify_free_multimesh(RID p_rid) { // print_line("free multimesh " + itos(p_rid.get_id())); // if the instance was on any of the lists, remove multimesh_interpolate_update_list.erase_multiple_unordered(p_rid); multimesh_transform_update_lists[0].erase_multiple_unordered(p_rid); multimesh_transform_update_lists[1].erase_multiple_unordered(p_rid); } void RasterizerStorage::update_interpolation_tick(bool p_process) { // detect any that were on the previous transform list that are no longer active, // we should remove them from the interpolate list for (unsigned int n = 0; n < _interpolation_data.multimesh_transform_update_list_prev->size(); n++) { const RID &rid = (*_interpolation_data.multimesh_transform_update_list_prev)[n]; bool active = true; // no longer active? (either the instance deleted or no longer being transformed) MMInterpolator *mmi = _multimesh_get_interpolator(rid); if (mmi && !mmi->on_transform_update_list) { active = false; mmi->on_interpolate_update_list = false; // make sure the most recent transform is set // copy data rather than use Pool = function? mmi->_data_interpolated = mmi->_data_curr; // and that both prev and current are the same, just in case of any interpolations mmi->_data_prev = mmi->_data_curr; // make sure are updated one more time to ensure the AABBs are correct //_instance_queue_update(instance, true); } if (!mmi) { active = false; } if (!active) { _interpolation_data.multimesh_interpolate_update_list.erase(rid); } } if (p_process) { for (unsigned int i = 0; i < _interpolation_data.multimesh_transform_update_list_curr->size(); i++) { const RID &rid = (*_interpolation_data.multimesh_transform_update_list_curr)[i]; MMInterpolator *mmi = _multimesh_get_interpolator(rid); if (mmi) { // reset for next tick mmi->on_transform_update_list = false; mmi->_data_prev = mmi->_data_curr; } } // for n } // if any have left the transform list, remove from the interpolate list // we maintain a mirror list for the transform updates, so we can detect when an instance // is no longer being transformed, and remove it from the interpolate list SWAP(_interpolation_data.multimesh_transform_update_list_curr, _interpolation_data.multimesh_transform_update_list_prev); // prepare for the next iteration _interpolation_data.multimesh_transform_update_list_curr->clear(); } void RasterizerStorage::update_interpolation_frame(bool p_process) { if (p_process) { // Only need 32 bit for interpolation, don't use real_t float f = Engine::get_singleton()->get_physics_interpolation_fraction(); for (unsigned int c = 0; c < _interpolation_data.multimesh_interpolate_update_list.size(); c++) { const RID &rid = _interpolation_data.multimesh_interpolate_update_list[c]; // We could use the TransformInterpolator here to slerp transforms, but that might be too expensive, // so just using a Basis lerp for now. MMInterpolator *mmi = _multimesh_get_interpolator(rid); if (mmi) { // make sure arrays are correct size DEV_ASSERT(mmi->_data_prev.size() == mmi->_data_curr.size()); if (mmi->_data_interpolated.size() < mmi->_data_curr.size()) { mmi->_data_interpolated.resize(mmi->_data_curr.size()); } DEV_ASSERT(mmi->_data_interpolated.size() >= mmi->_data_curr.size()); DEV_ASSERT((mmi->_data_curr.size() % mmi->_stride) == 0); int num = mmi->_data_curr.size() / mmi->_stride; PoolVector::Read r_prev = mmi->_data_prev.read(); PoolVector::Read r_curr = mmi->_data_curr.read(); PoolVector::Write w = mmi->_data_interpolated.write(); const float *pf_prev = r_prev.ptr(); const float *pf_curr = r_curr.ptr(); float *pf_int = w.ptr(); bool use_lerp = mmi->quality == 0; // temporary transform (needed for swizzling) // (transform prev, curr and result) Transform tp, tc, tr; // Test for cache friendliness versus doing branchless for (int n = 0; n < num; n++) { // Transform if (use_lerp) { for (int i = 0; i < mmi->_vf_size_xform; i++) { float a = pf_prev[i]; float b = pf_curr[i]; pf_int[i] = (a + ((b - a) * f)); } } else { // Silly swizzling, this will slow things down. no idea why it is using this format // .. maybe due to the shader. tp.basis.rows[0][0] = pf_prev[0]; tp.basis.rows[0][1] = pf_prev[1]; tp.basis.rows[0][2] = pf_prev[2]; tp.basis.rows[1][0] = pf_prev[4]; tp.basis.rows[1][1] = pf_prev[5]; tp.basis.rows[1][2] = pf_prev[6]; tp.basis.rows[2][0] = pf_prev[8]; tp.basis.rows[2][1] = pf_prev[9]; tp.basis.rows[2][2] = pf_prev[10]; tp.origin.x = pf_prev[3]; tp.origin.y = pf_prev[7]; tp.origin.z = pf_prev[11]; tc.basis.rows[0][0] = pf_curr[0]; tc.basis.rows[0][1] = pf_curr[1]; tc.basis.rows[0][2] = pf_curr[2]; tc.basis.rows[1][0] = pf_curr[4]; tc.basis.rows[1][1] = pf_curr[5]; tc.basis.rows[1][2] = pf_curr[6]; tc.basis.rows[2][0] = pf_curr[8]; tc.basis.rows[2][1] = pf_curr[9]; tc.basis.rows[2][2] = pf_curr[10]; tc.origin.x = pf_curr[3]; tc.origin.y = pf_curr[7]; tc.origin.z = pf_curr[11]; TransformInterpolator::interpolate_transform(tp, tc, tr, f); pf_int[0] = tr.basis.rows[0][0]; pf_int[1] = tr.basis.rows[0][1]; pf_int[2] = tr.basis.rows[0][2]; pf_int[4] = tr.basis.rows[1][0]; pf_int[5] = tr.basis.rows[1][1]; pf_int[6] = tr.basis.rows[1][2]; pf_int[8] = tr.basis.rows[2][0]; pf_int[9] = tr.basis.rows[2][1]; pf_int[10] = tr.basis.rows[2][2]; pf_int[3] = tr.origin.x; pf_int[7] = tr.origin.y; pf_int[11] = tr.origin.z; } pf_prev += mmi->_vf_size_xform; pf_curr += mmi->_vf_size_xform; pf_int += mmi->_vf_size_xform; // Color if (mmi->_vf_size_color == 1) { const uint8_t *p8_prev = (const uint8_t *)pf_prev; const uint8_t *p8_curr = (const uint8_t *)pf_curr; uint8_t *p8_int = (uint8_t *)pf_int; _interpolate_RGBA8(p8_prev, p8_curr, p8_int, f); pf_prev += 1; pf_curr += 1; pf_int += 1; } else if (mmi->_vf_size_color == 4) { for (int i = 0; i < 4; i++) { pf_int[i] = pf_prev[i] + ((pf_curr[i] - pf_prev[i]) * f); } pf_prev += 4; pf_curr += 4; pf_int += 4; } // Custom Data if (mmi->_vf_size_data == 1) { const uint8_t *p8_prev = (const uint8_t *)pf_prev; const uint8_t *p8_curr = (const uint8_t *)pf_curr; uint8_t *p8_int = (uint8_t *)pf_int; _interpolate_RGBA8(p8_prev, p8_curr, p8_int, f); pf_prev += 1; pf_curr += 1; pf_int += 1; } else if (mmi->_vf_size_data == 4) { for (int i = 0; i < 4; i++) { pf_int[i] = pf_prev[i] + ((pf_curr[i] - pf_prev[i]) * f); } pf_prev += 4; pf_curr += 4; pf_int += 4; } } _multimesh_set_as_bulk_array(rid, mmi->_data_interpolated); // make sure AABBs are constantly up to date through the interpolation? // NYI } } // for n } } RID RasterizerStorage::multimesh_create() { return _multimesh_create(); } void RasterizerStorage::multimesh_allocate(RID p_multimesh, int p_instances, RS::MultimeshTransformFormat p_transform_format, RS::MultimeshColorFormat p_color_format, RS::MultimeshCustomDataFormat p_data) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { mmi->_transform_format = p_transform_format; mmi->_color_format = p_color_format; mmi->_data_format = p_data; mmi->_num_instances = p_instances; mmi->_vf_size_xform = p_transform_format == RS::MULTIMESH_TRANSFORM_3D ? 12 : 8; switch (p_color_format) { default: { mmi->_vf_size_color = 0; } break; case RS::MULTIMESH_COLOR_8BIT: { mmi->_vf_size_color = 1; } break; case RS::MULTIMESH_COLOR_FLOAT: { mmi->_vf_size_color = 4; } break; } switch (p_data) { default: { mmi->_vf_size_data = 0; } break; case RS::MULTIMESH_CUSTOM_DATA_8BIT: { mmi->_vf_size_data = 1; } break; case RS::MULTIMESH_CUSTOM_DATA_FLOAT: { mmi->_vf_size_data = 4; } break; } mmi->_stride = mmi->_vf_size_xform + mmi->_vf_size_color + mmi->_vf_size_data; int size_in_floats = p_instances * mmi->_stride; mmi->_data_curr.resize(size_in_floats); mmi->_data_prev.resize(size_in_floats); mmi->_data_interpolated.resize(size_in_floats); } return _multimesh_allocate(p_multimesh, p_instances, p_transform_format, p_color_format, p_data); } int RasterizerStorage::multimesh_get_instance_count(RID p_multimesh) const { return _multimesh_get_instance_count(p_multimesh); } void RasterizerStorage::multimesh_set_mesh(RID p_multimesh, RID p_mesh) { _multimesh_set_mesh(p_multimesh, p_mesh); } void RasterizerStorage::multimesh_instance_set_transform(RID p_multimesh, int p_index, const Transform &p_transform) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { if (mmi->interpolated) { ERR_FAIL_COND(p_index >= mmi->_num_instances); ERR_FAIL_COND(mmi->_vf_size_xform != 12); PoolVector::Write w = mmi->_data_curr.write(); int start = p_index * mmi->_stride; float *ptr = w.ptr(); ptr += start; const Transform &t = p_transform; ptr[0] = t.basis.rows[0][0]; ptr[1] = t.basis.rows[0][1]; ptr[2] = t.basis.rows[0][2]; ptr[3] = t.origin.x; ptr[4] = t.basis.rows[1][0]; ptr[5] = t.basis.rows[1][1]; ptr[6] = t.basis.rows[1][2]; ptr[7] = t.origin.y; ptr[8] = t.basis.rows[2][0]; ptr[9] = t.basis.rows[2][1]; ptr[10] = t.basis.rows[2][2]; ptr[11] = t.origin.z; _multimesh_add_to_interpolation_lists(p_multimesh, *mmi); return; } } _multimesh_instance_set_transform(p_multimesh, p_index, p_transform); } void RasterizerStorage::multimesh_instance_set_transform_2d(RID p_multimesh, int p_index, const Transform2D &p_transform) { _multimesh_instance_set_transform_2d(p_multimesh, p_index, p_transform); } void RasterizerStorage::multimesh_instance_set_color(RID p_multimesh, int p_index, const Color &p_color) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { if (mmi->interpolated) { ERR_FAIL_COND(p_index >= mmi->_num_instances); ERR_FAIL_COND(mmi->_vf_size_color == 0); PoolVector::Write w = mmi->_data_curr.write(); int start = (p_index * mmi->_stride) + mmi->_vf_size_xform; float *ptr = w.ptr(); ptr += start; if (mmi->_vf_size_color == 4) { for (int n = 0; n < 4; n++) { ptr[n] = p_color.components[n]; } } else { #ifdef DEV_ENABLED // The options are currently 4, 1, or zero, but just in case this changes in future... ERR_FAIL_COND(mmi->_vf_size_color != 1); #endif uint32_t *pui = (uint32_t *)ptr; *pui = p_color.to_rgba32(); } _multimesh_add_to_interpolation_lists(p_multimesh, *mmi); return; } } _multimesh_instance_set_color(p_multimesh, p_index, p_color); } void RasterizerStorage::multimesh_instance_set_custom_data(RID p_multimesh, int p_index, const Color &p_color) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { if (mmi->interpolated) { ERR_FAIL_COND(p_index >= mmi->_num_instances); ERR_FAIL_COND(mmi->_vf_size_data == 0); PoolVector::Write w = mmi->_data_curr.write(); int start = (p_index * mmi->_stride) + mmi->_vf_size_xform + mmi->_vf_size_color; float *ptr = w.ptr(); ptr += start; if (mmi->_vf_size_data == 4) { for (int n = 0; n < 4; n++) { ptr[n] = p_color.components[n]; } } else { #ifdef DEV_ENABLED // The options are currently 4, 1, or zero, but just in case this changes in future... ERR_FAIL_COND(mmi->_vf_size_data != 1); #endif uint32_t *pui = (uint32_t *)ptr; *pui = p_color.to_rgba32(); } _multimesh_add_to_interpolation_lists(p_multimesh, *mmi); return; } } _multimesh_instance_set_custom_data(p_multimesh, p_index, p_color); } RID RasterizerStorage::multimesh_get_mesh(RID p_multimesh) const { return _multimesh_get_mesh(p_multimesh); } Transform RasterizerStorage::multimesh_instance_get_transform(RID p_multimesh, int p_index) const { return _multimesh_instance_get_transform(p_multimesh, p_index); } Transform2D RasterizerStorage::multimesh_instance_get_transform_2d(RID p_multimesh, int p_index) const { return _multimesh_instance_get_transform_2d(p_multimesh, p_index); } Color RasterizerStorage::multimesh_instance_get_color(RID p_multimesh, int p_index) const { return _multimesh_instance_get_color(p_multimesh, p_index); } Color RasterizerStorage::multimesh_instance_get_custom_data(RID p_multimesh, int p_index) const { return _multimesh_instance_get_custom_data(p_multimesh, p_index); } void RasterizerStorage::multimesh_set_physics_interpolated(RID p_multimesh, bool p_interpolated) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { mmi->interpolated = p_interpolated; } } void RasterizerStorage::multimesh_set_physics_interpolation_quality(RID p_multimesh, RS::MultimeshPhysicsInterpolationQuality p_quality) { ERR_FAIL_COND((p_quality < 0) || (p_quality > 1)); MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { mmi->quality = (int)p_quality; } } void RasterizerStorage::multimesh_instance_reset_physics_interpolation(RID p_multimesh, int p_index) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { ERR_FAIL_INDEX(p_index, mmi->_num_instances); PoolVector::Write w = mmi->_data_prev.write(); PoolVector::Read r = mmi->_data_curr.read(); int start = p_index * mmi->_stride; for (int n = 0; n < mmi->_stride; n++) { w[start + n] = r[start + n]; } } } void RasterizerStorage::_multimesh_add_to_interpolation_lists(RID p_multimesh, MMInterpolator &r_mmi) { if (!r_mmi.on_interpolate_update_list) { r_mmi.on_interpolate_update_list = true; _interpolation_data.multimesh_interpolate_update_list.push_back(p_multimesh); } if (!r_mmi.on_transform_update_list) { r_mmi.on_transform_update_list = true; _interpolation_data.multimesh_transform_update_list_curr->push_back(p_multimesh); } } void RasterizerStorage::multimesh_set_as_bulk_array_interpolated(RID p_multimesh, const PoolVector &p_array, const PoolVector &p_array_prev) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { ERR_FAIL_COND_MSG(p_array.size() != mmi->_data_curr.size(), vformat("Array for current frame should have %d elements, got %d instead.", mmi->_data_curr.size(), p_array.size())); ERR_FAIL_COND_MSG(p_array_prev.size() != mmi->_data_prev.size(), vformat("Array for previous frame should have %d elements, got %d instead.", mmi->_data_prev.size(), p_array_prev.size())); // We are assuming that mmi->interpolated is the case, // (can possibly assert this?) // even if this flag hasn't been set - just calling this function suggests // interpolation is desired. mmi->_data_prev = p_array_prev; mmi->_data_curr = p_array; _multimesh_add_to_interpolation_lists(p_multimesh, *mmi); } } void RasterizerStorage::multimesh_set_as_bulk_array(RID p_multimesh, const PoolVector &p_array) { MMInterpolator *mmi = _multimesh_get_interpolator(p_multimesh); if (mmi) { if (mmi->interpolated) { ERR_FAIL_COND_MSG(p_array.size() != mmi->_data_curr.size(), vformat("Array should have %d elements, got %d instead.", mmi->_data_curr.size(), p_array.size())); mmi->_data_curr = p_array; _multimesh_add_to_interpolation_lists(p_multimesh, *mmi); return; } } _multimesh_set_as_bulk_array(p_multimesh, p_array); } void RasterizerStorage::multimesh_set_visible_instances(RID p_multimesh, int p_visible) { _multimesh_set_visible_instances(p_multimesh, p_visible); } int RasterizerStorage::multimesh_get_visible_instances(RID p_multimesh) const { return _multimesh_get_visible_instances(p_multimesh); } AABB RasterizerStorage::multimesh_get_aabb(RID p_multimesh) const { return _multimesh_get_aabb(p_multimesh); } Rect2 RasterizerCanvas::Item::calculate_polygon_bounds(const Item::CommandPolygon &p_polygon) const { int num_points = p_polygon.points.size(); // With no skeleton, all points are untransformed. Rect2 r; const Point2 *pp = &p_polygon.points[0]; r.position = pp[0]; for (int n = 1; n < num_points; n++) { r.expand_to(pp[n]); } return r; }