/* SPDX-License-Identifier: GPL-2.0-or-later * Copyright 2011 Blender Foundation. */ #include "COM_ScaleOperation.h" #include "COM_ConstantOperation.h" namespace blender::compositor { #define USE_FORCE_BILINEAR /* XXX(campbell): ignore input and use default from old compositor, * could become an option like the transform node. * * NOTE: use bilinear because bicubic makes fuzzy even when not scaling at all (1:1) */ BaseScaleOperation::BaseScaleOperation() { #ifdef USE_FORCE_BILINEAR sampler_ = (int)PixelSampler::Bilinear; #else sampler_ = -1; #endif variable_size_ = false; } void BaseScaleOperation::set_scale_canvas_max_size(Size2f size) { max_scale_canvas_size_ = size; } ScaleOperation::ScaleOperation() : ScaleOperation(DataType::Color) { } ScaleOperation::ScaleOperation(DataType data_type) : BaseScaleOperation() { this->add_input_socket(data_type, ResizeMode::None); this->add_input_socket(DataType::Value); this->add_input_socket(DataType::Value); this->add_output_socket(data_type); input_operation_ = nullptr; input_xoperation_ = nullptr; input_yoperation_ = nullptr; } float ScaleOperation::get_constant_scale(const int input_op_idx, const float factor) { const bool is_constant = get_input_operation(input_op_idx)->get_flags().is_constant_operation; if (is_constant) { return ((ConstantOperation *)get_input_operation(input_op_idx))->get_constant_elem()[0] * factor; } return 1.0f; } float ScaleOperation::get_constant_scale_x(const float width) { return get_constant_scale(X_INPUT_INDEX, get_relative_scale_x_factor(width)); } float ScaleOperation::get_constant_scale_y(const float height) { return get_constant_scale(Y_INPUT_INDEX, get_relative_scale_y_factor(height)); } bool ScaleOperation::is_scaling_variable() { return !get_input_operation(X_INPUT_INDEX)->get_flags().is_constant_operation || !get_input_operation(Y_INPUT_INDEX)->get_flags().is_constant_operation; } void ScaleOperation::scale_area(rcti &area, float relative_scale_x, float relative_scale_y) { const rcti src_area = area; const float center_x = BLI_rcti_size_x(&area) / 2.0f; const float center_y = BLI_rcti_size_y(&area) / 2.0f; area.xmin = floorf(scale_coord(area.xmin, center_x, relative_scale_x)); area.xmax = ceilf(scale_coord(area.xmax, center_x, relative_scale_x)); area.ymin = floorf(scale_coord(area.ymin, center_y, relative_scale_y)); area.ymax = ceilf(scale_coord(area.ymax, center_y, relative_scale_y)); float scale_offset_x, scale_offset_y; ScaleOperation::get_scale_offset(src_area, area, scale_offset_x, scale_offset_y); BLI_rcti_translate(&area, -scale_offset_x, -scale_offset_y); } void ScaleOperation::clamp_area_size_max(rcti &area, Size2f max_size) { if (BLI_rcti_size_x(&area) > max_size.x) { area.xmax = area.xmin + max_size.x; } if (BLI_rcti_size_y(&area) > max_size.y) { area.ymax = area.ymin + max_size.y; } } void ScaleOperation::init_data() { canvas_center_x_ = canvas_.xmin + get_width() / 2.0f; canvas_center_y_ = canvas_.ymin + get_height() / 2.0f; } void ScaleOperation::init_execution() { input_operation_ = this->get_input_socket_reader(0); input_xoperation_ = this->get_input_socket_reader(1); input_yoperation_ = this->get_input_socket_reader(2); } void ScaleOperation::deinit_execution() { input_operation_ = nullptr; input_xoperation_ = nullptr; input_yoperation_ = nullptr; } void ScaleOperation::get_scale_offset(const rcti &input_canvas, const rcti &scale_canvas, float &r_scale_offset_x, float &r_scale_offset_y) { r_scale_offset_x = (BLI_rcti_size_x(&input_canvas) - BLI_rcti_size_x(&scale_canvas)) / 2.0f; r_scale_offset_y = (BLI_rcti_size_y(&input_canvas) - BLI_rcti_size_y(&scale_canvas)) / 2.0f; } void ScaleOperation::get_scale_area_of_interest(const rcti &input_canvas, const rcti &scale_canvas, const float relative_scale_x, const float relative_scale_y, const rcti &output_area, rcti &r_input_area) { const float scale_center_x = BLI_rcti_size_x(&input_canvas) / 2.0f; const float scale_center_y = BLI_rcti_size_y(&input_canvas) / 2.0f; float scale_offset_x, scale_offset_y; ScaleOperation::get_scale_offset(input_canvas, scale_canvas, scale_offset_x, scale_offset_y); r_input_area.xmin = floorf( scale_coord_inverted(output_area.xmin + scale_offset_x, scale_center_x, relative_scale_x)); r_input_area.xmax = ceilf( scale_coord_inverted(output_area.xmax + scale_offset_x, scale_center_x, relative_scale_x)); r_input_area.ymin = floorf( scale_coord_inverted(output_area.ymin + scale_offset_y, scale_center_y, relative_scale_y)); r_input_area.ymax = ceilf( scale_coord_inverted(output_area.ymax + scale_offset_y, scale_center_y, relative_scale_y)); } void ScaleOperation::get_area_of_interest(const int input_idx, const rcti &output_area, rcti &r_input_area) { r_input_area = output_area; if (input_idx != 0 || is_scaling_variable()) { return; } NodeOperation *image_op = get_input_operation(IMAGE_INPUT_INDEX); const float scale_x = get_constant_scale_x(image_op->get_width()); const float scale_y = get_constant_scale_y(image_op->get_height()); get_scale_area_of_interest( image_op->get_canvas(), this->get_canvas(), scale_x, scale_y, output_area, r_input_area); expand_area_for_sampler(r_input_area, (PixelSampler)sampler_); } void ScaleOperation::update_memory_buffer_partial(MemoryBuffer *output, const rcti &area, Span inputs) { NodeOperation *input_image_op = get_input_operation(IMAGE_INPUT_INDEX); const int input_image_width = input_image_op->get_width(); const int input_image_height = input_image_op->get_height(); const float scale_x_factor = get_relative_scale_x_factor(input_image_width); const float scale_y_factor = get_relative_scale_y_factor(input_image_height); const float scale_center_x = input_image_width / 2.0f; const float scale_center_y = input_image_height / 2.0f; float from_scale_offset_x, from_scale_offset_y; ScaleOperation::get_scale_offset( input_image_op->get_canvas(), this->get_canvas(), from_scale_offset_x, from_scale_offset_y); const MemoryBuffer *input_image = inputs[IMAGE_INPUT_INDEX]; MemoryBuffer *input_x = inputs[X_INPUT_INDEX]; MemoryBuffer *input_y = inputs[Y_INPUT_INDEX]; BuffersIterator it = output->iterate_with({input_x, input_y}, area); for (; !it.is_end(); ++it) { const float rel_scale_x = *it.in(0) * scale_x_factor; const float rel_scale_y = *it.in(1) * scale_y_factor; const float scaled_x = scale_coord_inverted( from_scale_offset_x + canvas_.xmin + it.x, scale_center_x, rel_scale_x); const float scaled_y = scale_coord_inverted( from_scale_offset_y + canvas_.ymin + it.y, scale_center_y, rel_scale_y); input_image->read_elem_sampled( scaled_x - canvas_.xmin, scaled_y - canvas_.ymin, (PixelSampler)sampler_, it.out); } } void ScaleOperation::determine_canvas(const rcti &preferred_area, rcti &r_area) { if (execution_model_ == eExecutionModel::Tiled) { NodeOperation::determine_canvas(preferred_area, r_area); return; } const bool image_determined = get_input_socket(IMAGE_INPUT_INDEX)->determine_canvas(preferred_area, r_area); if (image_determined) { rcti image_canvas = r_area; rcti unused = COM_AREA_NONE; NodeOperationInput *x_socket = get_input_socket(X_INPUT_INDEX); NodeOperationInput *y_socket = get_input_socket(Y_INPUT_INDEX); x_socket->determine_canvas(image_canvas, unused); y_socket->determine_canvas(image_canvas, unused); if (is_scaling_variable()) { /* Do not scale canvas. */ return; } /* Determine scaled canvas. */ const float input_width = BLI_rcti_size_x(&r_area); const float input_height = BLI_rcti_size_y(&r_area); const float scale_x = get_constant_scale_x(input_width); const float scale_y = get_constant_scale_y(input_height); scale_area(r_area, scale_x, scale_y); const Size2f max_scale_size = {MAX2(input_width, max_scale_canvas_size_.x), MAX2(input_height, max_scale_canvas_size_.y)}; clamp_area_size_max(r_area, max_scale_size); /* Re-determine canvases of x and y constant inputs with scaled canvas as preferred. */ get_input_operation(X_INPUT_INDEX)->unset_canvas(); get_input_operation(Y_INPUT_INDEX)->unset_canvas(); x_socket->determine_canvas(r_area, unused); y_socket->determine_canvas(r_area, unused); } } ScaleRelativeOperation::ScaleRelativeOperation() : ScaleOperation() { } ScaleRelativeOperation::ScaleRelativeOperation(DataType data_type) : ScaleOperation(data_type) { } void ScaleRelativeOperation::execute_pixel_sampled(float output[4], float x, float y, PixelSampler sampler) { PixelSampler effective_sampler = get_effective_sampler(sampler); float scaleX[4]; float scaleY[4]; input_xoperation_->read_sampled(scaleX, x, y, effective_sampler); input_yoperation_->read_sampled(scaleY, x, y, effective_sampler); const float scx = scaleX[0]; const float scy = scaleY[0]; float nx = this->canvas_center_x_ + (x - this->canvas_center_x_) / scx; float ny = this->canvas_center_y_ + (y - this->canvas_center_y_) / scy; input_operation_->read_sampled(output, nx, ny, effective_sampler); } bool ScaleRelativeOperation::determine_depending_area_of_interest( rcti *input, ReadBufferOperation *read_operation, rcti *output) { rcti new_input; if (!variable_size_) { float scaleX[4]; float scaleY[4]; input_xoperation_->read_sampled(scaleX, 0, 0, PixelSampler::Nearest); input_yoperation_->read_sampled(scaleY, 0, 0, PixelSampler::Nearest); const float scx = scaleX[0]; const float scy = scaleY[0]; new_input.xmax = this->canvas_center_x_ + (input->xmax - this->canvas_center_x_) / scx + 1; new_input.xmin = this->canvas_center_x_ + (input->xmin - this->canvas_center_x_) / scx - 1; new_input.ymax = this->canvas_center_y_ + (input->ymax - this->canvas_center_y_) / scy + 1; new_input.ymin = this->canvas_center_y_ + (input->ymin - this->canvas_center_y_) / scy - 1; } else { new_input.xmax = this->get_width(); new_input.xmin = 0; new_input.ymax = this->get_height(); new_input.ymin = 0; } return BaseScaleOperation::determine_depending_area_of_interest( &new_input, read_operation, output); } void ScaleAbsoluteOperation::execute_pixel_sampled(float output[4], float x, float y, PixelSampler sampler) { PixelSampler effective_sampler = get_effective_sampler(sampler); float scaleX[4]; float scaleY[4]; input_xoperation_->read_sampled(scaleX, x, y, effective_sampler); input_yoperation_->read_sampled(scaleY, x, y, effective_sampler); const float scx = scaleX[0]; /* Target absolute scale. */ const float scy = scaleY[0]; /* Target absolute scale. */ const float width = this->get_width(); const float height = this->get_height(); /* Divide. */ float relative_xscale = scx / width; float relative_yscale = scy / height; float nx = this->canvas_center_x_ + (x - this->canvas_center_x_) / relative_xscale; float ny = this->canvas_center_y_ + (y - this->canvas_center_y_) / relative_yscale; input_operation_->read_sampled(output, nx, ny, effective_sampler); } bool ScaleAbsoluteOperation::determine_depending_area_of_interest( rcti *input, ReadBufferOperation *read_operation, rcti *output) { rcti new_input; if (!variable_size_) { float scaleX[4]; float scaleY[4]; input_xoperation_->read_sampled(scaleX, 0, 0, PixelSampler::Nearest); input_yoperation_->read_sampled(scaleY, 0, 0, PixelSampler::Nearest); const float scx = scaleX[0]; const float scy = scaleY[0]; const float width = this->get_width(); const float height = this->get_height(); /* Divide. */ float relateve_xscale = scx / width; float relateve_yscale = scy / height; new_input.xmax = this->canvas_center_x_ + (input->xmax - this->canvas_center_x_) / relateve_xscale; new_input.xmin = this->canvas_center_x_ + (input->xmin - this->canvas_center_x_) / relateve_xscale; new_input.ymax = this->canvas_center_y_ + (input->ymax - this->canvas_center_y_) / relateve_yscale; new_input.ymin = this->canvas_center_y_ + (input->ymin - this->canvas_center_y_) / relateve_yscale; } else { new_input.xmax = this->get_width(); new_input.xmin = 0; new_input.ymax = this->get_height(); new_input.ymin = 0; } return ScaleOperation::determine_depending_area_of_interest(&new_input, read_operation, output); } ScaleFixedSizeOperation::ScaleFixedSizeOperation() : BaseScaleOperation() { this->add_input_socket(DataType::Color, ResizeMode::None); this->add_output_socket(DataType::Color); this->set_canvas_input_index(0); input_operation_ = nullptr; is_offset_ = false; } void ScaleFixedSizeOperation::init_data(const rcti &input_canvas) { const int input_width = BLI_rcti_size_x(&input_canvas); const int input_height = BLI_rcti_size_y(&input_canvas); rel_x_ = input_width / (float)new_width_; rel_y_ = input_height / (float)new_height_; /* *** all the options below are for a fairly special case - camera framing *** */ if (offset_x_ != 0.0f || offset_y_ != 0.0f) { is_offset_ = true; if (new_width_ > new_height_) { offset_x_ *= new_width_; offset_y_ *= new_width_; } else { offset_x_ *= new_height_; offset_y_ *= new_height_; } } if (is_aspect_) { /* apply aspect from clip */ const float w_src = input_width; const float h_src = input_height; /* destination aspect is already applied from the camera frame */ const float w_dst = new_width_; const float h_dst = new_height_; const float asp_src = w_src / h_src; const float asp_dst = w_dst / h_dst; if (fabsf(asp_src - asp_dst) >= FLT_EPSILON) { if ((asp_src > asp_dst) == (is_crop_ == true)) { /* fit X */ const float div = asp_src / asp_dst; rel_x_ /= div; offset_x_ += ((w_src - (w_src * div)) / (w_src / w_dst)) / 2.0f; if (is_crop_ && execution_model_ == eExecutionModel::FullFrame) { int fit_width = new_width_ * div; if (fit_width > max_scale_canvas_size_.x) { fit_width = max_scale_canvas_size_.x; } const int added_width = fit_width - new_width_; new_width_ += added_width; offset_x_ += added_width / 2.0f; } } else { /* fit Y */ const float div = asp_dst / asp_src; rel_y_ /= div; offset_y_ += ((h_src - (h_src * div)) / (h_src / h_dst)) / 2.0f; if (is_crop_ && execution_model_ == eExecutionModel::FullFrame) { int fit_height = new_height_ * div; if (fit_height > max_scale_canvas_size_.y) { fit_height = max_scale_canvas_size_.y; } const int added_height = fit_height - new_height_; new_height_ += added_height; offset_y_ += added_height / 2.0f; } } is_offset_ = true; } } /* *** end framing options *** */ } void ScaleFixedSizeOperation::init_execution() { input_operation_ = this->get_input_socket_reader(0); } void ScaleFixedSizeOperation::deinit_execution() { input_operation_ = nullptr; } void ScaleFixedSizeOperation::execute_pixel_sampled(float output[4], float x, float y, PixelSampler sampler) { PixelSampler effective_sampler = get_effective_sampler(sampler); if (is_offset_) { float nx = ((x - offset_x_) * rel_x_); float ny = ((y - offset_y_) * rel_y_); input_operation_->read_sampled(output, nx, ny, effective_sampler); } else { input_operation_->read_sampled(output, x * rel_x_, y * rel_y_, effective_sampler); } } bool ScaleFixedSizeOperation::determine_depending_area_of_interest( rcti *input, ReadBufferOperation *read_operation, rcti *output) { rcti new_input; new_input.xmax = (input->xmax - offset_x_) * rel_x_ + 1; new_input.xmin = (input->xmin - offset_x_) * rel_x_; new_input.ymax = (input->ymax - offset_y_) * rel_y_ + 1; new_input.ymin = (input->ymin - offset_y_) * rel_y_; return BaseScaleOperation::determine_depending_area_of_interest( &new_input, read_operation, output); } void ScaleFixedSizeOperation::determine_canvas(const rcti &preferred_area, rcti &r_area) { rcti local_preferred = preferred_area; local_preferred.xmax = local_preferred.xmin + new_width_; local_preferred.ymax = local_preferred.ymin + new_height_; rcti input_canvas = COM_AREA_NONE; const bool input_determined = get_input_socket(0)->determine_canvas(local_preferred, input_canvas); if (input_determined) { init_data(input_canvas); r_area = input_canvas; if (execution_model_ == eExecutionModel::FullFrame) { r_area.xmin /= rel_x_; r_area.ymin /= rel_y_; r_area.xmin += offset_x_; r_area.ymin += offset_y_; } r_area.xmax = r_area.xmin + new_width_; r_area.ymax = r_area.ymin + new_height_; } } void ScaleFixedSizeOperation::get_area_of_interest(const int input_idx, const rcti &output_area, rcti &r_input_area) { BLI_assert(input_idx == 0); UNUSED_VARS_NDEBUG(input_idx); r_input_area.xmax = ceilf((output_area.xmax - offset_x_) * rel_x_); r_input_area.xmin = floorf((output_area.xmin - offset_x_) * rel_x_); r_input_area.ymax = ceilf((output_area.ymax - offset_y_) * rel_y_); r_input_area.ymin = floorf((output_area.ymin - offset_y_) * rel_y_); expand_area_for_sampler(r_input_area, (PixelSampler)sampler_); } void ScaleFixedSizeOperation::update_memory_buffer_partial(MemoryBuffer *output, const rcti &area, Span inputs) { const MemoryBuffer *input_img = inputs[0]; PixelSampler sampler = (PixelSampler)sampler_; BuffersIterator it = output->iterate_with({}, area); if (is_offset_) { for (; !it.is_end(); ++it) { const float nx = (canvas_.xmin + it.x - offset_x_) * rel_x_; const float ny = (canvas_.ymin + it.y - offset_y_) * rel_y_; input_img->read_elem_sampled(nx - canvas_.xmin, ny - canvas_.ymin, sampler, it.out); } } else { for (; !it.is_end(); ++it) { input_img->read_elem_sampled((canvas_.xmin + it.x) * rel_x_ - canvas_.xmin, (canvas_.ymin + it.y) * rel_y_ - canvas_.ymin, sampler, it.out); } } } } // namespace blender::compositor