467 lines
20 KiB
C++
467 lines
20 KiB
C++
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// Copyright 2020 The MediaPipe Authors.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "mediapipe/modules/face_geometry/libs/geometry_pipeline.h"
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#include <cmath>
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#include <cstdint>
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#include <memory>
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#include <utility>
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#include <vector>
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#include "Eigen/Core"
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#include "absl/memory/memory.h"
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#include "mediapipe/framework/formats/landmark.pb.h"
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#include "mediapipe/framework/formats/matrix.h"
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#include "mediapipe/framework/formats/matrix_data.pb.h"
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#include "mediapipe/framework/port/ret_check.h"
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#include "mediapipe/framework/port/status.h"
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#include "mediapipe/framework/port/status_macros.h"
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#include "mediapipe/framework/port/statusor.h"
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#include "mediapipe/modules/face_geometry/libs/mesh_3d_utils.h"
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#include "mediapipe/modules/face_geometry/libs/procrustes_solver.h"
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#include "mediapipe/modules/face_geometry/libs/validation_utils.h"
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#include "mediapipe/modules/face_geometry/protos/environment.pb.h"
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#include "mediapipe/modules/face_geometry/protos/face_geometry.pb.h"
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#include "mediapipe/modules/face_geometry/protos/geometry_pipeline_metadata.pb.h"
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#include "mediapipe/modules/face_geometry/protos/mesh_3d.pb.h"
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namespace mediapipe::face_geometry {
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namespace {
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struct PerspectiveCameraFrustum {
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// NOTE: all arguments must be validated prior to calling this constructor.
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PerspectiveCameraFrustum(const PerspectiveCamera& perspective_camera,
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int frame_width, int frame_height) {
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static constexpr float kDegreesToRadians = 3.14159265358979323846f / 180.f;
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const float height_at_near =
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2.f * perspective_camera.near() *
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std::tan(0.5f * kDegreesToRadians *
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perspective_camera.vertical_fov_degrees());
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const float width_at_near = frame_width * height_at_near / frame_height;
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left = -0.5f * width_at_near;
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right = 0.5f * width_at_near;
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bottom = -0.5f * height_at_near;
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top = 0.5f * height_at_near;
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near = perspective_camera.near();
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far = perspective_camera.far();
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}
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float left;
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float right;
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float bottom;
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float top;
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float near;
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float far;
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};
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class ScreenToMetricSpaceConverter {
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public:
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ScreenToMetricSpaceConverter(
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OriginPointLocation origin_point_location, //
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InputSource input_source, //
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Eigen::Matrix3Xf&& canonical_metric_landmarks, //
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Eigen::VectorXf&& landmark_weights, //
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std::unique_ptr<ProcrustesSolver> procrustes_solver)
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: origin_point_location_(origin_point_location),
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input_source_(input_source),
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canonical_metric_landmarks_(std::move(canonical_metric_landmarks)),
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landmark_weights_(std::move(landmark_weights)),
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procrustes_solver_(std::move(procrustes_solver)) {}
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// Converts `screen_landmark_list` into `metric_landmark_list` and estimates
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// the `pose_transform_mat`.
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//
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// Here's the algorithm summary:
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//
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// (1) Project X- and Y- screen landmark coordinates at the Z near plane.
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//
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// (2) Estimate a canonical-to-runtime landmark set scale by running the
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// Procrustes solver using the screen runtime landmarks.
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//
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// On this iteration, screen landmarks are used instead of unprojected
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// metric landmarks as it is not safe to unproject due to the relative
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// nature of the input screen landmark Z coordinate.
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//
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// (3) Use the canonical-to-runtime scale from (2) to unproject the screen
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// landmarks. The result is referenced as "intermediate landmarks" because
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// they are the first estimation of the resuling metric landmarks, but are
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// not quite there yet.
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//
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// (4) Estimate a canonical-to-runtime landmark set scale by running the
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// Procrustes solver using the intermediate runtime landmarks.
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//
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// (5) Use the product of the scale factors from (2) and (4) to unproject
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// the screen landmarks the second time. This is the second and the final
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// estimation of the metric landmarks.
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//
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// (6) Multiply each of the metric landmarks by the inverse pose
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// transformation matrix to align the runtime metric face landmarks with
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// the canonical metric face landmarks.
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//
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// Note: the input screen landmarks are in the left-handed coordinate system,
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// however any metric landmarks - including the canonical metric
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// landmarks, the final runtime metric landmarks and any intermediate
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// runtime metric landmarks - are in the right-handed coordinate system.
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//
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// To keep the logic correct, the landmark set handedness is changed any
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// time the screen-to-metric semantic barrier is passed.
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absl::Status Convert(const NormalizedLandmarkList& screen_landmark_list, //
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const PerspectiveCameraFrustum& pcf, //
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LandmarkList& metric_landmark_list, //
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Eigen::Matrix4f& pose_transform_mat) const {
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RET_CHECK_EQ(screen_landmark_list.landmark_size(),
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canonical_metric_landmarks_.cols())
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<< "The number of landmarks doesn't match the number passed upon "
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"initialization!";
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Eigen::Matrix3Xf screen_landmarks;
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ConvertLandmarkListToEigenMatrix(screen_landmark_list, screen_landmarks);
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ProjectXY(pcf, screen_landmarks);
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const float depth_offset = screen_landmarks.row(2).mean();
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// 1st iteration: don't unproject XY because it's unsafe to do so due to
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// the relative nature of the Z coordinate. Instead, run the
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// first estimation on the projected XY and use that scale to
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// unproject for the 2nd iteration.
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Eigen::Matrix3Xf intermediate_landmarks(screen_landmarks);
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ChangeHandedness(intermediate_landmarks);
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ASSIGN_OR_RETURN(const float first_iteration_scale,
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EstimateScale(intermediate_landmarks),
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_ << "Failed to estimate first iteration scale!");
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// 2nd iteration: unproject XY using the scale from the 1st iteration.
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intermediate_landmarks = screen_landmarks;
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MoveAndRescaleZ(pcf, depth_offset, first_iteration_scale,
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intermediate_landmarks);
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UnprojectXY(pcf, intermediate_landmarks);
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ChangeHandedness(intermediate_landmarks);
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// For face detection input landmarks, re-write Z-coord from the canonical
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// landmarks.
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if (input_source_ == InputSource::FACE_DETECTION_PIPELINE) {
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Eigen::Matrix4f intermediate_pose_transform_mat;
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MP_RETURN_IF_ERROR(procrustes_solver_->SolveWeightedOrthogonalProblem(
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canonical_metric_landmarks_, intermediate_landmarks,
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landmark_weights_, intermediate_pose_transform_mat))
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<< "Failed to estimate pose transform matrix!";
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intermediate_landmarks.row(2) =
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(intermediate_pose_transform_mat *
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canonical_metric_landmarks_.colwise().homogeneous())
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.row(2);
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}
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ASSIGN_OR_RETURN(const float second_iteration_scale,
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EstimateScale(intermediate_landmarks),
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_ << "Failed to estimate second iteration scale!");
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// Use the total scale to unproject the screen landmarks.
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const float total_scale = first_iteration_scale * second_iteration_scale;
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MoveAndRescaleZ(pcf, depth_offset, total_scale, screen_landmarks);
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UnprojectXY(pcf, screen_landmarks);
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ChangeHandedness(screen_landmarks);
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// At this point, screen landmarks are converted into metric landmarks.
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Eigen::Matrix3Xf& metric_landmarks = screen_landmarks;
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MP_RETURN_IF_ERROR(procrustes_solver_->SolveWeightedOrthogonalProblem(
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canonical_metric_landmarks_, metric_landmarks, landmark_weights_,
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pose_transform_mat))
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<< "Failed to estimate pose transform matrix!";
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// For face detection input landmarks, re-write Z-coord from the canonical
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// landmarks and run the pose transform estimation again.
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if (input_source_ == InputSource::FACE_DETECTION_PIPELINE) {
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metric_landmarks.row(2) =
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(pose_transform_mat *
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canonical_metric_landmarks_.colwise().homogeneous())
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.row(2);
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MP_RETURN_IF_ERROR(procrustes_solver_->SolveWeightedOrthogonalProblem(
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canonical_metric_landmarks_, metric_landmarks, landmark_weights_,
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pose_transform_mat))
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<< "Failed to estimate pose transform matrix!";
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}
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// Multiply each of the metric landmarks by the inverse pose
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// transformation matrix to align the runtime metric face landmarks with
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// the canonical metric face landmarks.
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metric_landmarks = (pose_transform_mat.inverse() *
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metric_landmarks.colwise().homogeneous())
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.topRows(3);
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ConvertEigenMatrixToLandmarkList(metric_landmarks, metric_landmark_list);
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return absl::OkStatus();
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}
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private:
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void ProjectXY(const PerspectiveCameraFrustum& pcf,
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Eigen::Matrix3Xf& landmarks) const {
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float x_scale = pcf.right - pcf.left;
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float y_scale = pcf.top - pcf.bottom;
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float x_translation = pcf.left;
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float y_translation = pcf.bottom;
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if (origin_point_location_ == OriginPointLocation::TOP_LEFT_CORNER) {
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landmarks.row(1) = 1.f - landmarks.row(1).array();
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}
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landmarks =
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landmarks.array().colwise() * Eigen::Array3f(x_scale, y_scale, x_scale);
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landmarks.colwise() += Eigen::Vector3f(x_translation, y_translation, 0.f);
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}
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absl::StatusOr<float> EstimateScale(Eigen::Matrix3Xf& landmarks) const {
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Eigen::Matrix4f transform_mat;
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MP_RETURN_IF_ERROR(procrustes_solver_->SolveWeightedOrthogonalProblem(
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canonical_metric_landmarks_, landmarks, landmark_weights_,
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transform_mat))
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<< "Failed to estimate canonical-to-runtime landmark set transform!";
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return transform_mat.col(0).norm();
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}
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static void MoveAndRescaleZ(const PerspectiveCameraFrustum& pcf,
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float depth_offset, float scale,
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Eigen::Matrix3Xf& landmarks) {
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landmarks.row(2) =
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(landmarks.array().row(2) - depth_offset + pcf.near) / scale;
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}
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static void UnprojectXY(const PerspectiveCameraFrustum& pcf,
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Eigen::Matrix3Xf& landmarks) {
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landmarks.row(0) =
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landmarks.row(0).cwiseProduct(landmarks.row(2)) / pcf.near;
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landmarks.row(1) =
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landmarks.row(1).cwiseProduct(landmarks.row(2)) / pcf.near;
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}
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static void ChangeHandedness(Eigen::Matrix3Xf& landmarks) {
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landmarks.row(2) *= -1.f;
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}
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static void ConvertLandmarkListToEigenMatrix(
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const NormalizedLandmarkList& landmark_list,
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Eigen::Matrix3Xf& eigen_matrix) {
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eigen_matrix = Eigen::Matrix3Xf(3, landmark_list.landmark_size());
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for (int i = 0; i < landmark_list.landmark_size(); ++i) {
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const auto& landmark = landmark_list.landmark(i);
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eigen_matrix(0, i) = landmark.x();
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eigen_matrix(1, i) = landmark.y();
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eigen_matrix(2, i) = landmark.z();
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}
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}
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static void ConvertEigenMatrixToLandmarkList(
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const Eigen::Matrix3Xf& eigen_matrix, LandmarkList& landmark_list) {
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landmark_list.Clear();
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for (int i = 0; i < eigen_matrix.cols(); ++i) {
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auto& landmark = *landmark_list.add_landmark();
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landmark.set_x(eigen_matrix(0, i));
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landmark.set_y(eigen_matrix(1, i));
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landmark.set_z(eigen_matrix(2, i));
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}
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}
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const OriginPointLocation origin_point_location_;
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const InputSource input_source_;
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Eigen::Matrix3Xf canonical_metric_landmarks_;
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Eigen::VectorXf landmark_weights_;
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std::unique_ptr<ProcrustesSolver> procrustes_solver_;
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};
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class GeometryPipelineImpl : public GeometryPipeline {
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public:
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GeometryPipelineImpl(
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const PerspectiveCamera& perspective_camera, //
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const Mesh3d& canonical_mesh, //
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uint32_t canonical_mesh_vertex_size, //
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uint32_t canonical_mesh_num_vertices,
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uint32_t canonical_mesh_vertex_position_offset,
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std::unique_ptr<ScreenToMetricSpaceConverter> space_converter)
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: perspective_camera_(perspective_camera),
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canonical_mesh_(canonical_mesh),
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canonical_mesh_vertex_size_(canonical_mesh_vertex_size),
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canonical_mesh_num_vertices_(canonical_mesh_num_vertices),
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canonical_mesh_vertex_position_offset_(
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canonical_mesh_vertex_position_offset),
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space_converter_(std::move(space_converter)) {}
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absl::StatusOr<std::vector<FaceGeometry>> EstimateFaceGeometry(
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const std::vector<NormalizedLandmarkList>& multi_face_landmarks,
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int frame_width, int frame_height) const override {
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MP_RETURN_IF_ERROR(ValidateFrameDimensions(frame_width, frame_height))
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<< "Invalid frame dimensions!";
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// Create a perspective camera frustum to be shared for geometry estimation
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// per each face.
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PerspectiveCameraFrustum pcf(perspective_camera_, frame_width,
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frame_height);
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std::vector<FaceGeometry> multi_face_geometry;
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// From this point, the meaning of "face landmarks" is clarified further as
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// "screen face landmarks". This is done do distinguish from "metric face
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// landmarks" that are derived during the face geometry estimation process.
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for (const NormalizedLandmarkList& screen_face_landmarks :
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multi_face_landmarks) {
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// Having a too compact screen landmark list will result in numerical
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// instabilities, therefore such faces are filtered.
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if (IsScreenLandmarkListTooCompact(screen_face_landmarks)) {
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continue;
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}
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// Convert the screen landmarks into the metric landmarks and get the pose
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// transformation matrix.
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LandmarkList metric_face_landmarks;
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Eigen::Matrix4f pose_transform_mat;
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MP_RETURN_IF_ERROR(space_converter_->Convert(screen_face_landmarks, pcf,
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metric_face_landmarks,
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pose_transform_mat))
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<< "Failed to convert landmarks from the screen to the metric space!";
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// Pack geometry data for this face.
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FaceGeometry face_geometry;
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Mesh3d* mutable_mesh = face_geometry.mutable_mesh();
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// Copy the canonical face mesh as the face geometry mesh.
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mutable_mesh->CopyFrom(canonical_mesh_);
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// Replace XYZ vertex mesh coodinates with the metric landmark positions.
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for (int i = 0; i < canonical_mesh_num_vertices_; ++i) {
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uint32_t vertex_buffer_offset = canonical_mesh_vertex_size_ * i +
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canonical_mesh_vertex_position_offset_;
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mutable_mesh->set_vertex_buffer(vertex_buffer_offset,
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metric_face_landmarks.landmark(i).x());
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mutable_mesh->set_vertex_buffer(vertex_buffer_offset + 1,
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metric_face_landmarks.landmark(i).y());
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mutable_mesh->set_vertex_buffer(vertex_buffer_offset + 2,
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metric_face_landmarks.landmark(i).z());
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}
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// Populate the face pose transformation matrix.
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mediapipe::MatrixDataProtoFromMatrix(
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pose_transform_mat, face_geometry.mutable_pose_transform_matrix());
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multi_face_geometry.push_back(face_geometry);
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}
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return multi_face_geometry;
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}
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private:
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static bool IsScreenLandmarkListTooCompact(
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const NormalizedLandmarkList& screen_landmarks) {
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float mean_x = 0.f;
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float mean_y = 0.f;
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for (int i = 0; i < screen_landmarks.landmark_size(); ++i) {
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const auto& landmark = screen_landmarks.landmark(i);
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mean_x += (landmark.x() - mean_x) / static_cast<float>(i + 1);
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mean_y += (landmark.y() - mean_y) / static_cast<float>(i + 1);
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}
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float max_sq_dist = 0.f;
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for (const auto& landmark : screen_landmarks.landmark()) {
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const float d_x = landmark.x() - mean_x;
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const float d_y = landmark.y() - mean_y;
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max_sq_dist = std::max(max_sq_dist, d_x * d_x + d_y * d_y);
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}
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||
|
|
||
|
static constexpr float kIsScreenLandmarkListTooCompactThreshold = 1e-3f;
|
||
|
return std::sqrt(max_sq_dist) <= kIsScreenLandmarkListTooCompactThreshold;
|
||
|
}
|
||
|
|
||
|
const PerspectiveCamera perspective_camera_;
|
||
|
const Mesh3d canonical_mesh_;
|
||
|
const uint32_t canonical_mesh_vertex_size_;
|
||
|
const uint32_t canonical_mesh_num_vertices_;
|
||
|
const uint32_t canonical_mesh_vertex_position_offset_;
|
||
|
|
||
|
std::unique_ptr<ScreenToMetricSpaceConverter> space_converter_;
|
||
|
};
|
||
|
|
||
|
} // namespace
|
||
|
|
||
|
absl::StatusOr<std::unique_ptr<GeometryPipeline>> CreateGeometryPipeline(
|
||
|
const Environment& environment, const GeometryPipelineMetadata& metadata) {
|
||
|
MP_RETURN_IF_ERROR(ValidateEnvironment(environment))
|
||
|
<< "Invalid environment!";
|
||
|
MP_RETURN_IF_ERROR(ValidateGeometryPipelineMetadata(metadata))
|
||
|
<< "Invalid geometry pipeline metadata!";
|
||
|
|
||
|
const auto& canonical_mesh = metadata.canonical_mesh();
|
||
|
RET_CHECK(HasVertexComponent(canonical_mesh.vertex_type(),
|
||
|
VertexComponent::POSITION))
|
||
|
<< "Canonical face mesh must have the `POSITION` vertex component!";
|
||
|
RET_CHECK(HasVertexComponent(canonical_mesh.vertex_type(),
|
||
|
VertexComponent::TEX_COORD))
|
||
|
<< "Canonical face mesh must have the `TEX_COORD` vertex component!";
|
||
|
|
||
|
uint32_t canonical_mesh_vertex_size =
|
||
|
GetVertexSize(canonical_mesh.vertex_type());
|
||
|
uint32_t canonical_mesh_num_vertices =
|
||
|
canonical_mesh.vertex_buffer_size() / canonical_mesh_vertex_size;
|
||
|
uint32_t canonical_mesh_vertex_position_offset =
|
||
|
GetVertexComponentOffset(canonical_mesh.vertex_type(),
|
||
|
VertexComponent::POSITION)
|
||
|
.value();
|
||
|
|
||
|
// Put the Procrustes landmark basis into Eigen matrices for an easier access.
|
||
|
Eigen::Matrix3Xf canonical_metric_landmarks =
|
||
|
Eigen::Matrix3Xf::Zero(3, canonical_mesh_num_vertices);
|
||
|
Eigen::VectorXf landmark_weights =
|
||
|
Eigen::VectorXf::Zero(canonical_mesh_num_vertices);
|
||
|
|
||
|
for (int i = 0; i < canonical_mesh_num_vertices; ++i) {
|
||
|
uint32_t vertex_buffer_offset =
|
||
|
canonical_mesh_vertex_size * i + canonical_mesh_vertex_position_offset;
|
||
|
|
||
|
canonical_metric_landmarks(0, i) =
|
||
|
canonical_mesh.vertex_buffer(vertex_buffer_offset);
|
||
|
canonical_metric_landmarks(1, i) =
|
||
|
canonical_mesh.vertex_buffer(vertex_buffer_offset + 1);
|
||
|
canonical_metric_landmarks(2, i) =
|
||
|
canonical_mesh.vertex_buffer(vertex_buffer_offset + 2);
|
||
|
}
|
||
|
|
||
|
for (const WeightedLandmarkRef& wlr : metadata.procrustes_landmark_basis()) {
|
||
|
uint32_t landmark_id = wlr.landmark_id();
|
||
|
landmark_weights(landmark_id) = wlr.weight();
|
||
|
}
|
||
|
|
||
|
std::unique_ptr<GeometryPipeline> result =
|
||
|
absl::make_unique<GeometryPipelineImpl>(
|
||
|
environment.perspective_camera(), canonical_mesh,
|
||
|
canonical_mesh_vertex_size, canonical_mesh_num_vertices,
|
||
|
canonical_mesh_vertex_position_offset,
|
||
|
absl::make_unique<ScreenToMetricSpaceConverter>(
|
||
|
environment.origin_point_location(),
|
||
|
metadata.input_source() == InputSource::DEFAULT
|
||
|
? InputSource::FACE_LANDMARK_PIPELINE
|
||
|
: metadata.input_source(),
|
||
|
std::move(canonical_metric_landmarks),
|
||
|
std::move(landmark_weights),
|
||
|
CreateFloatPrecisionProcrustesSolver()));
|
||
|
|
||
|
return result;
|
||
|
}
|
||
|
|
||
|
} // namespace mediapipe::face_geometry
|