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Run multitag on coprocessor (#816)

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This commit is contained in:
Matt
2023-10-17 10:20:00 -04:00
committed by GitHub
parent ededc4f130
commit 47bd077bbb
72 changed files with 1708 additions and 1801 deletions
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113
photon-lib/src/main/native/cpp/photonlib/MultiTargetPNPResult.cpp Normal file
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@@ -0,0 +1,113 @@
/*
* MIT License
*
* Copyright (c) PhotonVision
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include "photonlib/MultiTargetPNPResult.h"
namespace photonlib {
Packet& operator<<(Packet& packet, const MultiTargetPnpResult& target) {
packet << target.result;
size_t i;
for (i = 0; i < target.fiducialIdsUsed.capacity(); i++) {
if (i < target.fiducialIdsUsed.size()) {
packet << static_cast<int16_t>(target.fiducialIdsUsed[i]);
} else {
packet << static_cast<int16_t>(-1);
}
}
return packet;
}
Packet& operator>>(Packet& packet, MultiTargetPnpResult& target) {
packet >> target.result;
target.fiducialIdsUsed.clear();
for (size_t i = 0; i < target.fiducialIdsUsed.capacity(); i++) {
int16_t id = 0;
packet >> id;
if (id > -1) {
target.fiducialIdsUsed.push_back(id);
}
}
return packet;
}
// Encode a transform3d
Packet& operator<<(Packet& packet, const frc::Transform3d& transform) {
packet << transform.Translation().X().value()
<< transform.Translation().Y().value()
<< transform.Translation().Z().value()
<< transform.Rotation().GetQuaternion().W()
<< transform.Rotation().GetQuaternion().X()
<< transform.Rotation().GetQuaternion().Y()
<< transform.Rotation().GetQuaternion().Z();
return packet;
}
// Decode a transform3d
Packet& operator>>(Packet& packet, frc::Transform3d& transform) {
frc::Transform3d ret;
// We use these for best and alt transforms below
double x = 0;
double y = 0;
double z = 0;
double w = 0;
// decode and unitify translation
packet >> x >> y >> z;
const auto translation = frc::Translation3d(
units::meter_t(x), units::meter_t(y), units::meter_t(z));
// decode and add units to rotation
packet >> w >> x >> y >> z;
const auto rotation = frc::Rotation3d(frc::Quaternion(w, x, y, z));
transform = frc::Transform3d(translation, rotation);
return packet;
}
Packet& operator<<(Packet& packet, PNPResults const& result) {
packet << result.isValid << result.best << result.alt
<< result.bestReprojectionErr << result.altReprojectionErr
<< result.ambiguity;
return packet;
}
Packet& operator>>(Packet& packet, PNPResults& result) {
packet >> result.isValid >> result.best >> result.alt >>
result.bestReprojectionErr >> result.altReprojectionErr >>
result.ambiguity;
return packet;
}
} // namespace photonlib

6
photon-lib/src/main/native/cpp/photonlib/PhotonPipelineResult.cpp
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@@ -40,7 +40,7 @@ bool PhotonPipelineResult::operator!=(const PhotonPipelineResult& other) const {
Packet& operator<<(Packet& packet, const PhotonPipelineResult& result) {
// Encode latency and number of targets.
packet << result.latency.value() * 1000
packet << result.latency.value() * 1000 << result.m_pnpResults
<< static_cast<int8_t>(result.targets.size());
// Encode the information of each target.
@@ -52,9 +52,9 @@ Packet& operator<<(Packet& packet, const PhotonPipelineResult& result) {
Packet& operator>>(Packet& packet, PhotonPipelineResult& result) {
// Decode latency, existence of targets, and number of targets.
int8_t targetCount = 0;
double latencyMillis = 0;
packet >> latencyMillis >> targetCount;
int8_t targetCount = 0;
packet >> latencyMillis >> result.m_pnpResults >> targetCount;
result.latency = units::second_t(latencyMillis / 1000.0);
result.targets.clear();

46
photon-lib/src/main/native/cpp/photonlib/PhotonPoseEstimator.cpp
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@@ -82,7 +82,8 @@ PhotonPoseEstimator::PhotonPoseEstimator(frc::AprilTagFieldLayout tags,
poseCacheTimestamp(-1_s) {}
void PhotonPoseEstimator::SetMultiTagFallbackStrategy(PoseStrategy strategy) {
if (strategy == MULTI_TAG_PNP) {
if (strategy == MULTI_TAG_PNP_ON_COPROCESSOR ||
strategy == MULTI_TAG_PNP_ON_RIO) {
FRC_ReportError(
frc::warn::Warning,
"Fallback cannot be set to MULTI_TAG_PNP! Setting to lowest ambiguity",
@@ -162,8 +163,12 @@ std::optional<EstimatedRobotPose> PhotonPoseEstimator::Update(
case AVERAGE_BEST_TARGETS:
ret = AverageBestTargetsStrategy(result);
break;
case ::photonlib::MULTI_TAG_PNP:
ret = MultiTagPnpStrategy(result, cameraMatrixData, cameraDistCoeffs);
case MULTI_TAG_PNP_ON_COPROCESSOR:
ret =
MultiTagOnCoprocStrategy(result, cameraMatrixData, cameraDistCoeffs);
break;
case MULTI_TAG_PNP_ON_RIO:
ret = MultiTagOnRioStrategy(result, cameraMatrixData, cameraDistCoeffs);
break;
default:
FRC_ReportError(frc::warn::Warning, "Invalid Pose Strategy selected!",
@@ -205,7 +210,7 @@ std::optional<EstimatedRobotPose> PhotonPoseEstimator::LowestAmbiguityStrategy(
fiducialPose.value()
.TransformBy(bestTarget.GetBestCameraToTarget().Inverse())
.TransformBy(m_robotToCamera.Inverse()),
result.GetTimestamp(), result.GetTargets()};
result.GetTimestamp(), result.GetTargets(), LOWEST_AMBIGUITY};
}
std::optional<EstimatedRobotPose>
@@ -241,14 +246,14 @@ PhotonPoseEstimator::ClosestToCameraHeightStrategy(
pose = EstimatedRobotPose{
targetPose.TransformBy(target.GetAlternateCameraToTarget().Inverse())
.TransformBy(m_robotToCamera.Inverse()),
result.GetTimestamp(), result.GetTargets()};
result.GetTimestamp(), result.GetTargets(), CLOSEST_TO_CAMERA_HEIGHT};
}
if (bestDifference < smallestHeightDifference) {
smallestHeightDifference = bestDifference;
pose = EstimatedRobotPose{
targetPose.TransformBy(target.GetBestCameraToTarget().Inverse())
.TransformBy(m_robotToCamera.Inverse()),
result.GetTimestamp(), result.GetTargets()};
result.GetTimestamp(), result.GetTargets(), CLOSEST_TO_CAMERA_HEIGHT};
}
}
@@ -299,7 +304,8 @@ PhotonPoseEstimator::ClosestToReferencePoseStrategy(
}
}
return EstimatedRobotPose{pose, stateTimestamp, result.GetTargets()};
return EstimatedRobotPose{pose, stateTimestamp, result.GetTargets(),
CLOSEST_TO_REFERENCE_POSE};
}
std::optional<std::array<cv::Point3d, 4>> detail::CalcTagCorners(
@@ -351,7 +357,24 @@ frc::Pose3d detail::ToPose3d(const cv::Mat& tvec, const cv::Mat& rvec) {
Rotation3d(rv));
}
std::optional<EstimatedRobotPose> PhotonPoseEstimator::MultiTagPnpStrategy(
std::optional<EstimatedRobotPose> PhotonPoseEstimator::MultiTagOnCoprocStrategy(
PhotonPipelineResult result, std::optional<cv::Mat> camMat,
std::optional<cv::Mat> distCoeffs) {
if (result.MultiTagResult().result.isValid) {
const auto field2camera = result.MultiTagResult().result.best;
const auto fieldToRobot =
frc::Pose3d() + field2camera + m_robotToCamera.Inverse();
return photonlib::EstimatedRobotPose(fieldToRobot, result.GetTimestamp(),
result.GetTargets(),
MULTI_TAG_PNP_ON_COPROCESSOR);
}
return Update(result, std::nullopt, std::nullopt,
this->multiTagFallbackStrategy);
}
std::optional<EstimatedRobotPose> PhotonPoseEstimator::MultiTagOnRioStrategy(
PhotonPipelineResult result, std::optional<cv::Mat> camMat,
std::optional<cv::Mat> distCoeffs) {
using namespace frc;
@@ -404,7 +427,7 @@ std::optional<EstimatedRobotPose> PhotonPoseEstimator::MultiTagPnpStrategy(
return photonlib::EstimatedRobotPose(
pose.TransformBy(m_robotToCamera.Inverse()), result.GetTimestamp(),
result.GetTargets());
result.GetTargets(), MULTI_TAG_PNP_ON_RIO);
}
std::optional<EstimatedRobotPose>
@@ -430,7 +453,7 @@ PhotonPoseEstimator::AverageBestTargetsStrategy(PhotonPipelineResult result) {
return EstimatedRobotPose{
targetPose.TransformBy(target.GetBestCameraToTarget().Inverse())
.TransformBy(m_robotToCamera.Inverse()),
result.GetTimestamp(), result.GetTargets()};
result.GetTimestamp(), result.GetTargets(), AVERAGE_BEST_TARGETS};
}
totalAmbiguity += 1. / target.GetPoseAmbiguity();
@@ -450,6 +473,7 @@ PhotonPoseEstimator::AverageBestTargetsStrategy(PhotonPipelineResult result) {
}
return EstimatedRobotPose{frc::Pose3d(transform, rotation),
result.GetTimestamp(), result.GetTargets()};
result.GetTimestamp(), result.GetTargets(),
AVERAGE_BEST_TARGETS};
}
} // namespace photonlib

282
photon-lib/src/main/native/cpp/photonlib/RobotPoseEstimator.cpp
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@@ -1,282 +0,0 @@
/*
* MIT License
*
* Copyright (c) PhotonVision
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include "photonlib/RobotPoseEstimator.h"
#include <iostream>
#include <limits>
#include <map>
#include <span>
#include <string>
#include <utility>
#include <vector>
#include <frc/Errors.h>
#include <frc/apriltag/AprilTagFieldLayout.h>
#include <frc/geometry/Pose3d.h>
#include <frc/geometry/Rotation3d.h>
#include <frc/geometry/Transform3d.h>
#include <units/time.h>
#include "photonlib/PhotonCamera.h"
#include "photonlib/PhotonPipelineResult.h"
#include "photonlib/PhotonTrackedTarget.h"
namespace photonlib {
RobotPoseEstimator::RobotPoseEstimator(
std::shared_ptr<frc::AprilTagFieldLayout> tags, PoseStrategy strat,
std::vector<std::pair<std::shared_ptr<PhotonCamera>, frc::Transform3d>>
cams)
: aprilTags(tags),
strategy(strat),
cameras(std::move(cams)),
lastPose(frc::Pose3d()),
referencePose(frc::Pose3d()) {}
std::pair<frc::Pose3d, units::second_t> RobotPoseEstimator::Update() {
if (cameras.empty()) {
return std::make_pair(lastPose, units::second_t(0));
}
std::pair<frc::Pose3d, units::second_t> pair;
switch (strategy) {
case LOWEST_AMBIGUITY:
pair = LowestAmbiguityStrategy();
lastPose = pair.first;
return pair;
case CLOSEST_TO_CAMERA_HEIGHT:
pair = ClosestToCameraHeightStrategy();
lastPose = pair.first;
return pair;
case CLOSEST_TO_REFERENCE_POSE:
pair = ClosestToReferencePoseStrategy();
lastPose = pair.first;
return pair;
case CLOSEST_TO_LAST_POSE:
SetReferencePose(lastPose);
pair = ClosestToReferencePoseStrategy();
lastPose = pair.first;
return pair;
case AVERAGE_BEST_TARGETS:
pair = AverageBestTargetsStrategy();
lastPose = pair.first;
return pair;
default:
FRC_ReportError(frc::warn::Warning, "Invalid Pose Strategy selected!",
"");
}
return std::make_pair(lastPose, units::second_t(0));
}
std::pair<frc::Pose3d, units::second_t>
RobotPoseEstimator::LowestAmbiguityStrategy() {
int lowestAI = -1;
int lowestAJ = -1;
double lowestAmbiguityScore = std::numeric_limits<double>::infinity();
for (RobotPoseEstimator::size_type i = 0; i < cameras.size(); ++i) {
std::pair<std::shared_ptr<PhotonCamera>, frc::Transform3d> p = cameras[i];
std::span<const PhotonTrackedTarget> targets =
p.first->GetLatestResult().GetTargets();
for (RobotPoseEstimator::size_type j = 0; j < targets.size(); ++j) {
if (targets[j].GetPoseAmbiguity() < lowestAmbiguityScore) {
lowestAI = i;
lowestAJ = j;
lowestAmbiguityScore = targets[j].GetPoseAmbiguity();
}
}
}
if (lowestAI == -1 || lowestAJ == -1) {
return std::make_pair(lastPose, units::second_t(0));
}
PhotonTrackedTarget bestTarget =
cameras[lowestAI].first->GetLatestResult().GetTargets()[lowestAJ];
std::optional<frc::Pose3d> fiducialPose =
aprilTags->GetTagPose(bestTarget.GetFiducialId());
if (!fiducialPose) {
FRC_ReportError(frc::warn::Warning,
"Tried to get pose of unknown April Tag: {}",
bestTarget.GetFiducialId());
return std::make_pair(lastPose, units::second_t(0));
}
return std::make_pair(
fiducialPose.value()
.TransformBy(bestTarget.GetBestCameraToTarget().Inverse())
.TransformBy(cameras[lowestAI].second.Inverse()),
cameras[lowestAI].first->GetLatestResult().GetTimestamp());
}
std::pair<frc::Pose3d, units::second_t>
RobotPoseEstimator::ClosestToCameraHeightStrategy() {
units::meter_t smallestHeightDifference =
units::meter_t(std::numeric_limits<double>::infinity());
units::second_t stateTimestamp = units::second_t(0);
frc::Pose3d pose = lastPose;
for (RobotPoseEstimator::size_type i = 0; i < cameras.size(); ++i) {
std::pair<std::shared_ptr<PhotonCamera>, frc::Transform3d> p = cameras[i];
std::span<const PhotonTrackedTarget> targets =
p.first->GetLatestResult().GetTargets();
for (RobotPoseEstimator::size_type j = 0; j < targets.size(); ++j) {
PhotonTrackedTarget target = targets[j];
std::optional<frc::Pose3d> fiducialPose =
aprilTags->GetTagPose(target.GetFiducialId());
if (!fiducialPose) {
FRC_ReportError(frc::warn::Warning,
"Tried to get pose of unknown April Tag: {}",
target.GetFiducialId());
continue;
}
frc::Pose3d targetPose = fiducialPose.value();
units::meter_t alternativeDifference = units::math::abs(
p.second.Z() -
targetPose.TransformBy(target.GetAlternateCameraToTarget().Inverse())
.Z());
units::meter_t bestDifference = units::math::abs(
p.second.Z() -
targetPose.TransformBy(target.GetBestCameraToTarget().Inverse()).Z());
if (alternativeDifference < smallestHeightDifference) {
smallestHeightDifference = alternativeDifference;
pose = targetPose.TransformBy(
target.GetAlternateCameraToTarget().Inverse());
stateTimestamp = p.first->GetLatestResult().GetTimestamp();
}
if (bestDifference < smallestHeightDifference) {
smallestHeightDifference = bestDifference;
pose = targetPose.TransformBy(target.GetBestCameraToTarget().Inverse());
stateTimestamp = p.first->GetLatestResult().GetTimestamp();
}
}
}
return std::make_pair(pose, stateTimestamp);
}
std::pair<frc::Pose3d, units::second_t>
RobotPoseEstimator::ClosestToReferencePoseStrategy() {
units::meter_t smallestDifference =
units::meter_t(std::numeric_limits<double>::infinity());
units::second_t stateTimestamp = units::second_t(0);
frc::Pose3d pose = lastPose;
for (RobotPoseEstimator::size_type i = 0; i < cameras.size(); ++i) {
std::pair<std::shared_ptr<PhotonCamera>, frc::Transform3d> p = cameras[i];
std::span<const PhotonTrackedTarget> targets =
p.first->GetLatestResult().GetTargets();
for (RobotPoseEstimator::size_type j = 0; j < targets.size(); ++j) {
PhotonTrackedTarget target = targets[j];
std::optional<frc::Pose3d> fiducialPose =
aprilTags->GetTagPose(target.GetFiducialId());
if (!fiducialPose) {
FRC_ReportError(frc::warn::Warning,
"Tried to get pose of unknown April Tag: {}",
target.GetFiducialId());
continue;
}
frc::Pose3d targetPose = fiducialPose.value();
units::meter_t alternativeDifference =
units::math::abs(referencePose.Translation().Distance(
targetPose
.TransformBy(target.GetAlternateCameraToTarget().Inverse())
.Translation()));
units::meter_t bestDifference =
units::math::abs(referencePose.Translation().Distance(
targetPose.TransformBy(target.GetBestCameraToTarget().Inverse())
.Translation()));
if (alternativeDifference < smallestDifference) {
smallestDifference = alternativeDifference;
pose = targetPose.TransformBy(
target.GetAlternateCameraToTarget().Inverse());
stateTimestamp = p.first->GetLatestResult().GetTimestamp();
}
if (bestDifference < smallestDifference) {
smallestDifference = bestDifference;
pose = targetPose.TransformBy(target.GetBestCameraToTarget().Inverse());
stateTimestamp = p.first->GetLatestResult().GetTimestamp();
}
}
}
return std::make_pair(pose, stateTimestamp);
}
std::pair<frc::Pose3d, units::second_t>
RobotPoseEstimator::AverageBestTargetsStrategy() {
std::vector<std::pair<frc::Pose3d, std::pair<double, units::second_t>>>
tempPoses;
double totalAmbiguity = 0;
units::second_t timstampSum = units::second_t(0);
for (RobotPoseEstimator::size_type i = 0; i < cameras.size(); ++i) {
std::pair<std::shared_ptr<PhotonCamera>, frc::Transform3d> p = cameras[i];
std::span<const PhotonTrackedTarget> targets =
p.first->GetLatestResult().GetTargets();
timstampSum += p.first->GetLatestResult().GetTimestamp();
for (RobotPoseEstimator::size_type j = 0; j < targets.size(); ++j) {
PhotonTrackedTarget target = targets[j];
std::optional<frc::Pose3d> fiducialPose =
aprilTags->GetTagPose(target.GetFiducialId());
if (!fiducialPose) {
FRC_ReportError(frc::warn::Warning,
"Tried to get pose of unknown April Tag: {}",
target.GetFiducialId());
continue;
}
frc::Pose3d targetPose = fiducialPose.value();
if (target.GetPoseAmbiguity() == 0) {
FRC_ReportError(frc::warn::Warning,
"Pose ambiguity of zero exists, using that instead!",
"");
return std::make_pair(
targetPose.TransformBy(target.GetBestCameraToTarget().Inverse()),
p.first->GetLatestResult().GetLatency() / 1000.);
}
totalAmbiguity += 1. / target.GetPoseAmbiguity();
tempPoses.push_back(std::make_pair(
targetPose.TransformBy(target.GetBestCameraToTarget().Inverse()),
std::make_pair(target.GetPoseAmbiguity(),
p.first->GetLatestResult().GetTimestamp())));
}
}
frc::Translation3d transform = frc::Translation3d();
frc::Rotation3d rotation = frc::Rotation3d();
for (std::pair<frc::Pose3d, std::pair<double, units::second_t>>& pair :
tempPoses) {
double weight = (1. / pair.second.first) / totalAmbiguity;
transform = transform + pair.first.Translation() * weight;
rotation = rotation + pair.first.Rotation() * weight;
}
return std::make_pair(frc::Pose3d(transform, rotation),
timstampSum / cameras.size());
}
} // namespace photonlib