sysid/src/main/native/cpp/view/AnalyzerPlot.cpp

// Copyright (c) FIRST and other WPILib contributors.
// Open Source Software; you can modify and/or share it under the terms of
// the WPILib BSD license file in the root directory of this project.

#include "sysid/view/AnalyzerPlot.h"

#include <algorithm>
#include <cmath>
#include <mutex>

#include <fmt/format.h>
#include <units/math.h>

#include "sysid/Util.h"
#include "sysid/analysis/AnalysisManager.h"
#include "sysid/analysis/ArmSim.h"
#include "sysid/analysis/ElevatorSim.h"
#include "sysid/analysis/FilteringUtils.h"
#include "sysid/analysis/SimpleMotorSim.h"

using namespace sysid;

static ImPlotPoint Getter(int idx, void* data) {
  return static_cast<ImPlotPoint*>(data)[idx];
}

template <typename Model>
static std::vector<std::vector<ImPlotPoint>> PopulateTimeDomainSim(
    const std::vector<PreparedData>& data,
    const std::array<units::second_t, 4>& startTimes, size_t step, Model model,
    double* simSquaredErrorSum, double* squaredVariationSum,
    int* timeSeriesPoints) {
  // Create the vector of ImPlotPoints that will contain our simulated data.
  std::vector<std::vector<ImPlotPoint>> pts;
  std::vector<ImPlotPoint> tmp;

  auto startTime = data[0].timestamp;

  tmp.emplace_back(startTime.value(), data[0].velocity);

  model.Reset(data[0].position, data[0].velocity);
  units::second_t t = 0_s;

  for (size_t i = 1; i < data.size(); ++i) {
    const auto& now = data[i];
    const auto& pre = data[i - 1];

    t += now.timestamp - pre.timestamp;

    // If the current time stamp and previous time stamp are across a test's
    // start timestamp, it is the start of a new test and the model needs to be
    // reset.
    if (std::find(startTimes.begin(), startTimes.end(), now.timestamp) !=
        startTimes.end()) {
      pts.emplace_back(std::move(tmp));
      model.Reset(now.position, now.velocity);
      continue;
    }

    model.Update(units::volt_t{pre.voltage}, now.timestamp - pre.timestamp);
    tmp.emplace_back((startTime + t).value(), model.GetVelocity());
    *simSquaredErrorSum += std::pow(now.velocity - model.GetVelocity(), 2);
    *squaredVariationSum += std::pow(now.velocity, 2);
    ++(*timeSeriesPoints);
  }

  pts.emplace_back(std::move(tmp));
  return pts;
}

AnalyzerPlot::AnalyzerPlot(wpi::Logger& logger) : m_logger(logger) {}

void AnalyzerPlot::SetRawTimeData(const std::vector<PreparedData>& rawSlow,
                                  const std::vector<PreparedData>& rawFast,
                                  std::atomic<bool>& abort) {
  auto rawSlowStep = std::ceil(rawSlow.size() * 1.0 / kMaxSize * 4);
  auto rawFastStep = std::ceil(rawFast.size() * 1.0 / kMaxSize * 4);
  // Populate Raw Slow Time Series Data
  for (size_t i = 0; i < rawSlow.size(); i += rawSlowStep) {
    if (abort) {
      return;
    }
    m_quasistaticData.rawData.emplace_back((rawSlow[i].timestamp).value(),
                                           rawSlow[i].velocity);
  }

  // Populate Raw fast Time Series Data
  for (size_t i = 0; i < rawFast.size(); i += rawFastStep) {
    if (abort) {
      return;
    }
    m_dynamicData.rawData.emplace_back((rawFast[i].timestamp).value(),
                                       rawFast[i].velocity);
  }
}

void AnalyzerPlot::ResetData() {
  m_quasistaticData.Clear();
  m_dynamicData.Clear();
  m_regressionData.Clear();
  m_timestepData.Clear();

  FitPlots();
}

void AnalyzerPlot::SetGraphLabels(std::string_view unit) {
  std::string_view abbreviation = GetAbbreviation(unit);
  m_velocityLabel = fmt::format("Velocity ({}/s)", abbreviation);
  m_accelerationLabel = fmt::format("Acceleration ({}/s²)", abbreviation);
  m_velPortionAccelLabel =
      fmt::format("Velocity-Portion Accel ({}/s²)", abbreviation);
}

void AnalyzerPlot::SetRawData(const Storage& data, std::string_view unit,
                              std::atomic<bool>& abort) {
  const auto& [slowForward, slowBackward, fastForward, fastBackward] = data;
  const auto& slow = m_direction == 0 ? slowForward : slowBackward;
  const auto& fast = m_direction == 0 ? fastForward : fastBackward;

  SetGraphLabels(unit);

  std::scoped_lock lock(m_mutex);

  ResetData();
  SetRawTimeData(slow, fast, abort);
}

void AnalyzerPlot::SetData(const Storage& rawData, const Storage& filteredData,
                           std::string_view unit,
                           const std::vector<double>& ffGains,
                           const std::array<units::second_t, 4>& startTimes,
                           AnalysisType type, std::atomic<bool>& abort) {
  double simSquaredErrorSum = 0;
  double squaredVariationSum = 0;
  int timeSeriesPoints = 0;

  const auto& Ks = ffGains[0];
  const auto& Kv = ffGains[1];
  const auto& Ka = ffGains[2];

  auto& [slowForward, slowBackward, fastForward, fastBackward] = filteredData;
  auto& [rawSlowForward, rawSlowBackward, rawFastForward, rawFastBackward] =
      rawData;

  const auto slow = AnalysisManager::DataConcat(slowForward, slowBackward);
  const auto fast = AnalysisManager::DataConcat(fastForward, fastBackward);
  const auto rawSlow =
      AnalysisManager::DataConcat(rawSlowForward, rawSlowBackward);
  const auto rawFast =
      AnalysisManager::DataConcat(rawFastForward, rawFastBackward);

  SetGraphLabels(unit);

  std::scoped_lock lock(m_mutex);

  ResetData();

  // Calculate step sizes to ensure that we only use the memory that we
  // allocated.
  auto slowStep = std::ceil(slow.size() * 1.0 / kMaxSize * 4);
  auto fastStep = std::ceil(fast.size() * 1.0 / kMaxSize * 4);

  units::second_t dtMean = GetMeanTimeDelta(filteredData);

  // Velocity-vs-time plots
  {
    const auto& slow = m_direction == 0 ? slowForward : slowBackward;
    const auto& fast = m_direction == 0 ? fastForward : fastBackward;
    const auto& rawSlow = m_direction == 0 ? rawSlowForward : rawSlowBackward;
    const auto& rawFast = m_direction == 0 ? rawFastForward : rawFastBackward;

    // Populate quasistatic time-domain graphs
    for (size_t i = 0; i < slow.size(); i += slowStep) {
      if (abort) {
        return;
      }

      m_quasistaticData.filteredData.emplace_back((slow[i].timestamp).value(),
                                                  slow[i].velocity);

      if (i > 0) {
        // If the current timestamp is not in the startTimes array, it is the
        // during a test and should be included. If it is in the startTimes
        // array, it is the beginning of a new test and the dt will be inflated.
        // Therefore we skip those to exclude that dt and effectively reset dt
        // calculations.
        if (slow[i].dt > 0_s &&
            std::find(startTimes.begin(), startTimes.end(),
                      slow[i].timestamp) == startTimes.end()) {
          m_timestepData.data.emplace_back(
              (slow[i].timestamp).value(),
              units::millisecond_t{slow[i].dt}.value());
        }
      }
    }

    // Populate dynamic time-domain graphs
    for (size_t i = 0; i < fast.size(); i += fastStep) {
      if (abort) {
        return;
      }

      m_dynamicData.filteredData.emplace_back((fast[i].timestamp).value(),
                                              fast[i].velocity);

      if (i > 0) {
        // If the current timestamp is not in the startTimes array, it is the
        // during a test and should be included. If it is in the startTimes
        // array, it is the beginning of a new test and the dt will be inflated.
        // Therefore we skip those to exclude that dt and effectively reset dt
        // calculations.
        if (fast[i].dt > 0_s &&
            std::find(startTimes.begin(), startTimes.end(),
                      fast[i].timestamp) == startTimes.end()) {
          m_timestepData.data.emplace_back(
              (fast[i].timestamp).value(),
              units::millisecond_t{fast[i].dt}.value());
        }
      }
    }

    SetRawTimeData(rawSlow, rawFast, abort);

    // Populate simulated time domain data
    if (type == analysis::kElevator) {
      const auto& Kg = ffGains[3];
      m_quasistaticData.simData = PopulateTimeDomainSim(
          rawSlow, startTimes, fastStep, sysid::ElevatorSim{Ks, Kv, Ka, Kg},
          &simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);
      m_dynamicData.simData = PopulateTimeDomainSim(
          rawFast, startTimes, fastStep, sysid::ElevatorSim{Ks, Kv, Ka, Kg},
          &simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);
    } else if (type == analysis::kArm) {
      const auto& Kg = ffGains[3];
      const auto& offset = ffGains[4];
      m_quasistaticData.simData = PopulateTimeDomainSim(
          rawSlow, startTimes, fastStep, sysid::ArmSim{Ks, Kv, Ka, Kg, offset},
          &simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);
      m_dynamicData.simData = PopulateTimeDomainSim(
          rawFast, startTimes, fastStep, sysid::ArmSim{Ks, Kv, Ka, Kg, offset},
          &simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);
    } else {
      m_quasistaticData.simData = PopulateTimeDomainSim(
          rawSlow, startTimes, fastStep, sysid::SimpleMotorSim{Ks, Kv, Ka},
          &simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);
      m_dynamicData.simData = PopulateTimeDomainSim(
          rawFast, startTimes, fastStep, sysid::SimpleMotorSim{Ks, Kv, Ka},
          &simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);
    }
  }

  // Acceleration-vs-velocity plot

  // Find minimum velocity of slow and fast datasets, then find point for line
  // of best fit
  auto slowMinVel =
      std::min_element(slow.cbegin(), slow.cend(), [](auto& a, auto& b) {
        return a.velocity < b.velocity;
      })->velocity;
  auto fastMinVel =
      std::min_element(fast.cbegin(), fast.cend(), [](auto& a, auto& b) {
        return a.velocity < b.velocity;
      })->velocity;
  auto minVel = std::min(slowMinVel, fastMinVel);
  m_regressionData.fitLine[0] = ImPlotPoint{minVel, -Kv / Ka * minVel};

  // Find maximum velocity of slow and fast datasets, then find point for line
  // of best fit
  auto slowMaxVel =
      std::max_element(slow.cbegin(), slow.cend(), [](auto& a, auto& b) {
        return a.velocity < b.velocity;
      })->velocity;
  auto fastMaxVel =
      std::max_element(fast.cbegin(), fast.cend(), [](auto& a, auto& b) {
        return a.velocity < b.velocity;
      })->velocity;
  auto maxVel = std::max(slowMaxVel, fastMaxVel);
  m_regressionData.fitLine[1] = ImPlotPoint{maxVel, -Kv / Ka * maxVel};

  // Populate acceleration vs velocity graph
  for (size_t i = 0; i < slow.size(); i += slowStep) {
    if (abort) {
      return;
    }

    // Calculate portion of acceleration caused by back-EMF
    double accelPortion = slow[i].acceleration - 1.0 / Ka * slow[i].voltage +
                          std::copysign(Ks / Ka, slow[i].velocity);

    if (type == analysis::kElevator) {
      const auto& Kg = ffGains[3];
      accelPortion -= Kg / Ka;
    } else if (type == analysis::kArm) {
      const auto& Kg = ffGains[3];
      accelPortion -= Kg / Ka * slow[i].cos;
    }

    m_regressionData.data.emplace_back(slow[i].velocity, accelPortion);
  }
  for (size_t i = 0; i < fast.size(); i += fastStep) {
    if (abort) {
      return;
    }

    // Calculate portion of voltage that corresponds to change in acceleration.
    double accelPortion = fast[i].acceleration - 1.0 / Ka * fast[i].voltage +
                          std::copysign(Ks / Ka, fast[i].velocity);

    if (type == analysis::kElevator) {
      const auto& Kg = ffGains[3];
      accelPortion -= Kg / Ka;
    } else if (type == analysis::kArm) {
      const auto& Kg = ffGains[3];
      accelPortion -= Kg / Ka * fast[i].cos;
    }

    m_regressionData.data.emplace_back(fast[i].velocity, accelPortion);
  }

  // Timestep-vs-time plot

  for (size_t i = 0; i < slow.size(); i += slowStep) {
    if (i > 0) {
      // If the current timestamp is not in the startTimes array, it is the
      // during a test and should be included. If it is in the startTimes
      // array, it is the beginning of a new test and the dt will be inflated.
      // Therefore we skip those to exclude that dt and effectively reset dt
      // calculations.
      if (slow[i].dt > 0_s &&
          std::find(startTimes.begin(), startTimes.end(), slow[i].timestamp) ==
              startTimes.end()) {
        m_timestepData.data.emplace_back(
            (slow[i].timestamp).value(),
            units::millisecond_t{slow[i].dt}.value());
      }
    }
  }

  for (size_t i = 0; i < fast.size(); i += fastStep) {
    if (i > 0) {
      // If the current timestamp is not in the startTimes array, it is the
      // during a test and should be included. If it is in the startTimes
      // array, it is the beginning of a new test and the dt will be inflated.
      // Therefore we skip those to exclude that dt and effectively reset dt
      // calculations.
      if (fast[i].dt > 0_s &&
          std::find(startTimes.begin(), startTimes.end(), fast[i].timestamp) ==
              startTimes.end()) {
        m_timestepData.data.emplace_back(
            (fast[i].timestamp).value(),
            units::millisecond_t{fast[i].dt}.value());
      }
    }
  }

  auto minTime =
      units::math::min(slow.front().timestamp, fast.front().timestamp);
  m_timestepData.fitLine[0] =
      ImPlotPoint{minTime.value(), units::millisecond_t{dtMean}.value()};

  auto maxTime = units::math::max(slow.back().timestamp, fast.back().timestamp);
  m_timestepData.fitLine[1] =
      ImPlotPoint{maxTime.value(), units::millisecond_t{dtMean}.value()};

  // RMSE = std::sqrt(sum((x_i - x^_i)^2) / N) where sum represents the sum of
  // all time series points, x_i represents the velocity at a timestep, x^_i
  // represents the prediction at the timestep, and N represents the number of
  // points
  m_RMSE = std::sqrt(simSquaredErrorSum / timeSeriesPoints);
  m_accelRSquared =
      1 - m_RMSE / std::sqrt(squaredVariationSum / timeSeriesPoints);
  FitPlots();
}

void AnalyzerPlot::FitPlots() {
  // Set the "fit" flag to true.
  m_quasistaticData.fitNextPlot = true;
  m_dynamicData.fitNextPlot = true;
  m_regressionData.fitNextPlot = true;
  m_timestepData.fitNextPlot = true;
}

double* AnalyzerPlot::GetSimRMSE() {
  return &m_RMSE;
}

double* AnalyzerPlot::GetSimRSquared() {
  return &m_accelRSquared;
}

static void PlotSimData(std::vector<std::vector<ImPlotPoint>>& data) {
  for (auto&& pts : data) {
    ImPlot::SetNextLineStyle(IMPLOT_AUTO_COL, 1.5);
    ImPlot::PlotLineG("Simulation", Getter, pts.data(), pts.size());
  }
}

bool AnalyzerPlot::DisplayPlots() {
  std::unique_lock lock(m_mutex, std::defer_lock);

  if (!lock.try_lock()) {
    ImGui::Text("Loading %c",
                "|/-\\"[static_cast<int>(ImGui::GetTime() / 0.05f) & 3]);
    return false;
  }

  ImVec2 plotSize = ImGui::GetContentRegionAvail();

  // Fit two plots horizontally
  plotSize.x = (plotSize.x - ImGui::GetStyle().ItemSpacing.x) / 2.f;

  // Fit two plots vertically while leaving room for three text boxes
  const float textBoxHeight = ImGui::GetFontSize() * 1.75;
  plotSize.y =
      (plotSize.y - textBoxHeight * 3 - ImGui::GetStyle().ItemSpacing.y) / 2.f;

  m_quasistaticData.Plot("Quasistatic Velocity vs. Time", plotSize,
                         m_velocityLabel.c_str(), m_pointSize);
  ImGui::SameLine();
  m_dynamicData.Plot("Dynamic Velocity vs. Time", plotSize,
                     m_velocityLabel.c_str(), m_pointSize);

  m_regressionData.Plot("Acceleration vs. Velocity", plotSize,
                        m_velocityLabel.c_str(), m_velPortionAccelLabel.c_str(),
                        true, true, m_pointSize);
  ImGui::SameLine();
  m_timestepData.Plot("Timesteps vs. Time", plotSize, "Time (s)",
                      "Timestep duration (ms)", true, false, m_pointSize,
                      [] { ImPlot::SetupAxisLimits(ImAxis_Y1, 0, 50); });

  return true;
}

AnalyzerPlot::FilteredDataVsTimePlot::FilteredDataVsTimePlot() {
  rawData.reserve(kMaxSize);
  filteredData.reserve(kMaxSize);
  simData.reserve(kMaxSize);
}

void AnalyzerPlot::FilteredDataVsTimePlot::Plot(const char* title,
                                                const ImVec2& size,
                                                const char* yLabel,
                                                float pointSize) {
  // Generate Sim vs Filtered Plot
  if (fitNextPlot) {
    ImPlot::SetNextAxesToFit();
  }

  if (ImPlot::BeginPlot(title, size)) {
    ImPlot::SetupAxis(ImAxis_X1, "Time (s)", ImPlotAxisFlags_NoGridLines);
    ImPlot::SetupAxis(ImAxis_Y1, yLabel, ImPlotAxisFlags_NoGridLines);
    ImPlot::SetupLegend(ImPlotLocation_NorthEast);

    // Plot Raw Data
    ImPlot::SetNextMarkerStyle(IMPLOT_AUTO, 1, IMPLOT_AUTO_COL, 0);
    ImPlot::SetNextMarkerStyle(ImPlotStyleVar_MarkerSize, pointSize);
    ImPlot::PlotScatterG("Raw Data", Getter, rawData.data(), rawData.size());

    // Plot Filtered Data after Raw data
    ImPlot::SetNextMarkerStyle(IMPLOT_AUTO, 1, IMPLOT_AUTO_COL, 0);
    ImPlot::SetNextMarkerStyle(ImPlotStyleVar_MarkerSize, pointSize);
    ImPlot::PlotScatterG("Filtered Data", Getter, filteredData.data(),
                         filteredData.size());

    // Plot Simulation Data for Velocity Data
    PlotSimData(simData);

    // Disable constant resizing
    if (fitNextPlot) {
      fitNextPlot = false;
    }

    ImPlot::EndPlot();
  }
}

void AnalyzerPlot::FilteredDataVsTimePlot::Clear() {
  rawData.clear();
  filteredData.clear();
  simData.clear();
}

AnalyzerPlot::DataWithFitLinePlot::DataWithFitLinePlot() {
  data.reserve(kMaxSize);
}

void AnalyzerPlot::DataWithFitLinePlot::Plot(const char* title,
                                             const ImVec2& size,
                                             const char* xLabel,
                                             const char* yLabel, bool fitX,
                                             bool fitY, float pointSize,
                                             std::function<void()> setup) {
  if (fitNextPlot) {
    if (fitX && fitY) {
      ImPlot::SetNextAxesToFit();
    } else if (fitX && !fitY) {
      ImPlot::SetNextAxisToFit(ImAxis_X1);
    } else if (!fitX && fitY) {
      ImPlot::SetNextAxisToFit(ImAxis_Y1);
    }
  }

  if (ImPlot::BeginPlot(title, size)) {
    setup();
    ImPlot::SetupAxis(ImAxis_X1, xLabel, ImPlotAxisFlags_NoGridLines);
    ImPlot::SetupAxis(ImAxis_Y1, yLabel, ImPlotAxisFlags_NoGridLines);
    ImPlot::SetupLegend(ImPlotLocation_NorthEast);

    // Get a reference to the data that we are plotting.
    ImPlot::SetNextMarkerStyle(IMPLOT_AUTO, 1, IMPLOT_AUTO_COL, 0);
    ImPlot::SetNextMarkerStyle(ImPlotStyleVar_MarkerSize, pointSize);
    ImPlot::PlotScatterG("Filtered Data", Getter, data.data(), data.size());

    ImPlot::SetNextLineStyle(IMPLOT_AUTO_COL, 1.5);
    ImPlot::PlotLineG("Fit", Getter, fitLine.data(), fitLine.size());

    ImPlot::EndPlot();

    if (fitNextPlot) {
      fitNextPlot = false;
    }
  }
}

void AnalyzerPlot::DataWithFitLinePlot::Clear() {
  data.clear();

  // Reset line of best fit
  fitLine[0] = ImPlotPoint{0, 0};
  fitLine[1] = ImPlotPoint{0, 0};
}
[sysid] Add SysId (#5672) The source is copied from this commit: https://github.com/wpilibsuite/sysid/commit/625ff04784e5240991275b9fa52e7836d1dbb058. 2023-10-01 15:09:09 -07:00			`// Copyright (c) FIRST and other WPILib contributors.`
			`// Open Source Software; you can modify and/or share it under the terms of`
			`// the WPILib BSD license file in the root directory of this project.`

			`#include "sysid/view/AnalyzerPlot.h"`

			`#include <algorithm>`
			`#include <cmath>`
			`#include <mutex>`

			`#include <fmt/format.h>`
			`#include <units/math.h>`

			`#include "sysid/Util.h"`
			`#include "sysid/analysis/AnalysisManager.h"`
			`#include "sysid/analysis/ArmSim.h"`
			`#include "sysid/analysis/ElevatorSim.h"`
			`#include "sysid/analysis/FilteringUtils.h"`
			`#include "sysid/analysis/SimpleMotorSim.h"`

			`using namespace sysid;`

			`static ImPlotPoint Getter(int idx, void* data) {`
			`return static_cast<ImPlotPoint*>(data)[idx];`
			`}`

			`template <typename Model>`
			`static std::vector<std::vector<ImPlotPoint>> PopulateTimeDomainSim(`
			`const std::vector<PreparedData>& data,`
			`const std::array<units::second_t, 4>& startTimes, size_t step, Model model,`
			`double* simSquaredErrorSum, double* squaredVariationSum,`
			`int* timeSeriesPoints) {`
			`// Create the vector of ImPlotPoints that will contain our simulated data.`
			`std::vector<std::vector<ImPlotPoint>> pts;`
			`std::vector<ImPlotPoint> tmp;`

			`auto startTime = data[0].timestamp;`

			`tmp.emplace_back(startTime.value(), data[0].velocity);`

			`model.Reset(data[0].position, data[0].velocity);`
			`units::second_t t = 0_s;`

			`for (size_t i = 1; i < data.size(); ++i) {`
			`const auto& now = data[i];`
			`const auto& pre = data[i - 1];`

			`t += now.timestamp - pre.timestamp;`

			`// If the current time stamp and previous time stamp are across a test's`
			`// start timestamp, it is the start of a new test and the model needs to be`
			`// reset.`
			`if (std::find(startTimes.begin(), startTimes.end(), now.timestamp) !=`
			`startTimes.end()) {`
			`pts.emplace_back(std::move(tmp));`
			`model.Reset(now.position, now.velocity);`
			`continue;`
			`}`

			`model.Update(units::volt_t{pre.voltage}, now.timestamp - pre.timestamp);`
			`tmp.emplace_back((startTime + t).value(), model.GetVelocity());`
			`*simSquaredErrorSum += std::pow(now.velocity - model.GetVelocity(), 2);`
			`*squaredVariationSum += std::pow(now.velocity, 2);`
			`++(*timeSeriesPoints);`
			`}`

			`pts.emplace_back(std::move(tmp));`
			`return pts;`
			`}`

			`AnalyzerPlot::AnalyzerPlot(wpi::Logger& logger) : m_logger(logger) {}`

			`void AnalyzerPlot::SetRawTimeData(const std::vector<PreparedData>& rawSlow,`
			`const std::vector<PreparedData>& rawFast,`
			`std::atomic<bool>& abort) {`
			`auto rawSlowStep = std::ceil(rawSlow.size() * 1.0 / kMaxSize * 4);`
			`auto rawFastStep = std::ceil(rawFast.size() * 1.0 / kMaxSize * 4);`
			`// Populate Raw Slow Time Series Data`
			`for (size_t i = 0; i < rawSlow.size(); i += rawSlowStep) {`
			`if (abort) {`
			`return;`
			`}`
			`m_quasistaticData.rawData.emplace_back((rawSlow[i].timestamp).value(),`
			`rawSlow[i].velocity);`
			`}`

			`// Populate Raw fast Time Series Data`
			`for (size_t i = 0; i < rawFast.size(); i += rawFastStep) {`
			`if (abort) {`
			`return;`
			`}`
			`m_dynamicData.rawData.emplace_back((rawFast[i].timestamp).value(),`
			`rawFast[i].velocity);`
			`}`
			`}`

			`void AnalyzerPlot::ResetData() {`
			`m_quasistaticData.Clear();`
			`m_dynamicData.Clear();`
			`m_regressionData.Clear();`
			`m_timestepData.Clear();`

			`FitPlots();`
			`}`

			`void AnalyzerPlot::SetGraphLabels(std::string_view unit) {`
			`std::string_view abbreviation = GetAbbreviation(unit);`
			`m_velocityLabel = fmt::format("Velocity ({}/s)", abbreviation);`
			`m_accelerationLabel = fmt::format("Acceleration ({}/s²)", abbreviation);`
			`m_velPortionAccelLabel =`
			`fmt::format("Velocity-Portion Accel ({}/s²)", abbreviation);`
			`}`

			`void AnalyzerPlot::SetRawData(const Storage& data, std::string_view unit,`
			`std::atomic<bool>& abort) {`
			`const auto& [slowForward, slowBackward, fastForward, fastBackward] = data;`
			`const auto& slow = m_direction == 0 ? slowForward : slowBackward;`
			`const auto& fast = m_direction == 0 ? fastForward : fastBackward;`

			`SetGraphLabels(unit);`

			`std::scoped_lock lock(m_mutex);`

			`ResetData();`
			`SetRawTimeData(slow, fast, abort);`
			`}`

			`void AnalyzerPlot::SetData(const Storage& rawData, const Storage& filteredData,`
			`std::string_view unit,`
			`const std::vector<double>& ffGains,`
			`const std::array<units::second_t, 4>& startTimes,`
			`AnalysisType type, std::atomic<bool>& abort) {`
			`double simSquaredErrorSum = 0;`
			`double squaredVariationSum = 0;`
			`int timeSeriesPoints = 0;`

			`const auto& Ks = ffGains[0];`
			`const auto& Kv = ffGains[1];`
			`const auto& Ka = ffGains[2];`

			`auto& [slowForward, slowBackward, fastForward, fastBackward] = filteredData;`
			`auto& [rawSlowForward, rawSlowBackward, rawFastForward, rawFastBackward] =`
			`rawData;`

			`const auto slow = AnalysisManager::DataConcat(slowForward, slowBackward);`
			`const auto fast = AnalysisManager::DataConcat(fastForward, fastBackward);`
			`const auto rawSlow =`
			`AnalysisManager::DataConcat(rawSlowForward, rawSlowBackward);`
			`const auto rawFast =`
			`AnalysisManager::DataConcat(rawFastForward, rawFastBackward);`

			`SetGraphLabels(unit);`

			`std::scoped_lock lock(m_mutex);`

			`ResetData();`

			`// Calculate step sizes to ensure that we only use the memory that we`
			`// allocated.`
			`auto slowStep = std::ceil(slow.size() * 1.0 / kMaxSize * 4);`
			`auto fastStep = std::ceil(fast.size() * 1.0 / kMaxSize * 4);`

			`units::second_t dtMean = GetMeanTimeDelta(filteredData);`

			`// Velocity-vs-time plots`
			`{`
			`const auto& slow = m_direction == 0 ? slowForward : slowBackward;`
			`const auto& fast = m_direction == 0 ? fastForward : fastBackward;`
			`const auto& rawSlow = m_direction == 0 ? rawSlowForward : rawSlowBackward;`
			`const auto& rawFast = m_direction == 0 ? rawFastForward : rawFastBackward;`

			`// Populate quasistatic time-domain graphs`
			`for (size_t i = 0; i < slow.size(); i += slowStep) {`
			`if (abort) {`
			`return;`
			`}`

			`m_quasistaticData.filteredData.emplace_back((slow[i].timestamp).value(),`
			`slow[i].velocity);`

			`if (i > 0) {`
			`// If the current timestamp is not in the startTimes array, it is the`
			`// during a test and should be included. If it is in the startTimes`
			`// array, it is the beginning of a new test and the dt will be inflated.`
			`// Therefore we skip those to exclude that dt and effectively reset dt`
			`// calculations.`
			`if (slow[i].dt > 0_s &&`
			`std::find(startTimes.begin(), startTimes.end(),`
			`slow[i].timestamp) == startTimes.end()) {`
			`m_timestepData.data.emplace_back(`
			`(slow[i].timestamp).value(),`
			`units::millisecond_t{slow[i].dt}.value());`
			`}`
			`}`
			`}`

			`// Populate dynamic time-domain graphs`
			`for (size_t i = 0; i < fast.size(); i += fastStep) {`
			`if (abort) {`
			`return;`
			`}`

			`m_dynamicData.filteredData.emplace_back((fast[i].timestamp).value(),`
			`fast[i].velocity);`

			`if (i > 0) {`
			`// If the current timestamp is not in the startTimes array, it is the`
			`// during a test and should be included. If it is in the startTimes`
			`// array, it is the beginning of a new test and the dt will be inflated.`
			`// Therefore we skip those to exclude that dt and effectively reset dt`
			`// calculations.`
			`if (fast[i].dt > 0_s &&`
			`std::find(startTimes.begin(), startTimes.end(),`
			`fast[i].timestamp) == startTimes.end()) {`
			`m_timestepData.data.emplace_back(`
			`(fast[i].timestamp).value(),`
			`units::millisecond_t{fast[i].dt}.value());`
			`}`
			`}`
			`}`

			`SetRawTimeData(rawSlow, rawFast, abort);`

			`// Populate simulated time domain data`
			`if (type == analysis::kElevator) {`
			`const auto& Kg = ffGains[3];`
			`m_quasistaticData.simData = PopulateTimeDomainSim(`
			`rawSlow, startTimes, fastStep, sysid::ElevatorSim{Ks, Kv, Ka, Kg},`
			`&simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);`
			`m_dynamicData.simData = PopulateTimeDomainSim(`
			`rawFast, startTimes, fastStep, sysid::ElevatorSim{Ks, Kv, Ka, Kg},`
			`&simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);`
			`} else if (type == analysis::kArm) {`
			`const auto& Kg = ffGains[3];`
			`const auto& offset = ffGains[4];`
			`m_quasistaticData.simData = PopulateTimeDomainSim(`
			`rawSlow, startTimes, fastStep, sysid::ArmSim{Ks, Kv, Ka, Kg, offset},`
			`&simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);`
			`m_dynamicData.simData = PopulateTimeDomainSim(`
			`rawFast, startTimes, fastStep, sysid::ArmSim{Ks, Kv, Ka, Kg, offset},`
			`&simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);`
			`} else {`
			`m_quasistaticData.simData = PopulateTimeDomainSim(`
			`rawSlow, startTimes, fastStep, sysid::SimpleMotorSim{Ks, Kv, Ka},`
			`&simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);`
			`m_dynamicData.simData = PopulateTimeDomainSim(`
			`rawFast, startTimes, fastStep, sysid::SimpleMotorSim{Ks, Kv, Ka},`
			`&simSquaredErrorSum, &squaredVariationSum, &timeSeriesPoints);`
			`}`
			`}`

			`// Acceleration-vs-velocity plot`

			`// Find minimum velocity of slow and fast datasets, then find point for line`
			`// of best fit`
			`auto slowMinVel =`
			`std::min_element(slow.cbegin(), slow.cend(), [](auto& a, auto& b) {`
			`return a.velocity < b.velocity;`
			`})->velocity;`
			`auto fastMinVel =`
			`std::min_element(fast.cbegin(), fast.cend(), [](auto& a, auto& b) {`
			`return a.velocity < b.velocity;`
			`})->velocity;`
			`auto minVel = std::min(slowMinVel, fastMinVel);`
			`m_regressionData.fitLine[0] = ImPlotPoint{minVel, -Kv / Ka * minVel};`

			`// Find maximum velocity of slow and fast datasets, then find point for line`
			`// of best fit`
			`auto slowMaxVel =`
			`std::max_element(slow.cbegin(), slow.cend(), [](auto& a, auto& b) {`
			`return a.velocity < b.velocity;`
			`})->velocity;`
			`auto fastMaxVel =`
			`std::max_element(fast.cbegin(), fast.cend(), [](auto& a, auto& b) {`
			`return a.velocity < b.velocity;`
			`})->velocity;`
			`auto maxVel = std::max(slowMaxVel, fastMaxVel);`
			`m_regressionData.fitLine[1] = ImPlotPoint{maxVel, -Kv / Ka * maxVel};`

			`// Populate acceleration vs velocity graph`
			`for (size_t i = 0; i < slow.size(); i += slowStep) {`
			`if (abort) {`
			`return;`
			`}`

			`// Calculate portion of acceleration caused by back-EMF`
			`double accelPortion = slow[i].acceleration - 1.0 / Ka * slow[i].voltage +`
			`std::copysign(Ks / Ka, slow[i].velocity);`

			`if (type == analysis::kElevator) {`
			`const auto& Kg = ffGains[3];`
			`accelPortion -= Kg / Ka;`
			`} else if (type == analysis::kArm) {`
			`const auto& Kg = ffGains[3];`
			`accelPortion -= Kg / Ka * slow[i].cos;`
			`}`

			`m_regressionData.data.emplace_back(slow[i].velocity, accelPortion);`
			`}`
			`for (size_t i = 0; i < fast.size(); i += fastStep) {`
			`if (abort) {`
			`return;`
			`}`

			`// Calculate portion of voltage that corresponds to change in acceleration.`
			`double accelPortion = fast[i].acceleration - 1.0 / Ka * fast[i].voltage +`
			`std::copysign(Ks / Ka, fast[i].velocity);`

			`if (type == analysis::kElevator) {`
			`const auto& Kg = ffGains[3];`
			`accelPortion -= Kg / Ka;`
			`} else if (type == analysis::kArm) {`
			`const auto& Kg = ffGains[3];`
			`accelPortion -= Kg / Ka * fast[i].cos;`
			`}`

			`m_regressionData.data.emplace_back(fast[i].velocity, accelPortion);`
			`}`

			`// Timestep-vs-time plot`

			`for (size_t i = 0; i < slow.size(); i += slowStep) {`
			`if (i > 0) {`
			`// If the current timestamp is not in the startTimes array, it is the`
			`// during a test and should be included. If it is in the startTimes`
			`// array, it is the beginning of a new test and the dt will be inflated.`
			`// Therefore we skip those to exclude that dt and effectively reset dt`
			`// calculations.`
			`if (slow[i].dt > 0_s &&`
			`std::find(startTimes.begin(), startTimes.end(), slow[i].timestamp) ==`
			`startTimes.end()) {`
			`m_timestepData.data.emplace_back(`
			`(slow[i].timestamp).value(),`
			`units::millisecond_t{slow[i].dt}.value());`
			`}`
			`}`
			`}`

			`for (size_t i = 0; i < fast.size(); i += fastStep) {`
			`if (i > 0) {`
			`// If the current timestamp is not in the startTimes array, it is the`
			`// during a test and should be included. If it is in the startTimes`
			`// array, it is the beginning of a new test and the dt will be inflated.`
			`// Therefore we skip those to exclude that dt and effectively reset dt`
			`// calculations.`
			`if (fast[i].dt > 0_s &&`
			`std::find(startTimes.begin(), startTimes.end(), fast[i].timestamp) ==`
			`startTimes.end()) {`
			`m_timestepData.data.emplace_back(`
			`(fast[i].timestamp).value(),`
			`units::millisecond_t{fast[i].dt}.value());`
			`}`
			`}`
			`}`

			`auto minTime =`
			`units::math::min(slow.front().timestamp, fast.front().timestamp);`
			`m_timestepData.fitLine[0] =`
			`ImPlotPoint{minTime.value(), units::millisecond_t{dtMean}.value()};`

			`auto maxTime = units::math::max(slow.back().timestamp, fast.back().timestamp);`
			`m_timestepData.fitLine[1] =`
			`ImPlotPoint{maxTime.value(), units::millisecond_t{dtMean}.value()};`

			`// RMSE = std::sqrt(sum((x_i - x^_i)^2) / N) where sum represents the sum of`
			`// all time series points, x_i represents the velocity at a timestep, x^_i`
			`// represents the prediction at the timestep, and N represents the number of`
			`// points`
			`m_RMSE = std::sqrt(simSquaredErrorSum / timeSeriesPoints);`
			`m_accelRSquared =`
			`1 - m_RMSE / std::sqrt(squaredVariationSum / timeSeriesPoints);`
			`FitPlots();`
			`}`

			`void AnalyzerPlot::FitPlots() {`
			`// Set the "fit" flag to true.`
			`m_quasistaticData.fitNextPlot = true;`
			`m_dynamicData.fitNextPlot = true;`
			`m_regressionData.fitNextPlot = true;`
			`m_timestepData.fitNextPlot = true;`
			`}`

			`double* AnalyzerPlot::GetSimRMSE() {`
			`return &m_RMSE;`
			`}`

			`double* AnalyzerPlot::GetSimRSquared() {`
			`return &m_accelRSquared;`
			`}`

			`static void PlotSimData(std::vector<std::vector<ImPlotPoint>>& data) {`
			`for (auto&& pts : data) {`
			`ImPlot::SetNextLineStyle(IMPLOT_AUTO_COL, 1.5);`
			`ImPlot::PlotLineG("Simulation", Getter, pts.data(), pts.size());`
			`}`
			`}`

			`bool AnalyzerPlot::DisplayPlots() {`
			`std::unique_lock lock(m_mutex, std::defer_lock);`

			`if (!lock.try_lock()) {`
			`ImGui::Text("Loading %c",`
			`"\|/-\\"[static_cast<int>(ImGui::GetTime() / 0.05f) & 3]);`
			`return false;`
			`}`

			`ImVec2 plotSize = ImGui::GetContentRegionAvail();`

			`// Fit two plots horizontally`
			`plotSize.x = (plotSize.x - ImGui::GetStyle().ItemSpacing.x) / 2.f;`

			`// Fit two plots vertically while leaving room for three text boxes`
			`const float textBoxHeight = ImGui::GetFontSize() * 1.75;`
			`plotSize.y =`
			`(plotSize.y - textBoxHeight * 3 - ImGui::GetStyle().ItemSpacing.y) / 2.f;`

			`m_quasistaticData.Plot("Quasistatic Velocity vs. Time", plotSize,`
			`m_velocityLabel.c_str(), m_pointSize);`
			`ImGui::SameLine();`
			`m_dynamicData.Plot("Dynamic Velocity vs. Time", plotSize,`
			`m_velocityLabel.c_str(), m_pointSize);`

			`m_regressionData.Plot("Acceleration vs. Velocity", plotSize,`
			`m_velocityLabel.c_str(), m_velPortionAccelLabel.c_str(),`
			`true, true, m_pointSize);`
			`ImGui::SameLine();`
			`m_timestepData.Plot("Timesteps vs. Time", plotSize, "Time (s)",`
			`"Timestep duration (ms)", true, false, m_pointSize,`
			`[] { ImPlot::SetupAxisLimits(ImAxis_Y1, 0, 50); });`

			`return true;`
			`}`

			`AnalyzerPlot::FilteredDataVsTimePlot::FilteredDataVsTimePlot() {`
			`rawData.reserve(kMaxSize);`
			`filteredData.reserve(kMaxSize);`
			`simData.reserve(kMaxSize);`
			`}`

			`void AnalyzerPlot::FilteredDataVsTimePlot::Plot(const char* title,`
			`const ImVec2& size,`
			`const char* yLabel,`
			`float pointSize) {`
			`// Generate Sim vs Filtered Plot`
			`if (fitNextPlot) {`
			`ImPlot::SetNextAxesToFit();`
			`}`

			`if (ImPlot::BeginPlot(title, size)) {`
			`ImPlot::SetupAxis(ImAxis_X1, "Time (s)", ImPlotAxisFlags_NoGridLines);`
			`ImPlot::SetupAxis(ImAxis_Y1, yLabel, ImPlotAxisFlags_NoGridLines);`
			`ImPlot::SetupLegend(ImPlotLocation_NorthEast);`

			`// Plot Raw Data`
			`ImPlot::SetNextMarkerStyle(IMPLOT_AUTO, 1, IMPLOT_AUTO_COL, 0);`
			`ImPlot::SetNextMarkerStyle(ImPlotStyleVar_MarkerSize, pointSize);`
			`ImPlot::PlotScatterG("Raw Data", Getter, rawData.data(), rawData.size());`

			`// Plot Filtered Data after Raw data`
			`ImPlot::SetNextMarkerStyle(IMPLOT_AUTO, 1, IMPLOT_AUTO_COL, 0);`
			`ImPlot::SetNextMarkerStyle(ImPlotStyleVar_MarkerSize, pointSize);`
			`ImPlot::PlotScatterG("Filtered Data", Getter, filteredData.data(),`
			`filteredData.size());`

			`// Plot Simulation Data for Velocity Data`
			`PlotSimData(simData);`

			`// Disable constant resizing`
			`if (fitNextPlot) {`
			`fitNextPlot = false;`
			`}`

			`ImPlot::EndPlot();`
			`}`
			`}`

			`void AnalyzerPlot::FilteredDataVsTimePlot::Clear() {`
			`rawData.clear();`
			`filteredData.clear();`
			`simData.clear();`
			`}`

			`AnalyzerPlot::DataWithFitLinePlot::DataWithFitLinePlot() {`
			`data.reserve(kMaxSize);`
			`}`

			`void AnalyzerPlot::DataWithFitLinePlot::Plot(const char* title,`
			`const ImVec2& size,`
			`const char* xLabel,`
			`const char* yLabel, bool fitX,`
			`bool fitY, float pointSize,`
			`std::function<void()> setup) {`
			`if (fitNextPlot) {`
			`if (fitX && fitY) {`
			`ImPlot::SetNextAxesToFit();`
			`} else if (fitX && !fitY) {`
			`ImPlot::SetNextAxisToFit(ImAxis_X1);`
			`} else if (!fitX && fitY) {`
			`ImPlot::SetNextAxisToFit(ImAxis_Y1);`
			`}`
			`}`

			`if (ImPlot::BeginPlot(title, size)) {`
			`setup();`
			`ImPlot::SetupAxis(ImAxis_X1, xLabel, ImPlotAxisFlags_NoGridLines);`
			`ImPlot::SetupAxis(ImAxis_Y1, yLabel, ImPlotAxisFlags_NoGridLines);`
			`ImPlot::SetupLegend(ImPlotLocation_NorthEast);`

			`// Get a reference to the data that we are plotting.`
			`ImPlot::SetNextMarkerStyle(IMPLOT_AUTO, 1, IMPLOT_AUTO_COL, 0);`
			`ImPlot::SetNextMarkerStyle(ImPlotStyleVar_MarkerSize, pointSize);`
			`ImPlot::PlotScatterG("Filtered Data", Getter, data.data(), data.size());`

			`ImPlot::SetNextLineStyle(IMPLOT_AUTO_COL, 1.5);`
			`ImPlot::PlotLineG("Fit", Getter, fitLine.data(), fitLine.size());`

			`ImPlot::EndPlot();`

			`if (fitNextPlot) {`
			`fitNextPlot = false;`
			`}`
			`}`
			`}`

			`void AnalyzerPlot::DataWithFitLinePlot::Clear() {`
			`data.clear();`

			`// Reset line of best fit`
			`fitLine[0] = ImPlotPoint{0, 0};`
			`fitLine[1] = ImPlotPoint{0, 0};`
			`}`