openarm_teleop/control/openarm_unilateral_control.cpp

// Copyright 2025 Enactic, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

#include <atomic>
#include <chrono>
#include <controller/control.hpp>
#include <controller/dynamics.hpp>
#include <csignal>
#include <filesystem>
#include <iostream>
#include <openarm/can/socket/openarm.hpp>
#include <openarm/damiao_motor/dm_motor_constants.hpp>
#include <openarm_port/openarm_init.hpp>
#include <periodic_timer_thread.hpp>
#include <robot_state.hpp>
#include <thread>
#include <yamlloader.hpp>

std::atomic<bool> keep_running(true);

void signal_handler(int signal) {
    if (signal == SIGINT) {
        std::cout << "\nCtrl+C detected. Exiting loop..." << std::endl;
        keep_running = false;
    }
}

class LeaderArmThread : public PeriodicTimerThread {
public:
    LeaderArmThread(std::shared_ptr<RobotSystemState> robot_state, Control *control_l,
                    double hz = 500.0)
        : PeriodicTimerThread(hz), robot_state_(robot_state), control_l_(control_l) {}

protected:
    void before_start() override { std::cout << "leader start thread " << std::endl; }

    void after_stop() override { std::cout << "leader stop thread " << std::endl; }

    void on_timer() override {
        static auto prev_time = std::chrono::steady_clock::now();

        control_l_->unilateral_step();

        auto now = std::chrono::steady_clock::now();

        auto elapsed_us =
            std::chrono::duration_cast<std::chrono::microseconds>(now - prev_time).count();
        prev_time = now;

        // std::cout << "[Leader] Period: " << elapsed_us << " us" << std::endl;
    }

private:
    std::shared_ptr<RobotSystemState> robot_state_;
    Control *control_l_;
};

class FollowerArmThread : public PeriodicTimerThread {
public:
    FollowerArmThread(std::shared_ptr<RobotSystemState> robot_state, Control *control_f,
                      double hz = 500.0)
        : PeriodicTimerThread(hz), robot_state_(robot_state), control_f_(control_f) {}

protected:
    void before_start() override { std::cout << "follower start thread " << std::endl; }

    void after_stop() override { std::cout << "follower stop thread " << std::endl; }

    void on_timer() override {
        static auto prev_time = std::chrono::steady_clock::now();

        control_f_->unilateral_step();

        auto now = std::chrono::steady_clock::now();

        auto elapsed_us =
            std::chrono::duration_cast<std::chrono::microseconds>(now - prev_time).count();
        prev_time = now;

        // std::cout << "[Follower] Period: " << elapsed_us << " us" << std::endl;
    }

private:
    std::shared_ptr<RobotSystemState> robot_state_;
    Control *control_f_;
};

class AdminThread : public PeriodicTimerThread {
public:
    AdminThread(std::shared_ptr<RobotSystemState> leader_state,
                std::shared_ptr<RobotSystemState> follower_state, Control *control_l,
                Control *control_f, double hz = 500.0)
        : PeriodicTimerThread(hz),
          leader_state_(leader_state),
          follower_state_(follower_state),
          control_l_(control_l),
          control_f_(control_f) {}

protected:
    void before_start() override { std::cout << "admin start thread " << std::endl; }

    void after_stop() override { std::cout << "admin stop thread " << std::endl; }

    void on_timer() override {
        static auto prev_time = std::chrono::steady_clock::now();
        auto now = std::chrono::steady_clock::now();

        // get response
        auto leader_arm_resp = leader_state_->arm_state().get_all_responses();
        auto follower_arm_resp = follower_state_->arm_state().get_all_responses();

        auto leader_hand_resp = leader_state_->hand_state().get_all_responses();
        auto follower_hand_resp = follower_state_->hand_state().get_all_responses();

        // set referense
        leader_state_->arm_state().set_all_references(follower_arm_resp);
        leader_state_->hand_state().set_all_references(follower_hand_resp);

        follower_state_->arm_state().set_all_references(leader_arm_resp);
        follower_state_->hand_state().set_all_references(leader_hand_resp);

        auto elapsed_us =
            std::chrono::duration_cast<std::chrono::microseconds>(now - prev_time).count();
        prev_time = now;

        // std::cout << "[Admin] Period: " << elapsed_us << " us" << std::endl;
    }

private:
    std::shared_ptr<RobotSystemState> leader_state_;
    std::shared_ptr<RobotSystemState> follower_state_;
    Control *control_l_;
    Control *control_f_;
};

int main(int argc, char **argv) {
    try {
        std::signal(SIGINT, signal_handler);

        // default configration
        std::string arm_side = "right_arm";
        std::string leader_urdf_path;
        std::string follower_urdf_path;
        std::string leader_can_interface = "can0";
        std::string follower_can_interface = "can2";

        if (argc < 3) {
            std::cerr
                << "Usage: " << argv[0]
                << " <leader_urdf_path> <follower_urdf_path> [arm_side] [leader_can] [follower_can]"
                << std::endl;
            return 1;
        }

        // Required: URDF paths
        leader_urdf_path = argv[1];
        follower_urdf_path = argv[2];

        // Optional: arm_side
        if (argc >= 4) {
            arm_side = argv[3];
            if (arm_side != "left_arm" && arm_side != "right_arm") {
                std::cerr << "[ERROR] Invalid arm_side: " << arm_side
                          << ". Must be 'left_arm' or 'right_arm'." << std::endl;
                return 1;
            }
        }

        // Optional: CAN interfaces
        if (argc >= 6) {
            leader_can_interface = argv[4];
            follower_can_interface = argv[5];
        }

        // URDF file existence check
        if (!std::filesystem::exists(leader_urdf_path)) {
            std::cerr << "[ERROR] Leader URDF not found: " << leader_urdf_path << std::endl;
            return 1;
        }
        if (!std::filesystem::exists(follower_urdf_path)) {
            std::cerr << "[ERROR] Follower URDF not found: " << follower_urdf_path << std::endl;
            return 1;
        }

        // Setup dynamics
        std::string root_link = "openarm_body_link0";
        std::string leaf_link =
            (arm_side == "left_arm") ? "openarm_left_hand" : "openarm_right_hand";

        // Output confirmation
        std::cout << "=== OpenArm Unilateral Control ===" << std::endl;
        std::cout << "Arm side         : " << arm_side << std::endl;
        std::cout << "Leader CAN       : " << leader_can_interface << std::endl;
        std::cout << "Follower CAN     : " << follower_can_interface << std::endl;
        std::cout << "Leader URDF path : " << leader_urdf_path << std::endl;
        std::cout << "Follower URDF path: " << follower_urdf_path << std::endl;
        std::cout << "Root link         : " << root_link << std::endl;
        std::cout << "Leaf link         : " << leaf_link << std::endl;

        YamlLoader leader_loader("config/leader.yaml");
        YamlLoader follower_loader("config/follower.yaml");

        // Leader parameters
        std::vector<double> leader_kp = leader_loader.get_vector("LeaderArmParam", "Kp");
        std::vector<double> leader_kd = leader_loader.get_vector("LeaderArmParam", "Kd");
        std::vector<double> leader_Fc = leader_loader.get_vector("LeaderArmParam", "Fc");
        std::vector<double> leader_k = leader_loader.get_vector("LeaderArmParam", "k");
        std::vector<double> leader_Fv = leader_loader.get_vector("LeaderArmParam", "Fv");
        std::vector<double> leader_Fo = leader_loader.get_vector("LeaderArmParam", "Fo");

        // Follower parameters
        std::vector<double> follower_kp = follower_loader.get_vector("FollowerArmParam", "Kp");
        std::vector<double> follower_kd = follower_loader.get_vector("FollowerArmParam", "Kd");
        std::vector<double> follower_Fc = follower_loader.get_vector("FollowerArmParam", "Fc");
        std::vector<double> follower_k = follower_loader.get_vector("FollowerArmParam", "k");
        std::vector<double> follower_Fv = follower_loader.get_vector("FollowerArmParam", "Fv");
        std::vector<double> follower_Fo = follower_loader.get_vector("FollowerArmParam", "Fo");

        Dynamics *leader_arm_dynamics = new Dynamics(leader_urdf_path, root_link, leaf_link);
        leader_arm_dynamics->Init();

        Dynamics *follower_arm_dynamics = new Dynamics(follower_urdf_path, root_link, leaf_link);
        follower_arm_dynamics->Init();

        std::cout << "=== Initializing Leader OpenArm ===" << std::endl;
        openarm::can::socket::OpenArm *leader_openarm =
            openarm_init::OpenArmInitializer::initialize_openarm(leader_can_interface, true);

        std::cout << "=== Initializing Follower OpenArm ===" << std::endl;
        openarm::can::socket::OpenArm *follower_openarm =
            openarm_init::OpenArmInitializer::initialize_openarm(follower_can_interface, true);

        size_t leader_arm_motor_num = leader_openarm->get_arm().get_motors().size();
        size_t follower_arm_motor_num = follower_openarm->get_arm().get_motors().size();
        size_t leader_hand_motor_num = leader_openarm->get_gripper().get_motors().size();
        size_t follower_hand_motor_num = follower_openarm->get_gripper().get_motors().size();

        std::cout << "leader arm motor num : " << leader_arm_motor_num << std::endl;
        std::cout << "follower arm motor num : " << follower_arm_motor_num << std::endl;
        std::cout << "leader hand motor num : " << leader_hand_motor_num << std::endl;
        std::cout << "follower hand motor num : " << follower_hand_motor_num << std::endl;

        // Declare robot_state (Joint and motor counts are assumed to be equal)
        std::shared_ptr<RobotSystemState> leader_state =
            std::make_shared<RobotSystemState>(leader_arm_motor_num, leader_hand_motor_num);

        std::shared_ptr<RobotSystemState> follower_state =
            std::make_shared<RobotSystemState>(follower_arm_motor_num, follower_hand_motor_num);

        Control *control_leader = new Control(
            leader_openarm, leader_arm_dynamics, follower_arm_dynamics, leader_state,
            1.0 / FREQUENCY, ROLE_LEADER, arm_side, leader_arm_motor_num, leader_hand_motor_num);
        Control *control_follower =
            new Control(follower_openarm, leader_arm_dynamics, follower_arm_dynamics,
                        follower_state, 1.0 / FREQUENCY, ROLE_FOLLOWER, arm_side,
                        follower_arm_motor_num, follower_hand_motor_num);

        control_leader->SetParameter(leader_kp, leader_kd, leader_Fc, leader_k, leader_Fv,
                                     leader_Fo);

        control_follower->SetParameter(follower_kp, follower_kd, follower_Fc, follower_k,
                                       follower_Fv, follower_Fo);

        // set home postion
        std::thread thread_l(&Control::AdjustPosition, control_leader);
        std::thread thread_f(&Control::AdjustPosition, control_follower);
        thread_l.join();
        thread_f.join();

        // Start control process
        LeaderArmThread leader_thread(leader_state, control_leader, FREQUENCY);
        FollowerArmThread follower_thread(follower_state, control_follower, FREQUENCY);
        AdminThread admin_thread(leader_state, follower_state, control_leader, control_follower,
                                 FREQUENCY);

        leader_thread.start_thread();
        follower_thread.start_thread();
        admin_thread.start_thread();

        while (keep_running) {
            std::this_thread::sleep_for(std::chrono::milliseconds(100));
        }

        leader_thread.stop_thread();
        follower_thread.stop_thread();
        admin_thread.stop_thread();

        leader_openarm->disable_all();
        follower_openarm->disable_all();

    } catch (const std::exception &e) {
        std::cerr << e.what() << '\n';
    }

    return 0;
}