/*
   This program is free software: you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
/*
  implementation of MSP and BLHeli-4way protocols for pass-through ESC
  calibration and firmware update

  With thanks to betaflight for a great reference implementation
 */

#pragma once

#include <AP_Common/AP_Common.h>
#include <AP_HAL/AP_HAL.h>

#if HAL_SUPPORT_RCOUT_SERIAL

#define HAVE_AP_BLHELI_SUPPORT

#include <AP_Param/AP_Param.h>
#include "msp_protocol.h"
#include "blheli_4way_protocol.h"

#define AP_BLHELI_MAX_ESCS 8

class AP_BLHeli {

public:
    AP_BLHeli();
    
    void update(void);
    void update_telemetry(void);
    bool process_input(uint8_t b);

    static const struct AP_Param::GroupInfo var_info[];

    struct telem_data {
        uint8_t temperature; // degrees C
        uint16_t voltage;    // volts * 100
        uint16_t current;    // amps * 100
        uint16_t consumption;// mAh
        uint16_t rpm;        // eRPM
        uint16_t count;
        uint32_t timestamp_ms;
    };

    // get the most recent telemetry data packet for a motor
    bool get_telem_data(uint8_t esc_index, struct telem_data &td);

    static AP_BLHeli *get_singleton(void) {
        return _singleton;
    }

    // send ESC telemetry messages over MAVLink
    void send_esc_telemetry_mavlink(uint8_t mav_chan);
    
private:
    static AP_BLHeli *_singleton;
    
    // mask of channels to use for BLHeli protocol
    AP_Int32 channel_mask;
    AP_Int32 channel_reversible_mask;
    AP_Int8 channel_auto;
    AP_Int8 run_test;
    AP_Int16 timeout_sec;
    AP_Int16 telem_rate;
    AP_Int8 debug_level;
    AP_Int8 output_type;
    AP_Int8 control_port;
    AP_Int8 motor_poles;
    
    enum mspState {
        MSP_IDLE=0,
        MSP_HEADER_START,
        MSP_HEADER_M,
        MSP_HEADER_ARROW,
        MSP_HEADER_SIZE,
        MSP_HEADER_CMD,
        MSP_COMMAND_RECEIVED
    };

    enum mspPacketType {
        MSP_PACKET_COMMAND,
        MSP_PACKET_REPLY
    };

    enum escProtocol {
        PROTOCOL_SIMONK = 0,
        PROTOCOL_BLHELI = 1,
        PROTOCOL_KISS = 2,
        PROTOCOL_KISSALL = 3,
        PROTOCOL_CASTLE = 4,
        PROTOCOL_MAX = 5,
        PROTOCOL_NONE = 0xfe,
        PROTOCOL_4WAY = 0xff
    };

    enum motorPwmProtocol {
        PWM_TYPE_STANDARD = 0,
        PWM_TYPE_ONESHOT125,
        PWM_TYPE_ONESHOT42,
        PWM_TYPE_MULTISHOT,
        PWM_TYPE_BRUSHED,
        PWM_TYPE_DSHOT150,
        PWM_TYPE_DSHOT300,
        PWM_TYPE_DSHOT600,
        PWM_TYPE_DSHOT1200,
        PWM_TYPE_PROSHOT1000,
    };

    enum MSPFeatures {
        FEATURE_RX_PPM = 1 << 0,
        FEATURE_INFLIGHT_ACC_CAL = 1 << 2,
        FEATURE_RX_SERIAL = 1 << 3,
        FEATURE_MOTOR_STOP = 1 << 4,
        FEATURE_SERVO_TILT = 1 << 5,
        FEATURE_SOFTSERIAL = 1 << 6,
        FEATURE_GPS = 1 << 7,
        FEATURE_RANGEFINDER = 1 << 9,
        FEATURE_TELEMETRY = 1 << 10,
        FEATURE_3D = 1 << 12,
        FEATURE_RX_PARALLEL_PWM = 1 << 13,
        FEATURE_RX_MSP = 1 << 14,
        FEATURE_RSSI_ADC = 1 << 15,
        FEATURE_LED_STRIP = 1 << 16,
        FEATURE_DASHBOARD = 1 << 17,
        FEATURE_OSD = 1 << 18,
        FEATURE_CHANNEL_FORWARDING = 1 << 20,
        FEATURE_TRANSPONDER = 1 << 21,
        FEATURE_AIRMODE = 1 << 22,
        FEATURE_RX_SPI = 1 << 25,
        FEATURE_SOFTSPI = 1 << 26,
        FEATURE_ESC_SENSOR = 1 << 27,
        FEATURE_ANTI_GRAVITY = 1 << 28,
        FEATURE_DYNAMIC_FILTER = 1 << 29,
    };


    /*
      state of MSP command processing
    */
    struct {
        enum mspState state;
        enum mspPacketType packetType;
        uint8_t offset;
        uint8_t dataSize;
        uint8_t checksum;
        uint8_t buf[192];
        uint8_t cmdMSP;
        enum escProtocol escMode;
        uint8_t portIndex;
    } msp;

    enum blheliState {
        BLHELI_IDLE=0,
        BLHELI_HEADER_START,
        BLHELI_HEADER_CMD,
        BLHELI_HEADER_ADDR_LOW,
        BLHELI_HEADER_ADDR_HIGH,
        BLHELI_HEADER_LEN,
        BLHELI_CRC1,
        BLHELI_CRC2,
        BLHELI_COMMAND_RECEIVED
    };

    /*
      state of blheli 4way protocol handling
    */
    struct {
        enum blheliState state;
        uint8_t command;
        uint16_t address;
        uint16_t param_len;
        uint16_t offset;
        uint8_t buf[256+3+8];
        uint8_t crc1;
        uint16_t crc;
        bool connected[AP_BLHELI_MAX_ESCS];
        uint8_t interface_mode[AP_BLHELI_MAX_ESCS];
        uint8_t deviceInfo[AP_BLHELI_MAX_ESCS][4];
        uint8_t chan;
        uint8_t ack;
    } blheli;

    const uint16_t esc_status_addr = 0xEB00;
    
    // protocol reported by ESC in esc_status
    enum esc_protocol {
        ESC_PROTOCOL_NONE=0,
        ESC_PROTOCOL_NORMAL=1,
        ESC_PROTOCOL_ONESHOT125=2,
        ESC_PROTOCOL_DSHOT=5,
    };
    
    // ESC status structure at address 0xEB00
    struct PACKED esc_status {
        uint8_t unknown[3];
        enum esc_protocol protocol;
        uint32_t good_frames;
        uint32_t bad_frames;
        uint32_t unknown2;
    };
    
    
    AP_HAL::UARTDriver *uart;
    AP_HAL::UARTDriver *debug_uart;
    AP_HAL::UARTDriver *telem_uart;    
    
    static const uint8_t max_motors = AP_BLHELI_MAX_ESCS;
    uint8_t num_motors;

    struct telem_data last_telem[max_motors];

    // have we initialised the interface?
    bool initialised;

    // last valid packet timestamp
    uint32_t last_valid_ms;

    // when did we start the serial ESC output?
    uint32_t serial_start_ms;

    // have we disabled motor outputs?
    bool motors_disabled;

    // have we locked the UART?
    bool uart_locked;

    // mapping from BLHeli motor numbers to RC output channels
    uint8_t motor_map[max_motors];
    uint16_t motor_mask;

    // when did we last request telemetry?
    uint32_t last_telem_request_us;
    uint8_t last_telem_esc;
    static const uint8_t telem_packet_size = 10;
    bool telem_uart_started;
    uint32_t last_telem_byte_read_us;
    int8_t last_control_port;

    bool msp_process_byte(uint8_t c);
    void blheli_crc_update(uint8_t c);
    bool blheli_4way_process_byte(uint8_t c);
    void msp_send_reply(uint8_t cmd, const uint8_t *buf, uint8_t len);
    void putU16(uint8_t *b, uint16_t v);
    uint16_t getU16(const uint8_t *b);
    void putU32(uint8_t *b, uint32_t v);
    void putU16_BE(uint8_t *b, uint16_t v);
    void msp_process_command(void);
    void blheli_send_reply(const uint8_t *buf, uint16_t len);
    uint16_t BL_CRC(const uint8_t *buf, uint16_t len);
    bool isMcuConnected(void);
    void setDisconnected(void);
    bool BL_SendBuf(const uint8_t *buf, uint16_t len);
    bool BL_ReadBuf(uint8_t *buf, uint16_t len);
    uint8_t BL_GetACK(uint16_t timeout_ms=2);
    bool BL_SendCMDSetAddress();
    bool BL_ReadA(uint8_t cmd, uint8_t *buf, uint16_t n);
    bool BL_ConnectEx(void);
    bool BL_SendCMDKeepAlive(void);
    bool BL_PageErase(void);
    void BL_SendCMDRunRestartBootloader(void);
    uint8_t BL_SendCMDSetBuffer(const uint8_t *buf, uint16_t nbytes);
    bool BL_WriteA(uint8_t cmd, const uint8_t *buf, uint16_t nbytes, uint32_t timeout);
    uint8_t BL_WriteFlash(const uint8_t *buf, uint16_t n);
    bool BL_VerifyFlash(const uint8_t *buf, uint16_t n);
    void blheli_process_command(void);
    void run_connection_test(uint8_t chan);
    uint8_t telem_crc8(uint8_t crc, uint8_t crc_seed) const;
    void read_telemetry_packet(void);
    
    // protocol handler hook
    bool protocol_handler(uint8_t , AP_HAL::UARTDriver *);
};

#endif // HAL_SUPPORT_RCOUT_SERIAL