#pragma once #define CMDID(cmdid, cmdSubId) ((cmdid << 8) + cmdSubId) namespace iflytop { namespace zcr { typedef enum { #if 0 virtual int32_t board_reset() = 0; #endif kboard_reset = CMDID(0, 0), // para:{}, ack:{} kevent_bus_reg_change_report = CMDID(0, 100), // para:{}, ack:{} #if 0 virtual int32_t module_get_state(int32_t state_id, int32_t *state_value) { return err::koperation_not_support; } virtual int32_t module_read_raw(int32_t startadd, int32_t *data, int32_t *len) { return err::koperation_not_support; } virtual int32_t module_enable(int32_t enable) { return err::koperation_not_support; } virtual int32_t module_start() { return err::koperation_not_support; } #endif kmodule_ping = CMDID(1, 0), // para:{}, ack:{} kmodule_stop = CMDID(1, 1), // para:{}, ack:{} kmodule_break = CMDID(1, 2), // para:{}, ack:{} kmodule_get_last_exec_status = CMDID(1, 3), // para:{}, ack:{4} kmodule_get_status = CMDID(1, 4), // para:{}, ack:{4} kmodule_set_reg = CMDID(1, 5), // para:{4,4}, ack:{} kmodule_get_reg = CMDID(1, 6), // para:{4}, ack:{4}I kmodule_readio = CMDID(1, 7), // para:{}, ack:{4} kmodule_writeio = CMDID(1, 8), // para:{4}, ack:{} kmodule_read_adc = CMDID(1, 9), // para:{4}, ack:{4} kmodule_get_error = CMDID(1, 10), // para:{}, ack:{1} kmodule_clear_error = CMDID(1, 11), // para:{}, ack:{} kmodule_set_inited_flag = CMDID(1, 12), // para:{4}, ack:{} kmodule_get_inited_flag = CMDID(1, 13), // para:{}, ack:{4} kmodule_factory_reset = CMDID(1, 14), // para:{}, ack:{} kmodule_flush_cfg = CMDID(1, 15), // para:{}, ack:{} kmodule_active_cfg = CMDID(1, 16), // para:{}, ack:{} kmodule_read_raw = CMDID(1, 19), // para:{4,4}, ack:{4} kmodule_enable = CMDID(1, 20), // para:{4}, ack:{} kmodule_start = CMDID(1, 21), // para:{4}, ack:{} #if 0 virtual int32_t motor_enable(int32_t enable) { return err::koperation_not_support; } virtual int32_t motor_rotate(int32_t direction, int32_t motor_velocity, int32_t acc) { return err::koperation_not_support; } virtual int32_t motor_move_by(int32_t distance, int32_t motor_velocity, int32_t acc) { return err::koperation_not_support; } virtual int32_t motor_move_to(int32_t position, int32_t motor_velocity, int32_t acc) { return err::koperation_not_support; } virtual int32_t motor_rotate_acctime(int32_t direction, int32_t motor_velocity, int32_t acctime) { return err::koperation_not_support; } virtual int32_t motor_move_by_acctime(int32_t distance, int32_t motor_velocity, int32_t acctime) { return err::koperation_not_support; } virtual int32_t motor_move_to_acctime(int32_t position, int32_t motor_velocity, int32_t acctime) { return err::koperation_not_support; } virtual int32_t motor_rotate_with_torque(int32_t direction, int32_t torque) { return err::koperation_not_support; } virtual int32_t motor_move_to_torque(int32_t pos, int32_t torque, int32_t overtime) { return err::koperation_not_support; } virtual int32_t motor_move_to_zero_forward(int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime) { return err::koperation_not_support; } virtual int32_t motor_move_to_zero_backward(int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime) { return err::koperation_not_support; } virtual int32_t motor_move_to_zero_forward_and_calculated_shift(int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime) { return err::koperation_not_support; } virtual int32_t motor_move_to_zero_backward_and_calculated_shift(int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime) { return err::koperation_not_support; } virtual int32_t motor_read_pos(int32_t* pos) { return err::koperation_not_support; } virtual int32_t motor_set_current_pos_by_change_shift(int32_t pos) { return err::koperation_not_support; } // Ò»°ãÓÃÓÚ¶æ»ú virtual int32_t motor_easy_rotate(int32_t direction) { return err::koperation_not_support; }; virtual int32_t motor_easy_move_by(int32_t distance) { return err::koperation_not_support; }; virtual int32_t motor_easy_move_to(int32_t position) { return err::koperation_not_support; }; virtual int32_t motor_easy_move_to_zero(int32_t direction) { return err::koperation_not_support; }; virtual int32_t motor_easy_move_to_io(int32_t ioindex, int32_t direction) { return err::koperation_not_support; }; #endif kmotor_enable = CMDID(2, 1), // para:{1}, ack:{} kmotor_rotate = CMDID(2, 2), // para:{1,4}, ack:{} kmotor_move_by = CMDID(2, 3), // para:{4,4}, ack:{} kmotor_move_to = CMDID(2, 4), // para:{4,4}, ack:{} kmotor_rotate_acctime = CMDID(2, 5), // para:{4,4}, ack:{} kmotor_move_by_acctime = CMDID(2, 6), // para:{4,4}, ack:{} kmotor_move_to_acctime = CMDID(2, 7), // para:{4,4}, ack:{} kmotor_rotate_with_torque = CMDID(2, 8), // para:{4,4}, ack:{} kmotor_move_to_zero_forward = CMDID(2, 9), // para:{4,4,4,4}, ack:{} //int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime kmotor_move_to_zero_backward = CMDID(2, 10), // para:{4,4,4,4}, ack:{} //int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime kmotor_read_pos = CMDID(2, 11), // para:{}, ack:{4} kmotor_set_current_pos_by_change_shift = CMDID(2, 12), // para:{4}, ack:{} kmotor_motor_move_to_zero_forward_and_calculated_shift = CMDID(2, 13), // para:{4,4,4,4}, ack:{} //int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime kmotor_motor_move_to_zero_backward_and_calculated_shift = CMDID(2, 14), // para:{4,4,4,4}, ack:{} //int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime kmotor_move_to_torque = CMDID(2, 15), // para:{4,4,4}, ack:{} kmotor_calculated_pos_by_move_to_zero = CMDID(2, 16), // para:{}, ack:{} kmotor_easy_rotate = CMDID(2, 17), // para:{4}, ack:{} kmotor_easy_move_by = CMDID(2, 18), // para:{4}, ack:{} kmotor_easy_move_to = CMDID(2, 19), // para:{4}, ack:{} kmotor_easy_move_to_zero = CMDID(2, 20), // para:{1}, ack:{} kmotor_easy_set_current_pos = CMDID(2, 21), // para:{4}, ack:{} kmotor_easy_move_to_io = CMDID(2, 22), // para:{4,4}, ack:{} #if 0 virtual ~ZIXYMotor() {} virtual int32_t xymotor_enable(int32_t enable) { return err::koperation_not_support; } virtual int32_t xymotor_move_by(int32_t dx, int32_t dy, int32_t motor_velocity) { return err::koperation_not_support; } virtual int32_t xymotor_move_to(int32_t x, int32_t y, int32_t motor_velocity) { return err::koperation_not_support; } virtual int32_t xymotor_move_to_zero() { return err::koperation_not_support; } virtual int32_t xymotor_move_to_zero_and_calculated_shift() { return err::koperation_not_support; } virtual int32_t xymotor_read_pos(int32_t *x, int32_t *y) { return err::koperation_not_support; } virtual int32_t xymotor_calculated_pos_by_move_to_zero() { return err::koperation_not_support; } #endif kxymotor_enable = CMDID(3, 1), // para:{1}, ack:{} kxymotor_move_by = CMDID(3, 2), // para:{4,4,4}, ack:{} kxymotor_move_to = CMDID(3, 3), // para:{4,4,4}, ack:{} kxymotor_move_to_zero = CMDID(3, 4), // para:{}, ack:{} kxymotor_move_to_zero_and_calculated_shift = CMDID(3, 5), // para:{4,4,4,4}, ack:{} //int32_t findzerospeed, int32_t findzeroedge_speed, int32_t acc, int32_t overtime kxymotor_read_pos = CMDID(3, 6), // para:{}, ack:{4,4} kxymotor_calculated_pos_by_move_to_zero = CMDID(3, 7), // para:{}, ack:{} #if 0 virtual int32_t code_scaner_start_scan() { return err::koperation_not_support; } virtual int32_t code_scaner_stop_scan() { return err::koperation_not_support; } virtual int32_t code_scaner_read_scaner_result(int32_t startadd, uint8_t *data, int32_t *len) { return err::koperation_not_support; } #endif kcode_scaner_start_scan = CMDID(4, 1), // para:{}, ack:{} kcode_scaner_stop_scan = CMDID(4, 2), // para:{}, ack:{} kcode_scaner_read_scaner_result = CMDID(4, 3), // para:{4,4}, ack:{4} #if 0 virtual int32_t pipette_ctrl_init_device() { return err::koperation_not_support; }; virtual int32_t pipette_ctrl_put_tip() { return err::koperation_not_support; }; virtual int32_t pipette_ctrl_move_to_ul(int32_t ul) { return err::koperation_not_support; }; #endif kpipette_ctrl_init_device = CMDID(5, 1), // para:{}, ack:{} kpipette_ctrl_put_tip = CMDID(5, 2), // para:{}, ack:{} kpipette_ctrl_move_to_ul = CMDID(5, 3), // para:{4}, ack:{} #if 0 virtual int32_t a8000_optical_module_power_ctrl(int32_t state) = 0; virtual int32_t a8000_optical_open_laser(int32_t type) = 0; virtual int32_t a8000_optical_close_laser(int32_t type) = 0; virtual int32_t a8000_optical_set_laster_gain(int32_t type, int32_t gain) = 0; virtual int32_t a8000_optical_set_scan_amp_gain(int32_t type, int32_t gain) = 0; virtual int32_t a8000_optical_read_scanner_adc_val(int32_t type, int32_t* adcval) = 0; virtual int32_t a8000_optical_read_laster_adc_val(int32_t type, int32_t* adcval) = 0; virtual int32_t a8000_optical_scan_current_point_amp_adc_val(int32_t type, int32_t lastergain, int32_t ampgain, int32_t* laster_fb_val, int32_t* adcval) = 0; #endif ka8000_optical_module_power_ctrl = CMDID(6, 0), // para:{4}, ack:{} ka8000_optical_open_laser = CMDID(6, 1), // para:{4}, ack:{} ka8000_optical_close_laser = CMDID(6, 2), // para:{4}, ack:{} ka8000_optical_set_laster_gain = CMDID(6, 3), // para:{4,4}, ack:{} ka8000_optical_set_scan_amp_gain = CMDID(6, 4), // para:{4,4}, ack:{} ka8000_optical_read_scanner_adc_val = CMDID(6, 5), // para:{4}, ack:{4} ka8000_optical_read_laster_adc_val = CMDID(6, 6), // para:{4}, ack:{4} ka8000_optical_scan_current_point_amp_adc_val = CMDID(6, 7), // para:{4,4,4,4}, ack:{4,4} } cmdid_t; } // namespace zcr } // namespace iflytop