Ben Katz
SPI to quad CAN firmware
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Teleop_Controller
by 
Ben Katz
main.cpp
- Committer:
- benkatz
- Date:
- 2019-10-04
- Revision:
- 9:56747e76c9c1
- Parent:
- 7:f10513577d4c
File content as of revision 9:56747e76c9c1:
#include "mbed.h"
#include "math_ops.h"
#include <cstring>
#include "leg_message.h"
// length of receive/transmit buffers
#define RX_LEN 66
#define TX_LEN 66
// length of outgoing/incoming messages
#define DATA_LEN 30
#define CMD_LEN 66
// Master CAN ID ///
#define CAN_ID 0x0
/// Value Limits ///
#define P_MIN -12.5f
#define P_MAX 12.5f
#define V_MIN -65.0f
#define V_MAX 65.0f
#define KP_MIN 0.0f
#define KP_MAX 500.0f
#define KD_MIN 0.0f
#define KD_MAX 5.0f
#define T_MIN -18.0f
#define T_MAX 18.0f
/// Joint Soft Stops ///
#define A_LIM_P 1.5f
#define A_LIM_N -1.5f
#define H_LIM_P 5.0f
#define H_LIM_N -5.0f
#define K_LIM_P 0.2f
#define K_LIM_N 7.7f
#define KP_SOFTSTOP 100.0f
#define KD_SOFTSTOP 0.4f;
#define ENABLE_CMD 0xFFFF
#define DISABLE_CMD 0x1F1F
spi_data_t spi_data; // data from spine to up
spi_command_t spi_command; // data from up to spine
// spi buffers
uint16_t rx_buff[RX_LEN];
uint16_t tx_buff[TX_LEN];
DigitalOut led(PC_5);
Serial pc(PA_2, PA_3);
CAN can1(PB_12, PB_13, 1000000); // CAN Rx pin name, CAN Tx pin name
CAN can2(PB_8, PB_9, 1000000); // CAN Rx pin name, CAN Tx pin name
CANMessage rxMsg1, rxMsg2;
CANMessage txMsg1, txMsg2;
CANMessage a1_can, a2_can, h1_can, h2_can, k1_can, k2_can; //TX Messages
int ledState;
Ticker sendCAN;
int counter = 0;
volatile bool msgAvailable = false;
Ticker loop;
int spi_enabled = 0;
InterruptIn cs(PA_4);
DigitalIn estop(PB_15);
//SPISlave spi(PA_7, PA_6, PA_5, PA_4);
leg_state l1_state, l2_state;;
leg_control l1_control, l2_control;
uint16_t x = 0;
uint16_t x2 = 0;
uint16_t count = 0;
uint16_t counter2 = 0;
int control_mode = 1;
int is_standing = 0;
int enabled = 0;
// generates fake spi data from spi command
void test_control();
void control();
/// CAN Command Packet Structure ///
/// 16 bit position command, between -4*pi and 4*pi
/// 12 bit velocity command, between -30 and + 30 rad/s
/// 12 bit kp, between 0 and 500 N-m/rad
/// 12 bit kd, between 0 and 100 N-m*s/rad
/// 12 bit feed forward torque, between -18 and 18 N-m
/// CAN Packet is 8 8-bit words
/// Formatted as follows. For each quantity, bit 0 is LSB
/// 0: [position[15-8]]
/// 1: [position[7-0]]
/// 2: [velocity[11-4]]
/// 3: [velocity[3-0], kp[11-8]]
/// 4: [kp[7-0]]
/// 5: [kd[11-4]]
/// 6: [kd[3-0], torque[11-8]]
/// 7: [torque[7-0]]
void pack_cmd(CANMessage * msg, joint_control joint){
/// limit data to be within bounds ///
float p_des = fminf(fmaxf(P_MIN, joint.p_des), P_MAX);
float v_des = fminf(fmaxf(V_MIN, joint.v_des), V_MAX);
float kp = fminf(fmaxf(KP_MIN, joint.kp), KP_MAX);
float kd = fminf(fmaxf(KD_MIN, joint.kd), KD_MAX);
float t_ff = fminf(fmaxf(T_MIN, joint.t_ff), T_MAX);
/// convert floats to unsigned ints ///
uint16_t p_int = float_to_uint(p_des, P_MIN, P_MAX, 16);
uint16_t v_int = float_to_uint(v_des, V_MIN, V_MAX, 12);
uint16_t kp_int = float_to_uint(kp, KP_MIN, KP_MAX, 12);
uint16_t kd_int = float_to_uint(kd, KD_MIN, KD_MAX, 12);
uint16_t t_int = float_to_uint(t_ff, T_MIN, T_MAX, 12);
/// pack ints into the can buffer ///
msg->data[0] = p_int>>8;
msg->data[1] = p_int&0xFF;
msg->data[2] = v_int>>4;
msg->data[3] = ((v_int&0xF)<<4)|(kp_int>>8);
msg->data[4] = kp_int&0xFF;
msg->data[5] = kd_int>>4;
msg->data[6] = ((kd_int&0xF)<<4)|(t_int>>8);
msg->data[7] = t_int&0xff;
}
/// CAN Reply Packet Structure ///
/// 16 bit position, between -4*pi and 4*pi
/// 12 bit velocity, between -30 and + 30 rad/s
/// 12 bit current, between -40 and 40;
/// CAN Packet is 5 8-bit words
/// Formatted as follows. For each quantity, bit 0 is LSB
/// 0: [position[15-8]]
/// 1: [position[7-0]]
/// 2: [velocity[11-4]]
/// 3: [velocity[3-0], current[11-8]]
/// 4: [current[7-0]]
void unpack_reply(CANMessage msg, leg_state * leg){
/// unpack ints from can buffer ///
uint16_t id = msg.data[0];
uint16_t p_int = (msg.data[1]<<8)|msg.data[2];
uint16_t v_int = (msg.data[3]<<4)|(msg.data[4]>>4);
uint16_t i_int = ((msg.data[4]&0xF)<<8)|msg.data[5];
/// convert uints to floats ///
float p = uint_to_float(p_int, P_MIN, P_MAX, 16);
float v = uint_to_float(v_int, V_MIN, V_MAX, 12);
float t = uint_to_float(i_int, -T_MAX, T_MAX, 12);
if(id==1){
leg->a.p = p;
leg->a.v = v;
leg->a.t = t;
}
else if(id==2){
leg->h.p = p;
leg->h.v = v;
leg->h.t = t;
}
else if(id==3){
leg->k.p = p;
leg->k.v = v;
leg->k.t = t;
}
}
void rxISR1() {
can1.read(rxMsg1); // read message into Rx message storage
unpack_reply(rxMsg1, &l1_state);
}
void rxISR2(){
can2.read(rxMsg2);
unpack_reply(rxMsg2, &l2_state);
}
void PackAll(){
pack_cmd(&a1_can, l1_control.a);
pack_cmd(&a2_can, l2_control.a);
pack_cmd(&h1_can, l1_control.h);
pack_cmd(&h2_can, l2_control.h);
pack_cmd(&k1_can, l1_control.k);
pack_cmd(&k2_can, l2_control.k);
}
void WriteAll(){
//toggle = 1;
can1.write(a1_can);
wait(.00002);
can2.write(a2_can);
wait(.00002);
can1.write(h1_can);
wait(.00002);
can2.write(h2_can);
wait(.00002);
can1.write(k1_can);
wait(.00002);
can2.write(k2_can);
wait(.00002);
//toggle = 0;
}
void sendCMD(){
counter ++;
PackAll();
if(counter>100){
printf("%.3f %.3f %.3f %.3f %.3f %.3f\n\r", l1_state.a.p, l1_state.h.p, l1_state.k.p, l2_state.a.p, l2_state.h.p, l2_state.k.p);
counter = 0 ;
}
WriteAll();
}
void Zero(CANMessage * msg){
msg->data[0] = 0xFF;
msg->data[1] = 0xFF;
msg->data[2] = 0xFF;
msg->data[3] = 0xFF;
msg->data[4] = 0xFF;
msg->data[5] = 0xFF;
msg->data[6] = 0xFF;
msg->data[7] = 0xFE;
WriteAll();
}
void EnterMotorMode(CANMessage * msg){
msg->data[0] = 0xFF;
msg->data[1] = 0xFF;
msg->data[2] = 0xFF;
msg->data[3] = 0xFF;
msg->data[4] = 0xFF;
msg->data[5] = 0xFF;
msg->data[6] = 0xFF;
msg->data[7] = 0xFC;
//WriteAll();
}
void ExitMotorMode(CANMessage * msg){
msg->data[0] = 0xFF;
msg->data[1] = 0xFF;
msg->data[2] = 0xFF;
msg->data[3] = 0xFF;
msg->data[4] = 0xFF;
msg->data[5] = 0xFF;
msg->data[6] = 0xFF;
msg->data[7] = 0xFD;
//WriteAll();
}
void serial_isr(){
/// handle keyboard commands from the serial terminal ///
while(pc.readable()){
char c = pc.getc();
//led = !led;
switch(c){
case(27):
//loop.detach();
printf("\n\r exiting motor mode \n\r");
ExitMotorMode(&a1_can);
ExitMotorMode(&a2_can);
ExitMotorMode(&h1_can);
ExitMotorMode(&h2_can);
ExitMotorMode(&k1_can);
ExitMotorMode(&k2_can);
enabled = 0;
break;
case('m'):
printf("\n\r entering motor mode \n\r");
EnterMotorMode(&a1_can);
EnterMotorMode(&a2_can);
EnterMotorMode(&h1_can);
EnterMotorMode(&h2_can);
EnterMotorMode(&k1_can);
EnterMotorMode(&k2_can);
wait(.5);
enabled = 1;
//loop.attach(&sendCMD, .001);
break;
case('s'):
printf("\n\r standing \n\r");
counter2 = 0;
is_standing = 1;
//stand();
break;
case('z'):
printf("\n\r zeroing \n\r");
Zero(&a1_can);
Zero(&a2_can);
Zero(&h1_can);
Zero(&h2_can);
Zero(&k1_can);
Zero(&k2_can);
break;
}
}
WriteAll();
}
uint32_t xor_checksum(uint32_t* data, size_t len)
{
uint32_t t = 0;
for(int i = 0; i < len; i++)
t = t ^ data[i];
return t;
}
void spi_isr(void)
{
GPIOC->ODR |= (1 << 8);
GPIOC->ODR &= ~(1 << 8);
int bytecount = 0;
SPI1->DR = tx_buff[0];
while(cs == 0) {
if(SPI1->SR&0x1) {
rx_buff[bytecount] = SPI1->DR;
bytecount++;
if(bytecount<TX_LEN) {
SPI1->DR = tx_buff[bytecount];
}
}
}
// after reading, save into spi_command
// should probably check checksum first!
uint32_t calc_checksum = xor_checksum((uint32_t*)rx_buff,32);
for(int i = 0; i < CMD_LEN; i++)
{
((uint16_t*)(&spi_command))[i] = rx_buff[i];
}
// run control, which fills in tx_buff for the next iteration
if(calc_checksum != spi_command.checksum){
spi_data.flags[1] = 0xdead;}
//test_control();
//spi_data.q_abad[0] = 12.0f;
control();
PackAll();
WriteAll();
//for (int i = 0; i<TX_LEN; i++) {
// tx_buff[i] = 2*rx_buff[i];
//}
// for (int i=0; i<TX_LEN; i++) {
// //printf("%d ", rx_buff[i]);
// }
//printf("\n\r");
}
int softstop_joint(joint_state state, joint_control * control, float limit_p, float limit_n){
if((state.p)>=limit_p){
//control->p_des = limit_p;
control->v_des = 0.0f;
control->kp = 0;
control->kd = KD_SOFTSTOP;
control->t_ff += KP_SOFTSTOP*(limit_p - state.p);
return 1;
}
else if((state.p)<=limit_n){
//control->p_des = limit_n;
control->v_des = 0.0f;
control->kp = 0;
control->kd = KD_SOFTSTOP;
control->t_ff += KP_SOFTSTOP*(limit_n - state.p);
return 1;
}
return 0;
}
void control()
{
if(((spi_command.flags[0]&0x1)==1) && (enabled==0)){
enabled = 1;
EnterMotorMode(&a1_can);
can1.write(a1_can);
EnterMotorMode(&a2_can);
can2.write(a2_can);
EnterMotorMode(&k1_can);
can1.write(k1_can);
EnterMotorMode(&k2_can);
can2.write(k2_can);
EnterMotorMode(&h1_can);
can1.write(h1_can);
EnterMotorMode(&h2_can);
can2.write(h2_can);
printf("e\n\r");
return;
}
else if((((spi_command.flags[0]&0x1))==0) && (enabled==1)){
enabled = 0;
ExitMotorMode(&a1_can);
can1.write(a1_can);
ExitMotorMode(&a2_can);
can2.write(a2_can);
ExitMotorMode(&h1_can);
can1.write(h1_can);
ExitMotorMode(&h2_can);
can2.write(h2_can);
ExitMotorMode(&k1_can);
can1.write(k1_can);
ExitMotorMode(&k2_can);
can2.write(k2_can);
printf("x\n\r");
return;
}
spi_data.q_abad[0] = l1_state.a.p;
spi_data.q_hip[0] = l1_state.h.p;
spi_data.q_knee[0] = l1_state.k.p;
spi_data.qd_abad[0] = l1_state.a.v;
spi_data.qd_hip[0] = l1_state.h.v;
spi_data.qd_knee[0] = l1_state.k.v;
spi_data.q_abad[1] = l2_state.a.p;
spi_data.q_hip[1] = l2_state.h.p;
spi_data.q_knee[1] = l2_state.k.p;
spi_data.qd_abad[1] = l2_state.a.v;
spi_data.qd_hip[1] = l2_state.h.v;
spi_data.qd_knee[1] = l2_state.k.v;
if(estop==0){
//printf("estopped!!!!\n\r");
memset(&l1_control, 0, sizeof(l1_control));
memset(&l2_control, 0, sizeof(l2_control));
spi_data.flags[0] = 0xdead;
spi_data.flags[1] = 0xdead;
led = 1;
}
else{
led = 0;
memset(&l1_control, 0, sizeof(l1_control));
memset(&l2_control, 0, sizeof(l2_control));
l1_control.a.p_des = spi_command.q_des_abad[0];
l1_control.a.v_des = spi_command.qd_des_abad[0];
l1_control.a.kp = spi_command.kp_abad[0];
l1_control.a.kd = spi_command.kd_abad[0];
l1_control.a.t_ff = spi_command.tau_abad_ff[0];
l1_control.h.p_des = spi_command.q_des_hip[0];
l1_control.h.v_des = spi_command.qd_des_hip[0];
l1_control.h.kp = spi_command.kp_hip[0];
l1_control.h.kd = spi_command.kd_hip[0];
l1_control.h.t_ff = spi_command.tau_hip_ff[0];
l1_control.k.p_des = spi_command.q_des_knee[0];
l1_control.k.v_des = spi_command.qd_des_knee[0];
l1_control.k.kp = spi_command.kp_knee[0];
l1_control.k.kd = spi_command.kd_knee[0];
l1_control.k.t_ff = spi_command.tau_knee_ff[0];
l2_control.a.p_des = spi_command.q_des_abad[1];
l2_control.a.v_des = spi_command.qd_des_abad[1];
l2_control.a.kp = spi_command.kp_abad[1];
l2_control.a.kd = spi_command.kd_abad[1];
l2_control.a.t_ff = spi_command.tau_abad_ff[1];
l2_control.h.p_des = spi_command.q_des_hip[1];
l2_control.h.v_des = spi_command.qd_des_hip[1];
l2_control.h.kp = spi_command.kp_hip[1];
l2_control.h.kd = spi_command.kd_hip[1];
l2_control.h.t_ff = spi_command.tau_hip_ff[1];
l2_control.k.p_des = spi_command.q_des_knee[1];
l2_control.k.v_des = spi_command.qd_des_knee[1];
l2_control.k.kp = spi_command.kp_knee[1];
l2_control.k.kd = spi_command.kd_knee[1];
l2_control.k.t_ff = spi_command.tau_knee_ff[1];
spi_data.flags[0] = 0;
spi_data.flags[1] = 0;
spi_data.flags[0] |= softstop_joint(l1_state.a, &l1_control.a, A_LIM_P, A_LIM_N);
spi_data.flags[0] |= (softstop_joint(l1_state.h, &l1_control.h, H_LIM_P, H_LIM_N))<<1;
//spi_data.flags[0] |= (softstop_joint(l1_state.k, &l1_control.k, K_LIM_P, K_LIM_N))<<2;
spi_data.flags[1] |= softstop_joint(l2_state.a, &l2_control.a, A_LIM_P, A_LIM_N);
spi_data.flags[1] |= (softstop_joint(l2_state.h, &l2_control.h, H_LIM_P, H_LIM_N))<<1;
//spi_data.flags[1] |= (softstop_joint(l2_state.k, &l2_control.k, K_LIM_P, K_LIM_N))<<2;
//spi_data.flags[0] = 0xbeef;
//spi_data.flags[1] = 0xbeef;
//PackAll();
//WriteAll();
}
spi_data.checksum = xor_checksum((uint32_t*)&spi_data,14);
for(int i = 0; i < DATA_LEN; i++){
tx_buff[i] = ((uint16_t*)(&spi_data))[i];}
}
void test_control()
{
for(int i = 0; i < 2; i++)
{
spi_data.q_abad[i] = spi_command.q_des_abad[i] + 1.f;
spi_data.q_knee[i] = spi_command.q_des_knee[i] + 1.f;
spi_data.q_hip[i] = spi_command.q_des_hip[i] + 1.f;
spi_data.qd_abad[i] = spi_command.qd_des_abad[i] + 1.f;
spi_data.qd_knee[i] = spi_command.qd_des_knee[i] + 1.f;
spi_data.qd_hip[i] = spi_command.qd_des_hip[i] + 1.f;
}
spi_data.flags[0] = 0xdead;
//spi_data.flags[1] = 0xbeef;
// only do first 56 bytes of message.
spi_data.checksum = xor_checksum((uint32_t*)&spi_data,14);
for(int i = 0; i < DATA_LEN; i++)
tx_buff[i] = ((uint16_t*)(&spi_data))[i];
}
void init_spi(void){
SPISlave *spi = new SPISlave(PA_7, PA_6, PA_5, PA_4);
spi->format(16, 0);
spi->frequency(12000000);
spi->reply(0x0);
cs.fall(&spi_isr);
printf("done\n\r");
}
int main() {
wait(1);
//led = 1;
pc.baud(921600);
pc.attach(&serial_isr);
estop.mode(PullUp);
//spi.format(16, 0);
//spi.frequency(1000000);
//spi.reply(0x0);
//cs.fall(&spi_isr);
//can1.frequency(1000000); // set bit rate to 1Mbps
//can1.attach(&rxISR1); // attach 'CAN receive-complete' interrupt handler
can1.filter(CAN_ID<<21, 0xFFE00004, CANStandard, 0); //set up can filter
//can2.frequency(1000000); // set bit rate to 1Mbps
//can2.attach(&rxISR2); // attach 'CAN receive-complete' interrupt handler
can2.filter(CAN_ID<<21, 0xFFE00004, CANStandard, 0); //set up can filter
memset(&tx_buff, 0, TX_LEN * sizeof(uint16_t));
memset(&spi_data, 0, sizeof(spi_data_t));
memset(&spi_command,0,sizeof(spi_command_t));
NVIC_SetPriority(TIM5_IRQn, 1);
//NVIC_SetPriority(CAN1_RX0_IRQn, 3);
//NVIC_SetPriority(CAN2_RX0_IRQn, 3);
printf("\n\r SPIne\n\r");
//printf("%d\n\r", RX_ID << 18);
a1_can.len = 8; //transmit 8 bytes
a2_can.len = 8; //transmit 8 bytes
h1_can.len = 8;
h2_can.len = 8;
k1_can.len = 8;
k2_can.len = 8;
rxMsg1.len = 6; //receive 6 bytes
rxMsg2.len = 6; //receive 6 bytes
a1_can.id = 0x1;
a2_can.id = 0x1;
h1_can.id = 0x2;
h2_can.id = 0x2;
k1_can.id = 0x3;
k2_can.id = 0x3;
pack_cmd(&a1_can, l1_control.a);
pack_cmd(&a2_can, l2_control.a);
pack_cmd(&h1_can, l1_control.h);
pack_cmd(&h2_can, l2_control.h);
pack_cmd(&k1_can, l1_control.k);
pack_cmd(&k2_can, l2_control.k);
WriteAll();
// SPI doesn't work if enabled while the CS pin is pulled low
// Wait for CS to not be low, then enable SPI
if(!spi_enabled){
while((spi_enabled==0) && (cs.read() ==0)){wait_us(10);}
init_spi();
spi_enabled = 1;
}
while(1) {
counter++;
can2.read(rxMsg2);
unpack_reply(rxMsg2, &l2_state);
can1.read(rxMsg1); // read message into Rx message storage
unpack_reply(rxMsg1, &l1_state);
wait_us(10);
}
}