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realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / 25329e62abc2acd0f49fc24450f4b33bb66b1d5d / . / gyro_board / src / usb / analog.c
blob: c9d6752cd9f825b1265a7b339ec86b5a51697354 [file] [log] [blame]
// ****************************************************************************
// CopyLeft qwerk Robotics unINC. 2010 All Rights Reserved.
// ****************************************************************************
// ****************************************************************************
// **************** IO Pin Setup
// ****************************************************************************
#include "FreeRTOS.h"
#include "queue.h"
#include "task.h"
#include "analog.h"
// How long (in ms) to wait after a falling edge on the bottom indexer sensor
// before reading the indexer encoder.
static const int kBottomFallDelayTime = 32;
void analog_init(void) {
// b[1:0] CAN RD1 p0.0
// b[3:2] CAN TD1 p0.1
//PINCON->PINSEL0 = 0x00000005;
// b[29:28] USB_DMIN p0.30
// b[27:26] USB_DPLUS p0.29
// b[21:20] AD0.3 p0.26
// b[19:18] AD0.2 p0.25
// PINCON->PINSEL1 = 0x14140000;
// PINCON->PINSEL2 = 0x0;
// b[31:30] AD0.5 p1.31
// b[29:28] V_BUS p1.30
// b[21:20] MCOB1 p1.26
// b[19:18] MCOA1 p1.25
// b[15:14] MCI1 p1.23
// b[13:12] MCOB0 p1.22
// b[09:08] MCI0 p1.20
// b[07:06] MCOA0 p1.19
// b[05:04] USB_UP_LED p1.18
//PINCON->PINSEL3 = 0xE0145150;
SC->PCONP |= PCONP_PCAD;
// Enable AD0.0, AD0.1, AD0.2, AD0.3
PINCON->PINSEL1 &= 0xFFC03FFF;
PINCON->PINSEL1 |= 0x00D54000;
ADC->ADCR = 0x00200500;
}
// ****************************************************************************
// **************** ADC Functions
// ****************************************************************************
// **************** macros
// starts conversion [26:24] = 001
// **************** functions
int analog(int channel) {
ADC->ADCR = ((ADC->ADCR & 0xF8FFFF00) | (0x01000000 | (1 << channel)));
// Poll until it is done.
while(!(ADC->ADGDR & 0x80000000));
return ((ADC->ADGDR & 0x0000FFF0) >> 4);
}
// GPIO1 P0.4
// GPIO2 P0.5
// GPIO3 P0.6
// GPIO4 P0.7
// GPIO5 P0.8
// GPIO6 P0.9
// GPIO7 P2.0
// GPIO8 P2.1
// GPIO9 P2.2
// GPIO10 P2.3
// GPIO11 P2.4
// GPIO12 P2.5
// DIP0 P1.29
// DIP1 P2.13
// DIP2 P0.11
// DIP3 P0.10
#define readGPIO(gpio, chan) ((((gpio)->FIOPIN) >> (chan)) & 1)
inline int readGPIO_inline(int major, int minor) {
switch (major) {
case 0:
return readGPIO(GPIO0, minor);
case 1:
return readGPIO(GPIO1, minor);
case 2:
return readGPIO(GPIO2, minor);
default:
return -1;
}
}
int digital(int channel) {
if (channel < 1) {
return -1;
} else if (channel < 7) {
int chan = channel + 3;
return readGPIO(GPIO0, chan);
} else if (channel < 13) {
int chan = channel - 7;
return readGPIO(GPIO2, chan);
}
return -1;
}
int dip(int channel) {
switch (channel) {
case 0:
return readGPIO(GPIO1, 29);
case 1:
return readGPIO(GPIO2, 13);
case 2:
return readGPIO(GPIO0, 11);
case 3:
return readGPIO(GPIO0, 10);
default:
return -1;
}
}
// ENC0A 1.20
// ENC0B 1.23
// ENC1A 2.11
// ENC1B 2.12
// ENC2A 0.21
// ENC2B 0.22
// ENC3A 0.19
// ENC3B 0.20
#define ENC(gpio, a, b) readGPIO(gpio, a) * 2 + readGPIO(gpio, b)
int encoder_bits(int channel) {
switch (channel) {
case 0:
return ENC(GPIO1, 20, 23);
case 1:
return ENC(GPIO2, 11, 12);
case 2:
return ENC(GPIO0, 21, 22);
case 3:
return ENC(GPIO0, 19, 20);
default:
return -1;
}
return -1;
}
#undef ENC
// Uses EINT1 and EINT2 on 2.11 and 2.12.
volatile int32_t encoder1_val;
// On GPIO pins 0.22 and 0.21.
volatile int32_t encoder2_val;
// On GPIO pins 0.20 and 0.19.
volatile int32_t encoder3_val;
// On GPIO pins 2.0 and 2.1.
volatile int32_t encoder4_val;
// On GPIO pins 2.2 and 2.3.
volatile int32_t encoder5_val;
// ENC1A 2.11
void EINT1_IRQHandler(void) {
// TODO(brians): figure out why this has to be up here too
SC->EXTINT = 0x2;
int fiopin = GPIO2->FIOPIN;
if (((fiopin >> 1) ^ fiopin) & 0x800) {
++encoder1_val;
} else {
--encoder1_val;
}
SC->EXTPOLAR ^= 0x2;
SC->EXTINT = 0x2;
}
// ENC1B 2.12
void EINT2_IRQHandler(void) {
SC->EXTINT = 0x4;
int fiopin = GPIO2->FIOPIN;
if (((fiopin >> 1) ^ fiopin) & 0x800) {
--encoder1_val;
} else {
++encoder1_val;
}
SC->EXTPOLAR ^= 0x4;
SC->EXTINT = 0x4;
}
// GPIO Interrupt handlers
static void NoGPIO() {}
static void Encoder2ARise() {
GPIOINT->IO0IntClr |= (1 << 22);
if (GPIO0->FIOPIN & (1 << 21)) {
++encoder2_val;
} else {
--encoder2_val;
}
}
static void Encoder2AFall() {
GPIOINT->IO0IntClr |= (1 << 22);
if (GPIO0->FIOPIN & (1 << 21)) {
--encoder2_val;
} else {
++encoder2_val;
}
}
static void Encoder2BRise() {
GPIOINT->IO0IntClr |= (1 << 21);
if (GPIO0->FIOPIN & (1 << 22)) {
--encoder2_val;
} else {
++encoder2_val;
}
}
static void Encoder2BFall() {
GPIOINT->IO0IntClr |= (1 << 21);
if (GPIO0->FIOPIN & (1 << 22)) {
++encoder2_val;
} else {
--encoder2_val;
}
}
static void Encoder3ARise() {
GPIOINT->IO0IntClr |= (1 << 20);
if (GPIO0->FIOPIN & (1 << 19)) {
++encoder3_val;
} else {
--encoder3_val;
}
}
static void Encoder3AFall() {
GPIOINT->IO0IntClr |= (1 << 20);
if (GPIO0->FIOPIN & (1 << 19)) {
--encoder3_val;
} else {
++encoder3_val;
}
}
static void Encoder3BRise() {
GPIOINT->IO0IntClr |= (1 << 19);
if (GPIO0->FIOPIN & (1 << 20)) {
--encoder3_val;
} else {
++encoder3_val;
}
}
static void Encoder3BFall() {
GPIOINT->IO0IntClr |= (1 << 19);
if (GPIO0->FIOPIN & (1 << 20)) {
++encoder3_val;
} else {
--encoder3_val;
}
}
static void Encoder4ARise() {
GPIOINT->IO2IntClr |= (1 << 0);
if (GPIO2->FIOPIN & (1 << 1)) {
++encoder4_val;
} else {
--encoder4_val;
}
}
static void Encoder4AFall() {
GPIOINT->IO2IntClr |= (1 << 0);
if (GPIO2->FIOPIN & (1 << 1)) {
--encoder4_val;
} else {
++encoder4_val;
}
}
static void Encoder4BRise() {
GPIOINT->IO2IntClr |= (1 << 1);
if (GPIO2->FIOPIN & (1 << 0)) {
--encoder4_val;
} else {
++encoder4_val;
}
}
static void Encoder4BFall() {
GPIOINT->IO2IntClr |= (1 << 1);
if (GPIO2->FIOPIN & (1 << 0)) {
++encoder4_val;
} else {
--encoder4_val;
}
}
static void Encoder5ARise() {
GPIOINT->IO2IntClr |= (1 << 2);
if (GPIO2->FIOPIN & (1 << 3)) {
++encoder5_val;
} else {
--encoder5_val;
}
}
static void Encoder5AFall() {
GPIOINT->IO2IntClr |= (1 << 2);
if (GPIO2->FIOPIN & (1 << 3)) {
--encoder5_val;
} else {
++encoder5_val;
}
}
static void Encoder5BRise() {
GPIOINT->IO2IntClr |= (1 << 3);
if (GPIO2->FIOPIN & (1 << 2)) {
--encoder5_val;
} else {
++encoder5_val;
}
}
static void Encoder5BFall() {
GPIOINT->IO2IntClr |= (1 << 3);
if (GPIO2->FIOPIN & (1 << 2)) {
++encoder5_val;
} else {
--encoder5_val;
}
}
volatile int32_t capture_top_rise;
volatile int8_t top_rise_count;
static void IndexerTopRise() {
GPIOINT->IO0IntClr |= (1 << 5);
// edge counting encoder capture
++top_rise_count;
capture_top_rise = encoder3_val;
}
volatile int32_t capture_top_fall;
volatile int8_t top_fall_count;
static void IndexerTopFall() {
GPIOINT->IO0IntClr |= (1 << 5);
// edge counting encoder capture
++top_fall_count;
capture_top_fall = encoder3_val;
}
volatile int8_t bottom_rise_count;
static void IndexerBottomRise() {
GPIOINT->IO0IntClr |= (1 << 4);
// edge counting
++bottom_rise_count;
}
volatile int32_t capture_bottom_fall_delay;
volatile int8_t bottom_fall_delay_count;
volatile int32_t dirty_delay;
portTickType xDelayTimeFrom;
static portTASK_FUNCTION(vDelayCapture, pvParameters)
{
portTickType xSleepFrom = xTaskGetTickCount();
for (;;) {
NVIC_DisableIRQ(EINT3_IRQn);
if (dirty_delay != 0) {
xSleepFrom = xDelayTimeFrom;
dirty_delay = 0;
NVIC_EnableIRQ(EINT3_IRQn);
vTaskDelayUntil(&xSleepFrom, kBottomFallDelayTime / portTICK_RATE_MS);
NVIC_DisableIRQ(EINT3_IRQn);
++bottom_fall_delay_count;
capture_bottom_fall_delay = encoder3_val;
NVIC_EnableIRQ(EINT3_IRQn);
} else {
NVIC_EnableIRQ(EINT3_IRQn);
vTaskDelayUntil(&xSleepFrom, 10 / portTICK_RATE_MS);
}
}
}
volatile int8_t bottom_fall_count;
static void IndexerBottomFall() {
GPIOINT->IO0IntClr |= (1 << 4);
++bottom_fall_count;
// edge counting start delayed capture
xDelayTimeFrom = xTaskGetTickCount();
dirty_delay = 1;
}
volatile int32_t capture_wrist_rise;
volatile int8_t wrist_rise_count;
static void WristHallRise() {
GPIOINT->IO0IntClr |= (1 << 6);
// edge counting encoder capture
++wrist_rise_count;
capture_wrist_rise = (int32_t)QEI->QEIPOS;
}
volatile int32_t capture_shooter_angle_rise;
volatile int8_t shooter_angle_rise_count;
static void ShooterHallRise() {
GPIOINT->IO0IntClr |= (1 << 7);
// edge counting encoder capture
++shooter_angle_rise_count;
capture_shooter_angle_rise = encoder2_val;
}
// Count leading zeros.
// Returns 0 if bit 31 is set etc.
__attribute__((always_inline)) static __INLINE uint32_t __clz(uint32_t value) {
uint32_t result;
__asm__("clz %0, %1" : "=r" (result) : "r" (value));
return result;
}
inline static void IRQ_Dispatch(void) {
// TODO(brians): think about adding a loop here so that we can handle multiple
// interrupts right on top of each other faster
uint32_t index = __clz(GPIOINT->IO2IntStatR | GPIOINT->IO0IntStatR |
(GPIOINT->IO2IntStatF << 28) | (GPIOINT->IO0IntStatF << 4));
typedef void (*Handler)(void);
const static Handler table[] = {
Encoder5BFall, // index 0: P2.3 Fall #bit 31 //Encoder 5 B //Dio 10
Encoder5AFall, // index 1: P2.2 Fall #bit 30 //Encoder 5 A //Dio 9
Encoder4BFall, // index 2: P2.1 Fall #bit 29 //Encoder 4 B //Dio 8
Encoder4AFall, // index 3: P2.0 Fall #bit 28 //Encoder 4 A //Dio 7
NoGPIO, // index 4: NO GPIO #bit 27
Encoder2AFall, // index 5: P0.22 Fall #bit 26 //Encoder 2 A
Encoder2BFall, // index 6: P0.21 Fall #bit 25 //Encoder 2 B
Encoder3AFall, // index 7: P0.20 Fall #bit 24 //Encoder 3 A
Encoder3BFall, // index 8: P0.19 Fall #bit 23 //Encoder 3 B
Encoder2ARise, // index 9: P0.22 Rise #bit 22 //Encoder 2 A
Encoder2BRise, // index 10: P0.21 Rise #bit 21 //Encoder 2 B
Encoder3ARise, // index 11: P0.20 Rise #bit 20 //Encoder 3 A
Encoder3BRise, // index 12: P0.19 Rise #bit 19 //Encoder 3 B
NoGPIO, // index 13: NO GPIO #bit 18
NoGPIO, // index 14: NO GPIO #bit 17
NoGPIO, // index 15: NO GPIO #bit 16
NoGPIO, // index 16: NO GPIO #bit 15
NoGPIO, // index 17: NO GPIO #bit 14
NoGPIO, // index 18: NO GPIO #bit 13
NoGPIO, // index 19: NO GPIO #bit 12
ShooterHallRise, // index 20: P0.7 Fall #bit 11 //Shooter Hall //Dio 4
WristHallRise, // index 21: P0.6 Fall #bit 10 //Wrist Hall //Dio 3
IndexerTopRise, // index 22: P0.5 Fall #bit 9 //Indexer Top //Dio 2
IndexerBottomRise, // index 23: P0.4 Fall #bit 8 //Indexer Bottom //Dio 1
NoGPIO, // index 24: NO GPIO #bit 7
NoGPIO, // index 25: NO GPIO #bit 6
IndexerTopFall, // index 26: P0.5 Rise #bit 5 //Indexer Top //Dio 2
IndexerBottomFall, // index 27: P0.4 Rise #bit 4 //Indexer Bottom //Dio 1
Encoder5BRise, // index 28: P2.3 Rise #bit 3 //Encoder 5 B //Dio 10
Encoder5ARise, // index 29: P2.2 Rise #bit 2 //Encoder 5 A //Dio 9
Encoder4BRise, // index 30: P2.1 Rise #bit 1 //Encoder 4 B //Dio 8
Encoder4ARise, // index 31: P2.0 Rise #bit 0 //Encoder 4 A //Dio 7
NoGPIO // index 32: NO BITS SET #False Alarm
};
table[index]();
}
void EINT3_IRQHandler(void) {
// Have to disable it here or else it re-fires the interrupt while the code
// reads to figure out which pin the interrupt is for.
// TODO(brians): figure out details + look for an alternative
NVIC_DisableIRQ(EINT3_IRQn);
IRQ_Dispatch();
NVIC_EnableIRQ(EINT3_IRQn);
}
int32_t encoder_val(int chan) {
int32_t val;
switch (chan) {
case 0: // Wrist
return (int32_t)QEI->QEIPOS;
case 1: // Shooter Wheel
NVIC_DisableIRQ(EINT1_IRQn);
NVIC_DisableIRQ(EINT2_IRQn);
val = encoder1_val;
NVIC_EnableIRQ(EINT2_IRQn);
NVIC_EnableIRQ(EINT1_IRQn);
return val;
case 2: // Shooter Angle
NVIC_DisableIRQ(EINT3_IRQn);
val = encoder2_val;
NVIC_EnableIRQ(EINT3_IRQn);
return val;
case 3: // Indexer
NVIC_DisableIRQ(EINT3_IRQn);
val = encoder3_val;
NVIC_EnableIRQ(EINT3_IRQn);
return val;
case 4: // Drive R
NVIC_DisableIRQ(EINT3_IRQn);
val = encoder4_val;
NVIC_EnableIRQ(EINT3_IRQn);
return val;
case 5: // Drive L
NVIC_DisableIRQ(EINT3_IRQn);
val = encoder5_val;
NVIC_EnableIRQ(EINT3_IRQn);
return val;
default:
return -1;
}
}
void fillSensorPacket(struct DataStruct *packet) {
packet->gyro_angle = gyro_angle;
packet->shooter = encoder1_val;
packet->left_drive = encoder4_val;
packet->right_drive = encoder5_val;
packet->shooter_angle = encoder2_val;
packet->indexer = encoder3_val;
NVIC_DisableIRQ(EINT1_IRQn);
NVIC_DisableIRQ(EINT2_IRQn);
packet->wrist = (int32_t)QEI->QEIPOS;
packet->wrist_hall_effect = !digital(3);
packet->capture_wrist_rise = capture_wrist_rise;
packet->wrist_rise_count = wrist_rise_count;
NVIC_EnableIRQ(EINT1_IRQn);
NVIC_EnableIRQ(EINT2_IRQn);
NVIC_DisableIRQ(EINT3_IRQn);
packet->capture_top_rise = capture_top_rise;
packet->top_rise_count = top_rise_count;
packet->capture_top_fall = capture_top_fall;
packet->top_fall_count = top_fall_count;
packet->top_disc = !digital(2);
packet->capture_bottom_fall_delay = capture_bottom_fall_delay;
packet->bottom_fall_delay_count = bottom_fall_delay_count;
packet->bottom_fall_count = bottom_fall_count;
packet->bottom_disc = !digital(1);
packet->loader_top = !digital(5);
packet->capture_shooter_angle_rise = capture_shooter_angle_rise;
packet->shooter_angle_rise_count = shooter_angle_rise_count;
packet->angle_adjust_bottom_hall_effect = !digital(4);
NVIC_EnableIRQ(EINT3_IRQn);
packet->bottom_rise_count = bottom_rise_count;
}
void encoder_init(void) {
// Setup the encoder interface.
SC->PCONP |= PCONP_PCQEI;
PINCON->PINSEL3 = ((PINCON->PINSEL3 & 0xffff3dff) | 0x00004100);
// Reset the count and velocity.
QEI->QEICON = 0x00000005;
QEI->QEICONF = 0x00000004;
// Wrap back to 0 when we wrap the int and vice versa.
QEI->QEIMAXPOS = 0xFFFFFFFF;
// Set up encoder 1.
// Make GPIOs 2.11 and 2.12 trigger EINT1 and EINT2 (respectively).
// PINSEL4[23:22] = {0 1}
// PINSEL4[25:24] = {0 1}
PINCON->PINSEL4 = (PINCON->PINSEL4 & ~(0x3 << 22)) | (0x1 << 22);
PINCON->PINSEL4 = (PINCON->PINSEL4 & ~(0x3 << 24)) | (0x1 << 24);
// Clear the interrupt flags for EINT1 and EINT2 (0x6 = 0b0110).
SC->EXTMODE = 0x6;
SC->EXTINT = 0x6;
NVIC_EnableIRQ(EINT1_IRQn);
NVIC_EnableIRQ(EINT2_IRQn);
encoder1_val = 0;
// Set up encoder 2.
GPIOINT->IO0IntEnF |= (1 << 22); // Set GPIO falling interrupt.
GPIOINT->IO0IntEnR |= (1 << 22); // Set GPIO rising interrupt.
GPIOINT->IO0IntEnF |= (1 << 21); // Set GPIO falling interrupt.
GPIOINT->IO0IntEnR |= (1 << 21); // Set GPIO rising interrupt.
// Make sure they're in mode 00 (the default, aka nothing special).
PINCON->PINSEL1 &= ~(0x3 << 12);
PINCON->PINSEL1 &= ~(0x3 << 10);
encoder2_val = 0;
// Set up encoder 3.
GPIOINT->IO0IntEnF |= (1 << 20); // Set GPIO falling interrupt.
GPIOINT->IO0IntEnR |= (1 << 20); // Set GPIO rising interrupt.
GPIOINT->IO0IntEnF |= (1 << 19); // Set GPIO falling interrupt.
GPIOINT->IO0IntEnR |= (1 << 19); // Set GPIO rising interrupt.
// Make sure they're in mode 00 (the default, aka nothing special).
PINCON->PINSEL1 &= ~(0x3 << 8);
PINCON->PINSEL1 &= ~(0x3 << 6);
encoder3_val = 0;
// Set up encoder 4.
GPIOINT->IO2IntEnF |= (1 << 0); // Set GPIO falling interrupt.
GPIOINT->IO2IntEnR |= (1 << 0); // Set GPIO rising interrupt.
GPIOINT->IO2IntEnF |= (1 << 1); // Set GPIO falling interrupt.
GPIOINT->IO2IntEnR |= (1 << 1); // Set GPIO rising interrupt.
// Make sure they're in mode 00 (the default, aka nothing special).
PINCON->PINSEL4 &= ~(0x3 << 0);
PINCON->PINSEL4 &= ~(0x3 << 2);
encoder4_val = 0;
// Set up encoder 5.
GPIOINT->IO2IntEnF |= (1 << 2); // Set GPIO falling interrupt.
GPIOINT->IO2IntEnR |= (1 << 2); // Set GPIO rising interrupt.
GPIOINT->IO2IntEnF |= (1 << 3); // Set GPIO falling interrupt.
GPIOINT->IO2IntEnR |= (1 << 3); // Set GPIO rising interrupt.
// Make sure they're in mode 00 (the default, aka nothing special).
PINCON->PINSEL4 &= ~(0x3 << 4);
PINCON->PINSEL4 &= ~(0x3 << 6);
encoder5_val = 0;
// Enable interrupts from the GPIO pins.
NVIC_EnableIRQ(EINT3_IRQn);
xTaskCreate(vDelayCapture,
(signed char *) "SENSORs",
configMINIMAL_STACK_SIZE + 100,
NULL /*parameters*/,
tskIDLE_PRIORITY + 5,
NULL /*return task handle*/);
GPIOINT->IO0IntEnF |= (1 << 4); // Set GPIO falling interrupt
GPIOINT->IO0IntEnR |= (1 << 4); // Set GPIO rising interrupt
PINCON->PINSEL0 &= ~(0x3 << 8);
GPIOINT->IO0IntEnF |= (1 << 5); // Set GPIO falling interrupt
GPIOINT->IO0IntEnR |= (1 << 5); // Set GPIO rising interrupt
PINCON->PINSEL0 &= ~(0x3 << 10);
GPIOINT->IO0IntEnF |= (1 << 6);
PINCON->PINSEL0 &= ~(0x3 << 12);
GPIOINT->IO0IntEnF |= (1 << 7);
PINCON->PINSEL0 &= ~(0x3 << 14);
}