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mitchellhansen
2020-02-02 15:28:36 -08:00
parent 0189d519c6
commit 6480bc593f
3583 changed files with 1305025 additions and 247 deletions
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arduino/libraries/Adafruit_Circuit_Playground/utility/Adafruit_CPlay_FreeTouch.cpp Normal file
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/*
* FreeTouch, a QTouch-compatible library - tested on ATSAMD21 only!
* The MIT License (MIT)
*
* Copyright (c) 2017 Limor 'ladyada' Fried for Adafruit Industries
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "Adafruit_CPlay_FreeTouch.h"
#if defined(__SAMD21G18A__)
Adafruit_CPlay_FreeTouch::Adafruit_CPlay_FreeTouch(int p, oversample_t f, series_resistor_t r, freq_mode_t fh) {
pin = p;
oversample = f;
seriesres = r;
freqhop = fh;
compcap = 0x2000;
intcap = 0x3F;
yline = -1;
}
bool Adafruit_CPlay_FreeTouch::begin(void) {
yline = getYLine(); // determine the Y0-15 #
if (yline == -1) // not all pins have Y line
return false;
setupClock();
ptcInitSettings();
enablePTC(false);
enableWCOint(false);
enableEOCint(false);
// enable the sensor, only done once per line
if (yline < 8) {
sync_config();
QTOUCH_PTC->YENABLEL.reg |= 1 << yline;
sync_config();
} else if (yline < 16) {
QTOUCH_PTC->YENABLEH.reg |= 1 << (yline - 8);
}
enablePTC(true);
return true;
}
void Adafruit_CPlay_FreeTouch::setupClock(void) {
/* Setup and enable generic clock source for PTC module.
struct system_gclk_chan_config gclk_chan_conf;
system_gclk_chan_get_config_defaults(&gclk_chan_conf);
*/
uint8_t channel = PTC_GCLK_ID;
uint8_t source_generator = 1;
// original line: system_gclk_chan_set_config(PTC_GCLK_ID, &gclk_chan_conf);
uint32_t new_clkctrl_config = (channel << GCLK_CLKCTRL_ID_Pos); // from gclk.c
// original line: gclk_chan_conf.source_generator = GCLK_GENERATOR_1;
/* Select the desired generic clock generator */
new_clkctrl_config |= source_generator << GCLK_CLKCTRL_GEN_Pos; // from gclk.c
/* Disable generic clock channel */
// original line: system_gclk_chan_disable(channel);
noInterrupts();
/* Select the requested generator channel */
*((uint8_t*)&GCLK->CLKCTRL.reg) = channel;
/* Sanity check WRTLOCK */
//Assert(!GCLK->CLKCTRL.bit.WRTLOCK);
/* Switch to known-working source so that the channel can be disabled */
uint32_t prev_gen_id = GCLK->CLKCTRL.bit.GEN;
GCLK->CLKCTRL.bit.GEN = 0;
/* Disable the generic clock */
GCLK->CLKCTRL.reg &= ~GCLK_CLKCTRL_CLKEN;
while (GCLK->CLKCTRL.reg & GCLK_CLKCTRL_CLKEN) {
/* Wait for clock to become disabled */
}
/* Restore previous configured clock generator */
GCLK->CLKCTRL.bit.GEN = prev_gen_id;
//system_interrupt_leave_critical_section();
interrupts();
/* Write the new configuration */
GCLK->CLKCTRL.reg = new_clkctrl_config;
// original line: system_gclk_chan_enable(PTC_GCLK_ID);
*((uint8_t*)&GCLK->CLKCTRL.reg) = channel;
GCLK->CLKCTRL.reg |= GCLK_CLKCTRL_CLKEN; /* Enable the generic clock */
// original line: system_apb_clock_set_mask(SYSTEM_CLOCK_APB_APBC, PM_APBCMASK_PTC);
PM->APBCMASK.reg |= PM_APBCMASK_PTC;
}
uint16_t Adafruit_CPlay_FreeTouch::measure(void) {
uint16_t m;
m = measureRaw();
if (m == -1) return -1;
// normalize the signal
switch (oversample) {
case OVERSAMPLE_1: return m;
case OVERSAMPLE_2: return m/2;
case OVERSAMPLE_4: return m/4;
case OVERSAMPLE_8: return m/8;
case OVERSAMPLE_16: return m/16;
case OVERSAMPLE_32: return m/32;
case OVERSAMPLE_64: return m/64;
}
return -1; // shouldn't reach here but fail if we do!
}
uint16_t Adafruit_CPlay_FreeTouch::measureRaw(void) {
if (yline == -1)
return -1;
runInStandby(true);
enablePTC(true);
// check if in progress
// set up NVIC if using INT (we're not)
enableWCOint(false);
clearWCOintFlag();
clearEOCintFlag();
// enable_eoc_int(); // not using irq (for now)
// set up pin!
//Serial.print("Y Line #"); Serial.println(yline);
selectYLine();
// set up sense resistor
setSeriesResistor(seriesres);
// set up prescalar
setOversampling(oversample);
// set up freq hopping
setFreqHopping(freqhop, hops);
// set up compensation cap + int (?) cap
setCompCap(compcap);
setIntCap(intcap);
QTOUCH_PTC->BURSTMODE.reg = 0xA4;
sync_config();
return startPtcAcquire();
}
uint16_t Adafruit_CPlay_FreeTouch::startPtcAcquire(void) {
ptcConfigIOpin();
ptcAcquire();
while (QTOUCH_PTC->CONVCONTROL.bit.CONVERT) {
yield();
}
sync_config();
uint16_t result = QTOUCH_PTC->RESULT.reg;
return result;
}
/*********************************** low level config **/
void Adafruit_CPlay_FreeTouch::selectYLine(void) {
sync_config();
if (yline < 8) {
QTOUCH_PTC->YSELECTL.reg = 1 << yline;
} else {
QTOUCH_PTC->YSELECTL.reg = 0;
}
if (yline > 7) {
QTOUCH_PTC->YSELECTH.reg = 1 << (yline - 8);
} else {
QTOUCH_PTC->YSELECTH.reg = 0;
}
sync_config();
}
int Adafruit_CPlay_FreeTouch::getYLine(void) {
int p = g_APinDescription[pin].ulPin;
if (g_APinDescription[pin].ulPort == PORTA) {
if ((p >= 2) && (p <= 7)) {
return (p - 2);
}
}
if (g_APinDescription[pin].ulPort == PORTB) {
if ((p >= 0) && (p <= 9)) {
return (p + 6);
}
}
// not valid
return -1;
}
void Adafruit_CPlay_FreeTouch::setCompCap(uint16_t cc) {
compcap = cc & 0x3FFF;
sync_config();
QTOUCH_PTC->COMPCAPL.bit.VALUE = compcap & 0xFF;
QTOUCH_PTC->COMPCAPH.bit.VALUE = (compcap>>8) & 0x3F;
sync_config();
}
void Adafruit_CPlay_FreeTouch::setIntCap(uint8_t ic) {
intcap = ic & 0x3F;
sync_config();
QTOUCH_PTC->INTCAP.bit.VALUE = intcap & 0x3F;
sync_config();
}
void Adafruit_CPlay_FreeTouch::setOversampling(oversample_t lvl) {
oversample = lvl; // back it up for later
sync_config();
QTOUCH_PTC->CONVCONTROL.bit.ADCACCUM = lvl;
sync_config();
}
void Adafruit_CPlay_FreeTouch::setSeriesResistor(series_resistor_t res) {
seriesres = res;
sync_config();
QTOUCH_PTC->SERRES.bit.RESISTOR = res;
sync_config();
}
void Adafruit_CPlay_FreeTouch::setFreqHopping(freq_mode_t fh, freq_hop_t hs) {
freqhop = fh;
hops = hs;
sync_config();
if (fh == FREQ_MODE_NONE) {
QTOUCH_PTC->FREQCONTROL.bit.FREQSPREADEN = 0;
QTOUCH_PTC->FREQCONTROL.bit.SAMPLEDELAY = 0;
} else {
QTOUCH_PTC->FREQCONTROL.bit.FREQSPREADEN = 1;
QTOUCH_PTC->FREQCONTROL.bit.SAMPLEDELAY = hops;
}
sync_config();
}
void Adafruit_CPlay_FreeTouch::ptcInitSettings(void) {
ptcConfigIOpin();
enablePTC(false);
QTOUCH_PTC->UNK4C04.reg &= 0xF7; //MEMORY[0x42004C04] &= 0xF7u;
QTOUCH_PTC->UNK4C04.reg &= 0xFB; //MEMORY[0x42004C04] &= 0xFBu;
QTOUCH_PTC->UNK4C04.reg &= 0xFC; //MEMORY[0x42004C04] &= 0xFCu;
sync_config();
QTOUCH_PTC->FREQCONTROL.reg &= 0x9F; //MEMORY[0x42004C0C] &= 0x9Fu;
sync_config();
QTOUCH_PTC->FREQCONTROL.reg &= 0xEF; //MEMORY[0x42004C0C] &= 0xEFu;
sync_config();
QTOUCH_PTC->FREQCONTROL.bit.SAMPLEDELAY = 0; //MEMORY[0x42004C0C] &= 0xF0u;
QTOUCH_PTC->CONTROLC.bit.INIT = 1; //MEMORY[0x42004C05] |= 1u;
QTOUCH_PTC->CONTROLA.bit.RUNINSTANDBY = 1; //MEMORY[0x42004C00] |= 4u;
sync_config();
enablePTC(true); //MEMORY[0x42004C00] |= 2u;
}
void Adafruit_CPlay_FreeTouch::ptcConfigIOpin(void) {
uint32_t ulpin = g_APinDescription[pin].ulPin;
uint32_t ulport = g_APinDescription[pin].ulPort;
PORT->Group[ulport].PINCFG[ulpin].reg = 0x3; // pmuxen + input
uint8_t curr_pmux = (PORT->Group[ulport].PMUX[ulpin/2].reg);
if (ulpin & 1) {
// pmuxodd
curr_pmux &= PORT_PMUX_PMUXE(0xF); // keep the even mux data
curr_pmux |= PORT_PMUX_PMUXO(0x1); // set to mux B
} else {
// pmuxeven
curr_pmux &= PORT_PMUX_PMUXO(0xF); // keep the odd mux data
curr_pmux |= PORT_PMUX_PMUXE(0x1); // set to mux B
}
PORT->Group[ulport].PMUX[ulpin/2].reg = curr_pmux;
}
void Adafruit_CPlay_FreeTouch::runInStandby(boolean en) {
sync_config();
if (en) {
QTOUCH_PTC->CONTROLA.bit.RUNINSTANDBY = 1;
} else {
QTOUCH_PTC->CONTROLA.bit.RUNINSTANDBY = 0;
}
sync_config();
}
void Adafruit_CPlay_FreeTouch::enablePTC(boolean en) {
sync_config();
if (en) {
QTOUCH_PTC->CONTROLA.bit.ENABLE = 1;
} else {
QTOUCH_PTC->CONTROLA.bit.ENABLE = 0;
}
sync_config();
}
void Adafruit_CPlay_FreeTouch::enableWCOint(boolean en) {
sync_config();
if (en) {
QTOUCH_PTC->INTENABLE.bit.WCO = 1;
} else {
QTOUCH_PTC->INTDISABLE.bit.WCO = 1;
}
sync_config();
}
void Adafruit_CPlay_FreeTouch::enableEOCint(boolean en) {
sync_config();
if (en) {
QTOUCH_PTC->INTENABLE.bit.EOC = 1;
} else {
QTOUCH_PTC->INTDISABLE.bit.EOC = 1;
}
sync_config();
}
void Adafruit_CPlay_FreeTouch::clearWCOintFlag(void) {
sync_config();
QTOUCH_PTC->INTFLAGS.bit.WCO = 1;
sync_config();
}
void Adafruit_CPlay_FreeTouch::clearEOCintFlag(void) {
sync_config();
QTOUCH_PTC->INTFLAGS.bit.EOC = 1;
sync_config();
}
void Adafruit_CPlay_FreeTouch::ptcAcquire(void) {
sync_config();
QTOUCH_PTC->CONVCONTROL.bit.CONVERT = 1;
sync_config();
}
void Adafruit_CPlay_FreeTouch::sync_config(void) {
while (QTOUCH_PTC->CONTROLB.bit.SYNCFLAG) ;
}
/**************************** DEBUGGING ASSIST *************************/
void Adafruit_CPlay_FreeTouch::snapshotRegsAndPrint(uint32_t base, uint8_t numregs) {
volatile uint32_t addr = base;
uint8_t datas[255];
digitalWrite(LED_BUILTIN, HIGH);
for (uint8_t i=0; i<numregs; i++) {
datas[i] = *(uint8_t *)(addr+i);
}
digitalWrite(LED_BUILTIN, LOW);
printPTCregs(base, datas, numregs);
for (uint8_t i=0; i<numregs; i++) {
// Serial.print("$"); Serial.print(addr+i, HEX); Serial.print("\t0x");
// printHex(datas[i]); Serial.println();
}
}
// Print a hex with leading zero
void Adafruit_CPlay_FreeTouch::printHex(uint8_t h, boolean newline) {
if (h < 0x10) Serial.print("0");
Serial.print(h, HEX);
if (newline) Serial.println();
}
void Adafruit_CPlay_FreeTouch::printPTCregs(uint32_t base, uint8_t *regs, uint8_t num) {
Serial.println("--------------------------------------------------------");
for (uint8_t i=0; i<num; i++) {
switch (i + base) {
case 0x41004430: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PMUX0:\t\t0x"); printHex(regs[i], true); break;
case 0x41004431: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PMUX1:\t\t0x"); printHex(regs[i], true); break;
case 0x41004432: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PMUX2:\t\t0x"); printHex(regs[i], true); break;
case 0x41004433: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PMUX3:\t\t0x"); printHex(regs[i], true); break;
case 0x41004440: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PCFG0:\t\t0x"); printHex(regs[i], true); break;
case 0x41004441: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PCFG1:\t\t0x"); printHex(regs[i], true); break;
case 0x41004442: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PCFG2:\t\t0x"); printHex(regs[i], true); break;
case 0x41004443: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PCFG3:\t\t0x"); printHex(regs[i], true); break;
case 0x41004444: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" PCFG4:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C00: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Control A:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C01: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Sync: \t\t0x"); printHex(regs[i], true); break;
case 0x42004C04: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Prescaler:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C05: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Init: \t\t0x"); printHex(regs[i], true); break;
case 0x42004C08: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Disable Irq:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C09: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Enable Irq:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C0A: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Flags: \t\t0x"); printHex(regs[i], true); break;
case 0x42004C0C: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Freq Cntl:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C0D: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Conv Cntl:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C10: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Y Select1:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C11: Serial.print("0x"); Serial.print(i+0x42004C00, HEX);
Serial.print(" Y Select2:\t\t0x"); printHex(regs[i], true); break;
/*
case 0x42004C12: Serial.print("0x"); Serial.print(i+0x42004C00, HEX);
Serial.print(" X Select1:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C13: Serial.print("0x"); Serial.print(i+0x42004C00, HEX);
Serial.print(" X Select2:\t\t0x"); printHex(regs[i], true); break;
*/
case 0x42004C14: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Y Enable1:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C15: Serial.print("0x"); Serial.print(i+0x42004C00, HEX);
Serial.print(" Y Enable2:\t\t0x"); printHex(regs[i], true); break;
/*
case 0x42004C16: Serial.print("0x"); Serial.print(i+0x42004C00, HEX);
Serial.print(" X Enable1:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C17: Serial.print("0x"); Serial.print(i+0x42004C00, HEX);
Serial.print(" X Enable2:\t\t0x"); printHex(regs[i], true); break;
*/
case 0x42004C18: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Compcap L:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C19: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Compcap H:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C1A: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Intcap: \t\t0x"); printHex(regs[i], true); break;
case 0x42004C1B: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Sense res:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C1C: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Result L:\t\t0x"); printHex(regs[i], true); break;
case 0x42004C1D: Serial.print("0x"); Serial.print(i+base, HEX);
Serial.print(" Result H:\t\t0x"); printHex(regs[i], true); break;
}
}
}
#endif