/**
* Marlin 3D Printer Firmware
* Copyright (c) 2020 MarlinFirmware [https://github.com/MarlinFirmware/Marlin]
*
* 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 .
*
*/
#pragma once
#include
#ifdef NUM_DIGITAL_PINS // Only in ST's Arduino core (STM32duino, STM32Core)
/**
* Life gets complicated if you want an easy to use 'M43 I' output (in port/pin order)
* because the variants in this platform do not always define all the I/O port/pins
* that a CPU has.
*
* VARIABLES:
* Ard_num - Arduino pin number - defined by the platform. It is used by digitalRead and
* digitalWrite commands and by M42.
* - does not contain port/pin info
* - is not in port/pin order
* - typically a variant will only assign Ard_num to port/pins that are actually used
* Index - M43 counter - only used to get Ard_num
* x - a parameter/argument used to search the pin_array to try to find a signal name
* associated with a Ard_num
* Port_pin - port number and pin number for use with CPU registers and printing reports
*
* Since M43 uses digitalRead and digitalWrite commands, only the Port_pins with an Ard_num
* are accessed and/or displayed.
*
* Three arrays are used.
*
* digitalPin[] is provided by the platform. It consists of the Port_pin numbers in
* Arduino pin number order.
*
* pin_array is a structure generated by the pins/pinsDebug.h header file. It is generated by
* the preprocessor. Only the signals associated with enabled options are in this table.
* It contains:
* - name of the signal
* - the Ard_num assigned by the pins_YOUR_BOARD.h file using the platform defines.
* EXAMPLE: "#define KILL_PIN PB1" results in Ard_num of 57. 57 is then used as an
* index into digitalPin[] to get the Port_pin number
* - if it is a digital or analog signal. PWMs are considered digital here.
*
* pin_xref is a structure generated by this header file. It is generated by the
* preprocessor. It is in port/pin order. It contains just the port/pin numbers defined by the
* platform for this variant.
* - Ard_num
* - printable version of Port_pin
*
* Routines with an "x" as a parameter/argument are used to search the pin_array to try to
* find a signal name associated with a port/pin.
*
* NOTE - the Arduino pin number is what is used by the M42 command, NOT the port/pin for that
* signal. The Arduino pin number is listed by the M43 I command.
*/
extern const PinName digitalPin[]; // provided by the platform
////////////////////////////////////////////////////////
//
// make a list of the Arduino pin numbers in the Port/Pin order
//
#define _PIN_ADD_2(NAME_ALPHA, ARDUINO_NUM) { {NAME_ALPHA}, ARDUINO_NUM },
#define _PIN_ADD(NAME_ALPHA, ARDUINO_NUM) { NAME_ALPHA, ARDUINO_NUM },
#define PIN_ADD(NAME) _PIN_ADD(#NAME, NAME)
typedef struct {
char Port_pin_alpha[5];
pin_t Ard_num;
} XrefInfo;
const XrefInfo pin_xref[] PROGMEM = {
#include "pins_Xref.h"
};
////////////////////////////////////////////////////////////
#define MODE_PIN_INPUT 0 // Input mode (reset state)
#define MODE_PIN_OUTPUT 1 // General purpose output mode
#define MODE_PIN_ALT 2 // Alternate function mode
#define MODE_PIN_ANALOG 3 // Analog mode
#define PIN_NUM(P) (P & 0x000F)
#define PIN_NUM_ALPHA_LEFT(P) (((P & 0x000F) < 10) ? ('0' + (P & 0x000F)) : '1')
#define PIN_NUM_ALPHA_RIGHT(P) (((P & 0x000F) > 9) ? ('0' + (P & 0x000F) - 10) : 0 )
#define PORT_NUM(P) ((P >> 4) & 0x0007)
#define PORT_ALPHA(P) ('A' + (P >> 4))
/**
* Translation of routines & variables used by pinsDebug.h
*/
#define NUMBER_PINS_TOTAL NUM_DIGITAL_PINS
#define VALID_PIN(ANUM) ((ANUM) >= 0 && (ANUM) < NUMBER_PINS_TOTAL)
#define digitalRead_mod(Ard_num) extDigitalRead(Ard_num) // must use Arduino pin numbers when doing reads
#define PRINT_PIN(Q)
#define PRINT_PORT(ANUM) port_print(ANUM)
#define DIGITAL_PIN_TO_ANALOG_PIN(ANUM) -1 // will report analog pin number in the print port routine
#define GET_PIN_MAP_PIN_M43(Index) pin_xref[Index].Ard_num
// x is a variable used to search pin_array
#define GET_ARRAY_IS_DIGITAL(x) ((bool) pin_array[x].is_digital)
#define GET_ARRAY_PIN(x) ((pin_t) pin_array[x].pin)
#define PRINT_ARRAY_NAME(x) do{ sprintf_P(buffer, PSTR("%-" STRINGIFY(MAX_NAME_LENGTH) "s"), pin_array[x].name); SERIAL_ECHO(buffer); }while(0)
#define MULTI_NAME_PAD 33 // space needed to be pretty if not first name assigned to a pin
#ifndef M43_NEVER_TOUCH
#define _M43_NEVER_TOUCH(Index) (Index >= 9 && Index <= 12) // SERIAL/USB pins: PA9(TX) PA10(RX) PA11(USB_DM) PA12(USB_DP)
#ifdef KILL_PIN
#define M43_NEVER_TOUCH(Index) m43_never_touch(Index)
bool m43_never_touch(const pin_t Index) {
static pin_t M43_kill_index = -1;
if (M43_kill_index < 0)
for (M43_kill_index = 0; M43_kill_index < NUMBER_PINS_TOTAL; M43_kill_index++)
if (KILL_PIN == GET_PIN_MAP_PIN_M43(M43_kill_index)) break;
return _M43_NEVER_TOUCH(Index) || Index == M43_kill_index; // KILL_PIN and SERIAL/USB
}
#else
#define M43_NEVER_TOUCH(Index) _M43_NEVER_TOUCH(Index)
#endif
#endif
uint8_t get_pin_mode(const pin_t Ard_num) {
uint32_t mode_all = 0;
const PinName dp = digitalPin[Ard_num];
switch (PORT_ALPHA(dp)) {
case 'A' : mode_all = GPIOA->MODER; break;
case 'B' : mode_all = GPIOB->MODER; break;
case 'C' : mode_all = GPIOC->MODER; break;
case 'D' : mode_all = GPIOD->MODER; break;
#ifdef PE_0
case 'E' : mode_all = GPIOE->MODER; break;
#elif defined(PF_0)
case 'F' : mode_all = GPIOF->MODER; break;
#elif defined(PG_0)
case 'G' : mode_all = GPIOG->MODER; break;
#elif defined(PH_0)
case 'H' : mode_all = GPIOH->MODER; break;
#elif defined(PI_0)
case 'I' : mode_all = GPIOI->MODER; break;
#elif defined(PJ_0)
case 'J' : mode_all = GPIOJ->MODER; break;
#elif defined(PK_0)
case 'K' : mode_all = GPIOK->MODER; break;
#elif defined(PL_0)
case 'L' : mode_all = GPIOL->MODER; break;
#endif
}
return (mode_all >> (2 * uint8_t(PIN_NUM(dp)))) & 0x03;
}
bool GET_PINMODE(const pin_t Ard_num) {
const uint8_t pin_mode = get_pin_mode(Ard_num);
return pin_mode == MODE_PIN_OUTPUT || pin_mode == MODE_PIN_ALT; // assume all alt definitions are PWM
}
int8_t digital_pin_to_analog_pin(pin_t Ard_num) {
Ard_num -= NUM_ANALOG_FIRST;
return (Ard_num >= 0 && Ard_num < NUM_ANALOG_INPUTS) ? Ard_num : -1;
}
bool IS_ANALOG(const pin_t Ard_num) {
return get_pin_mode(Ard_num) == MODE_PIN_ANALOG;
}
bool is_digital(const pin_t x) {
const uint8_t pin_mode = get_pin_mode(pin_array[x].pin);
return pin_mode == MODE_PIN_INPUT || pin_mode == MODE_PIN_OUTPUT;
}
void port_print(const pin_t Ard_num) {
char buffer[16];
pin_t Index;
for (Index = 0; Index < NUMBER_PINS_TOTAL; Index++)
if (Ard_num == GET_PIN_MAP_PIN_M43(Index)) break;
const char * ppa = pin_xref[Index].Port_pin_alpha;
sprintf_P(buffer, PSTR("%s"), ppa);
SERIAL_ECHO(buffer);
if (ppa[3] == '\0') SERIAL_CHAR(' ');
// print analog pin number
const int8_t Port_pin = digital_pin_to_analog_pin(Ard_num);
if (Port_pin >= 0) {
sprintf_P(buffer, PSTR(" (A%d) "), Port_pin);
SERIAL_ECHO(buffer);
if (Port_pin < 10) SERIAL_CHAR(' ');
}
else
SERIAL_ECHO_SP(7);
// Print number to be used with M42
sprintf_P(buffer, PSTR(" M42 P%d "), Ard_num);
SERIAL_ECHO(buffer);
if (Ard_num < 10) SERIAL_CHAR(' ');
if (Ard_num < 100) SERIAL_CHAR(' ');
}
bool pwm_status(const pin_t Ard_num) {
return get_pin_mode(Ard_num) == MODE_PIN_ALT;
}
void pwm_details(const pin_t Ard_num) {
if (pwm_status(Ard_num)) {
uint32_t alt_all = 0;
const PinName dp = digitalPin[Ard_num];
pin_t pin_number = uint8_t(PIN_NUM(dp));
const bool over_7 = pin_number >= 8;
const uint8_t ind = over_7 ? 1 : 0;
switch (PORT_ALPHA(dp)) { // get alt function
case 'A' : alt_all = GPIOA->AFR[ind]; break;
case 'B' : alt_all = GPIOB->AFR[ind]; break;
case 'C' : alt_all = GPIOC->AFR[ind]; break;
case 'D' : alt_all = GPIOD->AFR[ind]; break;
#ifdef PE_0
case 'E' : alt_all = GPIOE->AFR[ind]; break;
#elif defined (PF_0)
case 'F' : alt_all = GPIOF->AFR[ind]; break;
#elif defined (PG_0)
case 'G' : alt_all = GPIOG->AFR[ind]; break;
#elif defined (PH_0)
case 'H' : alt_all = GPIOH->AFR[ind]; break;
#elif defined (PI_0)
case 'I' : alt_all = GPIOI->AFR[ind]; break;
#elif defined (PJ_0)
case 'J' : alt_all = GPIOJ->AFR[ind]; break;
#elif defined (PK_0)
case 'K' : alt_all = GPIOK->AFR[ind]; break;
#elif defined (PL_0)
case 'L' : alt_all = GPIOL->AFR[ind]; break;
#endif
}
if (over_7) pin_number -= 8;
uint8_t alt_func = (alt_all >> (4 * pin_number)) & 0x0F;
SERIAL_ECHOPAIR("Alt Function: ", alt_func);
if (alt_func < 10) SERIAL_CHAR(' ');
SERIAL_ECHOPGM(" - ");
switch (alt_func) {
case 0 : SERIAL_ECHOPGM("system (misc. I/O)"); break;
case 1 : SERIAL_ECHOPGM("TIM1/TIM2 (probably PWM)"); break;
case 2 : SERIAL_ECHOPGM("TIM3..5 (probably PWM)"); break;
case 3 : SERIAL_ECHOPGM("TIM8..11 (probably PWM)"); break;
case 4 : SERIAL_ECHOPGM("I2C1..3"); break;
case 5 : SERIAL_ECHOPGM("SPI1/SPI2"); break;
case 6 : SERIAL_ECHOPGM("SPI3"); break;
case 7 : SERIAL_ECHOPGM("USART1..3"); break;
case 8 : SERIAL_ECHOPGM("USART4..6"); break;
case 9 : SERIAL_ECHOPGM("CAN1/CAN2, TIM12..14 (probably PWM)"); break;
case 10 : SERIAL_ECHOPGM("OTG"); break;
case 11 : SERIAL_ECHOPGM("ETH"); break;
case 12 : SERIAL_ECHOPGM("FSMC, SDIO, OTG"); break;
case 13 : SERIAL_ECHOPGM("DCMI"); break;
case 14 : SERIAL_ECHOPGM("unused (shouldn't see this)"); break;
case 15 : SERIAL_ECHOPGM("EVENTOUT"); break;
}
}
} // pwm_details
#endif // NUM_DIGITAL_PINS