Wemos8266RelaysLedDisplay/src/mapper_main.txt

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// Test software to map display hardware rows and columns
// Generic SPI interface and only one MAX72xx/8x8 LED module required
//
// Does not use any libraries as the code is used to directly map the display orientation
// Observe the display and relate it to the MAX7219 hardware being exercised through the
// instructions and output on the serial monitor.
//
// NOTE: You need to change the hardware pins to match your specific setup
#include <Arduino.h>
#include <SPI.h>
#define SERIAL_SPEED 115200
// Hardware definition
#define CLK_PIN D5 // or SCK
#define DATA_PIN D7 // or MOSI
#define CS_PIN D6 // or SS
// Opcodes for the MAX7221 and MAX7219
// All OP_DIGITn are offsets from OP_DIGIT0
#define OP_NOOP 0 ///< MAX72xx opcode for NO OP
#define OP_DIGIT0 1 ///< MAX72xx opcode for DIGIT0
#define OP_DIGIT1 2 ///< MAX72xx opcode for DIGIT1
#define OP_DIGIT2 3 ///< MAX72xx opcode for DIGIT2
#define OP_DIGIT3 4 ///< MAX72xx opcode for DIGIT3
#define OP_DIGIT4 5 ///< MAX72xx opcode for DIGIT4
#define OP_DIGIT5 6 ///< MAX72xx opcode for DIGIT5
#define OP_DIGIT6 7 ///< MAX72xx opcode for DIGIT6
#define OP_DIGIT7 8 ///< MAX72xx opcode for DIGIT7
#define OP_DECODEMODE 9 ///< MAX72xx opcode for DECODE MODE
#define OP_INTENSITY 10 ///< MAX72xx opcode for SET INTENSITY
#define OP_SCANLIMIT 11 ///< MAX72xx opcode for SCAN LIMIT
#define OP_SHUTDOWN 12 ///< MAX72xx opcode for SHUT DOWN
#define OP_DISPLAYTEST 15 ///< MAX72xx opcode for DISPLAY TEST
#define MAX_DIG 8
#define MAX_SEG 8
#define USER_DELAY 1000 // ms
void spiTransmit(uint8_t opCode, uint8_t data)
{
// enable the devices to receive data
digitalWrite(CS_PIN, LOW);
// shift out the data
shiftOut(DATA_PIN, CLK_PIN, MSBFIRST, opCode);
shiftOut(DATA_PIN, CLK_PIN, MSBFIRST, data);
// latch the data onto the display
digitalWrite(CS_PIN, HIGH);
}
void instructions(void)
{
Serial.print(F("\nINTRODUCTION\n------------"));
Serial.print(F("\nHow the LED matrix is wired is important for the MD_MAX72xx library as different"));
Serial.print(F("\nLED modules are wired differently. The library can accommodate these, but it"));
Serial.print(F("\nneeds to know what transformations need to be carried out to map your board to the"));
Serial.print(F("\nstandard coordinate system. This utility shows you how the matrix is wired so that"));
Serial.print(F("\nyou can set the correct *_HW module type for your application."));
Serial.print(F("\n\nThe standard functions in the library expect that:"));
Serial.print(F("\no COLUMNS are addressed through the SEGMENT selection lines, and"));
Serial.print(F("\no ROWS are addressed through the DIGIT selection lines."));
Serial.print(F("\n\nThe DISPLAY always has its origin in the top right corner of a display:"));
Serial.print(F("\no LED matrix module numbers increase from right to left,"));
Serial.print(F("\no Column numbers (ie, the hardware segment numbers) increase from right to left (0..7), and "));
Serial.print(F("\no Row numbers (ie, the hardware digit numbers) increase down (0..7)."));
Serial.print(F("\n\nThere are three hardware setting that describe your hardware configuration:"));
Serial.print(F("\n- HW_DIG_ROWS - HardWare DIGits are ROWS. This will be 1 if the digits map to the rows"));
Serial.print(F("\n of the matrix, 0 otherwise"));
Serial.print(F("\n- HW_REV_COLS - HardWare REVerse COLumnS. The normal column coordinates orientation"));
Serial.print(F("\n is col 0 on the right side of the display. This will be 1 if reversed."));
Serial.print(F("\n (ie, hardware 0 is on the left)."));
Serial.print(F("\n- HW_REV_ROWS - HardWare REVerse ROWS. The normal row coordinates orientation is row"));
Serial.print(F("\n 0 at top of the display. This will be 1 if reversed (ie, row 0"));
Serial.print(F("\n is at the bottom)."));
Serial.print(F("\n\nThese individual setting then determine the model type of the hardware you are using."));
Serial.print(F("\n\nINSTRUCTIONS\n------------"));
Serial.print(F("\n1. Wire up one matrix only, or cover up the other modules, to avoid confusion."));
Serial.print(F("\n2. Enter the answers to the question in the edit field at the top of Serial Monitor."));
}
void setup(void)
{
Serial.begin(SERIAL_SPEED);
Serial.print(F("\n\n[MD_MAX72xx Hardware mapping utility]\n"));
instructions();
// Initialize comms hardware
digitalWrite(CS_PIN, HIGH);
pinMode(CS_PIN, OUTPUT);
pinMode(DATA_PIN, OUTPUT);
pinMode(CLK_PIN, OUTPUT);
}
void initialize(void)
// Initialize the display devices.
// On initial power-up, all control registers are reset, the
// display is blanked, and the MAX7219/MAX7221 enters shutdown
// mode.
{
spiTransmit(OP_SHUTDOWN, 1); // wake up
spiTransmit(OP_SCANLIMIT, 7); // all on
spiTransmit(OP_INTENSITY, 7); // mid intensity
spiTransmit(OP_DISPLAYTEST, 0); // no test
spiTransmit(OP_DECODEMODE, 0); // no decode
}
void mapSegment(char *label, uint8_t data)
{
Serial.print(F("-"));
Serial.print(label);
spiTransmit(OP_DIGIT0, data);
delay(USER_DELAY);
}
void mapDigit(uint8_t opCode)
{
Serial.print(F("-"));
Serial.print(opCode - OP_DIGIT0);
spiTransmit(opCode, 0xff);
delay(USER_DELAY);
spiTransmit(opCode, 0x0);
}
void clear(void)
{
for (uint8_t i=0; i<MAX_DIG; i++)
spiTransmit(OP_DIGIT0 + i, 0);
}
char getResponse(char *validInput)
// blocking wait for user input from the serial monitor
{
char c = '\0';
do
{
if (Serial.available())
{
uint8_t i;
c = Serial.read();
for (i=0; validInput[i] != '\0' && validInput[i] != c; i++)
; // set the index I to the matching character or nul if none - all work done in the loop
c = validInput[i]; // could be nul character
}
} while (c == '\0');
Serial.print(c);
return(toupper(c));
}
void loop()
{
boolean def_dig_rows, def_rev_cols, def_rev_rows;
clear();
Serial.print(F("\n\n======================================================"));
Serial.print(F("\n\nSTEP 1 - DIGITS MAPPING (rows)\n------------------------------"));
Serial.print(F("\nIn this step you will see a line moving across the LED matrix."));
Serial.print(F("\nYou need to observe whether the bar is scanning ROWS or COLUMNS,"));
Serial.print(F("\nand the direction it is moving."));
Serial.print(F("\n>> Enter Y when you are ready to start: "));
getResponse("Yy");
initialize();
Serial.print("\nDig");
for (uint8_t i=0; i<MAX_DIG; i++)
mapDigit(OP_DIGIT0+i);
clear();
Serial.print(F("\n>> Enter Y if you saw ROWS animated, N if you saw COLUMNS animated: "));
def_dig_rows = (getResponse("YyNn") == 'Y');
if (def_dig_rows)
Serial.print(F("\n>> Enter Y if you saw the line moving BOTTOM to TOP, or enter N otherwise: "));
else
Serial.print(F("\n>> Enter Y if you saw the line moving LEFT to RIGHT, or enter N otherwise: "));
def_rev_rows = (getResponse("YyNn") == 'Y');
Serial.print(F("\n\nSTEP 2 - SEGMENT MAPPING (columns)\n----------------------------------"));
Serial.print(F("\nIn this step you will see a dot moving along one edge of the LED matrix."));
Serial.print(F("\nYou need to observe the direction it is moving."));
Serial.print(F("\n>> Enter Y when you are ready to start: "));
getResponse ("Yy");
Serial.print(F("\nSeg"));
mapSegment("G", 1);
mapSegment("F", 2);
mapSegment("E", 4);
mapSegment("D", 8);
mapSegment("C", 16);
mapSegment("B", 32);
mapSegment("A", 64);
mapSegment("DP", 128);
clear();
if (def_dig_rows)
Serial.print(F("\n>> Enter Y if you saw the LED moving LEFT to RIGHT, or enter N otherwise: "));
else
Serial.print(F("\n>> Enter Y if you saw the LED moving BOTTOM to TOP, or enter N otherwise: "));
def_rev_cols = (getResponse("YyNn") == 'Y');
Serial.print(F("\n\nSTEP 3 - RESULTS\n----------------"));
Serial.print(F("\nYour responses produce these hardware parameters\n"));
Serial.print(F("\nHW_DIG_ROWS\t")); Serial.print(def_dig_rows ? 1 : 0 );
Serial.print(F("\nHW_REV_COLS\t")); Serial.print(def_rev_cols ? 1 : 0 );
Serial.print(F("\nHW_REV_ROWS\t")); Serial.print(def_rev_rows ? 1 : 0 );
Serial.print(F("\n\nYour hardware matches the setting for "));
if (def_dig_rows && def_rev_cols && !def_rev_rows)
Serial.print(F("Parola modules. Please set PAROLA_HW."));
else if (!def_dig_rows && def_rev_cols && !def_rev_rows)
Serial.print(F("Generic modules. Please set GENERIC_HW."));
else if (def_dig_rows && def_rev_cols && def_rev_rows)
Serial.print(F("IC Station modules. Please set ICSTATION_HW."));
else if (def_dig_rows && !def_rev_cols && !def_rev_rows)
Serial.print(F("FC-16 modules. Please set FC16_HW."));
else
{
Serial.print(F("none of the preconfigured module types."));
Serial.print(F("\nYou should try rotating the matrix by 180 degrees and re-running this utility."));
Serial.print(F("\n\nIf that still fails to provide a solution - congratulations! You have discovered"));
Serial.print(F("\na new type of hardware module! Please contact the author of the libraries so that"));
Serial.print(F("\nthese can be included in the next official release."));
}
}