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TEST
Dependents: ADXL345Test ADXL345Test1
Fork of
TM1638
by 
Wim Huiskamp
TM1638.cpp
- Committer:
- wim
- Date:
- 2016-01-31
- Revision:
- 4:b2bbdc58967e
- Parent:
- 3:25ddabfadc8c
- Child:
- 5:a4634cc2ab71
File content as of revision 4:b2bbdc58967e:
/* mbed TM1638 Library, for TM1638 LED controller
* Copyright (c) 2015, v01: WH, Initial version
* 2016, v02: WH, Added ASCII alphabet display selector, refactored display and keyboard defines
* 2016, v03: WH, Added QYF-TM1638 and LKM1638, refactoring of writeData()
*
* 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 "mbed.h"
#include "TM1638.h"
/** Constructor for class for driving TM1638 LED controller with SPI bus interface device.
* @brief Supports 8 digits @ 10 segments.
* Also supports a scanned keyboard of upto 24 keys.
*
* @param PinName mosi, miso, sclk, cs SPI bus pins
*/
TM1638::TM1638(PinName mosi, PinName miso, PinName sclk, PinName cs) : _spi(mosi,miso,sclk), _cs(cs) {
_init();
}
/** Init the SPI interface and the controller
* @param none
* @return none
*/
void TM1638::_init(){
//init SPI
_cs=1;
_spi.format(8,3); //TM1638 uses mode 3 (Clock High on Idle, Data latched on second (=rising) edge)
_spi.frequency(500000);
//init controller
_display = TM1638_DSP_ON;
_bright = TM1638_BRT_DEF;
_writeCmd(TM1638_DSP_CTRL_CMD, _display | _bright ); // Display control cmd, display on/off, brightness
_writeCmd(TM1638_DATA_SET_CMD, TM1638_DATA_WR | TM1638_ADDR_INC | TM1638_MODE_NORM); // Data set cmd, normal mode, auto incr, write data
}
/** Clear the screen and locate to 0
*/
void TM1638::cls() {
_cs=0;
wait_us(1);
_spi.write(_flip(TM1638_ADDR_SET_CMD | 0x00)); // Address set cmd, 0
for (int cnt=0; cnt<TM1638_DISPLAY_MEM; cnt++) {
_spi.write(0x00); // data
}
wait_us(1);
_cs=1;
}
/** Set Brightness
*
* @param char brightness (3 significant bits, valid range 0..7 (1/16 .. 14/14 dutycycle)
* @return none
*/
void TM1638::setBrightness(char brightness){
_bright = brightness & TM1638_BRT_MSK; // mask invalid bits
_writeCmd(TM1638_DSP_CTRL_CMD, _display | _bright ); // Display control cmd, display on/off, brightness
}
/** Set the Display mode On/off
*
* @param bool display mode
*/
void TM1638::setDisplay(bool on) {
if (on) {
_display = TM1638_DSP_ON;
}
else {
_display = TM1638_DSP_OFF;
}
_writeCmd(TM1638_DSP_CTRL_CMD, _display | _bright ); // Display control cmd, display on/off, brightness
}
/** Write databyte to TM1638
* @param char data byte written at given address
* @param int address display memory location to write byte
* @return none
*/
void TM1638::writeData(char data, int address) {
_cs=0;
wait_us(1);
_spi.write(_flip(TM1638_ADDR_SET_CMD | (address & TM1638_ADDR_MSK))); // Set Address cmd
_spi.write(_flip(data)); // data
wait_us(1);
_cs=1;
}
/** Write Display datablock to TM1638
* @param DisplayData_t data Array of TM1638_DISPLAY_MEM (=16) bytes for displaydata
* @param length number bytes to write (valid range 0..TM1638_DISPLAY_MEM (=16), when starting at address 0)
* @param int address display memory location to write bytes (default = 0)
* @return none
*/
void TM1638::writeData(DisplayData_t data, int length, int address) {
_cs=0;
wait_us(1);
// sanity check
address &= TM1638_ADDR_MSK;
if (length < 0) {length = 0;}
if ((length + address) > TM1638_DISPLAY_MEM) {length = (TM1638_DISPLAY_MEM - address);}
// _spi.write(_flip(TM1638_ADDR_SET_CMD | 0x00)); // Set Address at 0
_spi.write(_flip(TM1638_ADDR_SET_CMD | address)); // Set Address
for (int idx=0; idx<length; idx++) {
//_spi.write(_flip(data[idx])); // data
_spi.write(_flip(data[address + idx])); // data
}
wait_us(1);
_cs=1;
}
/** Read keydata block from TM1638
* @param *keydata Ptr to Array of TM1638_KEY_MEM (=4) bytes for keydata
* @return bool keypress True when at least one key was pressed
*
* Note: Due to the hardware configuration the TM1638 key matrix scanner will detect multiple keys pressed at same time,
* but this may also result in some spurious keys being set in keypress data array.
* It may be best to ignore all keys in those situations. That option is implemented in this method depending on #define setting.
*/
bool TM1638::getKeys(KeyData_t *keydata) {
int keypress = 0;
char data;
// Read keys
_cs=0;
wait_us(1);
// Enable Key Read mode
_spi.write(_flip(TM1638_DATA_SET_CMD | TM1638_KEY_RD | TM1638_ADDR_INC | TM1638_MODE_NORM)); // Data set cmd, normal mode, auto incr, read data
for (int idx=0; idx < TM1638_KEY_MEM; idx++) {
data = _flip(_spi.write(0xFF)); // read keys and correct bitorder
data = data & TM1638_KEY_MSK; // Mask valid bits
if (data != 0) { // Check for any pressed key
for (int bit=0; bit < 8; bit++) {
if (data & (1 << bit)) {keypress++;} // Test all significant bits
}
}
(*keydata)[idx] = data; // Store keydata after correcting bitorder
}
wait_us(1);
_cs=1;
// Restore Data Write mode
_writeCmd(TM1638_DATA_SET_CMD, TM1638_DATA_WR | TM1638_ADDR_INC | TM1638_MODE_NORM); // Data set cmd, normal mode, auto incr, write data
#if(1)
// Dismiss multiple keypresses at same time
return (keypress == 1);
#else
// Allow multiple keypress and accept possible spurious keys
return (keypress > 0);
#endif
}
/** Helper to reverse all command or databits. The TM1638 expects LSB first, whereas SPI is MSB first
* @param char data
* @return bitreversed data
*/
#if(1)
char TM1638::_flip(char data) {
char value=0;
if (data & 0x01) {value |= 0x80;} ;
if (data & 0x02) {value |= 0x40;} ;
if (data & 0x04) {value |= 0x20;} ;
if (data & 0x08) {value |= 0x10;} ;
if (data & 0x10) {value |= 0x08;} ;
if (data & 0x20) {value |= 0x04;} ;
if (data & 0x40) {value |= 0x02;} ;
if (data & 0x80) {value |= 0x01;} ;
return value;
}
#else
char TM1638::_flip(char data) {
data = (((data & 0xAA) >> 1) | ((data & 0x55) << 1));
data = (((data & 0xCC) >> 2) | ((data & 0x33) << 2));
return (((data & 0xF0) >> 4) | ((data & 0x0F) << 4));
}
#endif
/** Write command and parameter to TM1638
* @param int cmd Command byte
* &Param int data Parameters for command
* @return none
*/
void TM1638::_writeCmd(int cmd, int data){
_cs=0;
wait_us(1);
// _spi.write(_flip( (cmd & 0xF0) | (data & 0x0F)));
_spi.write(_flip( (cmd & TM1638_CMD_MSK) | (data & ~TM1638_CMD_MSK)));
wait_us(1);
_cs=1;
}
#if (LEDKEY8_TEST == 1)
// Derived class for TM1638 used in LED&KEY display unit
//
/** Constructor for class for driving TM1638 LED controller as used in LEDKEY8
*
* @brief Supports 8 Digits of 7 Segments + DP + LED Icons. Also supports a scanned keyboard of 8.
*
* @param PinName mosi, miso, sclk, cs SPI bus pins
*/
TM1638_LEDKEY8::TM1638_LEDKEY8(PinName mosi, PinName miso, PinName sclk, PinName cs) : TM1638(mosi, miso, sclk, cs) {
_column = 0;
_columns = LEDKEY8_NR_DIGITS;
}
#if(0)
#if DOXYGEN_ONLY
/** Write a character to the Display
*
* @param c The character to write to the display
*/
int putc(int c);
/** Write a formatted string to the Display
*
* @param format A printf-style format string, followed by the
* variables to use in formatting the string.
*/
int printf(const char* format, ...);
#endif
#endif
/** Locate cursor to a screen column
*
* @param column The horizontal position from the left, indexed from 0
*/
void TM1638_LEDKEY8::locate(int column) {
//sanity check
if (column < 0) {column = 0;}
if (column > (_columns - 1)) {column = _columns - 1;}
_column = column;
}
/** Number of screen columns
*
* @param none
* @return columns
*/
int TM1638_LEDKEY8::columns() {
return _columns;
}
/** Clear the screen and locate to 0
* @param bool clrAll Clear Icons also (default = false)
*/
void TM1638_LEDKEY8::cls(bool clrAll) {
if (clrAll) {
//clear local buffer (including Icons)
for (int idx=0; idx < (LEDKEY8_NR_GRIDS << 1); idx++) {
_displaybuffer[idx] = 0x00;
}
}
else {
//clear local buffer (preserving Icons)
for (int idx=0; idx < LEDKEY8_NR_GRIDS; idx++) {
_displaybuffer[(idx<<1)] = _displaybuffer[(idx<<1)] & MASK_ICON_GRID[idx][0];
_displaybuffer[(idx<<1) + 1] = _displaybuffer[(idx<<1) + 1] & MASK_ICON_GRID[idx][1];
}
}
writeData(_displaybuffer, (LEDKEY8_NR_GRIDS * TM1638_BYTES_PER_GRID));
_column = 0;
}
/** Set Icon
*
* @param Icon icon Enums Icon has Grid position encoded in 8 MSBs, Icon pattern encoded in 16 LSBs
* @return none
*/
void TM1638_LEDKEY8::setIcon(Icon icon) {
int addr, icn;
icn = icon & 0xFFFF;
addr = (icon >> 24) & 0xFF;
addr = (addr - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save char...and set bits for icon to write
_displaybuffer[addr] = _displaybuffer[addr] | LO(icn);
_displaybuffer[addr+1] = _displaybuffer[addr+1] | HI(icn);
// writeData(_displaybuffer, (LEDKEY8_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
}
/** Clr Icon
*
* @param Icon icon Enums Icon has Grid position encoded in 8 MSBs, Icon pattern encoded in 16 LSBs
* @return none
*/
void TM1638_LEDKEY8::clrIcon(Icon icon) {
int addr, icn;
icn = icon & 0xFFFF;
addr = (icon >> 24) & 0xFF;
addr = (addr - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save char...and clr bits for icon to write
_displaybuffer[addr] = _displaybuffer[addr] & ~LO(icn);
_displaybuffer[addr+1] = _displaybuffer[addr+1] & ~HI(icn);
// writeData(_displaybuffer, (LEDKEY8_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
}
/** Set User Defined Characters (UDC)
*
* @param unsigned char udc_idx The Index of the UDC (0..7)
* @param int udc_data The bitpattern for the UDC (8 bits)
*/
void TM1638_LEDKEY8::setUDC(unsigned char udc_idx, int udc_data) {
//Sanity check
if (udc_idx > (LEDKEY8_NR_UDC-1)) {
return;
}
// Mask out Icon bits?
_UDC_7S[udc_idx] = LO(udc_data);
}
/** Write a single character (Stream implementation)
*/
int TM1638_LEDKEY8::_putc(int value) {
int addr;
bool validChar = false;
char pattern = 0x00;
if ((value == '\n') || (value == '\r')) {
//No character to write
validChar = false;
//Update Cursor
_column = 0;
}
else if ((value == '.') || (value == ',')) {
//No character to write
validChar = false;
pattern = S7_DP; // placeholder for all DPs
// Check to see that DP can be shown for current column
if (_column > 0) {
//Translate between _column and displaybuffer entries
//Add DP to bitpattern of digit left of current column.
addr = (_column - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save icons...and set bits for decimal point to write
_displaybuffer[addr] = _displaybuffer[addr] | pattern;
// _displaybuffer[addr+1] = _displaybuffer[addr+1] | pattern;
// writeData(_displaybuffer, (LEDKEY8_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
//No Cursor Update
}
}
else if ((value >= 0) && (value < LEDKEY8_NR_UDC)) {
//Character to write
validChar = true;
pattern = _UDC_7S[value];
}
#if (SHOW_ASCII == 1)
//display all ASCII characters
else if ((value >= FONT_7S_START) && (value <= FONT_7S_END)) {
//Character to write
validChar = true;
pattern = FONT_7S[value - FONT_7S_START];
} // else
#else
//display only digits and hex characters
else if (value == '-') {
//Character to write
validChar = true;
pattern = C7_MIN;
}
else if ((value >= (int)'0') && (value <= (int) '9')) {
//Character to write
validChar = true;
pattern = FONT_7S[value - (int) '0'];
}
else if ((value >= (int) 'A') && (value <= (int) 'F')) {
//Character to write
validChar = true;
pattern = FONT_7S[10 + value - (int) 'A'];
}
else if ((value >= (int) 'a') && (value <= (int) 'f')) {
//Character to write
validChar = true;
pattern = FONT_7S[10 + value - (int) 'a'];
} //else
#endif
if (validChar) {
//Character to write
//Translate between _column and displaybuffer entries
addr = _column << 1; // * TM1638_BYTES_PER_GRID
//Save icons...and set bits for character to write
_displaybuffer[addr] = (_displaybuffer[addr] & MASK_ICON_GRID[_column][0]) | pattern;
// _displaybuffer[addr+1] = (_displaybuffer[addr+1] & MASK_ICON_GRID[_column][0]) | pattern;
// writeData(_displaybuffer, (LEDKEY8_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
//Update Cursor
_column++;
if (_column > (LEDKEY8_NR_DIGITS - 1)) {
_column = 0;
}
} // if validChar
return value;
}
// get a single character (Stream implementation)
int TM1638_LEDKEY8::_getc() {
return -1;
}
#endif
#if (QYF_TEST == 1)
// Derived class for TM1638 used in QYF-TM1638 display unit
//
/** Constructor for class for driving TM1638 LED controller as used in QYF
*
* @brief Supports 8 Digits of 7 Segments + DP. Also supports a scanned keyboard of 16 keys.
*
* @param PinName mosi, miso, sclk, cs SPI bus pins
*/
TM1638_QYF::TM1638_QYF(PinName mosi, PinName miso, PinName sclk, PinName cs) : TM1638(mosi, miso, sclk, cs) {
_column = 0;
_columns = QYF_NR_DIGITS;
}
#if(0)
#if DOXYGEN_ONLY
/** Write a character to the Display
*
* @param c The character to write to the display
*/
int putc(int c);
/** Write a formatted string to the Display
*
* @param format A printf-style format string, followed by the
* variables to use in formatting the string.
*/
int printf(const char* format, ...);
#endif
#endif
/** Locate cursor to a screen column
*
* @param column The horizontal position from the left, indexed from 0
*/
void TM1638_QYF::locate(int column) {
//sanity check
if (column < 0) {column = 0;}
if (column > (_columns - 1)) {column = _columns - 1;}
_column = column;
}
/** Number of screen columns
*
* @param none
* @return columns
*/
int TM1638_QYF::columns() {
return _columns;
}
/** Clear the screen and locate to 0
* @param bool clrAll Clear Icons also (default = false)
*/
void TM1638_QYF::cls(bool clrAll) {
if (clrAll) {
//clear local buffer (including Icons)
for (int idx=0; idx < (QYF_NR_GRIDS << 1); idx++) {
_displaybuffer[idx] = 0x00;
}
}
else {
//clear local buffer (preserving Icons)
for (int idx=0; idx < QYF_NR_GRIDS; idx++) {
_displaybuffer[(idx<<1)] = _displaybuffer[(idx<<1)] & MASK_ICON_GRID[idx][0];
_displaybuffer[(idx<<1) + 1] = _displaybuffer[(idx<<1) + 1] & MASK_ICON_GRID[idx][1];
}
}
writeData(_displaybuffer, (QYF_NR_GRIDS * TM1638_BYTES_PER_GRID));
_column = 0;
}
/** Set Icon
*
* @param Icon icon Enums Icon has Grid position encoded in 8 MSBs, Icon pattern encoded in 16 LSBs
* @return none
*/
void TM1638_QYF::setIcon(Icon icon) {
int addr, icn;
icn = icon & 0xFFFF;
addr = (icon >> 24) & 0xFF;
addr = (addr - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save char...and set bits for icon to write
_displaybuffer[addr] = _displaybuffer[addr] | LO(icn);
_displaybuffer[addr+1] = _displaybuffer[addr+1] | HI(icn);
// writeData(_displaybuffer, (QYF_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
}
/** Clr Icon
*
* @param Icon icon Enums Icon has Grid position encoded in 8 MSBs, Icon pattern encoded in 16 LSBs
* @return none
*/
void TM1638_QYF::clrIcon(Icon icon) {
int addr, icn;
icn = icon & 0xFFFF;
addr = (icon >> 24) & 0xFF;
addr = (addr - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save char...and clr bits for icon to write
_displaybuffer[addr] = _displaybuffer[addr] & ~LO(icn);
_displaybuffer[addr+1] = _displaybuffer[addr+1] & ~HI(icn);
// writeData(_displaybuffer, (QYF_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
}
/** Set User Defined Characters (UDC)
*
* @param unsigned char udc_idx The Index of the UDC (0..7)
* @param int udc_data The bitpattern for the UDC (8 bits)
*/
void TM1638_QYF::setUDC(unsigned char udc_idx, int udc_data) {
//Sanity check
if (udc_idx > (QYF_NR_UDC-1)) {
return;
}
// Mask out Icon bits?
_UDC_7S[udc_idx] = LO(udc_data);
}
/** Write a single character (Stream implementation)
*/
int TM1638_QYF::_putc(int value) {
bool validChar = false;
char pattern = 0x00;
char bit = 0x00;
if ((value == '\n') || (value == '\r')) {
//No character to write
validChar = false;
//Update Cursor
_column = 0;
}
else if ((value == '.') || (value == ',')) {
//No character to write
validChar = false;
pattern = S7_DP; // placeholder for all DPs
// Check to see that DP can be shown for current column
if (_column > 0) {
//Add DP to bitpattern of digit left of current column.
bit = 1 << (8 - _column); // bitposition for the previous _column
_displaybuffer[14] = (_displaybuffer[14] | bit); // set bit
writeData(_displaybuffer, (QYF_NR_GRIDS * TM1638_BYTES_PER_GRID));
//No Cursor Update
}
}
else if ((value >= 0) && (value < QYF_NR_UDC)) {
//Character to write
validChar = true;
pattern = _UDC_7S[value];
}
#if (SHOW_ASCII == 1)
//display all ASCII characters
else if ((value >= FONT_7S_START) && (value <= FONT_7S_END)) {
//Character to write
validChar = true;
pattern = FONT_7S[value - FONT_7S_START];
} // else
#else
//display only digits and hex characters
else if (value == '-') {
//Character to write
validChar = true;
pattern = C7_MIN;
}
else if ((value >= (int)'0') && (value <= (int) '9')) {
//Character to write
validChar = true;
pattern = FONT_7S[value - (int) '0'];
}
else if ((value >= (int) 'A') && (value <= (int) 'F')) {
//Character to write
validChar = true;
pattern = FONT_7S[10 + value - (int) 'A'];
}
else if ((value >= (int) 'a') && (value <= (int) 'f')) {
//Character to write
validChar = true;
pattern = FONT_7S[10 + value - (int) 'a'];
} //else
#endif
if (validChar) {
//Character to write
// Very annoying bitmapping :(
// This display module uses a single byte of each grid to drive a specific segment of all digits.
// So the bits in byte 0 (Grid 1) drive all A-segments, the bits in byte 2 (Grid 2) drive all B-segments etc.
// Bit0 is for the segment in Digit 8, Bit1 is for the segment in Digit 7 etc.. This bit manipulation is handled in _putc().
bit = 1 << (7 - _column); // bitposition for the current _column
if (pattern & S7_A) {_displaybuffer[0] = (_displaybuffer[0] | bit); } // set bit
else {_displaybuffer[0] = (_displaybuffer[0] & ~bit);} // clr bit
if (pattern & S7_B) {_displaybuffer[2] = (_displaybuffer[2] | bit); } // set bit
else {_displaybuffer[2] = (_displaybuffer[2] & ~bit);} // clr bit
if (pattern & S7_C) {_displaybuffer[4] = (_displaybuffer[4] | bit); } // set bit
else {_displaybuffer[4] = (_displaybuffer[4] & ~bit);} // clr bit
if (pattern & S7_D) {_displaybuffer[6] = (_displaybuffer[6] | bit); } // set bit
else {_displaybuffer[6] = (_displaybuffer[6] & ~bit);} // clr bit
if (pattern & S7_E) {_displaybuffer[8] = (_displaybuffer[8] | bit); } // set bit
else {_displaybuffer[8] = (_displaybuffer[8] & ~bit);} // clr bit
if (pattern & S7_F) {_displaybuffer[10] = (_displaybuffer[10] | bit); } // set bit
else {_displaybuffer[10] = (_displaybuffer[10] & ~bit);} // clr bit
if (pattern & S7_G) {_displaybuffer[12] = (_displaybuffer[12] | bit); } // set bit
else {_displaybuffer[12] = (_displaybuffer[12] & ~bit);} // clr bit
if (pattern & S7_DP) {_displaybuffer[14] = (_displaybuffer[14] | bit); } // set bit
else {_displaybuffer[14] = (_displaybuffer[14] & ~bit);} // clr bit
//Save icons...and set bits for character to write
// _displaybuffer[addr] = (_displaybuffer[addr] & MASK_ICON_GRID[_column][0]) | pattern;
// _displaybuffer[addr+1] = (_displaybuffer[addr+1] & MASK_ICON_GRID[_column][0]) | pattern;
writeData(_displaybuffer, (QYF_NR_GRIDS * TM1638_BYTES_PER_GRID));
//Update Cursor
_column++;
if (_column > (QYF_NR_DIGITS - 1)) {
_column = 0;
}
} // if validChar
return value;
}
// get a single character (Stream implementation)
int TM1638_QYF::_getc() {
return -1;
}
#endif
#if (LKM1638_TEST == 1)
// Derived class for TM1638 used in LMK1638 display unit
//
/** Constructor for class for driving TM1638 LED controller as used in LKM1638
*
* @brief Supports 8 Digits of 7 Segments + DP + Bi-Color LED Icons. Also supports a scanned keyboard of 8.
*
* @param PinName mosi, miso, sclk, cs SPI bus pins
*/
TM1638_LKM1638::TM1638_LKM1638(PinName mosi, PinName miso, PinName sclk, PinName cs) : TM1638(mosi, miso, sclk, cs) {
_column = 0;
_columns = LKM1638_NR_DIGITS;
}
#if(0)
#if DOXYGEN_ONLY
/** Write a character to the Display
*
* @param c The character to write to the display
*/
int putc(int c);
/** Write a formatted string to the Display
*
* @param format A printf-style format string, followed by the
* variables to use in formatting the string.
*/
int printf(const char* format, ...);
#endif
#endif
/** Locate cursor to a screen column
*
* @param column The horizontal position from the left, indexed from 0
*/
void TM1638_LKM1638::locate(int column) {
//sanity check
if (column < 0) {column = 0;}
if (column > (_columns - 1)) {column = _columns - 1;}
_column = column;
}
/** Number of screen columns
*
* @param none
* @return columns
*/
int TM1638_LKM1638::columns() {
return _columns;
}
/** Clear the screen and locate to 0
* @param bool clrAll Clear Icons also (default = false)
*/
void TM1638_LKM1638::cls(bool clrAll) {
if (clrAll) {
//clear local buffer (including Icons)
for (int idx=0; idx < (LKM1638_NR_GRIDS << 1); idx++) {
_displaybuffer[idx] = 0x00;
}
}
else {
//clear local buffer (preserving Icons)
for (int idx=0; idx < LKM1638_NR_GRIDS; idx++) {
_displaybuffer[(idx<<1)] = _displaybuffer[(idx<<1)] & MASK_ICON_GRID[idx][0];
_displaybuffer[(idx<<1) + 1] = _displaybuffer[(idx<<1) + 1] & MASK_ICON_GRID[idx][1];
}
}
writeData(_displaybuffer, (LKM1638_NR_GRIDS * TM1638_BYTES_PER_GRID));
_column = 0;
}
/** Set Icon
*
* @param Icon icon Enums Icon has Grid position encoded in 8 MSBs, Icon pattern encoded in 16 LSBs
* @return none
*/
void TM1638_LKM1638::setIcon(Icon icon) {
int addr, icn;
icn = icon & 0xFFFF;
addr = (icon >> 24) & 0xFF;
addr = (addr - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save char...and set bits for icon to write
_displaybuffer[addr] = _displaybuffer[addr] | LO(icn);
_displaybuffer[addr+1] = _displaybuffer[addr+1] | HI(icn);
// writeData(_displaybuffer, (LKM1638_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
}
/** Clr Icon
*
* @param Icon icon Enums Icon has Grid position encoded in 8 MSBs, Icon pattern encoded in 16 LSBs
* @return none
*/
void TM1638_LKM1638::clrIcon(Icon icon) {
int addr, icn;
icn = icon & 0xFFFF;
addr = (icon >> 24) & 0xFF;
addr = (addr - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save char...and clr bits for icon to write
_displaybuffer[addr] = _displaybuffer[addr] & ~LO(icn);
_displaybuffer[addr+1] = _displaybuffer[addr+1] & ~HI(icn);
// writeData(_displaybuffer, (LKM1638_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
}
/** Set User Defined Characters (UDC)
*
* @param unsigned char udc_idx The Index of the UDC (0..7)
* @param int udc_data The bitpattern for the UDC (8 bits)
*/
void TM1638_LKM1638::setUDC(unsigned char udc_idx, int udc_data) {
//Sanity check
if (udc_idx > (LKM1638_NR_UDC-1)) {
return;
}
// Mask out Icon bits?
_UDC_7S[udc_idx] = LO(udc_data);
}
/** Write a single character (Stream implementation)
*/
int TM1638_LKM1638::_putc(int value) {
int addr;
bool validChar = false;
char pattern = 0x00;
if ((value == '\n') || (value == '\r')) {
//No character to write
validChar = false;
//Update Cursor
_column = 0;
}
else if ((value == '.') || (value == ',')) {
//No character to write
validChar = false;
pattern = S7_DP; // placeholder for all DPs
// Check to see that DP can be shown for current column
if (_column > 0) {
//Translate between _column and displaybuffer entries
//Add DP to bitpattern of digit left of current column.
addr = (_column - 1) << 1; // * TM1638_BYTES_PER_GRID
//Save icons...and set bits for decimal point to write
_displaybuffer[addr] = _displaybuffer[addr] | pattern;
// _displaybuffer[addr+1] = _displaybuffer[addr+1] | pattern;
// writeData(_displaybuffer, (LKM1638_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
//No Cursor Update
}
}
else if ((value >= 0) && (value < LKM1638_NR_UDC)) {
//Character to write
validChar = true;
pattern = _UDC_7S[value];
}
#if (SHOW_ASCII == 1)
//display all ASCII characters
else if ((value >= FONT_7S_START) && (value <= FONT_7S_END)) {
//Character to write
validChar = true;
pattern = FONT_7S[value - FONT_7S_START];
} // else
#else
//display only digits and hex characters
else if (value == '-') {
//Character to write
validChar = true;
pattern = C7_MIN;
}
else if ((value >= (int)'0') && (value <= (int) '9')) {
//Character to write
validChar = true;
pattern = FONT_7S[value - (int) '0'];
}
else if ((value >= (int) 'A') && (value <= (int) 'F')) {
//Character to write
validChar = true;
pattern = FONT_7S[10 + value - (int) 'A'];
}
else if ((value >= (int) 'a') && (value <= (int) 'f')) {
//Character to write
validChar = true;
pattern = FONT_7S[10 + value - (int) 'a'];
} //else
#endif
if (validChar) {
//Character to write
//Translate between _column and displaybuffer entries
addr = _column << 1; // * TM1638_BYTES_PER_GRID
//Save icons...and set bits for character to write
_displaybuffer[addr] = (_displaybuffer[addr] & MASK_ICON_GRID[_column][0]) | pattern;
// _displaybuffer[addr+1] = (_displaybuffer[addr+1] & MASK_ICON_GRID[_column][0]) | pattern;
// writeData(_displaybuffer, (LKM1638_NR_GRIDS * TM1638_BYTES_PER_GRID));
writeData(_displaybuffer, TM1638_BYTES_PER_GRID, addr);
//Update Cursor
_column++;
if (_column > (LKM1638_NR_DIGITS - 1)) {
_column = 0;
}
} // if validChar
return value;
}
// get a single character (Stream implementation)
int TM1638_LKM1638::_getc() {
return -1;
}
#endif