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- /* Copyright (c) 2009 by Alex Leone <acleone ~AT~ gmail.com>
-
- This file is part of the Arduino TLC5940 Library.
-
- The Arduino TLC5940 Library 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.
-
- The Arduino TLC5940 Library 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 The Arduino TLC5940 Library. If not, see
- <http://www.gnu.org/licenses/>. */
-
- /** \file
- Tlc5940 class functions. */
-
- #include "Tlc5940.h"
- #include "pinouts/pin_functions.h"
-
-
- /** This will be true (!= 0) if update was just called and the data has not
- been latched in yet. */
- volatile uint8_t tlc_needXLAT;
-
- /** Some of the extened library will need to be called after a successful
- update. */
- volatile void (*tlc_onUpdateFinished)(void);
-
- /** Packed grayscale data, 24 bytes (16 * 12 bits) per TLC.
-
- Format: Lets assume we have 2 TLCs, A and B, daisy-chained with the SOUT of
- A going into the SIN of B.
- - byte 0: upper 8 bits of B.15
- - byte 1: lower 4 bits of B.15 and upper 4 bits of B.14
- - byte 2: lower 8 bits of B.0
- - ...
- - byte 24: upper 8 bits of A.15
- - byte 25: lower 4 bits of A.15 and upper 4 bits of A.14
- - ...
- - byte 47: lower 8 bits of A.0
-
- \note Normally packing data like this is bad practice. But in this
- situation, shifting the data out is really fast because the format of
- the array is the same as the format of the TLC's serial interface. */
- uint8_t tlc_GSData[NUM_TLCS * 24];
-
- /** Don't add an extra SCLK pulse after switching from dot-correction mode. */
- static uint8_t firstGSInput;
-
- /** Interrupt called after an XLAT pulse to prevent more XLAT pulses. */
- static inline void Tlc5940_interrupt(void)
- {
- disable_XLAT_pulses();
- clear_XLAT_interrupt();
- tlc_needXLAT = 0;
- if (tlc_onUpdateFinished) {
- sei();
- tlc_onUpdateFinished();
- }
- }
-
- #if defined(__AVR__)
- ISR(TIMER1_OVF_vect)
- {
- Tlc5940_interrupt();
- }
-
- #elif defined(__arm__) && defined(TEENSYDUINO)
- void ftm1_isr(void)
- {
- uint32_t sc = FTM1_SC;
- if (sc & 0x80) FTM1_SC = sc & 0x7F;
- Tlc5940_interrupt();
- }
-
- #endif
-
- /** \defgroup ReqVPRG_ENABLED Functions that Require VPRG_ENABLED
- Functions that require VPRG_ENABLED == 1.
- You can enable VPRG by changing
- \code #define VPRG_ENABLED 0 \endcode to
- \code #define VPRG_ENABLED 1 \endcode in tlc_config.h
-
- You will also have to connect Arduino digital pin 6 to TLC pin 27. (The
- pin to be used can be changed in tlc_config.h). If VPRG is not enabled,
- the TLC pin should grounded (remember to unconnect TLC pin 27 from GND
- if you do enable VPRG). */
- /* @{ */ /* @} */
-
- /** \defgroup CoreFunctions Core Libary Functions
- These function are all prefixed with "Tlc." */
- /* @{ */
-
- /** Pin i/o and Timer setup. The grayscale register will be reset to all
- zeros, or whatever initialValue is set to and the Timers will start.
- \param initialValue = 0, optional parameter specifing the inital startup
- value */
- void Tlc5940::init(uint16_t initialValue)
- {
- /* Pin Setup */
- output_pin(XLAT_DDR, XLAT_PIN);
- output_pin(BLANK_DDR, BLANK_PIN);
- output_pin(GSCLK_DDR, GSCLK_PIN);
- #if VPRG_ENABLED
- output_pin(VPRG_DDR, VPRG_PIN);
- clear_pin(VPRG_PORT, VPRG_PIN); // grayscale mode (VPRG low)
- #endif
- #if XERR_ENABLED
- pullup_pin(XERR_DDR, XERR_PORT, XERR_PIN); // XERR as input, enable pull-up resistor
- #endif
- set_pin(BLANK_PORT, BLANK_PIN); // leave blank high (until the timers start)
-
- tlc_shift8_init();
-
- setAll(initialValue);
- update();
- disable_XLAT_pulses();
- clear_XLAT_interrupt();
- tlc_needXLAT = 0;
- pulse_pin(XLAT_PORT, XLAT_PIN);
-
-
- /* Timer Setup */
- #if defined(__AVR__)
- /* Timer 1 - BLANK / XLAT */
- TCCR1A = _BV(COM1B1); // non inverting, output on OC1B, BLANK
- TCCR1B = _BV(WGM13); // Phase/freq correct PWM, ICR1 top
- OCR1A = 1; // duty factor on OC1A, XLAT is inside BLANK
- OCR1B = 2; // duty factor on BLANK (larger than OCR1A (XLAT))
- ICR1 = TLC_PWM_PERIOD; // see tlc_config.h
-
- /* Timer 2 - GSCLK */
- #if defined(TLC_ATMEGA_8_H)
- TCCR2 = _BV(COM20) // set on BOTTOM, clear on OCR2A (non-inverting),
- | _BV(WGM21); // output on OC2B, CTC mode with OCR2 top
- OCR2 = TLC_GSCLK_PERIOD / 2; // see tlc_config.h
- TCCR2 |= _BV(CS20); // no prescale, (start pwm output)
- #elif defined(TLC_TIMER3_GSCLK)
- TCCR3A = _BV(COM3A1) // set on BOTTOM, clear on OCR3A (non-inverting),
- // output on OC3A
- | _BV(WGM31); // Fast pwm with ICR3 top
- OCR3A = 0; // duty factor (as short a pulse as possible)
- ICR3 = TLC_GSCLK_PERIOD; // see tlc_config.h
- TCCR3B = _BV(CS30) // no prescale, (start pwm output)
- | _BV(WGM32) // Fast pwm with ICR3 top
- | _BV(WGM33); // Fast pwm with ICR3 top
- #else
- TCCR2A = _BV(COM2B1) // set on BOTTOM, clear on OCR2A (non-inverting),
- // output on OC2B
- | _BV(WGM21) // Fast pwm with OCR2A top
- | _BV(WGM20); // Fast pwm with OCR2A top
- TCCR2B = _BV(WGM22); // Fast pwm with OCR2A top
- OCR2B = 0; // duty factor (as short a pulse as possible)
- OCR2A = TLC_GSCLK_PERIOD; // see tlc_config.h
- TCCR2B |= _BV(CS20); // no prescale, (start pwm output)
- #endif
- TCCR1B |= _BV(CS10); // no prescale, (start pwm output)
-
- #elif defined(__arm__) && defined(TEENSYDUINO)
- clear_pin(XLAT_DDR, XLAT_PIN);
- SIM_SCGC4 |= SIM_SCGC4_CMT;
- CMT_MSC = 0;
- CMT_PPS = 0;
- CMT_CGH1 = TLC_TIMER_TEENSY3_NORMAL_CGH1;
- CMT_CGL1 = TLC_TIMER_TEENSY3_NORMAL_CGL1;
- CMT_CMD1 = 1;
- CMT_CMD2 = 0;
- CMT_CMD3 = 0;
- CMT_CMD4 = 0;
- CMT_OC = 0x60;
- CMT_MSC = 0x01;
- CORE_PIN5_CONFIG = PORT_PCR_MUX(2)|PORT_PCR_DSE|PORT_PCR_SRE;
- FTM1_SC = 0;
- FTM1_MOD = TLC_TIMER_TEENSY3_NORMAL_MOD;
- FTM1_CNT = 0;
- FTM1_C0SC = 0x24;
- FTM1_C1SC = 0x24;
- FTM1_C0V = TLC_TIMER_TEENSY3_NORMAL_MOD - TLC_TIMER_TEENSY3_NORMAL_CV;
- FTM1_C1V = TLC_TIMER_TEENSY3_NORMAL_MOD - TLC_TIMER_TEENSY3_NORMAL_CV - 1;
- FTM1_SC = FTM_SC_CLKS(1) | FTM_SC_CPWMS;
- NVIC_ENABLE_IRQ(IRQ_FTM1);
- CORE_PIN4_CONFIG = PORT_PCR_MUX(3)|PORT_PCR_DSE|PORT_PCR_SRE;
- #endif
- update();
- }
-
- /** Clears the grayscale data array, #tlc_GSData, but does not shift in any
- data. This call should be followed by update() if you are turning off
- all the outputs. */
- void Tlc5940::clear(void)
- {
- setAll(0);
- }
-
- /** Shifts in the data from the grayscale data array, #tlc_GSData.
- If data has already been shifted in this grayscale cycle, another call to
- update() will immediately return 1 without shifting in the new data. To
- ensure that a call to update() does shift in new data, use
- \code while(Tlc.update()); \endcode
- or
- \code while(tlc_needXLAT); \endcode
- \returns 1 if there is data waiting to be latched, 0 if data was
- successfully shifted in */
- uint8_t Tlc5940::update(void)
- {
- if (tlc_needXLAT) {
- return 1;
- }
- disable_XLAT_pulses();
- if (firstGSInput) {
- // adds an extra SCLK pulse unless we've just set dot-correction data
- firstGSInput = 0;
- } else {
- pulse_pin(SCLK_PORT, SCLK_PIN);
- }
- uint8_t *p = tlc_GSData;
- while (p < tlc_GSData + NUM_TLCS * 24) {
- tlc_shift8(*p++);
- tlc_shift8(*p++);
- tlc_shift8(*p++);
- }
- tlc_needXLAT = 1;
- enable_XLAT_pulses();
- set_XLAT_interrupt();
- return 0;
- }
-
- /** Sets channel to value in the grayscale data array, #tlc_GSData.
- \param channel (0 to #NUM_TLCS * 16 - 1). OUT0 of the first TLC is
- channel 0, OUT0 of the next TLC is channel 16, etc.
- \param value (0-4095). The grayscale value, 4095 is maximum.
- \see get */
- void Tlc5940::set(TLC_CHANNEL_TYPE channel, uint16_t value)
- {
- TLC_CHANNEL_TYPE index8 = (NUM_TLCS * 16 - 1) - channel;
- uint8_t *index12p = tlc_GSData + ((((uint16_t)index8) * 3) >> 1);
- if (index8 & 1) { // starts in the middle
- // first 4 bits intact | 4 top bits of value
- *index12p = (*index12p & 0xF0) | (value >> 8);
- // 8 lower bits of value
- *(++index12p) = value & 0xFF;
- } else { // starts clean
- // 8 upper bits of value
- *(index12p++) = value >> 4;
- // 4 lower bits of value | last 4 bits intact
- *index12p = ((uint8_t)(value << 4)) | (*index12p & 0xF);
- }
- }
-
- /** Gets the current grayscale value for a channel
- \param channel (0 to #NUM_TLCS * 16 - 1). OUT0 of the first TLC is
- channel 0, OUT0 of the next TLC is channel 16, etc.
- \returns current grayscale value (0 - 4095) for channel
- \see set */
- uint16_t Tlc5940::get(TLC_CHANNEL_TYPE channel)
- {
- TLC_CHANNEL_TYPE index8 = (NUM_TLCS * 16 - 1) - channel;
- uint8_t *index12p = tlc_GSData + ((((uint16_t)index8) * 3) >> 1);
- return (index8 & 1)? // starts in the middle
- (((uint16_t)(*index12p & 15)) << 8) | // upper 4 bits
- *(index12p + 1) // lower 8 bits
- : // starts clean
- (((uint16_t)(*index12p)) << 4) | // upper 8 bits
- ((*(index12p + 1) & 0xF0) >> 4); // lower 4 bits
- // that's probably the ugliest ternary operator I've ever created.
- }
-
- /** Sets all channels to value.
- \param value grayscale value (0 - 4095) */
- void Tlc5940::setAll(uint16_t value)
- {
- uint8_t firstByte = value >> 4;
- uint8_t secondByte = (value << 4) | (value >> 8);
- uint8_t *p = tlc_GSData;
- while (p < tlc_GSData + NUM_TLCS * 24) {
- *p++ = firstByte;
- *p++ = secondByte;
- *p++ = (uint8_t)value;
- }
- }
-
- #if VPRG_ENABLED
-
- /** \addtogroup ReqVPRG_ENABLED
- From the \ref CoreFunctions "Core Functions":
- - \link Tlc5940::setAllDC Tlc.setAllDC(uint8_t value(0-63)) \endlink - sets
- all the dot correction data to value */
- /* @{ */
-
- /** Sets the dot correction for all channels to value. The dot correction
- value correspondes to maximum output current by
- \f$\displaystyle I_{OUT_n} = I_{max} \times \frac{DCn}{63} \f$
- where
- - \f$\displaystyle I_{max} = \frac{1.24V}{R_{IREF}} \times 31.5 =
- \frac{39.06}{R_{IREF}} \f$
- - DCn is the dot correction value for channel n
- \param value (0-63) */
- void Tlc5940::setAllDC(uint8_t value)
- {
- tlc_dcModeStart();
-
- uint8_t firstByte = value << 2 | value >> 4;
- uint8_t secondByte = value << 4 | value >> 2;
- uint8_t thirdByte = value << 6 | value;
-
- for (TLC_CHANNEL_TYPE i = 0; i < NUM_TLCS * 12; i += 3) {
- tlc_shift8(firstByte);
- tlc_shift8(secondByte);
- tlc_shift8(thirdByte);
- }
- pulse_pin(XLAT_PORT, XLAT_PIN);
-
- tlc_dcModeStop();
- }
-
- /* @} */
-
- #endif
-
- #if XERR_ENABLED
-
- /** Checks for shorted/broken LEDs reported by any of the TLCs.
- \returns 1 if a TLC is reporting an error, 0 otherwise. */
- uint8_t Tlc5940::readXERR(void)
- {
- return ((XERR_PINS & _BV(XERR_PIN)) == 0);
- }
-
- #endif
-
- /* @} */
-
- #if DATA_TRANSFER_MODE == TLC_BITBANG
-
- /** Sets all the bit-bang pins to output */
- void tlc_shift8_init(void)
- {
- output_pin(SIN_DDR, SIN_PIN); // SIN as output
- output_pin(SCLK_DDR, SCLK_PIN); // SCLK as output
- clear_pin(SCLK_PORT, SCLK_PIN);
- }
-
- /** Shifts a byte out, MSB first */
- void tlc_shift8(uint8_t byte)
- {
- for (uint8_t bit = 0x80; bit; bit >>= 1) {
- if (bit & byte) {
- set_pin(SIN_PORT, SIN_PIN);
- } else {
- clear_pin(SIN_PORT, SIN_PIN);
- }
- pulse_pin(SCLK_PORT, SCLK_PIN);
- }
- }
-
- #elif DATA_TRANSFER_MODE == TLC_SPI
-
- /** Initializes the SPI module to double speed (f_osc / 2) */
- void tlc_shift8_init(void)
- {
- output_pin(SIN_DDR, SIN_PIN); // SPI MOSI as output
- output_pin(SCLK_DDR, SCLK_PIN); // SPI SCK as output
- output_pin(TLC_SS_DDR, TLC_SS_PIN); // SPI SS as output
-
- clear_pin(SCLK_PORT, SCLK_PIN);
-
- SPSR = _BV(SPI2X); // double speed (f_osc / 2)
- SPCR = _BV(SPE) // enable SPI
- | _BV(MSTR); // master mode
- }
-
- /** Shifts out a byte, MSB first */
- void tlc_shift8(uint8_t byte)
- {
- SPDR = byte; // starts transmission
- while (!(SPSR & _BV(SPIF)))
- ; // wait for transmission complete
- }
-
- #endif
-
- #if VPRG_ENABLED
-
- /** Switches to dot correction mode and clears any waiting grayscale latches.*/
- void tlc_dcModeStart(void)
- {
- disable_XLAT_pulses(); // ensure that no latches happen
- clear_XLAT_interrupt(); // (in case this was called right after update)
- tlc_needXLAT = 0;
- set_pin(VPRG_PORT, VPRG_PIN); // dot correction mode
- }
-
- /** Switches back to grayscale mode. */
- void tlc_dcModeStop(void)
- {
- clear_pin(VPRG_PORT, VPRG_PIN); // back to grayscale mode
- firstGSInput = 1;
- }
-
- #endif
-
- /** Preinstantiated Tlc variable. */
- Tlc5940 Tlc;
-
- /** \defgroup ExtendedFunctions Extended Library Functions
- These functions require an include statement at the top of the sketch. */
- /* @{ */ /* @} */
-
- /** \mainpage
- The <a href="http://www.ti.com/lit/gpn/TLC5940">Texas Instruments TLC5940
- </a> is a 16-channel, constant-current sink LED driver. Each channel has
- an individually adjustable 4096-step grayscale PWM brightness control and
- a 64-step, constant-current sink (no LED resistors needed!). This chip
- is a current sink, so be sure to use common anode RGB LEDs.
-
- Check the <a href="http://code.google.com/p/tlc5940arduino/">tlc5940arduino
- project</a> on Google Code for updates. To install, unzip the "Tlc5940"
- folder to <Arduino Folder>/hardware/libraries/
-
-
-
- \section hardwaresetup Hardware Setup
- The basic hardware setup is explained at the top of the Examples. A good
- place to start would be the BasicUse Example. (The examples are in
- File->Sketchbook->Examples->Library-Tlc5940).
-
- All the options for the library are located in tlc_config.h, including
- #NUM_TLCS, what pins to use, and the PWM period. After changing
- tlc_config.h, be sure to delete the Tlc5940.o file in the library folder
- to save the changes.
-
-
-
- \section libref Library Reference
- \ref CoreFunctions "Core Functions" (see the BasicUse Example and Tlc5940):
- - \link Tlc5940::init Tlc.init(int initialValue (0-4095))\endlink - Call this is
- to setup the timers before using any other Tlc functions.
- initialValue defaults to zero (all channels off).
- - \link Tlc5940::clear Tlc.clear()\endlink - Turns off all channels
- (Needs Tlc.update())
- - \link Tlc5940::set Tlc.set(uint8_t channel (0-(NUM_TLCS * 16 - 1)),
- int value (0-4095))\endlink - sets the grayscale data for channel.
- (Needs Tlc.update())
- - \link Tlc5940::setAll Tlc.setAll(int value(0-4095))\endlink - sets all
- channels to value. (Needs Tlc.update())
- - \link Tlc5940::get uint16_t Tlc.get(uint8_t channel)\endlink - returns
- the grayscale data for channel (see set).
- - \link Tlc5940::update Tlc.update()\endlink - Sends the changes from any
- Tlc.clear's, Tlc.set's, or Tlc.setAll's.
-
- \ref ExtendedFunctions "Extended Functions". These require an include
- statement at the top of the sketch to use.
-
- \ref ReqVPRG_ENABLED "Functions that require VPRG_ENABLED". These
- require VPRG_ENABLED == 1 in tlc_config.h
-
-
-
- \section expansion Expanding the Library
- Lets say we wanted to add a function like "tlc_goCrazy(...)". The first
- thing to do is to create a source file in the library folder,
- "tlc_my_crazy_functions.h".
- A template for this .h file is
- \code
- // Explination for my crazy function extension
-
- #ifndef TLC_MY_CRAZY_FUNCTIONS_H
- #define TLC_MY_CRAZY_FUNCTIONS_H
-
- #include "tlc_config.h"
- #include "Tlc5940.h"
-
- void tlc_goCrazy(void);
-
- void tlc_goCrazy(void)
- {
- uint16_t crazyFactor = 4000;
- Tlc.clear();
- for (uint8_t channel = 4; channel < 9; channel++) {
- Tlc.set(channel, crazyFactor);
- }
- Tlc.update();
- }
-
- #endif
- * \endcode
- * Now to use your library in a sketch, just add
- * \code
- #include "tlc_my_crazy_functions.h"
-
- // ...
-
- tlc_goCrazy();
- \endcode
- If you would like to share your extended functions for others to use,
- email me (acleone ~AT~ gmail.com) with the file and an example and I'll
- include them in the library.
-
-
-
- \section bugs Contact
- If you found a bug in the library, email me so I can fix it!
- My email is acleone ~AT~ gmail.com
-
-
-
- \section license License - GPLv3
- Copyright (c) 2009 by Alex Leone <acleone ~AT~ gmail.com>
-
- This file is part of the Arduino TLC5940 Library.
-
- The Arduino TLC5940 Library 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.
-
- The Arduino TLC5940 Library 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 The Arduino TLC5940 Library. If not, see
- <http://www.gnu.org/licenses/>. */
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