AMiRo-OS

/*

AMiRo-LLD is a compilation of low-level hardware drivers for the Autonomous Mini Robot (AMiRo) platform.

Copyright (C) 2016..2019  Thomas Schöpping et al.

This program is free software: you can redistribute it and/or modify

it under the terms of the GNU Lesser 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 Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public License

along with this program.  If not, see <http://www.gnu.org/licenses/>.

*/

/**

 * @file    alld_TLC5947.c

 * @brief   LED Driver function implementations.

 *

 * @addtogroup lld_leddriver

 * @{

 */

#include <alld_TLC5947.h>

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/* LOCAL DEFINITIONS                                                          */

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/* EXPORTED VARIABLES                                                         */

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/* LOCAL TYPES                                                                */

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/* LOCAL VARIABLES                                                            */

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/* LOCAL FUNCTIONS                                                            */

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/* EXPORTED FUNCTIONS                                                         */

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/**

 * @brief   Set the blank state of the TLC5947.

 * @param[in] tlc5947   The TLC5947 driver object.

 * @param[in] blank     The state to set the TLC5947 driver to.

 * @return              An indicator whether the call was successful.

 */

apalExitStatus_t tlc5947_lld_setBlank(const TLC5947Driver* const tlc5947, const tlc5947_lld_blank_t blank)

{

  apalDbgAssert(tlc5947 != NULL);

  // BLANK signal is optional

  if (tlc5947->blank_gpio == NULL) {

    return APAL_STATUS_WARNING;

  } else {

    // set the output value of the GPIO pin depending on the activation property

    return apalControlGpioSet(tlc5947->blank_gpio, blank == TLC5947_LLD_BLANK_ENABLE ? APAL_GPIO_ON : APAL_GPIO_OFF);

  }

}

/**

 * @brief   Get the current status of the TLC5947s blank pin.

 * @param[in]  tlc5947  The TLC5947 driver object.

 * @param[out] blank    The state object to fill.

 * @return              An indicator whether the call was successful.

 */

apalExitStatus_t tlc5947_lld_getBlank(const TLC5947Driver* const tlc5947, tlc5947_lld_blank_t* const blank)

{

  apalDbgAssert(tlc5947 != NULL);

  apalDbgAssert(blank != NULL);

  // BLANK signal is optional

  if (tlc5947->blank_gpio == NULL) {

    return APAL_STATUS_WARNING;

  } else {

    apalControlGpioState_t gpio_state;

    apalExitStatus_t status = apalControlGpioGet(tlc5947->blank_gpio, &gpio_state);

    *blank = gpio_state == APAL_GPIO_ON ? TLC5947_LLD_BLANK_ENABLE : TLC5947_LLD_BLANK_DISABLE;

    return status;

  }

}

/**

 * @brief   Writes a pulse on XLAT signal.

 * @details A pulse makes the TLC to move the grayscale register data to the internal latch and visualize it.

 * @param[in] tlc5947   The TLC5947 driver object.

 * @return              An indicator whether the call was successful.

 */

apalExitStatus_t tlc5947_lld_update(const TLC5947Driver* const tlc5947)

{

  apalDbgAssert(tlc5947 != NULL);

  // XLAT signal GPIO is optional

  if (tlc5947->xlat_gpio == NULL) {

    return APAL_STATUS_WARNING;

  } else {

    apalExitStatus_t status = apalGpioWrite(tlc5947->xlat_gpio->gpio, (tlc5947->xlat_gpio->meta.edge == APAL_GPIO_EDGE_RISING) ? APAL_GPIO_LOW : APAL_GPIO_HIGH);

    // The XLAT signal has to be active for at least 30 ns.

    // It is assumed that that these function calls satisfy this requirement even without explicit delay.

    status |= apalGpioWrite(tlc5947->xlat_gpio->gpio, (tlc5947->xlat_gpio->meta.edge == APAL_GPIO_EDGE_RISING) ? APAL_GPIO_HIGH : APAL_GPIO_LOW);

    return status;

  }

}

/**

 * @brief Write buffer via SPI to the TLC5947.

 * @return                  An indicator whether the call was successful.

 */

apalExitStatus_t tlc5947_lld_write(const TLC5947Driver* const tlc5947, const tlc5947_lld_buffer_t* const buffer)

{

  apalDbgAssert(tlc5947 != NULL);

  apalDbgAssert(buffer != NULL);

  // send buffer via SPI

  return apalSPITransmit(tlc5947->spi_driver, buffer->data, TLC5947_LLD_BUFFER_SIZE);

}

/**

 * @brief   Set a specific channel of a given buffer.

 * @param[in] buffer    The buffer to modify.

 * @param[in] channel   The channel to set.

 * @param[in] value     The new value to set.

 *                      Must be a 12bit value.

 * @return              An indicator whether the call was successful.

 */

void tlc5947_lld_setBuffer(tlc5947_lld_buffer_t* const buffer, const uint8_t channel, const uint16_t value)

{

  apalDbgAssert(buffer != NULL);

  apalDbgAssert(channel < TLC5947_LLD_NUM_CHANNELS);

  apalDbgAssert(value <= (1 << TLC5947_LLD_PWM_RESOLUTION_BITS) - 1);

  // reverse the channel number, since the data is shifted within the TLC5947 and thus the order is inverted

  const uint8_t idx = (uint16_t)(TLC5947_LLD_NUM_CHANNELS-1 - channel) * TLC5947_LLD_PWM_RESOLUTION_BITS / 8;

  // channel is odd / inverse channel is even

  if (channel % 2) {

    buffer->data[idx] = (value >> 4) & 0xFFu;

    buffer->data[idx+1] = ((value << 4) & 0xF0u) | (buffer->data[idx+1] & 0x0Fu);

  }

  // channel is even / inverse channel is odd

  else {

    buffer->data[idx] = (buffer->data[idx] & 0xF0u) | ((value >> 8) & 0x0Fu);

    buffer->data[idx+1] = value & 0xFFu;

  }

  return;

}

/**

 * @brief   Read a specific state from a given buffer.

 * @param[in] buffer    The buffer to read from.

 * @param[in] channel   The channel to read

 * @return              An indicator whether the call was successful.

 */

uint16_t tlc5947_lld_getBuffer(const tlc5947_lld_buffer_t* const buffer, const uint8_t channel)

{

  apalDbgAssert(buffer != NULL);

  apalDbgAssert(channel < TLC5947_LLD_NUM_CHANNELS);

  // reverse the channel number, since the data is shifted within the TLC5947 and thus the order is inverted

  const uint8_t idx = (uint16_t)(TLC5947_LLD_NUM_CHANNELS-1- channel) * TLC5947_LLD_PWM_RESOLUTION_BITS / 8;

  // channel is odd / inverse channel is even

  if (channel % 2) {

    return (((uint16_t)(buffer->data[idx])) << 4) | (uint16_t)((buffer->data[idx+1] & 0xF0u) >> 4);

  }

  // channel is even / inverse channel is odd

  else {

    return (((uint16_t)(buffer->data[idx] & 0x0Fu)) << 8) | (uint16_t)(buffer->data[idx+1]);

  }

}

/** @} */