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diff --git a/firmwares/wifishield/wifi_dnld/src/SOFTWARE_FRAMEWORK/DRIVERS/USART/usart.c b/firmwares/wifishield/wifi_dnld/src/SOFTWARE_FRAMEWORK/DRIVERS/USART/usart.c
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+++ b/firmwares/wifishield/wifi_dnld/src/SOFTWARE_FRAMEWORK/DRIVERS/USART/usart.c
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+/* This source file is part of the ATMEL AVR-UC3-SoftwareFramework-1.7.0 Release */
+
+/*This file is prepared for Doxygen automatic documentation generation.*/
+/*! \file *********************************************************************
+ *
+ * \brief USART driver for AVR32 UC3.
+ *
+ * This file contains basic functions for the AVR32 USART, with support for all
+ * modes, settings and clock speeds.
+ *
+ * - Compiler:           IAR EWAVR32 and GNU GCC for AVR32
+ * - Supported devices:  All AVR32 devices with a USART module can be used.
+ * - AppNote:
+ *
+ * \author               Atmel Corporation: http://www.atmel.com \n
+ *                       Support and FAQ: http://support.atmel.no/
+ *
+ ******************************************************************************/
+
+/* Copyright (c) 2009 Atmel Corporation. All rights reserved.
+ *
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions are met:
+ *
+ * 1. Redistributions of source code must retain the above copyright notice, this
+ * list of conditions and the following disclaimer.
+ *
+ * 2. Redistributions in binary form must reproduce the above copyright notice,
+ * this list of conditions and the following disclaimer in the documentation
+ * and/or other materials provided with the distribution.
+ *
+ * 3. The name of Atmel may not be used to endorse or promote products derived
+ * from this software without specific prior written permission.
+ *
+ * 4. This software may only be redistributed and used in connection with an Atmel
+ * AVR product.
+ *
+ * THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
+ * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
+ * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
+ * EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR
+ * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
+ * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
+ * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
+ * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
+ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
+ * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
+ *
+ */
+
+#include "compiler.h"
+#include "usart.h"
+
+
+//------------------------------------------------------------------------------
+/*! \name Private Functions
+ */
+//! @{
+
+
+/*! \brief Checks if the USART is in multidrop mode.
+ *
+ * \param usart Base address of the USART instance.
+ *
+ * \return \c 1 if the USART is in multidrop mode, otherwise \c 0.
+ */
+#if (defined __GNUC__)
+__attribute__((__always_inline__))
+#endif
+static __inline__ int usart_mode_is_multidrop(volatile avr32_usart_t *usart)
+{
+  return ((usart->mr >> AVR32_USART_MR_PAR_OFFSET) & AVR32_USART_MR_PAR_MULTI) == AVR32_USART_MR_PAR_MULTI;
+}
+
+
+/*! \brief Calculates a clock divider (\e CD) and a fractional part (\e FP) for
+ *         the USART asynchronous modes to generate a baud rate as close as
+ *         possible to the baud rate set point.
+ *
+ * Baud rate calculation:
+ * \f$ Baudrate = \frac{SelectedClock}{Over \times (CD + \frac{FP}{8})} \f$, \e Over being 16 or 8.
+ * The maximal oversampling is selected if it allows to generate a baud rate close to the set point.
+ *
+ * \param usart     Base address of the USART instance.
+ * \param baudrate  Baud rate set point.
+ * \param pba_hz    USART module input clock frequency (PBA clock, Hz).
+ *
+ * \retval USART_SUCCESS        Baud rate successfully initialized.
+ * \retval USART_INVALID_INPUT  Baud rate set point is out of range for the given input clock frequency.
+ */
+static int usart_set_async_baudrate(volatile avr32_usart_t *usart, unsigned int baudrate, unsigned long pba_hz)
+{
+  unsigned int over = (pba_hz >= 16 * baudrate) ? 16 : 8;
+  unsigned int cd_fp = ((1 << AVR32_USART_BRGR_FP_SIZE) * pba_hz + (over * baudrate) / 2) / (over * baudrate);
+  unsigned int cd = cd_fp >> AVR32_USART_BRGR_FP_SIZE;
+  unsigned int fp = cd_fp & ((1 << AVR32_USART_BRGR_FP_SIZE) - 1);
+
+  if (cd < 1 || cd > (1 << AVR32_USART_BRGR_CD_SIZE) - 1)
+    return USART_INVALID_INPUT;
+
+  usart->mr = (usart->mr & ~(AVR32_USART_MR_USCLKS_MASK |
+                             AVR32_USART_MR_SYNC_MASK |
+                             AVR32_USART_MR_OVER_MASK)) |
+              AVR32_USART_MR_USCLKS_MCK << AVR32_USART_MR_USCLKS_OFFSET |
+              ((over == 16) ? AVR32_USART_MR_OVER_X16 : AVR32_USART_MR_OVER_X8) << AVR32_USART_MR_OVER_OFFSET;
+
+  usart->brgr = cd << AVR32_USART_BRGR_CD_OFFSET |
+                fp << AVR32_USART_BRGR_FP_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+/*! \brief Calculates a clock divider (\e CD) for the USART synchronous master
+ *         modes to generate a baud rate as close as possible to the baud rate
+ *         set point.
+ *
+ * Baud rate calculation:
+ * \f$ Baudrate = \frac{SelectedClock}{CD} \f$.
+ *
+ * \param usart     Base address of the USART instance.
+ * \param baudrate  Baud rate set point.
+ * \param pba_hz    USART module input clock frequency (PBA clock, Hz).
+ *
+ * \retval USART_SUCCESS        Baud rate successfully initialized.
+ * \retval USART_INVALID_INPUT  Baud rate set point is out of range for the given input clock frequency.
+ */
+static int usart_set_sync_master_baudrate(volatile avr32_usart_t *usart, unsigned int baudrate, unsigned long pba_hz)
+{
+  unsigned int cd = (pba_hz + baudrate / 2) / baudrate;
+
+  if (cd < 1 || cd > (1 << AVR32_USART_BRGR_CD_SIZE) - 1)
+    return USART_INVALID_INPUT;
+
+  usart->mr = (usart->mr & ~AVR32_USART_MR_USCLKS_MASK) |
+              AVR32_USART_MR_USCLKS_MCK << AVR32_USART_MR_USCLKS_OFFSET |
+              AVR32_USART_MR_SYNC_MASK;
+
+  usart->brgr = cd << AVR32_USART_BRGR_CD_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+/*! \brief Selects the SCK pin as the source of baud rate for the USART
+ *         synchronous slave modes.
+ *
+ * \param usart Base address of the USART instance.
+ *
+ * \retval USART_SUCCESS  Baud rate successfully initialized.
+ */
+static int usart_set_sync_slave_baudrate(volatile avr32_usart_t *usart)
+{
+  usart->mr = (usart->mr & ~AVR32_USART_MR_USCLKS_MASK) |
+              AVR32_USART_MR_USCLKS_SCK << AVR32_USART_MR_USCLKS_OFFSET |
+              AVR32_USART_MR_SYNC_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+/*! \brief Calculates a clock divider (\e CD) for the USART ISO7816 mode to
+ *         generate an ISO7816 clock as close as possible to the clock set point.
+ *
+ * ISO7816 clock calculation:
+ * \f$ Clock = \frac{SelectedClock}{CD} \f$.
+ *
+ * \param usart   Base address of the USART instance.
+ * \param clock   ISO7816 clock set point.
+ * \param pba_hz  USART module input clock frequency (PBA clock, Hz).
+ *
+ * \retval USART_SUCCESS        ISO7816 clock successfully initialized.
+ * \retval USART_INVALID_INPUT  ISO7816 clock set point is out of range for the given input clock frequency.
+ */
+static int usart_set_iso7816_clock(volatile avr32_usart_t *usart, unsigned int clock, unsigned long pba_hz)
+{
+  unsigned int cd = (pba_hz + clock / 2) / clock;
+
+  if (cd < 1 || cd > (1 << AVR32_USART_BRGR_CD_SIZE) - 1)
+    return USART_INVALID_INPUT;
+
+  usart->mr = (usart->mr & ~(AVR32_USART_MR_USCLKS_MASK |
+                             AVR32_USART_MR_SYNC_MASK |
+                             AVR32_USART_MR_OVER_MASK)) |
+              AVR32_USART_MR_USCLKS_MCK << AVR32_USART_MR_USCLKS_OFFSET |
+              AVR32_USART_MR_OVER_X16 << AVR32_USART_MR_OVER_OFFSET;
+
+  usart->brgr = cd << AVR32_USART_BRGR_CD_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+#if defined(AVR32_USART_400_H_INCLUDED) || \
+    defined(AVR32_USART_410_H_INCLUDED) || \
+    defined(AVR32_USART_420_H_INCLUDED) || \
+    defined(AVR32_USART_440_H_INCLUDED) || \
+    defined(AVR32_USART_602_H_INCLUDED)
+
+
+/*! \brief Calculates a clock divider (\e CD) for the USART SPI master mode to
+ *         generate a baud rate as close as possible to the baud rate set point.
+ *
+ * Baud rate calculation:
+ * \f$ Baudrate = \frac{SelectedClock}{CD} \f$.
+ *
+ * \param usart     Base address of the USART instance.
+ * \param baudrate  Baud rate set point.
+ * \param pba_hz    USART module input clock frequency (PBA clock, Hz).
+ *
+ * \retval USART_SUCCESS        Baud rate successfully initialized.
+ * \retval USART_INVALID_INPUT  Baud rate set point is out of range for the given input clock frequency.
+ */
+static int usart_set_spi_master_baudrate(volatile avr32_usart_t *usart, unsigned int baudrate, unsigned long pba_hz)
+{
+  unsigned int cd = (pba_hz + baudrate / 2) / baudrate;
+
+  if (cd < 4 || cd > (1 << AVR32_USART_BRGR_CD_SIZE) - 1)
+    return USART_INVALID_INPUT;
+
+  usart->mr = (usart->mr & ~AVR32_USART_MR_USCLKS_MASK) |
+              AVR32_USART_MR_USCLKS_MCK << AVR32_USART_MR_USCLKS_OFFSET;
+
+  usart->brgr = cd << AVR32_USART_BRGR_CD_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+/*! \brief Selects the SCK pin as the source of baud rate for the USART SPI
+ *         slave mode.
+ *
+ * \param usart Base address of the USART instance.
+ *
+ * \retval USART_SUCCESS  Baud rate successfully initialized.
+ */
+static int usart_set_spi_slave_baudrate(volatile avr32_usart_t *usart)
+{
+  usart->mr = (usart->mr & ~AVR32_USART_MR_USCLKS_MASK) |
+              AVR32_USART_MR_USCLKS_SCK << AVR32_USART_MR_USCLKS_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+#endif  // USART rev. >= 4.0.0
+
+
+//! @}
+
+
+//------------------------------------------------------------------------------
+/*! \name Initialization Functions
+ */
+//! @{
+
+
+void usart_reset(volatile avr32_usart_t *usart)
+{
+  Bool global_interrupt_enabled = Is_global_interrupt_enabled();
+
+  // Disable all USART interrupts.
+  // Interrupts needed should be set explicitly on every reset.
+  if (global_interrupt_enabled) Disable_global_interrupt();
+  usart->idr = 0xFFFFFFFF;
+  usart->csr;
+  if (global_interrupt_enabled) Enable_global_interrupt();
+
+  // Reset mode and other registers that could cause unpredictable behavior after reset.
+  usart->mr = 0;
+  usart->rtor = 0;
+  usart->ttgr = 0;
+
+  // Shutdown TX and RX (will be re-enabled when setup has successfully completed),
+  // reset status bits and turn off DTR and RTS.
+  usart->cr = AVR32_USART_CR_RSTRX_MASK   |
+              AVR32_USART_CR_RSTTX_MASK   |
+              AVR32_USART_CR_RSTSTA_MASK  |
+              AVR32_USART_CR_RSTIT_MASK   |
+              AVR32_USART_CR_RSTNACK_MASK |
+#ifndef AVR32_USART_440_H_INCLUDED
+// Note: Modem Signal Management DTR-DSR-DCD-RI are not included in USART rev.440.
+              AVR32_USART_CR_DTRDIS_MASK  |
+#endif
+              AVR32_USART_CR_RTSDIS_MASK;
+}
+
+
+int usart_init_rs232(volatile avr32_usart_t *usart, const usart_options_t *opt, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (!opt || // Null pointer.
+      opt->charlength < 5 || opt->charlength > 9 ||
+      opt->paritytype > 7 ||
+      opt->stopbits > 2 + 255 ||
+      opt->channelmode > 3 ||
+      usart_set_async_baudrate(usart, opt->baudrate, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  if (opt->charlength == 9)
+  {
+    // Character length set to 9 bits. MODE9 dominates CHRL.
+    usart->mr |= AVR32_USART_MR_MODE9_MASK;
+  }
+  else
+  {
+    // CHRL gives the character length (- 5) when MODE9 = 0.
+    usart->mr |= (opt->charlength - 5) << AVR32_USART_MR_CHRL_OFFSET;
+  }
+
+  usart->mr |= opt->paritytype << AVR32_USART_MR_PAR_OFFSET |
+               opt->channelmode << AVR32_USART_MR_CHMODE_OFFSET;
+
+  if (opt->stopbits > USART_2_STOPBITS)
+  {
+    // Set two stop bits
+    usart->mr |= AVR32_USART_MR_NBSTOP_2 << AVR32_USART_MR_NBSTOP_OFFSET;
+    // and a timeguard period gives the rest.
+    usart->ttgr = opt->stopbits - USART_2_STOPBITS;
+  }
+  else
+    // Insert 1, 1.5 or 2 stop bits.
+    usart->mr |= opt->stopbits << AVR32_USART_MR_NBSTOP_OFFSET;
+
+  // Set normal mode.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MR_MODE_NORMAL << AVR32_USART_MR_MODE_OFFSET;
+
+  // Setup complete; enable communication.
+  // Enable input and output.
+  usart->cr = AVR32_USART_CR_RXEN_MASK |
+              AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_rs232_tx_only(volatile avr32_usart_t *usart, const usart_options_t *opt, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (!opt || // Null pointer.
+      opt->charlength < 5 || opt->charlength > 9 ||
+      opt->paritytype > 7 ||
+      opt->stopbits == 1 || opt->stopbits > 2 + 255 ||
+      opt->channelmode > 3 ||
+      usart_set_sync_master_baudrate(usart, opt->baudrate, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  if (opt->charlength == 9)
+  {
+    // Character length set to 9 bits. MODE9 dominates CHRL.
+    usart->mr |= AVR32_USART_MR_MODE9_MASK;
+  }
+  else
+  {
+    // CHRL gives the character length (- 5) when MODE9 = 0.
+    usart->mr |= (opt->charlength - 5) << AVR32_USART_MR_CHRL_OFFSET;
+  }
+
+  usart->mr |= opt->paritytype << AVR32_USART_MR_PAR_OFFSET |
+               opt->channelmode << AVR32_USART_MR_CHMODE_OFFSET;
+
+  if (opt->stopbits > USART_2_STOPBITS)
+  {
+    // Set two stop bits
+    usart->mr |= AVR32_USART_MR_NBSTOP_2 << AVR32_USART_MR_NBSTOP_OFFSET;
+    // and a timeguard period gives the rest.
+    usart->ttgr = opt->stopbits - USART_2_STOPBITS;
+  }
+  else
+    // Insert 1 or 2 stop bits.
+    usart->mr |= opt->stopbits << AVR32_USART_MR_NBSTOP_OFFSET;
+
+  // Set normal mode.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MR_MODE_NORMAL << AVR32_USART_MR_MODE_OFFSET;
+
+  // Setup complete; enable communication.
+  // Enable only output as input is not possible in synchronous mode without
+  // transferring clock.
+  usart->cr = AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_hw_handshaking(volatile avr32_usart_t *usart, const usart_options_t *opt, long pba_hz)
+{
+  // First: Setup standard RS232.
+  if (usart_init_rs232(usart, opt, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  // Set hardware handshaking mode.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MR_MODE_HARDWARE << AVR32_USART_MR_MODE_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_modem(volatile avr32_usart_t *usart, const usart_options_t *opt, long pba_hz)
+{
+  // First: Setup standard RS232.
+  if (usart_init_rs232(usart, opt, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  // Set modem mode.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MR_MODE_MODEM << AVR32_USART_MR_MODE_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_sync_master(volatile avr32_usart_t *usart, const usart_options_t *opt, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (!opt || // Null pointer.
+      opt->charlength < 5 || opt->charlength > 9 ||
+      opt->paritytype > 7 ||
+      opt->stopbits == 1 || opt->stopbits > 2 + 255 ||
+      opt->channelmode > 3 ||
+      usart_set_sync_master_baudrate(usart, opt->baudrate, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  if (opt->charlength == 9)
+  {
+    // Character length set to 9 bits. MODE9 dominates CHRL.
+    usart->mr |= AVR32_USART_MR_MODE9_MASK;
+  }
+  else
+  {
+    // CHRL gives the character length (- 5) when MODE9 = 0.
+    usart->mr |= (opt->charlength - 5) << AVR32_USART_MR_CHRL_OFFSET;
+  }
+
+  usart->mr |= opt->paritytype << AVR32_USART_MR_PAR_OFFSET |
+               opt->channelmode << AVR32_USART_MR_CHMODE_OFFSET;
+
+  if (opt->stopbits > USART_2_STOPBITS)
+  {
+    // Set two stop bits
+    usart->mr |= AVR32_USART_MR_NBSTOP_2 << AVR32_USART_MR_NBSTOP_OFFSET;
+    // and a timeguard period gives the rest.
+    usart->ttgr = opt->stopbits - USART_2_STOPBITS;
+  }
+  else
+    // Insert 1 or 2 stop bits.
+    usart->mr |= opt->stopbits << AVR32_USART_MR_NBSTOP_OFFSET;
+
+  // Set normal mode.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MR_MODE_NORMAL << AVR32_USART_MR_MODE_OFFSET |
+              AVR32_USART_MR_CLKO_MASK;
+
+  // Setup complete; enable communication.
+  // Enable input and output.
+  usart->cr = AVR32_USART_CR_RXEN_MASK |
+              AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_sync_slave(volatile avr32_usart_t *usart, const usart_options_t *opt, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (!opt || // Null pointer.
+      opt->charlength < 5 || opt->charlength > 9 ||
+      opt->paritytype > 7 ||
+      opt->stopbits == 1 || opt->stopbits > 2 + 255 ||
+      opt->channelmode > 3 ||
+      usart_set_sync_slave_baudrate(usart) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  if (opt->charlength == 9)
+  {
+    // Character length set to 9 bits. MODE9 dominates CHRL.
+    usart->mr |= AVR32_USART_MR_MODE9_MASK;
+  }
+  else
+  {
+    // CHRL gives the character length (- 5) when MODE9 = 0.
+    usart->mr |= (opt->charlength - 5) << AVR32_USART_MR_CHRL_OFFSET;
+  }
+
+  usart->mr |= opt->paritytype << AVR32_USART_MR_PAR_OFFSET |
+               opt->channelmode << AVR32_USART_MR_CHMODE_OFFSET;
+
+  if (opt->stopbits > USART_2_STOPBITS)
+  {
+    // Set two stop bits
+    usart->mr |= AVR32_USART_MR_NBSTOP_2 << AVR32_USART_MR_NBSTOP_OFFSET;
+    // and a timeguard period gives the rest.
+    usart->ttgr = opt->stopbits - USART_2_STOPBITS;
+  }
+  else
+    // Insert 1 or 2 stop bits.
+    usart->mr |= opt->stopbits << AVR32_USART_MR_NBSTOP_OFFSET;
+
+  // Set normal mode.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MR_MODE_NORMAL << AVR32_USART_MR_MODE_OFFSET;
+
+  // Setup complete; enable communication.
+  // Enable input and output.
+  usart->cr = AVR32_USART_CR_RXEN_MASK |
+              AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_rs485(volatile avr32_usart_t *usart, const usart_options_t *opt, long pba_hz)
+{
+  // First: Setup standard RS232.
+  if (usart_init_rs232(usart, opt, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  // Set RS485 mode.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MR_MODE_RS485 << AVR32_USART_MR_MODE_OFFSET;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_IrDA(volatile avr32_usart_t *usart, const usart_options_t *opt,
+                    long pba_hz, unsigned char irda_filter)
+{
+  // First: Setup standard RS232.
+  if (usart_init_rs232(usart, opt, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  // Set IrDA filter.
+  usart->ifr = irda_filter;
+
+  // Set IrDA mode and activate filtering of input.
+  usart->mr = (usart->mr & ~AVR32_USART_MR_MODE_MASK) |
+              AVR32_USART_MODE_IRDA << AVR32_USART_MR_MODE_OFFSET |
+              AVR32_USART_MR_FILTER_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_iso7816(volatile avr32_usart_t *usart, const usart_iso7816_options_t *opt, int t, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (!opt || // Null pointer.
+      opt->paritytype > 1)
+    return USART_INVALID_INPUT;
+
+  if (t == 0)
+  {
+    // Set USART mode to ISO7816, T=0.
+    // The T=0 protocol always uses 2 stop bits.
+    usart->mr = AVR32_USART_MR_MODE_ISO7816_T0 << AVR32_USART_MR_MODE_OFFSET |
+                AVR32_USART_MR_NBSTOP_2 << AVR32_USART_MR_NBSTOP_OFFSET |
+                opt->bit_order << AVR32_USART_MR_MSBF_OFFSET; // Allow MSBF in T=0.
+  }
+  else if (t == 1)
+  {
+    // Only LSB first in the T=1 protocol.
+    // max_iterations field is only used in T=0 mode.
+    if (opt->bit_order != 0 ||
+        opt->max_iterations != 0)
+      return USART_INVALID_INPUT;
+
+    // Set USART mode to ISO7816, T=1.
+    // The T=1 protocol always uses 1 stop bit.
+    usart->mr = AVR32_USART_MR_MODE_ISO7816_T1 << AVR32_USART_MR_MODE_OFFSET |
+                AVR32_USART_MR_NBSTOP_1 << AVR32_USART_MR_NBSTOP_OFFSET;
+  }
+  else
+    return USART_INVALID_INPUT;
+
+  if (usart_set_iso7816_clock(usart, opt->iso7816_hz, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  // Set FIDI register: bit rate = selected clock/FI_DI_ratio/16.
+  usart->fidi = opt->fidi_ratio;
+
+  // Set ISO7816 spesific options in the MODE register.
+  usart->mr |= opt->paritytype << AVR32_USART_MR_PAR_OFFSET |
+               AVR32_USART_MR_CLKO_MASK | // Enable clock output.
+               opt->inhibit_nack << AVR32_USART_MR_INACK_OFFSET |
+               opt->dis_suc_nack << AVR32_USART_MR_DSNACK_OFFSET |
+               opt->max_iterations << AVR32_USART_MR_MAX_ITERATION_OFFSET;
+
+  // Setup complete; enable the receiver by default.
+  usart_iso7816_enable_receiver(usart);
+
+  return USART_SUCCESS;
+}
+
+
+#if defined(AVR32_USART_400_H_INCLUDED) || \
+    defined(AVR32_USART_410_H_INCLUDED) || \
+    defined(AVR32_USART_420_H_INCLUDED) || \
+    defined(AVR32_USART_440_H_INCLUDED) || \
+    defined(AVR32_USART_602_H_INCLUDED)
+
+
+int usart_init_lin_master(volatile avr32_usart_t *usart, unsigned long baudrate, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (usart_set_async_baudrate(usart, baudrate, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  usart->mr |= AVR32_USART_MR_MODE_LIN_MASTER << AVR32_USART_MR_MODE_OFFSET;  // LIN master mode.
+
+  // Setup complete; enable communication.
+  // Enable input and output.
+  usart->cr = AVR32_USART_CR_RXEN_MASK |
+              AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_lin_slave(volatile avr32_usart_t *usart, unsigned long baudrate, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (usart_set_async_baudrate(usart, baudrate, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  usart->mr |= AVR32_USART_MR_MODE_LIN_SLAVE << AVR32_USART_MR_MODE_OFFSET; // LIN slave mode.
+
+  // Setup complete; enable communication.
+  // Enable input and output.
+  usart->cr = AVR32_USART_CR_RXEN_MASK |
+              AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_spi_master(volatile avr32_usart_t *usart, const usart_spi_options_t *opt, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (!opt || // Null pointer.
+      opt->charlength < 5 || opt->charlength > 9 ||
+      opt->spimode > 3 ||
+      opt->channelmode > 3 ||
+      usart_set_spi_master_baudrate(usart, opt->baudrate, pba_hz) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  if (opt->charlength == 9)
+  {
+    // Character length set to 9 bits. MODE9 dominates CHRL.
+    usart->mr |= AVR32_USART_MR_MODE9_MASK;
+  }
+  else
+  {
+    // CHRL gives the character length (- 5) when MODE9 = 0.
+    usart->mr |= (opt->charlength - 5) << AVR32_USART_MR_CHRL_OFFSET;
+  }
+
+  usart->mr |= AVR32_USART_MR_MODE_SPI_MASTER << AVR32_USART_MR_MODE_OFFSET | // SPI master mode.
+               ((opt->spimode & 0x1) ^ 0x1) << AVR32_USART_MR_SYNC_OFFSET |   // SPI clock phase.
+               opt->channelmode << AVR32_USART_MR_CHMODE_OFFSET |             // Channel mode.
+               (opt->spimode >> 1) << AVR32_USART_MR_MSBF_OFFSET |            // SPI clock polarity.
+               AVR32_USART_MR_CLKO_MASK;                                      // Drive SCK pin.
+
+  // Setup complete; enable communication.
+  // Enable input and output.
+  usart->cr = AVR32_USART_CR_RXEN_MASK |
+              AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_init_spi_slave(volatile avr32_usart_t *usart, const usart_spi_options_t *opt, long pba_hz)
+{
+  // Reset the USART and shutdown TX and RX.
+  usart_reset(usart);
+
+  // Check input values.
+  if (!opt || // Null pointer.
+      opt->charlength < 5 || opt->charlength > 9 ||
+      opt->spimode > 3 ||
+      opt->channelmode > 3 ||
+      usart_set_spi_slave_baudrate(usart) == USART_INVALID_INPUT)
+    return USART_INVALID_INPUT;
+
+  if (opt->charlength == 9)
+  {
+    // Character length set to 9 bits. MODE9 dominates CHRL.
+    usart->mr |= AVR32_USART_MR_MODE9_MASK;
+  }
+  else
+  {
+    // CHRL gives the character length (- 5) when MODE9 = 0.
+    usart->mr |= (opt->charlength - 5) << AVR32_USART_MR_CHRL_OFFSET;
+  }
+
+  usart->mr |= AVR32_USART_MR_MODE_SPI_SLAVE << AVR32_USART_MR_MODE_OFFSET |  // SPI slave mode.
+               ((opt->spimode & 0x1) ^ 0x1) << AVR32_USART_MR_SYNC_OFFSET |   // SPI clock phase.
+               opt->channelmode << AVR32_USART_MR_CHMODE_OFFSET |             // Channel mode.
+               (opt->spimode >> 1) << AVR32_USART_MR_MSBF_OFFSET;             // SPI clock polarity.
+
+  // Setup complete; enable communication.
+  // Enable input and output.
+  usart->cr = AVR32_USART_CR_RXEN_MASK |
+              AVR32_USART_CR_TXEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+#endif  // USART rev. >= 4.0.0
+
+
+//! @}
+
+
+//------------------------------------------------------------------------------
+#if defined(AVR32_USART_400_H_INCLUDED) || \
+    defined(AVR32_USART_410_H_INCLUDED) || \
+    defined(AVR32_USART_420_H_INCLUDED) || \
+    defined(AVR32_USART_440_H_INCLUDED) || \
+    defined(AVR32_USART_602_H_INCLUDED)
+
+
+/*! \name SPI Control Functions
+ */
+//! @{
+
+
+int usart_spi_selectChip(volatile avr32_usart_t *usart)
+{
+  // Force the SPI chip select.
+  usart->cr = AVR32_USART_CR_RTSEN_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+int usart_spi_unselectChip(volatile avr32_usart_t *usart)
+{
+  int timeout = USART_DEFAULT_TIMEOUT;
+
+  do
+  {
+    if (!timeout--) return USART_FAILURE;
+  } while (!usart_tx_empty(usart));
+
+  // Release the SPI chip select.
+  usart->cr = AVR32_USART_CR_RTSDIS_MASK;
+
+  return USART_SUCCESS;
+}
+
+
+//! @}
+
+
+#endif  // USART rev. >= 4.0.0
+
+
+//------------------------------------------------------------------------------
+/*! \name Transmit/Receive Functions
+ */
+//! @{
+
+
+int usart_send_address(volatile avr32_usart_t *usart, int address)
+{
+  // Check if USART is in multidrop / RS485 mode.
+  if (!usart_mode_is_multidrop(usart)) return USART_MODE_FAULT;
+
+  // Prepare to send an address.
+  usart->cr = AVR32_USART_CR_SENDA_MASK;
+
+  // Write the address to TX.
+  usart_bw_write_char(usart, address);
+
+  return USART_SUCCESS;
+}
+
+
+int usart_write_char(volatile avr32_usart_t *usart, int c)
+{
+  if (usart_tx_ready(usart))
+  {
+    usart->thr = (c << AVR32_USART_THR_TXCHR_OFFSET) & AVR32_USART_THR_TXCHR_MASK;
+    return USART_SUCCESS;
+  }
+  else
+    return USART_TX_BUSY;
+}
+
+
+int usart_putchar(volatile avr32_usart_t *usart, int c)
+{
+  int timeout = USART_DEFAULT_TIMEOUT;
+
+  if (c == '\n')
+  {
+    do
+    {
+      if (!timeout--) return USART_FAILURE;
+    } while (usart_write_char(usart, '\r') != USART_SUCCESS);
+
+    timeout = USART_DEFAULT_TIMEOUT;
+  }
+
+  do
+  {
+    if (!timeout--) return USART_FAILURE;
+  } while (usart_write_char(usart, c) != USART_SUCCESS);
+
+  return USART_SUCCESS;
+}
+
+
+int usart_read_char(volatile avr32_usart_t *usart, int *c)
+{
+  // Check for errors: frame, parity and overrun. In RS485 mode, a parity error
+  // would mean that an address char has been received.
+  if (usart->csr & (AVR32_USART_CSR_OVRE_MASK |
+                    AVR32_USART_CSR_FRAME_MASK |
+                    AVR32_USART_CSR_PARE_MASK))
+    return USART_RX_ERROR;
+
+  // No error; if we really did receive a char, read it and return SUCCESS.
+  if (usart_test_hit(usart))
+  {
+    *c = (usart->rhr & AVR32_USART_RHR_RXCHR_MASK) >> AVR32_USART_RHR_RXCHR_OFFSET;
+    return USART_SUCCESS;
+  }
+  else
+    return USART_RX_EMPTY;
+}
+
+
+int usart_getchar(volatile avr32_usart_t *usart)
+{
+  int c, ret;
+
+  while ((ret = usart_read_char(usart, &c)) == USART_RX_EMPTY);
+
+  if (ret == USART_RX_ERROR)
+    return USART_FAILURE;
+
+  return c;
+}
+
+
+void usart_write_line(volatile avr32_usart_t *usart, const char *string)
+{
+  while (*string != '\0')
+    usart_putchar(usart, *string++);
+}
+
+
+int usart_get_echo_line(volatile avr32_usart_t *usart)
+{
+  int rx_char;
+  int retval = USART_SUCCESS;
+
+  while (1)
+  {
+    rx_char = usart_getchar(usart);
+    if (rx_char == USART_FAILURE)
+    {
+      usart_write_line(usart, "Error!!!\n");
+      retval = USART_FAILURE;
+      break;
+    }
+    if (rx_char == '\x03')
+    {
+      retval = USART_FAILURE;
+      break;
+    }
+    usart_putchar(usart, rx_char);
+    if (rx_char == '\r')
+    {
+      usart_putchar(usart, '\n');
+      break;
+    }
+  }
+
+  return retval;
+}
+
+
+//! @}