bacnet_stack/ports/xplained/ASF/xmega/drivers/tc/tc.c

/**
 * \file
 *
 * \brief AVR XMEGA TC Driver
 *
 * Copyright (c) 2010 Atmel Corporation. All rights reserved.
 *
 * \asf_license_start
 *
 * \page License
 *
 * 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 microcontroller 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.
 *
 * \asf_license_stop
 *
 */
#include <stdint.h>

#include "interrupt.h"
#include "compiler.h"
#include "parts.h"

#include "tc.h"
#include "sysclk.h"
#include "sleepmgr.h"
#include "status_codes.h"

#if defined(TCC0) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCC0 interrupt callback function
static tc_callback_t tc_tcc0_ovf_callback;
static tc_callback_t tc_tcc0_err_callback;
static tc_callback_t tc_tcc0_cca_callback;
static tc_callback_t tc_tcc0_ccb_callback;
static tc_callback_t tc_tcc0_ccc_callback;
static tc_callback_t tc_tcc0_ccd_callback;


/**
 * \internal
 * \brief Interrupt handler for Timer Counter C0 overflow
 *
 * This function will handle interrupt on Timer Counter CO overflow and
 * call the callback function.
 */
ISR(TCC0_OVF_vect)
{
    if (tc_tcc0_ovf_callback) {
        tc_tcc0_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C0 error
 *
 * This function will handle interrupt on Timer Counter CO error and
 * call the callback function.
 */
ISR(TCC0_ERR_vect)
{
    if (tc_tcc0_err_callback) {
        tc_tcc0_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C0 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter CO Compare/CaptureA and
 * call the callback function.
 */
ISR(TCC0_CCA_vect)
{
    if (tc_tcc0_cca_callback) {
        tc_tcc0_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C0 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter CO Compare/CaptureB and
 * call the callback function.
 */
ISR(TCC0_CCB_vect)
{
    if (tc_tcc0_ccb_callback) {
        tc_tcc0_ccb_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C0 Compare/CaptureC
 *
 * This function will handle interrupt on Timer Counter CO Compare/CaptureC and
 * call the callback function.
 */
ISR(TCC0_CCC_vect)
{
    if (tc_tcc0_ccc_callback) {
        tc_tcc0_ccc_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C0 Compare/CaptureD
 *
 * This function will handle interrupt on Timer Counter CO Compare/CaptureD and
 * call the callback function.
 */
ISR(TCC0_CCD_vect)
{
    if (tc_tcc0_ccd_callback) {
        tc_tcc0_ccd_callback();
    }
}

#endif

#if defined(TCC1) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCC1 interrupt callback function
static tc_callback_t tc_tcc1_ovf_callback;
static tc_callback_t tc_tcc1_err_callback;
static tc_callback_t tc_tcc1_cca_callback;
static tc_callback_t tc_tcc1_ccb_callback;

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C1 overflow
 *
 * This function will handle interrupt on Timer Counter C1 overflow and
 * call the callback function.
 */
ISR(TCC1_OVF_vect)
{
    if (tc_tcc1_ovf_callback) {
        tc_tcc1_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C1 error
 *
 * This function will handle interrupt on Timer Counter C1 error and
 * call the callback function.
 */
ISR(TCC1_ERR_vect)
{
    if (tc_tcc1_err_callback) {
        tc_tcc1_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C1 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter C1 Compare/CaptureA and
 * call the callback function.
 */
ISR(TCC1_CCA_vect)
{
    if (tc_tcc1_cca_callback) {
        tc_tcc1_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter C1 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter C1 Compare/CaptureB and
 * call the callback function.
 */
ISR(TCC1_CCB_vect)
{
    if (tc_tcc1_ccb_callback) {
        tc_tcc1_ccb_callback();
    }
}

#endif

#if defined(TCD0) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCD0 interrupt callback function
static tc_callback_t tc_tcd0_ovf_callback;
static tc_callback_t tc_tcd0_err_callback;
static tc_callback_t tc_tcd0_cca_callback;
static tc_callback_t tc_tcd0_ccb_callback;
static tc_callback_t tc_tcd0_ccc_callback;
static tc_callback_t tc_tcd0_ccd_callback;


/**
 * \internal
 * \brief Interrupt handler for Timer Counter D0 overflow
 *
 * This function will handle interrupt on Timer Counter D0 overflow and
 * call the callback function.
 */
ISR(TCD0_OVF_vect)
{
    if (tc_tcd0_ovf_callback) {
        tc_tcd0_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D0 error
 *
 * This function will handle interrupt on Timer Counter D0 error and
 * call the callback function.
 */
ISR(TCD0_ERR_vect)
{
    if (tc_tcd0_err_callback) {
        tc_tcd0_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D0 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter D0 Compare/CaptureA and
 * call the callback function.
 */
ISR(TCD0_CCA_vect)
{
    if (tc_tcd0_cca_callback) {
        tc_tcd0_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D0 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter D0 Compare/CaptureB and
 * call the callback function.
 */
ISR(TCD0_CCB_vect)
{
    if (tc_tcd0_ccb_callback) {
        tc_tcd0_ccb_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D0 Compare/CaptureC
 *
 * This function will handle interrupt on Timer Counter D0 Compare/CaptureC and
 * call the callback function.
 */
ISR(TCD0_CCC_vect)
{
    if (tc_tcd0_ccc_callback) {
        tc_tcd0_ccc_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D0 Compare/CaptureD
 *
 * This function will handle interrupt on Timer Counter D0 Compare/CaptureD and
 * call the callback function.
 */
ISR(TCD0_CCD_vect)
{
    if (tc_tcd0_ccd_callback) {
        tc_tcd0_ccd_callback();
    }
}

#endif

#if defined(TCD1) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCD1 interrupt callback function
static tc_callback_t tc_tcd1_ovf_callback;
static tc_callback_t tc_tcd1_err_callback;
static tc_callback_t tc_tcd1_cca_callback;
static tc_callback_t tc_tcd1_ccb_callback;

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D1 overflow
 *
 * This function will handle interrupt on Timer Counter D1 overflow and
 * call the callback function.
 */
ISR(TCD1_OVF_vect)
{
    if (tc_tcd1_ovf_callback) {
        tc_tcd1_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D1 error
 *
 * This function will handle interrupt on Timer Counter D1 error and
 * call the callback function.
 */
ISR(TCD1_ERR_vect)
{
    if (tc_tcd1_err_callback) {
        tc_tcd1_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D1 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter D1 Compare/CaptureA and
 * call the callback function.
 */
ISR(TCD1_CCA_vect)
{
    if (tc_tcd1_cca_callback) {
        tc_tcd1_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter D1 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter D1 Compare/CaptureB and
 * call the callback function.
 */
ISR(TCD1_CCB_vect)
{
    if (tc_tcd1_ccb_callback) {
        tc_tcd1_ccb_callback();
    }
}

#endif


#if defined(TCE0) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCE0 interrupt callback function
static tc_callback_t tc_tce0_ovf_callback;
static tc_callback_t tc_tce0_err_callback;
static tc_callback_t tc_tce0_cca_callback;
static tc_callback_t tc_tce0_ccb_callback;
static tc_callback_t tc_tce0_ccc_callback;
static tc_callback_t tc_tce0_ccd_callback;


/**
 * \internal
 * \brief Interrupt handler for Timer Counter E0 overflow
 *
 * This function will handle interrupt on Timer Counter E0 overflow and
 * call the callback function.
 */
ISR(TCE0_OVF_vect)
{
    if (tc_tce0_ovf_callback) {
        tc_tce0_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E0 error
 *
 * This function will handle interrupt on Timer Counter E0 error and
 * call the callback function.
 */
ISR(TCE0_ERR_vect)
{
    if (tc_tce0_err_callback) {
        tc_tce0_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E0 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter E0 Compare/CaptureA and
 * call the callback function.
 */
ISR(TCE0_CCA_vect)
{
    if (tc_tce0_cca_callback) {
        tc_tce0_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E0 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter E0 Compare/CaptureB and
 * call the callback function.
 */
ISR(TCE0_CCB_vect)
{
    if (tc_tce0_ccb_callback) {
        tc_tce0_ccb_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E0 Compare/CaptureC
 *
 * This function will handle interrupt on Timer Counter E0 Compare/CaptureC and
 * call the callback function.
 */
ISR(TCE0_CCC_vect)
{
    if (tc_tce0_ccc_callback) {
        tc_tce0_ccc_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E0 Compare/CaptureD
 *
 * This function will handle interrupt on Timer Counter E0 Compare/CaptureD and
 * call the callback function.
 */
ISR(TCE0_CCD_vect)
{
    if (tc_tce0_ccd_callback) {
        tc_tce0_ccd_callback();
    }
}

#endif

#if defined(TCE1) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCE1 interrupt callback function
static tc_callback_t tc_tce1_ovf_callback;
static tc_callback_t tc_tce1_err_callback;
static tc_callback_t tc_tce1_cca_callback;
static tc_callback_t tc_tce1_ccb_callback;

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E1 overflow
 *
 * This function will handle interrupt on Timer Counter E1 overflow and
 * call the callback function.
 */
ISR(TCE1_OVF_vect)
{
    if (tc_tce1_ovf_callback) {
        tc_tce1_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E1 error
 *
 * This function will handle interrupt on Timer Counter E1 error and
 * call the callback function.
 */
ISR(TCE1_ERR_vect)
{
    if (tc_tce1_err_callback) {
        tc_tce1_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E1 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter E1 Compare/CaptureA and
 * call the callback function.
 */
ISR(TCE1_CCA_vect)
{
    if (tc_tce1_cca_callback) {
        tc_tce1_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter E1 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter E1 Compare/CaptureB and
 * call the callback function.
 */
ISR(TCE1_CCB_vect)
{
    if (tc_tce1_ccb_callback) {
        tc_tce1_ccb_callback();
    }
}

#endif

#if defined(TCF0) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCF0 interrupt callback function
static tc_callback_t tc_tcf0_ovf_callback;
static tc_callback_t tc_tcf0_err_callback;
static tc_callback_t tc_tcf0_cca_callback;
static tc_callback_t tc_tcf0_ccb_callback;
static tc_callback_t tc_tcf0_ccc_callback;
static tc_callback_t tc_tcf0_ccd_callback;


/**
 * \internal
 * \brief Interrupt handler for Timer Counter E0 overflow
 *
 * This function will handle interrupt on Timer Counter F0 overflow and
 * call the callback function.
 */
ISR(TCF0_OVF_vect)
{
    if (tc_tcf0_ovf_callback) {
        tc_tcf0_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F0 error
 *
 * This function will handle interrupt on Timer Counter F0 error and
 * call the callback function.
 */
ISR(TCF0_ERR_vect)
{
    if (tc_tcf0_err_callback) {
        tc_tcf0_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F0 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter F0 Compare/CaptureA and
 * call the callback function.
 */
ISR(TCF0_CCA_vect)
{
    if (tc_tcf0_cca_callback) {
        tc_tcf0_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F0 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter F0 Compare/CaptureB and
 * call the callback function.
 */
ISR(TCF0_CCB_vect)
{
    if (tc_tcf0_ccb_callback) {
        tc_tcf0_ccb_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F0 Compare/CaptureC
 *
 * This function will handle interrupt on Timer Counter F0 Compare/CaptureC and
 * call the callback function.
 */
ISR(TCF0_CCC_vect)
{
    if (tc_tcf0_ccc_callback) {
        tc_tcf0_ccc_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F0 Compare/CaptureD
 *
 * This function will handle interrupt on Timer Counter F0 Compare/CaptureD and
 * call the callback function.
 */
ISR(TCF0_CCD_vect)
{
    if (tc_tcf0_ccd_callback) {
        tc_tcf0_ccd_callback();
    }
}

#endif

#if defined(TCF1) || defined(__DOXYGEN__)
//! \internal Local storage of Timer Counter TCF1 interrupt callback function
static tc_callback_t tc_tcf1_ovf_callback;
static tc_callback_t tc_tcf1_err_callback;
static tc_callback_t tc_tcf1_cca_callback;
static tc_callback_t tc_tcf1_ccb_callback;

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F1 overflow
 *
 * This function will handle interrupt on Timer Counter F1 overflow and
 * call the callback function.
 */
ISR(TCF1_OVF_vect)
{
    if (tc_tcf1_ovf_callback) {
        tc_tcf1_ovf_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F1 error
 *
 * This function will handle interrupt on Timer Counter F1 error and
 * call the callback function.
 */
ISR(TCF1_ERR_vect)
{
    if (tc_tcf1_err_callback) {
        tc_tcf1_err_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F1 Compare/CaptureA
 *
 * This function will handle interrupt on Timer Counter F1 Compare/CaptureA and
 * call the callback function.
 */
ISR(TCF1_CCA_vect)
{
    if (tc_tcf1_cca_callback) {
        tc_tcf1_cca_callback();
    }
}

/**
 * \internal
 * \brief Interrupt handler for Timer Counter F1 Compare/CaptureB
 *
 * This function will handle interrupt on Timer Counter F1 Compare/CaptureB and
 * call the callback function.
 */
ISR(TCF1_CCB_vect)
{
    if (tc_tcf1_ccb_callback) {
        tc_tcf1_ccb_callback();
    }
}

#endif

/**
 * \brief Enable TC
 *
 * Enables the TC.
 *
 * \param tc Pointer to TC module
 *
 * \note
 * unmask TC clock (sysclk), but does not configure the TC clock source.
 */
void tc_enable(volatile void *tc)
{
    irqflags_t iflags = cpu_irq_save();

#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        sysclk_enable_module(SYSCLK_PORT_C, SYSCLK_TC0);
        sysclk_enable_module(SYSCLK_PORT_C, SYSCLK_HIRES);
    } else
#endif
#ifdef TCC1
    if ((uintptr_t) tc == (uintptr_t) & TCC1) {
        sysclk_enable_module(SYSCLK_PORT_C, SYSCLK_TC1);
        sysclk_enable_module(SYSCLK_PORT_C, SYSCLK_HIRES);
    } else
#endif
#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        sysclk_enable_module(SYSCLK_PORT_D, SYSCLK_TC0);
        sysclk_enable_module(SYSCLK_PORT_D, SYSCLK_HIRES);
    } else
#endif
#ifdef TCD1
    if ((uintptr_t) tc == (uintptr_t) & TCD1) {
        sysclk_enable_module(SYSCLK_PORT_D, SYSCLK_TC1);
        sysclk_enable_module(SYSCLK_PORT_D, SYSCLK_HIRES);
    } else
#endif
#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        sysclk_enable_module(SYSCLK_PORT_E, SYSCLK_TC0);
        sysclk_enable_module(SYSCLK_PORT_E, SYSCLK_HIRES);
    } else
#endif
#ifdef TCE1
    if ((uintptr_t) tc == (uintptr_t) & TCE1) {
        sysclk_enable_module(SYSCLK_PORT_E, SYSCLK_TC1);
        sysclk_enable_module(SYSCLK_PORT_E, SYSCLK_HIRES);
    } else
#endif
#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        sysclk_enable_module(SYSCLK_PORT_F, SYSCLK_TC0);
        sysclk_enable_module(SYSCLK_PORT_F, SYSCLK_HIRES);
    } else
#endif
#ifdef TCF1
    if ((uintptr_t) tc == (uintptr_t) & TCF1) {
        sysclk_enable_module(SYSCLK_PORT_F, SYSCLK_TC1);
        sysclk_enable_module(SYSCLK_PORT_F, SYSCLK_HIRES);
    } else
#endif
    {
        cpu_irq_restore(iflags);
        return;
    }
    sleepmgr_lock_mode(SLEEPMGR_IDLE);
    cpu_irq_restore(iflags);
}


/**
 * \brief Disable TC
 *
 * Disables the TC.
 *
 * \param tc Pointer to TC module
 *
 * \note
 * mask TC clock (sysclk).
 */
void tc_disable(volatile void *tc)
{
    irqflags_t iflags = cpu_irq_save();

    sleepmgr_unlock_mode(SLEEPMGR_IDLE);

#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        sysclk_disable_module(SYSCLK_PORT_C, SYSCLK_TC0);
        sysclk_disable_module(SYSCLK_PORT_C, SYSCLK_HIRES);
    } else
#endif
#ifdef TCC1
    if ((uintptr_t) tc == (uintptr_t) & TCC1) {
        sysclk_disable_module(SYSCLK_PORT_C, SYSCLK_TC1);
        sysclk_disable_module(SYSCLK_PORT_C, SYSCLK_HIRES);
    } else
#endif
#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        sysclk_disable_module(SYSCLK_PORT_D, SYSCLK_TC0);
        sysclk_disable_module(SYSCLK_PORT_D, SYSCLK_HIRES);
    } else
#endif
#ifdef TCD1
    if ((uintptr_t) tc == (uintptr_t) & TCD1) {
        sysclk_disable_module(SYSCLK_PORT_D, SYSCLK_TC1);
        sysclk_disable_module(SYSCLK_PORT_D, SYSCLK_HIRES);
    } else
#endif
#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        sysclk_disable_module(SYSCLK_PORT_E, SYSCLK_TC0);
        sysclk_disable_module(SYSCLK_PORT_E, SYSCLK_HIRES);
    } else
#endif
#ifdef TCE1
    if ((uintptr_t) tc == (uintptr_t) & TCE1) {
        sysclk_disable_module(SYSCLK_PORT_E, SYSCLK_TC1);
        sysclk_disable_module(SYSCLK_PORT_E, SYSCLK_HIRES);
    } else
#endif
#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        sysclk_disable_module(SYSCLK_PORT_F, SYSCLK_TC0);
        sysclk_disable_module(SYSCLK_PORT_F, SYSCLK_HIRES);
    } else
#endif
#ifdef TCF1
    if ((uintptr_t) tc == (uintptr_t) & TCF1) {
        sysclk_disable_module(SYSCLK_PORT_F, SYSCLK_TC1);
        sysclk_disable_module(SYSCLK_PORT_F, SYSCLK_HIRES);
    } else
#endif
    {
        cpu_irq_restore(iflags);
        return;
    }
    cpu_irq_restore(iflags);
}

void tc_set_overflow_interrupt_callback(volatile void *tc,
    tc_callback_t callback)
{
#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        tc_tcc0_ovf_callback = callback;
    } else
#endif
#ifdef TCC1
    if ((uintptr_t) tc == (uintptr_t) & TCC1) {
        tc_tcc1_ovf_callback = callback;
    } else
#endif
#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        tc_tcd0_ovf_callback = callback;
    } else
#endif
#ifdef TCD1
    if ((uintptr_t) tc == (uintptr_t) & TCD1) {
        tc_tcd1_ovf_callback = callback;
    } else
#endif
#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        tc_tce0_ovf_callback = callback;
    } else
#endif
#ifdef TCE1
    if ((uintptr_t) tc == (uintptr_t) & TCE1) {
        tc_tce1_ovf_callback = callback;
    } else
#endif
#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        tc_tcf0_ovf_callback = callback;
    } else
#endif
#ifdef TCF1
    if ((uintptr_t) tc == (uintptr_t) & TCF1) {
        tc_tcf1_ovf_callback = callback;
    } else
#endif
    {
    }
}

void tc_set_error_interrupt_callback(volatile void *tc,
    tc_callback_t callback)
{
#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        tc_tcc0_err_callback = callback;
    } else
#endif
#ifdef TCC1
    if ((uintptr_t) tc == (uintptr_t) & TCC1) {
        tc_tcc1_err_callback = callback;
    } else
#endif
#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        tc_tcd0_err_callback = callback;
    } else
#endif
#ifdef TCD1
    if ((uintptr_t) tc == (uintptr_t) & TCD1) {
        tc_tcd1_err_callback = callback;
    } else
#endif
#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        tc_tce0_err_callback = callback;
    } else
#endif
#ifdef TCE1
    if ((uintptr_t) tc == (uintptr_t) & TCE1) {
        tc_tce1_err_callback = callback;
    } else
#endif
#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        tc_tcf0_err_callback = callback;
    } else
#endif
#ifdef TCF1
    if ((uintptr_t) tc == (uintptr_t) & TCF1) {
        tc_tcf1_err_callback = callback;
    } else
#endif
    {
    }
}

void tc_set_cca_interrupt_callback(volatile void *tc,
    tc_callback_t callback)
{
#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        tc_tcc0_cca_callback = callback;
    } else
#endif
#ifdef TCC1
    if ((uintptr_t) tc == (uintptr_t) & TCC1) {
        tc_tcc1_cca_callback = callback;
    } else
#endif
#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        tc_tcd0_cca_callback = callback;
    } else
#endif
#ifdef TCD1
    if ((uintptr_t) tc == (uintptr_t) & TCD1) {
        tc_tcd1_cca_callback = callback;
    } else
#endif
#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        tc_tce0_cca_callback = callback;
    } else
#endif
#ifdef TCE1
    if ((uintptr_t) tc == (uintptr_t) & TCE1) {
        tc_tce1_cca_callback = callback;
    } else
#endif
#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        tc_tcf0_cca_callback = callback;
    } else
#endif
#ifdef TCF1
    if ((uintptr_t) tc == (uintptr_t) & TCF1) {
        tc_tcf1_cca_callback = callback;
    } else
#endif
    {
    }
}

void tc_set_ccb_interrupt_callback(volatile void *tc,
    tc_callback_t callback)
{
#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        tc_tcc0_ccb_callback = callback;
    } else
#endif
#ifdef TCC1
    if ((uintptr_t) tc == (uintptr_t) & TCC1) {
        tc_tcc1_ccb_callback = callback;
    } else
#endif
#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        tc_tcd0_ccb_callback = callback;
    } else
#endif
#ifdef TCD1
    if ((uintptr_t) tc == (uintptr_t) & TCD1) {
        tc_tcd1_ccb_callback = callback;
    } else
#endif
#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        tc_tce0_ccb_callback = callback;
    } else
#endif
#ifdef TCE1
    if ((uintptr_t) tc == (uintptr_t) & TCE1) {
        tc_tce1_ccb_callback = callback;
    } else
#endif
#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        tc_tcf0_ccb_callback = callback;
    } else
#endif
#ifdef TCF1
    if ((uintptr_t) tc == (uintptr_t) & TCF1) {
        tc_tcf1_ccb_callback = callback;
    } else
#endif
    {
    }
}

void tc_set_ccc_interrupt_callback(volatile void *tc,
    tc_callback_t callback)
{
#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        tc_tcc0_ccc_callback = callback;
    } else
#endif

#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        tc_tcd0_ccc_callback = callback;
    } else
#endif

#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        tc_tce0_ccc_callback = callback;
    } else
#endif

#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        tc_tcf0_ccc_callback = callback;
    } else
#endif
    {
    }

}


void tc_set_ccd_interrupt_callback(volatile void *tc,
    tc_callback_t callback)
{
#ifdef TCC0
    if ((uintptr_t) tc == (uintptr_t) & TCC0) {
        tc_tcc0_ccd_callback = callback;
    } else
#endif

#ifdef TCD0
    if ((uintptr_t) tc == (uintptr_t) & TCD0) {
        tc_tcd0_ccd_callback = callback;
    } else
#endif

#ifdef TCE0
    if ((uintptr_t) tc == (uintptr_t) & TCE0) {
        tc_tce0_ccd_callback = callback;
    } else
#endif

#ifdef TCF0
    if ((uintptr_t) tc == (uintptr_t) & TCF0) {
        tc_tcf0_ccd_callback = callback;
    } else
#endif
    {
    }
}