FreeRTOS/Demo/lwIP_AVR32_UC3/DRIVERS/INTC/intc.c - nest-yale-lock/1.0.1/freertos - Git at Google

 /*This file is prepared for Doxygen automatic documentation generation.*/
 /*! \file *********************************************************************
  *
  * \brief INTC driver for AVR32 UC3.
  *
  * AVR32 Interrupt Controller driver module.
  *
  * - Compiler:           IAR EWAVR32 and GNU GCC for AVR32
  * - Supported devices:  All AVR32 devices with an INTC module can be used.
  * - AppNote:
  *
  * \author               Atmel Corporation: http://www.atmel.com \n
  *                       Support and FAQ: http://support.atmel.no/
  *
  ******************************************************************************/

 /* Copyright (c) 2007, 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.
  *
  * THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR IMPLIED
  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 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 <avr32/io.h>
 #include "compiler.h"
 #include "preprocessor.h"
 #include "intc.h"


 //! Values to store in the interrupt priority registers for the various interrupt priority levels.
 extern const unsigned int ipr_val[AVR32_INTC_NUM_INT_LEVELS];

 //! Creates a table of interrupt line handlers per interrupt group in order to optimize RAM space.
 //! Each line handler table contains a set of pointers to interrupt handlers.
 #if __GNUC__
 #define DECL_INT_LINE_HANDLER_TABLE(GRP, unused) \
 static volatile __int_handler _int_line_handler_table_##GRP[Max(AVR32_INTC_NUM_IRQS_PER_GRP##GRP, 1)];
 #elif __ICCAVR32__
 #define DECL_INT_LINE_HANDLER_TABLE(GRP, unused) \
 static volatile __no_init __int_handler _int_line_handler_table_##GRP[Max(AVR32_INTC_NUM_IRQS_PER_GRP##GRP, 1)];
 #endif
 MREPEAT(AVR32_INTC_NUM_INT_GRPS, DECL_INT_LINE_HANDLER_TABLE, ~);
 #undef DECL_INT_LINE_HANDLER_TABLE

 //! Table containing for each interrupt group the number of interrupt request
 //! lines and a pointer to the table of interrupt line handlers.
 static const struct
 {
   unsigned int num_irqs;
   volatile __int_handler *_int_line_handler_table;
 } _int_handler_table[AVR32_INTC_NUM_INT_GRPS] =
 {
 #define INSERT_INT_LINE_HANDLER_TABLE(GRP, unused) \
   {AVR32_INTC_NUM_IRQS_PER_GRP##GRP, _int_line_handler_table_##GRP},
   MREPEAT(AVR32_INTC_NUM_INT_GRPS, INSERT_INT_LINE_HANDLER_TABLE, ~)
 #undef INSERT_INT_LINE_HANDLER_TABLE
 };


 /*! \brief Default interrupt handler.
  *
  * \note Taken and adapted from Newlib.
  */
 #if __GNUC__
 __attribute__((__interrupt__))
 #elif __ICCAVR32__
 __interrupt
 #endif
 static void _unhandled_interrupt(void)
 {
   // Catch unregistered interrupts.
   while (TRUE);
 }


 /*! \brief Gets the interrupt handler of the current event at the \a int_lev
  *         interrupt priority level (called from exception.S).
  *
  * \param int_lev Interrupt priority level to handle.
  *
  * \return Interrupt handler to execute.
  *
  * \note Taken and adapted from Newlib.
  */
 __int_handler _get_interrupt_handler(unsigned int int_lev)
 {
   // ICR3 is mapped first, ICR0 last.
   // Code in exception.S puts int_lev in R12 which is used by AVR32-GCC to pass
   // a single argument to a function.
   unsigned int int_grp = (&AVR32_INTC.icr3)[INT3 - int_lev];
   unsigned int int_req = AVR32_INTC.irr[int_grp];

   // As an interrupt may disappear while it is being fetched by the CPU
   // (spurious interrupt caused by a delayed response from an MCU peripheral to
   // an interrupt flag clear or interrupt disable instruction), check if there
   // are remaining interrupt lines to process.
   // If a spurious interrupt occurs, the status register (SR) contains an
   // execution mode and interrupt level masks corresponding to a level 0
   // interrupt, whatever the interrupt priority level causing the spurious
   // event. This behavior has been chosen because a spurious interrupt has not
   // to be a priority one and because it may not cause any trouble to other
   // interrupts.
   // However, these spurious interrupts place the hardware in an unstable state
   // and could give problems in other/future versions of the CPU, so the
   // software has to be written so that they never occur. The only safe way of
   // achieving this is to always clear or disable peripheral interrupts with the
   // following sequence:
   // 1: Mask the interrupt in the CPU by setting GM (or IxM) in SR.
   // 2: Perform the bus access to the peripheral register that clears or
   //    disables the interrupt.
   // 3: Wait until the interrupt has actually been cleared or disabled by the
   //    peripheral. This is usually performed by reading from a register in the
   //    same peripheral (it DOES NOT have to be the same register that was
   //    accessed in step 2, but it MUST be in the same peripheral), what takes
   //    bus system latencies into account, but peripheral internal latencies
   //    (generally 0 cycle) also have to be considered.
   // 4: Unmask the interrupt in the CPU by clearing GM (or IxM) in SR.
   // Note that steps 1 and 4 are useless inside interrupt handlers as the
   // corresponding interrupt level is automatically masked by IxM (unless IxM is
   // explicitly cleared by the software).
   //
   // Get the right IRQ handler.
   //
   // If several interrupt lines are active in the group, the interrupt line with
   // the highest number is selected. This is to be coherent with the
   // prioritization of interrupt groups performed by the hardware interrupt
   // controller.
   //
   // If no handler has been registered for the pending interrupt,
   // _unhandled_interrupt will be selected thanks to the initialization of
   // _int_line_handler_table_x by INTC_init_interrupts.
   //
   // exception.S will provide the interrupt handler with a clean interrupt stack
   // frame, with nothing more pushed onto the stack. The interrupt handler must
   // manage the `rete' instruction, what can be done thanks to pure assembly,
   // inline assembly or the `__attribute__((__interrupt__))' C function
   // attribute.
   return (int_req) ? _int_handler_table[int_grp]._int_line_handler_table[32 - clz(int_req) - 1] : NULL;
 }


 void INTC_init_interrupts(void)
 {
   unsigned int int_grp, int_req;

   // For all interrupt groups,
   for (int_grp = 0; int_grp < AVR32_INTC_NUM_INT_GRPS; int_grp++)
   {
     // For all interrupt request lines of each group,
     for (int_req = 0; int_req < _int_handler_table[int_grp].num_irqs; int_req++)
     {
       // Assign _unhandled_interrupt as default interrupt handler.
       _int_handler_table[int_grp]._int_line_handler_table[int_req] = &_unhandled_interrupt;
     }

     // Set the interrupt group priority register to its default value.
     // By default, all interrupt groups are linked to the interrupt priority
     // level 0 and to the interrupt vector _int0.
     AVR32_INTC.ipr[int_grp] = ipr_val[INT0];
   }
 }


 void INTC_register_interrupt(__int_handler handler, unsigned int irq, unsigned int int_lev)
 {
   // Determine the group of the IRQ.
   unsigned int int_grp = irq / AVR32_INTC_MAX_NUM_IRQS_PER_GRP;

   // Store in _int_line_handler_table_x the pointer to the interrupt handler, so
   // that _get_interrupt_handler can retrieve it when the interrupt is vectored.
   _int_handler_table[int_grp]._int_line_handler_table[irq % AVR32_INTC_MAX_NUM_IRQS_PER_GRP] = handler;

   // Program the corresponding IPRX register to set the interrupt priority level
   // and the interrupt vector offset that will be fetched by the core interrupt
   // system.
   // NOTE: The _intx functions are intermediate assembly functions between the
   // core interrupt system and the user interrupt handler.
   AVR32_INTC.ipr[int_grp] = ipr_val[int_lev & (AVR32_INTC_IPR0_INTLEV_MASK >> AVR32_INTC_IPR0_INTLEV_OFFSET)];
 }
	/This file is prepared for Doxygen automatic documentation generation./
	/! \file ********************************************************************
	*
	* \brief INTC driver for AVR32 UC3.
	*
	* AVR32 Interrupt Controller driver module.
	*
	* - Compiler: IAR EWAVR32 and GNU GCC for AVR32
	* - Supported devices: All AVR32 devices with an INTC module can be used.
	* - AppNote:
	*
	* \author Atmel Corporation: http://www.atmel.com \n
	* Support and FAQ: http://support.atmel.no/
	*
	******************************************************************************/

	/* Copyright (c) 2007, 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.
	*
	* THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR IMPLIED
	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 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 <avr32/io.h>
	#include "compiler.h"
	#include "preprocessor.h"
	#include "intc.h"


	//! Values to store in the interrupt priority registers for the various interrupt priority levels.
	extern const unsigned int ipr_val[AVR32_INTC_NUM_INT_LEVELS];

	//! Creates a table of interrupt line handlers per interrupt group in order to optimize RAM space.
	//! Each line handler table contains a set of pointers to interrupt handlers.
	#if __GNUC__
	#define DECL_INT_LINE_HANDLER_TABLE(GRP, unused) \
	static volatile __int_handler _int_line_handler_table_##GRP[Max(AVR32_INTC_NUM_IRQS_PER_GRP##GRP, 1)];
	#elif __ICCAVR32__
	#define DECL_INT_LINE_HANDLER_TABLE(GRP, unused) \
	static volatile __no_init __int_handler _int_line_handler_table_##GRP[Max(AVR32_INTC_NUM_IRQS_PER_GRP##GRP, 1)];
	#endif
	MREPEAT(AVR32_INTC_NUM_INT_GRPS, DECL_INT_LINE_HANDLER_TABLE, ~);
	#undef DECL_INT_LINE_HANDLER_TABLE

	//! Table containing for each interrupt group the number of interrupt request
	//! lines and a pointer to the table of interrupt line handlers.
	static const struct
	{
	unsigned int num_irqs;
	volatile __int_handler *_int_line_handler_table;
	} _int_handler_table[AVR32_INTC_NUM_INT_GRPS] =
	{
	#define INSERT_INT_LINE_HANDLER_TABLE(GRP, unused) \
	{AVR32_INTC_NUM_IRQS_PER_GRP##GRP, _int_line_handler_table_##GRP},
	MREPEAT(AVR32_INTC_NUM_INT_GRPS, INSERT_INT_LINE_HANDLER_TABLE, ~)
	#undef INSERT_INT_LINE_HANDLER_TABLE
	};


	/*! \brief Default interrupt handler.
	*
	* \note Taken and adapted from Newlib.
	*/
	#if __GNUC__
	__attribute__((__interrupt__))
	#elif __ICCAVR32__
	__interrupt
	#endif
	static void _unhandled_interrupt(void)
	{
	// Catch unregistered interrupts.
	while (TRUE);
	}


	/*! \brief Gets the interrupt handler of the current event at the \a int_lev
	* interrupt priority level (called from exception.S).
	*
	* \param int_lev Interrupt priority level to handle.
	*
	* \return Interrupt handler to execute.
	*
	* \note Taken and adapted from Newlib.
	*/
	__int_handler _get_interrupt_handler(unsigned int int_lev)
	{
	// ICR3 is mapped first, ICR0 last.
	// Code in exception.S puts int_lev in R12 which is used by AVR32-GCC to pass
	// a single argument to a function.
	unsigned int int_grp = (&AVR32_INTC.icr3)[INT3 - int_lev];
	unsigned int int_req = AVR32_INTC.irr[int_grp];

	// As an interrupt may disappear while it is being fetched by the CPU
	// (spurious interrupt caused by a delayed response from an MCU peripheral to
	// an interrupt flag clear or interrupt disable instruction), check if there
	// are remaining interrupt lines to process.
	// If a spurious interrupt occurs, the status register (SR) contains an
	// execution mode and interrupt level masks corresponding to a level 0
	// interrupt, whatever the interrupt priority level causing the spurious
	// event. This behavior has been chosen because a spurious interrupt has not
	// to be a priority one and because it may not cause any trouble to other
	// interrupts.
	// However, these spurious interrupts place the hardware in an unstable state
	// and could give problems in other/future versions of the CPU, so the
	// software has to be written so that they never occur. The only safe way of
	// achieving this is to always clear or disable peripheral interrupts with the
	// following sequence:
	// 1: Mask the interrupt in the CPU by setting GM (or IxM) in SR.
	// 2: Perform the bus access to the peripheral register that clears or
	// disables the interrupt.
	// 3: Wait until the interrupt has actually been cleared or disabled by the
	// peripheral. This is usually performed by reading from a register in the
	// same peripheral (it DOES NOT have to be the same register that was
	// accessed in step 2, but it MUST be in the same peripheral), what takes
	// bus system latencies into account, but peripheral internal latencies
	// (generally 0 cycle) also have to be considered.
	// 4: Unmask the interrupt in the CPU by clearing GM (or IxM) in SR.
	// Note that steps 1 and 4 are useless inside interrupt handlers as the
	// corresponding interrupt level is automatically masked by IxM (unless IxM is
	// explicitly cleared by the software).
	//
	// Get the right IRQ handler.
	//
	// If several interrupt lines are active in the group, the interrupt line with
	// the highest number is selected. This is to be coherent with the
	// prioritization of interrupt groups performed by the hardware interrupt
	// controller.
	//
	// If no handler has been registered for the pending interrupt,
	// _unhandled_interrupt will be selected thanks to the initialization of
	// _int_line_handler_table_x by INTC_init_interrupts.
	//
	// exception.S will provide the interrupt handler with a clean interrupt stack
	// frame, with nothing more pushed onto the stack. The interrupt handler must
	// manage the `rete' instruction, what can be done thanks to pure assembly,
	// inline assembly or the `__attribute__((__interrupt__))' C function
	// attribute.
	return (int_req) ? _int_handler_table[int_grp]._int_line_handler_table[32 - clz(int_req) - 1] : NULL;
	}


	void INTC_init_interrupts(void)
	{
	unsigned int int_grp, int_req;

	// For all interrupt groups,
	for (int_grp = 0; int_grp < AVR32_INTC_NUM_INT_GRPS; int_grp++)
	{
	// For all interrupt request lines of each group,
	for (int_req = 0; int_req < _int_handler_table[int_grp].num_irqs; int_req++)
	{
	// Assign _unhandled_interrupt as default interrupt handler.
	_int_handler_table[int_grp]._int_line_handler_table[int_req] = &_unhandled_interrupt;
	}

	// Set the interrupt group priority register to its default value.
	// By default, all interrupt groups are linked to the interrupt priority
	// level 0 and to the interrupt vector _int0.
	AVR32_INTC.ipr[int_grp] = ipr_val[INT0];
	}
	}


	void INTC_register_interrupt(__int_handler handler, unsigned int irq, unsigned int int_lev)
	{
	// Determine the group of the IRQ.
	unsigned int int_grp = irq / AVR32_INTC_MAX_NUM_IRQS_PER_GRP;

	// Store in _int_line_handler_table_x the pointer to the interrupt handler, so
	// that _get_interrupt_handler can retrieve it when the interrupt is vectored.
	_int_handler_table[int_grp]._int_line_handler_table[irq % AVR32_INTC_MAX_NUM_IRQS_PER_GRP] = handler;

	// Program the corresponding IPRX register to set the interrupt priority level
	// and the interrupt vector offset that will be fetched by the core interrupt
	// system.
	// NOTE: The _intx functions are intermediate assembly functions between the
	// core interrupt system and the user interrupt handler.
	AVR32_INTC.ipr[int_grp] = ipr_val[int_lev & (AVR32_INTC_IPR0_INTLEV_MASK >> AVR32_INTC_IPR0_INTLEV_OFFSET)];
	}