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Enhance and document the AVR32 UC3 platform drivers.

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pull/1469/head
Dean Camera 13 years ago
parent bd8046976f
commit 5f51554a5e
5 changed files with 401 additions and 177 deletions
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LUFA.pnproj
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LUFA/ManPages/Groups.txt
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@ -19,3 +19,7 @@
* Miscellaneous driver Functions, macros, variables, enums and types. * Miscellaneous driver Functions, macros, variables, enums and types.
*/ */
/** @defgroup Group_PlatformDrivers System Platform Drivers
*
* Drivers relating to the general architecture platform, such as clock setup and interrupt management.
*/

398
LUFA/Platform/UC3/ClockManagement.h
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@ -28,8 +28,48 @@
this software. this software.
*/ */
#ifndef _CLOCK_MANAGEMENT_H_ /** \file
#define _CLOCK_MANAGEMENT_H_ * \brief Module Clock Driver for the AVR32 UC3 microcontrollers.
*
* Clock management driver for the AVR32 UC3 microcontrollers. This driver allows for the configuration
* of the various clocks within the device to clock the various peripherals.
*/
/** \ingroup Group_PlatformDrivers
* \defgroup Group_PlatformDrivers_UC3Clocks UC3 Clock Management Driver - LUFA/Platform/UC3/ClockManagement.h
* \brief Module Clock Driver for the AVR32 UC3 microcontrollers.
*
* \section Sec_Dependencies Module Source Dependencies
* The following files must be built with any user project that uses this module:
* - None
*
* \section Sec_ModDescription Module Description
* Clock management driver for the AVR32 UC3 microcontrollers. This driver allows for the configuration
* of the various clocks within the device to clock the various peripherals.
*
* Usage Example:
* \code
* #include <LUFA/Platform/UC3/ClockManagement.h>
*
* void main(void)
* {
* // Start the master external oscillator which will be used as the main clock reference
* AVR32CLK_StartExternalOscillator(0, EXOSC_MODE_8MHZ_OR_MORE, EXOSC_START_0CLK);
*
* // Start the PLL for the CPU clock, switch CPU to it
* AVR32CLK_StartPLL(0, CLOCK_SRC_OSC0, 12000000, F_CPU);
* AVR32CLK_SetCPUClockSource(CLOCK_SRC_PLL0, F_CPU);
*
* // Start the PLL for the USB Generic Clock module
* AVR32CLK_StartPLL(1, CLOCK_SRC_OSC0, 12000000, 48000000);
* }
* \endcode
*
* @{
*/
#ifndef _UC3_CLOCK_MANAGEMENT_H_
#define _UC3_CLOCK_MANAGEMENT_H_
/* Includes: */ /* Includes: */
#include <avr32/io.h> #include <avr32/io.h>
@ -38,144 +78,240 @@
#include <LUFA/Common/Common.h> #include <LUFA/Common/Common.h>
/* Macros: */ /* Enable C linkage for C++ Compilers: */
enum Extern_OSC_ClockStartup_t #if defined(__cplusplus)
{ extern "C" {
EXOSC_START_0CLK = 0, #endif
EXOSC_START_64CLK = 1,
EXOSC_START_128CLK = 2, /* Public Interface - May be used in end-application: */
EXOSC_START_2048CLK = 3, /* Macros: */
EXOSC_START_4096CLK = 4, /** Enum for the possible external oscillator types. */
EXOSC_START_8192CLK = 5, enum Extern_OSC_ClockTypes_t
EXOSC_START_16384CLK = 6, {
}; EXOSC_MODE_CLOCK = 0, /**< External clock (non-crystal) mode. */
EXOSC_MODE_900KHZ_MAX = 1, /**< External crystal oscillator equal to or slower than 900KHz. */
enum Extern_OSC_ClockMode_t EXOSC_MODE_3MHZ_MAX = 2, /**< External crystal oscillator equal to or slower than 3MHz. */
{ EXOSC_MODE_8MHZ_MAX = 3, /**< External crystal oscillator equal to or slower than 8MHz. */
EXOSC_MODE_CLOCK = 0, EXOSC_MODE_8MHZ_OR_MORE = 4, /**< External crystal oscillator equal to or faster than 8MHz. */
EXOSC_MODE_900KHZ_MAX = 1, };
EXOSC_MODE_3MHZ_MAX = 2,
EXOSC_MODE_8MHZ_MAX = 3, /** Enum for the possible external oscillator statup times. */
EXOSC_MODE_8MHZ_OR_MORE = 4, enum Extern_OSC_ClockStartup_t
}; {
EXOSC_START_0CLK = 0, /**< Immediate startup, no delay. */
enum EXOSC_START_64CLK = 1, /**< Wait 64 clock cyles before startup for stability. */
{ EXOSC_START_128CLK = 2, /**< Wait 128 clock cyles before startup for stability. */
CLOCK_SRC_SLOW_CLK = 0, EXOSC_START_2048CLK = 3, /**< Wait 2048 clock cyles before startup for stability. */
CLOCK_SRC_OSC0 = 1, EXOSC_START_4096CLK = 4, /**< Wait 4096 clock cyles before startup for stability. */
CLOCK_SRC_OSC1 = 2, EXOSC_START_8192CLK = 5, /**< Wait 8192 clock cyles before startup for stability. */
CLOCK_SRC_PLL0 = 3, EXOSC_START_16384CLK = 6, /**< Wait 16384 clock cyles before startup for stability. */
CLOCK_SRC_PLL1 = 4, };
};
/** Enum for the possible module clock sources. */
/* Inline Functions: */ enum System_ClockSource_t
static inline bool AVR32CLK_StartExternalOscillator(const uint8_t Channel, {
const uint8_t Type, CLOCK_SRC_SLOW_CLK = 0, /**< Clock sourced from the internal slow clock. */
const uint8_t Startup) CLOCK_SRC_OSC0 = 1, /**< Clock sourced from the Oscillator 0 clock. */
{ CLOCK_SRC_OSC1 = 2, /**< Clock sourced from the Oscillator 1 clock. */
AVR32_PM.OSCCTRL0.startup = Startup; CLOCK_SRC_PLL0 = 3, /**< Clock sourced from the PLL 0 clock. */
AVR32_PM.OSCCTRL0.mode = Type; CLOCK_SRC_PLL1 = 4, /**< Clock sourced from the PLL 1 clock. */
AVR32_PM.mcctrl |= (1 << (AVR32_PM_MCCTRL_OSC0EN_OFFSET + Channel)); };
while (!(AVR32_PM.poscsr & (1 << (AVR32_PM_POSCSR_OSC0RDY_OFFSET + Channel)))); /* Inline Functions: */
return true; /** Starts the given external oscillator of the UC3 microcontroller, with the given options. This routine blocks until
} * the oscillator is ready for use.
*
static inline void AVR32CLK_StopExternalOscillator(const uint8_t Channel) * \param[in] Channel Index of the external oscillator to start.
{ * \param[in] Type Type of clock attached to the given oscillator channel, a value from \ref Extern_OSC_ClockTypes_t.
AVR32_PM.mcctrl &= ~(1 << (AVR32_PM_MCCTRL_OSC0EN_OFFSET + Channel)); * \param[in] Startup Statup time of the external oscillator, a value from \ref Extern_OSC_ClockStartup_t.
} *
* \return Boolean \c true if the external oscillator was successfully started, \c false if invalid parameters specified.
static inline bool AVR32CLK_StartPLL(const uint8_t Channel, */
const uint8_t Source, static inline void AVR32CLK_StartExternalOscillator(const uint8_t Channel,
const uint32_t SourceFreq, const uint8_t Type,
const uint32_t Frequency) const uint8_t Startup) ATTR_ALWAYS_INLINE;
{ static inline void AVR32CLK_StartExternalOscillator(const uint8_t Channel,
switch (Source) const uint8_t Type,
const uint8_t Startup)
{
switch (Channel)
{
case 0:
AVR32_PM.OSCCTRL0.startup = Startup;
AVR32_PM.OSCCTRL0.mode = Type;
break;
case 1:
AVR32_PM.OSCCTRL1.startup = Startup;
AVR32_PM.OSCCTRL1.mode = Type;
break;
default:
return false;
}
AVR32_PM.mcctrl |= (1 << (AVR32_PM_MCCTRL_OSC0EN_OFFSET + Channel));
while (!(AVR32_PM.poscsr & (1 << (AVR32_PM_POSCSR_OSC0RDY_OFFSET + Channel))));
return true;
}
/** Stops the given external oscillator of the UC3 microcontroller.
*
* \param[in] Channel Index of the external oscillator to stop.
*/
static inline void AVR32CLK_StopExternalOscillator(const uint8_t Channel) ATTR_ALWAYS_INLINE;
static inline void AVR32CLK_StopExternalOscillator(const uint8_t Channel)
{ {
case CLOCK_SRC_OSC0: AVR32_PM.mcctrl &= ~(1 << (AVR32_PM_MCCTRL_OSC0EN_OFFSET + Channel));
AVR32_PM.PLL[Channel].pllosc = 0;
break;
case CLOCK_SRC_OSC1:
AVR32_PM.PLL[Channel].pllosc = 1;
break;
default:
return false;
} }
AVR32_PM.PLL[Channel].pllmul = (Frequency / SourceFreq) ? (((Frequency / SourceFreq) - 1) / 2) : 0; /** Starts the given PLL of the UC3 microcontroller, with the given options. This routine blocks until the PLL is ready for use.
AVR32_PM.PLL[Channel].plldiv = 0; *
AVR32_PM.PLL[Channel].pllen = true; * \param[in] Channel Index of the PLL to start.
* \param[in] Source Clock source for the PLL, a value from \ref System_ClockSource_t.
while (!(AVR32_PM.poscsr & (1 << (AVR32_PM_POSCSR_LOCK0_OFFSET + Channel)))); * \param[in] SourceFreq Frequency of the PLL's clock source, in Hz.
return true; * \param[in] Frequency Target frequency of the PLL's output.
} *
* \return Boolean \c true if the PLL was successfully started, \c false if invalid parameters specified.
static inline void AVR32CLK_StopPLL(const uint8_t Channel) */
{ static inline bool AVR32CLK_StartPLL(const uint8_t Channel,
AVR32_PM.PLL[Channel].pllen = false; const uint8_t Source,
} const uint32_t SourceFreq,
const uint32_t Frequency) ATTR_ALWAYS_INLINE;
static inline bool AVR32CLK_StartGenericClock(const uint8_t Channel, static inline bool AVR32CLK_StartPLL(const uint8_t Channel,
const uint8_t Source, const uint8_t Source,
const uint32_t SourceFreq, const uint32_t SourceFreq,
const uint32_t Frequency) const uint32_t Frequency)
{
switch (Source)
{ {
case CLOCK_SRC_OSC0: switch (Source)
AVR32_PM.GCCTRL[Channel].pllsel = 0; {
AVR32_PM.GCCTRL[Channel].oscsel = 0; case CLOCK_SRC_OSC0:
break; AVR32_PM.PLL[Channel].pllosc = 0;
case CLOCK_SRC_OSC1: break;
AVR32_PM.GCCTRL[Channel].pllsel = 0; case CLOCK_SRC_OSC1:
AVR32_PM.GCCTRL[Channel].oscsel = 1; AVR32_PM.PLL[Channel].pllosc = 1;
break; break;
case CLOCK_SRC_PLL0: default:
AVR32_PM.GCCTRL[Channel].pllsel = 1; return false;
AVR32_PM.GCCTRL[Channel].oscsel = 0; }
break;
case CLOCK_SRC_PLL1: AVR32_PM.PLL[Channel].pllmul = (Frequency / SourceFreq) ? (((Frequency / SourceFreq) - 1) / 2) : 0;
AVR32_PM.GCCTRL[Channel].pllsel = 1; AVR32_PM.PLL[Channel].plldiv = 0;
AVR32_PM.GCCTRL[Channel].oscsel = 1; AVR32_PM.PLL[Channel].pllen = true;
break;
default: while (!(AVR32_PM.poscsr & (1 << (AVR32_PM_POSCSR_LOCK0_OFFSET + Channel))));
return false; return true;
} }
AVR32_PM.GCCTRL[Channel].diven = (SourceFreq > Frequency) ? true : false; /** Stops the given PLL of the UC3 microcontroller.
AVR32_PM.GCCTRL[Channel].div = (((SourceFreq / Frequency) - 1) / 2); *
AVR32_PM.GCCTRL[Channel].cen = true; * \param[in] Channel Index of the PLL to stop.
*/
static inline void AVR32CLK_StopPLL(const uint8_t Channel) ATTR_ALWAYS_INLINE;
static inline void AVR32CLK_StopPLL(const uint8_t Channel)
{
AVR32_PM.PLL[Channel].pllen = false;
}
/** Starts the given Generic Clock of the UC3 microcontroller, with the given options.
*
* \param[in] Channel Index of the Generic Clock to start.
* \param[in] Source Clock source for the Generic Clock, a value from \ref System_ClockSource_t.
* \param[in] SourceFreq Frequency of the Generic Clock's clock source, in Hz.
* \param[in] Frequency Target frequency of the Generic Clock's output.
*
* \return Boolean \c true if the Generic Clock was successfully started, \c false if invalid parameters specified.
*/
static inline bool AVR32CLK_StartGenericClock(const uint8_t Channel,
const uint8_t Source,
const uint32_t SourceFreq,
const uint32_t Frequency) ATTR_ALWAYS_INLINE;
static inline bool AVR32CLK_StartGenericClock(const uint8_t Channel,
const uint8_t Source,
const uint32_t SourceFreq,
const uint32_t Frequency)
{
switch (Source)
{
case CLOCK_SRC_OSC0:
AVR32_PM.GCCTRL[Channel].pllsel = 0;
AVR32_PM.GCCTRL[Channel].oscsel = 0;
break;
case CLOCK_SRC_OSC1:
AVR32_PM.GCCTRL[Channel].pllsel = 0;
AVR32_PM.GCCTRL[Channel].oscsel = 1;
break;
case CLOCK_SRC_PLL0:
AVR32_PM.GCCTRL[Channel].pllsel = 1;
AVR32_PM.GCCTRL[Channel].oscsel = 0;
break;
case CLOCK_SRC_PLL1:
AVR32_PM.GCCTRL[Channel].pllsel = 1;
AVR32_PM.GCCTRL[Channel].oscsel = 1;
break;
default:
return false;
}
if (SourceFreq < Frequency)
return false;
AVR32_PM.GCCTRL[Channel].diven = (SourceFreq > Frequency) ? true : false;
AVR32_PM.GCCTRL[Channel].div = (((SourceFreq / Frequency) - 1) / 2);
AVR32_PM.GCCTRL[Channel].cen = true;
return true;
}
return true; /** Stops the given generic clock of the UC3 microcontroller.
} *
* \param[in] Channel Index of the generic clock to stop.
static inline void AVR32CLK_StopGenericClock(const uint8_t Channel) */
{ static inline void AVR32CLK_StopGenericClock(const uint8_t Channel) ATTR_ALWAYS_INLINE;
AVR32_PM.GCCTRL[Channel].cen = false; static inline void AVR32CLK_StopGenericClock(const uint8_t Channel)
}
static inline bool AVR32CLK_SetCPUClockSource(const uint8_t Source,
const uint32_t SourceFreq)
{
AVR32_FLASHC.FCR.fws = (SourceFreq > 30000000) ? true : false;
switch (Source)
{ {
case CLOCK_SRC_SLOW_CLK: AVR32_PM.GCCTRL[Channel].cen = false;
AVR32_PM.MCCTRL.mcsel = 0;
break;
case CLOCK_SRC_OSC0:
AVR32_PM.MCCTRL.mcsel = 1;
break;
case CLOCK_SRC_PLL0:
AVR32_PM.MCCTRL.mcsel = 2;
break;
default:
return false;
} }
return true; /** Sets the clock source for the main microcontroller core. The given clock source should be configured
} * and ready for use before this function is called.
*
* This function will configure the FLASH controller's wait states automatically to suit the given clock source.
*
* \param[in] Source Clock source for the CPU core, a value from \ref System_ClockSource_t.
* \param[in] SourceFreq Frequency of the CPU core's clock source, in Hz.
*
* \return Boolean \c true if the CPU core clock was sucessfully altered, \c false if invalid parameters specified.
*/
static inline bool AVR32CLK_SetCPUClockSource(const uint8_t Source,
const uint32_t SourceFreq) ATTR_ALWAYS_INLINE;
static inline bool AVR32CLK_SetCPUClockSource(const uint8_t Source,
const uint32_t SourceFreq)
{
AVR32_FLASHC.FCR.fws = (SourceFreq > 30000000) ? true : false;
switch (Source)
{
case CLOCK_SRC_SLOW_CLK:
AVR32_PM.MCCTRL.mcsel = 0;
break;
case CLOCK_SRC_OSC0:
AVR32_PM.MCCTRL.mcsel = 1;
break;
case CLOCK_SRC_PLL0:
AVR32_PM.MCCTRL.mcsel = 2;
break;
default:
return false;
}
return true;
}
/* Disable C linkage for C++ Compilers: */
#if defined(__cplusplus)
}
#endif
#endif #endif
/** @} */

6
LUFA/Platform/UC3/InterruptManagement.c
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@ -36,11 +36,11 @@ InterruptHandlerPtr_t InterruptHandlers[AVR32_INTC_NUM_INT_GRPS];
/** ISR for unhandled interrupt groups */ /** ISR for unhandled interrupt groups */
ISR(Unhandled_Interrupt) ISR(Unhandled_Interrupt)
{ {
while (true); for (;;);
} }
/** Retrieves the associated interrupt handler for the interrupt currently being fired. This is /** Retrieves the associated interrupt handler for the interrupt group currently being fired. This
* called directly from the exception handler routine before dispatching to the ISR. * is called directly from the exception handler routine before dispatching to the ISR.
*/ */
InterruptHandlerPtr_t INTC_GetInterruptHandler(const uint_reg_t InterruptLevel) InterruptHandlerPtr_t INTC_GetInterruptHandler(const uint_reg_t InterruptLevel)
{ {

168
LUFA/Platform/UC3/InterruptManagement.h
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@ -28,8 +28,47 @@
this software. this software.
*/ */
#ifndef _INTERRUPT_MANAGEMENT_H_ /** \file
#define _INTERRUPT_MANAGEMENT_H_ * \brief Interrupt Controller Driver for the AVR32 UC3 microcontrollers.
*
* Interrupt controller driver for the AVR32 UC3 microcontrollers, for the configuration of interrupt
* handlers within the device.
*/
/** \ingroup Group_PlatformDrivers
* \defgroup Group_PlatformDrivers_UC3Interrupts UC3 Interrupt Controller Driver - LUFA/Platform/UC3/InterruptManagement.h
* \brief Interrupt Controller Driver for the AVR32 UC3 microcontrollers.
*
* \section Sec_Dependencies Module Source Dependencies
* The following files must be built with any user project that uses this module:
* - LUFA/Platform/UC3/InterruptManagement.c
* - LUFA/Platform/UC3/Exception.S
*
* \section Sec_ModDescription Module Description
* Interrupt controller driver for the AVR32 UC3 microcontrollers, for the configuration of interrupt
* handlers within the device.
*
* Usage Example:
* \code
* #include <LUFA/Platform/UC3/InterruptManagement.h>
*
* ISR(USB_Group_IRQ_Handler)
* {
* // USB group handler code here
* }
*
* void main(void)
* {
* INTC_Init();
* INTC_RegisterGroupHandler(INTC_IRQ_GROUP(AVR32_USBB_IRQ), AVR32_INTC_INT0, USB_Group_IRQ_Handler);
* }
* \endcode
*
* @{
*/
#ifndef _UC3_INTERRUPT_MANAGEMENT_H_
#define _UC3_INTERRUPT_MANAGEMENT_H_
/* Includes: */ /* Includes: */
#include <avr32/io.h> #include <avr32/io.h>
@ -38,46 +77,91 @@
#include <LUFA/Common/Common.h> #include <LUFA/Common/Common.h>
/* Macros: */ /* Enable C linkage for C++ Compilers: */
#if !defined(ISR) #if defined(__cplusplus)
#define ISR(Name) void Name (void) __attribute__((__interrupt__)); void Name (void) extern "C" {
#endif
/* Private Interface - For use in library only: */
#if !defined(__DOXYGEN__)
/* External Variables: */
extern const void EVBA_Table;
extern const uint32_t Autovector_Table[];
extern InterruptHandlerPtr_t InterruptHandlers[AVR32_INTC_NUM_INT_GRPS];
#endif
/* Public Interface - May be used in end-application: */
/* Macros: */
/** Converts a given interrupt index into its assocated interrupt group.
*
* \param[in] IRQIndex Index of the interrupt request to convert.
*
* \return Interrupt group number associated with the interrupt index.
*/
#define INTC_IRQ_GROUP(IRQIndex) (IRQIndex / 32)
/** Converts a given interrupt index into its assocated interrupt line.
*
* \param[in] IRQIndex Index of the interrupt request to convert.
*
* \return Interrupt line number associated with the interrupt index.
*/
#define INTC_IRQ_LINE(IRQIndex) (IRQIndex % 32)
/* Type Defines: */
/** Type define for an interrupt handler ISR function. */
typedef void (*InterruptHandlerPtr_t)(void);
/* Function Prototypes: */
/** Initializes the interrupt controller, nulling out all interrupt handlers ready for new registration. This
* function should be called once on startup to ensure the interrupt controller is ready for use.
*/
void INTC_Init(void);
/* Inline Functions: */
/** Registers a handler for a given interrupt group. On the AVR32 UC3 devices, interrupts are grouped by
* peripheral. To save on SRAM used, a single ISR handles all interrupt lines within a single group - to
* determine the exact line that has interrupted within the group ISR handler, use \ref INTC_GetGroupInterrupts().
*
* If multiple interrupts with the same group are registered, the last registered handler will become the
* handler called for interrupts raised within that group.
*
* To obtain the group number of a specific interrupt index, use the \ref INTC_IRQ_GROUP() macro.
*
* \param[in] GroupNumber Group number of the interrupt group to register a handler for.
* \param[in] InterruptLevel Priority level for the specified interrupt, a \c AVR32_INTC_INT* mask.
* \param[in] Handler Address of the ISR handler for the interrupt group.
*/
static inline void INTC_RegisterGroupHandler(const uint16_t GroupNumber,
const uint8_t InterruptLevel,
const InterruptHandlerPtr_t Handler) ATTR_ALWAYS_INLINE;
static inline void INTC_RegisterGroupHandler(const uint16_t GroupNumber,
const uint8_t InterruptLevel,
const InterruptHandlerPtr_t Handler)
{
InterruptHandlers[GroupNumber] = Handler;
AVR32_INTC.ipr[GroupNumber] = Autovector_Table[InterruptLevel];
}
/** Retrieves the pending interrupts for a given interrupt group. The result of this function should be masked
* against interrupt request indexes converted to a request line number via the \ref INTC_IRQ_LINE() macro. To
* obtain the group number of a given interrupt request, use the \ref INTC_IRQ_GROUP() macro.
*
* \param[in] GroupNumber Group number of the interrupt group to check.
*
* \return Mask of pending interrupt lines for the given interrupt group.
*/
static inline uint_reg_t INTC_GetGroupInterrupts(const uint16_t GroupNumber) ATTR_ALWAYS_INLINE;
static inline uint_reg_t INTC_GetGroupInterrupts(const uint16_t GroupNumber)
{
return AVR32_INTC.irr[GroupNumber];
}
/* Disable C linkage for C++ Compilers: */
#if defined(__cplusplus)
}
#endif #endif
#define INTC_EnableInterrupts() do { GCC_MEMORY_BARRIER(); __builtin_csrf(AVR32_SR_GM_OFFSET); } while (0)
#define INTC_DisableInterrupts() do { __builtin_ssrf(AVR32_SR_GM_OFFSET); GCC_MEMORY_BARRIER(); } while (0)
/* Type Defines: */
typedef void (*InterruptHandlerPtr_t)(void);
/* External Variables: */
extern const void EVBA_Table;
extern const uint32_t Autovector_Table[];
extern InterruptHandlerPtr_t InterruptHandlers[AVR32_INTC_NUM_INT_GRPS];
/* Function Prototypes: */
void INTC_Init(void);
/* Inline Functions: */
/** Registers a handler for a given interrupt group. On the AVR32 UC3 devices, interrupts are grouped by
* peripheral. To save on SRAM used, a single ISR handles all interrupt lines within a single group - to
* determine the exact line that has interrupted within the group ISR handler, examine the module's interrupt
* flag register bits.
*
* If multiple interrupts with the same group are registered, the last registered handler will become the
* handler called for interrupts raised within that group.
*
* \param[in] InterruptRequest Interrupt request index for the given interrupt, a AVR32_*_IRQ mask.
* \param[in] InterruptLevel Priority level for the specified interrupt, a AVR32_INTC_INT* mask.
* \param[in] Handler Address of the ISR handler for the interrupt group.
*/
static inline void INTC_RegisterGroupHandler(const uint16_t InterruptRequest,
const uint8_t InterruptLevel,
const InterruptHandlerPtr_t Handler)
{
uint8_t InterruptGroup = (InterruptRequest >> 5);
InterruptHandlers[InterruptGroup] = Handler;
AVR32_INTC.ipr[InterruptGroup] = Autovector_Table[InterruptLevel];
}
#endif #endif
/** @} */

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