FreeRTOS/Demo/CORTEX_LM3S102_GCC/init/startup.c - nest-detect/1.2/freertos - Git at Google

 //*****************************************************************************
 //
 // startup.c - Boot code for Stellaris.
 //
 // Copyright (c) 2005,2006 Luminary Micro, Inc.  All rights reserved.
 //
 // Software License Agreement
 //
 // Luminary Micro, Inc. (LMI) is supplying this software for use solely and
 // exclusively on LMI's Stellaris Family of microcontroller products.
 //
 // The software is owned by LMI and/or its suppliers, and is protected under
 // applicable copyright laws.  All rights are reserved.  Any use in violation
 // of the foregoing restrictions may subject the user to criminal sanctions
 // under applicable laws, as well as to civil liability for the breach of the
 // terms and conditions of this license.
 //
 // THIS SOFTWARE IS PROVIDED "AS IS".  NO WARRANTIES, WHETHER EXPRESS, IMPLIED
 // OR STATUTORY, INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF
 // MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE.
 // LMI SHALL NOT, IN ANY CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR
 // CONSEQUENTIAL DAMAGES, FOR ANY REASON WHATSOEVER.
 //
 //*****************************************************************************

 //*****************************************************************************
 //
 // Forward declaration of the default fault handlers.
 //
 //*****************************************************************************
 void ResetISR(void);
 static void NmiSR(void);
 void FaultISR(void);
 extern void xPortPendSVHandler(void);
 extern void xPortSysTickHandler(void);
 extern void vUART_ISR( void );
 extern void vPortSVCHandler( void );

 //*****************************************************************************
 //
 // The entry point for the application.
 //
 //*****************************************************************************
 extern void entry(void);

 //*****************************************************************************
 //
 // Reserve space for the system stack.
 //
 //*****************************************************************************
 #ifndef STACK_SIZE
 #define STACK_SIZE                              51
 #endif
 static unsigned long pulMainStack[STACK_SIZE];

 //*****************************************************************************
 //
 // The minimal vector table for a Cortex-M3.  Note that the proper constructs
 // must be placed on this to ensure that it ends up at physical address
 // 0x0000.0000.
 //
 //*****************************************************************************
 __attribute__ ((section("vectors")))
 void (* const g_pfnVectors[])(void) =
 {
     (void (*)(void))((unsigned long)pulMainStack + sizeof(pulMainStack)),
     ResetISR,
     NmiSR,
     FaultISR,								//FAULT
     0,                                      // The MPU fault handler
     0,                                      // The bus fault handler
     0,                                      // The usage fault handler
     0,                                      // Reserved
     0,                                      // Reserved
     0,                                      // Reserved
     0,                                      // Reserved
     vPortSVCHandler,						// SVCall handler
     0,                                      // Debug monitor handler
     0,                                      // Reserved
     xPortPendSVHandler,                     // The PendSV handler
     xPortSysTickHandler,                    // The SysTick handler
     0,                      // GPIO Port A
     0,                      // GPIO Port B
     0,                      // GPIO Port C
     0,                      // GPIO Port D
     0,                      // GPIO Port E
     vUART_ISR                      // UART0 Rx and Tx
 };

 //*****************************************************************************
 //
 // The following are constructs created by the linker, indicating where the
 // the "data" and "bss" segments reside in memory.  The initializers for the
 // for the "data" segment resides immediately following the "text" segment.
 //
 //*****************************************************************************
 extern unsigned long _etext;
 extern unsigned long _data;
 extern unsigned long _edata;
 extern unsigned long _bss;
 extern unsigned long _ebss;

 //*****************************************************************************
 //
 // This is the code that gets called when the processor first starts execution
 // following a reset event.  Only the absolutely necessary set is performed,
 // after which the application supplied entry() routine is called.  Any fancy
 // actions (such as making decisions based on the reset cause register, and
 // resetting the bits in that register) are left solely in the hands of the
 // application.
 //
 //*****************************************************************************
 void
 ResetISR(void)
 {
     unsigned long *pulSrc, *pulDest;

     //
     // Copy the data segment initializers from flash to SRAM.
     //
     pulSrc = &_etext;
     for(pulDest = &_data; pulDest < &_edata; )
     {
         *pulDest++ = *pulSrc++;
     }

     //
     // Zero fill the bss segment.
     //
     for(pulDest = &_bss; pulDest < &_ebss; )
     {
         *pulDest++ = 0;
     }

     //
     // Call the application's entry point.
     //
     Main();
 }

 //*****************************************************************************
 //
 // This is the code that gets called when the processor receives a NMI.  This
 // simply enters an infinite loop, preserving the system state for examination
 // by a debugger.
 //
 //*****************************************************************************
 static void
 NmiSR(void)
 {
     //
     // Enter an infinite loop.
     //
     while(1)
     {
     }
 }

 //*****************************************************************************
 //
 // This is the code that gets called when the processor receives a fault
 // interrupt.  This simply enters an infinite loop, preserving the system state
 // for examination by a debugger.
 //
 //*****************************************************************************
 void
 FaultISR(void)
 {
     //
     // Enter an infinite loop.
     //
     while(1)
     {
     }
 }
	//*****************************************************************************
	//
	// startup.c - Boot code for Stellaris.
	//
	// Copyright (c) 2005,2006 Luminary Micro, Inc. All rights reserved.
	//
	// Software License Agreement
	//
	// Luminary Micro, Inc. (LMI) is supplying this software for use solely and
	// exclusively on LMI's Stellaris Family of microcontroller products.
	//
	// The software is owned by LMI and/or its suppliers, and is protected under
	// applicable copyright laws. All rights are reserved. Any use in violation
	// of the foregoing restrictions may subject the user to criminal sanctions
	// under applicable laws, as well as to civil liability for the breach of the
	// terms and conditions of this license.
	//
	// THIS SOFTWARE IS PROVIDED "AS IS". NO WARRANTIES, WHETHER EXPRESS, IMPLIED
	// OR STATUTORY, INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF
	// MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE.
	// LMI SHALL NOT, IN ANY CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR
	// CONSEQUENTIAL DAMAGES, FOR ANY REASON WHATSOEVER.
	//
	//*****************************************************************************

	//*****************************************************************************
	//
	// Forward declaration of the default fault handlers.
	//
	//*****************************************************************************
	void ResetISR(void);
	static void NmiSR(void);
	void FaultISR(void);
	extern void xPortPendSVHandler(void);
	extern void xPortSysTickHandler(void);
	extern void vUART_ISR( void );
	extern void vPortSVCHandler( void );

	//*****************************************************************************
	//
	// The entry point for the application.
	//
	//*****************************************************************************
	extern void entry(void);

	//*****************************************************************************
	//
	// Reserve space for the system stack.
	//
	//*****************************************************************************
	#ifndef STACK_SIZE
	#define STACK_SIZE 51
	#endif
	static unsigned long pulMainStack[STACK_SIZE];

	//*****************************************************************************
	//
	// The minimal vector table for a Cortex-M3. Note that the proper constructs
	// must be placed on this to ensure that it ends up at physical address
	// 0x0000.0000.
	//
	//*****************************************************************************
	__attribute__ ((section("vectors")))
	void (* const g_pfnVectors[])(void) =
	{
	(void (*)(void))((unsigned long)pulMainStack + sizeof(pulMainStack)),
	ResetISR,
	NmiSR,
	FaultISR, //FAULT
	0, // The MPU fault handler
	0, // The bus fault handler
	0, // The usage fault handler
	0, // Reserved
	0, // Reserved
	0, // Reserved
	0, // Reserved
	vPortSVCHandler, // SVCall handler
	0, // Debug monitor handler
	0, // Reserved
	xPortPendSVHandler, // The PendSV handler
	xPortSysTickHandler, // The SysTick handler
	0, // GPIO Port A
	0, // GPIO Port B
	0, // GPIO Port C
	0, // GPIO Port D
	0, // GPIO Port E
	vUART_ISR // UART0 Rx and Tx
	};

	//*****************************************************************************
	//
	// The following are constructs created by the linker, indicating where the
	// the "data" and "bss" segments reside in memory. The initializers for the
	// for the "data" segment resides immediately following the "text" segment.
	//
	//*****************************************************************************
	extern unsigned long _etext;
	extern unsigned long _data;
	extern unsigned long _edata;
	extern unsigned long _bss;
	extern unsigned long _ebss;

	//*****************************************************************************
	//
	// This is the code that gets called when the processor first starts execution
	// following a reset event. Only the absolutely necessary set is performed,
	// after which the application supplied entry() routine is called. Any fancy
	// actions (such as making decisions based on the reset cause register, and
	// resetting the bits in that register) are left solely in the hands of the
	// application.
	//
	//*****************************************************************************
	void
	ResetISR(void)
	{
	unsigned long pulSrc, pulDest;

	//
	// Copy the data segment initializers from flash to SRAM.
	//
	pulSrc = &_etext;
	for(pulDest = &_data; pulDest < &_edata; )
	{
	pulDest++ = pulSrc++;
	}

	//
	// Zero fill the bss segment.
	//
	for(pulDest = &_bss; pulDest < &_ebss; )
	{
	*pulDest++ = 0;
	}

	//
	// Call the application's entry point.
	//
	Main();
	}

	//*****************************************************************************
	//
	// This is the code that gets called when the processor receives a NMI. This
	// simply enters an infinite loop, preserving the system state for examination
	// by a debugger.
	//
	//*****************************************************************************
	static void
	NmiSR(void)
	{
	//
	// Enter an infinite loop.
	//
	while(1)
	{
	}
	}

	//*****************************************************************************
	//
	// This is the code that gets called when the processor receives a fault
	// interrupt. This simply enters an infinite loop, preserving the system state
	// for examination by a debugger.
	//
	//*****************************************************************************
	void
	FaultISR(void)
	{
	//
	// Enter an infinite loop.
	//
	while(1)
	{
	}
	}