versions/v1_4_0/mynewt-core/hw/mcu/ambiq/src/ext/AmbiqSuite/utils/am_util_faultisr.c - mynewt-documentation - Git at Google

 //*****************************************************************************
 //
 //! @file am_util_faultisr.c
 //!
 //! @brief An extended hard-fault handler.
 //
 // This module is intended to be completely portable with no HAL or BSP
 // dependencies.
 //
 // Further, it is intended to be compiler/platform independent enabling it to
 // run on GCC, Keil, IAR, etc.
 //
 //*****************************************************************************

 //*****************************************************************************
 //
 // Copyright (c) 2017, Ambiq Micro
 // 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. Neither the name of the copyright holder nor the names of its
 // contributors may be used to endorse or promote products derived from this
 // software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "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 DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS 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.
 //
 // This is part of revision v1.2.10-2-gea660ad-hotfix2 of the AmbiqSuite Development Package.
 //
 //*****************************************************************************

 #include <stdint.h>
 #include "am_mcu_apollo.h"

 //*****************************************************************************
 //
 // Macros
 //
 //*****************************************************************************

 //
 // Macros used by am_util_faultisr_collect_data().
 //
 #define AM_REG_SYSCTRL_CFSR_O                        0xE000ED28
 #define AM_REG_SYSCTRL_BFAR_O                        0xE000ED38
 #define AM_REGVAL(x)               (*((volatile uint32_t *)(x)))

 //*****************************************************************************
 //
 // Data structures
 //
 //*****************************************************************************

 //
 // Define a structure for local storage in am_util_faultisr_collect_data().
 // Set structure alignment to 1 byte to minimize storage requirements.
 //
 #pragma pack(1)
 typedef struct
 {
     //
     // Stacked registers
     //
     volatile uint32_t u32R0;
     volatile uint32_t u32R1;
     volatile uint32_t u32R2;
     volatile uint32_t u32R3;
     volatile uint32_t u32R12;
     volatile uint32_t u32LR;
     volatile uint32_t u32PC;
     volatile uint32_t u32PSR;

     //
     // Other data
     //
     volatile uint32_t u32FaultAddr;
     volatile uint32_t u32BFAR;
     volatile uint32_t u32CFSR;
     volatile uint8_t  u8MMSR;
     volatile uint8_t  u8BFSR;
     volatile uint16_t u16UFSR;

 } am_fault_t;

 //
 // Restore the default structure alignment
 //
 #pragma pack()

 //*****************************************************************************
 //
 // Prototypes
 //
 //*****************************************************************************
 void am_util_faultisr_collect_data(uint32_t u32IsrSP);

 //
 // Prototype for printf, if used.
 //
 extern uint32_t am_util_stdio_printf(char *pui8Fmt, ...);

 //*****************************************************************************
 //
 // am_fault_isr() replaces the weak one defined in the startup code.  This
 // simple function captures SP (which is needed by getStackedReg) then calls
 // the function that actually decodes the hard fault data,
 // am_util_faultisr_collect_data().
 //
 //*****************************************************************************
 //*****************************************************************************
 //
 // getStackedReg() will retrieve a specified register value, as it was stacked
 // by the processor after the fault, from the stack.
 //
 // The registers are stacked in the following order:
 //  R0, R1, R2, R3, R12, LR, PC, PSR.
 // To get R0 from the stack, call getStackedReg(0), r1 is getStackedReg(1)...
 //
 //*****************************************************************************
 #if defined(__GNUC_STDC_INLINE__)
 uint32_t __attribute__((naked))
 am_fault_isr(void)
 {
     __asm("    push    {r7,lr}");
     __asm("    mov     r0, sp");
     __asm("    adds    r0, #(2*4)");
     __asm("    bl      am_util_faultisr_collect_data");
     __asm("    pop     {r0,pc}");
 }

 uint32_t __attribute__((naked))
 getStackedReg(uint32_t regnum, uint32_t u32SP)
 {
     __asm("    lsls    r0, r0, #2");
     __asm("    adds    r0, r1");
     __asm("    ldr     r0, [r0]");
     __asm("    bx      lr");
 }
 #elif defined(__ARMCC_VERSION)
 __asm uint32_t
 am_fault_isr(void)
 {
     import  am_util_faultisr_collect_data

     push    {r7, lr}
     mov     r0, sp
     adds    r0, #(2*4)
     bl      am_util_faultisr_collect_data
     pop     {r0, pc}
 }

 __asm uint32_t
 getStackedReg(uint32_t regnum, uint32_t u32SP)
 {
     lsls    r0, r0, #2
     adds    r0, r0, r1
     ldr     r0, [r0]
     bx      lr
 }
 #elif defined(__IAR_SYSTEMS_ICC__)
 #pragma diag_suppress = Pe940   // Suppress IAR compiler warning about missing
                                 // return statement on a non-void function
 __stackless uint32_t
 am_fault_isr(void)
 {
     __asm("     push    {r7,lr}");
     __asm("     mov     r0, sp");
     __asm("     adds    r0, #(2*4)");
     __asm("     bl      am_util_faultisr_collect_data");
     __asm("     pop     {r0,pc}");
 }

 __stackless uint32_t
 getStackedReg(uint32_t regnum, uint32_t u32SP)
 {
     __asm("     lsls    r0, r0, #2");
     __asm("     adds    r0, r0, r1");
     __asm("     ldr     r0, [r0]");
     __asm("     bx      lr");
 }
 #pragma diag_default = Pe940    // Restore IAR compiler warning
 #endif

 //*****************************************************************************
 //
 // am_util_faultisr_collect_data(uint32_t u32IsrSP);
 //
 // This function is intended to be called by am_fault_isr(), which is called
 // when the processor receives a hard fault interrupt.  This part of the
 // handler parses through the various fault codes and saves them into a data
 // structure so they can be readily examined by the user in the debugger.
 //
 // The input u32IsrSP is expected to be the value of the stack pointer when
 // am_fault_isr() was called.
 //
 //*****************************************************************************
 void
 am_util_faultisr_collect_data(uint32_t u32IsrSP)
 {
     volatile am_fault_t sFaultData;
     am_hal_mcuctrl_fault_t sHalFaultData = {0};

     uint32_t u32Mask = 0;

     //
     // Following is a brief overview of fault information provided by the M4.
     // More details can be found in the Cortex M4 User Guide.
     //
     // CFSR (Configurable Fault Status Reg) contains MMSR, BFSR, and UFSR:
     //   7:0    MMSR (MemManage)
     //          [0] IACCVIOL    Instr fetch from a location that does not
     //                          permit execution.
     //          [1] DACCVIOL    Data access violation flag. MMAR contains
     //                          address of the attempted access.
     //          [2] Reserved
     //          [3] MUNSTKERR   MemMange fault on unstacking for a return
     //                          from exception.
     //          [4] MSTKERR     MemMange fault on stacking for exception
     //                          entry.
     //          [5] MLSPERR     MemMange fault during FP lazy state
     //                          preservation.
     //          [6] Reserved
     //          [7] MMARVALID   MemManage Fault Addr Reg (MMFAR) valid flag.
     //  15:8    BusFault
     //          [0] IBUSERR     If set, instruction bus error.
     //          [1] PRECISERR   Data bus error. Stacked PC points to instr
     //                          that caused the fault.
     //          [2] IMPRECISERR Data bus error, but stacked return addr is not
     //                          related to the instr that caused the error and
     //                          BFAR is not valid.
     //          [3] UNSTKERR    Bus fault on unstacking for a return from
     //                          exception.
     //          [4] STKERR      Bus fault on stacking for exception entry.
     //          [5] LSPERR      Bus fault during FP lazy state preservation.
     //          [6] Reserved
     //          [7] BFARVALID   BFAR valid.
     //  31:16   UFSR (UsageFault)
     //          [0] UNDEFINSTR  Undefined instruction.
     //          [1] INVSTATE    Invalid state.
     //          [2] INVPC       Invalid PC load.
     //          [3] NOCP        No coprocessor.
     //        [7:4] Reserved
     //          [8] UNALIGNED   Unaligned access.
     //          [9] DIVBYZERO   Divide by zero.
     //      [15:10] Reserved
     //

     //
     // u32Mask is used for 2 things: 1) in the print loop, 2) as a spot to set
     // a breakpoint at the end of the routine.  If the printing is not used,
     // we'll get a compiler warning; so to avoid that warning, we'll use it
     // in a dummy assignment here.
     //
     sFaultData.u32CFSR = u32Mask;       // Avoid compiler warning
     sFaultData.u32CFSR = AM_REGVAL(AM_REG_SYSCTRL_CFSR_O);
     sFaultData.u8MMSR  = (sFaultData.u32CFSR >> 0)  & 0xff;
     sFaultData.u8BFSR  = (sFaultData.u32CFSR >> 8)  & 0xff;
     sFaultData.u16UFSR = (sFaultData.u32CFSR >> 16) & 0xffff;

     //
     // The address of the location that caused the fault.  e.g. if accessing an
     // invalid data location caused the fault, that address will appear here.
     //
     sFaultData.u32BFAR = AM_REGVAL(AM_REG_SYSCTRL_BFAR_O);

     //
     // The address of the instruction that caused the fault is the stacked PC
     // if BFSR bit1 is set.
     //
     sFaultData.u32FaultAddr = (sFaultData.u8BFSR & 0x02) ? getStackedReg(6, u32IsrSP) : 0xffffffff;

     //
     // Get the stacked registers.
     // Note - the address of the instruction that caused the fault is u32PC.
     //
     sFaultData.u32R0  = getStackedReg(0, u32IsrSP);
     sFaultData.u32R1  = getStackedReg(1, u32IsrSP);
     sFaultData.u32R2  = getStackedReg(2, u32IsrSP);
     sFaultData.u32R3  = getStackedReg(3, u32IsrSP);
     sFaultData.u32R12 = getStackedReg(4, u32IsrSP);
     sFaultData.u32LR  = getStackedReg(5, u32IsrSP);
     sFaultData.u32PC  = getStackedReg(6, u32IsrSP);
     sFaultData.u32PSR = getStackedReg(7, u32IsrSP);

     //
     // Use the HAL MCUCTRL functions to read the fault data.
     //
     am_hal_mcuctrl_fault_status(&sHalFaultData);


 #ifdef AM_UTIL_FAULTISR_PRINT
     //
     // If printf has previously been initialized in the application, we should
     // be able to print out the fault information.
     //
     am_util_stdio_printf("Hard Fault stacked data:\n");
     am_util_stdio_printf("    R0  = 0x%08X\n", sFaultData.u32R0);
     am_util_stdio_printf("    R1  = 0x%08X\n", sFaultData.u32R1);
     am_util_stdio_printf("    R2  = 0x%08X\n", sFaultData.u32R2);
     am_util_stdio_printf("    R3  = 0x%08X\n", sFaultData.u32R3);
     am_util_stdio_printf("    R12 = 0x%08X\n", sFaultData.u32R12);
     am_util_stdio_printf("    LR  = 0x%08X\n", sFaultData.u32LR);
     am_util_stdio_printf("    PC  = 0x%08X\n", sFaultData.u32PC);
     am_util_stdio_printf("    PSR = 0x%08X\n", sFaultData.u32PSR);
     am_util_stdio_printf("Other Hard Fault data:\n");
     am_util_stdio_printf("    Fault address = 0x%08X\n", sFaultData.u32FaultAddr);
     am_util_stdio_printf("    BFAR (Bus Fault Addr Reg) = 0x%08X\n", sFaultData.u32BFAR);
     am_util_stdio_printf("    MMSR (Mem Mgmt Fault Status Reg) = 0x%02X\n", sFaultData.u8MMSR);
     am_util_stdio_printf("    BFSR (Bus Fault Status Reg) = 0x%02X\n", sFaultData.u8BFSR);
     am_util_stdio_printf("    UFSR (Usage Fault Status Reg) = 0x%04X\n", sFaultData.u16UFSR);

     //
     // Print out any bits set in the BFSR.
     //
     u32Mask = 0x80;
     while (u32Mask)
     {
         switch (sFaultData.u8BFSR & u32Mask)
         {
             case 0x80:
                 am_util_stdio_printf("        BFSR bit7: BFARVALID\n");
                 break;
             case 0x40:
                 am_util_stdio_printf("        BFSR bit6: RESERVED\n");
                 break;
             case 0x20:
                 am_util_stdio_printf("        BFSR bit5: LSPERR\n");
                 break;
             case 0x10:
                 am_util_stdio_printf("        BFSR bit4: STKERR\n");
                 break;
             case 0x08:
                 am_util_stdio_printf("        BFSR bit3: UNSTKERR\n");
                 break;
             case 0x04:
                 am_util_stdio_printf("        BFSR bit2: IMPRECISERR\n");
                 break;
             case 0x02:
                 am_util_stdio_printf("        BFSR bit1: PRECISEERR\n");
                 break;
             case 0x01:
                 am_util_stdio_printf("        BFSR bit0: IBUSERR\n");
                 break;
             default:
                 break;
         }
         u32Mask >>= 1;
     }

     //
     // Print out any Apollo2 Internal fault information.
     //
     am_util_stdio_printf("Apollo2 Fault data:\n");
     if (sHalFaultData.bICODE)
     {
       am_util_stdio_printf("   ICODE Fault Address: 0x%08X\n", sHalFaultData.ui32ICODE);
     }
     if (sHalFaultData.bDCODE)
     {
       am_util_stdio_printf("   DCODE Fault Address: 0x%08X\n", sHalFaultData.ui32DCODE);
     }
     if (sHalFaultData.bSYS)
     {
       am_util_stdio_printf("   SYS Fault Address: 0x%08X\n", sHalFaultData.ui32SYS);
     }


 #endif

     u32Mask = 0;

     //
     // Spin in an infinite loop.
     // We need to spin here inside the function so that we have access to
     // local data, i.e. sFaultData.
     //
     while(1)
     {
     }
 }
	//*****************************************************************************
	//
	//! @file am_util_faultisr.c
	//!
	//! @brief An extended hard-fault handler.
	//
	// This module is intended to be completely portable with no HAL or BSP
	// dependencies.
	//
	// Further, it is intended to be compiler/platform independent enabling it to
	// run on GCC, Keil, IAR, etc.
	//
	//*****************************************************************************

	//*****************************************************************************
	//
	// Copyright (c) 2017, Ambiq Micro
	// 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. Neither the name of the copyright holder nor the names of its
	// contributors may be used to endorse or promote products derived from this
	// software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "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 DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS 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.
	//
	// This is part of revision v1.2.10-2-gea660ad-hotfix2 of the AmbiqSuite Development Package.
	//
	//*****************************************************************************

	#include <stdint.h>
	#include "am_mcu_apollo.h"

	//*****************************************************************************
	//
	// Macros
	//
	//*****************************************************************************

	//
	// Macros used by am_util_faultisr_collect_data().
	//
	#define AM_REG_SYSCTRL_CFSR_O 0xE000ED28
	#define AM_REG_SYSCTRL_BFAR_O 0xE000ED38
	#define AM_REGVAL(x) (((volatile uint32_t )(x)))

	//*****************************************************************************
	//
	// Data structures
	//
	//*****************************************************************************

	//
	// Define a structure for local storage in am_util_faultisr_collect_data().
	// Set structure alignment to 1 byte to minimize storage requirements.
	//
	#pragma pack(1)
	typedef struct
	{
	//
	// Stacked registers
	//
	volatile uint32_t u32R0;
	volatile uint32_t u32R1;
	volatile uint32_t u32R2;
	volatile uint32_t u32R3;
	volatile uint32_t u32R12;
	volatile uint32_t u32LR;
	volatile uint32_t u32PC;
	volatile uint32_t u32PSR;

	//
	// Other data
	//
	volatile uint32_t u32FaultAddr;
	volatile uint32_t u32BFAR;
	volatile uint32_t u32CFSR;
	volatile uint8_t u8MMSR;
	volatile uint8_t u8BFSR;
	volatile uint16_t u16UFSR;

	} am_fault_t;

	//
	// Restore the default structure alignment
	//
	#pragma pack()

	//*****************************************************************************
	//
	// Prototypes
	//
	//*****************************************************************************
	void am_util_faultisr_collect_data(uint32_t u32IsrSP);

	//
	// Prototype for printf, if used.
	//
	extern uint32_t am_util_stdio_printf(char *pui8Fmt, ...);

	//*****************************************************************************
	//
	// am_fault_isr() replaces the weak one defined in the startup code. This
	// simple function captures SP (which is needed by getStackedReg) then calls
	// the function that actually decodes the hard fault data,
	// am_util_faultisr_collect_data().
	//
	//*****************************************************************************
	//*****************************************************************************
	//
	// getStackedReg() will retrieve a specified register value, as it was stacked
	// by the processor after the fault, from the stack.
	//
	// The registers are stacked in the following order:
	// R0, R1, R2, R3, R12, LR, PC, PSR.
	// To get R0 from the stack, call getStackedReg(0), r1 is getStackedReg(1)...
	//
	//*****************************************************************************
	#if defined(__GNUC_STDC_INLINE__)
	uint32_t __attribute__((naked))
	am_fault_isr(void)
	{
	__asm(" push {r7,lr}");
	__asm(" mov r0, sp");
	__asm(" adds r0, #(2*4)");
	__asm(" bl am_util_faultisr_collect_data");
	__asm(" pop {r0,pc}");
	}

	uint32_t __attribute__((naked))
	getStackedReg(uint32_t regnum, uint32_t u32SP)
	{
	__asm(" lsls r0, r0, #2");
	__asm(" adds r0, r1");
	__asm(" ldr r0, [r0]");
	__asm(" bx lr");
	}
	#elif defined(__ARMCC_VERSION)
	__asm uint32_t
	am_fault_isr(void)
	{
	import am_util_faultisr_collect_data

	push {r7, lr}
	mov r0, sp
	adds r0, #(2*4)
	bl am_util_faultisr_collect_data
	pop {r0, pc}
	}

	__asm uint32_t
	getStackedReg(uint32_t regnum, uint32_t u32SP)
	{
	lsls r0, r0, #2
	adds r0, r0, r1
	ldr r0, [r0]
	bx lr
	}
	#elif defined(__IAR_SYSTEMS_ICC__)
	#pragma diag_suppress = Pe940 // Suppress IAR compiler warning about missing
	// return statement on a non-void function
	__stackless uint32_t
	am_fault_isr(void)
	{
	__asm(" push {r7,lr}");
	__asm(" mov r0, sp");
	__asm(" adds r0, #(2*4)");
	__asm(" bl am_util_faultisr_collect_data");
	__asm(" pop {r0,pc}");
	}

	__stackless uint32_t
	getStackedReg(uint32_t regnum, uint32_t u32SP)
	{
	__asm(" lsls r0, r0, #2");
	__asm(" adds r0, r0, r1");
	__asm(" ldr r0, [r0]");
	__asm(" bx lr");
	}
	#pragma diag_default = Pe940 // Restore IAR compiler warning
	#endif

	//*****************************************************************************
	//
	// am_util_faultisr_collect_data(uint32_t u32IsrSP);
	//
	// This function is intended to be called by am_fault_isr(), which is called
	// when the processor receives a hard fault interrupt. This part of the
	// handler parses through the various fault codes and saves them into a data
	// structure so they can be readily examined by the user in the debugger.
	//
	// The input u32IsrSP is expected to be the value of the stack pointer when
	// am_fault_isr() was called.
	//
	//*****************************************************************************
	void
	am_util_faultisr_collect_data(uint32_t u32IsrSP)
	{
	volatile am_fault_t sFaultData;
	am_hal_mcuctrl_fault_t sHalFaultData = {0};

	uint32_t u32Mask = 0;

	//
	// Following is a brief overview of fault information provided by the M4.
	// More details can be found in the Cortex M4 User Guide.
	//
	// CFSR (Configurable Fault Status Reg) contains MMSR, BFSR, and UFSR:
	// 7:0 MMSR (MemManage)
	// [0] IACCVIOL Instr fetch from a location that does not
	// permit execution.
	// [1] DACCVIOL Data access violation flag. MMAR contains
	// address of the attempted access.
	// [2] Reserved
	// [3] MUNSTKERR MemMange fault on unstacking for a return
	// from exception.
	// [4] MSTKERR MemMange fault on stacking for exception
	// entry.
	// [5] MLSPERR MemMange fault during FP lazy state
	// preservation.
	// [6] Reserved
	// [7] MMARVALID MemManage Fault Addr Reg (MMFAR) valid flag.
	// 15:8 BusFault
	// [0] IBUSERR If set, instruction bus error.
	// [1] PRECISERR Data bus error. Stacked PC points to instr
	// that caused the fault.
	// [2] IMPRECISERR Data bus error, but stacked return addr is not
	// related to the instr that caused the error and
	// BFAR is not valid.
	// [3] UNSTKERR Bus fault on unstacking for a return from
	// exception.
	// [4] STKERR Bus fault on stacking for exception entry.
	// [5] LSPERR Bus fault during FP lazy state preservation.
	// [6] Reserved
	// [7] BFARVALID BFAR valid.
	// 31:16 UFSR (UsageFault)
	// [0] UNDEFINSTR Undefined instruction.
	// [1] INVSTATE Invalid state.
	// [2] INVPC Invalid PC load.
	// [3] NOCP No coprocessor.
	// [7:4] Reserved
	// [8] UNALIGNED Unaligned access.
	// [9] DIVBYZERO Divide by zero.
	// [15:10] Reserved
	//

	//
	// u32Mask is used for 2 things: 1) in the print loop, 2) as a spot to set
	// a breakpoint at the end of the routine. If the printing is not used,
	// we'll get a compiler warning; so to avoid that warning, we'll use it
	// in a dummy assignment here.
	//
	sFaultData.u32CFSR = u32Mask; // Avoid compiler warning
	sFaultData.u32CFSR = AM_REGVAL(AM_REG_SYSCTRL_CFSR_O);
	sFaultData.u8MMSR = (sFaultData.u32CFSR >> 0) & 0xff;
	sFaultData.u8BFSR = (sFaultData.u32CFSR >> 8) & 0xff;
	sFaultData.u16UFSR = (sFaultData.u32CFSR >> 16) & 0xffff;

	//
	// The address of the location that caused the fault. e.g. if accessing an
	// invalid data location caused the fault, that address will appear here.
	//
	sFaultData.u32BFAR = AM_REGVAL(AM_REG_SYSCTRL_BFAR_O);

	//
	// The address of the instruction that caused the fault is the stacked PC
	// if BFSR bit1 is set.
	//
	sFaultData.u32FaultAddr = (sFaultData.u8BFSR & 0x02) ? getStackedReg(6, u32IsrSP) : 0xffffffff;

	//
	// Get the stacked registers.
	// Note - the address of the instruction that caused the fault is u32PC.
	//
	sFaultData.u32R0 = getStackedReg(0, u32IsrSP);
	sFaultData.u32R1 = getStackedReg(1, u32IsrSP);
	sFaultData.u32R2 = getStackedReg(2, u32IsrSP);
	sFaultData.u32R3 = getStackedReg(3, u32IsrSP);
	sFaultData.u32R12 = getStackedReg(4, u32IsrSP);
	sFaultData.u32LR = getStackedReg(5, u32IsrSP);
	sFaultData.u32PC = getStackedReg(6, u32IsrSP);
	sFaultData.u32PSR = getStackedReg(7, u32IsrSP);

	//
	// Use the HAL MCUCTRL functions to read the fault data.
	//
	am_hal_mcuctrl_fault_status(&sHalFaultData);


	#ifdef AM_UTIL_FAULTISR_PRINT
	//
	// If printf has previously been initialized in the application, we should
	// be able to print out the fault information.
	//
	am_util_stdio_printf("Hard Fault stacked data:\n");
	am_util_stdio_printf(" R0 = 0x%08X\n", sFaultData.u32R0);
	am_util_stdio_printf(" R1 = 0x%08X\n", sFaultData.u32R1);
	am_util_stdio_printf(" R2 = 0x%08X\n", sFaultData.u32R2);
	am_util_stdio_printf(" R3 = 0x%08X\n", sFaultData.u32R3);
	am_util_stdio_printf(" R12 = 0x%08X\n", sFaultData.u32R12);
	am_util_stdio_printf(" LR = 0x%08X\n", sFaultData.u32LR);
	am_util_stdio_printf(" PC = 0x%08X\n", sFaultData.u32PC);
	am_util_stdio_printf(" PSR = 0x%08X\n", sFaultData.u32PSR);
	am_util_stdio_printf("Other Hard Fault data:\n");
	am_util_stdio_printf(" Fault address = 0x%08X\n", sFaultData.u32FaultAddr);
	am_util_stdio_printf(" BFAR (Bus Fault Addr Reg) = 0x%08X\n", sFaultData.u32BFAR);
	am_util_stdio_printf(" MMSR (Mem Mgmt Fault Status Reg) = 0x%02X\n", sFaultData.u8MMSR);
	am_util_stdio_printf(" BFSR (Bus Fault Status Reg) = 0x%02X\n", sFaultData.u8BFSR);
	am_util_stdio_printf(" UFSR (Usage Fault Status Reg) = 0x%04X\n", sFaultData.u16UFSR);

	//
	// Print out any bits set in the BFSR.
	//
	u32Mask = 0x80;
	while (u32Mask)
	{
	switch (sFaultData.u8BFSR & u32Mask)
	{
	case 0x80:
	am_util_stdio_printf(" BFSR bit7: BFARVALID\n");
	break;
	case 0x40:
	am_util_stdio_printf(" BFSR bit6: RESERVED\n");
	break;
	case 0x20:
	am_util_stdio_printf(" BFSR bit5: LSPERR\n");
	break;
	case 0x10:
	am_util_stdio_printf(" BFSR bit4: STKERR\n");
	break;
	case 0x08:
	am_util_stdio_printf(" BFSR bit3: UNSTKERR\n");
	break;
	case 0x04:
	am_util_stdio_printf(" BFSR bit2: IMPRECISERR\n");
	break;
	case 0x02:
	am_util_stdio_printf(" BFSR bit1: PRECISEERR\n");
	break;
	case 0x01:
	am_util_stdio_printf(" BFSR bit0: IBUSERR\n");
	break;
	default:
	break;
	}
	u32Mask >>= 1;
	}

	//
	// Print out any Apollo2 Internal fault information.
	//
	am_util_stdio_printf("Apollo2 Fault data:\n");
	if (sHalFaultData.bICODE)
	{
	am_util_stdio_printf(" ICODE Fault Address: 0x%08X\n", sHalFaultData.ui32ICODE);
	}
	if (sHalFaultData.bDCODE)
	{
	am_util_stdio_printf(" DCODE Fault Address: 0x%08X\n", sHalFaultData.ui32DCODE);
	}
	if (sHalFaultData.bSYS)
	{
	am_util_stdio_printf(" SYS Fault Address: 0x%08X\n", sHalFaultData.ui32SYS);
	}


	#endif

	u32Mask = 0;

	//
	// Spin in an infinite loop.
	// We need to spin here inside the function so that we have access to
	// local data, i.e. sFaultData.
	//
	while(1)
	{
	}
	}