error: #5: cannot open source input file “core_cmInstr.h“

GD32F103VET6和STM32F103VET6引脚兼容。

GD32F103VET6工程模板需要包含头文件:core_cmInstr.h和core_cmFunc.h,这个和STM32F103还是有区别的,否则会报错,如下:

error: #5: cannot open source input file "core_cmInstr.h": No such file or directory

贴出来,以便大家去下载,还要积分,找得还辛苦。

/**************************************************************************//**
 * @file     core_cmFunc.h
 * @brief    CMSIS Cortex-M Core Function Access Header File
 * @version  V3.02
 * @date     24. May 2012
 *
 * @note
 * Copyright (C) 2009-2012 ARM Limited. All rights reserved.
 *
 * @par
 * ARM Limited (ARM) is supplying this software for use with Cortex-M
 * processor based microcontrollers.  This file can be freely distributed
 * within development tools that are supporting such ARM based processors.
 *
 * @par
 * 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.
 * ARM SHALL NOT, IN ANY CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR
 * CONSEQUENTIAL DAMAGES, FOR ANY REASON WHATSOEVER.
 *
 ******************************************************************************/

#ifndef __CORE_CMFUNC_H
#define __CORE_CMFUNC_H


/* ###########################  Core Function Access  ########################### */
/** \ingroup  CMSIS_Core_FunctionInterface
    \defgroup CMSIS_Core_RegAccFunctions CMSIS Core Register Access Functions
  @{
 */

#if   defined ( __CC_ARM ) /*------------------RealView Compiler -----------------*/
/* ARM armcc specific functions */

#if (__ARMCC_VERSION < 400677)
  #error "Please use ARM Compiler Toolchain V4.0.677 or later!"
#endif

/* intrinsic void __enable_irq();     */
/* intrinsic void __disable_irq();    */

/** \brief  Get Control Register

    This function returns the content of the Control Register.

    \return               Control Register value
 */
__STATIC_INLINE uint32_t __get_CONTROL(void)
{
  register uint32_t __regControl         __ASM("control");
  return(__regControl);
}


/** \brief  Set Control Register

    This function writes the given value to the Control Register.

    \param [in]    control  Control Register value to set
 */
__STATIC_INLINE void __set_CONTROL(uint32_t control)
{
  register uint32_t __regControl         __ASM("control");
  __regControl = control;
}


/** \brief  Get IPSR Register

    This function returns the content of the IPSR Register.

    \return               IPSR Register value
 */
__STATIC_INLINE uint32_t __get_IPSR(void)
{
  register uint32_t __regIPSR          __ASM("ipsr");
  return(__regIPSR);
}


/** \brief  Get APSR Register

    This function returns the content of the APSR Register.

    \return               APSR Register value
 */
__STATIC_INLINE uint32_t __get_APSR(void)
{
  register uint32_t __regAPSR          __ASM("apsr");
  return(__regAPSR);
}


/** \brief  Get xPSR Register

    This function returns the content of the xPSR Register.

    \return               xPSR Register value
 */
__STATIC_INLINE uint32_t __get_xPSR(void)
{
  register uint32_t __regXPSR          __ASM("xpsr");
  return(__regXPSR);
}


/** \brief  Get Process Stack Pointer

    This function returns the current value of the Process Stack Pointer (PSP).

    \return               PSP Register value
 */
__STATIC_INLINE uint32_t __get_PSP(void)
{
  register uint32_t __regProcessStackPointer  __ASM("psp");
  return(__regProcessStackPointer);
}


/** \brief  Set Process Stack Pointer

    This function assigns the given value to the Process Stack Pointer (PSP).

    \param [in]    topOfProcStack  Process Stack Pointer value to set
 */
__STATIC_INLINE void __set_PSP(uint32_t topOfProcStack)
{
  register uint32_t __regProcessStackPointer  __ASM("psp");
  __regProcessStackPointer = topOfProcStack;
}


/** \brief  Get Main Stack Pointer

    This function returns the current value of the Main Stack Pointer (MSP).

    \return               MSP Register value
 */
__STATIC_INLINE uint32_t __get_MSP(void)
{
  register uint32_t __regMainStackPointer     __ASM("msp");
  return(__regMainStackPointer);
}


/** \brief  Set Main Stack Pointer

    This function assigns the given value to the Main Stack Pointer (MSP).

    \param [in]    topOfMainStack  Main Stack Pointer value to set
 */
__STATIC_INLINE void __set_MSP(uint32_t topOfMainStack)
{
  register uint32_t __regMainStackPointer     __ASM("msp");
  __regMainStackPointer = topOfMainStack;
}


/** \brief  Get Priority Mask

    This function returns the current state of the priority mask bit from the Priority Mask Register.

    \return               Priority Mask value
 */
__STATIC_INLINE uint32_t __get_PRIMASK(void)
{
  register uint32_t __regPriMask         __ASM("primask");
  return(__regPriMask);
}


/** \brief  Set Priority Mask

    This function assigns the given value to the Priority Mask Register.

    \param [in]    priMask  Priority Mask
 */
__STATIC_INLINE void __set_PRIMASK(uint32_t priMask)
{
  register uint32_t __regPriMask         __ASM("primask");
  __regPriMask = (priMask);
}


#if       (__CORTEX_M >= 0x03)

/** \brief  Enable FIQ

    This function enables FIQ interrupts by clearing the F-bit in the CPSR.
    Can only be executed in Privileged modes.
 */
#define __enable_fault_irq                __enable_fiq


/** \brief  Disable FIQ

    This function disables FIQ interrupts by setting the F-bit in the CPSR.
    Can only be executed in Privileged modes.
 */
#define __disable_fault_irq               __disable_fiq


/** \brief  Get Base Priority

    This function returns the current value of the Base Priority register.

    \return               Base Priority register value
 */
__STATIC_INLINE uint32_t  __get_BASEPRI(void)
{
  register uint32_t __regBasePri         __ASM("basepri");
  return(__regBasePri);
}


/** \brief  Set Base Priority

    This function assigns the given value to the Base Priority register.

    \param [in]    basePri  Base Priority value to set
 */
__STATIC_INLINE void __set_BASEPRI(uint32_t basePri)
{
  register uint32_t __regBasePri         __ASM("basepri");
  __regBasePri = (basePri & 0xff);
}


/** \brief  Get Fault Mask

    This function returns the current value of the Fault Mask register.

    \return               Fault Mask register value
 */
__STATIC_INLINE uint32_t __get_FAULTMASK(void)
{
  register uint32_t __regFaultMask       __ASM("faultmask");
  return(__regFaultMask);
}


/** \brief  Set Fault Mask

    This function assigns the given value to the Fault Mask register.

    \param [in]    faultMask  Fault Mask value to set
 */
__STATIC_INLINE void __set_FAULTMASK(uint32_t faultMask)
{
  register uint32_t __regFaultMask       __ASM("faultmask");
  __regFaultMask = (faultMask & (uint32_t)1);
}

#endif /* (__CORTEX_M >= 0x03) */


#if       (__CORTEX_M == 0x04)

/** \brief  Get FPSCR

    This function returns the current value of the Floating Point Status/Control register.

    \return               Floating Point Status/Control register value
 */
__STATIC_INLINE uint32_t __get_FPSCR(void)
{
#if (__FPU_PRESENT == 1) && (__FPU_USED == 1)
  register uint32_t __regfpscr         __ASM("fpscr");
  return(__regfpscr);
#else
   return(0);
#endif
}


/** \brief  Set FPSCR

    This function assigns the given value to the Floating Point Status/Control register.

    \param [in]    fpscr  Floating Point Status/Control value to set
 */
__STATIC_INLINE void __set_FPSCR(uint32_t fpscr)
{
#if (__FPU_PRESENT == 1) && (__FPU_USED == 1)
  register uint32_t __regfpscr         __ASM("fpscr");
  __regfpscr = (fpscr);
#endif
}

#endif /* (__CORTEX_M == 0x04) */


#elif defined ( __ICCARM__ ) /*------------------ ICC Compiler -------------------*/
/* IAR iccarm specific functions */

#include <cmsis_iar.h>


#elif defined ( __TMS470__ ) /*---------------- TI CCS Compiler ------------------*/
/* TI CCS specific functions */

#include <cmsis_ccs.h>


#elif defined ( __GNUC__ ) /*------------------ GNU Compiler ---------------------*/
/* GNU gcc specific functions */

/** \brief  Enable IRQ Interrupts

  This function enables IRQ interrupts by clearing the I-bit in the CPSR.
  Can only be executed in Privileged modes.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __enable_irq(void)
{
  __ASM volatile ("cpsie i" : : : "memory");
}


/** \brief  Disable IRQ Interrupts

  This function disables IRQ interrupts by setting the I-bit in the CPSR.
  Can only be executed in Privileged modes.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __disable_irq(void)
{
  __ASM volatile ("cpsid i" : : : "memory");
}


/** \brief  Get Control Register

    This function returns the content of the Control Register.

    \return               Control Register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_CONTROL(void)
{
  uint32_t result;

  __ASM volatile ("MRS %0, control" : "=r" (result) );
  return(result);
}


/** \brief  Set Control Register

    This function writes the given value to the Control Register.

    \param [in]    control  Control Register value to set
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __set_CONTROL(uint32_t control)
{
  __ASM volatile ("MSR control, %0" : : "r" (control) );
}


/** \brief  Get IPSR Register

    This function returns the content of the IPSR Register.

    \return               IPSR Register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_IPSR(void)
{
  uint32_t result;

  __ASM volatile ("MRS %0, ipsr" : "=r" (result) );
  return(result);
}


/** \brief  Get APSR Register

    This function returns the content of the APSR Register.

    \return               APSR Register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_APSR(void)
{
  uint32_t result;

  __ASM volatile ("MRS %0, apsr" : "=r" (result) );
  return(result);
}


/** \brief  Get xPSR Register

    This function returns the content of the xPSR Register.

    \return               xPSR Register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_xPSR(void)
{
  uint32_t result;

  __ASM volatile ("MRS %0, xpsr" : "=r" (result) );
  return(result);
}


/** \brief  Get Process Stack Pointer

    This function returns the current value of the Process Stack Pointer (PSP).

    \return               PSP Register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_PSP(void)
{
  register uint32_t result;

  __ASM volatile ("MRS %0, psp\n"  : "=r" (result) );
  return(result);
}


/** \brief  Set Process Stack Pointer

    This function assigns the given value to the Process Stack Pointer (PSP).

    \param [in]    topOfProcStack  Process Stack Pointer value to set
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __set_PSP(uint32_t topOfProcStack)
{
  __ASM volatile ("MSR psp, %0\n" : : "r" (topOfProcStack) );
}


/** \brief  Get Main Stack Pointer

    This function returns the current value of the Main Stack Pointer (MSP).

    \return               MSP Register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_MSP(void)
{
  register uint32_t result;

  __ASM volatile ("MRS %0, msp\n" : "=r" (result) );
  return(result);
}


/** \brief  Set Main Stack Pointer

    This function assigns the given value to the Main Stack Pointer (MSP).

    \param [in]    topOfMainStack  Main Stack Pointer value to set
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __set_MSP(uint32_t topOfMainStack)
{
  __ASM volatile ("MSR msp, %0\n" : : "r" (topOfMainStack) );
}


/** \brief  Get Priority Mask

    This function returns the current state of the priority mask bit from the Priority Mask Register.

    \return               Priority Mask value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_PRIMASK(void)
{
  uint32_t result;

  __ASM volatile ("MRS %0, primask" : "=r" (result) );
  return(result);
}


/** \brief  Set Priority Mask

    This function assigns the given value to the Priority Mask Register.

    \param [in]    priMask  Priority Mask
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __set_PRIMASK(uint32_t priMask)
{
  __ASM volatile ("MSR primask, %0" : : "r" (priMask) );
}


#if       (__CORTEX_M >= 0x03)

/** \brief  Enable FIQ

    This function enables FIQ interrupts by clearing the F-bit in the CPSR.
    Can only be executed in Privileged modes.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __enable_fault_irq(void)
{
  __ASM volatile ("cpsie f" : : : "memory");
}


/** \brief  Disable FIQ

    This function disables FIQ interrupts by setting the F-bit in the CPSR.
    Can only be executed in Privileged modes.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __disable_fault_irq(void)
{
  __ASM volatile ("cpsid f" : : : "memory");
}


/** \brief  Get Base Priority

    This function returns the current value of the Base Priority register.

    \return               Base Priority register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_BASEPRI(void)
{
  uint32_t result;

  __ASM volatile ("MRS %0, basepri_max" : "=r" (result) );
  return(result);
}


/** \brief  Set Base Priority

    This function assigns the given value to the Base Priority register.

    \param [in]    basePri  Base Priority value to set
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __set_BASEPRI(uint32_t value)
{
  __ASM volatile ("MSR basepri, %0" : : "r" (value) );
}


/** \brief  Get Fault Mask

    This function returns the current value of the Fault Mask register.

    \return               Fault Mask register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_FAULTMASK(void)
{
  uint32_t result;

  __ASM volatile ("MRS %0, faultmask" : "=r" (result) );
  return(result);
}


/** \brief  Set Fault Mask

    This function assigns the given value to the Fault Mask register.

    \param [in]    faultMask  Fault Mask value to set
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __set_FAULTMASK(uint32_t faultMask)
{
  __ASM volatile ("MSR faultmask, %0" : : "r" (faultMask) );
}

#endif /* (__CORTEX_M >= 0x03) */


#if       (__CORTEX_M == 0x04)

/** \brief  Get FPSCR

    This function returns the current value of the Floating Point Status/Control register.

    \return               Floating Point Status/Control register value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __get_FPSCR(void)
{
#if (__FPU_PRESENT == 1) && (__FPU_USED == 1)
  uint32_t result;

  __ASM volatile ("VMRS %0, fpscr" : "=r" (result) );
  return(result);
#else
   return(0);
#endif
}


/** \brief  Set FPSCR

    This function assigns the given value to the Floating Point Status/Control register.

    \param [in]    fpscr  Floating Point Status/Control value to set
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __set_FPSCR(uint32_t fpscr)
{
#if (__FPU_PRESENT == 1) && (__FPU_USED == 1)
  __ASM volatile ("VMSR fpscr, %0" : : "r" (fpscr) );
#endif
}

#endif /* (__CORTEX_M == 0x04) */


#elif defined ( __TASKING__ ) /*------------------ TASKING Compiler --------------*/
/* TASKING carm specific functions */

/*
 * The CMSIS functions have been implemented as intrinsics in the compiler.
 * Please use "carm -?i" to get an up to date list of all instrinsics,
 * Including the CMSIS ones.
 */

#endif

/*@} end of CMSIS_Core_RegAccFunctions */


#endif /* __CORE_CMFUNC_H */

/**************************************************************************//**
 * @file     core_cmInstr.h
 * @brief    CMSIS Cortex-M Core Instruction Access Header File
 * @version  V3.02
 * @date     08. May 2012
 *
 * @note
 * Copyright (C) 2009-2012 ARM Limited. All rights reserved.
 *
 * @par
 * ARM Limited (ARM) is supplying this software for use with Cortex-M
 * processor based microcontrollers.  This file can be freely distributed
 * within development tools that are supporting such ARM based processors.
 *
 * @par
 * 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.
 * ARM SHALL NOT, IN ANY CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR
 * CONSEQUENTIAL DAMAGES, FOR ANY REASON WHATSOEVER.
 *
 ******************************************************************************/

#ifndef __CORE_CMINSTR_H
#define __CORE_CMINSTR_H


/* ##########################  Core Instruction Access  ######################### */
/** \defgroup CMSIS_Core_InstructionInterface CMSIS Core Instruction Interface
  Access to dedicated instructions
  @{
*/

#if   defined ( __CC_ARM ) /*------------------RealView Compiler -----------------*/
/* ARM armcc specific functions */

#if (__ARMCC_VERSION < 400677)
  #error "Please use ARM Compiler Toolchain V4.0.677 or later!"
#endif


/** \brief  No Operation

    No Operation does nothing. This instruction can be used for code alignment purposes.
 */
#define __NOP                             __nop


/** \brief  Wait For Interrupt

    Wait For Interrupt is a hint instruction that suspends execution
    until one of a number of events occurs.
 */
#define __WFI                             __wfi


/** \brief  Wait For Event

    Wait For Event is a hint instruction that permits the processor to enter
    a low-power state until one of a number of events occurs.
 */
#define __WFE                             __wfe


/** \brief  Send Event

    Send Event is a hint instruction. It causes an event to be signaled to the CPU.
 */
#define __SEV                             __sev


/** \brief  Instruction Synchronization Barrier

    Instruction Synchronization Barrier flushes the pipeline in the processor,
    so that all instructions following the ISB are fetched from cache or
    memory, after the instruction has been completed.
 */
#define __ISB()                           __isb(0xF)


/** \brief  Data Synchronization Barrier

    This function acts as a special kind of Data Memory Barrier.
    It completes when all explicit memory accesses before this instruction complete.
 */
#define __DSB()                           __dsb(0xF)


/** \brief  Data Memory Barrier

    This function ensures the apparent order of the explicit memory operations before
    and after the instruction, without ensuring their completion.
 */
#define __DMB()                           __dmb(0xF)


/** \brief  Reverse byte order (32 bit)

    This function reverses the byte order in integer value.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
#define __REV                             __rev


/** \brief  Reverse byte order (16 bit)

    This function reverses the byte order in two unsigned short values.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
#ifndef __NO_EMBEDDED_ASM
__attribute__((section(".rev16_text"))) __STATIC_INLINE __ASM uint32_t __REV16(uint32_t value)
{
  rev16 r0, r0
  bx lr
}
#endif

/** \brief  Reverse byte order in signed short value

    This function reverses the byte order in a signed short value with sign extension to integer.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
#ifndef __NO_EMBEDDED_ASM
__attribute__((section(".revsh_text"))) __STATIC_INLINE __ASM int32_t __REVSH(int32_t value)
{
  revsh r0, r0
  bx lr
}
#endif


/** \brief  Rotate Right in unsigned value (32 bit)

    This function Rotate Right (immediate) provides the value of the contents of a register rotated by a variable number of bits.

    \param [in]    value  Value to rotate
    \param [in]    value  Number of Bits to rotate
    \return               Rotated value
 */
#define __ROR                             __ror


#if       (__CORTEX_M >= 0x03)

/** \brief  Reverse bit order of value

    This function reverses the bit order of the given value.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
#define __RBIT                            __rbit


/** \brief  LDR Exclusive (8 bit)

    This function performs a exclusive LDR command for 8 bit value.

    \param [in]    ptr  Pointer to data
    \return             value of type uint8_t at (*ptr)
 */
#define __LDREXB(ptr)                     ((uint8_t ) __ldrex(ptr))


/** \brief  LDR Exclusive (16 bit)

    This function performs a exclusive LDR command for 16 bit values.

    \param [in]    ptr  Pointer to data
    \return        value of type uint16_t at (*ptr)
 */
#define __LDREXH(ptr)                     ((uint16_t) __ldrex(ptr))


/** \brief  LDR Exclusive (32 bit)

    This function performs a exclusive LDR command for 32 bit values.

    \param [in]    ptr  Pointer to data
    \return        value of type uint32_t at (*ptr)
 */
#define __LDREXW(ptr)                     ((uint32_t ) __ldrex(ptr))


/** \brief  STR Exclusive (8 bit)

    This function performs a exclusive STR command for 8 bit values.

    \param [in]  value  Value to store
    \param [in]    ptr  Pointer to location
    \return          0  Function succeeded
    \return          1  Function failed
 */
#define __STREXB(value, ptr)              __strex(value, ptr)


/** \brief  STR Exclusive (16 bit)

    This function performs a exclusive STR command for 16 bit values.

    \param [in]  value  Value to store
    \param [in]    ptr  Pointer to location
    \return          0  Function succeeded
    \return          1  Function failed
 */
#define __STREXH(value, ptr)              __strex(value, ptr)


/** \brief  STR Exclusive (32 bit)

    This function performs a exclusive STR command for 32 bit values.

    \param [in]  value  Value to store
    \param [in]    ptr  Pointer to location
    \return          0  Function succeeded
    \return          1  Function failed
 */
#define __STREXW(value, ptr)              __strex(value, ptr)


/** \brief  Remove the exclusive lock

    This function removes the exclusive lock which is created by LDREX.

 */
#define __CLREX                           __clrex


/** \brief  Signed Saturate

    This function saturates a signed value.

    \param [in]  value  Value to be saturated
    \param [in]    sat  Bit position to saturate to (1..32)
    \return             Saturated value
 */
#define __SSAT                            __ssat


/** \brief  Unsigned Saturate

    This function saturates an unsigned value.

    \param [in]  value  Value to be saturated
    \param [in]    sat  Bit position to saturate to (0..31)
    \return             Saturated value
 */
#define __USAT                            __usat


/** \brief  Count leading zeros

    This function counts the number of leading zeros of a data value.

    \param [in]  value  Value to count the leading zeros
    \return             number of leading zeros in value
 */
#define __CLZ                             __clz

#endif /* (__CORTEX_M >= 0x03) */



#elif defined ( __ICCARM__ ) /*------------------ ICC Compiler -------------------*/
/* IAR iccarm specific functions */

#include <cmsis_iar.h>


#elif defined ( __TMS470__ ) /*---------------- TI CCS Compiler ------------------*/
/* TI CCS specific functions */

#include <cmsis_ccs.h>


#elif defined ( __GNUC__ ) /*------------------ GNU Compiler ---------------------*/
/* GNU gcc specific functions */

/** \brief  No Operation

    No Operation does nothing. This instruction can be used for code alignment purposes.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __NOP(void)
{
  __ASM volatile ("nop");
}


/** \brief  Wait For Interrupt

    Wait For Interrupt is a hint instruction that suspends execution
    until one of a number of events occurs.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __WFI(void)
{
  __ASM volatile ("wfi");
}


/** \brief  Wait For Event

    Wait For Event is a hint instruction that permits the processor to enter
    a low-power state until one of a number of events occurs.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __WFE(void)
{
  __ASM volatile ("wfe");
}


/** \brief  Send Event

    Send Event is a hint instruction. It causes an event to be signaled to the CPU.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __SEV(void)
{
  __ASM volatile ("sev");
}


/** \brief  Instruction Synchronization Barrier

    Instruction Synchronization Barrier flushes the pipeline in the processor,
    so that all instructions following the ISB are fetched from cache or
    memory, after the instruction has been completed.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __ISB(void)
{
  __ASM volatile ("isb");
}


/** \brief  Data Synchronization Barrier

    This function acts as a special kind of Data Memory Barrier.
    It completes when all explicit memory accesses before this instruction complete.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __DSB(void)
{
  __ASM volatile ("dsb");
}


/** \brief  Data Memory Barrier

    This function ensures the apparent order of the explicit memory operations before
    and after the instruction, without ensuring their completion.
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __DMB(void)
{
  __ASM volatile ("dmb");
}


/** \brief  Reverse byte order (32 bit)

    This function reverses the byte order in integer value.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __REV(uint32_t value)
{
  uint32_t result;

  __ASM volatile ("rev %0, %1" : "=r" (result) : "r" (value) );
  return(result);
}


/** \brief  Reverse byte order (16 bit)

    This function reverses the byte order in two unsigned short values.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __REV16(uint32_t value)
{
  uint32_t result;

  __ASM volatile ("rev16 %0, %1" : "=r" (result) : "r" (value) );
  return(result);
}


/** \brief  Reverse byte order in signed short value

    This function reverses the byte order in a signed short value with sign extension to integer.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE int32_t __REVSH(int32_t value)
{
  uint32_t result;

  __ASM volatile ("revsh %0, %1" : "=r" (result) : "r" (value) );
  return(result);
}


/** \brief  Rotate Right in unsigned value (32 bit)

    This function Rotate Right (immediate) provides the value of the contents of a register rotated by a variable number of bits.

    \param [in]    value  Value to rotate
    \param [in]    value  Number of Bits to rotate
    \return               Rotated value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __ROR(uint32_t op1, uint32_t op2)
{

  __ASM volatile ("ror %0, %0, %1" : "+r" (op1) : "r" (op2) );
  return(op1);
}


#if       (__CORTEX_M >= 0x03)

/** \brief  Reverse bit order of value

    This function reverses the bit order of the given value.

    \param [in]    value  Value to reverse
    \return               Reversed value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __RBIT(uint32_t value)
{
  uint32_t result;

   __ASM volatile ("rbit %0, %1" : "=r" (result) : "r" (value) );
   return(result);
}


/** \brief  LDR Exclusive (8 bit)

    This function performs a exclusive LDR command for 8 bit value.

    \param [in]    ptr  Pointer to data
    \return             value of type uint8_t at (*ptr)
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint8_t __LDREXB(volatile uint8_t *addr)
{
    uint8_t result;

   __ASM volatile ("ldrexb %0, [%1]" : "=r" (result) : "r" (addr) );
   return(result);
}


/** \brief  LDR Exclusive (16 bit)

    This function performs a exclusive LDR command for 16 bit values.

    \param [in]    ptr  Pointer to data
    \return        value of type uint16_t at (*ptr)
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint16_t __LDREXH(volatile uint16_t *addr)
{
    uint16_t result;

   __ASM volatile ("ldrexh %0, [%1]" : "=r" (result) : "r" (addr) );
   return(result);
}


/** \brief  LDR Exclusive (32 bit)

    This function performs a exclusive LDR command for 32 bit values.

    \param [in]    ptr  Pointer to data
    \return        value of type uint32_t at (*ptr)
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __LDREXW(volatile uint32_t *addr)
{
    uint32_t result;

   __ASM volatile ("ldrex %0, [%1]" : "=r" (result) : "r" (addr) );
   return(result);
}


/** \brief  STR Exclusive (8 bit)

    This function performs a exclusive STR command for 8 bit values.

    \param [in]  value  Value to store
    \param [in]    ptr  Pointer to location
    \return          0  Function succeeded
    \return          1  Function failed
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __STREXB(uint8_t value, volatile uint8_t *addr)
{
   uint32_t result;

   __ASM volatile ("strexb %0, %2, [%1]" : "=&r" (result) : "r" (addr), "r" (value) );
   return(result);
}


/** \brief  STR Exclusive (16 bit)

    This function performs a exclusive STR command for 16 bit values.

    \param [in]  value  Value to store
    \param [in]    ptr  Pointer to location
    \return          0  Function succeeded
    \return          1  Function failed
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __STREXH(uint16_t value, volatile uint16_t *addr)
{
   uint32_t result;

   __ASM volatile ("strexh %0, %2, [%1]" : "=&r" (result) : "r" (addr), "r" (value) );
   return(result);
}


/** \brief  STR Exclusive (32 bit)

    This function performs a exclusive STR command for 32 bit values.

    \param [in]  value  Value to store
    \param [in]    ptr  Pointer to location
    \return          0  Function succeeded
    \return          1  Function failed
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint32_t __STREXW(uint32_t value, volatile uint32_t *addr)
{
   uint32_t result;

   __ASM volatile ("strex %0, %2, [%1]" : "=&r" (result) : "r" (addr), "r" (value) );
   return(result);
}


/** \brief  Remove the exclusive lock

    This function removes the exclusive lock which is created by LDREX.

 */
__attribute__( ( always_inline ) ) __STATIC_INLINE void __CLREX(void)
{
  __ASM volatile ("clrex");
}


/** \brief  Signed Saturate

    This function saturates a signed value.

    \param [in]  value  Value to be saturated
    \param [in]    sat  Bit position to saturate to (1..32)
    \return             Saturated value
 */
#define __SSAT(ARG1,ARG2) \
({                          \
  uint32_t __RES, __ARG1 = (ARG1); \
  __ASM ("ssat %0, %1, %2" : "=r" (__RES) :  "I" (ARG2), "r" (__ARG1) ); \
  __RES; \
 })


/** \brief  Unsigned Saturate

    This function saturates an unsigned value.

    \param [in]  value  Value to be saturated
    \param [in]    sat  Bit position to saturate to (0..31)
    \return             Saturated value
 */
#define __USAT(ARG1,ARG2) \
({                          \
  uint32_t __RES, __ARG1 = (ARG1); \
  __ASM ("usat %0, %1, %2" : "=r" (__RES) :  "I" (ARG2), "r" (__ARG1) ); \
  __RES; \
 })


/** \brief  Count leading zeros

    This function counts the number of leading zeros of a data value.

    \param [in]  value  Value to count the leading zeros
    \return             number of leading zeros in value
 */
__attribute__( ( always_inline ) ) __STATIC_INLINE uint8_t __CLZ(uint32_t value)
{
  uint8_t result;

  __ASM volatile ("clz %0, %1" : "=r" (result) : "r" (value) );
  return(result);
}

#endif /* (__CORTEX_M >= 0x03) */




#elif defined ( __TASKING__ ) /*------------------ TASKING Compiler --------------*/
/* TASKING carm specific functions */

/*
 * The CMSIS functions have been implemented as intrinsics in the compiler.
 * Please use "carm -?i" to get an up to date list of all intrinsics,
 * Including the CMSIS ones.
 */

#endif

/*@}*/ /* end of group CMSIS_Core_InstructionInterface */

#endif /* __CORE_CMINSTR_H */
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