Compiler Control

Compiler agnostic #define symbols for generic C/C++ source code. More...

Macros
#define	__ARM_ARCH_7A__   1
	Set to 1 when generating code for Armv7-A (Cortex-A7) More...
#define	__ASM   __asm
	Pass information from the compiler to the assembler. More...
#define	__INLINE   __inline
	Recommend that function should be inlined by the compiler. More...
#define	__STATIC_INLINE   static __inline
	Define a static function should be inlined by the compiler. More...
#define	__STATIC_FORCEINLINE
	Define a static function that should be always inlined by the compiler. More...
#define	__NO_RETURN   __declspec(noreturn)
	Inform the compiler that a function does not return. More...
#define	__USED   __attribute__((used))
	Inform that a variable shall be retained in executable image. More...
#define	__WEAK   __attribute__((weak))
	Export a function or variable weakly to allow overwrites. More...
#define	__ALIGNED(x)   __attribute__((aligned(x)))
	Minimum alignment for a variable. More...
#define	__PACKED   __attribute__((packed))
	Request smallest possible alignment. More...
#define	__PACKED_STRUCT
	Request smallest possible alignment for a structure. More...
#define	__UNALIGNED_UINT32
	Pointer for unaligned access of a uint32_t variable. More...
#define	__UNALIGNED_UINT16_READ
	Pointer for unaligned read of a uint16_t variable. More...
#define	__UNALIGNED_UINT16_WRITE
	Pointer for unaligned write of a uint16_t variable. More...
#define	__UNALIGNED_UINT32_READ
	Pointer for unaligned read of a uint32_t variable. More...
#define	__UNALIGNED_UINT32_WRITE
	Pointer for unaligned write of a uint32_t variable. More...

Description

The CMSIS-Core provides the header file cmsis_compiler.h with consistent #define symbols to generate C or C++ source files that should be compiler agnostic. Each CMSIS compliant compiler should support the functionality described in this section.

Macro Definition Documentation

#define __ALIGNED

(

x

)

__attribute__((aligned(x)))

Specifies a minimum alignment for a variable or structure field, measured in bytes.

Code Example:

uint32_t stack_space[0x100] __ALIGNED(8);   // 8-byte alignment required

#define __ARM_ARCH_7A__   1

The #define ARM_ARCH_7A is set to 1 when generating code for the Armv7-A architecture. This architecture is for example used by the Cortex-A7 processor.

#define __ASM   __asm

The __ASM keyword can declare or define an embedded assembly function or incorporate inline assembly into a function (shown in the code example below).

Code Example:

// Reverse bit order of 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);
}

#define __INLINE   __inline

Inline functions offer a trade-off between code size and performance. By default, the compiler decides during optimization whether to inline code or not. The __INLINE attribute gives the compiler an hint to inline this function. Still, the compiler may decide not to inline the function. As the function is global an callable function is also generated.

Code Example:

const uint32_t led_mask[] = {1U << 4, 1U << 5, 1U << 6, 1U << 7};
 
//------------------------------------------------------------------------------
// Switch on LEDs
//------------------------------------------------------------------------------
__INLINE static void LED_On (uint32_t led) {
 
  PTD->PCOR   = led_mask[led];
}

#define __NO_RETURN   __declspec(noreturn)

Informs the compiler that the function does not return. The compiler can then perform optimizations by removing code that is never reached.

Code Example:

// OS idle demon (running when no other thread is ready to run).
 
__NO_RETURN void os_idle_demon (void);

#define __PACKED   __attribute__((packed))

Specifies that a type must have the smallest possible alignment.

Code Example:

struct foo {
  uint8_t  u8;
  uint32_t u32[2] __PACKED;
};

#define __PACKED_STRUCT

Specifies that a structure must have the smallest possible alignment.

Code Example:

__PACKED_STRUCT foo {
  uint8_t   u8;
  uint32_t  u32;
  uint16_t  u16;
};

#define __STATIC_FORCEINLINE

Defines a static function that should be always inlined by the compiler.

Note

For compilers that do not allow to force function inlining, the macro maps to __STATIC_INLINE.

Code Example:

\\ Get Interrupt Vector
__STATIC_FORCEINLINE uint32_t NVIC_GetVector(IRQn_Type IRQn)
{
    uint32_t *vectors = (uint32_t *)SCB->VTOR;
    return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}

#define __STATIC_INLINE   static __inline

Defines a static function that may be inlined by the compiler. If the compiler generates inline code for all calls to this functions, no additional function implementation is generated which may further optimize space.

Code Example:

__STATIC_INLINE uint32_t GIC_GetPriority(IRQn_Type IRQn)
{
  return((uint32_t)GICDistributor->D_IPRIORITYR[((uint32_t)(int32_t)IRQn)]);
}

#define __UNALIGNED_UINT16_READ

Defines a pointer to a uint16_t from an address that does not need to be aligned. This can then be used in read operations. The compiler will generate the appropriate access (aligned or non-aligned) depending on the underlying Arm processor core and compiler settings.

Code Example:

uint16_t val16;
 
void test (uint8_t *ptr) {
   val16 = __UNALIGNED_UINT16_READ(ptr);
}

#define __UNALIGNED_UINT16_WRITE

Defines a pointer to a uint16_t from an address that does not need to be aligned. This can then be used in write operations. The compiler will generate the appropriate access (aligned or non-aligned) depending on the underlying Arm processor core and compiler settings.

Code Example:

uint16_t val16 = 0U;
 
void test (uint8_t *ptr) {
   __UNALIGNED_UINT16_WRITE(ptr, val16);
}

#define __UNALIGNED_UINT32

Deprecated:

Do not use this macro. It has been superseded by __UNALIGNED_UINT32_READ, __UNALIGNED_UINT32_WRITE and will be removed in the future.

Defines a pointer to a uint32_t from an address that does not need to be aligned. This can then be used in read/write operations. The compiler will generate the appropriate access (aligned or non-aligned) depending on the underlying Arm processor core and compiler settings.

Code Example:

uint32_t val32;
 
void test (uint8_t *ptr) {
  __UNALIGNED_UINT32(ptr) = val32;
}

#define __UNALIGNED_UINT32_READ

Defines a pointer to a uint32_t from an address that does not need to be aligned. This can then be used in read operations. The compiler will generate the appropriate access (aligned or non-aligned) depending on the underlying Arm processor core and compiler settings.

Code Example:

uint32_t val32;
 
void test (uint8_t *ptr) {
   val32 = __UNALIGNED_UINT32_READ(ptr);
}

#define __UNALIGNED_UINT32_WRITE

Defines a pointer to a uint32_t from an address that does not need to be aligned. This can then be used in write operations. The compiler will generate the appropriate access (aligned or non-aligned) depending on the underlying Arm processor core and compiler settings.

Code Example:

uint32_t val32 = 0U;
 
void test (uint8_t *ptr) {
   __UNALIGNED_UINT32_WRITE(ptr, val32);
}

#define __USED   __attribute__((used))

Definitions tagged with __USED in the source code should be not removed by the linker when detected as unused.

Code Example:

// Export following variables for debugging 
__USED uint32_t const CMSIS_RTOS_API_Version = osCMSIS;
__USED uint32_t const CMSIS_RTOS_RTX_Version = osCMSIS_RTX;
__USED uint32_t const os_clockrate = OS_TICK;
__USED uint32_t const os_timernum  = 0;

#define __WEAK   __attribute__((weak))

Functions defined with __WEAK export their symbols weakly. A function defined weak behaves like a normal defined function unless a non-weak function with the same name is linked into the same image. If both a non-weak function and a weak defined function exist in the same image, then all calls to the function resolve to the non-weak function.

Functions declared with __WEAK and then defined without __WEAK behave as non-weak functions.

Code Example:

__WEAK void SystemInit(void)
{
  SystemCoreSetup();
  SystemCoreClockSetup(); 
}