src/rp2_common/pico_platform/include/pico/platform.h - third_party/github/raspberrypi/pico-sdk - Git at Google

 /*
  * Copyright (c) 2020 Raspberry Pi (Trading) Ltd.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #ifndef _PICO_PLATFORM_H_
 #define _PICO_PLATFORM_H_

 /** \file platform.h
  *  \defgroup pico_platform pico_platform
  *
  * Macros and definitions (and functions when included by non assembly code) for the RP2 family device / architecture
  * to provide a common abstraction over low level compiler / platform specifics.
  *
  * This header may be included by assembly code
  */

 #include "hardware/platform_defs.h"

 // Marker for builds targeting the RP2040
 #define PICO_RP2040 1

 // PICO_CONFIG: PICO_STACK_SIZE, Stack Size, min=0x100, default=0x800, advanced=true, group=pico_platform
 #ifndef PICO_STACK_SIZE
 #define PICO_STACK_SIZE _u(0x800)
 #endif

 // PICO_CONFIG: PICO_HEAP_SIZE, Heap size to reserve, min=0x100, default=0x800, advanced=true, group=pico_platform
 #ifndef PICO_HEAP_SIZE
 #define PICO_HEAP_SIZE _u(0x800)
 #endif

 // PICO_CONFIG: PICO_NO_RAM_VECTOR_TABLE, Enable/disable the RAM vector table, type=bool, default=0, advanced=true, group=pico_platform
 #ifndef PICO_NO_RAM_VECTOR_TABLE
 #define PICO_NO_RAM_VECTOR_TABLE 0
 #endif

 // PICO_CONFIG: PICO_RP2040_B0_SUPPORTED, Whether to include any specific software support for RP2040 B0 revision, type=bool, default=1, advanced=true, group=pico_platform
 #ifndef PICO_RP2040_B0_SUPPORTED
 #define PICO_RP2040_B0_SUPPORTED 1
 #endif

 // PICO_CONFIG: PICO_FLOAT_SUPPORT_ROM_V1, Include float support code for RP2040 B0 when that chip revision is supported , type=bool, default=1, advanced=true, group=pico_platform
 #ifndef PICO_FLOAT_SUPPORT_ROM_V1
 #define PICO_FLOAT_SUPPORT_ROM_V1 1
 #endif

 // PICO_CONFIG: PICO_DOUBLE_SUPPORT_ROM_V1, Include double support code for RP2040 B0 when that chip revision is supported , type=bool, default=1, advanced=true, group=pico_platform
 #ifndef PICO_DOUBLE_SUPPORT_ROM_V1
 #define PICO_DOUBLE_SUPPORT_ROM_V1 1
 #endif


 // PICO_CONFIG: PICO_RP2040_B1_SUPPORTED, Whether to include any specific software support for RP2040 B1 revision, type=bool, default=1, advanced=true, group=pico_platform
 #ifndef PICO_RP2040_B1_SUPPORTED
 #define PICO_RP2040_B1_SUPPORTED 1
 #endif

 // PICO_CONFIG: PICO_RP2040_B2_SUPPORTED, Whether to include any specific software support for RP2040 B2 revision, type=bool, default=1, advanced=true, group=pico_platform
 #ifndef PICO_RP2040_B2_SUPPORTED
 #define PICO_RP2040_B2_SUPPORTED 1
 #endif

 // --- remainder of file is not included by assembly code ---

 #ifndef __ASSEMBLER__

 #include <sys/cdefs.h>
 #include "pico/types.h"

 #ifdef __cplusplus
 extern "C" {
 #endif

 /*! \brief Marker for an interrupt handler
  *  \ingroup pico_platform
  * For example an IRQ handler function called my_interrupt_handler:
  *
  *     void __isr my_interrupt_handler(void) {
  */
 #define __isr

 /*! \brief Section attribute macro for placement in RAM after the `.data` section
  *  \ingroup pico_platform
  *
  * For example a 400 element `uint32_t` array placed after the .data section
  *
  *     uint32_t __after_data("my_group_name") a_big_array[400];
  *
  * The section attribute is `.after_data.<group>`
  *
  * \param group a string suffix to use in the section name to distinguish groups that can be linker
  *              garbage-collected independently
  */
 #define __after_data(group) __attribute__((section(".after_data." group)))

 /*! \brief Section attribute macro for placement not in flash (i.e in RAM)
  *  \ingroup pico_platform
  *
  * For example a 3 element `uint32_t` array placed in RAM (even though it is `static const`)
  *
  *     static const uint32_t __not_in_flash("my_group_name") an_array[3];
  *
  * The section attribute is `.time_critical.<group>`
  *
  * \param group a string suffix to use in the section name to distinguish groups that can be linker
  *              garbage-collected independently
  */
 #define __not_in_flash(group) __attribute__((section(".time_critical." group)))

 /*! \brief Section attribute macro for placement in the SRAM bank 4 (known as "scratch X")
  *  \ingroup pico_platform
  *
  * Scratch X is commonly used for critical data and functions accessed only by one core (when only
  * one core is accessing the RAM bank, there is no opportunity for stalls)
  *
  * For example a `uint32_t` variable placed in "scratch X"
  *
  *     uint32_t __scratch_x("my_group_name") foo = 23;
  *
  * The section attribute is `.scratch_x.<group>`
  *
  * \param group a string suffix to use in the section name to distinguish groups that can be linker
  *              garbage-collected independently
  */
 #define __scratch_x(group) __attribute__((section(".scratch_x." group)))

 /*! \brief Section attribute macro for placement in the SRAM bank 5 (known as "scratch Y")
  *  \ingroup pico_platform
  *
  * Scratch Y is commonly used for critical data and functions accessed only by one core (when only
  * one core is accessing the RAM bank, there is no opportunity for stalls)
  *
  * For example a `uint32_t` variable placed in "scratch Y"
  *
  *     uint32_t __scratch_y("my_group_name") foo = 23;
  *
  * The section attribute is `.scratch_y.<group>`
  *
  * \param group a string suffix to use in the section name to distinguish groups that can be linker
  *              garbage-collected independently
  */
 #define __scratch_y(group) __attribute__((section(".scratch_y." group)))

 /*! \brief Section attribute macro for data that is to be left uninitialized
  *  \ingroup pico_platform
  *
  * Data marked this way will retain its value across a reset (normally uninitialized data - in the .bss
  * section) is initialized to zero during runtime initialization
  *
  * For example a `uint32_t` foo that will retain its value if the program is restarted by reset.
  *
  *     uint32_t __uninitialized_ram("my_group_name") foo;
  *
  * The section attribute is `.uninitialized_ram.<group>`
  *
  * \param group a string suffix to use in the section name to distinguish groups that can be linker
  *              garbage-collected independently
  */
 #define __uninitialized_ram(group) __attribute__((section(".uninitialized_ram." #group))) group

 /*! \brief Section attribute macro for placement in flash even in a COPY_TO_RAM binary
  *  \ingroup pico_platform
  *
  * For example a `uint32_t` variable explicitly placed in flash (it will hard fault if you attempt to write it!)
  *
  *     uint32_t __in_flash("my_group_name") foo = 23;
  *
  * The section attribute is `.flashdata.<group>`
  *
  * \param group a string suffix to use in the section name to distinguish groups that can be linker
  *              garbage-collected independently
  */
 #define __in_flash(group) __attribute__((section(".flashdata" group)))

 /*! \brief Indicates a function should not be stored in flash
  *  \ingroup pico_platform
  *
  * Decorates a function name, such that the function will execute from RAM (assuming it is not inlined
  * into a flash function by the compiler)
  *
  * For example a function called my_func taking an int parameter:
  *
  *     void __not_in_flash_func(my_func)(int some_arg) {
  *
  * The function is placed in the `.time_critical.<func_name>` linker section
  *
  * \see __no_inline_not_in_flash_func
  */
 #define __not_in_flash_func(func_name) __not_in_flash(__STRING(func_name)) func_name

 /*! \brief Indicates a function is time/latency critical and should not run from flash
  *  \ingroup pico_platform
  *
  * Decorates a function name, such that the function will execute from RAM (assuming it is not inlined
  * into a flash function by the compiler) to avoid possible flash latency. Currently this macro is identical
  * in implementation to `__not_in_flash_func`, however the semantics are distinct and a `__time_critical_func`
  * may in the future be treated more specially to reduce the overhead when calling such function from a flash
  * function.
  *
  * For example a function called my_func taking an int parameter:
  *
  *     void __time_critical(my_func)(int some_arg) {
  *
  * The function is placed in the `.time_critical.<func_name>` linker section
  *
  * \see __not_in_flash_func
  */
 #define __time_critical_func(func_name) __not_in_flash_func(func_name)

 /*! \brief Indicate a function should not be stored in flash and should not be inlined
  *  \ingroup pico_platform
  *
  * Decorates a function name, such that the function will execute from RAM, explicitly marking it as
  * noinline to prevent it being inlined into a flash function by the compiler
  *
  * For example a function called my_func taking an int parameter:
  *
  *     void __no_inline_not_in_flash_func(my_func)(int some_arg) {
  *
  * The function is placed in the `.time_critical.<func_name>` linker section
  */
 #define __no_inline_not_in_flash_func(func_name) __noinline __not_in_flash_func(func_name)

 #define __packed_aligned __packed __aligned(4)

 /*! \brief Attribute to force inlining of a function regardless of optimization level
  *  \ingroup pico_platform
  *
  *  For example my_function here will always be inlined:
  *
  *      int __force_inline my_function(int x) {
  *
  */
 #if defined(__GNUC__) && __GNUC__ <= 7
 #define __force_inline inline __always_inline
 #else
 #define __force_inline __always_inline
 #endif

 /*! \brief Macro to determine the number of elements in an array
  *  \ingroup pico_platform
  */
 #ifndef count_of
 #define count_of(a) (sizeof(a)/sizeof((a)[0]))
 #endif

 /*! \brief Macro to return the maximum of two comparable values
  *  \ingroup pico_platform
  */
 #ifndef MAX
 #define MAX(a, b) ((a)>(b)?(a):(b))
 #endif

 /*! \brief Macro to return the minimum of two comparable values
  *  \ingroup pico_platform
  */
 #ifndef MIN
 #define MIN(a, b) ((b)>(a)?(a):(b))
 #endif

 /*! \brief Execute a breakpoint instruction
  *  \ingroup pico_platform
  */
 static inline void __breakpoint(void) {
     __asm__("bkpt #0");
 }

 /*! \brief Ensure that the compiler does not move memory access across this method call
  *  \ingroup pico_platform
  *
  *  For example in the following code:
  *
  *      *some_memory_location = var_a;
  *      __compiler_memory_barrier();
  *      uint32_t var_b = *some_other_memory_location
  *
  * The compiler will not move the load from `some_other_memory_location` above the memory barrier (which it otherwise
  * might - even above the memory store!)
  */
 __force_inline static void __compiler_memory_barrier(void) {
     __asm__ volatile ("" : : : "memory");
 }

 /*! \brief Macro for converting memory addresses to 32 bit addresses suitable for DMA
  *  \ingroup pico_platform
  *
  *  This is just a cast to `uintptr_t` on the RP2040, however you may want to use this when developing code
  *  that also runs in "host" mode. If the host mode is 64 bit and you are embedding data pointers
  *  in other data (e.g. DMA chaining), then there is a need in "host" mode to convert a 64 bit native
  *  pointer to a 32 bit value for storage, which can be done using this macro.
  */
 #define host_safe_hw_ptr(x) ((uintptr_t)(x))
 #define native_safe_hw_ptr(x) host_safe_hw_ptr(x)


 /*! \brief Panics with the message "Unsupported"
  *  \ingroup pico_platform
  *  \see panic
  */
 void __attribute__((noreturn)) panic_unsupported(void);

 /*! \brief Displays a panic message and halts execution
  *  \ingroup pico_platform
  *
  * An attempt is made to output the message to all registered STDOUT drivers
  * after which this method executes a BKPT instruction.
  *
  * @param fmt format string (printf-like)
  * @param ...  printf-like arguments
  */
 void __attribute__((noreturn)) panic(const char *fmt, ...);

 // PICO_CONFIG: PICO_NO_FPGA_CHECK, Remove the FPGA platform check for small code size reduction, type=bool, default=0, advanced=true, group=pico_runtime
 #ifndef PICO_NO_FPGA_CHECK
 #define PICO_NO_FPGA_CHECK 0
 #endif

 #if PICO_NO_FPGA_CHECK
 static inline bool running_on_fpga(void) {return false;}
 #else
 bool running_on_fpga(void);
 #endif

 /*! \brief Returns the RP2040 chip revision number
  *  \ingroup pico_platform
  * @return the RP2040 chip revision number (1 for B0/B1, 2 for B2)
  */
 uint8_t rp2040_chip_version(void);

 /*! \brief Returns the RP2040 rom version number
  *  \ingroup pico_platform
  * @return the RP2040 rom version number (1 for RP2040-B0, 2 for RP2040-B1, 3 for RP2040-B2)
  */
 static inline uint8_t rp2040_rom_version(void) {
     return *(uint8_t*)0x13;
 }

 /*! \brief No-op function for the body of tight loops
  *  \ingroup pico_platform
  *
  * Np-op function intended to be called by any tight hardware polling loop. Using this ubiquitously
  * makes it much easier to find tight loops, but also in the future \#ifdef-ed support for lockup
  * debugging might be added
  */
 static __force_inline void tight_loop_contents(void) {}

 /*! \brief Multiply two integers using an assembly `MUL` instruction
  *  \ingroup pico_platform
  *
  * This multiplies a by b using multiply instruction using the ARM mul instruction regardless of values (the compiler
  * might otherwise choose to perform shifts/adds), i.e. this is a 1 cycle operation.
  *
  * \param a the first operand
  * \param b the second operand
  * \return a * b
  */
 __force_inline static int32_t __mul_instruction(int32_t a, int32_t b) {
     asm ("mul %0, %1" : "+l" (a) : "l" (b) : );
     return a;
 }

 /*! \brief multiply two integer values using the fastest method possible
  *  \ingroup pico_platform
  *
  * Efficiently multiplies value a by possibly constant value b.
  *
  * If b is known to be constant and not zero or a power of 2, then a mul instruction is used rather than gcc's default
  * which is often a slow combination of shifts and adds. If b is a power of 2 then a single shift is of course preferable
  * and will be used
  *
  * \param a the first operand
  * \param b the second operand
  * \return a * b
  */
 #define __fast_mul(a, b) __builtin_choose_expr(__builtin_constant_p(b) && !__builtin_constant_p(a), \
 (__builtin_popcount(b) >= 2 ? __mul_instruction(a,b) : (a)*(b)), \
 (a)*(b))

 /*! \brief Utility macro to assert two types are equivalent.
  *  \ingroup pico_platform
  *
  *  This macro can be useful in other macros along with `typeof` to assert that two parameters are of equivalent type
  *  (or that a single parameter is of an expected type)
  */
 #define __check_type_compatible(type_a, type_b) static_assert(__builtin_types_compatible_p(type_a, type_b), __STRING(type_a) " is not compatible with " __STRING(type_b));

 /*! \brief Get the current exception level on this core
  *  \ingroup pico_platform
  *
  * \return the exception number if the CPU is handling an exception, or 0 otherwise
  */
 uint __get_current_exception(void);

 #define WRAPPER_FUNC(x) __wrap_ ## x
 #define REAL_FUNC(x) __real_ ## x

 #ifdef __cplusplus
 }
 #endif

 #else // __ASSEMBLER__

 #define WRAPPER_FUNC_NAME(x) __wrap_##x
 #define SECTION_NAME(x) .text.##x
 #define RAM_SECTION_NAME(x) .time_critical.##x

 #endif // !__ASSEMBLER__

 #endif
	/*
	* Copyright (c) 2020 Raspberry Pi (Trading) Ltd.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#ifndef _PICO_PLATFORM_H_
	#define _PICO_PLATFORM_H_

	/** \file platform.h
	* \defgroup pico_platform pico_platform
	*
	* Macros and definitions (and functions when included by non assembly code) for the RP2 family device / architecture
	* to provide a common abstraction over low level compiler / platform specifics.
	*
	* This header may be included by assembly code
	*/

	#include "hardware/platform_defs.h"

	// Marker for builds targeting the RP2040
	#define PICO_RP2040 1

	// PICO_CONFIG: PICO_STACK_SIZE, Stack Size, min=0x100, default=0x800, advanced=true, group=pico_platform
	#ifndef PICO_STACK_SIZE
	#define PICO_STACK_SIZE _u(0x800)
	#endif

	// PICO_CONFIG: PICO_HEAP_SIZE, Heap size to reserve, min=0x100, default=0x800, advanced=true, group=pico_platform
	#ifndef PICO_HEAP_SIZE
	#define PICO_HEAP_SIZE _u(0x800)
	#endif

	// PICO_CONFIG: PICO_NO_RAM_VECTOR_TABLE, Enable/disable the RAM vector table, type=bool, default=0, advanced=true, group=pico_platform
	#ifndef PICO_NO_RAM_VECTOR_TABLE
	#define PICO_NO_RAM_VECTOR_TABLE 0
	#endif

	// PICO_CONFIG: PICO_RP2040_B0_SUPPORTED, Whether to include any specific software support for RP2040 B0 revision, type=bool, default=1, advanced=true, group=pico_platform
	#ifndef PICO_RP2040_B0_SUPPORTED
	#define PICO_RP2040_B0_SUPPORTED 1
	#endif

	// PICO_CONFIG: PICO_FLOAT_SUPPORT_ROM_V1, Include float support code for RP2040 B0 when that chip revision is supported , type=bool, default=1, advanced=true, group=pico_platform
	#ifndef PICO_FLOAT_SUPPORT_ROM_V1
	#define PICO_FLOAT_SUPPORT_ROM_V1 1
	#endif

	// PICO_CONFIG: PICO_DOUBLE_SUPPORT_ROM_V1, Include double support code for RP2040 B0 when that chip revision is supported , type=bool, default=1, advanced=true, group=pico_platform
	#ifndef PICO_DOUBLE_SUPPORT_ROM_V1
	#define PICO_DOUBLE_SUPPORT_ROM_V1 1
	#endif


	// PICO_CONFIG: PICO_RP2040_B1_SUPPORTED, Whether to include any specific software support for RP2040 B1 revision, type=bool, default=1, advanced=true, group=pico_platform
	#ifndef PICO_RP2040_B1_SUPPORTED
	#define PICO_RP2040_B1_SUPPORTED 1
	#endif

	// PICO_CONFIG: PICO_RP2040_B2_SUPPORTED, Whether to include any specific software support for RP2040 B2 revision, type=bool, default=1, advanced=true, group=pico_platform
	#ifndef PICO_RP2040_B2_SUPPORTED
	#define PICO_RP2040_B2_SUPPORTED 1
	#endif

	// --- remainder of file is not included by assembly code ---

	#ifndef __ASSEMBLER__

	#include <sys/cdefs.h>
	#include "pico/types.h"

	#ifdef __cplusplus
	extern "C" {
	#endif

	/*! \brief Marker for an interrupt handler
	* \ingroup pico_platform
	* For example an IRQ handler function called my_interrupt_handler:
	*
	* void __isr my_interrupt_handler(void) {
	*/
	#define __isr

	/*! \brief Section attribute macro for placement in RAM after the `.data` section
	* \ingroup pico_platform
	*
	* For example a 400 element `uint32_t` array placed after the .data section
	*
	* uint32_t __after_data("my_group_name") a_big_array[400];
	*
	* The section attribute is `.after_data.<group>`
	*
	* \param group a string suffix to use in the section name to distinguish groups that can be linker
	* garbage-collected independently
	*/
	#define __after_data(group) __attribute__((section(".after_data." group)))

	/*! \brief Section attribute macro for placement not in flash (i.e in RAM)
	* \ingroup pico_platform
	*
	* For example a 3 element `uint32_t` array placed in RAM (even though it is `static const`)
	*
	* static const uint32_t __not_in_flash("my_group_name") an_array[3];
	*
	* The section attribute is `.time_critical.<group>`
	*
	* \param group a string suffix to use in the section name to distinguish groups that can be linker
	* garbage-collected independently
	*/
	#define __not_in_flash(group) __attribute__((section(".time_critical." group)))

	/*! \brief Section attribute macro for placement in the SRAM bank 4 (known as "scratch X")
	* \ingroup pico_platform
	*
	* Scratch X is commonly used for critical data and functions accessed only by one core (when only
	* one core is accessing the RAM bank, there is no opportunity for stalls)
	*
	* For example a `uint32_t` variable placed in "scratch X"
	*
	* uint32_t __scratch_x("my_group_name") foo = 23;
	*
	* The section attribute is `.scratch_x.<group>`
	*
	* \param group a string suffix to use in the section name to distinguish groups that can be linker
	* garbage-collected independently
	*/
	#define __scratch_x(group) __attribute__((section(".scratch_x." group)))

	/*! \brief Section attribute macro for placement in the SRAM bank 5 (known as "scratch Y")
	* \ingroup pico_platform
	*
	* Scratch Y is commonly used for critical data and functions accessed only by one core (when only
	* one core is accessing the RAM bank, there is no opportunity for stalls)
	*
	* For example a `uint32_t` variable placed in "scratch Y"
	*
	* uint32_t __scratch_y("my_group_name") foo = 23;
	*
	* The section attribute is `.scratch_y.<group>`
	*
	* \param group a string suffix to use in the section name to distinguish groups that can be linker
	* garbage-collected independently
	*/
	#define __scratch_y(group) __attribute__((section(".scratch_y." group)))

	/*! \brief Section attribute macro for data that is to be left uninitialized
	* \ingroup pico_platform
	*
	* Data marked this way will retain its value across a reset (normally uninitialized data - in the .bss
	* section) is initialized to zero during runtime initialization
	*
	* For example a `uint32_t` foo that will retain its value if the program is restarted by reset.
	*
	* uint32_t __uninitialized_ram("my_group_name") foo;
	*
	* The section attribute is `.uninitialized_ram.<group>`
	*
	* \param group a string suffix to use in the section name to distinguish groups that can be linker
	* garbage-collected independently
	*/
	#define __uninitialized_ram(group) __attribute__((section(".uninitialized_ram." #group))) group

	/*! \brief Section attribute macro for placement in flash even in a COPY_TO_RAM binary
	* \ingroup pico_platform
	*
	* For example a `uint32_t` variable explicitly placed in flash (it will hard fault if you attempt to write it!)
	*
	* uint32_t __in_flash("my_group_name") foo = 23;
	*
	* The section attribute is `.flashdata.<group>`
	*
	* \param group a string suffix to use in the section name to distinguish groups that can be linker
	* garbage-collected independently
	*/
	#define __in_flash(group) __attribute__((section(".flashdata" group)))

	/*! \brief Indicates a function should not be stored in flash
	* \ingroup pico_platform
	*
	* Decorates a function name, such that the function will execute from RAM (assuming it is not inlined
	* into a flash function by the compiler)
	*
	* For example a function called my_func taking an int parameter:
	*
	* void __not_in_flash_func(my_func)(int some_arg) {
	*
	* The function is placed in the `.time_critical.<func_name>` linker section
	*
	* \see __no_inline_not_in_flash_func
	*/
	#define __not_in_flash_func(func_name) __not_in_flash(__STRING(func_name)) func_name

	/*! \brief Indicates a function is time/latency critical and should not run from flash
	* \ingroup pico_platform
	*
	* Decorates a function name, such that the function will execute from RAM (assuming it is not inlined
	* into a flash function by the compiler) to avoid possible flash latency. Currently this macro is identical
	* in implementation to `__not_in_flash_func`, however the semantics are distinct and a `__time_critical_func`
	* may in the future be treated more specially to reduce the overhead when calling such function from a flash
	* function.
	*
	* For example a function called my_func taking an int parameter:
	*
	* void __time_critical(my_func)(int some_arg) {
	*
	* The function is placed in the `.time_critical.<func_name>` linker section
	*
	* \see __not_in_flash_func
	*/
	#define __time_critical_func(func_name) __not_in_flash_func(func_name)

	/*! \brief Indicate a function should not be stored in flash and should not be inlined
	* \ingroup pico_platform
	*
	* Decorates a function name, such that the function will execute from RAM, explicitly marking it as
	* noinline to prevent it being inlined into a flash function by the compiler
	*
	* For example a function called my_func taking an int parameter:
	*
	* void __no_inline_not_in_flash_func(my_func)(int some_arg) {
	*
	* The function is placed in the `.time_critical.<func_name>` linker section
	*/
	#define __no_inline_not_in_flash_func(func_name) __noinline __not_in_flash_func(func_name)

	#define __packed_aligned __packed __aligned(4)

	/*! \brief Attribute to force inlining of a function regardless of optimization level
	* \ingroup pico_platform
	*
	* For example my_function here will always be inlined:
	*
	* int __force_inline my_function(int x) {
	*
	*/
	#if defined(__GNUC__) && __GNUC__ <= 7
	#define __force_inline inline __always_inline
	#else
	#define __force_inline __always_inline
	#endif

	/*! \brief Macro to determine the number of elements in an array
	* \ingroup pico_platform
	*/
	#ifndef count_of
	#define count_of(a) (sizeof(a)/sizeof((a)[0]))
	#endif

	/*! \brief Macro to return the maximum of two comparable values
	* \ingroup pico_platform
	*/
	#ifndef MAX
	#define MAX(a, b) ((a)>(b)?(a):(b))
	#endif

	/*! \brief Macro to return the minimum of two comparable values
	* \ingroup pico_platform
	*/
	#ifndef MIN
	#define MIN(a, b) ((b)>(a)?(a):(b))
	#endif

	/*! \brief Execute a breakpoint instruction
	* \ingroup pico_platform
	*/
	static inline void __breakpoint(void) {
	__asm__("bkpt #0");
	}

	/*! \brief Ensure that the compiler does not move memory access across this method call
	* \ingroup pico_platform
	*
	* For example in the following code:
	*
	* *some_memory_location = var_a;
	* __compiler_memory_barrier();
	* uint32_t var_b = *some_other_memory_location
	*
	* The compiler will not move the load from `some_other_memory_location` above the memory barrier (which it otherwise
	* might - even above the memory store!)
	*/
	__force_inline static void __compiler_memory_barrier(void) {
	__asm__ volatile ("" : : : "memory");
	}

	/*! \brief Macro for converting memory addresses to 32 bit addresses suitable for DMA
	* \ingroup pico_platform
	*
	* This is just a cast to `uintptr_t` on the RP2040, however you may want to use this when developing code
	* that also runs in "host" mode. If the host mode is 64 bit and you are embedding data pointers
	* in other data (e.g. DMA chaining), then there is a need in "host" mode to convert a 64 bit native
	* pointer to a 32 bit value for storage, which can be done using this macro.
	*/
	#define host_safe_hw_ptr(x) ((uintptr_t)(x))
	#define native_safe_hw_ptr(x) host_safe_hw_ptr(x)


	/*! \brief Panics with the message "Unsupported"
	* \ingroup pico_platform
	* \see panic
	*/
	void __attribute__((noreturn)) panic_unsupported(void);

	/*! \brief Displays a panic message and halts execution
	* \ingroup pico_platform
	*
	* An attempt is made to output the message to all registered STDOUT drivers
	* after which this method executes a BKPT instruction.
	*
	* @param fmt format string (printf-like)
	* @param ... printf-like arguments
	*/
	void __attribute__((noreturn)) panic(const char *fmt, ...);

	// PICO_CONFIG: PICO_NO_FPGA_CHECK, Remove the FPGA platform check for small code size reduction, type=bool, default=0, advanced=true, group=pico_runtime
	#ifndef PICO_NO_FPGA_CHECK
	#define PICO_NO_FPGA_CHECK 0
	#endif

	#if PICO_NO_FPGA_CHECK
	static inline bool running_on_fpga(void) {return false;}
	#else
	bool running_on_fpga(void);
	#endif

	/*! \brief Returns the RP2040 chip revision number
	* \ingroup pico_platform
	* @return the RP2040 chip revision number (1 for B0/B1, 2 for B2)
	*/
	uint8_t rp2040_chip_version(void);

	/*! \brief Returns the RP2040 rom version number
	* \ingroup pico_platform
	* @return the RP2040 rom version number (1 for RP2040-B0, 2 for RP2040-B1, 3 for RP2040-B2)
	*/
	static inline uint8_t rp2040_rom_version(void) {
	return (uint8_t)0x13;
	}

	/*! \brief No-op function for the body of tight loops
	* \ingroup pico_platform
	*
	* Np-op function intended to be called by any tight hardware polling loop. Using this ubiquitously
	* makes it much easier to find tight loops, but also in the future \#ifdef-ed support for lockup
	* debugging might be added
	*/
	static __force_inline void tight_loop_contents(void) {}

	/*! \brief Multiply two integers using an assembly `MUL` instruction
	* \ingroup pico_platform
	*
	* This multiplies a by b using multiply instruction using the ARM mul instruction regardless of values (the compiler
	* might otherwise choose to perform shifts/adds), i.e. this is a 1 cycle operation.
	*
	* \param a the first operand
	* \param b the second operand
	* \return a * b
	*/
	__force_inline static int32_t __mul_instruction(int32_t a, int32_t b) {
	asm ("mul %0, %1" : "+l" (a) : "l" (b) : );
	return a;
	}

	/*! \brief multiply two integer values using the fastest method possible
	* \ingroup pico_platform
	*
	* Efficiently multiplies value a by possibly constant value b.
	*
	* If b is known to be constant and not zero or a power of 2, then a mul instruction is used rather than gcc's default
	* which is often a slow combination of shifts and adds. If b is a power of 2 then a single shift is of course preferable
	* and will be used
	*
	* \param a the first operand
	* \param b the second operand
	* \return a * b
	*/
	#define __fast_mul(a, b) __builtin_choose_expr(__builtin_constant_p(b) && !__builtin_constant_p(a), \
	(__builtin_popcount(b) >= 2 ? __mul_instruction(a,b) : (a)*(b)), \
	(a)*(b))

	/*! \brief Utility macro to assert two types are equivalent.
	* \ingroup pico_platform
	*
	* This macro can be useful in other macros along with `typeof` to assert that two parameters are of equivalent type
	* (or that a single parameter is of an expected type)
	*/
	#define __check_type_compatible(type_a, type_b) static_assert(__builtin_types_compatible_p(type_a, type_b), __STRING(type_a) " is not compatible with " __STRING(type_b));

	/*! \brief Get the current exception level on this core
	* \ingroup pico_platform
	*
	* \return the exception number if the CPU is handling an exception, or 0 otherwise
	*/
	uint __get_current_exception(void);

	#define WRAPPER_FUNC(x) __wrap_ ## x
	#define REAL_FUNC(x) __real_ ## x

	#ifdef __cplusplus
	}
	#endif

	#else // __ASSEMBLER__

	#define WRAPPER_FUNC_NAME(x) __wrap_##x
	#define SECTION_NAME(x) .text.##x
	#define RAM_SECTION_NAME(x) .time_critical.##x

	#endif // !__ASSEMBLER__

	#endif