newlib-cygwin/libgloss/xtensa/crt1-boards.S

// crt1-boards.S
//
// For most hardware / boards, this code sets up the C calling context
// (setting up stack, PS, and clearing BSS) and jumps to __clibrary_start
// which sets up the C library, calls constructors and registers destructors,
// and calls main().
//
// Control arrives here at _start from the reset vector or from crt0-app.S.

// Copyright (c) 1998-2013 Tensilica Inc.
//
// Permission is hereby granted, free of charge, to any person obtaining
// a copy of this software and associated documentation files (the
// "Software"), to deal in the Software without restriction, including
// without limitation the rights to use, copy, modify, merge, publish,
// distribute, sublicense, and/or sell copies of the Software, and to
// permit persons to whom the Software is furnished to do so, subject to
// the following conditions:
//
// The above copyright notice and this permission notice shall be included
// in all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
// IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
// CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
// TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
// SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

#include <xtensa/corebits.h>


// Exports
.global _start

// Imports
//   __clibrary_init		from C library (eg. newlib or uclibc)
//   exit			from C library
//   main			from user application
//   board_init			board-specific (uart/mingloss/tinygloss.c)
//   xthal_dcache_all_writeback	from HAL library
//   __stack			from linker script (see LSP Ref Manual)
//   __bss_start		from linker script (see LSP Ref Manual)
//   _end			from linker script (see LSP Ref Manual)

.type	main, @function

# define CALL	call4
# define CALLX	callx4
# define ARG1	a6	/* 1st outgoing call argument */
# define ARG2	a7	/* 2nd outgoing call argument */
# define ARG3	a8	/* 3rd outgoing call argument */
# define ARG4	a9	/* 4th outgoing call argument */
# define ARG5	a10	/* 5th outgoing call argument */


/**************************************************************************/

	.text
	.align 4
_start:
	//  _start is typically NOT at the beginning of the text segment --
	//  it is always called from either the reset vector or other code
	//  that does equivalent initialization (such as crt0-app.S).
	//
	//  Assumptions on entry to _start:
	//	- low (level-one) and medium priority interrupts are disabled
	//	  via PS.INTLEVEL and/or INTENABLE (PS.INTLEVEL is expected to
	//	  be zeroed, to potentially enable them, before calling main)
	//	- C calling context not initialized:
	//	  - PS not initialized
	//	  - SP not initialized
	//	- the following are initialized:
	//	  - LITBASE, cache attributes, WindowBase, WindowStart,
	//	    CPENABLE, FP's FCR and FSR, EXCSAVE[n]

	// Keep a0 zero.  It is used to initialize a few things.
	// It is also the return address, where zero indicates
	// that the frame used by _start is the bottommost frame.
	//

	movi	a0, 0		// keep this register zero.

	wsr	a0, INTENABLE	// INTENABLE value is not defined after reset.
				//make sure that interrupts are shut off (*before* we lower PS.INTLEVEL and PS.EXCM!)

	//  Windowed register init, so we can call windowed code (eg. C code).
	movi	a1, 1
	wsr	a1, WINDOWSTART
	//  The processor always clears WINDOWBASE at reset, so no need to clear it here.
	//  It resets WINDOWSTART to 1 starting with LX2.0/X7.0 (RB-2006.0).
	//  However, assuming hard reset is not yet always practical, so do this anyway:
	wsr	a0, WINDOWBASE
	rsync

	// Set VECBASE to use our vectors instead vectors in ROM
	movi	a1, _vector_table
	wsr	a1, VECBASE

	// Initialize the stack pointer.
	// See the "ABI and Software Conventions" chapter in the
	// Xtensa ISA Reference manual for details.

	// NOTE: Because the _start routine does not use any memory in its
	// stack frame, and because all of its CALL instructions use a
	// window size of 4 (or zero), the stack frame for _start can be empty.

	movi	sp, __stack

	/*
	 *  Now that sp (a1) is set, we can set PS as per the application
	 *  (user vector mode, enable interrupts, enable window exceptions if applicable).
	 */
	movi	a3, PS_UM|PS_WOE
	wsr	a3, PS
	rsync


	/*
	 *  Do any initialization that affects the memory map, such as
	 *  setting up TLB entries, that needs to be done before we can
	 *  successfully clear BSS (e.g. if some BSS segments are in
	 *  remapped areas).
	 *
	 *  NOTE:  This hook works where the reset vector does not unpack
	 *  segments (see "ROM packing" in the LSP manual), or where
	 *  unpacking of segments is not affected by memory remapping.
	 *  If ROM unpacking is affected, TLB setup must be done in
	 *  assembler from the reset vector.
	 *
	 *  The __memmap_init() routine can be a C function, however it
	 *  does not have BSS initialized!  In particular, __memmap_init()
	 *  cannot set BSS variables, i.e. uninitialized global variables
	 *  (they'll be wiped out by the following BSS clear), nor can it
	 *  assume they are yet initialized to zero.
	 *
	 *  The __memmap_init() function is optional.  It is marked as a
	 *  weak symbol, so that it gets valued zero if not defined.
	 */
	.weak	__memmap_init
	movi	a4, __memmap_init
	beqz	a4, 1f
	CALLX	a4
1:

	/*
	 *  Clear the BSS (uninitialized data) segments.
	 *  This code supports multiple zeroed sections (*.bss).
	 *
	 */
	movi	a6, __bss_start
	movi	a8, _end
	sub	a8, a8, a6
	movi	a7, 0
	CALL	memset

	/* init semihosting if has function */
	.weak __semihosting_init
	movi	a4, __semihosting_init
	beqz	a4, 2f
	CALLX	a4
2:

	//  We can now call C code, the C calling environment has been initialized.
	//
	//  From this point on, we use ABI-specific macros to refer to registers a0 .. a15
	//  (ARG#).


	.type	board_init, @function
	.type	__clibrary_init, @function
	.type	exit, @function


	//  Initialize the board (eg. UART, etc).
	CALL	board_init

	/*
	 *  Call __clibrary_init to initialize the C library:
	 *
	 *  void __clibrary_init(int argc, char ** argv, char ** environ,
	 *		void(*init_func)(void), void(*fini_func)(void));
	 */

	//  Pass an empty argv array, with an empty string as the program name.

	.weak _init
	.weak _fini
	movi	ARG1, _start_argc	// argc address
	movi	ARG2, _start_argv	// argv = ["", 0]
	movi	ARG3, _start_envp	// envp = [0]
	movi 	ARG4, _init		// function that calls constructors
	movi	ARG5, _fini		// function that calls destructors
	l32i	ARG1, ARG1, 0		// argc = 1
	CALL	__clibrary_init

	//  Call:   int main(int argc, char ** argv, char ** environ);
	movi	ARG1, _start_argc	// argc address
	movi	ARG2, _start_argv	// argv = ["", 0]
	movi	ARG3, _start_envp	// envp = [0]
	l32i	ARG1, ARG1, 0		// argc = 1
	CALL	main
	//  The return value is the same register as the first outgoing argument.
	CALL	exit			// exit with main's return value
	// Does not return here.

	.data
	//  Mark argc/argv/envp parameters as weak so that an external
	//  object file can override them.
	.weak	_start_argc, _start_argv, _start_envp
	.align	4
_start_argv:
	.word	_start_null	// empty program name
_start_null:
_start_envp:
	.word	0		// end of argv array, empty string, empty environ
_start_argc:
	.word	1		// one argument (program name)
	.text

	.size	_start, . - _start
libgloss: add Xtensa port Supported esp32 and esp32s2 boards: https://github.com/espressif/esp-toolchain-docs/blob/main/gcc/build-and-run-native-app.md 2023-08-09 04:07:04 +08:00			`// crt1-boards.S`
			`//`
			`// For most hardware / boards, this code sets up the C calling context`
			`// (setting up stack, PS, and clearing BSS) and jumps to __clibrary_start`
			`// which sets up the C library, calls constructors and registers destructors,`
			`// and calls main().`
			`//`
			`// Control arrives here at _start from the reset vector or from crt0-app.S.`

			`// Copyright (c) 1998-2013 Tensilica Inc.`
			`//`
			`// Permission is hereby granted, free of charge, to any person obtaining`
			`// a copy of this software and associated documentation files (the`
			`// "Software"), to deal in the Software without restriction, including`
			`// without limitation the rights to use, copy, modify, merge, publish,`
			`// distribute, sublicense, and/or sell copies of the Software, and to`
			`// permit persons to whom the Software is furnished to do so, subject to`
			`// the following conditions:`
			`//`
			`// The above copyright notice and this permission notice shall be included`
			`// in all copies or substantial portions of the Software.`
			`//`
			`// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,`
			`// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF`
			`// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.`
			`// IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY`
			`// CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,`
			`// TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE`
			`// SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.`

			`#include <xtensa/corebits.h>`


			`// Exports`
			`.global _start`

			`// Imports`
			`// __clibrary_init from C library (eg. newlib or uclibc)`
			`// exit from C library`
			`// main from user application`
			`// board_init board-specific (uart/mingloss/tinygloss.c)`
			`// xthal_dcache_all_writeback from HAL library`
			`// __stack from linker script (see LSP Ref Manual)`
			`// __bss_start from linker script (see LSP Ref Manual)`
			`// _end from linker script (see LSP Ref Manual)`

			`.type main, @function`

			`# define CALL call4`
			`# define CALLX callx4`
			`# define ARG1 a6 /* 1st outgoing call argument */`
			`# define ARG2 a7 /* 2nd outgoing call argument */`
			`# define ARG3 a8 /* 3rd outgoing call argument */`
			`# define ARG4 a9 /* 4th outgoing call argument */`
			`# define ARG5 a10 /* 5th outgoing call argument */`


			`/**************************************************************************/`

			`.text`
			`.align 4`
			`_start:`
			`// _start is typically NOT at the beginning of the text segment --`
			`// it is always called from either the reset vector or other code`
			`// that does equivalent initialization (such as crt0-app.S).`
			`//`
			`// Assumptions on entry to _start:`
			`// - low (level-one) and medium priority interrupts are disabled`
			`// via PS.INTLEVEL and/or INTENABLE (PS.INTLEVEL is expected to`
			`// be zeroed, to potentially enable them, before calling main)`
			`// - C calling context not initialized:`
			`// - PS not initialized`
			`// - SP not initialized`
			`// - the following are initialized:`
			`// - LITBASE, cache attributes, WindowBase, WindowStart,`
			`// CPENABLE, FP's FCR and FSR, EXCSAVE[n]`

			`// Keep a0 zero. It is used to initialize a few things.`
			`// It is also the return address, where zero indicates`
			`// that the frame used by _start is the bottommost frame.`
			`//`

			`movi a0, 0 // keep this register zero.`

			`wsr a0, INTENABLE // INTENABLE value is not defined after reset.`
			`//make sure that interrupts are shut off (before we lower PS.INTLEVEL and PS.EXCM!)`

			`// Windowed register init, so we can call windowed code (eg. C code).`
			`movi a1, 1`
			`wsr a1, WINDOWSTART`
			`// The processor always clears WINDOWBASE at reset, so no need to clear it here.`
			`// It resets WINDOWSTART to 1 starting with LX2.0/X7.0 (RB-2006.0).`
			`// However, assuming hard reset is not yet always practical, so do this anyway:`
			`wsr a0, WINDOWBASE`
			`rsync`

			`// Set VECBASE to use our vectors instead vectors in ROM`
			`movi a1, _vector_table`
			`wsr a1, VECBASE`

			`// Initialize the stack pointer.`
			`// See the "ABI and Software Conventions" chapter in the`
			`// Xtensa ISA Reference manual for details.`

			`// NOTE: Because the _start routine does not use any memory in its`
			`// stack frame, and because all of its CALL instructions use a`
			`// window size of 4 (or zero), the stack frame for _start can be empty.`

			`movi sp, __stack`

			`/*`
			`* Now that sp (a1) is set, we can set PS as per the application`
			`* (user vector mode, enable interrupts, enable window exceptions if applicable).`
			`*/`
			`movi a3, PS_UM\|PS_WOE`
			`wsr a3, PS`
			`rsync`


			`/*`
			`* Do any initialization that affects the memory map, such as`
			`* setting up TLB entries, that needs to be done before we can`
			`* successfully clear BSS (e.g. if some BSS segments are in`
			`* remapped areas).`
			`*`
			`* NOTE: This hook works where the reset vector does not unpack`
			`* segments (see "ROM packing" in the LSP manual), or where`
			`* unpacking of segments is not affected by memory remapping.`
			`* If ROM unpacking is affected, TLB setup must be done in`
			`* assembler from the reset vector.`
			`*`
			`* The __memmap_init() routine can be a C function, however it`
			`* does not have BSS initialized! In particular, __memmap_init()`
			`* cannot set BSS variables, i.e. uninitialized global variables`
			`* (they'll be wiped out by the following BSS clear), nor can it`
			`* assume they are yet initialized to zero.`
			`*`
			`* The __memmap_init() function is optional. It is marked as a`
			`* weak symbol, so that it gets valued zero if not defined.`
			`*/`
			`.weak __memmap_init`
			`movi a4, __memmap_init`
			`beqz a4, 1f`
			`CALLX a4`
			`1:`

			`/*`
			`* Clear the BSS (uninitialized data) segments.`
			`* This code supports multiple zeroed sections (*.bss).`
			`*`
			`*/`
			`movi a6, __bss_start`
			`movi a8, _end`
			`sub a8, a8, a6`
			`movi a7, 0`
			`CALL memset`

			`/* init semihosting if has function */`
			`.weak __semihosting_init`
			`movi a4, __semihosting_init`
			`beqz a4, 2f`
			`CALLX a4`
			`2:`

			`// We can now call C code, the C calling environment has been initialized.`
			`//`
			`// From this point on, we use ABI-specific macros to refer to registers a0 .. a15`
			`// (ARG#).`


			`.type board_init, @function`
			`.type __clibrary_init, @function`
			`.type exit, @function`


			`// Initialize the board (eg. UART, etc).`
			`CALL board_init`

			`/*`
			`* Call __clibrary_init to initialize the C library:`
			`*`
			`* void __clibrary_init(int argc, char argv, char environ,`
			`* void(init_func)(void), void(fini_func)(void));`
			`*/`

			`// Pass an empty argv array, with an empty string as the program name.`

			`.weak _init`
			`.weak _fini`
			`movi ARG1, _start_argc // argc address`
			`movi ARG2, _start_argv // argv = ["", 0]`
			`movi ARG3, _start_envp // envp = [0]`
			`movi ARG4, _init // function that calls constructors`
			`movi ARG5, _fini // function that calls destructors`
			`l32i ARG1, ARG1, 0 // argc = 1`
			`CALL __clibrary_init`

			`// Call: int main(int argc, char argv, char environ);`
			`movi ARG1, _start_argc // argc address`
			`movi ARG2, _start_argv // argv = ["", 0]`
			`movi ARG3, _start_envp // envp = [0]`
			`l32i ARG1, ARG1, 0 // argc = 1`
			`CALL main`
			`// The return value is the same register as the first outgoing argument.`
			`CALL exit // exit with main's return value`
			`// Does not return here.`

			`.data`
			`// Mark argc/argv/envp parameters as weak so that an external`
			`// object file can override them.`
			`.weak _start_argc, _start_argv, _start_envp`
			`.align 4`
			`_start_argv:`
			`.word _start_null // empty program name`
			`_start_null:`
			`_start_envp:`
			`.word 0 // end of argv array, empty string, empty environ`
			`_start_argc:`
			`.word 1 // one argument (program name)`
			`.text`

			`.size _start, . - _start`