arch/tile/kernel/entry.S - pub/scm/linux/kernel/git/joro/linux - Git at Google

 /*
  * Copyright 2010 Tilera Corporation. All Rights Reserved.
  *
  *   This program is free software; you can redistribute it and/or
  *   modify it under the terms of the GNU General Public License
  *   as published by the Free Software Foundation, version 2.
  *
  *   This program is distributed in the hope that it will be useful, but
  *   WITHOUT ANY WARRANTY; without even the implied warranty of
  *   MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
  *   NON INFRINGEMENT.  See the GNU General Public License for
  *   more details.
  */

 #include <linux/linkage.h>
 #include <linux/unistd.h>
 #include <asm/irqflags.h>
 #include <arch/abi.h>

 #ifdef __tilegx__
 #define bnzt bnezt
 #endif

 STD_ENTRY(current_text_addr)
 	{ move r0, lr; jrp lr }
 	STD_ENDPROC(current_text_addr)

 STD_ENTRY(_sim_syscall)
 	/*
 	 * Wait for r0-r9 to be ready (and lr on the off chance we
 	 * want the syscall to locate its caller), then make a magic
 	 * simulator syscall.
 	 *
 	 * We carefully stall until the registers are readable in case they
 	 * are the target of a slow load, etc. so that tile-sim will
 	 * definitely be able to read all of them inside the magic syscall.
 	 *
 	 * Technically this is wrong for r3-r9 and lr, since an interrupt
 	 * could come in and restore the registers with a slow load right
 	 * before executing the mtspr. We may need to modify tile-sim to
 	 * explicitly stall for this case, but we do not yet have
 	 * a way to implement such a stall.
 	 */
 	{ and zero, lr, r9 ; and zero, r8, r7 }
 	{ and zero, r6, r5 ; and zero, r4, r3 }
 	{ and zero, r2, r1 ; mtspr SIM_CONTROL, r0 }
 	{ jrp lr }
 	STD_ENDPROC(_sim_syscall)

 /*
  * Implement execve().  The i386 code has a note that forking from kernel
  * space results in no copy on write until the execve, so we should be
  * careful not to write to the stack here.
  */
 STD_ENTRY(kernel_execve)
 	moveli TREG_SYSCALL_NR_NAME, __NR_execve
 	swint1
 	jrp lr
 	STD_ENDPROC(kernel_execve)

 /* Delay a fixed number of cycles. */
 STD_ENTRY(__delay)
 	{ addi r0, r0, -1; bnzt r0, . }
 	jrp lr
 	STD_ENDPROC(__delay)

 /*
  * We don't run this function directly, but instead copy it to a page
  * we map into every user process.  See vdso_setup().
  *
  * Note that libc has a copy of this function that it uses to compare
  * against the PC when a stack backtrace ends, so if this code is
  * changed, the libc implementation(s) should also be updated.
  */
 	.pushsection .data
 ENTRY(__rt_sigreturn)
 	moveli TREG_SYSCALL_NR_NAME,__NR_rt_sigreturn
 	swint1
 	ENDPROC(__rt_sigreturn)
 	ENTRY(__rt_sigreturn_end)
 	.popsection

 STD_ENTRY(dump_stack)
 	{ move r2, lr; lnk r1 }
 	{ move r4, r52; addli r1, r1, dump_stack - . }
 	{ move r3, sp; j _dump_stack }
 	jrp lr   /* keep backtracer happy */
 	STD_ENDPROC(dump_stack)

 STD_ENTRY(KBacktraceIterator_init_current)
 	{ move r2, lr; lnk r1 }
 	{ move r4, r52; addli r1, r1, KBacktraceIterator_init_current - . }
 	{ move r3, sp; j _KBacktraceIterator_init_current }
 	jrp lr   /* keep backtracer happy */
 	STD_ENDPROC(KBacktraceIterator_init_current)

 /*
  * Reset our stack to r1/r2 (sp and ksp0+cpu respectively), then
  * free the old stack (passed in r0) and re-invoke cpu_idle().
  * We update sp and ksp0 simultaneously to avoid backtracer warnings.
  */
 STD_ENTRY(cpu_idle_on_new_stack)
 	{
 	 move sp, r1
 	 mtspr SYSTEM_SAVE_1_0, r2
 	}
 	jal free_thread_info
 	j cpu_idle
 	STD_ENDPROC(cpu_idle_on_new_stack)

 /* Loop forever on a nap during SMP boot. */
 STD_ENTRY(smp_nap)
 	nap
 	j smp_nap /* we are not architecturally guaranteed not to exit nap */
 	jrp lr    /* clue in the backtracer */
 	STD_ENDPROC(smp_nap)

 /*
  * Enable interrupts racelessly and then nap until interrupted.
  * This function's _cpu_idle_nap address is special; see intvec.S.
  * When interrupted at _cpu_idle_nap, we bump the PC forward 8, and
  * as a result return to the function that called _cpu_idle().
  */
 STD_ENTRY(_cpu_idle)
 	{
 	 lnk r0
 	 movei r1, 1
 	}
 	{
 	 addli r0, r0, _cpu_idle_nap - .
 	 mtspr INTERRUPT_CRITICAL_SECTION, r1
 	}
 	IRQ_ENABLE(r2, r3)         /* unmask, but still with ICS set */
 	mtspr EX_CONTEXT_1_1, r1   /* PL1, ICS clear */
 	mtspr EX_CONTEXT_1_0, r0
 	iret
 	.global _cpu_idle_nap
 _cpu_idle_nap:
 	nap
 	jrp lr
 	STD_ENDPROC(_cpu_idle)
	/*
	* Copyright 2010 Tilera Corporation. All Rights Reserved.
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License
	* as published by the Free Software Foundation, version 2.
	*
	* This program is distributed in the hope that it will be useful, but
	* WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
	* NON INFRINGEMENT. See the GNU General Public License for
	* more details.
	*/

	#include <linux/linkage.h>
	#include <linux/unistd.h>
	#include <asm/irqflags.h>
	#include <arch/abi.h>

	#ifdef __tilegx__
	#define bnzt bnezt
	#endif

	STD_ENTRY(current_text_addr)
	{ move r0, lr; jrp lr }
	STD_ENDPROC(current_text_addr)

	STD_ENTRY(_sim_syscall)
	/*
	* Wait for r0-r9 to be ready (and lr on the off chance we
	* want the syscall to locate its caller), then make a magic
	* simulator syscall.
	*
	* We carefully stall until the registers are readable in case they
	* are the target of a slow load, etc. so that tile-sim will
	* definitely be able to read all of them inside the magic syscall.
	*
	* Technically this is wrong for r3-r9 and lr, since an interrupt
	* could come in and restore the registers with a slow load right
	* before executing the mtspr. We may need to modify tile-sim to
	* explicitly stall for this case, but we do not yet have
	* a way to implement such a stall.
	*/
	{ and zero, lr, r9 ; and zero, r8, r7 }
	{ and zero, r6, r5 ; and zero, r4, r3 }
	{ and zero, r2, r1 ; mtspr SIM_CONTROL, r0 }
	{ jrp lr }
	STD_ENDPROC(_sim_syscall)

	/*
	* Implement execve(). The i386 code has a note that forking from kernel
	* space results in no copy on write until the execve, so we should be
	* careful not to write to the stack here.
	*/
	STD_ENTRY(kernel_execve)
	moveli TREG_SYSCALL_NR_NAME, __NR_execve
	swint1
	jrp lr
	STD_ENDPROC(kernel_execve)

	/* Delay a fixed number of cycles. */
	STD_ENTRY(__delay)
	{ addi r0, r0, -1; bnzt r0, . }
	jrp lr
	STD_ENDPROC(__delay)

	/*
	* We don't run this function directly, but instead copy it to a page
	* we map into every user process. See vdso_setup().
	*
	* Note that libc has a copy of this function that it uses to compare
	* against the PC when a stack backtrace ends, so if this code is
	* changed, the libc implementation(s) should also be updated.
	*/
	.pushsection .data
	ENTRY(__rt_sigreturn)
	moveli TREG_SYSCALL_NR_NAME,__NR_rt_sigreturn
	swint1
	ENDPROC(__rt_sigreturn)
	ENTRY(__rt_sigreturn_end)
	.popsection

	STD_ENTRY(dump_stack)
	{ move r2, lr; lnk r1 }
	{ move r4, r52; addli r1, r1, dump_stack - . }
	{ move r3, sp; j _dump_stack }
	jrp lr /* keep backtracer happy */
	STD_ENDPROC(dump_stack)

	STD_ENTRY(KBacktraceIterator_init_current)
	{ move r2, lr; lnk r1 }
	{ move r4, r52; addli r1, r1, KBacktraceIterator_init_current - . }
	{ move r3, sp; j _KBacktraceIterator_init_current }
	jrp lr /* keep backtracer happy */
	STD_ENDPROC(KBacktraceIterator_init_current)

	/*
	* Reset our stack to r1/r2 (sp and ksp0+cpu respectively), then
	* free the old stack (passed in r0) and re-invoke cpu_idle().
	* We update sp and ksp0 simultaneously to avoid backtracer warnings.
	*/
	STD_ENTRY(cpu_idle_on_new_stack)
	{
	move sp, r1
	mtspr SYSTEM_SAVE_1_0, r2
	}
	jal free_thread_info
	j cpu_idle
	STD_ENDPROC(cpu_idle_on_new_stack)

	/* Loop forever on a nap during SMP boot. */
	STD_ENTRY(smp_nap)
	nap
	j smp_nap /* we are not architecturally guaranteed not to exit nap */
	jrp lr /* clue in the backtracer */
	STD_ENDPROC(smp_nap)

	/*
	* Enable interrupts racelessly and then nap until interrupted.
	* This function's _cpu_idle_nap address is special; see intvec.S.
	* When interrupted at _cpu_idle_nap, we bump the PC forward 8, and
	* as a result return to the function that called _cpu_idle().
	*/
	STD_ENTRY(_cpu_idle)
	{
	lnk r0
	movei r1, 1
	}
	{
	addli r0, r0, _cpu_idle_nap - .
	mtspr INTERRUPT_CRITICAL_SECTION, r1
	}
	IRQ_ENABLE(r2, r3) /* unmask, but still with ICS set */
	mtspr EX_CONTEXT_1_1, r1 /* PL1, ICS clear */
	mtspr EX_CONTEXT_1_0, r0
	iret
	.global _cpu_idle_nap
	_cpu_idle_nap:
	nap
	jrp lr
	STD_ENDPROC(_cpu_idle)