src/kernel/linux/v4.19/arch/arm/nwfpe/entry.S - T800 - Gitiles

 /*
     NetWinder Floating Point Emulator
     (c) Rebel.COM, 1998
     (c) 1998, 1999 Philip Blundell

     Direct questions, comments to Scott Bambrough <scottb@netwinder.org>

     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; either version 2 of the License, or
     (at your option) any later version.

     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.  See the
     GNU General Public License for more details.

     You should have received a copy of the GNU General Public License
     along with this program; if not, write to the Free Software
     Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 */
 #include <asm/assembler.h>
 #include <asm/opcodes.h>

 /* This is the kernel's entry point into the floating point emulator.
 It is called from the kernel with code similar to this:

 	sub	r4, r5, #4
 	ldrt	r0, [r4]			@ r0  = instruction
 	adrsvc	al, r9, ret_from_exception	@ r9  = normal FP return
 	adrsvc	al, lr, fpundefinstr		@ lr  = undefined instr return

 	get_current_task r10
 	mov	r8, #1
 	strb	r8, [r10, #TSK_USED_MATH]	@ set current->used_math
 	add	r10, r10, #TSS_FPESAVE		@ r10 = workspace
 	ldr	r4, .LC2
 	ldr	pc, [r4]			@ Call FP emulator entry point

 The kernel expects the emulator to return via one of two possible
 points of return it passes to the emulator.  The emulator, if
 successful in its emulation, jumps to ret_from_exception (passed in
 r9) and the kernel takes care of returning control from the trap to
 the user code.  If the emulator is unable to emulate the instruction,
 it returns via _fpundefinstr (passed via lr) and the kernel halts the
 user program with a core dump.

 On entry to the emulator r10 points to an area of private FP workspace
 reserved in the thread structure for this process.  This is where the
 emulator saves its registers across calls.  The first word of this area
 is used as a flag to detect the first time a process uses floating point,
 so that the emulator startup cost can be avoided for tasks that don't
 want it.

 This routine does three things:

 1) The kernel has created a struct pt_regs on the stack and saved the
 user registers into it.  See /usr/include/asm/proc/ptrace.h for details.

 2) It calls EmulateAll to emulate a floating point instruction.
 EmulateAll returns 1 if the emulation was successful, or 0 if not.

 3) If an instruction has been emulated successfully, it looks ahead at
 the next instruction.  If it is a floating point instruction, it
 executes the instruction, without returning to user space.  In this
 way it repeatedly looks ahead and executes floating point instructions
 until it encounters a non floating point instruction, at which time it
 returns via _fpreturn.

 This is done to reduce the effect of the trap overhead on each
 floating point instructions.  GCC attempts to group floating point
 instructions to allow the emulator to spread the cost of the trap over
 several floating point instructions.  */

 #include <asm/asm-offsets.h>

 	.globl	nwfpe_enter
 nwfpe_enter:
 	mov	r4, lr			@ save the failure-return addresses
 	mov	sl, sp			@ we access the registers via 'sl'

 	ldr	r5, [sp, #S_PC]		@ get contents of PC;
 	mov	r6, r0			@ save the opcode
 emulate:
 	ldr	r1, [sp, #S_PSR]	@ fetch the PSR
 	bl	arm_check_condition	@ check the condition
 	cmp	r0, #ARM_OPCODE_CONDTEST_PASS	@ condition passed?

 	@ if condition code failed to match, next insn
 	bne	next			@ get the next instruction;

 	mov	r0, r6			@ prepare for EmulateAll()
 	bl	EmulateAll		@ emulate the instruction
 	cmp	r0, #0			@ was emulation successful
 	reteq	r4			@ no, return failure

 next:
 	uaccess_enable r3
 .Lx1:	ldrt	r6, [r5], #4		@ get the next instruction and
 					@ increment PC
 	uaccess_disable r3
 	and	r2, r6, #0x0F000000	@ test for FP insns
 	teq	r2, #0x0C000000
 	teqne	r2, #0x0D000000
 	teqne	r2, #0x0E000000
 	retne	r9			@ return ok if not a fp insn

 	str	r5, [sp, #S_PC]		@ update PC copy in regs

 	mov	r0, r6			@ save a copy
 	b	emulate			@ check condition and emulate

 	@ We need to be prepared for the instructions at .Lx1 and .Lx2
 	@ to fault.  Emit the appropriate exception gunk to fix things up.
 	@ ??? For some reason, faults can happen at .Lx2 even with a
 	@ plain LDR instruction.  Weird, but it seems harmless.
 	.pushsection .text.fixup,"ax"
 	.align	2
 .Lfix:	ret	r9			@ let the user eat segfaults
 	.popsection

 	.pushsection __ex_table,"a"
 	.align	3
 	.long	.Lx1, .Lfix
 	.popsection
	/*
	NetWinder Floating Point Emulator
	(c) Rebel.COM, 1998
	(c) 1998, 1999 Philip Blundell

	Direct questions, comments to Scott Bambrough <scottb@netwinder.org>

	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; either version 2 of the License, or
	(at your option) any later version.

	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. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program; if not, write to the Free Software
	Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
	*/
	#include <asm/assembler.h>
	#include <asm/opcodes.h>

	/* This is the kernel's entry point into the floating point emulator.
	It is called from the kernel with code similar to this:

	sub r4, r5, #4
	ldrt r0, [r4] @ r0 = instruction
	adrsvc al, r9, ret_from_exception @ r9 = normal FP return
	adrsvc al, lr, fpundefinstr @ lr = undefined instr return

	get_current_task r10
	mov r8, #1
	strb r8, [r10, #TSK_USED_MATH] @ set current->used_math
	add r10, r10, #TSS_FPESAVE @ r10 = workspace
	ldr r4, .LC2
	ldr pc, [r4] @ Call FP emulator entry point

	The kernel expects the emulator to return via one of two possible
	points of return it passes to the emulator. The emulator, if
	successful in its emulation, jumps to ret_from_exception (passed in
	r9) and the kernel takes care of returning control from the trap to
	the user code. If the emulator is unable to emulate the instruction,
	it returns via _fpundefinstr (passed via lr) and the kernel halts the
	user program with a core dump.

	On entry to the emulator r10 points to an area of private FP workspace
	reserved in the thread structure for this process. This is where the
	emulator saves its registers across calls. The first word of this area
	is used as a flag to detect the first time a process uses floating point,
	so that the emulator startup cost can be avoided for tasks that don't
	want it.

	This routine does three things:

	1) The kernel has created a struct pt_regs on the stack and saved the
	user registers into it. See /usr/include/asm/proc/ptrace.h for details.

	2) It calls EmulateAll to emulate a floating point instruction.
	EmulateAll returns 1 if the emulation was successful, or 0 if not.

	3) If an instruction has been emulated successfully, it looks ahead at
	the next instruction. If it is a floating point instruction, it
	executes the instruction, without returning to user space. In this
	way it repeatedly looks ahead and executes floating point instructions
	until it encounters a non floating point instruction, at which time it
	returns via _fpreturn.

	This is done to reduce the effect of the trap overhead on each
	floating point instructions. GCC attempts to group floating point
	instructions to allow the emulator to spread the cost of the trap over
	several floating point instructions. */

	#include <asm/asm-offsets.h>

	.globl nwfpe_enter
	nwfpe_enter:
	mov r4, lr @ save the failure-return addresses
	mov sl, sp @ we access the registers via 'sl'

	ldr r5, [sp, #S_PC] @ get contents of PC;
	mov r6, r0 @ save the opcode
	emulate:
	ldr r1, [sp, #S_PSR] @ fetch the PSR
	bl arm_check_condition @ check the condition
	cmp r0, #ARM_OPCODE_CONDTEST_PASS @ condition passed?

	@ if condition code failed to match, next insn
	bne next @ get the next instruction;

	mov r0, r6 @ prepare for EmulateAll()
	bl EmulateAll @ emulate the instruction
	cmp r0, #0 @ was emulation successful
	reteq r4 @ no, return failure

	next:
	uaccess_enable r3
	.Lx1: ldrt r6, [r5], #4 @ get the next instruction and
	@ increment PC
	uaccess_disable r3
	and r2, r6, #0x0F000000 @ test for FP insns
	teq r2, #0x0C000000
	teqne r2, #0x0D000000
	teqne r2, #0x0E000000
	retne r9 @ return ok if not a fp insn

	str r5, [sp, #S_PC] @ update PC copy in regs

	mov r0, r6 @ save a copy
	b emulate @ check condition and emulate

	@ We need to be prepared for the instructions at .Lx1 and .Lx2
	@ to fault. Emit the appropriate exception gunk to fix things up.
	@ ??? For some reason, faults can happen at .Lx2 even with a
	@ plain LDR instruction. Weird, but it seems harmless.
	.pushsection .text.fixup,"ax"
	.align 2
	.Lfix: ret r9 @ let the user eat segfaults
	.popsection

	.pushsection __ex_table,"a"
	.align 3
	.long .Lx1, .Lfix
	.popsection