libgcc/config/microblaze/moddi3.S - gcc - Git at Google

 ###################################
 #
 #  Copyright (C) 2009-2021 Free Software Foundation, Inc.
 #
 #  Contributed by Michael Eager <eager@eagercon.com>.
 #
 #  This file 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 3, or (at your option) any
 #  later version.
 #
 #  GCC 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.
 #
 #  Under Section 7 of GPL version 3, you are granted additional
 #  permissions described in the GCC Runtime Library Exception, version
 #  3.1, as published by the Free Software Foundation.
 #
 #  You should have received a copy of the GNU General Public License and
 #  a copy of the GCC Runtime Library Exception along with this program;
 #  see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
 #  <http://www.gnu.org/licenses/>.
 #
 #  modsi3.S
 #
 #  modulo operation for 64 bit integers.
 #
 #######################################


 /* An executable stack is *not* required for these functions.  */
 #ifdef __linux__
 .section .note.GNU-stack,"",%progbits
 .previous
 #endif

 	.globl	__moddi3
 	.ent	__moddi3
 __moddi3:
 	.frame	r1,0,r15

 #Change the stack pointer value and Save callee saved regs
 	addik	r1,r1,-24
 	swi	r25,r1,0
 	swi	r26,r1,4
 	swi	r27,r1,8	# used for sign
 	swi	r28,r1,12	# used for loop count
 	swi	r29,r1,16	# Used for div value High
 	swi	r30,r1,20	# Used for div value Low

 #Check for Zero Value in the divisor/dividend
 	OR	r9,r5,r6			# Check for the op1 being zero
 	BEQID	r9,$LaResult_Is_Zero		# Result is zero
 	OR	r9,r7,r8			# Check for the dividend being zero
 	BEQI	r9,$LaDiv_By_Zero	        # Div_by_Zero   # Division Error
 	BGEId	r5,$La1_Pos
 	XOR	r27,r5,r7			# Get the sign of the result
 	RSUBI	r6,r6,0				# Make dividend positive
 	RSUBIC	r5,r5,0				# Make dividend positive
 $La1_Pos:
 	BGEI	r7,$La2_Pos
 	RSUBI	r8,r8,0				# Make Divisor Positive
 	RSUBIC	r9,r9,0				# Make Divisor Positive
 $La2_Pos:
 	ADDIK	r4,r0,0				# Clear mod low
 	ADDIK	r3,r0,0                	        # Clear mod high
 	ADDIK	r29,r0,0			# clear div high
 	ADDIK	r30,r0,0			# clear div low
 	ADDIK	r28,r0,64			# Initialize the loop count
    # First part try to find the first '1' in the r5/r6
 $LaDIV1:
 	ADD	r6,r6,r6
 	ADDC	r5,r5,r5			# left shift logical r5
 	BGEID	r5,$LaDIV1
 	ADDIK	r28,r28,-1
 $LaDIV2:
 	ADD	r6,r6,r6
 	ADDC	r5,r5,r5	# left shift logical r5/r6 get the '1' into the Carry
 	ADDC	r4,r4,r4	# Move that bit into the Mod register
 	ADDC	r3,r3,r3	# Move carry into high mod register
 	rsub	r18,r7,r3	# Compare the High Parts of Mod and Divisor
 	bnei	r18,$L_High_EQ
 	rsub	r18,r6,r4	# Compare Low Parts only if Mod[h] == Divisor[h]
 $L_High_EQ:
 	rSUB	r26,r8,r4	# Subtract divisor[L] from Mod[L]
 	rsubc	r25,r7,r3	# Subtract divisor[H] from Mod[H]
 	BLTi	r25,$LaMOD_TOO_SMALL
 	OR	r3,r0,r25	# move r25 to mod [h]
 	OR	r4,r0,r26	# move r26 to mod [l]
 	ADDI	r30,r30,1
 	ADDC	r29,r29,r0
 $LaMOD_TOO_SMALL:
 	ADDIK	r28,r28,-1
 	BEQi	r28,$LaLOOP_END
 	ADD	r30,r30,r30		# Shift in the '1' into div [low]
 	ADDC	r29,r29,r29		# Move the carry generated into high
 	BRI	$LaDIV2   # Div2
 $LaLOOP_END:
 	BGEI	r27,$LaRETURN_HERE
 	rsubi	r30,r30,0
 	rsubc	r29,r29,r0
 	BRI	$LaRETURN_HERE
 $LaDiv_By_Zero:
 $LaResult_Is_Zero:
 	or	r29,r0,r0	# set result to 0 [High]
 	or	r30,r0,r0	# set result to 0 [Low]
 $LaRETURN_HERE:
 # Restore values of CSRs and that of r29 and the divisor and the dividend

 	lwi	r25,r1,0
 	lwi	r26,r1,4
 	lwi	r27,r1,8
 	lwi	r28,r1,12
 	lwi	r29,r1,16
 	lwi	r30,r1,20
 	rtsd	r15,8
 	addik r1,r1,24
         .end __moddi3
	###################################
	#
	# Copyright (C) 2009-2021 Free Software Foundation, Inc.
	#
	# Contributed by Michael Eager <eager@eagercon.com>.
	#
	# This file 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 3, or (at your option) any
	# later version.
	#
	# GCC 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.
	#
	# Under Section 7 of GPL version 3, you are granted additional
	# permissions described in the GCC Runtime Library Exception, version
	# 3.1, as published by the Free Software Foundation.
	#
	# You should have received a copy of the GNU General Public License and
	# a copy of the GCC Runtime Library Exception along with this program;
	# see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
	# <http://www.gnu.org/licenses/>.
	#
	# modsi3.S
	#
	# modulo operation for 64 bit integers.
	#
	#######################################


	/* An executable stack is not required for these functions. */
	#ifdef __linux__
	.section .note.GNU-stack,"",%progbits
	.previous
	#endif

	.globl __moddi3
	.ent __moddi3
	__moddi3:
	.frame r1,0,r15

	#Change the stack pointer value and Save callee saved regs
	addik r1,r1,-24
	swi r25,r1,0
	swi r26,r1,4
	swi r27,r1,8 # used for sign
	swi r28,r1,12 # used for loop count
	swi r29,r1,16 # Used for div value High
	swi r30,r1,20 # Used for div value Low

	#Check for Zero Value in the divisor/dividend
	OR r9,r5,r6 # Check for the op1 being zero
	BEQID r9,$LaResult_Is_Zero # Result is zero
	OR r9,r7,r8 # Check for the dividend being zero
	BEQI r9,$LaDiv_By_Zero # Div_by_Zero # Division Error
	BGEId r5,$La1_Pos
	XOR r27,r5,r7 # Get the sign of the result
	RSUBI r6,r6,0 # Make dividend positive
	RSUBIC r5,r5,0 # Make dividend positive
	$La1_Pos:
	BGEI r7,$La2_Pos
	RSUBI r8,r8,0 # Make Divisor Positive
	RSUBIC r9,r9,0 # Make Divisor Positive
	$La2_Pos:
	ADDIK r4,r0,0 # Clear mod low
	ADDIK r3,r0,0 # Clear mod high
	ADDIK r29,r0,0 # clear div high
	ADDIK r30,r0,0 # clear div low
	ADDIK r28,r0,64 # Initialize the loop count
	# First part try to find the first '1' in the r5/r6
	$LaDIV1:
	ADD r6,r6,r6
	ADDC r5,r5,r5 # left shift logical r5
	BGEID r5,$LaDIV1
	ADDIK r28,r28,-1
	$LaDIV2:
	ADD r6,r6,r6
	ADDC r5,r5,r5 # left shift logical r5/r6 get the '1' into the Carry
	ADDC r4,r4,r4 # Move that bit into the Mod register
	ADDC r3,r3,r3 # Move carry into high mod register
	rsub r18,r7,r3 # Compare the High Parts of Mod and Divisor
	bnei r18,$L_High_EQ
	rsub r18,r6,r4 # Compare Low Parts only if Mod[h] == Divisor[h]
	$L_High_EQ:
	rSUB r26,r8,r4 # Subtract divisor[L] from Mod[L]
	rsubc r25,r7,r3 # Subtract divisor[H] from Mod[H]
	BLTi r25,$LaMOD_TOO_SMALL
	OR r3,r0,r25 # move r25 to mod [h]
	OR r4,r0,r26 # move r26 to mod [l]
	ADDI r30,r30,1
	ADDC r29,r29,r0
	$LaMOD_TOO_SMALL:
	ADDIK r28,r28,-1
	BEQi r28,$LaLOOP_END
	ADD r30,r30,r30 # Shift in the '1' into div [low]
	ADDC r29,r29,r29 # Move the carry generated into high
	BRI $LaDIV2 # Div2
	$LaLOOP_END:
	BGEI r27,$LaRETURN_HERE
	rsubi r30,r30,0
	rsubc r29,r29,r0
	BRI $LaRETURN_HERE
	$LaDiv_By_Zero:
	$LaResult_Is_Zero:
	or r29,r0,r0 # set result to 0 [High]
	or r30,r0,r0 # set result to 0 [Low]
	$LaRETURN_HERE:
	# Restore values of CSRs and that of r29 and the divisor and the dividend

	lwi r25,r1,0
	lwi r26,r1,4
	lwi r27,r1,8
	lwi r28,r1,12
	lwi r29,r1,16
	lwi r30,r1,20
	rtsd r15,8
	addik r1,r1,24
	.end __moddi3