sysdeps/unix/sysv/linux/ia64/__longjmp.S - nest-cam/v366/glibc - Git at Google

 /* Copyright (C) 1999, 2000, 2001, 2005 Free Software Foundation, Inc.
    Contributed by David Mosberger-Tang <davidm@hpl.hp.com>.

    The GNU C Library is free software; you can redistribute it and/or
    modify it under the terms of the GNU Lesser General Public
    License as published by the Free Software Foundation; either
    version 2.1 of the License, or (at your option) any later version.

    The GNU C Library 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
    Lesser General Public License for more details.

    You should have received a copy of the GNU Lesser General Public
    License along with the GNU C Library; if not, write to the Free
    Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
    02111-1307 USA.

    Note that __sigsetjmp() did NOT flush the register stack.  Instead,
    we do it here since __longjmp() is usually much less frequently
    invoked than __sigsetjmp(). The only difficulty is that __sigsetjmp()
    didn't (and wouldn't be able to) save ar.rnat either.  This is a problem
    because if we're not careful, we could end up loading random NaT bits.
    There are two cases:

 	(i)  ar.bsp < ia64_rse_rnat_addr(jmpbuf.ar_bsp)
 		ar.rnat contains the desired bits---preserve ar.rnat
 		across loadrs and write to ar.bspstore

 	(ii) ar.bsp >= ia64_rse_rnat_addr(jmpbuf.ar_bsp)
 		The desired ar.rnat is stored in
 		ia64_rse_rnat_addr(jmpbuf.ar_bsp).  Load those
 		bits into ar.rnat after setting ar.bspstore. */

 #include <sysdep.h>
 #include <features.h>

 #	define	pPos	p6	/* is rotate count positive? */
 #	define	pNeg	p7	/* is rotate count negative? */


 	/* __longjmp(__jmp_buf buf, int val) */

 LEAF(__longjmp)
 #ifdef CHECK_RSP
 	alloc r8=ar.pfs,2,1,1,0
 #else
 	alloc r8=ar.pfs,2,1,0,0
 #endif
 	mov r27=ar.rsc
 	add r2=0x98,in0		// r2 <- &jmpbuf.orig_jmp_buf_addr
 	;;
 	ld8 r8=[r2],-16		// r8 <- orig_jmp_buf_addr
 	mov r10=ar.bsp
 	and r11=~0x3,r27	// clear ar.rsc.mode
 	;;
 	flushrs			// flush dirty regs to backing store (must be first in insn grp)
 	ld8 r23=[r2],8		// r23 <- jmpbuf.ar_bsp
 	sub r8=r8,in0		// r8 <- &orig_jmpbuf - &jmpbuf
 	;;
 	ld8 r25=[r2]		// r25 <- jmpbuf.ar_unat
 	extr.u r8=r8,3,6	// r8 <- (&orig_jmpbuf - &jmpbuf)/8 & 0x3f
 	;;
 	cmp.lt pNeg,pPos=r8,r0
 	mov r2=in0
 	;;
 (pPos)	mov r16=r8
 (pNeg)	add r16=64,r8
 (pPos)	sub r17=64,r8
 (pNeg)	sub r17=r0,r8
 	;;
 	mov ar.rsc=r11		// put RSE in enforced lazy mode
 	shr.u r8=r25,r16
 	add r3=8,in0		// r3 <- &jmpbuf.r1
 	shl r9=r25,r17
 	;;
 	ld8.fill.nta r28=[r2],16	// r28 <- jmpbuf.sp
 	or r25=r8,r9
 	;;
 	mov r26=ar.rnat
 	mov ar.unat=r25		// setup ar.unat (NaT bits for r1, r4-r7, and r12)
 	;;
 #ifdef CHECK_RSP
 	CHECK_RSP (r28)
 #endif
 	ld8.fill.nta gp=[r3],16		// r1 (gp)
 	dep r11=-1,r23,3,6	// r11 <- ia64_rse_rnat_addr(jmpbuf.ar_bsp)
 	mov sp=r28		// r12 (sp)
 	;;
 	ld8.nta r16=[r2],16		// caller's unat
 	ld8.nta r17=[r3],16		// fpsr
 	;;
 	ld8.fill.nta r4=[r2],16	// r4
 	ld8.fill.nta r5=[r3],16		// r5 (gp)
 	cmp.geu p8,p0=r10,r11	// p8 <- (ar.bsp >= jmpbuf.ar_bsp)
 	;;
 	ld8.fill.nta r6=[r2],16	// r6
 	ld8.fill.nta r7=[r3],16		// r7
 	;;
 	mov ar.unat=r16			// restore caller's unat
 	mov ar.fpsr=r17			// restore fpsr
 	;;
 	ld8.nta r16=[r2],16		// b0
 	ld8.nta r17=[r3],16		// b1
 	;;
 (p8)	ld8 r26=[r11]		// r26 <- *ia64_rse_rnat_addr(jmpbuf.ar_bsp)
 	mov ar.bspstore=r23	// restore ar.bspstore
 	;;
 	ld8.nta r18=[r2],16		// b2
 	ld8.nta r19=[r3],16		// b3
 	;;
 #ifdef PTR_DEMANGLE
 	PTR_DEMANGLE (r16, r24)
 #endif
 	ld8.nta r20=[r2],16		// b4
 	ld8.nta r21=[r3],16		// b5
 	;;
 	ld8.nta r11=[r2],16		// ar.pfs
 	ld8.nta r22=[r3],56		// ar.lc
 	;;
 	ld8.nta r24=[r2],32		// pr
 	mov b0=r16
 	;;
 	ldf.fill.nta f2=[r2],32
 	ldf.fill.nta f3=[r3],32
 	mov b1=r17
 	;;
 	ldf.fill.nta f4=[r2],32
 	ldf.fill.nta f5=[r3],32
 	mov b2=r18
 	;;
 	ldf.fill.nta f16=[r2],32
 	ldf.fill.nta f17=[r3],32
 	mov b3=r19
 	;;
 	ldf.fill.nta f18=[r2],32
 	ldf.fill.nta f19=[r3],32
 	mov b4=r20
 	;;
 	ldf.fill.nta f20=[r2],32
 	ldf.fill.nta f21=[r3],32
 	mov b5=r21
 	;;
 	ldf.fill.nta f22=[r2],32
 	ldf.fill.nta f23=[r3],32
 	mov ar.lc=r22
 	;;
 	ldf.fill.nta f24=[r2],32
 	ldf.fill.nta f25=[r3],32
 	cmp.eq p8,p9=0,in1
 	;;
 	ldf.fill.nta f26=[r2],32
 	ldf.fill.nta f27=[r3],32
 	mov ar.pfs=r11
 	;;
 	ldf.fill.nta f28=[r2],32
 	ldf.fill.nta f29=[r3],32
 	;;
 	ldf.fill.nta f30=[r2]
 	ldf.fill.nta f31=[r3]
 (p8)	mov r8=1

 	mov ar.rnat=r26		// restore ar.rnat
 	;;
 	mov ar.rsc=r27		// restore ar.rsc
 (p9)	mov r8=in1

 	invala			// virt. -> phys. regnum mapping may change
 	mov pr=r24,-1
 	ret
 END(__longjmp)
	/* Copyright (C) 1999, 2000, 2001, 2005 Free Software Foundation, Inc.
	Contributed by David Mosberger-Tang <davidm@hpl.hp.com>.

	The GNU C Library is free software; you can redistribute it and/or
	modify it under the terms of the GNU Lesser General Public
	License as published by the Free Software Foundation; either
	version 2.1 of the License, or (at your option) any later version.

	The GNU C Library 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
	Lesser General Public License for more details.

	You should have received a copy of the GNU Lesser General Public
	License along with the GNU C Library; if not, write to the Free
	Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
	02111-1307 USA.

	Note that __sigsetjmp() did NOT flush the register stack. Instead,
	we do it here since __longjmp() is usually much less frequently
	invoked than __sigsetjmp(). The only difficulty is that __sigsetjmp()
	didn't (and wouldn't be able to) save ar.rnat either. This is a problem
	because if we're not careful, we could end up loading random NaT bits.
	There are two cases:

	(i) ar.bsp < ia64_rse_rnat_addr(jmpbuf.ar_bsp)
	ar.rnat contains the desired bits---preserve ar.rnat
	across loadrs and write to ar.bspstore

	(ii) ar.bsp >= ia64_rse_rnat_addr(jmpbuf.ar_bsp)
	The desired ar.rnat is stored in
	ia64_rse_rnat_addr(jmpbuf.ar_bsp). Load those
	bits into ar.rnat after setting ar.bspstore. */

	#include <sysdep.h>
	#include <features.h>

	# define pPos p6 /* is rotate count positive? */
	# define pNeg p7 /* is rotate count negative? */


	/* __longjmp(__jmp_buf buf, int val) */

	LEAF(__longjmp)
	#ifdef CHECK_RSP
	alloc r8=ar.pfs,2,1,1,0
	#else
	alloc r8=ar.pfs,2,1,0,0
	#endif
	mov r27=ar.rsc
	add r2=0x98,in0 // r2 <- &jmpbuf.orig_jmp_buf_addr
	;;
	ld8 r8=[r2],-16 // r8 <- orig_jmp_buf_addr
	mov r10=ar.bsp
	and r11=~0x3,r27 // clear ar.rsc.mode
	;;
	flushrs // flush dirty regs to backing store (must be first in insn grp)
	ld8 r23=[r2],8 // r23 <- jmpbuf.ar_bsp
	sub r8=r8,in0 // r8 <- &orig_jmpbuf - &jmpbuf
	;;
	ld8 r25=[r2] // r25 <- jmpbuf.ar_unat
	extr.u r8=r8,3,6 // r8 <- (&orig_jmpbuf - &jmpbuf)/8 & 0x3f
	;;
	cmp.lt pNeg,pPos=r8,r0
	mov r2=in0
	;;
	(pPos) mov r16=r8
	(pNeg) add r16=64,r8
	(pPos) sub r17=64,r8
	(pNeg) sub r17=r0,r8
	;;
	mov ar.rsc=r11 // put RSE in enforced lazy mode
	shr.u r8=r25,r16
	add r3=8,in0 // r3 <- &jmpbuf.r1
	shl r9=r25,r17
	;;
	ld8.fill.nta r28=[r2],16 // r28 <- jmpbuf.sp
	or r25=r8,r9
	;;
	mov r26=ar.rnat
	mov ar.unat=r25 // setup ar.unat (NaT bits for r1, r4-r7, and r12)
	;;
	#ifdef CHECK_RSP
	CHECK_RSP (r28)
	#endif
	ld8.fill.nta gp=[r3],16 // r1 (gp)
	dep r11=-1,r23,3,6 // r11 <- ia64_rse_rnat_addr(jmpbuf.ar_bsp)
	mov sp=r28 // r12 (sp)
	;;
	ld8.nta r16=[r2],16 // caller's unat
	ld8.nta r17=[r3],16 // fpsr
	;;
	ld8.fill.nta r4=[r2],16 // r4
	ld8.fill.nta r5=[r3],16 // r5 (gp)
	cmp.geu p8,p0=r10,r11 // p8 <- (ar.bsp >= jmpbuf.ar_bsp)
	;;
	ld8.fill.nta r6=[r2],16 // r6
	ld8.fill.nta r7=[r3],16 // r7
	;;
	mov ar.unat=r16 // restore caller's unat
	mov ar.fpsr=r17 // restore fpsr
	;;
	ld8.nta r16=[r2],16 // b0
	ld8.nta r17=[r3],16 // b1
	;;
	(p8) ld8 r26=[r11] // r26 <- *ia64_rse_rnat_addr(jmpbuf.ar_bsp)
	mov ar.bspstore=r23 // restore ar.bspstore
	;;
	ld8.nta r18=[r2],16 // b2
	ld8.nta r19=[r3],16 // b3
	;;
	#ifdef PTR_DEMANGLE
	PTR_DEMANGLE (r16, r24)
	#endif
	ld8.nta r20=[r2],16 // b4
	ld8.nta r21=[r3],16 // b5
	;;
	ld8.nta r11=[r2],16 // ar.pfs
	ld8.nta r22=[r3],56 // ar.lc
	;;
	ld8.nta r24=[r2],32 // pr
	mov b0=r16
	;;
	ldf.fill.nta f2=[r2],32
	ldf.fill.nta f3=[r3],32
	mov b1=r17
	;;
	ldf.fill.nta f4=[r2],32
	ldf.fill.nta f5=[r3],32
	mov b2=r18
	;;
	ldf.fill.nta f16=[r2],32
	ldf.fill.nta f17=[r3],32
	mov b3=r19
	;;
	ldf.fill.nta f18=[r2],32
	ldf.fill.nta f19=[r3],32
	mov b4=r20
	;;
	ldf.fill.nta f20=[r2],32
	ldf.fill.nta f21=[r3],32
	mov b5=r21
	;;
	ldf.fill.nta f22=[r2],32
	ldf.fill.nta f23=[r3],32
	mov ar.lc=r22
	;;
	ldf.fill.nta f24=[r2],32
	ldf.fill.nta f25=[r3],32
	cmp.eq p8,p9=0,in1
	;;
	ldf.fill.nta f26=[r2],32
	ldf.fill.nta f27=[r3],32
	mov ar.pfs=r11
	;;
	ldf.fill.nta f28=[r2],32
	ldf.fill.nta f29=[r3],32
	;;
	ldf.fill.nta f30=[r2]
	ldf.fill.nta f31=[r3]
	(p8) mov r8=1

	mov ar.rnat=r26 // restore ar.rnat
	;;
	mov ar.rsc=r27 // restore ar.rsc
	(p9) mov r8=in1

	invala // virt. -> phys. regnum mapping may change
	mov pr=r24,-1
	ret
	END(__longjmp)