src/parsec/disk-image/parsec/parsec-benchmark/pkgs/libs/ssl/src/crypto/rc4/asm/rc4-ia64.S - public/gem5-resources - Git at Google

 // ====================================================================
 // Written by Andy Polyakov <appro@fy.chalmers.se> for the OpenSSL
 // project.
 //
 // Rights for redistribution and usage in source and binary forms are
 // granted according to the OpenSSL license. Warranty of any kind is
 // disclaimed.
 // ====================================================================

 .ident  "rc4-ia64.S, Version 2.0"
 .ident  "IA-64 ISA artwork by Andy Polyakov <appro@fy.chalmers.se>"

 // What's wrong with compiler generated code? Because of the nature of
 // C language, compiler doesn't [dare to] reorder load and stores. But
 // being memory-bound, RC4 should benefit from reorder [on in-order-
 // execution core such as IA-64]. But what can we reorder? At the very
 // least we can safely reorder references to key schedule in respect
 // to input and output streams. Secondly, from the first [close] glance
 // it appeared that it's possible to pull up some references to
 // elements of the key schedule itself. Original rationale ["prior
 // loads are not safe only for "degenerated" key schedule, when some
 // elements equal to the same value"] was kind of sloppy. I should have
 // formulated as it really was: if we assume that pulling up reference
 // to key[x+1] is not safe, then it would mean that key schedule would
 // "degenerate," which is never the case. The problem is that this
 // holds true in respect to references to key[x], but not to key[y].
 // Legitimate "collisions" do occur within every 256^2 bytes window.
 // Fortunately there're enough free instruction slots to keep prior
 // reference to key[x+1], detect "collision" and compensate for it.
 // All this without sacrificing a single clock cycle:-) Throughput is
 // ~210MBps on 900MHz CPU, which is is >3x faster than gcc generated
 // code and +30% - if compared to HP-UX C. Unrolling loop below should
 // give >30% on top of that...

 .text
 .explicit

 #if defined(_HPUX_SOURCE) && !defined(_LP64)
 # define ADDP	addp4
 #else
 # define ADDP	add
 #endif

 #ifndef SZ
 #define SZ	4	// this is set to sizeof(RC4_INT)
 #endif
 // SZ==4 seems to be optimal. At least SZ==8 is not any faster, not for
 // assembler implementation, while SZ==1 code is ~30% slower.
 #if SZ==1	// RC4_INT is unsigned char
 # define	LDKEY	ld1
 # define	STKEY	st1
 # define	OFF	0
 #elif SZ==4	// RC4_INT is unsigned int
 # define	LDKEY	ld4
 # define	STKEY	st4
 # define	OFF	2
 #elif SZ==8	// RC4_INT is unsigned long
 # define	LDKEY	ld8
 # define	STKEY	st8
 # define	OFF	3
 #endif

 out=r8;		// [expanded] output pointer
 inp=r9;		// [expanded] output pointer
 prsave=r10;
 key=r28;	// [expanded] pointer to RC4_KEY
 ksch=r29;	// (key->data+255)[&~(sizeof(key->data)-1)]
 xx=r30;
 yy=r31;

 // void RC4(RC4_KEY *key,size_t len,const void *inp,void *out);
 .global	RC4#
 .proc	RC4#
 .align	32
 .skip	16
 RC4:
 	.prologue
 	.save   ar.pfs,r2
 { .mii;	alloc	r2=ar.pfs,4,12,0,16
 	.save	pr,prsave
 	mov	prsave=pr
 	ADDP	key=0,in0		};;
 { .mib;	cmp.eq	p6,p0=0,in1			// len==0?
 	.save	ar.lc,r3
 	mov	r3=ar.lc
 (p6)	br.ret.spnt.many	b0	};;	// emergency exit

 	.body
 	.rotr	dat[4],key_x[4],tx[2],rnd[2],key_y[2],ty[1];

 { .mib;	LDKEY	xx=[key],SZ			// load key->x
 	add	in1=-1,in1			// adjust len for loop counter
 	nop.b	0			}
 { .mib;	ADDP	inp=0,in2
 	ADDP	out=0,in3
 	brp.loop.imp	.Ltop,.Lexit-16	};;
 { .mmi;	LDKEY	yy=[key]			// load key->y
 	add	ksch=SZ,key
 	mov	ar.lc=in1		}
 { .mmi;	mov	key_y[1]=r0			// guarantee inequality
 						// in first iteration
 	add	xx=1,xx
 	mov	pr.rot=1<<16		};;
 { .mii;	nop.m	0
 	dep	key_x[1]=xx,r0,OFF,8
 	mov	ar.ec=3			};;	// note that epilogue counter
 						// is off by 1. I compensate
 						// for this at exit...
 .Ltop:
 // The loop is scheduled for 4*(n+2) spin-rate on Itanium 2, which
 // theoretically gives asymptotic performance of clock frequency
 // divided by 4 bytes per seconds, or 400MBps on 1.6GHz CPU. This is
 // for sizeof(RC4_INT)==4. For smaller RC4_INT STKEY inadvertently
 // splits the last bundle and you end up with 5*n spin-rate:-(
 // Originally the loop was scheduled for 3*n and relied on key
 // schedule to be aligned at 256*sizeof(RC4_INT) boundary. But
 // *(out++)=dat, which maps to st1, had same effect [inadvertent
 // bundle split] and holded the loop back. Rescheduling for 4*n
 // made it possible to eliminate dependence on specific alignment
 // and allow OpenSSH keep "abusing" our API. Reaching for 3*n would
 // require unrolling, sticking to variable shift instruction for
 // collecting output [to avoid starvation for integer shifter] and
 // copying of key schedule to controlled place in stack [so that
 // deposit instruction can serve as substitute for whole
 // key->data+((x&255)<<log2(sizeof(key->data[0])))]...
 { .mmi;	(p19)	st1	[out]=dat[3],1			// *(out++)=dat
 	(p16)	add	xx=1,xx				// x++
 	(p18)	dep	rnd[1]=rnd[1],r0,OFF,8	}	// ((tx+ty)&255)<<OFF
 { .mmi;	(p16)	add	key_x[1]=ksch,key_x[1]		// &key[xx&255]
 	(p17)	add	key_y[1]=ksch,key_y[1]	};;	// &key[yy&255]
 { .mmi;	(p16)	LDKEY	tx[0]=[key_x[1]]		// tx=key[xx]
 	(p17)	LDKEY	ty[0]=[key_y[1]]		// ty=key[yy]
 	(p16)	dep	key_x[0]=xx,r0,OFF,8	}	// (xx&255)<<OFF
 { .mmi;	(p18)	add	rnd[1]=ksch,rnd[1]		// &key[(tx+ty)&255]
 	(p16)	cmp.ne.unc p20,p21=key_x[1],key_y[1] };;
 { .mmi;	(p18)	LDKEY	rnd[1]=[rnd[1]]			// rnd=key[(tx+ty)&255]
 	(p16)	ld1	dat[0]=[inp],1		}	// dat=*(inp++)
 .pred.rel	"mutex",p20,p21
 { .mmi;	(p21)	add	yy=yy,tx[1]			// (p16)
 	(p20)	add	yy=yy,tx[0]			// (p16) y+=tx
 	(p21)	mov	tx[0]=tx[1]		};;	// (p16)
 { .mmi;	(p17)	STKEY	[key_y[1]]=tx[1]		// key[yy]=tx
 	(p17)	STKEY	[key_x[2]]=ty[0]		// key[xx]=ty
 	(p16)	dep	key_y[0]=yy,r0,OFF,8	}	// &key[yy&255]
 { .mmb;	(p17)	add	rnd[0]=tx[1],ty[0]		// tx+=ty
 	(p18)	xor	dat[2]=dat[2],rnd[1]		// dat^=rnd
 	br.ctop.sptk	.Ltop			};;
 .Lexit:
 { .mib;	STKEY	[key]=yy,-SZ			// save key->y
 	mov	pr=prsave,0x1ffff
 	nop.b	0			}
 { .mib;	st1	[out]=dat[3],1			// compensate for truncated
 						// epilogue counter
 	add	xx=-1,xx
 	nop.b	0			};;
 { .mib;	STKEY	[key]=xx			// save key->x
 	mov	ar.lc=r3
 	br.ret.sptk.many	b0	};;
 .endp	RC4#
	// ====================================================================
	// Written by Andy Polyakov <appro@fy.chalmers.se> for the OpenSSL
	// project.
	//
	// Rights for redistribution and usage in source and binary forms are
	// granted according to the OpenSSL license. Warranty of any kind is
	// disclaimed.
	// ====================================================================

	.ident "rc4-ia64.S, Version 2.0"
	.ident "IA-64 ISA artwork by Andy Polyakov <appro@fy.chalmers.se>"

	// What's wrong with compiler generated code? Because of the nature of
	// C language, compiler doesn't [dare to] reorder load and stores. But
	// being memory-bound, RC4 should benefit from reorder [on in-order-
	// execution core such as IA-64]. But what can we reorder? At the very
	// least we can safely reorder references to key schedule in respect
	// to input and output streams. Secondly, from the first [close] glance
	// it appeared that it's possible to pull up some references to
	// elements of the key schedule itself. Original rationale ["prior
	// loads are not safe only for "degenerated" key schedule, when some
	// elements equal to the same value"] was kind of sloppy. I should have
	// formulated as it really was: if we assume that pulling up reference
	// to key[x+1] is not safe, then it would mean that key schedule would
	// "degenerate," which is never the case. The problem is that this
	// holds true in respect to references to key[x], but not to key[y].
	// Legitimate "collisions" do occur within every 256^2 bytes window.
	// Fortunately there're enough free instruction slots to keep prior
	// reference to key[x+1], detect "collision" and compensate for it.
	// All this without sacrificing a single clock cycle:-) Throughput is
	// ~210MBps on 900MHz CPU, which is is >3x faster than gcc generated
	// code and +30% - if compared to HP-UX C. Unrolling loop below should
	// give >30% on top of that...

	.text
	.explicit

	#if defined(_HPUX_SOURCE) && !defined(_LP64)
	# define ADDP addp4
	#else
	# define ADDP add
	#endif

	#ifndef SZ
	#define SZ 4 // this is set to sizeof(RC4_INT)
	#endif
	// SZ==4 seems to be optimal. At least SZ==8 is not any faster, not for
	// assembler implementation, while SZ==1 code is ~30% slower.
	#if SZ==1 // RC4_INT is unsigned char
	# define LDKEY ld1
	# define STKEY st1
	# define OFF 0
	#elif SZ==4 // RC4_INT is unsigned int
	# define LDKEY ld4
	# define STKEY st4
	# define OFF 2
	#elif SZ==8 // RC4_INT is unsigned long
	# define LDKEY ld8
	# define STKEY st8
	# define OFF 3
	#endif

	out=r8; // [expanded] output pointer
	inp=r9; // [expanded] output pointer
	prsave=r10;
	key=r28; // [expanded] pointer to RC4_KEY
	ksch=r29; // (key->data+255)[&~(sizeof(key->data)-1)]
	xx=r30;
	yy=r31;

	// void RC4(RC4_KEY key,size_t len,const void inp,void *out);
	.global RC4#
	.proc RC4#
	.align 32
	.skip 16
	RC4:
	.prologue
	.save ar.pfs,r2
	{ .mii; alloc r2=ar.pfs,4,12,0,16
	.save pr,prsave
	mov prsave=pr
	ADDP key=0,in0 };;
	{ .mib; cmp.eq p6,p0=0,in1 // len==0?
	.save ar.lc,r3
	mov r3=ar.lc
	(p6) br.ret.spnt.many b0 };; // emergency exit

	.body
	.rotr dat[4],key_x[4],tx[2],rnd[2],key_y[2],ty[1];

	{ .mib; LDKEY xx=[key],SZ // load key->x
	add in1=-1,in1 // adjust len for loop counter
	nop.b 0 }
	{ .mib; ADDP inp=0,in2
	ADDP out=0,in3
	brp.loop.imp .Ltop,.Lexit-16 };;
	{ .mmi; LDKEY yy=[key] // load key->y
	add ksch=SZ,key
	mov ar.lc=in1 }
	{ .mmi; mov key_y[1]=r0 // guarantee inequality
	// in first iteration
	add xx=1,xx
	mov pr.rot=1<<16 };;
	{ .mii; nop.m 0
	dep key_x[1]=xx,r0,OFF,8
	mov ar.ec=3 };; // note that epilogue counter
	// is off by 1. I compensate
	// for this at exit...
	.Ltop:
	// The loop is scheduled for 4*(n+2) spin-rate on Itanium 2, which
	// theoretically gives asymptotic performance of clock frequency
	// divided by 4 bytes per seconds, or 400MBps on 1.6GHz CPU. This is
	// for sizeof(RC4_INT)==4. For smaller RC4_INT STKEY inadvertently
	// splits the last bundle and you end up with 5*n spin-rate:-(
	// Originally the loop was scheduled for 3*n and relied on key
	// schedule to be aligned at 256*sizeof(RC4_INT) boundary. But
	// *(out++)=dat, which maps to st1, had same effect [inadvertent
	// bundle split] and holded the loop back. Rescheduling for 4*n
	// made it possible to eliminate dependence on specific alignment
	// and allow OpenSSH keep "abusing" our API. Reaching for 3*n would
	// require unrolling, sticking to variable shift instruction for
	// collecting output [to avoid starvation for integer shifter] and
	// copying of key schedule to controlled place in stack [so that
	// deposit instruction can serve as substitute for whole
	// key->data+((x&255)<<log2(sizeof(key->data[0])))]...
	{ .mmi; (p19) st1 [out]=dat[3],1 // *(out++)=dat
	(p16) add xx=1,xx // x++
	(p18) dep rnd[1]=rnd[1],r0,OFF,8 } // ((tx+ty)&255)<<OFF
	{ .mmi; (p16) add key_x[1]=ksch,key_x[1] // &key[xx&255]
	(p17) add key_y[1]=ksch,key_y[1] };; // &key[yy&255]
	{ .mmi; (p16) LDKEY tx[0]=[key_x[1]] // tx=key[xx]
	(p17) LDKEY ty[0]=[key_y[1]] // ty=key[yy]
	(p16) dep key_x[0]=xx,r0,OFF,8 } // (xx&255)<<OFF
	{ .mmi; (p18) add rnd[1]=ksch,rnd[1] // &key[(tx+ty)&255]
	(p16) cmp.ne.unc p20,p21=key_x[1],key_y[1] };;
	{ .mmi; (p18) LDKEY rnd[1]=[rnd[1]] // rnd=key[(tx+ty)&255]
	(p16) ld1 dat[0]=[inp],1 } // dat=*(inp++)
	.pred.rel "mutex",p20,p21
	{ .mmi; (p21) add yy=yy,tx[1] // (p16)
	(p20) add yy=yy,tx[0] // (p16) y+=tx
	(p21) mov tx[0]=tx[1] };; // (p16)
	{ .mmi; (p17) STKEY [key_y[1]]=tx[1] // key[yy]=tx
	(p17) STKEY [key_x[2]]=ty[0] // key[xx]=ty
	(p16) dep key_y[0]=yy,r0,OFF,8 } // &key[yy&255]
	{ .mmb; (p17) add rnd[0]=tx[1],ty[0] // tx+=ty
	(p18) xor dat[2]=dat[2],rnd[1] // dat^=rnd
	br.ctop.sptk .Ltop };;
	.Lexit:
	{ .mib; STKEY [key]=yy,-SZ // save key->y
	mov pr=prsave,0x1ffff
	nop.b 0 }
	{ .mib; st1 [out]=dat[3],1 // compensate for truncated
	// epilogue counter
	add xx=-1,xx
	nop.b 0 };;
	{ .mib; STKEY [key]=xx // save key->x
	mov ar.lc=r3
	br.ret.sptk.many b0 };;
	.endp RC4#