xref: /openbmc/linux/arch/ia64/lib/memcpy.S (revision 94cdda6b)
1/*
2 *
3 * Optimized version of the standard memcpy() function
4 *
5 * Inputs:
6 * 	in0:	destination address
7 *	in1:	source address
8 *	in2:	number of bytes to copy
9 * Output:
10 * 	no return value
11 *
12 * Copyright (C) 2000-2001 Hewlett-Packard Co
13 *	Stephane Eranian <eranian@hpl.hp.com>
14 *	David Mosberger-Tang <davidm@hpl.hp.com>
15 */
16#include <asm/asmmacro.h>
17
18GLOBAL_ENTRY(memcpy)
19
20#	define MEM_LAT	21		/* latency to memory */
21
22#	define dst	r2
23#	define src	r3
24#	define retval	r8
25#	define saved_pfs r9
26#	define saved_lc	r10
27#	define saved_pr	r11
28#	define cnt	r16
29#	define src2	r17
30#	define t0	r18
31#	define t1	r19
32#	define t2	r20
33#	define t3	r21
34#	define t4	r22
35#	define src_end	r23
36
37#	define N	(MEM_LAT + 4)
38#	define Nrot	((N + 7) & ~7)
39
40	/*
41	 * First, check if everything (src, dst, len) is a multiple of eight.  If
42	 * so, we handle everything with no taken branches (other than the loop
43	 * itself) and a small icache footprint.  Otherwise, we jump off to
44	 * the more general copy routine handling arbitrary
45	 * sizes/alignment etc.
46	 */
47	.prologue
48	.save ar.pfs, saved_pfs
49	alloc saved_pfs=ar.pfs,3,Nrot,0,Nrot
50	.save ar.lc, saved_lc
51	mov saved_lc=ar.lc
52	or t0=in0,in1
53	;;
54
55	or t0=t0,in2
56	.save pr, saved_pr
57	mov saved_pr=pr
58
59	.body
60
61	cmp.eq p6,p0=in2,r0	// zero length?
62	mov retval=in0		// return dst
63(p6)	br.ret.spnt.many rp	// zero length, return immediately
64	;;
65
66	mov dst=in0		// copy because of rotation
67	shr.u cnt=in2,3		// number of 8-byte words to copy
68	mov pr.rot=1<<16
69	;;
70
71	adds cnt=-1,cnt		// br.ctop is repeat/until
72	cmp.gtu p7,p0=16,in2	// copying less than 16 bytes?
73	mov ar.ec=N
74	;;
75
76	and t0=0x7,t0
77	mov ar.lc=cnt
78	;;
79	cmp.ne p6,p0=t0,r0
80
81	mov src=in1		// copy because of rotation
82(p7)	br.cond.spnt.few .memcpy_short
83(p6)	br.cond.spnt.few .memcpy_long
84	;;
85	nop.m	0
86	;;
87	nop.m	0
88	nop.i	0
89	;;
90	nop.m	0
91	;;
92	.rotr val[N]
93	.rotp p[N]
94	.align 32
951: { .mib
96(p[0])	ld8 val[0]=[src],8
97	nop.i 0
98	brp.loop.imp 1b, 2f
99}
1002: { .mfb
101(p[N-1])st8 [dst]=val[N-1],8
102	nop.f 0
103	br.ctop.dptk.few 1b
104}
105	;;
106	mov ar.lc=saved_lc
107	mov pr=saved_pr,-1
108	mov ar.pfs=saved_pfs
109	br.ret.sptk.many rp
110
111	/*
112	 * Small (<16 bytes) unaligned copying is done via a simple byte-at-the-time
113	 * copy loop.  This performs relatively poorly on Itanium, but it doesn't
114	 * get used very often (gcc inlines small copies) and due to atomicity
115	 * issues, we want to avoid read-modify-write of entire words.
116	 */
117	.align 32
118.memcpy_short:
119	adds cnt=-1,in2		// br.ctop is repeat/until
120	mov ar.ec=MEM_LAT
121	brp.loop.imp 1f, 2f
122	;;
123	mov ar.lc=cnt
124	;;
125	nop.m	0
126	;;
127	nop.m	0
128	nop.i	0
129	;;
130	nop.m	0
131	;;
132	nop.m	0
133	;;
134	/*
135	 * It is faster to put a stop bit in the loop here because it makes
136	 * the pipeline shorter (and latency is what matters on short copies).
137	 */
138	.align 32
1391: { .mib
140(p[0])	ld1 val[0]=[src],1
141	nop.i 0
142	brp.loop.imp 1b, 2f
143} ;;
1442: { .mfb
145(p[MEM_LAT-1])st1 [dst]=val[MEM_LAT-1],1
146	nop.f 0
147	br.ctop.dptk.few 1b
148} ;;
149	mov ar.lc=saved_lc
150	mov pr=saved_pr,-1
151	mov ar.pfs=saved_pfs
152	br.ret.sptk.many rp
153
154	/*
155	 * Large (>= 16 bytes) copying is done in a fancy way.  Latency isn't
156	 * an overriding concern here, but throughput is.  We first do
157	 * sub-word copying until the destination is aligned, then we check
158	 * if the source is also aligned.  If so, we do a simple load/store-loop
159	 * until there are less than 8 bytes left over and then we do the tail,
160	 * by storing the last few bytes using sub-word copying.  If the source
161	 * is not aligned, we branch off to the non-congruent loop.
162	 *
163	 *   stage:   op:
164	 *         0  ld
165	 *	   :
166	 * MEM_LAT+3  shrp
167	 * MEM_LAT+4  st
168	 *
169	 * On Itanium, the pipeline itself runs without stalls.  However,  br.ctop
170	 * seems to introduce an unavoidable bubble in the pipeline so the overall
171	 * latency is 2 cycles/iteration.  This gives us a _copy_ throughput
172	 * of 4 byte/cycle.  Still not bad.
173	 */
174#	undef N
175#	undef Nrot
176#	define N	(MEM_LAT + 5)		/* number of stages */
177#	define Nrot	((N+1 + 2 + 7) & ~7)	/* number of rotating regs */
178
179#define LOG_LOOP_SIZE	6
180
181.memcpy_long:
182	alloc t3=ar.pfs,3,Nrot,0,Nrot	// resize register frame
183	and t0=-8,src		// t0 = src & ~7
184	and t2=7,src		// t2 = src & 7
185	;;
186	ld8 t0=[t0]		// t0 = 1st source word
187	adds src2=7,src		// src2 = (src + 7)
188	sub t4=r0,dst		// t4 = -dst
189	;;
190	and src2=-8,src2	// src2 = (src + 7) & ~7
191	shl t2=t2,3		// t2 = 8*(src & 7)
192	shl t4=t4,3		// t4 = 8*(dst & 7)
193	;;
194	ld8 t1=[src2]		// t1 = 1st source word if src is 8-byte aligned, 2nd otherwise
195	sub t3=64,t2		// t3 = 64-8*(src & 7)
196	shr.u t0=t0,t2
197	;;
198	add src_end=src,in2
199	shl t1=t1,t3
200	mov pr=t4,0x38		// (p5,p4,p3)=(dst & 7)
201	;;
202	or t0=t0,t1
203	mov cnt=r0
204	adds src_end=-1,src_end
205	;;
206(p3)	st1 [dst]=t0,1
207(p3)	shr.u t0=t0,8
208(p3)	adds cnt=1,cnt
209	;;
210(p4)	st2 [dst]=t0,2
211(p4)	shr.u t0=t0,16
212(p4)	adds cnt=2,cnt
213	;;
214(p5)	st4 [dst]=t0,4
215(p5)	adds cnt=4,cnt
216	and src_end=-8,src_end	// src_end = last word of source buffer
217	;;
218
219	// At this point, dst is aligned to 8 bytes and there at least 16-7=9 bytes left to copy:
220
2211:{	add src=cnt,src			// make src point to remainder of source buffer
222	sub cnt=in2,cnt			// cnt = number of bytes left to copy
223	mov t4=ip
224  }	;;
225	and src2=-8,src			// align source pointer
226	adds t4=.memcpy_loops-1b,t4
227	mov ar.ec=N
228
229	and t0=7,src			// t0 = src & 7
230	shr.u t2=cnt,3			// t2 = number of 8-byte words left to copy
231	shl cnt=cnt,3			// move bits 0-2 to 3-5
232	;;
233
234	.rotr val[N+1], w[2]
235	.rotp p[N]
236
237	cmp.ne p6,p0=t0,r0		// is src aligned, too?
238	shl t0=t0,LOG_LOOP_SIZE		// t0 = 8*(src & 7)
239	adds t2=-1,t2			// br.ctop is repeat/until
240	;;
241	add t4=t0,t4
242	mov pr=cnt,0x38			// set (p5,p4,p3) to # of bytes last-word bytes to copy
243	mov ar.lc=t2
244	;;
245	nop.m	0
246	;;
247	nop.m	0
248	nop.i	0
249	;;
250	nop.m	0
251	;;
252(p6)	ld8 val[1]=[src2],8		// prime the pump...
253	mov b6=t4
254	br.sptk.few b6
255	;;
256
257.memcpy_tail:
258	// At this point, (p5,p4,p3) are set to the number of bytes left to copy (which is
259	// less than 8) and t0 contains the last few bytes of the src buffer:
260(p5)	st4 [dst]=t0,4
261(p5)	shr.u t0=t0,32
262	mov ar.lc=saved_lc
263	;;
264(p4)	st2 [dst]=t0,2
265(p4)	shr.u t0=t0,16
266	mov ar.pfs=saved_pfs
267	;;
268(p3)	st1 [dst]=t0
269	mov pr=saved_pr,-1
270	br.ret.sptk.many rp
271
272///////////////////////////////////////////////////////
273	.align 64
274
275#define COPY(shift,index)									\
276 1: { .mib											\
277	(p[0])		ld8 val[0]=[src2],8;							\
278	(p[MEM_LAT+3])	shrp w[0]=val[MEM_LAT+3],val[MEM_LAT+4-index],shift;			\
279			brp.loop.imp 1b, 2f							\
280    };												\
281 2: { .mfb											\
282	(p[MEM_LAT+4])	st8 [dst]=w[1],8;							\
283			nop.f 0;								\
284			br.ctop.dptk.few 1b;							\
285    };												\
286			;;									\
287			ld8 val[N-1]=[src_end];	/* load last word (may be same as val[N]) */	\
288			;;									\
289			shrp t0=val[N-1],val[N-index],shift;					\
290			br .memcpy_tail
291.memcpy_loops:
292	COPY(0, 1) /* no point special casing this---it doesn't go any faster without shrp */
293	COPY(8, 0)
294	COPY(16, 0)
295	COPY(24, 0)
296	COPY(32, 0)
297	COPY(40, 0)
298	COPY(48, 0)
299	COPY(56, 0)
300
301END(memcpy)
302