2 * Copyright 2010 Tilera Corporation. All Rights Reserved.
4 * This program is free software; you can redistribute it and/or
5 * modify it under the terms of the GNU General Public License
6 * as published by the Free Software Foundation, version 2.
8 * This program is distributed in the hope that it will be useful, but
9 * WITHOUT ANY WARRANTY; without even the implied warranty of
10 * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
11 * NON INFRINGEMENT. See the GNU General Public License for
15 #include <arch/chip.h>
17 #include <linux/types.h>
18 #include <linux/string.h>
19 #include <linux/module.h>
22 void *memset(void *s, int c, size_t n)
34 /* Experimentation shows that a trivial tight loop is a win up until
35 * around a size of 20, where writing a word at a time starts to win.
37 #define BYTE_CUTOFF 20
40 /* This must be at least at least this big, or some code later
43 #error "BYTE_CUTOFF is too small"
46 if (n < BYTE_CUTOFF) {
47 /* Strangely, this turns out to be the tightest way to
52 /* Strangely, combining these into one line
64 /* Use a spare issue slot to start prefetching the first cache
65 * line early. This instruction is free as the store can be buried
66 * in otherwise idle issue slots doing ALU ops.
68 __insn_prefetch(out8);
70 /* We prefetch the end so that a short memset that spans two cache
71 * lines gets some prefetching benefit. Again we believe this is free
74 __insn_prefetch(&out8[n - 1]);
75 #endif /* !CHIP_HAS_WH64() */
78 /* Align 'out8'. We know n >= 3 so this won't write past the end. */
79 while (((uintptr_t) out8 & 3) != 0) {
88 out32 = (uint32_t *) out8;
91 /* Tile input byte out to 32 bits. */
92 v16 = __insn_intlb(c, c);
93 v32 = __insn_intlh(v16, v16);
95 /* This must be at least 8 or the following loop doesn't work. */
96 #define CACHE_LINE_SIZE_IN_WORDS (CHIP_L2_LINE_SIZE() / 4)
100 ahead32 = CACHE_LINE_SIZE_IN_WORDS;
102 /* We already prefetched the first and last cache lines, so
103 * we only need to do more prefetching if we are storing
104 * to more than two cache lines.
106 if (n32 > CACHE_LINE_SIZE_IN_WORDS * 2) {
109 /* Prefetch the next several cache lines.
110 * This is the setup code for the software-pipelined
113 #define MAX_PREFETCH 5
114 ahead32 = n32 & -CACHE_LINE_SIZE_IN_WORDS;
115 if (ahead32 > MAX_PREFETCH * CACHE_LINE_SIZE_IN_WORDS)
116 ahead32 = MAX_PREFETCH * CACHE_LINE_SIZE_IN_WORDS;
118 for (i = CACHE_LINE_SIZE_IN_WORDS;
119 i < ahead32; i += CACHE_LINE_SIZE_IN_WORDS)
120 __insn_prefetch(&out32[i]);
127 /* Prefetch by reading one word several cache lines
128 * ahead. Since loads are non-blocking this will
129 * cause the full cache line to be read while we are
130 * finishing earlier cache lines. Using a store
131 * here causes microarchitectural performance
132 * problems where a victimizing store miss goes to
133 * the head of the retry FIFO and locks the pipe for
134 * a few cycles. So a few subsequent stores in this
135 * loop go into the retry FIFO, and then later
136 * stores see other stores to the same cache line
137 * are already in the retry FIFO and themselves go
138 * into the retry FIFO, filling it up and grinding
139 * to a halt waiting for the original miss to be
142 __insn_prefetch(&out32[ahead32]);
145 #if CACHE_LINE_SIZE_IN_WORDS % 4 != 0
146 #error "Unhandled CACHE_LINE_SIZE_IN_WORDS"
149 n32 -= CACHE_LINE_SIZE_IN_WORDS;
151 /* Save icache space by only partially unrolling
154 for (j = CACHE_LINE_SIZE_IN_WORDS / 4; j > 0; j--) {
161 /* Unfortunately, due to a code generator flaw this
162 * allocates a separate register for each of these
163 * stores, which requires a large number of spills,
164 * which makes this procedure enormously bigger
165 * (something like 70%)
185 /* To save compiled code size, reuse this loop even
186 * when we run out of prefetching to do by dropping
189 if (n32 <= ahead32) {
190 /* Not even a full cache line left,
193 if (n32 < CACHE_LINE_SIZE_IN_WORDS)
196 /* Choose a small enough value that we don't
197 * prefetch past the end. There's no sense
198 * in touching cache lines we don't have to.
200 ahead32 = CACHE_LINE_SIZE_IN_WORDS - 1;
205 #else /* CHIP_HAS_WH64() */
207 /* Determine how many words we need to emit before the 'out32'
208 * pointer becomes aligned modulo the cache line size.
211 (-((uintptr_t)out32 >> 2)) & (CACHE_LINE_SIZE_IN_WORDS - 1);
213 /* Only bother aligning and using wh64 if there is at least
214 * one full cache line to process. This check also prevents
215 * overrunning the end of the buffer with alignment words.
217 if (to_align32 <= n32 - CACHE_LINE_SIZE_IN_WORDS) {
220 /* Align out32 mod the cache line size so we can use wh64. */
222 for (; to_align32 != 0; to_align32--) {
227 /* Use unsigned divide to turn this into a right shift. */
228 lines_left = (unsigned)n32 / CACHE_LINE_SIZE_IN_WORDS;
231 /* Only wh64 a few lines at a time, so we don't
232 * exceed the maximum number of victim lines.
234 int x = ((lines_left < CHIP_MAX_OUTSTANDING_VICTIMS())
236 : CHIP_MAX_OUTSTANDING_VICTIMS());
237 uint32_t *wh = out32;
245 wh += CACHE_LINE_SIZE_IN_WORDS;
248 for (j = x * (CACHE_LINE_SIZE_IN_WORDS / 4);
255 } while (lines_left != 0);
257 /* We processed all full lines above, so only this many
258 * words remain to be processed.
260 n32 &= CACHE_LINE_SIZE_IN_WORDS - 1;
263 #endif /* CHIP_HAS_WH64() */
265 /* Now handle any leftover values. */
270 } while (--n32 != 0);
275 EXPORT_SYMBOL(memset);
git.openpandora.org / pandora-kernel.git / blob