/* * strcpy/stpcpy - copy a string returning pointer to start/end. * * Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. * See https://llvm.org/LICENSE.txt for license information. * SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception */ /* Assumptions: * * ARMv8-a, AArch64, unaligned accesses, min page size 4k. */ #include "../asmdefs.h" /* To build as stpcpy, define BUILD_STPCPY before compiling this file. To test the page crossing code path more thoroughly, compile with -DSTRCPY_TEST_PAGE_CROSS - this will force all copies through the slower entry path. This option is not intended for production use. */ /* Arguments and results. */ #define dstin x0 #define srcin x1 /* Locals and temporaries. */ #define src x2 #define dst x3 #define data1 x4 #define data1w w4 #define data2 x5 #define data2w w5 #define has_nul1 x6 #define has_nul2 x7 #define tmp1 x8 #define tmp2 x9 #define tmp3 x10 #define tmp4 x11 #define zeroones x12 #define data1a x13 #define data2a x14 #define pos x15 #define len x16 #define to_align x17 #ifdef BUILD_STPCPY #define STRCPY __stpcpy_aarch64 #else #define STRCPY __strcpy_aarch64 #endif /* NUL detection works on the principle that (X - 1) & (~X) & 0x80 (=> (X - 1) & ~(X | 0x7f)) is non-zero iff a byte is zero, and can be done in parallel across the entire word. */ #define REP8_01 0x0101010101010101 #define REP8_7f 0x7f7f7f7f7f7f7f7f #define REP8_80 0x8080808080808080 /* AArch64 systems have a minimum page size of 4k. We can do a quick page size check for crossing this boundary on entry and if we do not, then we can short-circuit much of the entry code. We expect early page-crossing strings to be rare (probability of 16/MIN_PAGE_SIZE ~= 0.4%), so the branch should be quite predictable, even with random strings. We don't bother checking for larger page sizes, the cost of setting up the correct page size is just not worth the extra gain from a small reduction in the cases taking the slow path. Note that we only care about whether the first fetch, which may be misaligned, crosses a page boundary - after that we move to aligned fetches for the remainder of the string. */ #ifdef STRCPY_TEST_PAGE_CROSS /* Make everything that isn't Qword aligned look like a page cross. */ #define MIN_PAGE_P2 4 #else #define MIN_PAGE_P2 12 #endif #define MIN_PAGE_SIZE (1 << MIN_PAGE_P2) ENTRY (STRCPY) /* For moderately short strings, the fastest way to do the copy is to calculate the length of the string in the same way as strlen, then essentially do a memcpy of the result. This avoids the need for multiple byte copies and further means that by the time we reach the bulk copy loop we know we can always use DWord accesses. We expect __strcpy_aarch64 to rarely be called repeatedly with the same source string, so branch prediction is likely to always be difficult - we mitigate against this by preferring conditional select operations over branches whenever this is feasible. */ and tmp2, srcin, #(MIN_PAGE_SIZE - 1) mov zeroones, #REP8_01 and to_align, srcin, #15 cmp tmp2, #(MIN_PAGE_SIZE - 16) neg tmp1, to_align /* The first fetch will straddle a (possible) page boundary iff srcin + 15 causes bit[MIN_PAGE_P2] to change value. A 16-byte aligned string will never fail the page align check, so will always take the fast path. */ b.gt L(page_cross) L(page_cross_ok): ldp data1, data2, [srcin] #ifdef __AARCH64EB__ /* Because we expect the end to be found within 16 characters (profiling shows this is the most common case), it's worth swapping the bytes now to save having to recalculate the termination syndrome later. We preserve data1 and data2 so that we can re-use the values later on. */ rev tmp2, data1 sub tmp1, tmp2, zeroones orr tmp2, tmp2, #REP8_7f bics has_nul1, tmp1, tmp2 b.ne L(fp_le8) rev tmp4, data2 sub tmp3, tmp4, zeroones orr tmp4, tmp4, #REP8_7f #else sub tmp1, data1, zeroones orr tmp2, data1, #REP8_7f bics has_nul1, tmp1, tmp2 b.ne L(fp_le8) sub tmp3, data2, zeroones orr tmp4, data2, #REP8_7f #endif bics has_nul2, tmp3, tmp4 b.eq L(bulk_entry) /* The string is short (<=16 bytes). We don't know exactly how short though, yet. Work out the exact length so that we can quickly select the optimal copy strategy. */ L(fp_gt8): rev has_nul2, has_nul2 clz pos, has_nul2 mov tmp2, #56 add dst, dstin, pos, lsr #3 /* Bits to bytes. */ sub pos, tmp2, pos #ifdef __AARCH64EB__ lsr data2, data2, pos #else lsl data2, data2, pos #endif str data2, [dst, #1] str data1, [dstin] #ifdef BUILD_STPCPY add dstin, dst, #8 #endif ret L(fp_le8): rev has_nul1, has_nul1 clz pos, has_nul1 add dst, dstin, pos, lsr #3 /* Bits to bytes. */ subs tmp2, pos, #24 /* Pos in bits. */ b.lt L(fp_lt4) #ifdef __AARCH64EB__ mov tmp2, #56 sub pos, tmp2, pos lsr data2, data1, pos lsr data1, data1, #32 #else lsr data2, data1, tmp2 #endif /* 4->7 bytes to copy. */ str data2w, [dst, #-3] str data1w, [dstin] #ifdef BUILD_STPCPY mov dstin, dst #endif ret L(fp_lt4): cbz pos, L(fp_lt2) /* 2->3 bytes to copy. */ #ifdef __AARCH64EB__ lsr data1, data1, #48 #endif strh data1w, [dstin] /* Fall-through, one byte (max) to go. */ L(fp_lt2): /* Null-terminated string. Last character must be zero! */ strb wzr, [dst] #ifdef BUILD_STPCPY mov dstin, dst #endif ret .p2align 6 /* Aligning here ensures that the entry code and main loop all lies within one 64-byte cache line. */ L(bulk_entry): sub to_align, to_align, #16 stp data1, data2, [dstin] sub src, srcin, to_align sub dst, dstin, to_align b L(entry_no_page_cross) /* The inner loop deals with two Dwords at a time. This has a slightly higher start-up cost, but we should win quite quickly, especially on cores with a high number of issue slots per cycle, as we get much better parallelism out of the operations. */ L(main_loop): stp data1, data2, [dst], #16 L(entry_no_page_cross): ldp data1, data2, [src], #16 sub tmp1, data1, zeroones orr tmp2, data1, #REP8_7f sub tmp3, data2, zeroones orr tmp4, data2, #REP8_7f bic has_nul1, tmp1, tmp2 bics has_nul2, tmp3, tmp4 ccmp has_nul1, #0, #0, eq /* NZCV = 0000 */ b.eq L(main_loop) /* Since we know we are copying at least 16 bytes, the fastest way to deal with the tail is to determine the location of the trailing NUL, then (re)copy the 16 bytes leading up to that. */ cmp has_nul1, #0 #ifdef __AARCH64EB__ /* For big-endian, carry propagation (if the final byte in the string is 0x01) means we cannot use has_nul directly. The easiest way to get the correct byte is to byte-swap the data and calculate the syndrome a second time. */ csel data1, data1, data2, ne rev data1, data1 sub tmp1, data1, zeroones orr tmp2, data1, #REP8_7f bic has_nul1, tmp1, tmp2 #else csel has_nul1, has_nul1, has_nul2, ne #endif rev has_nul1, has_nul1 clz pos, has_nul1 add tmp1, pos, #72 add pos, pos, #8 csel pos, pos, tmp1, ne add src, src, pos, lsr #3 add dst, dst, pos, lsr #3 ldp data1, data2, [src, #-32] stp data1, data2, [dst, #-16] #ifdef BUILD_STPCPY sub dstin, dst, #1 #endif ret L(page_cross): bic src, srcin, #15 /* Start by loading two words at [srcin & ~15], then forcing the bytes that precede srcin to 0xff. This means they never look like termination bytes. */ ldp data1, data2, [src] lsl tmp1, tmp1, #3 /* Bytes beyond alignment -> bits. */ tst to_align, #7 csetm tmp2, ne #ifdef __AARCH64EB__ lsl tmp2, tmp2, tmp1 /* Shift (tmp1 & 63). */ #else lsr tmp2, tmp2, tmp1 /* Shift (tmp1 & 63). */ #endif orr data1, data1, tmp2 orr data2a, data2, tmp2 cmp to_align, #8 csinv data1, data1, xzr, lt csel data2, data2, data2a, lt sub tmp1, data1, zeroones orr tmp2, data1, #REP8_7f sub tmp3, data2, zeroones orr tmp4, data2, #REP8_7f bic has_nul1, tmp1, tmp2 bics has_nul2, tmp3, tmp4 ccmp has_nul1, #0, #0, eq /* NZCV = 0000 */ b.eq L(page_cross_ok) /* We now need to make data1 and data2 look like they've been loaded directly from srcin. Do a rotate on the 128-bit value. */ lsl tmp1, to_align, #3 /* Bytes->bits. */ neg tmp2, to_align, lsl #3 #ifdef __AARCH64EB__ lsl data1a, data1, tmp1 lsr tmp4, data2, tmp2 lsl data2, data2, tmp1 orr tmp4, tmp4, data1a cmp to_align, #8 csel data1, tmp4, data2, lt rev tmp2, data1 rev tmp4, data2 sub tmp1, tmp2, zeroones orr tmp2, tmp2, #REP8_7f sub tmp3, tmp4, zeroones orr tmp4, tmp4, #REP8_7f #else lsr data1a, data1, tmp1 lsl tmp4, data2, tmp2 lsr data2, data2, tmp1 orr tmp4, tmp4, data1a cmp to_align, #8 csel data1, tmp4, data2, lt sub tmp1, data1, zeroones orr tmp2, data1, #REP8_7f sub tmp3, data2, zeroones orr tmp4, data2, #REP8_7f #endif bic has_nul1, tmp1, tmp2 cbnz has_nul1, L(fp_le8) bic has_nul2, tmp3, tmp4 b L(fp_gt8) END (STRCPY)