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c3cf813247
This fixes compilation on 32 bit i386 with -WError. ../lib/crypto/aes_gcm_128.c:213:2: error: right shift count >= width of type [-Werror] ../lib/crypto/aes_gcm_128.c:213:2: error: left shift count >= width of type [-Werror] Signed-off-by: Douglas Bagnall <douglas.bagnall@catalyst.net.nz> Reviewed-by: Stefan Metzmacher <metze@samba.org> Reviewed-by: Andrew Bartlett <abartlet@samba.org>
191 lines
7.2 KiB
C
191 lines
7.2 KiB
C
/*
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Unix SMB/CIFS implementation.
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SMB Byte handling
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Copyright (C) Andrew Tridgell 1992-1998
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef _BYTEORDER_H
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#define _BYTEORDER_H
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/*
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This file implements macros for machine independent short and
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int manipulation
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Here is a description of this file that I emailed to the samba list once:
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> I am confused about the way that byteorder.h works in Samba. I have
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> looked at it, and I would have thought that you might make a distinction
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> between LE and BE machines, but you only seem to distinguish between 386
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> and all other architectures.
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>
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> Can you give me a clue?
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sure.
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Ok, now to the macros themselves. I'll take a simple example, say we
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want to extract a 2 byte integer from a SMB packet and put it into a
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type called uint16_t that is in the local machines byte order, and you
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want to do it with only the assumption that uint16_t is _at_least_ 16
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bits long (this last condition is very important for architectures
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that don't have any int types that are 2 bytes long)
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You do this:
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#define CVAL(buf,pos) (((uint8_t *)(buf))[pos])
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#define PVAL(buf,pos) ((unsigned int)CVAL(buf,pos))
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#define SVAL(buf,pos) (PVAL(buf,pos)|PVAL(buf,(pos)+1)<<8)
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then to extract a uint16_t value at offset 25 in a buffer you do this:
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char *buffer = foo_bar();
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uint16_t xx = SVAL(buffer,25);
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We are using the byteoder independence of the ANSI C bitshifts to do
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the work. A good optimising compiler should turn this into efficient
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code, especially if it happens to have the right byteorder :-)
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I know these macros can be made a bit tidier by removing some of the
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casts, but you need to look at byteorder.h as a whole to see the
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reasoning behind them. byteorder.h defines the following macros:
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SVAL(buf,pos) - extract a 2 byte SMB value
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IVAL(buf,pos) - extract a 4 byte SMB value
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BVAL(buf,pos) - extract a 8 byte SMB value
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SVALS(buf,pos) - signed version of SVAL()
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IVALS(buf,pos) - signed version of IVAL()
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BVALS(buf,pos) - signed version of BVAL()
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SSVAL(buf,pos,val) - put a 2 byte SMB value into a buffer
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SIVAL(buf,pos,val) - put a 4 byte SMB value into a buffer
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SBVAL(buf,pos,val) - put a 8 byte SMB value into a buffer
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SSVALS(buf,pos,val) - signed version of SSVAL()
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SIVALS(buf,pos,val) - signed version of SIVAL()
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SBVALS(buf,pos,val) - signed version of SBVAL()
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RSVAL(buf,pos) - like SVAL() but for NMB byte ordering
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RSVALS(buf,pos) - like SVALS() but for NMB byte ordering
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RIVAL(buf,pos) - like IVAL() but for NMB byte ordering
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RIVALS(buf,pos) - like IVALS() but for NMB byte ordering
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RSSVAL(buf,pos,val) - like SSVAL() but for NMB ordering
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RSIVAL(buf,pos,val) - like SIVAL() but for NMB ordering
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RSIVALS(buf,pos,val) - like SIVALS() but for NMB ordering
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it also defines lots of intermediate macros, just ignore those :-)
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*/
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/*
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* On powerpc we can use the magic instructions to load/store in little endian.
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* The instructions are reverse-indexing, so assume a big endian Power
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* processor. Power8 can be big or little endian, so we need to explicitly
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* check.
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*/
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#if (defined(__powerpc__) && defined(__GNUC__) && HAVE_BIG_ENDIAN)
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static __inline__ uint16_t ld_le16(const uint16_t *addr)
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{
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uint16_t val;
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__asm__ ("lhbrx %0,0,%1" : "=r" (val) : "r" (addr), "m" (*addr));
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return val;
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}
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static __inline__ void st_le16(uint16_t *addr, const uint16_t val)
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{
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__asm__ ("sthbrx %1,0,%2" : "=m" (*addr) : "r" (val), "r" (addr));
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}
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static __inline__ uint32_t ld_le32(const uint32_t *addr)
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{
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uint32_t val;
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__asm__ ("lwbrx %0,0,%1" : "=r" (val) : "r" (addr), "m" (*addr));
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return val;
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}
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static __inline__ void st_le32(uint32_t *addr, const uint32_t val)
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{
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__asm__ ("stwbrx %1,0,%2" : "=m" (*addr) : "r" (val), "r" (addr));
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}
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#define HAVE_ASM_BYTEORDER 1
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#else
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#define HAVE_ASM_BYTEORDER 0
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#endif
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#define CVAL(buf,pos) ((unsigned int)(((const uint8_t *)(buf))[pos]))
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#define CVAL_NC(buf,pos) (((uint8_t *)(buf))[pos]) /* Non-const version of CVAL */
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#define PVAL(buf,pos) (CVAL(buf,pos))
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#define SCVAL(buf,pos,val) (CVAL_NC(buf,pos) = (val))
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#if HAVE_ASM_BYTEORDER
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#define _PTRPOS(buf,pos) (((const uint8_t *)(buf))+(pos))
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#define SVAL(buf,pos) ld_le16((const uint16_t *)_PTRPOS(buf,pos))
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#define IVAL(buf,pos) ld_le32((const uint32_t *)_PTRPOS(buf,pos))
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#define SSVAL(buf,pos,val) st_le16((uint16_t *)_PTRPOS(buf,pos), val)
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#define SIVAL(buf,pos,val) st_le32((uint32_t *)_PTRPOS(buf,pos), val)
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#define SVALS(buf,pos) ((int16_t)SVAL(buf,pos))
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#define IVALS(buf,pos) ((int32_t)IVAL(buf,pos))
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#define SSVALS(buf,pos,val) SSVAL((buf),(pos),((int16_t)(val)))
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#define SIVALS(buf,pos,val) SIVAL((buf),(pos),((int32_t)(val)))
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#else /* not HAVE_ASM_BYTEORDER */
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#define SVAL(buf,pos) (PVAL(buf,pos)|PVAL(buf,(pos)+1)<<8)
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#define IVAL(buf,pos) (SVAL(buf,pos)|SVAL(buf,(pos)+2)<<16)
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#define SSVALX(buf,pos,val) (CVAL_NC(buf,pos)=(uint8_t)((val)&0xFF),CVAL_NC(buf,pos+1)=(uint8_t)((val)>>8))
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#define SIVALX(buf,pos,val) (SSVALX(buf,pos,val&0xFFFF),SSVALX(buf,pos+2,val>>16))
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#define SVALS(buf,pos) ((int16_t)SVAL(buf,pos))
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#define IVALS(buf,pos) ((int32_t)IVAL(buf,pos))
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#define SSVAL(buf,pos,val) SSVALX((buf),(pos),((uint16_t)(val)))
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#define SIVAL(buf,pos,val) SIVALX((buf),(pos),((uint32_t)(val)))
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#define SSVALS(buf,pos,val) SSVALX((buf),(pos),((int16_t)(val)))
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#define SIVALS(buf,pos,val) SIVALX((buf),(pos),((int32_t)(val)))
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#endif /* not HAVE_ASM_BYTEORDER */
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/* 64 bit macros */
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#define BVAL(p, ofs) (IVAL(p,ofs) | (((uint64_t)IVAL(p,(ofs)+4)) << 32))
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#define BVALS(p, ofs) ((int64_t)BVAL(p,ofs))
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#define SBVAL(p, ofs, v) (SIVAL(p,ofs,(v)&0xFFFFFFFF), SIVAL(p,(ofs)+4,((uint64_t)(v))>>32))
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#define SBVALS(p, ofs, v) (SBVAL(p,ofs,(uint64_t)v))
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/* now the reverse routines - these are used in nmb packets (mostly) */
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#define SREV(x) ((((x)&0xFF)<<8) | (((x)>>8)&0xFF))
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#define IREV(x) ((SREV(x)<<16) | (SREV((x)>>16)))
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#define BREV(x) ((IREV((uint64_t)x)<<32) | (IREV(((uint64_t)x)>>32)))
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#define RSVAL(buf,pos) SREV(SVAL(buf,pos))
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#define RSVALS(buf,pos) SREV(SVALS(buf,pos))
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#define RIVAL(buf,pos) IREV(IVAL(buf,pos))
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#define RIVALS(buf,pos) IREV(IVALS(buf,pos))
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#define RBVAL(buf,pos) BREV(BVAL(buf,pos))
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#define RBVALS(buf,pos) BREV(BVALS(buf,pos))
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#define RSSVAL(buf,pos,val) SSVAL(buf,pos,SREV(val))
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#define RSSVALS(buf,pos,val) SSVALS(buf,pos,SREV(val))
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#define RSIVAL(buf,pos,val) SIVAL(buf,pos,IREV(val))
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#define RSIVALS(buf,pos,val) SIVALS(buf,pos,IREV(val))
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#define RSBVAL(buf,pos,val) SBVAL(buf,pos,BREV(val))
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#define RSBVALS(buf,pos,val) SBVALS(buf,pos,BREV(val))
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/* Alignment macros. */
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#define ALIGN4(p,base) ((p) + ((4 - (PTR_DIFF((p), (base)) & 3)) & 3))
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#define ALIGN2(p,base) ((p) + ((2 - (PTR_DIFF((p), (base)) & 1)) & 1))
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/* macros for accessing SMB protocol elements */
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#define VWV(vwv) ((vwv)*2)
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#endif /* _BYTEORDER_H */
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