Import the skein hashing algorithm, based on the threefish block cipher

Connect it to userland (libmd, libcrypt, sbin/md5) and kernel (crypto.ko)

Support for skein as a ZFS checksum algorithm was introduced in r289422
but is disconnected because FreeBSD lacked a Skein implementation.

A further commit will enable it in ZFS.

Reviewed by:	cem
Sponsored by:	ScaleEngine Inc.
Differential Revision:	https://reviews.freebsd.org/D6166
This commit is contained in:
Allan Jude 2016-05-29 01:15:36 +00:00
commit b468a9ff1d
21 changed files with 4450 additions and 26 deletions

View File

@ -10,16 +10,25 @@ SHLIBDIR?= /lib
SHLIB_MAJOR= 5
LIB= crypt
.PATH: ${.CURDIR}/../libmd ${.CURDIR}/../../sys/crypto/sha2
.PATH: ${.CURDIR}/../libmd ${.CURDIR}/../../sys/crypto/sha2 ${.CURDIR}/../../sys/crypto/skein
SRCS= crypt.c misc.c \
crypt-md5.c md5c.c \
crypt-nthash.c md4c.c \
crypt-sha256.c sha256c.c \
crypt-sha512.c sha512c.c
crypt-sha512.c sha512c.c \
skein.c skein_block.c
MAN= crypt.3
MLINKS= crypt.3 crypt_get_format.3 crypt.3 crypt_set_format.3
CFLAGS+= -I${.CURDIR}/../libmd -I${.CURDIR}/../libutil \
-I${.CURDIR}/../../sys/crypto/sha2
-I${.CURDIR}/../../sys/crypto/sha2 -I${.CURDIR}/../../sys/crypto/skein
# Use assembly optimized skein if available
.if exists(${MACHINE_ARCH}/skein_block_asm.s)
.PATH: ${.CURDIR}/../../sys/crypto/skein/${MACHINE_ARCH}
SRCS += skein_block_asm.s
CFLAGS += -DSKEIN_ASM -DSKEIN_USE_ASM=1792 # list of block functions to replace with assembly: 256+512+1024 = 1792
ACFLAGS += -DELF -Wa,--noexecstack
.endif
# Pull in the strong crypto, if it is present.
.if exists(${.CURDIR}/../../secure/lib/libcrypt) && ${MK_CRYPT} != "no"
@ -34,7 +43,10 @@ CFLAGS+= -I${.CURDIR} -DHAS_DES -DHAS_BLOWFISH
SHA512_224_Init SHA512_224_Final SHA512_224_Update \
SHA512_256_Init SHA512_256_Final SHA512_256_Update \
SHA384_Init SHA384_Final SHA384_Update \
SHA512_Init SHA512_Final SHA512_Update
SHA512_Init SHA512_Final SHA512_Update \
SKEIN256_Init SKEIN256_Final SKEIN256_Update \
SKEIN512_Init SKEIN512_Final SKEIN512_Update \
SKEIN1024_Init SKEIN1024_Final SKEIN1024_Update
CFLAGS+= -D${sym}=__${sym}
.endfor

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@ -9,12 +9,15 @@ SRCS= md4c.c md5c.c md4hl.c md5hl.c \
sha0c.c sha0hl.c sha1c.c sha1hl.c \
sha256c.c sha256hl.c \
sha384hl.c \
sha512c.c sha512hl.c sha512thl.c
INCS= md4.h md5.h ripemd.h sha.h sha256.h sha384.h sha512.h sha512t.h
sha512c.c sha512hl.c sha512thl.c \
skein.c skein_block.c \
skein256hl.c skein512hl.c skein1024hl.c
INCS= md4.h md5.h ripemd.h sha.h sha256.h sha384.h sha512.h sha512t.h \
skein.h skein_port.h skein_freebsd.h skein_iv.h
WARNS?= 0
MAN+= md4.3 md5.3 ripemd.3 sha.3 sha256.3 sha512.3
MAN+= md4.3 md5.3 ripemd.3 sha.3 sha256.3 sha512.3 skein.3
MLINKS+=md4.3 MD4Init.3 md4.3 MD4Update.3 md4.3 MD4Final.3
MLINKS+=md4.3 MD4End.3 md4.3 MD4File.3 md4.3 MD4FileChunk.3
MLINKS+=md4.3 MD4Data.3
@ -47,11 +50,27 @@ MLINKS+=sha512.3 SHA512_256_Init.3 sha512.3 SHA512_256_Update.3
MLINKS+=sha512.3 SHA512_256_Final.3 sha512.3 SHA512_256_End.3
MLINKS+=sha512.3 SHA512_256_File.3 sha512.3 SHA512_256_FileChunk.3
MLINKS+=sha512.3 SHA512_256_Data.3
MLINKS+=skein.3 SKEIN256_Init.3 skein.3 SKEIN256_Update.3
MLINKS+=skein.3 SKEIN256_Final.3 skein.3 SKEIN256_End.3
MLINKS+=skein.3 SKEIN256_File.3 skein.3 SKEIN256_FileChunk.3
MLINKS+=skein.3 SKEIN256_Data.3 skein.3 skein256.3
MLINKS+=skein.3 SKEIN512_Init.3 skein.3 SKEIN512_Update.3
MLINKS+=skein.3 SKEIN512_Final.3 skein.3 SKEIN512_End.3
MLINKS+=skein.3 SKEIN512_File.3 skein.3 SKEIN512_FileChunk.3
MLINKS+=skein.3 SKEIN512_Data.3 skein.3 skein512.3
MLINKS+=skein.3 SKEIN1024_Init.3 skein.3 SKEIN1024_Update.3
MLINKS+=skein.3 SKEIN1024_Final.3 skein.3 SKEIN1024_End.3
MLINKS+=skein.3 SKEIN1024_File.3 skein.3 SKEIN1024_FileChunk.3
MLINKS+=skein.3 SKEIN1024_Data.3 skein.3 skein1024.3
CLEANFILES+= md[245]hl.c md[245].ref md[245].3 mddriver \
rmd160.ref rmd160hl.c rmddriver \
sha0.ref sha0hl.c sha1.ref sha1hl.c shadriver \
sha256.ref sha256hl.c sha384hl.c sha384.ref \
sha512.ref sha512hl.c sha512t256.ref sha512thl.c
sha512.ref sha512hl.c sha512t256.ref sha512thl.c \
skein256hl.c skein512hl.c skein1024hl.c \
skein256.ref skein512.ref skein1024.ref \
skeindriver
# Define WEAK_REFS to provide weak aliases for libmd symbols
#
@ -60,8 +79,10 @@ CLEANFILES+= md[245]hl.c md[245].ref md[245].3 mddriver \
# * macros are used to rename symbols to libcrypt internal names
# * no weak aliases are generated
CFLAGS+= -I${.CURDIR} -I${.CURDIR}/../../sys/crypto/sha2
CFLAGS+= -I${.CURDIR}/../../sys/crypto/skein
CFLAGS+= -DWEAK_REFS
.PATH: ${.CURDIR}/${MACHINE_ARCH} ${.CURDIR}/../../sys/crypto/sha2
.PATH: ${.CURDIR}/../../sys/crypto/skein ${.CURDIR}/../../sys/crypto/skein/${MACHINE_ARCH}
.if exists(${MACHINE_ARCH}/sha.S)
SRCS+= sha.S
@ -71,7 +92,11 @@ CFLAGS+= -DSHA1_ASM
SRCS+= rmd160.S
CFLAGS+= -DRMD160_ASM
.endif
.if exists(${MACHINE_ARCH}/sha.S) || exists(${MACHINE_ARCH}/rmd160.S)
.if exists(${MACHINE_ARCH}/skein_block_asm.s)
SRCS+= skein_block_asm.s
CFLAGS+= -DSKEIN_ASM -DSKEIN_USE_ASM=1792 # list of block functions to replace with assembly: 256+512+1024 = 1792
.endif
.if exists(${MACHINE_ARCH}/sha.S) || exists(${MACHINE_ARCH}/rmd160.S) || exists(${MACHINE_ARCH}/skein_block_asm.s)
ACFLAGS+= -DELF -Wa,--noexecstack
.endif
@ -124,6 +149,25 @@ rmd160hl.c: mdXhl.c
-e 's/RIPEMD160__/RIPEMD160_/g' \
${.ALLSRC}) > ${.TARGET}
skein256hl.c: mdXhl.c
(echo '#define LENGTH 32'; \
sed -e 's/mdX/skein/g' -e 's/MDX/SKEIN256_/g' \
-e 's/SKEIN256__/SKEIN256_/g' \
${.ALLSRC}) > ${.TARGET}
skein512hl.c: mdXhl.c
(echo '#define LENGTH 64'; \
sed -e 's/mdX/skein/g' -e 's/MDX/SKEIN512_/g' \
-e 's/SKEIN512__/SKEIN512_/g' \
${.ALLSRC}) > ${.TARGET}
skein1024hl.c: mdXhl.c
(echo '#define LENGTH 128'; \
sed -e 's/mdX/skein/g' -e 's/MDX/SKEIN1024_/g' \
-e 's/SKEIN1024__/SKEIN1024_/g' \
${.ALLSRC}) > ${.TARGET}
.for i in 2 4 5
md${i}.3: ${.CURDIR}/mdX.3
sed -e "s/mdX/md${i}/g" -e "s/MDX/MD${i}/g" ${.ALLSRC} > ${.TARGET}
@ -250,8 +294,51 @@ rmd160.ref:
@echo 'RIPEMD160 ("12345678901234567890123456789012345678901234567890123456789012345678901234567890") =' \
'9b752e45573d4b39f4dbd3323cab82bf63326bfb' >> ${.TARGET}
skein256.ref:
echo 'SKEIN256 test suite:' > ${.TARGET}
@echo 'SKEIN256 ("") = c8877087da56e072870daa843f176e9453115929094c3a40c463a196c29bf7ba' >> ${.TARGET}
@echo 'SKEIN256 ("abc") = 258bdec343b9fde1639221a5ae0144a96e552e5288753c5fec76c05fc2fc1870' >> ${.TARGET}
@echo 'SKEIN256 ("message digest") =' \
'4d2ce0062b5eb3a4db95bc1117dd8aa014f6cd50fdc8e64f31f7d41f9231e488' >> ${.TARGET}
@echo 'SKEIN256 ("abcdefghijklmnopqrstuvwxyz") =' \
'46d8440685461b00e3ddb891b2ecc6855287d2bd8834a95fb1c1708b00ea5e82' >> ${.TARGET}
@echo 'SKEIN256 ("ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789") =' \
'7c5eb606389556b33d34eb2536459528dc0af97adbcd0ce273aeb650f598d4b2' >> ${.TARGET}
@echo 'SKEIN256 ("12345678901234567890123456789012345678901234567890123456789012345678901234567890") =' \
'4def7a7e5464a140ae9c3a80279fbebce4bd00f9faad819ab7e001512f67a10d' >> ${.TARGET}
skein512.ref:
echo 'SKEIN512 test suite:' > ${.TARGET}
@echo 'SKEIN512 ("") =' \
'bc5b4c50925519c290cc634277ae3d6257212395cba733bbad37a4af0fa06af41fca7903d06564fea7a2d3730dbdb80c1f85562dfcc070334ea4d1d9e72cba7a' >> ${.TARGET}
@echo 'SKEIN512 ("abc") =' \
'8f5dd9ec798152668e35129496b029a960c9a9b88662f7f9482f110b31f9f93893ecfb25c009baad9e46737197d5630379816a886aa05526d3a70df272d96e75' >> ${.TARGET}
@echo 'SKEIN512 ("message digest") =' \
'15b73c158ffb875fed4d72801ded0794c720b121c0c78edf45f900937e6933d9e21a3a984206933d504b5dbb2368000411477ee1b204c986068df77886542fcc' >> ${.TARGET}
@echo 'SKEIN512 ("abcdefghijklmnopqrstuvwxyz") =' \
'23793ad900ef12f9165c8080da6fdfd2c8354a2929b8aadf83aa82a3c6470342f57cf8c035ec0d97429b626c4d94f28632c8f5134fd367dca5cf293d2ec13f8c' >> ${.TARGET}
@echo 'SKEIN512 ("ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789") =' \
'0c6bed927e022f5ddcf81877d42e5f75798a9f8fd3ede3d83baac0a2f364b082e036c11af35fe478745459dd8f5c0b73efe3c56ba5bb2009208d5a29cc6e469c' >> ${.TARGET}
@echo 'SKEIN512 ("12345678901234567890123456789012345678901234567890123456789012345678901234567890") =' \
'2ca9fcffb3456f297d1b5f407014ecb856f0baac8eb540f534b1f187196f21e88f31103128c2f03fcc9857d7a58eb66f9525e2302d88833ee069295537a434ce' >> ${.TARGET}
skein1024.ref:
echo 'SKEIN1024 test suite:' > ${.TARGET}
@echo 'SKEIN1024 ("") =' \
'0fff9563bb3279289227ac77d319b6fff8d7e9f09da1247b72a0a265cd6d2a62645ad547ed8193db48cff847c06494a03f55666d3b47eb4c20456c9373c86297d630d5578ebd34cb40991578f9f52b18003efa35d3da6553ff35db91b81ab890bec1b189b7f52cb2a783ebb7d823d725b0b4a71f6824e88f68f982eefc6d19c6' >> ${.TARGET}
@echo 'SKEIN1024 ("abc") =' \
'35a599a0f91abcdb4cb73c19b8cb8d947742d82c309137a7caed29e8e0a2ca7a9ff9a90c34c1908cc7e7fd99bb15032fb86e76df21b72628399b5f7c3cc209d7bb31c99cd4e19465622a049afbb87c03b5ce3888d17e6e667279ec0aa9b3e2712624c01b5f5bbe1a564220bdcf6990af0c2539019f313fdd7406cca3892a1f1f' >> ${.TARGET}
@echo 'SKEIN1024 ("message digest") =' \
'ea891f5268acd0fac97467fc1aa89d1ce8681a9992a42540e53babee861483110c2d16f49e73bac27653ff173003e40cfb08516cd34262e6af95a5d8645c9c1abb3e813604d508b8511b30f9a5c1b352aa0791c7d2f27b2706dccea54bc7de6555b5202351751c3299f97c09cf89c40f67187e2521c0fad82b30edbb224f0458' >> ${.TARGET}
@echo 'SKEIN1024 ("abcdefghijklmnopqrstuvwxyz") =' \
'f23d95c2a25fbcd0e797cd058fec39d3c52d2b5afd7a9af1df934e63257d1d3dcf3246e7329c0f1104c1e51e3d22e300507b0c3b9f985bb1f645ef49835080536becf83788e17fed09c9982ba65c3cb7ffe6a5f745b911c506962adf226e435c42f6f6bc08d288f9c810e807e3216ef444f3db22744441deefa4900982a1371f' >> ${.TARGET}
@echo 'SKEIN1024 ("ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789") =' \
'cf3889e8a8d11bfd3938055d7d061437962bc5eac8ae83b1b71c94be201b8cf657fdbfc38674997a008c0c903f56a23feb3ae30e012377f1cfa080a9ca7fe8b96138662653fb3335c7d06595bf8baf65e215307532094cfdfa056bd8052ab792a3944a2adaa47b30335b8badb8fe9eb94fe329cdca04e58bbc530f0af709f469' >> ${.TARGET}
@echo 'SKEIN1024 ("12345678901234567890123456789012345678901234567890123456789012345678901234567890") =' \
'cf21a613620e6c119eca31fdfaad449a8e02f95ca256c21d2a105f8e4157048f9fe1e897893ea18b64e0e37cb07d5ac947f27ba544caf7cbc1ad094e675aed77a366270f7eb7f46543bccfa61c526fd628408058ed00ed566ac35a9761d002e629c4fb0d430b2f4ad016fcc49c44d2981c4002da0eecc42144160e2eaea4855a' >> ${.TARGET}
test: md4.ref md5.ref sha0.ref rmd160.ref sha1.ref sha256.ref sha384.ref \
sha512.ref sha512t256.ref
sha512.ref sha512t256.ref skein256.ref skein512.ref skein1024.ref
@${ECHO} if any of these test fail, the code produces wrong results
@${ECHO} and should NOT be used.
${CC} ${CFLAGS} ${LDFLAGS} -DMD=4 -o mddriver ${.CURDIR}/mddriver.c libmd.a
@ -284,5 +371,15 @@ test: md4.ref md5.ref sha0.ref rmd160.ref sha1.ref sha256.ref sha384.ref \
./shadriver | cmp sha512t256.ref -
@${ECHO} SHA-512t256 passed test
-rm -f shadriver
${CC} ${CFLAGS} ${LDFLAGS} -DSKEIN=256 -o skeindriver ${.CURDIR}/skeindriver.c libmd.a
./skeindriver | cmp skein256.ref -
@${ECHO} SKEIN256 passed test
${CC} ${CFLAGS} ${LDFLAGS} -DSKEIN=512 -o skeindriver ${.CURDIR}/skeindriver.c libmd.a
./skeindriver | cmp skein512.ref -
@${ECHO} SKEIN512 passed test
${CC} ${CFLAGS} ${LDFLAGS} -DSKEIN=1024 -o skeindriver ${.CURDIR}/skeindriver.c libmd.a
./skeindriver | cmp skein1024.ref -
@${ECHO} SKEIN1024 passed test
-rm -f skeindriver
.include <bsd.lib.mk>

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@ -8,7 +8,7 @@
.\"
.\" $FreeBSD$
.\"
.Dd February 11, 1999
.Dd April 26, 2016
.Dt MDX 3
.Os
.Sh NAME
@ -145,7 +145,11 @@ argument is non-null it must point to at least 33 characters of buffer space.
.Sh SEE ALSO
.Xr md4 3 ,
.Xr md5 3 ,
.Xr sha 3
.Xr ripemd 3 ,
.Xr sha 3 ,
.Xr sha256 3 ,
.Xr sha512 3 ,
.Xr skein 3
.Rs
.%A R. Rivest
.%T The MD4 Message-Digest Algorithm

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@ -9,7 +9,7 @@
.\" From: Id: mdX.3,v 1.14 1999/02/11 20:31:49 wollman Exp
.\" $FreeBSD$
.\"
.Dd March 28, 2014
.Dd April 26, 2016
.Dt RIPEMD 3
.Os
.Sh NAME
@ -125,7 +125,10 @@ argument is non-null it must point to at least 41 characters of buffer space.
.Sh SEE ALSO
.Xr md4 3 ,
.Xr md5 3 ,
.Xr sha 3
.Xr sha 3 ,
.Xr sha256 3 ,
.Xr sha512 3 ,
.Xr skein 3
.Sh HISTORY
These functions appeared in
.Fx 4.0 .

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@ -9,7 +9,7 @@
.\" From: Id: mdX.3,v 1.14 1999/02/11 20:31:49 wollman Exp
.\" $FreeBSD$
.\"
.Dd March 28, 2014
.Dd April 26, 2016
.Dt SHA 3
.Os
.Sh NAME
@ -157,7 +157,9 @@ argument is non-null it must point to at least 41 characters of buffer space.
.Xr md4 3 ,
.Xr md5 3 ,
.Xr ripemd 3 ,
.Xr sha256 3
.Xr sha256 3 ,
.Xr sha512 3 ,
.Xr skein 3
.Sh HISTORY
These functions appeared in
.Fx 4.0 .

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@ -9,7 +9,7 @@
.\" From: Id: mdX.3,v 1.14 1999/02/11 20:31:49 wollman Exp
.\" $FreeBSD$
.\"
.Dd March 28, 2014
.Dd April 26, 2016
.Dt SHA256 3
.Os
.Sh NAME
@ -123,7 +123,10 @@ argument is non-null it must point to at least 65 characters of buffer space.
.Xr md4 3 ,
.Xr md5 3 ,
.Xr ripemd 3 ,
.Xr sha 3
.Xr sha 3 ,
.Xr sha256 3 ,
.Xr sha512 3 ,
.Xr skein 3
.Sh HISTORY
These functions appeared in
.Fx 6.0 .

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@ -192,7 +192,10 @@ string which represents the 256 bits in hexadecimal.
.Xr md4 3 ,
.Xr md5 3 ,
.Xr ripemd 3 ,
.Xr sha 3
.Xr sha 3 ,
.Xr sha256 3 ,
.Xr sha512 3 ,
.Xr skein 3
.Sh HISTORY
These functions appeared in
.Fx 9.0 .

214
lib/libmd/skein.3 Normal file
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@ -0,0 +1,214 @@
.\"-
.\" Copyright (c) 2016 Allan Jude
.\" All rights reserved.
.\"
.\" Redistribution and use in source and binary forms, with or without
.\" modification, are permitted provided that the following conditions
.\" are met:
.\" 1. Redistributions of source code must retain the above copyright
.\" notice, this list of conditions and the following disclaimer.
.\" 2. Redistributions in binary form must reproduce the above copyright
.\" notice, this list of conditions and the following disclaimer in the
.\" documentation and/or other materials provided with the distribution.
.\"
.\" THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
.\" ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
.\" SUCH DAMAGE.
.\"
.\" $FreeBSD$
.\"
.Dd May 28, 2016
.Dt SKEIN 3
.Os
.Sh NAME
.Nm SKEIN256_Init ,
.Nm SKEIN256_Update ,
.Nm SKEIN256_Final ,
.Nm SKEIN256_End ,
.Nm SKEIN256_File ,
.Nm SKEIN256_FileChunk ,
.Nm SKEIN256_Data ,
.Nm SKEIN512_Init ,
.Nm SKEIN512_Update ,
.Nm SKEIN512_Final ,
.Nm SKEIN512_End ,
.Nm SKEIN512_File ,
.Nm SKEIN512_FileChunk ,
.Nm SKEIN512_Data ,
.Nm SKEIN1024_Init ,
.Nm SKEIN1024_Update ,
.Nm SKEIN1024_Final ,
.Nm SKEIN1024_End ,
.Nm SKEIN1024_File ,
.Nm SKEIN1024_FileChunk ,
.Nm SKEIN1024_Data
.Nd calculate the ``SKEIN'' family of message digests
.Sh LIBRARY
.Lb libmd
.Sh SYNOPSIS
.In sys/types.h
.In skein.h
.Ft void
.Fn SKEIN256_Init "SKEIN256_CTX *context"
.Ft void
.Fn SKEIN256_Update "SKEIN256_CTX *context" "const unsigned char *data" "size_t len"
.Ft void
.Fn SKEIN256_Final "unsigned char digest[32]" "SKEIN256_CTX *context"
.Ft "char *"
.Fn SKEIN256_End "SKEIN256_CTX *context" "char *buf"
.Ft "char *"
.Fn SKEIN256_File "const char *filename" "char *buf"
.Ft "char *"
.Fn SKEIN256_FileChunk "const char *filename" "char *buf" "off_t offset" "off_t length"
.Ft "char *"
.Fn SKEIN256_Data "const unsigned char *data" "unsigned int len" "char *buf"
.Ft void
.Fn SKEIN512_Init "SKEIN512_CTX *context"
.Ft void
.Fn SKEIN512_Update "SKEIN512_CTX *context" "const unsigned char *data" "size_t len"
.Ft void
.Fn SKEIN512_Final "unsigned char digest[64]" "SKEIN512_CTX *context"
.Ft "char *"
.Fn SKEIN512_End "SKEIN512_CTX *context" "char *buf"
.Ft "char *"
.Fn SKEIN512_File "const char *filename" "char *buf"
.Ft "char *"
.Fn SKEIN512_FileChunk "const char *filename" "char *buf" "off_t offset" "off_t length"
.Ft "char *"
.Fn SKEIN512_Data "const unsigned char *data" "unsigned int len" "char *buf"
.Ft void
.Fn SKEIN1024_Init "SKEIN1024_CTX *context"
.Ft void
.Fn SKEIN1024_Update "SKEIN1024_CTX *context" "const unsigned char *data" "size_t len"
.Ft void
.Fn SKEIN1024_Final "unsigned char digest[128]" "SKEIN1024_CTX *context"
.Ft "char *"
.Fn SKEIN1024_End "SKEIN1024_CTX *context" "char *buf"
.Ft "char *"
.Fn SKEIN1024_File "const char *filename" "char *buf"
.Ft "char *"
.Fn SKEIN1024_FileChunk "const char *filename" "char *buf" "off_t offset" "off_t length"
.Ft "char *"
.Fn SKEIN1024_Data "const unsigned char *data" "unsigned int len" "char *buf"
.Sh DESCRIPTION
.Li Skein
is a new family of cryptographic hash functions based on the
.Li Threefish
large-block cipher.
Its design combines speed, security, simplicity, and a great deal of
flexibility in a modular package that is easy to analyze.
.Li Skein
is defined for three different internal state sizes\(em256 bits, 512 bits, and
1024 bits\(emand any output size.
This allows Skein to be a drop-in replacement for the entire SHA family
of hash functions.
.Pp
The
.Fn SKEIN256_Init ,
.Fn SKEIN256_Update ,
and
.Fn SKEIN256_Final
functions are the core functions.
Allocate an
.Vt SKEIN256_CTX ,
initialize it with
.Fn SKEIN256_Init ,
run over the data with
.Fn SKEIN256_Update ,
and finally extract the result using
.Fn SKEIN256_Final .
.Pp
.Fn SKEIN256_End
is a wrapper for
.Fn SKEIN256_Final
which converts the return value to a 33-character
(including the terminating '\e0')
.Tn ASCII
string which represents the 256 bits in hexadecimal.
.Pp
.Fn SKEIN256_File
calculates the digest of a file, and uses
.Fn SKEIN256_End
to return the result.
If the file cannot be opened, a null pointer is returned.
.Fn SKEIN256_FileChunk
is similar to
.Fn SKEIN256_File ,
but it only calculates the digest over a byte-range of the file specified,
starting at
.Fa offset
and spanning
.Fa length
bytes.
If the
.Fa length
parameter is specified as 0, or more than the length of the remaining part
of the file,
.Fn SKEIN256_FileChunk
calculates the digest from
.Fa offset
to the end of file.
.Fn SKEIN256_Data
calculates the digest of a chunk of data in memory, and uses
.Fn SKEIN256_End
to return the result.
.Pp
When using
.Fn SKEIN256_End ,
.Fn SKEIN256_File ,
or
.Fn SKEIN256_Data ,
the
.Fa buf
argument can be a null pointer, in which case the returned string
is allocated with
.Xr malloc 3
and subsequently must be explicitly deallocated using
.Xr free 3
after use.
If the
.Fa buf
argument is non-null it must point to at least 33 characters of buffer space.
.Pp
The
.Li SKEIN512_
and
.Li SKEIN1024_
functions are similar to the
.Li SKEIN256_
functions except they produce a 512-bit, 65 character,
or 1024-bit, 129 character, output.
.Sh SEE ALSO
.Xr md4 3 ,
.Xr md5 3 ,
.Xr ripemd 3 ,
.Xr sha 3 ,
.Xr sha256 3 ,
.Xr sha512 3
.Sh HISTORY
These functions appeared in
.Fx 11.0 .
.Sh AUTHORS
.An -nosplit
The core hash routines were imported from version 1.3 of the optimized
Skein reference implementation written by
.An Doug Whiting
as submitted to the NSA SHA-3 contest.
The algorithms were developed by
.An Niels Ferguson ,
.An Stefan Lucks ,
.An Bruce Schneier ,
.An Doug Whiting ,
.An Mihir Bellare ,
.An Tadayoshi Kohno ,
.An Jon Callas,
and
.An Jesse Walker .

68
lib/libmd/skeindriver.c Normal file
View File

@ -0,0 +1,68 @@
/* SKEINDRIVER.C - test driver for SKEIN */
/* Copyright (C) 1990-2, RSA Data Security, Inc. Created 1990. All rights
* reserved.
*
* RSA Data Security, Inc. makes no representations concerning either the
* merchantability of this software or the suitability of this software for
* any particular purpose. It is provided "as is" without express or implied
* warranty of any kind.
*
* These notices must be retained in any copies of any part of this
* documentation and/or software. */
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/types.h>
#include <stdio.h>
#include <time.h>
#include <string.h>
#include "skein.h"
/* The following makes SKEIN default to SKEIN512 if it has not already been
* defined with C compiler flags. */
#ifndef SKEIN
#define SKEIN 512
#endif
#if SKEIN == 256
#undef SKEIN_Data
#define SKEIN_Data SKEIN256_Data
#elif SKEIN == 512
#undef SKEIN_Data
#define SKEIN_Data SKEIN512_Data
#elif SKEIN == 1024
#undef SKEIN_Data
#define SKEIN_Data SKEIN1024_Data
#endif
/* Digests a string and prints the result. */
static void
SKEINString(char *string)
{
char buf[2*128 + 1];
printf("SKEIN%d (\"%s\") = %s\n",
SKEIN, string, SKEIN_Data(string, strlen(string), buf));
}
/* Digests a reference suite of strings and prints the results. */
int
main(void)
{
printf("SKEIN%d test suite:\n", SKEIN);
SKEINString("");
SKEINString("abc");
SKEINString("message digest");
SKEINString("abcdefghijklmnopqrstuvwxyz");
SKEINString("ABCDEFGHIJKLMNOPQRSTUVWXYZ"
"abcdefghijklmnopqrstuvwxyz0123456789");
SKEINString("1234567890123456789012345678901234567890"
"1234567890123456789012345678901234567890");
return 0;
}

View File

@ -9,14 +9,20 @@ LINKS= ${BINDIR}/md5 ${BINDIR}/rmd160 \
${BINDIR}/md5 ${BINDIR}/sha256 \
${BINDIR}/md5 ${BINDIR}/sha384 \
${BINDIR}/md5 ${BINDIR}/sha512 \
${BINDIR}/md5 ${BINDIR}/sha512t256
${BINDIR}/md5 ${BINDIR}/sha512t256 \
${BINDIR}/md5 ${BINDIR}/skein256 \
${BINDIR}/md5 ${BINDIR}/skein512 \
${BINDIR}/md5 ${BINDIR}/skein1024
MLINKS= md5.1 rmd160.1 \
md5.1 sha1.1 \
md5.1 sha256.1 \
md5.1 sha384.1 \
md5.1 sha512.1 \
md5.1 sha512t256.1
md5.1 sha512t256.1 \
md5.1 skein256.1 \
md5.1 skein512.1 \
md5.1 skein1024.1
LIBADD= md

View File

@ -31,6 +31,7 @@ __FBSDID("$FreeBSD$");
#include <sha384.h>
#include <sha512.h>
#include <sha512t.h>
#include <skein.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
@ -61,6 +62,9 @@ extern const char *SHA384_TestOutput[MDTESTCOUNT];
extern const char *SHA512_TestOutput[MDTESTCOUNT];
extern const char *SHA512t256_TestOutput[MDTESTCOUNT];
extern const char *RIPEMD160_TestOutput[MDTESTCOUNT];
extern const char *SKEIN256_TestOutput[MDTESTCOUNT];
extern const char *SKEIN512_TestOutput[MDTESTCOUNT];
extern const char *SKEIN1024_TestOutput[MDTESTCOUNT];
typedef struct Algorithm_t {
const char *progname;
@ -87,12 +91,15 @@ typedef union {
SHA384_CTX sha384;
SHA512_CTX sha512;
RIPEMD160_CTX ripemd160;
SKEIN256_CTX skein256;
SKEIN512_CTX skein512;
SKEIN1024_CTX skein1024;
} DIGEST_CTX;
/* max(MD5_DIGEST_LENGTH, SHA_DIGEST_LENGTH,
SHA256_DIGEST_LENGTH, SHA512_DIGEST_LENGTH,
RIPEMD160_DIGEST_LENGTH)*2+1 */
#define HEX_DIGEST_LENGTH 129
RIPEMD160_DIGEST_LENGTH, SKEIN1024_DIGEST_LENGTH)*2+1 */
#define HEX_DIGEST_LENGTH 257
/* algorithm function table */
@ -117,7 +124,16 @@ static const struct Algorithm_t Algorithm[] = {
&SHA512_256_Data, &SHA512_256_File },
{ "rmd160", "RMD160", &RIPEMD160_TestOutput,
(DIGEST_Init*)&RIPEMD160_Init, (DIGEST_Update*)&RIPEMD160_Update,
(DIGEST_End*)&RIPEMD160_End, &RIPEMD160_Data, &RIPEMD160_File }
(DIGEST_End*)&RIPEMD160_End, &RIPEMD160_Data, &RIPEMD160_File },
{ "skein256", "Skein256", &SKEIN256_TestOutput,
(DIGEST_Init*)&SKEIN256_Init, (DIGEST_Update*)&SKEIN256_Update,
(DIGEST_End*)&SKEIN256_End, &SKEIN256_Data, &SKEIN256_File },
{ "skein512", "Skein512", &SKEIN512_TestOutput,
(DIGEST_Init*)&SKEIN512_Init, (DIGEST_Update*)&SKEIN512_Update,
(DIGEST_End*)&SKEIN512_End, &SKEIN512_Data, &SKEIN512_File },
{ "skein1024", "Skein1024", &SKEIN1024_TestOutput,
(DIGEST_Init*)&SKEIN1024_Init, (DIGEST_Update*)&SKEIN1024_Update,
(DIGEST_End*)&SKEIN1024_End, &SKEIN1024_Data, &SKEIN1024_File }
};
static void
@ -286,8 +302,8 @@ MDTimeTrial(const Algorithm_t *alg)
printf(" done\n");
printf("Digest = %s", p);
printf("\nTime = %f seconds\n", seconds);
printf("Speed = %f bytes/second\n",
(float) TEST_BLOCK_LEN * (float) TEST_BLOCK_COUNT / seconds);
printf("Speed = %f MiB/second\n", (float) TEST_BLOCK_LEN *
(float) TEST_BLOCK_COUNT / seconds / (1 << 20));
}
/*
* Digests a reference suite of strings and prints the results.
@ -382,6 +398,39 @@ const char *RIPEMD160_TestOutput[MDTESTCOUNT] = {
"5feb69c6bf7c29d95715ad55f57d8ac5b2b7dd32"
};
const char *SKEIN256_TestOutput[MDTESTCOUNT] = {
"c8877087da56e072870daa843f176e9453115929094c3a40c463a196c29bf7ba",
"7fba44ff1a31d71a0c1f82e6e82fb5e9ac6c92a39c9185b9951fed82d82fe635",
"258bdec343b9fde1639221a5ae0144a96e552e5288753c5fec76c05fc2fc1870",
"4d2ce0062b5eb3a4db95bc1117dd8aa014f6cd50fdc8e64f31f7d41f9231e488",
"46d8440685461b00e3ddb891b2ecc6855287d2bd8834a95fb1c1708b00ea5e82",
"7c5eb606389556b33d34eb2536459528dc0af97adbcd0ce273aeb650f598d4b2",
"4def7a7e5464a140ae9c3a80279fbebce4bd00f9faad819ab7e001512f67a10d",
"d9c017dbe355f318d036469eb9b5fbe129fc2b5786a9dc6746a516eab6fe0126"
};
const char *SKEIN512_TestOutput[MDTESTCOUNT] = {
"bc5b4c50925519c290cc634277ae3d6257212395cba733bbad37a4af0fa06af41fca7903d06564fea7a2d3730dbdb80c1f85562dfcc070334ea4d1d9e72cba7a",
"b1cd8d33f61b3737adfd59bb13ad82f4a9548e92f22956a8976cca3fdb7fee4fe91698146c4197cec85d38b83c5d93bdba92c01fd9a53870d0c7f967bc62bdce",
"8f5dd9ec798152668e35129496b029a960c9a9b88662f7f9482f110b31f9f93893ecfb25c009baad9e46737197d5630379816a886aa05526d3a70df272d96e75",
"15b73c158ffb875fed4d72801ded0794c720b121c0c78edf45f900937e6933d9e21a3a984206933d504b5dbb2368000411477ee1b204c986068df77886542fcc",
"23793ad900ef12f9165c8080da6fdfd2c8354a2929b8aadf83aa82a3c6470342f57cf8c035ec0d97429b626c4d94f28632c8f5134fd367dca5cf293d2ec13f8c",
"0c6bed927e022f5ddcf81877d42e5f75798a9f8fd3ede3d83baac0a2f364b082e036c11af35fe478745459dd8f5c0b73efe3c56ba5bb2009208d5a29cc6e469c",
"2ca9fcffb3456f297d1b5f407014ecb856f0baac8eb540f534b1f187196f21e88f31103128c2f03fcc9857d7a58eb66f9525e2302d88833ee069295537a434ce",
"1131f2aaa0e97126c9314f9f968cc827259bbfabced2943bb8c9274448998fb3b78738b4580dd500c76105fd3c03e465e1414f2c29664286b1f79d3e51128125"
};
const char *SKEIN1024_TestOutput[MDTESTCOUNT] = {
"0fff9563bb3279289227ac77d319b6fff8d7e9f09da1247b72a0a265cd6d2a62645ad547ed8193db48cff847c06494a03f55666d3b47eb4c20456c9373c86297d630d5578ebd34cb40991578f9f52b18003efa35d3da6553ff35db91b81ab890bec1b189b7f52cb2a783ebb7d823d725b0b4a71f6824e88f68f982eefc6d19c6",
"6ab4c4ba9814a3d976ec8bffa7fcc638ceba0544a97b3c98411323ffd2dc936315d13dc93c13c4e88cda6f5bac6f2558b2d8694d3b6143e40d644ae43ca940685cb37f809d3d0550c56cba8036dee729a4f8fb960732e59e64d57f7f7710f8670963cdcdc95b41daab4855fcf8b6762a64b173ee61343a2c7689af1d293eba97",
"35a599a0f91abcdb4cb73c19b8cb8d947742d82c309137a7caed29e8e0a2ca7a9ff9a90c34c1908cc7e7fd99bb15032fb86e76df21b72628399b5f7c3cc209d7bb31c99cd4e19465622a049afbb87c03b5ce3888d17e6e667279ec0aa9b3e2712624c01b5f5bbe1a564220bdcf6990af0c2539019f313fdd7406cca3892a1f1f",
"ea891f5268acd0fac97467fc1aa89d1ce8681a9992a42540e53babee861483110c2d16f49e73bac27653ff173003e40cfb08516cd34262e6af95a5d8645c9c1abb3e813604d508b8511b30f9a5c1b352aa0791c7d2f27b2706dccea54bc7de6555b5202351751c3299f97c09cf89c40f67187e2521c0fad82b30edbb224f0458",
"f23d95c2a25fbcd0e797cd058fec39d3c52d2b5afd7a9af1df934e63257d1d3dcf3246e7329c0f1104c1e51e3d22e300507b0c3b9f985bb1f645ef49835080536becf83788e17fed09c9982ba65c3cb7ffe6a5f745b911c506962adf226e435c42f6f6bc08d288f9c810e807e3216ef444f3db22744441deefa4900982a1371f",
"cf3889e8a8d11bfd3938055d7d061437962bc5eac8ae83b1b71c94be201b8cf657fdbfc38674997a008c0c903f56a23feb3ae30e012377f1cfa080a9ca7fe8b96138662653fb3335c7d06595bf8baf65e215307532094cfdfa056bd8052ab792a3944a2adaa47b30335b8badb8fe9eb94fe329cdca04e58bbc530f0af709f469",
"cf21a613620e6c119eca31fdfaad449a8e02f95ca256c21d2a105f8e4157048f9fe1e897893ea18b64e0e37cb07d5ac947f27ba544caf7cbc1ad094e675aed77a366270f7eb7f46543bccfa61c526fd628408058ed00ed566ac35a9761d002e629c4fb0d430b2f4ad016fcc49c44d2981c4002da0eecc42144160e2eaea4855a",
"e6799b78db54085a2be7ff4c8007f147fa88d326abab30be0560b953396d8802feee9a15419b48a467574e9283be15685ca8a079ee52b27166b64dd70b124b1d4e4f6aca37224c3f2685e67e67baef9f94b905698adc794a09672aba977a61b20966912acdb08c21a2c37001785355dc884751a21f848ab36e590331ff938138"
};
static void
MDTestSuite(const Algorithm_t *alg)
{

File diff suppressed because it is too large Load Diff

858
sys/crypto/skein/skein.c Normal file
View File

@ -0,0 +1,858 @@
/***********************************************************************
**
** Implementation of the Skein hash function.
**
** Source code author: Doug Whiting, 2008.
**
** This algorithm and source code is released to the public domain.
**
************************************************************************/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/endian.h>
#include <sys/types.h>
/* get the memcpy/memset functions */
#ifdef _KERNEL
#include <sys/systm.h>
#else
#include <string.h>
#endif
#define SKEIN_PORT_CODE /* instantiate any code in skein_port.h */
#include "skein.h" /* get the Skein API definitions */
#include "skein_iv.h" /* get precomputed IVs */
/*****************************************************************/
/* External function to process blkCnt (nonzero) full block(s) of data. */
void Skein_256_Process_Block(Skein_256_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd);
void Skein_512_Process_Block(Skein_512_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd);
void Skein1024_Process_Block(Skein1024_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd);
/*****************************************************************/
/* 256-bit Skein */
/*****************************************************************/
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* init the context for a straight hashing operation */
int Skein_256_Init(Skein_256_Ctxt_t *ctx, size_t hashBitLen)
{
union
{
u08b_t b[SKEIN_256_STATE_BYTES];
u64b_t w[SKEIN_256_STATE_WORDS];
} cfg; /* config block */
Skein_Assert(hashBitLen > 0,SKEIN_BAD_HASHLEN);
ctx->h.hashBitLen = hashBitLen; /* output hash bit count */
switch (hashBitLen)
{ /* use pre-computed values, where available */
#ifndef SKEIN_NO_PRECOMP
case 256: memcpy(ctx->X,SKEIN_256_IV_256,sizeof(ctx->X)); break;
case 224: memcpy(ctx->X,SKEIN_256_IV_224,sizeof(ctx->X)); break;
case 160: memcpy(ctx->X,SKEIN_256_IV_160,sizeof(ctx->X)); break;
case 128: memcpy(ctx->X,SKEIN_256_IV_128,sizeof(ctx->X)); break;
#endif
default:
/* here if there is no precomputed IV value available */
/* build/process the config block, type == CONFIG (could be precomputed) */
Skein_Start_New_Type(ctx,CFG_FINAL); /* set tweaks: T0=0; T1=CFG | FINAL */
cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); /* set the schema, version */
cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */
cfg.w[2] = Skein_Swap64(SKEIN_CFG_TREE_INFO_SEQUENTIAL);
memset(&cfg.w[3],0,sizeof(cfg) - 3*sizeof(cfg.w[0])); /* zero pad config block */
/* compute the initial chaining values from config block */
memset(ctx->X,0,sizeof(ctx->X)); /* zero the chaining variables */
Skein_256_Process_Block(ctx,cfg.b,1,SKEIN_CFG_STR_LEN);
break;
}
/* The chaining vars ctx->X are now initialized for the given hashBitLen. */
/* Set up to process the data message portion of the hash (default) */
Skein_Start_New_Type(ctx,MSG); /* T0=0, T1= MSG type */
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* init the context for a MAC and/or tree hash operation */
/* [identical to Skein_256_Init() when keyBytes == 0 && treeInfo == SKEIN_CFG_TREE_INFO_SEQUENTIAL] */
int Skein_256_InitExt(Skein_256_Ctxt_t *ctx,size_t hashBitLen,u64b_t treeInfo, const u08b_t *key, size_t keyBytes)
{
union
{
u08b_t b[SKEIN_256_STATE_BYTES];
u64b_t w[SKEIN_256_STATE_WORDS];
} cfg; /* config block */
Skein_Assert(hashBitLen > 0,SKEIN_BAD_HASHLEN);
Skein_Assert(keyBytes == 0 || key != NULL,SKEIN_FAIL);
/* compute the initial chaining values ctx->X[], based on key */
if (keyBytes == 0) /* is there a key? */
{
memset(ctx->X,0,sizeof(ctx->X)); /* no key: use all zeroes as key for config block */
}
else /* here to pre-process a key */
{
Skein_assert(sizeof(cfg.b) >= sizeof(ctx->X));
/* do a mini-Init right here */
ctx->h.hashBitLen=8*sizeof(ctx->X); /* set output hash bit count = state size */
Skein_Start_New_Type(ctx,KEY); /* set tweaks: T0 = 0; T1 = KEY type */
memset(ctx->X,0,sizeof(ctx->X)); /* zero the initial chaining variables */
Skein_256_Update(ctx,key,keyBytes); /* hash the key */
Skein_256_Final_Pad(ctx,cfg.b); /* put result into cfg.b[] */
memcpy(ctx->X,cfg.b,sizeof(cfg.b)); /* copy over into ctx->X[] */
#if SKEIN_NEED_SWAP
{
uint_t i;
for (i=0;i<SKEIN_256_STATE_WORDS;i++) /* convert key bytes to context words */
ctx->X[i] = Skein_Swap64(ctx->X[i]);
}
#endif
}
/* build/process the config block, type == CONFIG (could be precomputed for each key) */
ctx->h.hashBitLen = hashBitLen; /* output hash bit count */
Skein_Start_New_Type(ctx,CFG_FINAL);
memset(&cfg.w,0,sizeof(cfg.w)); /* pre-pad cfg.w[] with zeroes */
cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER);
cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */
cfg.w[2] = Skein_Swap64(treeInfo); /* tree hash config info (or SKEIN_CFG_TREE_INFO_SEQUENTIAL) */
Skein_Show_Key(256,&ctx->h,key,keyBytes);
/* compute the initial chaining values from config block */
Skein_256_Process_Block(ctx,cfg.b,1,SKEIN_CFG_STR_LEN);
/* The chaining vars ctx->X are now initialized */
/* Set up to process the data message portion of the hash (default) */
ctx->h.bCnt = 0; /* buffer b[] starts out empty */
Skein_Start_New_Type(ctx,MSG);
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* process the input bytes */
int Skein_256_Update(Skein_256_Ctxt_t *ctx, const u08b_t *msg, size_t msgByteCnt)
{
size_t n;
Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
/* process full blocks, if any */
if (msgByteCnt + ctx->h.bCnt > SKEIN_256_BLOCK_BYTES)
{
if (ctx->h.bCnt) /* finish up any buffered message data */
{
n = SKEIN_256_BLOCK_BYTES - ctx->h.bCnt; /* # bytes free in buffer b[] */
if (n)
{
Skein_assert(n < msgByteCnt); /* check on our logic here */
memcpy(&ctx->b[ctx->h.bCnt],msg,n);
msgByteCnt -= n;
msg += n;
ctx->h.bCnt += n;
}
Skein_assert(ctx->h.bCnt == SKEIN_256_BLOCK_BYTES);
Skein_256_Process_Block(ctx,ctx->b,1,SKEIN_256_BLOCK_BYTES);
ctx->h.bCnt = 0;
}
/* now process any remaining full blocks, directly from input message data */
if (msgByteCnt > SKEIN_256_BLOCK_BYTES)
{
n = (msgByteCnt-1) / SKEIN_256_BLOCK_BYTES; /* number of full blocks to process */
Skein_256_Process_Block(ctx,msg,n,SKEIN_256_BLOCK_BYTES);
msgByteCnt -= n * SKEIN_256_BLOCK_BYTES;
msg += n * SKEIN_256_BLOCK_BYTES;
}
Skein_assert(ctx->h.bCnt == 0);
}
/* copy any remaining source message data bytes into b[] */
if (msgByteCnt)
{
Skein_assert(msgByteCnt + ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES);
memcpy(&ctx->b[ctx->h.bCnt],msg,msgByteCnt);
ctx->h.bCnt += msgByteCnt;
}
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* finalize the hash computation and output the result */
int Skein_256_Final(Skein_256_Ctxt_t *ctx, u08b_t *hashVal)
{
size_t i,n,byteCnt;
u64b_t X[SKEIN_256_STATE_WORDS];
Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */
if (ctx->h.bCnt < SKEIN_256_BLOCK_BYTES) /* zero pad b[] if necessary */
memset(&ctx->b[ctx->h.bCnt],0,SKEIN_256_BLOCK_BYTES - ctx->h.bCnt);
Skein_256_Process_Block(ctx,ctx->b,1,ctx->h.bCnt); /* process the final block */
/* now output the result */
byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* total number of output bytes */
/* run Threefish in "counter mode" to generate output */
memset(ctx->b,0,sizeof(ctx->b)); /* zero out b[], so it can hold the counter */
memcpy(X,ctx->X,sizeof(X)); /* keep a local copy of counter mode "key" */
for (i=0;i*SKEIN_256_BLOCK_BYTES < byteCnt;i++)
{
((u64b_t *)ctx->b)[0]= Skein_Swap64((u64b_t) i); /* build the counter block */
Skein_Start_New_Type(ctx,OUT_FINAL);
Skein_256_Process_Block(ctx,ctx->b,1,sizeof(u64b_t)); /* run "counter mode" */
n = byteCnt - i*SKEIN_256_BLOCK_BYTES; /* number of output bytes left to go */
if (n >= SKEIN_256_BLOCK_BYTES)
n = SKEIN_256_BLOCK_BYTES;
Skein_Put64_LSB_First(hashVal+i*SKEIN_256_BLOCK_BYTES,ctx->X,n); /* "output" the ctr mode bytes */
Skein_Show_Final(256,&ctx->h,n,hashVal+i*SKEIN_256_BLOCK_BYTES);
memcpy(ctx->X,X,sizeof(X)); /* restore the counter mode key for next time */
}
return SKEIN_SUCCESS;
}
#if defined(SKEIN_CODE_SIZE) || defined(SKEIN_PERF)
size_t Skein_256_API_CodeSize(void)
{
return ((u08b_t *) Skein_256_API_CodeSize) -
((u08b_t *) Skein_256_Init);
}
#endif
/*****************************************************************/
/* 512-bit Skein */
/*****************************************************************/
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* init the context for a straight hashing operation */
int Skein_512_Init(Skein_512_Ctxt_t *ctx, size_t hashBitLen)
{
union
{
u08b_t b[SKEIN_512_STATE_BYTES];
u64b_t w[SKEIN_512_STATE_WORDS];
} cfg; /* config block */
Skein_Assert(hashBitLen > 0,SKEIN_BAD_HASHLEN);
ctx->h.hashBitLen = hashBitLen; /* output hash bit count */
switch (hashBitLen)
{ /* use pre-computed values, where available */
#ifndef SKEIN_NO_PRECOMP
case 512: memcpy(ctx->X,SKEIN_512_IV_512,sizeof(ctx->X)); break;
case 384: memcpy(ctx->X,SKEIN_512_IV_384,sizeof(ctx->X)); break;
case 256: memcpy(ctx->X,SKEIN_512_IV_256,sizeof(ctx->X)); break;
case 224: memcpy(ctx->X,SKEIN_512_IV_224,sizeof(ctx->X)); break;
#endif
default:
/* here if there is no precomputed IV value available */
/* build/process the config block, type == CONFIG (could be precomputed) */
Skein_Start_New_Type(ctx,CFG_FINAL); /* set tweaks: T0=0; T1=CFG | FINAL */
cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); /* set the schema, version */
cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */
cfg.w[2] = Skein_Swap64(SKEIN_CFG_TREE_INFO_SEQUENTIAL);
memset(&cfg.w[3],0,sizeof(cfg) - 3*sizeof(cfg.w[0])); /* zero pad config block */
/* compute the initial chaining values from config block */
memset(ctx->X,0,sizeof(ctx->X)); /* zero the chaining variables */
Skein_512_Process_Block(ctx,cfg.b,1,SKEIN_CFG_STR_LEN);
break;
}
/* The chaining vars ctx->X are now initialized for the given hashBitLen. */
/* Set up to process the data message portion of the hash (default) */
Skein_Start_New_Type(ctx,MSG); /* T0=0, T1= MSG type */
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* init the context for a MAC and/or tree hash operation */
/* [identical to Skein_512_Init() when keyBytes == 0 && treeInfo == SKEIN_CFG_TREE_INFO_SEQUENTIAL] */
int Skein_512_InitExt(Skein_512_Ctxt_t *ctx,size_t hashBitLen,u64b_t treeInfo, const u08b_t *key, size_t keyBytes)
{
union
{
u08b_t b[SKEIN_512_STATE_BYTES];
u64b_t w[SKEIN_512_STATE_WORDS];
} cfg; /* config block */
Skein_Assert(hashBitLen > 0,SKEIN_BAD_HASHLEN);
Skein_Assert(keyBytes == 0 || key != NULL,SKEIN_FAIL);
/* compute the initial chaining values ctx->X[], based on key */
if (keyBytes == 0) /* is there a key? */
{
memset(ctx->X,0,sizeof(ctx->X)); /* no key: use all zeroes as key for config block */
}
else /* here to pre-process a key */
{
Skein_assert(sizeof(cfg.b) >= sizeof(ctx->X));
/* do a mini-Init right here */
ctx->h.hashBitLen=8*sizeof(ctx->X); /* set output hash bit count = state size */
Skein_Start_New_Type(ctx,KEY); /* set tweaks: T0 = 0; T1 = KEY type */
memset(ctx->X,0,sizeof(ctx->X)); /* zero the initial chaining variables */
Skein_512_Update(ctx,key,keyBytes); /* hash the key */
Skein_512_Final_Pad(ctx,cfg.b); /* put result into cfg.b[] */
memcpy(ctx->X,cfg.b,sizeof(cfg.b)); /* copy over into ctx->X[] */
#if SKEIN_NEED_SWAP
{
uint_t i;
for (i=0;i<SKEIN_512_STATE_WORDS;i++) /* convert key bytes to context words */
ctx->X[i] = Skein_Swap64(ctx->X[i]);
}
#endif
}
/* build/process the config block, type == CONFIG (could be precomputed for each key) */
ctx->h.hashBitLen = hashBitLen; /* output hash bit count */
Skein_Start_New_Type(ctx,CFG_FINAL);
memset(&cfg.w,0,sizeof(cfg.w)); /* pre-pad cfg.w[] with zeroes */
cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER);
cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */
cfg.w[2] = Skein_Swap64(treeInfo); /* tree hash config info (or SKEIN_CFG_TREE_INFO_SEQUENTIAL) */
Skein_Show_Key(512,&ctx->h,key,keyBytes);
/* compute the initial chaining values from config block */
Skein_512_Process_Block(ctx,cfg.b,1,SKEIN_CFG_STR_LEN);
/* The chaining vars ctx->X are now initialized */
/* Set up to process the data message portion of the hash (default) */
ctx->h.bCnt = 0; /* buffer b[] starts out empty */
Skein_Start_New_Type(ctx,MSG);
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* process the input bytes */
int Skein_512_Update(Skein_512_Ctxt_t *ctx, const u08b_t *msg, size_t msgByteCnt)
{
size_t n;
Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
/* process full blocks, if any */
if (msgByteCnt + ctx->h.bCnt > SKEIN_512_BLOCK_BYTES)
{
if (ctx->h.bCnt) /* finish up any buffered message data */
{
n = SKEIN_512_BLOCK_BYTES - ctx->h.bCnt; /* # bytes free in buffer b[] */
if (n)
{
Skein_assert(n < msgByteCnt); /* check on our logic here */
memcpy(&ctx->b[ctx->h.bCnt],msg,n);
msgByteCnt -= n;
msg += n;
ctx->h.bCnt += n;
}
Skein_assert(ctx->h.bCnt == SKEIN_512_BLOCK_BYTES);
Skein_512_Process_Block(ctx,ctx->b,1,SKEIN_512_BLOCK_BYTES);
ctx->h.bCnt = 0;
}
/* now process any remaining full blocks, directly from input message data */
if (msgByteCnt > SKEIN_512_BLOCK_BYTES)
{
n = (msgByteCnt-1) / SKEIN_512_BLOCK_BYTES; /* number of full blocks to process */
Skein_512_Process_Block(ctx,msg,n,SKEIN_512_BLOCK_BYTES);
msgByteCnt -= n * SKEIN_512_BLOCK_BYTES;
msg += n * SKEIN_512_BLOCK_BYTES;
}
Skein_assert(ctx->h.bCnt == 0);
}
/* copy any remaining source message data bytes into b[] */
if (msgByteCnt)
{
Skein_assert(msgByteCnt + ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES);
memcpy(&ctx->b[ctx->h.bCnt],msg,msgByteCnt);
ctx->h.bCnt += msgByteCnt;
}
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* finalize the hash computation and output the result */
int Skein_512_Final(Skein_512_Ctxt_t *ctx, u08b_t *hashVal)
{
size_t i,n,byteCnt;
u64b_t X[SKEIN_512_STATE_WORDS];
Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */
if (ctx->h.bCnt < SKEIN_512_BLOCK_BYTES) /* zero pad b[] if necessary */
memset(&ctx->b[ctx->h.bCnt],0,SKEIN_512_BLOCK_BYTES - ctx->h.bCnt);
Skein_512_Process_Block(ctx,ctx->b,1,ctx->h.bCnt); /* process the final block */
/* now output the result */
byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* total number of output bytes */
/* run Threefish in "counter mode" to generate output */
memset(ctx->b,0,sizeof(ctx->b)); /* zero out b[], so it can hold the counter */
memcpy(X,ctx->X,sizeof(X)); /* keep a local copy of counter mode "key" */
for (i=0;i*SKEIN_512_BLOCK_BYTES < byteCnt;i++)
{
((u64b_t *)ctx->b)[0]= Skein_Swap64((u64b_t) i); /* build the counter block */
Skein_Start_New_Type(ctx,OUT_FINAL);
Skein_512_Process_Block(ctx,ctx->b,1,sizeof(u64b_t)); /* run "counter mode" */
n = byteCnt - i*SKEIN_512_BLOCK_BYTES; /* number of output bytes left to go */
if (n >= SKEIN_512_BLOCK_BYTES)
n = SKEIN_512_BLOCK_BYTES;
Skein_Put64_LSB_First(hashVal+i*SKEIN_512_BLOCK_BYTES,ctx->X,n); /* "output" the ctr mode bytes */
Skein_Show_Final(512,&ctx->h,n,hashVal+i*SKEIN_512_BLOCK_BYTES);
memcpy(ctx->X,X,sizeof(X)); /* restore the counter mode key for next time */
}
return SKEIN_SUCCESS;
}
#if defined(SKEIN_CODE_SIZE) || defined(SKEIN_PERF)
size_t Skein_512_API_CodeSize(void)
{
return ((u08b_t *) Skein_512_API_CodeSize) -
((u08b_t *) Skein_512_Init);
}
#endif
/*****************************************************************/
/* 1024-bit Skein */
/*****************************************************************/
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* init the context for a straight hashing operation */
int Skein1024_Init(Skein1024_Ctxt_t *ctx, size_t hashBitLen)
{
union
{
u08b_t b[SKEIN1024_STATE_BYTES];
u64b_t w[SKEIN1024_STATE_WORDS];
} cfg; /* config block */
Skein_Assert(hashBitLen > 0,SKEIN_BAD_HASHLEN);
ctx->h.hashBitLen = hashBitLen; /* output hash bit count */
switch (hashBitLen)
{ /* use pre-computed values, where available */
#ifndef SKEIN_NO_PRECOMP
case 512: memcpy(ctx->X,SKEIN1024_IV_512 ,sizeof(ctx->X)); break;
case 384: memcpy(ctx->X,SKEIN1024_IV_384 ,sizeof(ctx->X)); break;
case 1024: memcpy(ctx->X,SKEIN1024_IV_1024,sizeof(ctx->X)); break;
#endif
default:
/* here if there is no precomputed IV value available */
/* build/process the config block, type == CONFIG (could be precomputed) */
Skein_Start_New_Type(ctx,CFG_FINAL); /* set tweaks: T0=0; T1=CFG | FINAL */
cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); /* set the schema, version */
cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */
cfg.w[2] = Skein_Swap64(SKEIN_CFG_TREE_INFO_SEQUENTIAL);
memset(&cfg.w[3],0,sizeof(cfg) - 3*sizeof(cfg.w[0])); /* zero pad config block */
/* compute the initial chaining values from config block */
memset(ctx->X,0,sizeof(ctx->X)); /* zero the chaining variables */
Skein1024_Process_Block(ctx,cfg.b,1,SKEIN_CFG_STR_LEN);
break;
}
/* The chaining vars ctx->X are now initialized for the given hashBitLen. */
/* Set up to process the data message portion of the hash (default) */
Skein_Start_New_Type(ctx,MSG); /* T0=0, T1= MSG type */
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* init the context for a MAC and/or tree hash operation */
/* [identical to Skein1024_Init() when keyBytes == 0 && treeInfo == SKEIN_CFG_TREE_INFO_SEQUENTIAL] */
int Skein1024_InitExt(Skein1024_Ctxt_t *ctx,size_t hashBitLen,u64b_t treeInfo, const u08b_t *key, size_t keyBytes)
{
union
{
u08b_t b[SKEIN1024_STATE_BYTES];
u64b_t w[SKEIN1024_STATE_WORDS];
} cfg; /* config block */
Skein_Assert(hashBitLen > 0,SKEIN_BAD_HASHLEN);
Skein_Assert(keyBytes == 0 || key != NULL,SKEIN_FAIL);
/* compute the initial chaining values ctx->X[], based on key */
if (keyBytes == 0) /* is there a key? */
{
memset(ctx->X,0,sizeof(ctx->X)); /* no key: use all zeroes as key for config block */
}
else /* here to pre-process a key */
{
Skein_assert(sizeof(cfg.b) >= sizeof(ctx->X));
/* do a mini-Init right here */
ctx->h.hashBitLen=8*sizeof(ctx->X); /* set output hash bit count = state size */
Skein_Start_New_Type(ctx,KEY); /* set tweaks: T0 = 0; T1 = KEY type */
memset(ctx->X,0,sizeof(ctx->X)); /* zero the initial chaining variables */
Skein1024_Update(ctx,key,keyBytes); /* hash the key */
Skein1024_Final_Pad(ctx,cfg.b); /* put result into cfg.b[] */
memcpy(ctx->X,cfg.b,sizeof(cfg.b)); /* copy over into ctx->X[] */
#if SKEIN_NEED_SWAP
{
uint_t i;
for (i=0;i<SKEIN1024_STATE_WORDS;i++) /* convert key bytes to context words */
ctx->X[i] = Skein_Swap64(ctx->X[i]);
}
#endif
}
/* build/process the config block, type == CONFIG (could be precomputed for each key) */
ctx->h.hashBitLen = hashBitLen; /* output hash bit count */
Skein_Start_New_Type(ctx,CFG_FINAL);
memset(&cfg.w,0,sizeof(cfg.w)); /* pre-pad cfg.w[] with zeroes */
cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER);
cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */
cfg.w[2] = Skein_Swap64(treeInfo); /* tree hash config info (or SKEIN_CFG_TREE_INFO_SEQUENTIAL) */
Skein_Show_Key(1024,&ctx->h,key,keyBytes);
/* compute the initial chaining values from config block */
Skein1024_Process_Block(ctx,cfg.b,1,SKEIN_CFG_STR_LEN);
/* The chaining vars ctx->X are now initialized */
/* Set up to process the data message portion of the hash (default) */
ctx->h.bCnt = 0; /* buffer b[] starts out empty */
Skein_Start_New_Type(ctx,MSG);
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* process the input bytes */
int Skein1024_Update(Skein1024_Ctxt_t *ctx, const u08b_t *msg, size_t msgByteCnt)
{
size_t n;
Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
/* process full blocks, if any */
if (msgByteCnt + ctx->h.bCnt > SKEIN1024_BLOCK_BYTES)
{
if (ctx->h.bCnt) /* finish up any buffered message data */
{
n = SKEIN1024_BLOCK_BYTES - ctx->h.bCnt; /* # bytes free in buffer b[] */
if (n)
{
Skein_assert(n < msgByteCnt); /* check on our logic here */
memcpy(&ctx->b[ctx->h.bCnt],msg,n);
msgByteCnt -= n;
msg += n;
ctx->h.bCnt += n;
}
Skein_assert(ctx->h.bCnt == SKEIN1024_BLOCK_BYTES);
Skein1024_Process_Block(ctx,ctx->b,1,SKEIN1024_BLOCK_BYTES);
ctx->h.bCnt = 0;
}
/* now process any remaining full blocks, directly from input message data */
if (msgByteCnt > SKEIN1024_BLOCK_BYTES)
{
n = (msgByteCnt-1) / SKEIN1024_BLOCK_BYTES; /* number of full blocks to process */
Skein1024_Process_Block(ctx,msg,n,SKEIN1024_BLOCK_BYTES);
msgByteCnt -= n * SKEIN1024_BLOCK_BYTES;
msg += n * SKEIN1024_BLOCK_BYTES;
}
Skein_assert(ctx->h.bCnt == 0);
}
/* copy any remaining source message data bytes into b[] */
if (msgByteCnt)
{
Skein_assert(msgByteCnt + ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES);
memcpy(&ctx->b[ctx->h.bCnt],msg,msgByteCnt);
ctx->h.bCnt += msgByteCnt;
}
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* finalize the hash computation and output the result */
int Skein1024_Final(Skein1024_Ctxt_t *ctx, u08b_t *hashVal)
{
size_t i,n,byteCnt;
u64b_t X[SKEIN1024_STATE_WORDS];
Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */
if (ctx->h.bCnt < SKEIN1024_BLOCK_BYTES) /* zero pad b[] if necessary */
memset(&ctx->b[ctx->h.bCnt],0,SKEIN1024_BLOCK_BYTES - ctx->h.bCnt);
Skein1024_Process_Block(ctx,ctx->b,1,ctx->h.bCnt); /* process the final block */
/* now output the result */
byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* total number of output bytes */
/* run Threefish in "counter mode" to generate output */
memset(ctx->b,0,sizeof(ctx->b)); /* zero out b[], so it can hold the counter */
memcpy(X,ctx->X,sizeof(X)); /* keep a local copy of counter mode "key" */
for (i=0;i*SKEIN1024_BLOCK_BYTES < byteCnt;i++)
{
((u64b_t *)ctx->b)[0]= Skein_Swap64((u64b_t) i); /* build the counter block */
Skein_Start_New_Type(ctx,OUT_FINAL);
Skein1024_Process_Block(ctx,ctx->b,1,sizeof(u64b_t)); /* run "counter mode" */
n = byteCnt - i*SKEIN1024_BLOCK_BYTES; /* number of output bytes left to go */
if (n >= SKEIN1024_BLOCK_BYTES)
n = SKEIN1024_BLOCK_BYTES;
Skein_Put64_LSB_First(hashVal+i*SKEIN1024_BLOCK_BYTES,ctx->X,n); /* "output" the ctr mode bytes */
Skein_Show_Final(1024,&ctx->h,n,hashVal+i*SKEIN1024_BLOCK_BYTES);
memcpy(ctx->X,X,sizeof(X)); /* restore the counter mode key for next time */
}
return SKEIN_SUCCESS;
}
#if defined(SKEIN_CODE_SIZE) || defined(SKEIN_PERF)
size_t Skein1024_API_CodeSize(void)
{
return ((u08b_t *) Skein1024_API_CodeSize) -
((u08b_t *) Skein1024_Init);
}
#endif
/**************** Functions to support MAC/tree hashing ***************/
/* (this code is identical for Optimized and Reference versions) */
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* finalize the hash computation and output the block, no OUTPUT stage */
int Skein_256_Final_Pad(Skein_256_Ctxt_t *ctx, u08b_t *hashVal)
{
Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */
if (ctx->h.bCnt < SKEIN_256_BLOCK_BYTES) /* zero pad b[] if necessary */
memset(&ctx->b[ctx->h.bCnt],0,SKEIN_256_BLOCK_BYTES - ctx->h.bCnt);
Skein_256_Process_Block(ctx,ctx->b,1,ctx->h.bCnt); /* process the final block */
Skein_Put64_LSB_First(hashVal,ctx->X,SKEIN_256_BLOCK_BYTES); /* "output" the state bytes */
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* finalize the hash computation and output the block, no OUTPUT stage */
int Skein_512_Final_Pad(Skein_512_Ctxt_t *ctx, u08b_t *hashVal)
{
Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */
if (ctx->h.bCnt < SKEIN_512_BLOCK_BYTES) /* zero pad b[] if necessary */
memset(&ctx->b[ctx->h.bCnt],0,SKEIN_512_BLOCK_BYTES - ctx->h.bCnt);
Skein_512_Process_Block(ctx,ctx->b,1,ctx->h.bCnt); /* process the final block */
Skein_Put64_LSB_First(hashVal,ctx->X,SKEIN_512_BLOCK_BYTES); /* "output" the state bytes */
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* finalize the hash computation and output the block, no OUTPUT stage */
int Skein1024_Final_Pad(Skein1024_Ctxt_t *ctx, u08b_t *hashVal)
{
Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */
if (ctx->h.bCnt < SKEIN1024_BLOCK_BYTES) /* zero pad b[] if necessary */
memset(&ctx->b[ctx->h.bCnt],0,SKEIN1024_BLOCK_BYTES - ctx->h.bCnt);
Skein1024_Process_Block(ctx,ctx->b,1,ctx->h.bCnt); /* process the final block */
Skein_Put64_LSB_First(hashVal,ctx->X,SKEIN1024_BLOCK_BYTES); /* "output" the state bytes */
return SKEIN_SUCCESS;
}
#if SKEIN_TREE_HASH
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* just do the OUTPUT stage */
int Skein_256_Output(Skein_256_Ctxt_t *ctx, u08b_t *hashVal)
{
size_t i,n,byteCnt;
u64b_t X[SKEIN_256_STATE_WORDS];
Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
/* now output the result */
byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* total number of output bytes */
/* run Threefish in "counter mode" to generate output */
memset(ctx->b,0,sizeof(ctx->b)); /* zero out b[], so it can hold the counter */
memcpy(X,ctx->X,sizeof(X)); /* keep a local copy of counter mode "key" */
for (i=0;i*SKEIN_256_BLOCK_BYTES < byteCnt;i++)
{
((u64b_t *)ctx->b)[0]= Skein_Swap64((u64b_t) i); /* build the counter block */
Skein_Start_New_Type(ctx,OUT_FINAL);
Skein_256_Process_Block(ctx,ctx->b,1,sizeof(u64b_t)); /* run "counter mode" */
n = byteCnt - i*SKEIN_256_BLOCK_BYTES; /* number of output bytes left to go */
if (n >= SKEIN_256_BLOCK_BYTES)
n = SKEIN_256_BLOCK_BYTES;
Skein_Put64_LSB_First(hashVal+i*SKEIN_256_BLOCK_BYTES,ctx->X,n); /* "output" the ctr mode bytes */
Skein_Show_Final(256,&ctx->h,n,hashVal+i*SKEIN_256_BLOCK_BYTES);
memcpy(ctx->X,X,sizeof(X)); /* restore the counter mode key for next time */
}
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* just do the OUTPUT stage */
int Skein_512_Output(Skein_512_Ctxt_t *ctx, u08b_t *hashVal)
{
size_t i,n,byteCnt;
u64b_t X[SKEIN_512_STATE_WORDS];
Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
/* now output the result */
byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* total number of output bytes */
/* run Threefish in "counter mode" to generate output */
memset(ctx->b,0,sizeof(ctx->b)); /* zero out b[], so it can hold the counter */
memcpy(X,ctx->X,sizeof(X)); /* keep a local copy of counter mode "key" */
for (i=0;i*SKEIN_512_BLOCK_BYTES < byteCnt;i++)
{
((u64b_t *)ctx->b)[0]= Skein_Swap64((u64b_t) i); /* build the counter block */
Skein_Start_New_Type(ctx,OUT_FINAL);
Skein_512_Process_Block(ctx,ctx->b,1,sizeof(u64b_t)); /* run "counter mode" */
n = byteCnt - i*SKEIN_512_BLOCK_BYTES; /* number of output bytes left to go */
if (n >= SKEIN_512_BLOCK_BYTES)
n = SKEIN_512_BLOCK_BYTES;
Skein_Put64_LSB_First(hashVal+i*SKEIN_512_BLOCK_BYTES,ctx->X,n); /* "output" the ctr mode bytes */
Skein_Show_Final(256,&ctx->h,n,hashVal+i*SKEIN_512_BLOCK_BYTES);
memcpy(ctx->X,X,sizeof(X)); /* restore the counter mode key for next time */
}
return SKEIN_SUCCESS;
}
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* just do the OUTPUT stage */
int Skein1024_Output(Skein1024_Ctxt_t *ctx, u08b_t *hashVal)
{
size_t i,n,byteCnt;
u64b_t X[SKEIN1024_STATE_WORDS];
Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES,SKEIN_FAIL); /* catch uninitialized context */
/* now output the result */
byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* total number of output bytes */
/* run Threefish in "counter mode" to generate output */
memset(ctx->b,0,sizeof(ctx->b)); /* zero out b[], so it can hold the counter */
memcpy(X,ctx->X,sizeof(X)); /* keep a local copy of counter mode "key" */
for (i=0;i*SKEIN1024_BLOCK_BYTES < byteCnt;i++)
{
((u64b_t *)ctx->b)[0]= Skein_Swap64((u64b_t) i); /* build the counter block */
Skein_Start_New_Type(ctx,OUT_FINAL);
Skein1024_Process_Block(ctx,ctx->b,1,sizeof(u64b_t)); /* run "counter mode" */
n = byteCnt - i*SKEIN1024_BLOCK_BYTES; /* number of output bytes left to go */
if (n >= SKEIN1024_BLOCK_BYTES)
n = SKEIN1024_BLOCK_BYTES;
Skein_Put64_LSB_First(hashVal+i*SKEIN1024_BLOCK_BYTES,ctx->X,n); /* "output" the ctr mode bytes */
Skein_Show_Final(256,&ctx->h,n,hashVal+i*SKEIN1024_BLOCK_BYTES);
memcpy(ctx->X,X,sizeof(X)); /* restore the counter mode key for next time */
}
return SKEIN_SUCCESS;
}
/* Adapt the functions to match the prototype expected by libmd */
void
SKEIN256_Init(SKEIN256_CTX * ctx)
{
Skein_256_Init(ctx, 256);
}
void
SKEIN512_Init(SKEIN512_CTX * ctx)
{
Skein_512_Init(ctx, 512);
}
void
SKEIN1024_Init(SKEIN1024_CTX * ctx)
{
Skein1024_Init(ctx, 1024);
}
void
SKEIN256_Update(SKEIN256_CTX * ctx, const void *in, size_t len)
{
Skein_256_Update(ctx, in, len);
}
void
SKEIN512_Update(SKEIN512_CTX * ctx, const void *in, size_t len)
{
Skein_512_Update(ctx, in, len);
}
void
SKEIN1024_Update(SKEIN1024_CTX * ctx, const void *in, size_t len)
{
Skein1024_Update(ctx, in, len);
}
void
SKEIN256_Final(unsigned char digest[static SKEIN_256_BLOCK_BYTES], SKEIN256_CTX *ctx)
{
Skein_256_Final(ctx, digest);
}
void
SKEIN512_Final(unsigned char digest[static SKEIN_512_BLOCK_BYTES], SKEIN512_CTX *ctx)
{
Skein_512_Final(ctx, digest);
}
void
SKEIN1024_Final(unsigned char digest[static SKEIN1024_BLOCK_BYTES], SKEIN1024_CTX *ctx)
{
Skein1024_Final(ctx, digest);
}
#ifdef WEAK_REFS
/* When building libmd, provide weak references. Note: this is not
activated in the context of compiling these sources for internal
use in libcrypt.
*/
#undef SKEIN256_Init
__weak_reference(_libmd_SKEIN256_Init, SKEIN256_Init);
#undef SKEIN256_Update
__weak_reference(_libmd_SKEIN256_Update, SKEIN256_Update);
#undef SKEIN256_Final
__weak_reference(_libmd_SKEIN256_Final, SKEIN256_Final);
#undef SKEIN512_Init
__weak_reference(_libmd_SKEIN512_Init, SKEIN512_Init);
#undef SKEIN512_Update
__weak_reference(_libmd_SKEIN512_Update, SKEIN512_Update);
#undef SKEIN512_Final
__weak_reference(_libmd_SKEIN512_Final, SKEIN512_Final);
#undef SKEIN1024_Init
__weak_reference(_libmd_SKEIN1024_Init, SKEIN1024_Init);
#undef SKEIN1024_Update
__weak_reference(_libmd_SKEIN1024_Update, SKEIN1024_Update);
#undef SKEIN1024_Final
__weak_reference(_libmd_SKEIN1024_Final, SKEIN1024_Final);
#endif
#endif

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/* $FreeBSD$ */
#ifndef _SKEIN_H_
#define _SKEIN_H_ 1
/**************************************************************************
**
** Interface declarations and internal definitions for Skein hashing.
**
** Source code author: Doug Whiting, 2008.
**
** This algorithm and source code is released to the public domain.
**
***************************************************************************
**
** The following compile-time switches may be defined to control some
** tradeoffs between speed, code size, error checking, and security.
**
** The "default" note explains what happens when the switch is not defined.
**
** SKEIN_DEBUG -- make callouts from inside Skein code
** to examine/display intermediate values.
** [default: no callouts (no overhead)]
**
** SKEIN_ERR_CHECK -- how error checking is handled inside Skein
** code. If not defined, most error checking
** is disabled (for performance). Otherwise,
** the switch value is interpreted as:
** 0: use assert() to flag errors
** 1: return SKEIN_FAIL to flag errors
**
***************************************************************************/
#ifdef __cplusplus
extern "C"
{
#endif
#ifndef _KERNEL
#include <stddef.h> /* get size_t definition */
#endif
#include "skein_port.h" /* get platform-specific definitions */
enum
{
SKEIN_SUCCESS = 0, /* return codes from Skein calls */
SKEIN_FAIL = 1,
SKEIN_BAD_HASHLEN = 2
};
#define SKEIN_MODIFIER_WORDS ( 2) /* number of modifier (tweak) words */
#define SKEIN_256_STATE_WORDS ( 4)
#define SKEIN_512_STATE_WORDS ( 8)
#define SKEIN1024_STATE_WORDS (16)
#define SKEIN_MAX_STATE_WORDS (16)
#define SKEIN_256_STATE_BYTES ( 8*SKEIN_256_STATE_WORDS)
#define SKEIN_512_STATE_BYTES ( 8*SKEIN_512_STATE_WORDS)
#define SKEIN1024_STATE_BYTES ( 8*SKEIN1024_STATE_WORDS)
#define SKEIN_256_STATE_BITS (64*SKEIN_256_STATE_WORDS)
#define SKEIN_512_STATE_BITS (64*SKEIN_512_STATE_WORDS)
#define SKEIN1024_STATE_BITS (64*SKEIN1024_STATE_WORDS)
#define SKEIN_256_BLOCK_BYTES ( 8*SKEIN_256_STATE_WORDS)
#define SKEIN_512_BLOCK_BYTES ( 8*SKEIN_512_STATE_WORDS)
#define SKEIN1024_BLOCK_BYTES ( 8*SKEIN1024_STATE_WORDS)
typedef struct
{
size_t hashBitLen; /* size of hash result, in bits */
size_t bCnt; /* current byte count in buffer b[] */
u64b_t T[SKEIN_MODIFIER_WORDS]; /* tweak words: T[0]=byte cnt, T[1]=flags */
} Skein_Ctxt_Hdr_t;
typedef struct /* 256-bit Skein hash context structure */
{
Skein_Ctxt_Hdr_t h; /* common header context variables */
u64b_t X[SKEIN_256_STATE_WORDS]; /* chaining variables */
u08b_t b[SKEIN_256_BLOCK_BYTES]; /* partial block buffer (8-byte aligned) */
} Skein_256_Ctxt_t;
typedef struct /* 512-bit Skein hash context structure */
{
Skein_Ctxt_Hdr_t h; /* common header context variables */
u64b_t X[SKEIN_512_STATE_WORDS]; /* chaining variables */
u08b_t b[SKEIN_512_BLOCK_BYTES]; /* partial block buffer (8-byte aligned) */
} Skein_512_Ctxt_t;
typedef struct /* 1024-bit Skein hash context structure */
{
Skein_Ctxt_Hdr_t h; /* common header context variables */
u64b_t X[SKEIN1024_STATE_WORDS]; /* chaining variables */
u08b_t b[SKEIN1024_BLOCK_BYTES]; /* partial block buffer (8-byte aligned) */
} Skein1024_Ctxt_t;
/* Skein APIs for (incremental) "straight hashing" */
int Skein_256_Init (Skein_256_Ctxt_t *ctx, size_t hashBitLen);
int Skein_512_Init (Skein_512_Ctxt_t *ctx, size_t hashBitLen);
int Skein1024_Init (Skein1024_Ctxt_t *ctx, size_t hashBitLen);
int Skein_256_Update(Skein_256_Ctxt_t *ctx, const u08b_t *msg, size_t msgByteCnt);
int Skein_512_Update(Skein_512_Ctxt_t *ctx, const u08b_t *msg, size_t msgByteCnt);
int Skein1024_Update(Skein1024_Ctxt_t *ctx, const u08b_t *msg, size_t msgByteCnt);
int Skein_256_Final (Skein_256_Ctxt_t *ctx, u08b_t * hashVal);
int Skein_512_Final (Skein_512_Ctxt_t *ctx, u08b_t * hashVal);
int Skein1024_Final (Skein1024_Ctxt_t *ctx, u08b_t * hashVal);
/*
** Skein APIs for "extended" initialization: MAC keys, tree hashing.
** After an InitExt() call, just use Update/Final calls as with Init().
**
** Notes: Same parameters as _Init() calls, plus treeInfo/key/keyBytes.
** When keyBytes == 0 and treeInfo == SKEIN_SEQUENTIAL,
** the results of InitExt() are identical to calling Init().
** The function Init() may be called once to "precompute" the IV for
** a given hashBitLen value, then by saving a copy of the context
** the IV computation may be avoided in later calls.
** Similarly, the function InitExt() may be called once per MAC key
** to precompute the MAC IV, then a copy of the context saved and
** reused for each new MAC computation.
**/
int Skein_256_InitExt(Skein_256_Ctxt_t *ctx, size_t hashBitLen, u64b_t treeInfo, const u08b_t *key, size_t keyBytes);
int Skein_512_InitExt(Skein_512_Ctxt_t *ctx, size_t hashBitLen, u64b_t treeInfo, const u08b_t *key, size_t keyBytes);
int Skein1024_InitExt(Skein1024_Ctxt_t *ctx, size_t hashBitLen, u64b_t treeInfo, const u08b_t *key, size_t keyBytes);
/*
** Skein APIs for MAC and tree hash:
** Final_Pad: pad, do final block, but no OUTPUT type
** Output: do just the output stage
*/
int Skein_256_Final_Pad(Skein_256_Ctxt_t *ctx, u08b_t * hashVal);
int Skein_512_Final_Pad(Skein_512_Ctxt_t *ctx, u08b_t * hashVal);
int Skein1024_Final_Pad(Skein1024_Ctxt_t *ctx, u08b_t * hashVal);
#ifndef SKEIN_TREE_HASH
#define SKEIN_TREE_HASH (1)
#endif
#if SKEIN_TREE_HASH
int Skein_256_Output (Skein_256_Ctxt_t *ctx, u08b_t * hashVal);
int Skein_512_Output (Skein_512_Ctxt_t *ctx, u08b_t * hashVal);
int Skein1024_Output (Skein1024_Ctxt_t *ctx, u08b_t * hashVal);
#endif
/*****************************************************************
** "Internal" Skein definitions
** -- not needed for sequential hashing API, but will be
** helpful for other uses of Skein (e.g., tree hash mode).
** -- included here so that they can be shared between
** reference and optimized code.
******************************************************************/
/* tweak word T[1]: bit field starting positions */
#define SKEIN_T1_BIT(BIT) ((BIT) - 64) /* offset 64 because it's the second word */
#define SKEIN_T1_POS_TREE_LVL SKEIN_T1_BIT(112) /* bits 112..118: level in hash tree */
#define SKEIN_T1_POS_BIT_PAD SKEIN_T1_BIT(119) /* bit 119 : partial final input byte */
#define SKEIN_T1_POS_BLK_TYPE SKEIN_T1_BIT(120) /* bits 120..125: type field */
#define SKEIN_T1_POS_FIRST SKEIN_T1_BIT(126) /* bits 126 : first block flag */
#define SKEIN_T1_POS_FINAL SKEIN_T1_BIT(127) /* bit 127 : final block flag */
/* tweak word T[1]: flag bit definition(s) */
#define SKEIN_T1_FLAG_FIRST (((u64b_t) 1 ) << SKEIN_T1_POS_FIRST)
#define SKEIN_T1_FLAG_FINAL (((u64b_t) 1 ) << SKEIN_T1_POS_FINAL)
#define SKEIN_T1_FLAG_BIT_PAD (((u64b_t) 1 ) << SKEIN_T1_POS_BIT_PAD)
/* tweak word T[1]: tree level bit field mask */
#define SKEIN_T1_TREE_LVL_MASK (((u64b_t)0x7F) << SKEIN_T1_POS_TREE_LVL)
#define SKEIN_T1_TREE_LEVEL(n) (((u64b_t) (n)) << SKEIN_T1_POS_TREE_LVL)
/* tweak word T[1]: block type field */
#define SKEIN_BLK_TYPE_KEY ( 0) /* key, for MAC and KDF */
#define SKEIN_BLK_TYPE_CFG ( 4) /* configuration block */
#define SKEIN_BLK_TYPE_PERS ( 8) /* personalization string */
#define SKEIN_BLK_TYPE_PK (12) /* public key (for digital signature hashing) */
#define SKEIN_BLK_TYPE_KDF (16) /* key identifier for KDF */
#define SKEIN_BLK_TYPE_NONCE (20) /* nonce for PRNG */
#define SKEIN_BLK_TYPE_MSG (48) /* message processing */
#define SKEIN_BLK_TYPE_OUT (63) /* output stage */
#define SKEIN_BLK_TYPE_MASK (63) /* bit field mask */
#define SKEIN_T1_BLK_TYPE(T) (((u64b_t) (SKEIN_BLK_TYPE_##T)) << SKEIN_T1_POS_BLK_TYPE)
#define SKEIN_T1_BLK_TYPE_KEY SKEIN_T1_BLK_TYPE(KEY) /* key, for MAC and KDF */
#define SKEIN_T1_BLK_TYPE_CFG SKEIN_T1_BLK_TYPE(CFG) /* configuration block */
#define SKEIN_T1_BLK_TYPE_PERS SKEIN_T1_BLK_TYPE(PERS) /* personalization string */
#define SKEIN_T1_BLK_TYPE_PK SKEIN_T1_BLK_TYPE(PK) /* public key (for digital signature hashing) */
#define SKEIN_T1_BLK_TYPE_KDF SKEIN_T1_BLK_TYPE(KDF) /* key identifier for KDF */
#define SKEIN_T1_BLK_TYPE_NONCE SKEIN_T1_BLK_TYPE(NONCE)/* nonce for PRNG */
#define SKEIN_T1_BLK_TYPE_MSG SKEIN_T1_BLK_TYPE(MSG) /* message processing */
#define SKEIN_T1_BLK_TYPE_OUT SKEIN_T1_BLK_TYPE(OUT) /* output stage */
#define SKEIN_T1_BLK_TYPE_MASK SKEIN_T1_BLK_TYPE(MASK) /* field bit mask */
#define SKEIN_T1_BLK_TYPE_CFG_FINAL (SKEIN_T1_BLK_TYPE_CFG | SKEIN_T1_FLAG_FINAL)
#define SKEIN_T1_BLK_TYPE_OUT_FINAL (SKEIN_T1_BLK_TYPE_OUT | SKEIN_T1_FLAG_FINAL)
#define SKEIN_VERSION (1)
#ifndef SKEIN_ID_STRING_LE /* allow compile-time personalization */
#define SKEIN_ID_STRING_LE (0x33414853) /* "SHA3" (little-endian)*/
#endif
#define SKEIN_MK_64(hi32,lo32) ((lo32) + (((u64b_t) (hi32)) << 32))
#define SKEIN_SCHEMA_VER SKEIN_MK_64(SKEIN_VERSION,SKEIN_ID_STRING_LE)
#define SKEIN_KS_PARITY SKEIN_MK_64(0x1BD11BDA,0xA9FC1A22)
#define SKEIN_CFG_STR_LEN (4*8)
/* bit field definitions in config block treeInfo word */
#define SKEIN_CFG_TREE_LEAF_SIZE_POS ( 0)
#define SKEIN_CFG_TREE_NODE_SIZE_POS ( 8)
#define SKEIN_CFG_TREE_MAX_LEVEL_POS (16)
#define SKEIN_CFG_TREE_LEAF_SIZE_MSK (((u64b_t) 0xFF) << SKEIN_CFG_TREE_LEAF_SIZE_POS)
#define SKEIN_CFG_TREE_NODE_SIZE_MSK (((u64b_t) 0xFF) << SKEIN_CFG_TREE_NODE_SIZE_POS)
#define SKEIN_CFG_TREE_MAX_LEVEL_MSK (((u64b_t) 0xFF) << SKEIN_CFG_TREE_MAX_LEVEL_POS)
#define SKEIN_CFG_TREE_INFO(leaf,node,maxLvl) \
( (((u64b_t)(leaf )) << SKEIN_CFG_TREE_LEAF_SIZE_POS) | \
(((u64b_t)(node )) << SKEIN_CFG_TREE_NODE_SIZE_POS) | \
(((u64b_t)(maxLvl)) << SKEIN_CFG_TREE_MAX_LEVEL_POS) )
#define SKEIN_CFG_TREE_INFO_SEQUENTIAL SKEIN_CFG_TREE_INFO(0,0,0) /* use as treeInfo in InitExt() call for sequential processing */
/*
** Skein macros for getting/setting tweak words, etc.
** These are useful for partial input bytes, hash tree init/update, etc.
**/
#define Skein_Get_Tweak(ctxPtr,TWK_NUM) ((ctxPtr)->h.T[TWK_NUM])
#define Skein_Set_Tweak(ctxPtr,TWK_NUM,tVal) {(ctxPtr)->h.T[TWK_NUM] = (tVal);}
#define Skein_Get_T0(ctxPtr) Skein_Get_Tweak(ctxPtr,0)
#define Skein_Get_T1(ctxPtr) Skein_Get_Tweak(ctxPtr,1)
#define Skein_Set_T0(ctxPtr,T0) Skein_Set_Tweak(ctxPtr,0,T0)
#define Skein_Set_T1(ctxPtr,T1) Skein_Set_Tweak(ctxPtr,1,T1)
/* set both tweak words at once */
#define Skein_Set_T0_T1(ctxPtr,T0,T1) \
{ \
Skein_Set_T0(ctxPtr,(T0)); \
Skein_Set_T1(ctxPtr,(T1)); \
}
#define Skein_Set_Type(ctxPtr,BLK_TYPE) \
Skein_Set_T1(ctxPtr,SKEIN_T1_BLK_TYPE_##BLK_TYPE)
/* set up for starting with a new type: h.T[0]=0; h.T[1] = NEW_TYPE; h.bCnt=0; */
#define Skein_Start_New_Type(ctxPtr,BLK_TYPE) \
{ Skein_Set_T0_T1(ctxPtr,0,SKEIN_T1_FLAG_FIRST | SKEIN_T1_BLK_TYPE_##BLK_TYPE); (ctxPtr)->h.bCnt=0; }
#define Skein_Clear_First_Flag(hdr) { (hdr).T[1] &= ~SKEIN_T1_FLAG_FIRST; }
#define Skein_Set_Bit_Pad_Flag(hdr) { (hdr).T[1] |= SKEIN_T1_FLAG_BIT_PAD; }
#define Skein_Set_Tree_Level(hdr,height) { (hdr).T[1] |= SKEIN_T1_TREE_LEVEL(height);}
/*****************************************************************
** "Internal" Skein definitions for debugging and error checking
******************************************************************/
#ifdef SKEIN_DEBUG /* examine/display intermediate values? */
#include "skein_debug.h"
#else /* default is no callouts */
#define Skein_Show_Block(bits,ctx,X,blkPtr,wPtr,ksEvenPtr,ksOddPtr)
#define Skein_Show_Round(bits,ctx,r,X)
#define Skein_Show_R_Ptr(bits,ctx,r,X_ptr)
#define Skein_Show_Final(bits,ctx,cnt,outPtr)
#define Skein_Show_Key(bits,ctx,key,keyBytes)
#endif
#ifndef SKEIN_ERR_CHECK /* run-time checks (e.g., bad params, uninitialized context)? */
#define Skein_Assert(x,retCode)/* default: ignore all Asserts, for performance */
#define Skein_assert(x)
#elif defined(SKEIN_ASSERT)
#include <assert.h>
#define Skein_Assert(x,retCode) assert(x)
#define Skein_assert(x) assert(x)
#else
#include <assert.h>
#define Skein_Assert(x,retCode) { if (!(x)) return retCode; } /* caller error */
#define Skein_assert(x) assert(x) /* internal error */
#endif
/*****************************************************************
** Skein block function constants (shared across Ref and Opt code)
******************************************************************/
enum
{
/* Skein_256 round rotation constants */
R_256_0_0=14, R_256_0_1=16,
R_256_1_0=52, R_256_1_1=57,
R_256_2_0=23, R_256_2_1=40,
R_256_3_0= 5, R_256_3_1=37,
R_256_4_0=25, R_256_4_1=33,
R_256_5_0=46, R_256_5_1=12,
R_256_6_0=58, R_256_6_1=22,
R_256_7_0=32, R_256_7_1=32,
/* Skein_512 round rotation constants */
R_512_0_0=46, R_512_0_1=36, R_512_0_2=19, R_512_0_3=37,
R_512_1_0=33, R_512_1_1=27, R_512_1_2=14, R_512_1_3=42,
R_512_2_0=17, R_512_2_1=49, R_512_2_2=36, R_512_2_3=39,
R_512_3_0=44, R_512_3_1= 9, R_512_3_2=54, R_512_3_3=56,
R_512_4_0=39, R_512_4_1=30, R_512_4_2=34, R_512_4_3=24,
R_512_5_0=13, R_512_5_1=50, R_512_5_2=10, R_512_5_3=17,
R_512_6_0=25, R_512_6_1=29, R_512_6_2=39, R_512_6_3=43,
R_512_7_0= 8, R_512_7_1=35, R_512_7_2=56, R_512_7_3=22,
/* Skein1024 round rotation constants */
R1024_0_0=24, R1024_0_1=13, R1024_0_2= 8, R1024_0_3=47, R1024_0_4= 8, R1024_0_5=17, R1024_0_6=22, R1024_0_7=37,
R1024_1_0=38, R1024_1_1=19, R1024_1_2=10, R1024_1_3=55, R1024_1_4=49, R1024_1_5=18, R1024_1_6=23, R1024_1_7=52,
R1024_2_0=33, R1024_2_1= 4, R1024_2_2=51, R1024_2_3=13, R1024_2_4=34, R1024_2_5=41, R1024_2_6=59, R1024_2_7=17,
R1024_3_0= 5, R1024_3_1=20, R1024_3_2=48, R1024_3_3=41, R1024_3_4=47, R1024_3_5=28, R1024_3_6=16, R1024_3_7=25,
R1024_4_0=41, R1024_4_1= 9, R1024_4_2=37, R1024_4_3=31, R1024_4_4=12, R1024_4_5=47, R1024_4_6=44, R1024_4_7=30,
R1024_5_0=16, R1024_5_1=34, R1024_5_2=56, R1024_5_3=51, R1024_5_4= 4, R1024_5_5=53, R1024_5_6=42, R1024_5_7=41,
R1024_6_0=31, R1024_6_1=44, R1024_6_2=47, R1024_6_3=46, R1024_6_4=19, R1024_6_5=42, R1024_6_6=44, R1024_6_7=25,
R1024_7_0= 9, R1024_7_1=48, R1024_7_2=35, R1024_7_3=52, R1024_7_4=23, R1024_7_5=31, R1024_7_6=37, R1024_7_7=20
};
#ifndef SKEIN_ROUNDS
#define SKEIN_256_ROUNDS_TOTAL (72) /* number of rounds for the different block sizes */
#define SKEIN_512_ROUNDS_TOTAL (72)
#define SKEIN1024_ROUNDS_TOTAL (80)
#else /* allow command-line define in range 8*(5..14) */
#define SKEIN_256_ROUNDS_TOTAL (8*((((SKEIN_ROUNDS/100) + 5) % 10) + 5))
#define SKEIN_512_ROUNDS_TOTAL (8*((((SKEIN_ROUNDS/ 10) + 5) % 10) + 5))
#define SKEIN1024_ROUNDS_TOTAL (8*((((SKEIN_ROUNDS ) + 5) % 10) + 5))
#endif
#ifdef __cplusplus
}
#endif
/* Pull in FreeBSD specific shims */
#include "skein_freebsd.h"
#endif /* ifndef _SKEIN_H_ */

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/***********************************************************************
**
** Implementation of the Skein block functions.
**
** Source code author: Doug Whiting, 2008.
**
** This algorithm and source code is released to the public domain.
**
** Compile-time switches:
**
** SKEIN_USE_ASM -- set bits (256/512/1024) to select which
** versions use ASM code for block processing
** [default: use C for all block sizes]
**
************************************************************************/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/endian.h>
#include <sys/types.h>
#ifdef _KERNEL
#include <sys/systm.h>
#else
#include <string.h>
#endif
#include "skein.h"
#ifndef SKEIN_USE_ASM
#define SKEIN_USE_ASM (0) /* default is all C code (no ASM) */
#endif
#ifndef SKEIN_LOOP
#define SKEIN_LOOP 001 /* default: unroll 256 and 512, but not 1024 */
#endif
#define BLK_BITS (WCNT*64) /* some useful definitions for code here */
#define KW_TWK_BASE (0)
#define KW_KEY_BASE (3)
#define ks (kw + KW_KEY_BASE)
#define ts (kw + KW_TWK_BASE)
#ifdef SKEIN_DEBUG
#define DebugSaveTweak(ctx) { ctx->h.T[0] = ts[0]; ctx->h.T[1] = ts[1]; }
#else
#define DebugSaveTweak(ctx)
#endif
/*****************************************************************/
/* functions to process blkCnt (nonzero) full block(s) of data. */
void Skein_256_Process_Block(Skein_256_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd);
void Skein_512_Process_Block(Skein_512_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd);
void Skein1024_Process_Block(Skein1024_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd);
/***************************** Skein_256 ******************************/
#if !(SKEIN_USE_ASM & 256)
void Skein_256_Process_Block(Skein_256_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd)
{ /* do it in C */
enum
{
WCNT = SKEIN_256_STATE_WORDS
};
#undef RCNT
#define RCNT (SKEIN_256_ROUNDS_TOTAL/8)
#ifdef SKEIN_LOOP /* configure how much to unroll the loop */
#define SKEIN_UNROLL_256 (((SKEIN_LOOP)/100)%10)
#else
#define SKEIN_UNROLL_256 (0)
#endif
#if SKEIN_UNROLL_256
#if (RCNT % SKEIN_UNROLL_256)
#error "Invalid SKEIN_UNROLL_256" /* sanity check on unroll count */
#endif
size_t r;
u64b_t kw[WCNT+4+RCNT*2]; /* key schedule words : chaining vars + tweak + "rotation"*/
#else
u64b_t kw[WCNT+4]; /* key schedule words : chaining vars + tweak */
#endif
u64b_t X0,X1,X2,X3; /* local copy of context vars, for speed */
u64b_t w [WCNT]; /* local copy of input block */
#ifdef SKEIN_DEBUG
const u64b_t *Xptr[4]; /* use for debugging (help compiler put Xn in registers) */
Xptr[0] = &X0; Xptr[1] = &X1; Xptr[2] = &X2; Xptr[3] = &X3;
#endif
Skein_assert(blkCnt != 0); /* never call with blkCnt == 0! */
ts[0] = ctx->h.T[0];
ts[1] = ctx->h.T[1];
do {
/* this implementation only supports 2**64 input bytes (no carry out here) */
ts[0] += byteCntAdd; /* update processed length */
/* precompute the key schedule for this block */
ks[0] = ctx->X[0];
ks[1] = ctx->X[1];
ks[2] = ctx->X[2];
ks[3] = ctx->X[3];
ks[4] = ks[0] ^ ks[1] ^ ks[2] ^ ks[3] ^ SKEIN_KS_PARITY;
ts[2] = ts[0] ^ ts[1];
Skein_Get64_LSB_First(w,blkPtr,WCNT); /* get input block in little-endian format */
DebugSaveTweak(ctx);
Skein_Show_Block(BLK_BITS,&ctx->h,ctx->X,blkPtr,w,ks,ts);
X0 = w[0] + ks[0]; /* do the first full key injection */
X1 = w[1] + ks[1] + ts[0];
X2 = w[2] + ks[2] + ts[1];
X3 = w[3] + ks[3];
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INITIAL,Xptr); /* show starting state values */
blkPtr += SKEIN_256_BLOCK_BYTES;
/* run the rounds */
#define Round256(p0,p1,p2,p3,ROT,rNum) \
X##p0 += X##p1; X##p1 = RotL_64(X##p1,ROT##_0); X##p1 ^= X##p0; \
X##p2 += X##p3; X##p3 = RotL_64(X##p3,ROT##_1); X##p3 ^= X##p2; \
#if SKEIN_UNROLL_256 == 0
#define R256(p0,p1,p2,p3,ROT,rNum) /* fully unrolled */ \
Round256(p0,p1,p2,p3,ROT,rNum) \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,rNum,Xptr);
#define I256(R) \
X0 += ks[((R)+1) % 5]; /* inject the key schedule value */ \
X1 += ks[((R)+2) % 5] + ts[((R)+1) % 3]; \
X2 += ks[((R)+3) % 5] + ts[((R)+2) % 3]; \
X3 += ks[((R)+4) % 5] + (R)+1; \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INJECT,Xptr);
#else /* looping version */
#define R256(p0,p1,p2,p3,ROT,rNum) \
Round256(p0,p1,p2,p3,ROT,rNum) \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,4*(r-1)+rNum,Xptr);
#define I256(R) \
X0 += ks[r+(R)+0]; /* inject the key schedule value */ \
X1 += ks[r+(R)+1] + ts[r+(R)+0]; \
X2 += ks[r+(R)+2] + ts[r+(R)+1]; \
X3 += ks[r+(R)+3] + r+(R) ; \
ks[r + (R)+4 ] = ks[r+(R)-1]; /* rotate key schedule */\
ts[r + (R)+2 ] = ts[r+(R)-1]; \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INJECT,Xptr);
for (r=1;r < 2*RCNT;r+=2*SKEIN_UNROLL_256) /* loop thru it */
#endif
{
#define R256_8_rounds(R) \
R256(0,1,2,3,R_256_0,8*(R) + 1); \
R256(0,3,2,1,R_256_1,8*(R) + 2); \
R256(0,1,2,3,R_256_2,8*(R) + 3); \
R256(0,3,2,1,R_256_3,8*(R) + 4); \
I256(2*(R)); \
R256(0,1,2,3,R_256_4,8*(R) + 5); \
R256(0,3,2,1,R_256_5,8*(R) + 6); \
R256(0,1,2,3,R_256_6,8*(R) + 7); \
R256(0,3,2,1,R_256_7,8*(R) + 8); \
I256(2*(R)+1);
R256_8_rounds( 0);
#define R256_Unroll_R(NN) ((SKEIN_UNROLL_256 == 0 && SKEIN_256_ROUNDS_TOTAL/8 > (NN)) || (SKEIN_UNROLL_256 > (NN)))
#if R256_Unroll_R( 1)
R256_8_rounds( 1);
#endif
#if R256_Unroll_R( 2)
R256_8_rounds( 2);
#endif
#if R256_Unroll_R( 3)
R256_8_rounds( 3);
#endif
#if R256_Unroll_R( 4)
R256_8_rounds( 4);
#endif
#if R256_Unroll_R( 5)
R256_8_rounds( 5);
#endif
#if R256_Unroll_R( 6)
R256_8_rounds( 6);
#endif
#if R256_Unroll_R( 7)
R256_8_rounds( 7);
#endif
#if R256_Unroll_R( 8)
R256_8_rounds( 8);
#endif
#if R256_Unroll_R( 9)
R256_8_rounds( 9);
#endif
#if R256_Unroll_R(10)
R256_8_rounds(10);
#endif
#if R256_Unroll_R(11)
R256_8_rounds(11);
#endif
#if R256_Unroll_R(12)
R256_8_rounds(12);
#endif
#if R256_Unroll_R(13)
R256_8_rounds(13);
#endif
#if R256_Unroll_R(14)
R256_8_rounds(14);
#endif
#if (SKEIN_UNROLL_256 > 14)
#error "need more unrolling in Skein_256_Process_Block"
#endif
}
/* do the final "feedforward" xor, update context chaining vars */
ctx->X[0] = X0 ^ w[0];
ctx->X[1] = X1 ^ w[1];
ctx->X[2] = X2 ^ w[2];
ctx->X[3] = X3 ^ w[3];
Skein_Show_Round(BLK_BITS,&ctx->h,SKEIN_RND_FEED_FWD,ctx->X);
ts[1] &= ~SKEIN_T1_FLAG_FIRST;
}
while (--blkCnt);
ctx->h.T[0] = ts[0];
ctx->h.T[1] = ts[1];
}
#if defined(SKEIN_CODE_SIZE) || defined(SKEIN_PERF)
size_t Skein_256_Process_Block_CodeSize(void)
{
return ((u08b_t *) Skein_256_Process_Block_CodeSize) -
((u08b_t *) Skein_256_Process_Block);
}
uint_t Skein_256_Unroll_Cnt(void)
{
return SKEIN_UNROLL_256;
}
#endif
#endif
/***************************** Skein_512 ******************************/
#if !(SKEIN_USE_ASM & 512)
void Skein_512_Process_Block(Skein_512_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd)
{ /* do it in C */
enum
{
WCNT = SKEIN_512_STATE_WORDS
};
#undef RCNT
#define RCNT (SKEIN_512_ROUNDS_TOTAL/8)
#ifdef SKEIN_LOOP /* configure how much to unroll the loop */
#define SKEIN_UNROLL_512 (((SKEIN_LOOP)/10)%10)
#else
#define SKEIN_UNROLL_512 (0)
#endif
#if SKEIN_UNROLL_512
#if (RCNT % SKEIN_UNROLL_512)
#error "Invalid SKEIN_UNROLL_512" /* sanity check on unroll count */
#endif
size_t r;
u64b_t kw[WCNT+4+RCNT*2]; /* key schedule words : chaining vars + tweak + "rotation"*/
#else
u64b_t kw[WCNT+4]; /* key schedule words : chaining vars + tweak */
#endif
u64b_t X0,X1,X2,X3,X4,X5,X6,X7; /* local copy of vars, for speed */
u64b_t w [WCNT]; /* local copy of input block */
#ifdef SKEIN_DEBUG
const u64b_t *Xptr[8]; /* use for debugging (help compiler put Xn in registers) */
Xptr[0] = &X0; Xptr[1] = &X1; Xptr[2] = &X2; Xptr[3] = &X3;
Xptr[4] = &X4; Xptr[5] = &X5; Xptr[6] = &X6; Xptr[7] = &X7;
#endif
Skein_assert(blkCnt != 0); /* never call with blkCnt == 0! */
ts[0] = ctx->h.T[0];
ts[1] = ctx->h.T[1];
do {
/* this implementation only supports 2**64 input bytes (no carry out here) */
ts[0] += byteCntAdd; /* update processed length */
/* precompute the key schedule for this block */
ks[0] = ctx->X[0];
ks[1] = ctx->X[1];
ks[2] = ctx->X[2];
ks[3] = ctx->X[3];
ks[4] = ctx->X[4];
ks[5] = ctx->X[5];
ks[6] = ctx->X[6];
ks[7] = ctx->X[7];
ks[8] = ks[0] ^ ks[1] ^ ks[2] ^ ks[3] ^
ks[4] ^ ks[5] ^ ks[6] ^ ks[7] ^ SKEIN_KS_PARITY;
ts[2] = ts[0] ^ ts[1];
Skein_Get64_LSB_First(w,blkPtr,WCNT); /* get input block in little-endian format */
DebugSaveTweak(ctx);
Skein_Show_Block(BLK_BITS,&ctx->h,ctx->X,blkPtr,w,ks,ts);
X0 = w[0] + ks[0]; /* do the first full key injection */
X1 = w[1] + ks[1];
X2 = w[2] + ks[2];
X3 = w[3] + ks[3];
X4 = w[4] + ks[4];
X5 = w[5] + ks[5] + ts[0];
X6 = w[6] + ks[6] + ts[1];
X7 = w[7] + ks[7];
blkPtr += SKEIN_512_BLOCK_BYTES;
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INITIAL,Xptr);
/* run the rounds */
#define Round512(p0,p1,p2,p3,p4,p5,p6,p7,ROT,rNum) \
X##p0 += X##p1; X##p1 = RotL_64(X##p1,ROT##_0); X##p1 ^= X##p0; \
X##p2 += X##p3; X##p3 = RotL_64(X##p3,ROT##_1); X##p3 ^= X##p2; \
X##p4 += X##p5; X##p5 = RotL_64(X##p5,ROT##_2); X##p5 ^= X##p4; \
X##p6 += X##p7; X##p7 = RotL_64(X##p7,ROT##_3); X##p7 ^= X##p6; \
#if SKEIN_UNROLL_512 == 0
#define R512(p0,p1,p2,p3,p4,p5,p6,p7,ROT,rNum) /* unrolled */ \
Round512(p0,p1,p2,p3,p4,p5,p6,p7,ROT,rNum) \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,rNum,Xptr);
#define I512(R) \
X0 += ks[((R)+1) % 9]; /* inject the key schedule value */ \
X1 += ks[((R)+2) % 9]; \
X2 += ks[((R)+3) % 9]; \
X3 += ks[((R)+4) % 9]; \
X4 += ks[((R)+5) % 9]; \
X5 += ks[((R)+6) % 9] + ts[((R)+1) % 3]; \
X6 += ks[((R)+7) % 9] + ts[((R)+2) % 3]; \
X7 += ks[((R)+8) % 9] + (R)+1; \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INJECT,Xptr);
#else /* looping version */
#define R512(p0,p1,p2,p3,p4,p5,p6,p7,ROT,rNum) \
Round512(p0,p1,p2,p3,p4,p5,p6,p7,ROT,rNum) \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,4*(r-1)+rNum,Xptr);
#define I512(R) \
X0 += ks[r+(R)+0]; /* inject the key schedule value */ \
X1 += ks[r+(R)+1]; \
X2 += ks[r+(R)+2]; \
X3 += ks[r+(R)+3]; \
X4 += ks[r+(R)+4]; \
X5 += ks[r+(R)+5] + ts[r+(R)+0]; \
X6 += ks[r+(R)+6] + ts[r+(R)+1]; \
X7 += ks[r+(R)+7] + r+(R) ; \
ks[r + (R)+8] = ks[r+(R)-1]; /* rotate key schedule */ \
ts[r + (R)+2] = ts[r+(R)-1]; \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INJECT,Xptr);
for (r=1;r < 2*RCNT;r+=2*SKEIN_UNROLL_512) /* loop thru it */
#endif /* end of looped code definitions */
{
#define R512_8_rounds(R) /* do 8 full rounds */ \
R512(0,1,2,3,4,5,6,7,R_512_0,8*(R)+ 1); \
R512(2,1,4,7,6,5,0,3,R_512_1,8*(R)+ 2); \
R512(4,1,6,3,0,5,2,7,R_512_2,8*(R)+ 3); \
R512(6,1,0,7,2,5,4,3,R_512_3,8*(R)+ 4); \
I512(2*(R)); \
R512(0,1,2,3,4,5,6,7,R_512_4,8*(R)+ 5); \
R512(2,1,4,7,6,5,0,3,R_512_5,8*(R)+ 6); \
R512(4,1,6,3,0,5,2,7,R_512_6,8*(R)+ 7); \
R512(6,1,0,7,2,5,4,3,R_512_7,8*(R)+ 8); \
I512(2*(R)+1); /* and key injection */
R512_8_rounds( 0);
#define R512_Unroll_R(NN) ((SKEIN_UNROLL_512 == 0 && SKEIN_512_ROUNDS_TOTAL/8 > (NN)) || (SKEIN_UNROLL_512 > (NN)))
#if R512_Unroll_R( 1)
R512_8_rounds( 1);
#endif
#if R512_Unroll_R( 2)
R512_8_rounds( 2);
#endif
#if R512_Unroll_R( 3)
R512_8_rounds( 3);
#endif
#if R512_Unroll_R( 4)
R512_8_rounds( 4);
#endif
#if R512_Unroll_R( 5)
R512_8_rounds( 5);
#endif
#if R512_Unroll_R( 6)
R512_8_rounds( 6);
#endif
#if R512_Unroll_R( 7)
R512_8_rounds( 7);
#endif
#if R512_Unroll_R( 8)
R512_8_rounds( 8);
#endif
#if R512_Unroll_R( 9)
R512_8_rounds( 9);
#endif
#if R512_Unroll_R(10)
R512_8_rounds(10);
#endif
#if R512_Unroll_R(11)
R512_8_rounds(11);
#endif
#if R512_Unroll_R(12)
R512_8_rounds(12);
#endif
#if R512_Unroll_R(13)
R512_8_rounds(13);
#endif
#if R512_Unroll_R(14)
R512_8_rounds(14);
#endif
#if (SKEIN_UNROLL_512 > 14)
#error "need more unrolling in Skein_512_Process_Block"
#endif
}
/* do the final "feedforward" xor, update context chaining vars */
ctx->X[0] = X0 ^ w[0];
ctx->X[1] = X1 ^ w[1];
ctx->X[2] = X2 ^ w[2];
ctx->X[3] = X3 ^ w[3];
ctx->X[4] = X4 ^ w[4];
ctx->X[5] = X5 ^ w[5];
ctx->X[6] = X6 ^ w[6];
ctx->X[7] = X7 ^ w[7];
Skein_Show_Round(BLK_BITS,&ctx->h,SKEIN_RND_FEED_FWD,ctx->X);
ts[1] &= ~SKEIN_T1_FLAG_FIRST;
}
while (--blkCnt);
ctx->h.T[0] = ts[0];
ctx->h.T[1] = ts[1];
}
#if defined(SKEIN_CODE_SIZE) || defined(SKEIN_PERF)
size_t Skein_512_Process_Block_CodeSize(void)
{
return ((u08b_t *) Skein_512_Process_Block_CodeSize) -
((u08b_t *) Skein_512_Process_Block);
}
uint_t Skein_512_Unroll_Cnt(void)
{
return SKEIN_UNROLL_512;
}
#endif
#endif
/***************************** Skein1024 ******************************/
#if !(SKEIN_USE_ASM & 1024)
void Skein1024_Process_Block(Skein1024_Ctxt_t *ctx,const u08b_t *blkPtr,size_t blkCnt,size_t byteCntAdd)
{ /* do it in C, always looping (unrolled is bigger AND slower!) */
enum
{
WCNT = SKEIN1024_STATE_WORDS
};
#undef RCNT
#define RCNT (SKEIN1024_ROUNDS_TOTAL/8)
#ifdef SKEIN_LOOP /* configure how much to unroll the loop */
#define SKEIN_UNROLL_1024 ((SKEIN_LOOP)%10)
#else
#define SKEIN_UNROLL_1024 (0)
#endif
#if (SKEIN_UNROLL_1024 != 0)
#if (RCNT % SKEIN_UNROLL_1024)
#error "Invalid SKEIN_UNROLL_1024" /* sanity check on unroll count */
#endif
size_t r;
u64b_t kw[WCNT+4+RCNT*2]; /* key schedule words : chaining vars + tweak + "rotation"*/
#else
u64b_t kw[WCNT+4]; /* key schedule words : chaining vars + tweak */
#endif
u64b_t X00,X01,X02,X03,X04,X05,X06,X07, /* local copy of vars, for speed */
X08,X09,X10,X11,X12,X13,X14,X15;
u64b_t w [WCNT]; /* local copy of input block */
#ifdef SKEIN_DEBUG
const u64b_t *Xptr[16]; /* use for debugging (help compiler put Xn in registers) */
Xptr[ 0] = &X00; Xptr[ 1] = &X01; Xptr[ 2] = &X02; Xptr[ 3] = &X03;
Xptr[ 4] = &X04; Xptr[ 5] = &X05; Xptr[ 6] = &X06; Xptr[ 7] = &X07;
Xptr[ 8] = &X08; Xptr[ 9] = &X09; Xptr[10] = &X10; Xptr[11] = &X11;
Xptr[12] = &X12; Xptr[13] = &X13; Xptr[14] = &X14; Xptr[15] = &X15;
#endif
Skein_assert(blkCnt != 0); /* never call with blkCnt == 0! */
ts[0] = ctx->h.T[0];
ts[1] = ctx->h.T[1];
do {
/* this implementation only supports 2**64 input bytes (no carry out here) */
ts[0] += byteCntAdd; /* update processed length */
/* precompute the key schedule for this block */
ks[ 0] = ctx->X[ 0];
ks[ 1] = ctx->X[ 1];
ks[ 2] = ctx->X[ 2];
ks[ 3] = ctx->X[ 3];
ks[ 4] = ctx->X[ 4];
ks[ 5] = ctx->X[ 5];
ks[ 6] = ctx->X[ 6];
ks[ 7] = ctx->X[ 7];
ks[ 8] = ctx->X[ 8];
ks[ 9] = ctx->X[ 9];
ks[10] = ctx->X[10];
ks[11] = ctx->X[11];
ks[12] = ctx->X[12];
ks[13] = ctx->X[13];
ks[14] = ctx->X[14];
ks[15] = ctx->X[15];
ks[16] = ks[ 0] ^ ks[ 1] ^ ks[ 2] ^ ks[ 3] ^
ks[ 4] ^ ks[ 5] ^ ks[ 6] ^ ks[ 7] ^
ks[ 8] ^ ks[ 9] ^ ks[10] ^ ks[11] ^
ks[12] ^ ks[13] ^ ks[14] ^ ks[15] ^ SKEIN_KS_PARITY;
ts[2] = ts[0] ^ ts[1];
Skein_Get64_LSB_First(w,blkPtr,WCNT); /* get input block in little-endian format */
DebugSaveTweak(ctx);
Skein_Show_Block(BLK_BITS,&ctx->h,ctx->X,blkPtr,w,ks,ts);
X00 = w[ 0] + ks[ 0]; /* do the first full key injection */
X01 = w[ 1] + ks[ 1];
X02 = w[ 2] + ks[ 2];
X03 = w[ 3] + ks[ 3];
X04 = w[ 4] + ks[ 4];
X05 = w[ 5] + ks[ 5];
X06 = w[ 6] + ks[ 6];
X07 = w[ 7] + ks[ 7];
X08 = w[ 8] + ks[ 8];
X09 = w[ 9] + ks[ 9];
X10 = w[10] + ks[10];
X11 = w[11] + ks[11];
X12 = w[12] + ks[12];
X13 = w[13] + ks[13] + ts[0];
X14 = w[14] + ks[14] + ts[1];
X15 = w[15] + ks[15];
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INITIAL,Xptr);
#define Round1024(p0,p1,p2,p3,p4,p5,p6,p7,p8,p9,pA,pB,pC,pD,pE,pF,ROT,rNum) \
X##p0 += X##p1; X##p1 = RotL_64(X##p1,ROT##_0); X##p1 ^= X##p0; \
X##p2 += X##p3; X##p3 = RotL_64(X##p3,ROT##_1); X##p3 ^= X##p2; \
X##p4 += X##p5; X##p5 = RotL_64(X##p5,ROT##_2); X##p5 ^= X##p4; \
X##p6 += X##p7; X##p7 = RotL_64(X##p7,ROT##_3); X##p7 ^= X##p6; \
X##p8 += X##p9; X##p9 = RotL_64(X##p9,ROT##_4); X##p9 ^= X##p8; \
X##pA += X##pB; X##pB = RotL_64(X##pB,ROT##_5); X##pB ^= X##pA; \
X##pC += X##pD; X##pD = RotL_64(X##pD,ROT##_6); X##pD ^= X##pC; \
X##pE += X##pF; X##pF = RotL_64(X##pF,ROT##_7); X##pF ^= X##pE; \
#if SKEIN_UNROLL_1024 == 0
#define R1024(p0,p1,p2,p3,p4,p5,p6,p7,p8,p9,pA,pB,pC,pD,pE,pF,ROT,rn) \
Round1024(p0,p1,p2,p3,p4,p5,p6,p7,p8,p9,pA,pB,pC,pD,pE,pF,ROT,rn) \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,rn,Xptr);
#define I1024(R) \
X00 += ks[((R)+ 1) % 17]; /* inject the key schedule value */ \
X01 += ks[((R)+ 2) % 17]; \
X02 += ks[((R)+ 3) % 17]; \
X03 += ks[((R)+ 4) % 17]; \
X04 += ks[((R)+ 5) % 17]; \
X05 += ks[((R)+ 6) % 17]; \
X06 += ks[((R)+ 7) % 17]; \
X07 += ks[((R)+ 8) % 17]; \
X08 += ks[((R)+ 9) % 17]; \
X09 += ks[((R)+10) % 17]; \
X10 += ks[((R)+11) % 17]; \
X11 += ks[((R)+12) % 17]; \
X12 += ks[((R)+13) % 17]; \
X13 += ks[((R)+14) % 17] + ts[((R)+1) % 3]; \
X14 += ks[((R)+15) % 17] + ts[((R)+2) % 3]; \
X15 += ks[((R)+16) % 17] + (R)+1; \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INJECT,Xptr);
#else /* looping version */
#define R1024(p0,p1,p2,p3,p4,p5,p6,p7,p8,p9,pA,pB,pC,pD,pE,pF,ROT,rn) \
Round1024(p0,p1,p2,p3,p4,p5,p6,p7,p8,p9,pA,pB,pC,pD,pE,pF,ROT,rn) \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,4*(r-1)+rn,Xptr);
#define I1024(R) \
X00 += ks[r+(R)+ 0]; /* inject the key schedule value */ \
X01 += ks[r+(R)+ 1]; \
X02 += ks[r+(R)+ 2]; \
X03 += ks[r+(R)+ 3]; \
X04 += ks[r+(R)+ 4]; \
X05 += ks[r+(R)+ 5]; \
X06 += ks[r+(R)+ 6]; \
X07 += ks[r+(R)+ 7]; \
X08 += ks[r+(R)+ 8]; \
X09 += ks[r+(R)+ 9]; \
X10 += ks[r+(R)+10]; \
X11 += ks[r+(R)+11]; \
X12 += ks[r+(R)+12]; \
X13 += ks[r+(R)+13] + ts[r+(R)+0]; \
X14 += ks[r+(R)+14] + ts[r+(R)+1]; \
X15 += ks[r+(R)+15] + r+(R) ; \
ks[r + (R)+16] = ks[r+(R)-1]; /* rotate key schedule */ \
ts[r + (R)+ 2] = ts[r+(R)-1]; \
Skein_Show_R_Ptr(BLK_BITS,&ctx->h,SKEIN_RND_KEY_INJECT,Xptr);
for (r=1;r <= 2*RCNT;r+=2*SKEIN_UNROLL_1024) /* loop thru it */
#endif
{
#define R1024_8_rounds(R) /* do 8 full rounds */ \
R1024(00,01,02,03,04,05,06,07,08,09,10,11,12,13,14,15,R1024_0,8*(R) + 1); \
R1024(00,09,02,13,06,11,04,15,10,07,12,03,14,05,08,01,R1024_1,8*(R) + 2); \
R1024(00,07,02,05,04,03,06,01,12,15,14,13,08,11,10,09,R1024_2,8*(R) + 3); \
R1024(00,15,02,11,06,13,04,09,14,01,08,05,10,03,12,07,R1024_3,8*(R) + 4); \
I1024(2*(R)); \
R1024(00,01,02,03,04,05,06,07,08,09,10,11,12,13,14,15,R1024_4,8*(R) + 5); \
R1024(00,09,02,13,06,11,04,15,10,07,12,03,14,05,08,01,R1024_5,8*(R) + 6); \
R1024(00,07,02,05,04,03,06,01,12,15,14,13,08,11,10,09,R1024_6,8*(R) + 7); \
R1024(00,15,02,11,06,13,04,09,14,01,08,05,10,03,12,07,R1024_7,8*(R) + 8); \
I1024(2*(R)+1);
R1024_8_rounds( 0);
#define R1024_Unroll_R(NN) ((SKEIN_UNROLL_1024 == 0 && SKEIN1024_ROUNDS_TOTAL/8 > (NN)) || (SKEIN_UNROLL_1024 > (NN)))
#if R1024_Unroll_R( 1)
R1024_8_rounds( 1);
#endif
#if R1024_Unroll_R( 2)
R1024_8_rounds( 2);
#endif
#if R1024_Unroll_R( 3)
R1024_8_rounds( 3);
#endif
#if R1024_Unroll_R( 4)
R1024_8_rounds( 4);
#endif
#if R1024_Unroll_R( 5)
R1024_8_rounds( 5);
#endif
#if R1024_Unroll_R( 6)
R1024_8_rounds( 6);
#endif
#if R1024_Unroll_R( 7)
R1024_8_rounds( 7);
#endif
#if R1024_Unroll_R( 8)
R1024_8_rounds( 8);
#endif
#if R1024_Unroll_R( 9)
R1024_8_rounds( 9);
#endif
#if R1024_Unroll_R(10)
R1024_8_rounds(10);
#endif
#if R1024_Unroll_R(11)
R1024_8_rounds(11);
#endif
#if R1024_Unroll_R(12)
R1024_8_rounds(12);
#endif
#if R1024_Unroll_R(13)
R1024_8_rounds(13);
#endif
#if R1024_Unroll_R(14)
R1024_8_rounds(14);
#endif
#if (SKEIN_UNROLL_1024 > 14)
#error "need more unrolling in Skein_1024_Process_Block"
#endif
}
/* do the final "feedforward" xor, update context chaining vars */
ctx->X[ 0] = X00 ^ w[ 0];
ctx->X[ 1] = X01 ^ w[ 1];
ctx->X[ 2] = X02 ^ w[ 2];
ctx->X[ 3] = X03 ^ w[ 3];
ctx->X[ 4] = X04 ^ w[ 4];
ctx->X[ 5] = X05 ^ w[ 5];
ctx->X[ 6] = X06 ^ w[ 6];
ctx->X[ 7] = X07 ^ w[ 7];
ctx->X[ 8] = X08 ^ w[ 8];
ctx->X[ 9] = X09 ^ w[ 9];
ctx->X[10] = X10 ^ w[10];
ctx->X[11] = X11 ^ w[11];
ctx->X[12] = X12 ^ w[12];
ctx->X[13] = X13 ^ w[13];
ctx->X[14] = X14 ^ w[14];
ctx->X[15] = X15 ^ w[15];
Skein_Show_Round(BLK_BITS,&ctx->h,SKEIN_RND_FEED_FWD,ctx->X);
ts[1] &= ~SKEIN_T1_FLAG_FIRST;
blkPtr += SKEIN1024_BLOCK_BYTES;
}
while (--blkCnt);
ctx->h.T[0] = ts[0];
ctx->h.T[1] = ts[1];
}
#if defined(SKEIN_CODE_SIZE) || defined(SKEIN_PERF)
size_t Skein1024_Process_Block_CodeSize(void)
{
return ((u08b_t *) Skein1024_Process_Block_CodeSize) -
((u08b_t *) Skein1024_Process_Block);
}
uint_t Skein1024_Unroll_Cnt(void)
{
return SKEIN_UNROLL_1024;
}
#endif
#endif

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/***********************************************************************
**
** Debug output functions for Skein hashing.
**
** Source code author: Doug Whiting, 2008.
**
** This algorithm and source code is released to the public domain.
**
************************************************************************/
#include <stdio.h>
#ifdef SKEIN_DEBUG /* only instantiate this code if SKEIN_DEBUG is on */
#include "skein.h"
static const char INDENT[] = " "; /* how much to indent on new line */
uint_t skein_DebugFlag = 0; /* off by default. Must be set externally */
static void Show64_step(size_t cnt,const u64b_t *X,size_t step)
{
size_t i,j;
for (i=j=0;i < cnt;i++,j+=step)
{
if (i % 4 == 0) printf(INDENT);
printf(" %08X.%08X ",(uint_32t)(X[j] >> 32),(uint_32t)X[j]);
if (i % 4 == 3 || i==cnt-1) printf("\n");
fflush(stdout);
}
}
#define Show64(cnt,X) Show64_step(cnt,X,1)
static void Show64_flag(size_t cnt,const u64b_t *X)
{
size_t xptr = (size_t) X;
size_t step = (xptr & 1) ? 2 : 1;
if (step != 1)
{
X = (const u64b_t *) (xptr & ~1);
}
Show64_step(cnt,X,step);
}
static void Show08(size_t cnt,const u08b_t *b)
{
size_t i;
for (i=0;i < cnt;i++)
{
if (i %16 == 0) printf(INDENT);
else if (i % 4 == 0) printf(" ");
printf(" %02X",b[i]);
if (i %16 == 15 || i==cnt-1) printf("\n");
fflush(stdout);
}
}
static const char *AlgoHeader(uint_t bits)
{
if (skein_DebugFlag & SKEIN_DEBUG_THREEFISH)
switch (bits)
{
case 256: return ":Threefish-256: ";
case 512: return ":Threefish-512: ";
case 1024: return ":Threefish-1024:";
}
else
switch (bits)
{
case 256: return ":Skein-256: ";
case 512: return ":Skein-512: ";
case 1024: return ":Skein-1024:";
}
return NULL;
}
void Skein_Show_Final(uint_t bits,const Skein_Ctxt_Hdr_t *h,size_t cnt,const u08b_t *outPtr)
{
if (skein_DebugFlag & SKEIN_DEBUG_CONFIG || ((h->T[1] & SKEIN_T1_BLK_TYPE_MASK) != SKEIN_T1_BLK_TYPE_CFG))
if (skein_DebugFlag & SKEIN_DEBUG_FINAL)
{
printf("\n%s Final output=\n",AlgoHeader(bits));
Show08(cnt,outPtr);
printf(" ++++++++++\n");
fflush(stdout);
}
}
/* show state after a round (or "pseudo-round") */
void Skein_Show_Round(uint_t bits,const Skein_Ctxt_Hdr_t *h,size_t r,const u64b_t *X)
{
static uint_t injectNum=0; /* not multi-thread safe! */
if (skein_DebugFlag & SKEIN_DEBUG_CONFIG || ((h->T[1] & SKEIN_T1_BLK_TYPE_MASK) != SKEIN_T1_BLK_TYPE_CFG))
if (skein_DebugFlag)
{
if (r >= SKEIN_RND_SPECIAL)
{ /* a key injection (or feedforward) point */
injectNum = (r == SKEIN_RND_KEY_INITIAL) ? 0 : injectNum+1;
if ( skein_DebugFlag & SKEIN_DEBUG_INJECT ||
((skein_DebugFlag & SKEIN_DEBUG_FINAL) && r == SKEIN_RND_FEED_FWD))
{
printf("\n%s",AlgoHeader(bits));
switch (r)
{
case SKEIN_RND_KEY_INITIAL:
printf(" [state after initial key injection]");
break;
case SKEIN_RND_KEY_INJECT:
printf(" [state after key injection #%02d]",injectNum);
break;
case SKEIN_RND_FEED_FWD:
printf(" [state after plaintext feedforward]");
injectNum = 0;
break;
}
printf("=\n");
Show64(bits/64,X);
if (r== SKEIN_RND_FEED_FWD)
printf(" ----------\n");
}
}
else if (skein_DebugFlag & SKEIN_DEBUG_ROUNDS)
{
uint_t j;
u64b_t p[SKEIN_MAX_STATE_WORDS];
const u08b_t *perm;
const static u08b_t PERM_256 [4][ 4] = { { 0,1,2,3 }, { 0,3,2,1 }, { 0,1,2,3 }, { 0,3,2,1 } };
const static u08b_t PERM_512 [4][ 8] = { { 0,1,2,3,4,5,6,7 },
{ 2,1,4,7,6,5,0,3 },
{ 4,1,6,3,0,5,2,7 },
{ 6,1,0,7,2,5,4,3 }
};
const static u08b_t PERM_1024[4][16] = { { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9,10,11,12,13,14,15 },
{ 0, 9, 2,13, 6,11, 4,15,10, 7,12, 3,14, 5, 8, 1 },
{ 0, 7, 2, 5, 4, 3, 6, 1,12,15,14,13, 8,11,10, 9 },
{ 0,15, 2,11, 6,13, 4, 9,14, 1, 8, 5,10, 3,12, 7 }
};
if ((skein_DebugFlag & SKEIN_DEBUG_PERMUTE) && (r & 3))
{
printf("\n%s [state after round %2d (permuted)]=\n",AlgoHeader(bits),(int)r);
switch (bits)
{
case 256: perm = PERM_256 [r&3]; break;
case 512: perm = PERM_512 [r&3]; break;
default: perm = PERM_1024[r&3]; break;
}
for (j=0;j<bits/64;j++)
p[j] = X[perm[j]];
Show64(bits/64,p);
}
else
{
printf("\n%s [state after round %2d]=\n",AlgoHeader(bits),(int)r);
Show64(bits/64,X);
}
}
}
}
/* show state after a round (or "pseudo-round"), given a list of pointers */
void Skein_Show_R_Ptr(uint_t bits,const Skein_Ctxt_Hdr_t *h,size_t r,const u64b_t *X_ptr[])
{
uint_t i;
u64b_t X[SKEIN_MAX_STATE_WORDS];
for (i=0;i<bits/64;i++) /* copy over the words */
X[i] = X_ptr[i][0];
Skein_Show_Round(bits,h,r,X);
}
/* show the state at the start of a block */
void Skein_Show_Block(uint_t bits,const Skein_Ctxt_Hdr_t *h,const u64b_t *X,const u08b_t *blkPtr,
const u64b_t *wPtr, const u64b_t *ksPtr, const u64b_t *tsPtr)
{
uint_t n;
if (skein_DebugFlag & SKEIN_DEBUG_CONFIG || ((h->T[1] & SKEIN_T1_BLK_TYPE_MASK) != SKEIN_T1_BLK_TYPE_CFG))
if (skein_DebugFlag)
{
if (skein_DebugFlag & SKEIN_DEBUG_HDR)
{
printf("\n%s Block: outBits=%4d. T0=%06X.",AlgoHeader(bits),(uint_t) h->hashBitLen,(uint_t)h->T[0]);
printf(" Type=");
n = (uint_t) ((h->T[1] & SKEIN_T1_BLK_TYPE_MASK) >> SKEIN_T1_POS_BLK_TYPE);
switch (n)
{
case SKEIN_BLK_TYPE_KEY: printf("KEY. "); break;
case SKEIN_BLK_TYPE_CFG: printf("CFG. "); break;
case SKEIN_BLK_TYPE_PERS: printf("PERS."); break;
case SKEIN_BLK_TYPE_PK : printf("PK. "); break;
case SKEIN_BLK_TYPE_KDF: printf("KDF. "); break;
case SKEIN_BLK_TYPE_MSG: printf("MSG. "); break;
case SKEIN_BLK_TYPE_OUT: printf("OUT. "); break;
default: printf("0x%02X.",n); break;
}
printf(" Flags=");
printf((h->T[1] & SKEIN_T1_FLAG_FIRST) ? " First":" ");
printf((h->T[1] & SKEIN_T1_FLAG_FINAL) ? " Final":" ");
printf((h->T[1] & SKEIN_T1_FLAG_BIT_PAD) ? " Pad" :" ");
n = (uint_t) ((h->T[1] & SKEIN_T1_TREE_LVL_MASK) >> SKEIN_T1_POS_TREE_LVL);
if (n)
printf(" TreeLevel = %02X",n);
printf("\n");
fflush(stdout);
}
if (skein_DebugFlag & SKEIN_DEBUG_TWEAK)
{
printf(" Tweak:\n");
Show64(2,h->T);
}
if (skein_DebugFlag & SKEIN_DEBUG_STATE)
{
printf(" %s words:\n",(skein_DebugFlag & SKEIN_DEBUG_THREEFISH)?"Key":"State");
Show64(bits/64,X);
}
if (skein_DebugFlag & SKEIN_DEBUG_KEYSCHED)
{
printf(" Tweak schedule:\n");
Show64_flag(3,tsPtr);
printf(" Key schedule:\n");
Show64_flag((bits/64)+1,ksPtr);
}
if (skein_DebugFlag & SKEIN_DEBUG_INPUT_64)
{
printf(" Input block (words):\n");
Show64(bits/64,wPtr);
}
if (skein_DebugFlag & SKEIN_DEBUG_INPUT_08)
{
printf(" Input block (bytes):\n");
Show08(bits/8,blkPtr);
}
}
}
void Skein_Show_Key(uint_t bits,const Skein_Ctxt_Hdr_t *h,const u08b_t *key,size_t keyBytes)
{
if (keyBytes)
if (skein_DebugFlag & SKEIN_DEBUG_CONFIG || ((h->T[1] & SKEIN_T1_BLK_TYPE_MASK) != SKEIN_T1_BLK_TYPE_CFG))
if (skein_DebugFlag & SKEIN_DEBUG_KEY)
{
printf("\n%s MAC key = %4u bytes\n",AlgoHeader(bits),(unsigned) keyBytes);
Show08(keyBytes,key);
}
}
#endif

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#ifndef _SKEIN_DEBUG_H_
#define _SKEIN_DEBUG_H_
/***********************************************************************
**
** Interface definitions for Skein hashing debug output.
**
** Source code author: Doug Whiting, 2008.
**
** This algorithm and source code is released to the public domain.
**
************************************************************************/
#ifdef SKEIN_DEBUG
/* callout functions used inside Skein code */
void Skein_Show_Block(uint_t bits,const Skein_Ctxt_Hdr_t *h,const u64b_t *X,const u08b_t *blkPtr,
const u64b_t *wPtr,const u64b_t *ksPtr,const u64b_t *tsPtr);
void Skein_Show_Round(uint_t bits,const Skein_Ctxt_Hdr_t *h,size_t r,const u64b_t *X);
void Skein_Show_R_Ptr(uint_t bits,const Skein_Ctxt_Hdr_t *h,size_t r,const u64b_t *X_ptr[]);
void Skein_Show_Final(uint_t bits,const Skein_Ctxt_Hdr_t *h,size_t cnt,const u08b_t *outPtr);
void Skein_Show_Key (uint_t bits,const Skein_Ctxt_Hdr_t *h,const u08b_t *key,size_t keyBytes);
extern uint_t skein_DebugFlag; /* flags to control debug output (0 --> none) */
#define SKEIN_RND_SPECIAL (1000u)
#define SKEIN_RND_KEY_INITIAL (SKEIN_RND_SPECIAL+0u)
#define SKEIN_RND_KEY_INJECT (SKEIN_RND_SPECIAL+1u)
#define SKEIN_RND_FEED_FWD (SKEIN_RND_SPECIAL+2u)
/* flag bits: skein_DebugFlag */
#define SKEIN_DEBUG_KEY (1u << 1) /* show MAC key */
#define SKEIN_DEBUG_CONFIG (1u << 2) /* show config block processing */
#define SKEIN_DEBUG_STATE (1u << 3) /* show input state during Show_Block() */
#define SKEIN_DEBUG_TWEAK (1u << 4) /* show input state during Show_Block() */
#define SKEIN_DEBUG_KEYSCHED (1u << 5) /* show expanded key schedule */
#define SKEIN_DEBUG_INPUT_64 (1u << 6) /* show input block as 64-bit words */
#define SKEIN_DEBUG_INPUT_08 (1u << 7) /* show input block as 8-bit bytes */
#define SKEIN_DEBUG_INJECT (1u << 8) /* show state after key injection & feedforward points */
#define SKEIN_DEBUG_ROUNDS (1u << 9) /* show state after all rounds */
#define SKEIN_DEBUG_FINAL (1u <<10) /* show final output of Skein */
#define SKEIN_DEBUG_HDR (1u <<11) /* show block header */
#define SKEIN_DEBUG_THREEFISH (1u <<12) /* use Threefish name instead of Skein */
#define SKEIN_DEBUG_PERMUTE (1u <<13) /* use word permutations */
#define SKEIN_DEBUG_ALL ((~0u) & ~(SKEIN_DEBUG_THREEFISH | SKEIN_DEBUG_PERMUTE))
#define THREEFISH_DEBUG_ALL (SKEIN_DEBUG_ALL | SKEIN_DEBUG_THREEFISH)
#endif /* SKEIN_DEBUG */
#endif /* _SKEIN_DEBUG_H_ */

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/*-
* Copyright 2016 Allan Jude
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $FreeBSD$
*/
#ifndef _SKEIN_FREEBSD_H_
#define _SKEIN_FREEBSD_H_
#define SKEIN_256_BLOCK_BYTES ( 8*SKEIN_256_STATE_WORDS)
#define SKEIN_512_BLOCK_BYTES ( 8*SKEIN_512_STATE_WORDS)
#define SKEIN1024_BLOCK_BYTES ( 8*SKEIN1024_STATE_WORDS)
#define SKEIN256_BLOCK_LENGTH SKEIN_256_BLOCK_BYTES
#define SKEIN256_DIGEST_LENGTH 32
#define SKEIN256_DIGEST_STRING_LENGTH (SKEIN256_DIGEST_LENGTH * 2 + 1)
#define SKEIN512_BLOCK_LENGTH SKEIN_512_BLOCK_BYTES
#define SKEIN512_DIGEST_LENGTH 64
#define SKEIN512_DIGEST_STRING_LENGTH (SKEIN512_DIGEST_LENGTH * 2 + 1)
#define SKEIN1024_BLOCK_LENGTH SKEIN1024_BLOCK_BYTES
#define SKEIN1024_DIGEST_LENGTH 128
#define SKEIN1024_DIGEST_STRING_LENGTH (SKEIN1024_DIGEST_LENGTH * 2 + 1)
/* Make the context types look like the other hashes on FreeBSD */
typedef Skein_256_Ctxt_t SKEIN256_CTX;
typedef Skein_512_Ctxt_t SKEIN512_CTX;
typedef Skein1024_Ctxt_t SKEIN1024_CTX;
/* Make the prototypes look like the other hashes */
void SKEIN256_Init (SKEIN256_CTX *ctx);
void SKEIN512_Init (SKEIN512_CTX *ctx);
void SKEIN1024_Init (SKEIN1024_CTX *ctx);
void SKEIN256_Update(SKEIN256_CTX *ctx, const void *in, size_t len);
void SKEIN512_Update(SKEIN512_CTX *ctx, const void *in, size_t len);
void SKEIN1024_Update(SKEIN1024_CTX *ctx, const void *in, size_t len);
void SKEIN256_Final(unsigned char digest[static SKEIN256_DIGEST_LENGTH], SKEIN256_CTX *ctx);
void SKEIN512_Final(unsigned char digest[static SKEIN512_DIGEST_LENGTH], SKEIN512_CTX *ctx);
void SKEIN1024_Final(unsigned char digest[static SKEIN1024_DIGEST_LENGTH], SKEIN1024_CTX *ctx);
#ifndef _KERNEL
char *SKEIN256_End(SKEIN256_CTX *, char *);
char *SKEIN512_End(SKEIN512_CTX *, char *);
char *SKEIN1024_End(SKEIN1024_CTX *, char *);
char *SKEIN256_Data(const void *, unsigned int, char *);
char *SKEIN512_Data(const void *, unsigned int, char *);
char *SKEIN1024_Data(const void *, unsigned int, char *);
char *SKEIN256_File(const char *, char *);
char *SKEIN512_File(const char *, char *);
char *SKEIN1024_File(const char *, char *);
char *SKEIN256_FileChunk(const char *, char *, off_t, off_t);
char *SKEIN512_FileChunk(const char *, char *, off_t, off_t);
char *SKEIN1024_FileChunk(const char *, char *, off_t, off_t);
#endif
#endif /* ifndef _SKEIN_FREEBSD_H_ */

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sys/crypto/skein/skein_iv.h Normal file
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/* $FreeBSD$ */
#ifndef _SKEIN_IV_H_
#define _SKEIN_IV_H_
#include "skein.h" /* get Skein macros and types */
/*
***************** Pre-computed Skein IVs *******************
**
** NOTE: these values are not "magic" constants, but
** are generated using the Threefish block function.
** They are pre-computed here only for speed; i.e., to
** avoid the need for a Threefish call during Init().
**
** The IV for any fixed hash length may be pre-computed.
** Only the most common values are included here.
**
************************************************************
**/
#define MK_64 SKEIN_MK_64
/* blkSize = 256 bits. hashSize = 128 bits */
const u64b_t SKEIN_256_IV_128[] =
{
MK_64(0xE1111906,0x964D7260),
MK_64(0x883DAAA7,0x7C8D811C),
MK_64(0x10080DF4,0x91960F7A),
MK_64(0xCCF7DDE5,0xB45BC1C2)
};
/* blkSize = 256 bits. hashSize = 160 bits */
const u64b_t SKEIN_256_IV_160[] =
{
MK_64(0x14202314,0x72825E98),
MK_64(0x2AC4E9A2,0x5A77E590),
MK_64(0xD47A5856,0x8838D63E),
MK_64(0x2DD2E496,0x8586AB7D)
};
/* blkSize = 256 bits. hashSize = 224 bits */
const u64b_t SKEIN_256_IV_224[] =
{
MK_64(0xC6098A8C,0x9AE5EA0B),
MK_64(0x876D5686,0x08C5191C),
MK_64(0x99CB88D7,0xD7F53884),
MK_64(0x384BDDB1,0xAEDDB5DE)
};
/* blkSize = 256 bits. hashSize = 256 bits */
const u64b_t SKEIN_256_IV_256[] =
{
MK_64(0xFC9DA860,0xD048B449),
MK_64(0x2FCA6647,0x9FA7D833),
MK_64(0xB33BC389,0x6656840F),
MK_64(0x6A54E920,0xFDE8DA69)
};
/* blkSize = 512 bits. hashSize = 128 bits */
const u64b_t SKEIN_512_IV_128[] =
{
MK_64(0xA8BC7BF3,0x6FBF9F52),
MK_64(0x1E9872CE,0xBD1AF0AA),
MK_64(0x309B1790,0xB32190D3),
MK_64(0xBCFBB854,0x3F94805C),
MK_64(0x0DA61BCD,0x6E31B11B),
MK_64(0x1A18EBEA,0xD46A32E3),
MK_64(0xA2CC5B18,0xCE84AA82),
MK_64(0x6982AB28,0x9D46982D)
};
/* blkSize = 512 bits. hashSize = 160 bits */
const u64b_t SKEIN_512_IV_160[] =
{
MK_64(0x28B81A2A,0xE013BD91),
MK_64(0xC2F11668,0xB5BDF78F),
MK_64(0x1760D8F3,0xF6A56F12),
MK_64(0x4FB74758,0x8239904F),
MK_64(0x21EDE07F,0x7EAF5056),
MK_64(0xD908922E,0x63ED70B8),
MK_64(0xB8EC76FF,0xECCB52FA),
MK_64(0x01A47BB8,0xA3F27A6E)
};
/* blkSize = 512 bits. hashSize = 224 bits */
const u64b_t SKEIN_512_IV_224[] =
{
MK_64(0xCCD06162,0x48677224),
MK_64(0xCBA65CF3,0xA92339EF),
MK_64(0x8CCD69D6,0x52FF4B64),
MK_64(0x398AED7B,0x3AB890B4),
MK_64(0x0F59D1B1,0x457D2BD0),
MK_64(0x6776FE65,0x75D4EB3D),
MK_64(0x99FBC70E,0x997413E9),
MK_64(0x9E2CFCCF,0xE1C41EF7)
};
/* blkSize = 512 bits. hashSize = 256 bits */
const u64b_t SKEIN_512_IV_256[] =
{
MK_64(0xCCD044A1,0x2FDB3E13),
MK_64(0xE8359030,0x1A79A9EB),
MK_64(0x55AEA061,0x4F816E6F),
MK_64(0x2A2767A4,0xAE9B94DB),
MK_64(0xEC06025E,0x74DD7683),
MK_64(0xE7A436CD,0xC4746251),
MK_64(0xC36FBAF9,0x393AD185),
MK_64(0x3EEDBA18,0x33EDFC13)
};
/* blkSize = 512 bits. hashSize = 384 bits */
const u64b_t SKEIN_512_IV_384[] =
{
MK_64(0xA3F6C6BF,0x3A75EF5F),
MK_64(0xB0FEF9CC,0xFD84FAA4),
MK_64(0x9D77DD66,0x3D770CFE),
MK_64(0xD798CBF3,0xB468FDDA),
MK_64(0x1BC4A666,0x8A0E4465),
MK_64(0x7ED7D434,0xE5807407),
MK_64(0x548FC1AC,0xD4EC44D6),
MK_64(0x266E1754,0x6AA18FF8)
};
/* blkSize = 512 bits. hashSize = 512 bits */
const u64b_t SKEIN_512_IV_512[] =
{
MK_64(0x4903ADFF,0x749C51CE),
MK_64(0x0D95DE39,0x9746DF03),
MK_64(0x8FD19341,0x27C79BCE),
MK_64(0x9A255629,0xFF352CB1),
MK_64(0x5DB62599,0xDF6CA7B0),
MK_64(0xEABE394C,0xA9D5C3F4),
MK_64(0x991112C7,0x1A75B523),
MK_64(0xAE18A40B,0x660FCC33)
};
/* blkSize = 1024 bits. hashSize = 384 bits */
const u64b_t SKEIN1024_IV_384[] =
{
MK_64(0x5102B6B8,0xC1894A35),
MK_64(0xFEEBC9E3,0xFE8AF11A),
MK_64(0x0C807F06,0xE32BED71),
MK_64(0x60C13A52,0xB41A91F6),
MK_64(0x9716D35D,0xD4917C38),
MK_64(0xE780DF12,0x6FD31D3A),
MK_64(0x797846B6,0xC898303A),
MK_64(0xB172C2A8,0xB3572A3B),
MK_64(0xC9BC8203,0xA6104A6C),
MK_64(0x65909338,0xD75624F4),
MK_64(0x94BCC568,0x4B3F81A0),
MK_64(0x3EBBF51E,0x10ECFD46),
MK_64(0x2DF50F0B,0xEEB08542),
MK_64(0x3B5A6530,0x0DBC6516),
MK_64(0x484B9CD2,0x167BBCE1),
MK_64(0x2D136947,0xD4CBAFEA)
};
/* blkSize = 1024 bits. hashSize = 512 bits */
const u64b_t SKEIN1024_IV_512[] =
{
MK_64(0xCAEC0E5D,0x7C1B1B18),
MK_64(0xA01B0E04,0x5F03E802),
MK_64(0x33840451,0xED912885),
MK_64(0x374AFB04,0xEAEC2E1C),
MK_64(0xDF25A0E2,0x813581F7),
MK_64(0xE4004093,0x8B12F9D2),
MK_64(0xA662D539,0xC2ED39B6),
MK_64(0xFA8B85CF,0x45D8C75A),
MK_64(0x8316ED8E,0x29EDE796),
MK_64(0x053289C0,0x2E9F91B8),
MK_64(0xC3F8EF1D,0x6D518B73),
MK_64(0xBDCEC3C4,0xD5EF332E),
MK_64(0x549A7E52,0x22974487),
MK_64(0x67070872,0x5B749816),
MK_64(0xB9CD28FB,0xF0581BD1),
MK_64(0x0E2940B8,0x15804974)
};
/* blkSize = 1024 bits. hashSize = 1024 bits */
const u64b_t SKEIN1024_IV_1024[] =
{
MK_64(0xD593DA07,0x41E72355),
MK_64(0x15B5E511,0xAC73E00C),
MK_64(0x5180E5AE,0xBAF2C4F0),
MK_64(0x03BD41D3,0xFCBCAFAF),
MK_64(0x1CAEC6FD,0x1983A898),
MK_64(0x6E510B8B,0xCDD0589F),
MK_64(0x77E2BDFD,0xC6394ADA),
MK_64(0xC11E1DB5,0x24DCB0A3),
MK_64(0xD6D14AF9,0xC6329AB5),
MK_64(0x6A9B0BFC,0x6EB67E0D),
MK_64(0x9243C60D,0xCCFF1332),
MK_64(0x1A1F1DDE,0x743F02D4),
MK_64(0x0996753C,0x10ED0BB8),
MK_64(0x6572DD22,0xF2B4969A),
MK_64(0x61FD3062,0xD00A579A),
MK_64(0x1DE0536E,0x8682E539)
};
#endif /* _SKEIN_IV_H_ */

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/* $FreeBSD$ */
#ifndef _SKEIN_PORT_H_
#define _SKEIN_PORT_H_
/*******************************************************************
**
** Platform-specific definitions for Skein hash function.
**
** Source code author: Doug Whiting, 2008.
**
** This algorithm and source code is released to the public domain.
**
** Many thanks to Brian Gladman for his portable header files.
**
** To port Skein to an "unsupported" platform, change the definitions
** in this file appropriately.
**
********************************************************************/
#include <sys/endian.h>
#include <sys/types.h>
typedef unsigned int uint_t; /* native unsigned integer */
typedef u_int8_t u08b_t; /* 8-bit unsigned integer */
typedef u_int32_t uint_32t; /* 32-bit unsigned integer */
typedef u_int64_t u64b_t; /* 64-bit unsigned integer */
#ifndef RotL_64
#define RotL_64(x,N) (((x) << (N)) | ((x) >> (64-(N))))
#endif
__BEGIN_DECLS
/*
* Skein is "natively" little-endian (unlike SHA-xxx), for optimal
* performance on x86 CPUs. The Skein code requires the following
* definitions for dealing with endianness:
*
* SKEIN_NEED_SWAP: 0 for little-endian, 1 for big-endian
* Skein_Put64_LSB_First
* Skein_Get64_LSB_First
* Skein_Swap64
*
* If SKEIN_NEED_SWAP is defined at compile time, it is used here
* along with the portable versions of Put64/Get64/Swap64, which
* are slow in general.
*
* Otherwise, an "auto-detect" of endianness is attempted below.
* If the default handling doesn't work well, the user may insert
* platform-specific code instead (e.g., for big-endian CPUs).
*
*/
#ifndef SKEIN_NEED_SWAP /* compile-time "override" for endianness? */
#if BYTE_ORDER == BIG_ENDIAN
/* here for big-endian CPUs */
#define SKEIN_NEED_SWAP (1)
#ifdef SKEIN_PORT_CODE
void Skein_Put64_LSB_First(u08b_t *dst,const u64b_t *src,size_t bCnt);
void Skein_Get64_LSB_First(u64b_t *dst,const u08b_t *src,size_t wCnt);
#endif /* ifdef SKEIN_PORT_CODE */
#elif BYTE_ORDER == LITTLE_ENDIAN
/* here for x86 and x86-64 CPUs (and other detected little-endian CPUs) */
#define SKEIN_NEED_SWAP (0)
#define Skein_Put64_LSB_First(dst08,src64,bCnt) memcpy(dst08,src64,bCnt)
#define Skein_Get64_LSB_First(dst64,src08,wCnt) memcpy(dst64,src08,8*(wCnt))
#else
#error "Skein needs endianness setting!"
#endif
#endif /* ifndef SKEIN_NEED_SWAP */
/*
******************************************************************
* Provide any definitions still needed.
******************************************************************
*/
#ifndef Skein_Swap64 /* swap for big-endian, nop for little-endian */
#if SKEIN_NEED_SWAP
#define Skein_Swap64(w64) bswap64(w64)
#else
#define Skein_Swap64(w64) (w64)
#endif
#endif /* ifndef Skein_Swap64 */
#ifndef Skein_Put64_LSB_First
void Skein_Put64_LSB_First(u08b_t *dst,const u64b_t *src,size_t bCnt)
#ifdef SKEIN_PORT_CODE /* instantiate the function code here? */
{
size_t n;
for (n = 0; n < bCnt / 8; n++)
le64enc(dst + n * 8, src[n]);
}
#else
; /* output only the function prototype */
#endif
#endif /* ifndef Skein_Put64_LSB_First */
#ifndef Skein_Get64_LSB_First
void Skein_Get64_LSB_First(u64b_t *dst,const u08b_t *src,size_t wCnt)
#ifdef SKEIN_PORT_CODE /* instantiate the function code here? */
{
size_t n;
for (n = 0; n < wCnt; n++)
dst[n] = le64dec(src + n * 8);
}
#else
; /* output only the function prototype */
#endif
#endif /* ifndef Skein_Get64_LSB_First */
/* Start FreeBSD libmd shims */
/* Ensure libmd symbols do not clash with libcrypto */
#ifndef SKEIN256_Init
#define SKEIN256_Init _libmd_SKEIN256_Init
#define SKEIN512_Init _libmd_SKEIN512_Init
#define SKEIN1024_Init _libmd_SKEIN1024_Init
#endif
#ifndef SKEIN256_Update
#define SKEIN256_Update _libmd_SKEIN256_Update
#define SKEIN512_Update _libmd_SKEIN512_Update
#define SKEIN1024_Update _libmd_SKEIN1024_Update
#endif
#ifndef SKEIN256_Final
#define SKEIN256_Final _libmd_SKEIN256_Final
#define SKEIN512_Final _libmd_SKEIN512_Final
#define SKEIN1024_Final _libmd_SKEIN1024_Final
#endif
#ifndef SKEIN256_End
#define SKEIN256_End _libmd_SKEIN256_End
#define SKEIN512_End _libmd_SKEIN512_End
#define SKEIN1024_End _libmd_SKEIN1024_End
#endif
#ifndef SKEIN256_File
#define SKEIN256_File _libmd_SKEIN256_File
#define SKEIN512_File _libmd_SKEIN512_File
#define SKEIN1024_File _libmd_SKEIN1024_File
#endif
#ifndef SKEIN256_FileChunk
#define SKEIN256_FileChunk _libmd_SKEIN256_FileChunk
#define SKEIN512_FileChunk _libmd_SKEIN512_FileChunk
#define SKEIN1024_FileChunk _libmd_SKEIN1024_FileChunk
#endif
#ifndef SKEIN256_Data
#define SKEIN256_Data _libmd_SKEIN256_Data
#define SKEIN512_Data _libmd_SKEIN512_Data
#define SKEIN1024_Data _libmd_SKEIN1024_Data
#endif
__END_DECLS
#endif /* ifndef _SKEIN_PORT_H_ */

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@ -8,6 +8,7 @@
.PATH: ${.CURDIR}/../../crypto/rijndael
.PATH: ${.CURDIR}/../../crypto/sha2
.PATH: ${.CURDIR}/../../crypto/siphash
.PATH: ${.CURDIR}/../../crypto/skein
KMOD = crypto
SRCS = crypto.c cryptodev_if.c
@ -17,6 +18,13 @@ SRCS += skipjack.c bf_enc.c bf_ecb.c bf_skey.c
SRCS += camellia.c camellia-api.c
SRCS += des_ecb.c des_enc.c des_setkey.c
SRCS += sha1.c sha256c.c sha512c.c
SRCS += skein.c skein_block.c
.if exists(${MACHINE_ARCH}/skein_block_asm.s)
.PATH: ${.CURDIR}/../../crypto/skein/${MACHINE_ARCH}
SRCS += skein_block_asm.s
CFLAGS += -DSKEIN_ASM -DSKEIN_USE_ASM=1792 # list of block functions to replace with assembly: 256+512+1024 = 1792
ACFLAGS += -DELF -Wa,--noexecstack
.endif
SRCS += siphash.c
SRCS += gmac.c gfmult.c
SRCS += opt_param.h cryptodev_if.h bus_if.h device_if.h