I can use SHA256 in Scheme using external libraries (Java, C or system dependent) or using a specific Scheme implementation (like Chicken e.g.), but I wonder if there is a "pure" scheme implementation.

26 years ago, I wrote a pureScheme implementation of MD5. Since SHA256 is also a MerkleDamgard hashing function like MD5, much of the same techniques will apply. I don't want to post 6yearold code, but I can probably write one from scratch relatively quickly. – Chris JesterYoung Jun 7 '14 at 3:15
I wrote an implementation today. Alas, R5RS has neither bytevectors nor binary I/O, so this uses the R7RS APIs for bytevectors and binary I/O. It should be easy to bridge those APIs to your Scheme implementation's native APIs (for example, I actually tested my implementation on Racket and Guile).
A few notes:
 This code assumes casesensitivity. This is the default for R7RS, but not R5RS, so if you're using an R5RS implementation, beware.
 It requires SRFIs 1, 26, 43, and 60.
 I emphasise elegance and clarity over speed. In fact, the code is quite slow.
 Contrary to what my profile says, I'm only licensing this code under the Apache Licence 2.0 (in addition to the standard Stack Overflow licence of CC BYSA 3.0), and not under CC0 or anything resembling public domain.
Anyway, without further ado, here it is (also available as a Gist):
;;; Auxiliary definitions to avoid having to use giant tables of constants.
(define primes80 '(2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73
79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157
163 167 173 179 181 191 193 197 199 211 223 227 229 233 239
241 251 257 263 269 271 277 281 283 293 307 311 313 317 331
337 347 349 353 359 367 373 379 383 389 397 401 409))
(define (sqrt x)
(fold (lambda (_ y) (/ (+ (/ x y) y) 2)) 4 (iota 7)))
(define (cbrt x)
(fold (lambda (_ y) (/ (+ (/ x y y) y y) 3)) 4 (iota 8)))
(define (frac x scale base)
(bitwiseand (floor (* x (arithmeticshift 1 scale)))
( (arithmeticshift 1 base) 1)))
;;; The actual initialisation and constant values.
(define sha1init '(#x67452301 #xefcdab89 #x98badcfe #x10325476 #xc3d2e1f0))
(define sha2init (map (lambda (x) (frac (sqrt x) 64 64)) (take primes80 16)))
(definevalues (sha512init sha384init) (splitat sha2init 8))
(define sha256init (map (cut arithmeticshift <> 32) sha512init))
(define sha224init (map (cut frac <> 0 32) sha384init))
(define sha1const (map (lambda (x) (frac (sqrt x) 30 32)) '(2 3 5 10)))
(define sha512const (map (lambda (x) (frac (cbrt x) 64 64)) primes80))
(define sha256const (map (cut arithmeticshift <> 32) (take sha512const 64)))
;;; Utility functions used by the compression and driver functions.
(define (u32+ . xs) (bitwiseand (apply + xs) #xffffffff))
(define (u64+ . xs) (bitwiseand (apply + xs) #xffffffffffffffff))
(define (bitwisemajority x y z)
(bitwisexor (bitwiseand x y) (bitwiseand x z) (bitwiseand y z)))
(define (bytevectorberef bv base n)
(let loop ((res 0) (i 0))
(if (< i n)
(loop (+ (arithmeticshift res 8) (bytevectoru8ref bv (+ base i)))
(+ i 1))
res)))
(define (bytevectoru64ref bv i)
(bytevectorberef bv (arithmeticshift i 3) 8))
(define (bytevectoru32ref bv i)
(bytevectorberef bv (arithmeticshift i 2) 4))
(define (bytevectorbeset! bv base n val)
(let loop ((i n) (val val))
(when (positive? i)
(bytevectoru8set! bv (+ base i 1) (bitwiseand val 255))
(loop ( i 1) (arithmeticshift val 8)))))
(define (mdpad! bv offset count countersize)
(define blocksize (bytevectorlength bv))
(unless (negative? offset)
(bytevectoru8set! bv offset #x80))
(let loop ((i (+ offset 1)))
(when (< i blocksize)
(bytevectoru8set! bv i 0)
(loop (+ i 1))))
(when count
(bytevectorbeset! bv ( blocksize countersize) countersize
(arithmeticshift count 3))))
(define (hashstate>bytevector hs trunc wordsize)
(define result (makebytevector (* trunc wordsize)))
(foreach (lambda (h i)
(bytevectorbeset! result i wordsize h))
hs (iota trunc 0 wordsize))
result)
;;; The compression functions.
(define (sha2compress K Σ0 Σ1 σ0 σ1 mod+ getter hs)
(define W (vector>list (apply vectorunfold
(lambda (_ a b c d e f g h i j k l m n o p)
(values a b c d e f g h i j k l m n o p
(mod+ a (σ0 b) j (σ1 o))))
(length K)
(listtabulate 16 getter))))
(define (loop k w a b c d e f g h)
(if (null? k)
(map mod+ hs (list a b c d e f g h))
(let ((T1 (mod+ h (Σ1 e) (bitwiseif e f g) (car k) (car w)))
(T2 (mod+ (Σ0 a) (bitwisemajority a b c))))
(loop (cdr k) (cdr w) (mod+ T1 T2) a b c (mod+ d T1) e f g))))
(apply loop K W hs))
(define (sha512compress bv hs)
(define (rotr x y) (rotatebitfield x ( y) 0 64))
(define (shr x y) (arithmeticshift x ( y)))
(sha2compress sha512const
(lambda (x) (bitwisexor (rotr x 28) (rotr x 34) (rotr x 39)))
(lambda (x) (bitwisexor (rotr x 14) (rotr x 18) (rotr x 41)))
(lambda (x) (bitwisexor (rotr x 1) (rotr x 8) (shr x 7)))
(lambda (x) (bitwisexor (rotr x 19) (rotr x 61) (shr x 6)))
u64+ (cut bytevectoru64ref bv <>) hs))
(define (sha256compress bv hs)
(define (rotr x y) (rotatebitfield x ( y) 0 32))
(define (shr x y) (arithmeticshift x ( y)))
(sha2compress sha256const
(lambda (x) (bitwisexor (rotr x 2) (rotr x 13) (rotr x 22)))
(lambda (x) (bitwisexor (rotr x 6) (rotr x 11) (rotr x 25)))
(lambda (x) (bitwisexor (rotr x 7) (rotr x 18) (shr x 3)))
(lambda (x) (bitwisexor (rotr x 17) (rotr x 19) (shr x 10)))
u32+ (cut bytevectoru32ref bv <>) hs))
(define (sha1compress bv hs)
(define (getter x) (bytevectoru32ref bv x))
(define (rotl x y) (rotatebitfield x y 0 32))
(define W (vector>list (apply vectorunfold
(lambda (_ a b c d e f g h i j k l m n o p)
(values a b c d e f g h i j k l m n o p
(rotl (bitwisexor a c i n) 1)))
80
(listtabulate 16 getter))))
(define (outer f k w a b c d e)
(if (null? k)
(map u32+ hs (list a b c d e))
(let inner ((i 0) (w w) (a a) (b b) (c c) (d d) (e e))
(if (< i 20)
(let ((T (u32+ (rotl a 5) ((car f) b c d) e (car k) (car w))))
(inner (+ i 1) (cdr w) T a (rotl b 30) c d))
(outer (cdr f) (cdr k) w a b c d e)))))
(apply outer (list bitwiseif bitwisexor bitwisemajority bitwisexor)
sha1const W hs))
;;; The MerkleDamgård "driver" function.
(define (mdloop init compress blocksize trunc wordsize countersize in)
(define leftover ( blocksize countersize))
(define bv (makebytevector blocksize))
(define pad! (cut mdpad! bv <> <> countersize))
(define hs>bv (cut hashstate>bytevector <> trunc wordsize))
(let loop ((count 0) (hs init))
(define readsize (readbytevector! bv in))
(cond ((eofobject? readsize)
(pad! 0 count)
(hs>bv (compress bv hs)))
((= readsize blocksize)
(loop (+ count readsize) (compress bv hs)))
((< readsize leftover)
(pad! readsize (+ count readsize))
(hs>bv (compress bv hs)))
(else
(pad! readsize #f)
(let ((pen (compress bv hs)))
(pad! 1 (+ count readsize))
(hs>bv (compress bv pen)))))))
;;; SHA512/t stuff.
(define sha512/tinit (map (cut bitwisexor <> #xa5a5a5a5a5a5a5a5) sha512init))
(define (makesha512/tinit t)
(define key (string>utf8 (stringappend "SHA512/" (number>string t))))
(define size (bytevectorlength key))
(define bv (makebytevector 128))
(bytevectorcopy! bv 0 key)
(mdpad! bv size size 16)
(sha512compress bv sha512/tinit))
(define (makesha512/t t)
(define init (makesha512/tinit t))
(define words (arithmeticshift t 6))
(if (zero? (bitwiseand t 63))
(cut mdloop init sha512compress 128 words 8 16 <>)
(lambda (in)
(bytevectorcopy
(mdloop init sha512compress 128 (ceiling words) 8 16 in)
0 (arithmeticshift t 3)))))
;;; Public entry points.
(define sha1 (cut mdloop sha1init sha1compress 64 5 4 8 <>))
(define sha224 (cut mdloop sha224init sha256compress 64 7 4 8 <>))
(define sha256 (cut mdloop sha256init sha256compress 64 8 4 8 <>))
(define sha384 (cut mdloop sha384init sha512compress 128 6 8 16 <>))
(define sha512 (cut mdloop sha512init sha512compress 128 8 8 16 <>))
(define sha512/256 (makesha512/t 256))
(define sha512/224 (makesha512/t 224))
I implemented all the algorithms in FIPS 1804, but you can strip out whatever you don't need.
As mentioned before, I tested this on Racket; the definitions I added to bridge to Racket's APIs are as follows:
#lang racket
(require (onlyin srfi/1 iota)
(onlyin srfi/26 cut)
(onlyin srfi/43 vectorunfold)
(onlyin srfi/60 bitwiseif rotatebitfield)
(renamein racket/base [buildlist listtabulate]
[bytescopy! bytevectorcopy!]
[byteslength bytevectorlength]
[bytesref bytevectoru8ref]
[bytesset! bytevectoru8set!]
[foldl fold]
[makebytes makebytevector]
[readbytes! readbytevector!]
[string>bytes/utf8 string>utf8]
[subbytes bytevectorcopy]))
And here are the definitions for Guile (requires version 2.0.11 or above):
(usemodules (srfi srfi1) (srfi srfi26) (srfi srfi43) (srfi srfi60)
(rnrs bytevectors) (ice9 binaryports))
(define* (bytevectorcopy bv #:optional (start 0) (end (bytevectorlength bv)))
(define copy (makebytevector ( end start)))
(bytevectorcopy! copy 0 bv start end)
copy)
(define* (bytevectorcopy! to at from #:optional (start 0)
(end (bytevectorlength from)))
((@ (rnrs bytevectors) bytevectorcopy!) from start to at ( end start)))
(define* (readbytevector! bv #:optional (port (currentinputport)) (start 0)
(end (bytevectorlength bv)))
(getbytevectorn! port bv start ( end start)))
It should be easy to make something similar for your chosen implementation.
I also have a function that prints out the output as a hex string, for ready comparison with various commandline SHA1 and SHA2 utilities (e.g., sha1sum
, sha256sum
, sha512sum
, etc.):
(define (hex bv)
(define out (openoutputstring))
(do ((i 0 (+ i 1)))
((>= i (bytevectorlength bv)) (getoutputstring out))
(letvalues (((q r) (truncate/ (bytevectoru8ref bv i) 16)))
(display (number>string q 16) out)
(display (number>string r 16) out))))


7@dfeuer Not for the purposes of deriving the SHA2 initialisation values. Most implementations use IEEE754 doubles, which have only 53 bits of significand, not nearly enough for the 64bit values used in the constants. I basically convert the doubles to rationals, then use NewtonRaphson to get the extra precision necessary. – Chris JesterYoung Jun 19 '14 at 6:10

1@dfeuer And now, on Mark Weaver's suggestion, I don't even use doubles at all, but instead use pure NewtonRaphson. It does make the startup slower, but that's a onetime cost. – Chris JesterYoung Aug 12 '14 at 15:26

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