This appears to work ... maybe. slowly.

src/ecdsa/private.rs

@@ -17,7 +17,6 @@ impl ECCPrivate<P192>
         ECCPrivate{ d }
     }
 
-
     pub fn sign<Hash>(&self, m: &[u8]) -> DSASignature<U192>
       where
         Hash: BlockInput + Clone + Default + Digest + FixedOutput + Input + Reset,
@@ -36,8 +35,11 @@ impl ECCPrivate<P192>
         //
         let h1 = <Hash>::digest(m);
         let size = <P192>::size();
+        println!("h1: {:?}", h1);
         let h0: U192 = bits2int(&h1, size);
+        println!("h0: {:X}", h0);
         let h = h0 % <P192>::n();
+        println!("h:  {:X}", h);
 
         // 2.  A random value modulo q, dubbed k, is generated.  That value
         //     shall not be 0; hence, it lies in the [1, q-1] range.  Most
@@ -45,7 +47,7 @@ impl ECCPrivate<P192>
         //     process used to generate k.  In plain DSA or ECDSA, k should
         //     be selected through a random selection that chooses a value
         //     among the q-1 possible values with uniform probability.
-        for k in KIterator::<Hash,U192>::new(&h1, size, &<P192>::n(), &<P192>::b()) {
+        for k in KIterator::<Hash,U192>::new(&h1, size, &<P192>::n(), &self.d) {
             // 3. A value r (modulo q) is computed from k and the key
             //    parameters:
             //     *  For DSA ...
@@ -53,6 +55,7 @@ impl ECCPrivate<P192>
             //
             //    If r turns out to be zero, a new k should be selected and r
             //    computed again (this is an utterly improbable occurrence).
+            println!("k: {:X}", k);
             let g = Point::<P192>::default();
             let ki = I192::new(false, k.clone());
             let kg = g.scale(&ki);
@@ -74,11 +77,69 @@ impl ECCPrivate<P192>
             if let Some(kinv) = k.modinv(&n) {
                 let xr = &self.d * &r;
                 let hxr = U384::from(&h) + xr;
-                let base = U192::from(hxr * U448::from(kinv));
-                let s = base % n;
+                let base = hxr * U448::from(kinv);
+                let s = U192::from(base % U896::from(n));
                 return DSASignature{ r, s };
             }
         }
         panic!("The world is broken; couldn't find a k in sign().");
     }
+}
+
+#[cfg(test)]
+mod tests {
+    use sha2::{Sha224,Sha256,Sha384,Sha512};
+    use super::*;
+    use testing::*;
+
+    #[test]
+    fn p192_sign() {
+        let fname = build_test_path("ecc/sign","P192");
+        run_test(fname.to_string(), 9, |case| {
+            let (negd, dbytes) = case.get("d").unwrap();
+            let (negk, kbytes) = case.get("k").unwrap();
+            let (negx, xbytes) = case.get("x").unwrap();
+            let (negy, ybytes) = case.get("y").unwrap();
+            let (negm, mbytes) = case.get("m").unwrap();
+            let (negh, hbytes) = case.get("h").unwrap();
+            let (negr, rbytes) = case.get("r").unwrap();
+            let (negs, sbytes) = case.get("s").unwrap();
+
+            assert!(!negd && !negk && !negx && !negy &&
+                    !negm && !negh && !negr && !negs);
+            let d = U192::from_bytes(dbytes);
+            let _ = U192::from_bytes(xbytes);
+            let _ = U192::from_bytes(ybytes);
+            let h = U192::from_bytes(hbytes);
+            let r = U192::from_bytes(rbytes);
+            let s = U192::from_bytes(sbytes);
+
+            {
+                let (negn, nbytes) = case.get("n").unwrap();
+                println!("nbytes<{}>: {:?}", usize::from(h.clone()), nbytes);
+                println!("hash<224>: {:?}", Sha224::digest(mbytes));
+                println!("hash<256>: {:?}", Sha256::digest(mbytes));
+                println!("hash<384>: {:?}", Sha384::digest(mbytes));
+                println!("hash<512>: {:?}", Sha512::digest(mbytes));
+                println!("kbytes:    {:?}", kbytes);
+                let k = U192::from_bytes(kbytes);
+                println!("k:         {:X}", k);
+                println!("target r:  {:X}", r);
+                println!("target s:  {:X}", s);
+            }
+
+            let private = ECCPrivate::new(d);
+            let sig = match usize::from(h) {
+                        224 => private.sign::<Sha224>(mbytes),
+                        256 => private.sign::<Sha256>(mbytes),
+                        384 => private.sign::<Sha384>(mbytes),
+                        512 => private.sign::<Sha512>(mbytes),
+                        x   => panic!("Unknown hash algorithm {}", x)
+            };
+            println!("my r:  {:X}", sig.r);
+            println!("my s:  {:X}", sig.s);
+            assert_eq!(r, sig.r, "r signature check");
+            assert_eq!(s, sig.s, "s signature check");
+        });
+    }
 }

test-generator/ECDSATesting.hs

@@ -8,13 +8,14 @@ import Crypto.Number.Generate(generateBetween)
 import Crypto.PubKey.ECC.ECDSA(PrivateKey(..),PublicKey(..),Signature(..),signWith)
 import Crypto.PubKey.ECC.Generate(generate)
 import Crypto.PubKey.ECC.Prim(scalarGenerate,pointAdd,pointNegate,pointDouble,pointBaseMul,pointMul)
-import Crypto.PubKey.ECC.Types(Curve,CurveName(..),Point(..),getCurveByName)
+import Crypto.PubKey.ECC.Types(Curve,CurveName(..),Point(..),common_curve,curveSizeBits,ecc_n,getCurveByName)
 import Crypto.Random(DRG(..),getRandomBytes,withDRG)
 import qualified Data.ByteString as S
 import qualified Data.Map.Strict as Map
 import Math(showX,showBin)
+import RFC6979(generateKStream)
 import Task(Task(..))
-import Utils(HashAlg(..),generateHash,showHash)
+import Utils(HashAlg(..),generateHash,runHash,showHash)
 
 curves :: [(String, Curve)]
 curves = [("P192", getCurveByName SEC_p192r1),
@@ -124,18 +125,27 @@ signTest name curve = Task {
         (msg, drg2)         = withDRG drg1 $ do x <- generateBetween 0 256
                                                 getRandomBytes (fromIntegral x)
         (hash, drg3)        = withDRG drg2 generateHash
-        k                   = 5
-    in case signWith' k priv hash msg of
-         Nothing -> go (memory0, drg3)
-         Just sig ->
-            let PublicKey _ (Point x y) = pub
-                PrivateKey _ d = priv
-                res = Map.fromList [("d", showX d),
-                                    ("x", showX x), ("y", showX y),
-                                    ("m", showBin msg), ("h", showHash hash),
-                                    ("r", showX (sign_r sig)),
-                                    ("s", showX (sign_s sig))]
-            in (res, d, (memory0, drg3))
+        n                   = ecc_n (common_curve curve)
+        PrivateKey _ d      = priv
+        kStream             = generateKStream hash msg d n (curveSizeBits curve)
+        findGoodK stream    =
+          case stream of
+            [] ->
+              go (memory0, drg3)
+            (k : restks) ->
+              case signWith' k priv hash msg of
+                Nothing ->
+                  findGoodK restks
+                Just sig ->
+                  let PublicKey _ (Point x y) = pub
+                      res = Map.fromList [("d", showX d), ("k", showX k),
+                                          ("x", showX x), ("y", showX y),
+                                          ("m", showBin msg), ("h", showHash hash),
+                                          ("n", showBin (runHash hash msg)),
+                                          ("r", showX (sign_r sig)),
+                                          ("s", showX (sign_s sig))]
+                  in (res, d, (memory0, drg3))
+    in findGoodK kStream
 
 signWith' :: Integer -> PrivateKey -> HashAlg -> S.ByteString -> Maybe Signature
 signWith' k priv Sha224 msg = signWith k priv SHA224 msg