ff_derive: Generate modulus representation with correct endianness

Now that PrimeField::ReprEndianness exists, users can obtain a
known-endianness representation from the output of PrimeField::char
(which is a PrimeField::Repr, and should return a representation with
the same endianness as PrimeField::into_repr).

ff/ff_derive/src/lib.rs

@@ -38,6 +38,23 @@ impl ReprEndianness {
         }
     }
 
+    fn modulus_repr(&self, modulus: &BigUint, bytes: usize) -> Vec<u8> {
+        match self {
+            ReprEndianness::Big => {
+                let buf = modulus.to_bytes_be();
+                iter::repeat(0)
+                    .take(bytes - buf.len())
+                    .chain(buf.into_iter())
+                    .collect()
+            }
+            ReprEndianness::Little => {
+                let mut buf = modulus.to_bytes_le();
+                buf.extend(iter::repeat(0).take(bytes - buf.len()));
+                buf
+            }
+        }
+    }
+
     fn from_repr(&self, name: &syn::Ident, limbs: usize) -> proc_macro2::TokenStream {
         let read_repr = match self {
             ReprEndianness::Big => quote! {
@@ -159,8 +176,14 @@ pub fn prime_field(input: proc_macro::TokenStream) -> proc_macro::TokenStream {
 
     let mut gen = proc_macro2::TokenStream::new();
 
-    let (constants_impl, sqrt_impl) =
-        prime_field_constants_and_sqrt(&ast.ident, &repr_ident, &modulus, limbs, generator);
+    let (constants_impl, sqrt_impl) = prime_field_constants_and_sqrt(
+        &ast.ident,
+        &repr_ident,
+        &modulus,
+        &endianness,
+        limbs,
+        generator,
+    );
 
     gen.extend(constants_impl);
     gen.extend(prime_field_repr_impl(&repr_ident, &endianness, limbs * 8));
@@ -466,6 +489,7 @@ fn prime_field_constants_and_sqrt(
     name: &syn::Ident,
     repr: &syn::Ident,
     modulus: &BigUint,
+    endianness: &ReprEndianness,
     limbs: usize,
     generator: BigUint,
 ) -> (proc_macro2::TokenStream, proc_macro2::TokenStream) {
@@ -576,11 +600,7 @@ fn prime_field_constants_and_sqrt(
     let r2 = biguint_to_u64_vec((&r * &r) % modulus, limbs);
 
     let r = biguint_to_u64_vec(r, limbs);
-    let modulus_repr = {
-        let mut buf = modulus.to_bytes_le();
-        buf.extend(iter::repeat(0).take((limbs * 8) - buf.len()));
-        buf
-    };
+    let modulus_repr = endianness.modulus_repr(modulus, limbs * 8);
     let modulus = biguint_to_real_u64_vec(modulus.clone(), limbs);
 
     // Compute -m^-1 mod 2**64 by exponentiating by totient(2**64) - 1

pairing/src/bls12_381/fq.rs

@@ -1644,7 +1644,8 @@ fn test_fq_pow() {
 
     use byteorder::ByteOrder;
     let mut char_limbs = [0; 6];
-    byteorder::LittleEndian::read_u64_into(Fq::char().as_ref(), &mut char_limbs);
+    byteorder::BigEndian::read_u64_into(Fq::char().as_ref(), &mut char_limbs);
+    char_limbs.reverse();
 
     for _ in 0..1000 {
         // Exponentiating by the modulus should have no effect in a prime field.

pairing/src/bls12_381/tests/mod.rs

@@ -147,13 +147,11 @@ fn test_g1_uncompressed_invalid_vectors() {
         }
     }
 
-    // PrimeField::char() returns the modulus in its little-endian byte representation,
-    // but Fq field elements use big-endian encoding, so flip the endianness.
-    let m: Vec<_> = Fq::char().as_ref().iter().cloned().rev().collect();
+    let m = Fq::char();
 
     {
         let mut o = o;
-        o.as_mut()[..48].copy_from_slice(&m[..]);
+        o.as_mut()[..48].copy_from_slice(m.as_ref());
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
             assert_eq!(coordinate, "x coordinate");
@@ -164,7 +162,7 @@ fn test_g1_uncompressed_invalid_vectors() {
 
     {
         let mut o = o;
-        o.as_mut()[48..].copy_from_slice(&m[..]);
+        o.as_mut()[48..].copy_from_slice(m.as_ref());
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
             assert_eq!(coordinate, "y coordinate");
@@ -265,13 +263,11 @@ fn test_g2_uncompressed_invalid_vectors() {
         }
     }
 
-    // PrimeField::char() returns the modulus in its little-endian byte representation,
-    // but Fq field elements use big-endian encoding, so flip the endianness.
-    let m: Vec<_> = Fq::char().as_ref().iter().cloned().rev().collect();
+    let m = Fq::char();
 
     {
         let mut o = o;
-        o.as_mut()[..48].copy_from_slice(&m[..]);
+        o.as_mut()[..48].copy_from_slice(m.as_ref());
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
             assert_eq!(coordinate, "x coordinate (c1)");
@@ -282,7 +278,7 @@ fn test_g2_uncompressed_invalid_vectors() {
 
     {
         let mut o = o;
-        o.as_mut()[48..96].copy_from_slice(&m[..]);
+        o.as_mut()[48..96].copy_from_slice(m.as_ref());
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
             assert_eq!(coordinate, "x coordinate (c0)");
@@ -293,7 +289,7 @@ fn test_g2_uncompressed_invalid_vectors() {
 
     {
         let mut o = o;
-        o.as_mut()[96..144].copy_from_slice(&m[..]);
+        o.as_mut()[96..144].copy_from_slice(m.as_ref());
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
             assert_eq!(coordinate, "y coordinate (c1)");
@@ -304,7 +300,7 @@ fn test_g2_uncompressed_invalid_vectors() {
 
     {
         let mut o = o;
-        o.as_mut()[144..].copy_from_slice(&m[..]);
+        o.as_mut()[144..].copy_from_slice(m.as_ref());
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
             assert_eq!(coordinate, "y coordinate (c0)");
@@ -411,13 +407,11 @@ fn test_g1_compressed_invalid_vectors() {
         }
     }
 
-    // PrimeField::char() returns the modulus in its little-endian byte representation,
-    // but Fq field elements use big-endian encoding, so flip the endianness.
-    let m: Vec<_> = Fq::char().as_ref().iter().cloned().rev().collect();
+    let m = Fq::char();
 
     {
         let mut o = o;
-        o.as_mut()[..48].copy_from_slice(&m[..]);
+        o.as_mut()[..48].copy_from_slice(m.as_ref());
         o.as_mut()[0] |= 0b1000_0000;
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
@@ -527,13 +521,11 @@ fn test_g2_compressed_invalid_vectors() {
         }
     }
 
-    // PrimeField::char() returns the modulus in its little-endian byte representation,
-    // but Fq field elements use big-endian encoding, so flip the endianness.
-    let m: Vec<_> = Fq::char().as_ref().iter().cloned().rev().collect();
+    let m = Fq::char();
 
     {
         let mut o = o;
-        o.as_mut()[..48].copy_from_slice(&m[..]);
+        o.as_mut()[..48].copy_from_slice(m.as_ref());
         o.as_mut()[0] |= 0b1000_0000;
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {
@@ -545,7 +537,7 @@ fn test_g2_compressed_invalid_vectors() {
 
     {
         let mut o = o;
-        o.as_mut()[48..96].copy_from_slice(&m[..]);
+        o.as_mut()[48..96].copy_from_slice(m.as_ref());
         o.as_mut()[0] |= 0b1000_0000;
 
         if let Err(GroupDecodingError::CoordinateDecodingError(coordinate)) = o.into_affine() {