Cleaned up a bit from poly_utils

mimc_stark/poly_utils.py

@@ -52,6 +52,41 @@ class PrimeField():
             power_of_x = (power_of_x * x) % self.modulus
         return y % self.modulus
         
+    # Arithmetic for polynomials
+    def add_polys(self, a, b):
+        return [((a[i] if i < len(a) else 0) + (b[i] if i < len(b) else 0))
+                % self.modulus for i in range(max(len(a), len(b)))]
+
+    def sub_polys(self, a, b):
+        return [((a[i] if i < len(a) else 0) - (b[i] if i < len(b) else 0))
+                % self.modulus for i in range(max(len(a), len(b)))]
+    
+    def mul_by_const(self, a, c):
+        return [(x*c) % self.modulus for x in a]
+    
+    def mul_polys(self, a, b):
+        o = [0] * (len(a) + len(b) - 1)
+        for i, aval in enumerate(a):
+            for j, bval in enumerate(b):
+                o[i+j] += a[i] * b[j]
+        return [x % self.modulus for x in o]
+    
+    def div_polys(self, a, b):
+        assert len(a) >= len(b)
+        a = [x for x in a]
+        o = []
+        apos = len(a) - 1
+        bpos = len(b) - 1
+        diff = apos - bpos
+        while diff >= 0:
+            quot = self.div(a[apos], b[bpos])
+            o.insert(0, quot)
+            for i in range(bpos, -1, -1):
+                a[diff+i] -= b[i] * quot
+            apos -= 1
+            diff -= 1
+        return [x % self.modulus for x in o]
+
     # Build a polynomial that returns 0 at all specified xs
     def zpoly(self, xs):
         root = [1]
@@ -124,63 +159,3 @@ class PrimeField():
         inv_y0 = ys[0] * invall * e1
         inv_y1 = ys[1] * invall * e0
         return [(eq0[i] * inv_y0 + eq1[i] * inv_y1) % m for i in range(2)]
-        
-    # Arithmetic for polynomials
-    def add_polys(self, a, b):
-        return [((a[i] if i < len(a) else 0) + (b[i] if i < len(b) else 0))
-                % self.modulus for i in range(max(len(a), len(b)))]
-
-    def sub_polys(self, a, b):
-        return [((a[i] if i < len(a) else 0) - (b[i] if i < len(b) else 0))
-                % self.modulus for i in range(max(len(a), len(b)))]
-    
-    def mul_by_const(self, a, c):
-        return [(x*c) % self.modulus for x in a]
-    
-    def mul_polys(self, a, b):
-        o = [0] * (len(a) + len(b) - 1)
-        for i, aval in enumerate(a):
-            for j, bval in enumerate(b):
-                o[i+j] += a[i] * b[j]
-        return [x % self.modulus for x in o]
-    
-    def div_polys(self, a, b):
-        assert len(a) >= len(b)
-        a = [x for x in a]
-        o = []
-        apos = len(a) - 1
-        bpos = len(b) - 1
-        diff = apos - bpos
-        while diff >= 0:
-            quot = self.div(a[apos], b[bpos])
-            o.insert(0, quot)
-            for i in range(bpos, -1, -1):
-                a[diff+i] -= b[i] * quot
-            apos -= 1
-            diff -= 1
-        return [x % self.modulus for x in o]
-
-    # Divides a polynomial by x^n-1
-    def divide_by_xnm1(self, poly, n):
-        if len(poly) <= n:
-            return []
-        return self.add_polys(poly[n:], self.divide_by_xnm1(poly[n:], n))
-    
-    # Returns P(x) = A(B(x))
-    def compose_polys(self, a, b):
-        o = []
-        p = [1]
-        for c in a:
-            o = self.add_polys(o, self.mul_by_const(p, c))
-            p = self.mul_polys(p, b)
-        return o
-
-    # Convert a polynomial P(x) into a polynomial Q(x) = P(fac * x)
-    # Equivalent to compose_polys(poly, [0, fac])
-    def multiply_base(self, poly, fac):
-        o = []
-        r = 1
-        for p in poly:
-            o.append(p * r % self.modulus)
-            r = r * fac % self.modulus
-        return o