return remainder from sqrt() to see what it looks like

[ieee754fpu.git] / src / add / fsqrt.py

diff --git a/src/add/fsqrt.py b/src/add/fsqrt.py
index da3819c17a6d6877c885793177dc9ae0a6da7f60..c88aea3991f119b29a9415396292ddf64d626773 100644 (file)
--- a/src/add/fsqrt.py
+++ b/src/add/fsqrt.py
@@ -25,28 +25,28 @@ def sqrt(num):
     Q = 0
     R = 0
     r = 0 # remainder
-    for i in range(15, -1, -1): # negative ranges are weird...
+    for i in range(64, -1, -1): # negative ranges are weird...
 
         if (R>=0):
-        
+
             R = (R<<2)|((D>>(i+i))&3)
             R = R-((Q<<2)|1) #/*-Q01*/
-         
+
         else:
 
             R = (R<<2)|((D>>(i+i))&3)
             R = R+((Q<<2)|3) #/*+Q11*/
-        
+
         if (R>=0):
             Q = (Q<<1)|1 #/*new Q:*/
         else:
             Q = (Q<<1)|0 #/*new Q:*/
-    
+
 
     if (R<0):
         R = R+((Q<<1)|1)
         r = R
-    return Q
+    return Q, r
 
 
 # grabbed these from unit_test_single (convenience, this is just experimenting)
@@ -80,10 +80,40 @@ def decode_fp32(x):
 def main(mantissa, exponent):
     if exponent & 1 != 0:
         # shift mantissa up, subtract 1 from exp to compensate
-        return sqrt(mantissa << 1), (exponent - 1) >> 1
-    # mantissa as-is, no compensating needed on exp
-    return sqrt(mantissa), (exponent >> 1)
+        mantissa <<= 1
+        exponent -= 1
+    m, r = sqrt(mantissa)
+    return m, r, exponent >> 1
+
+
+def fsqrt_test(x):
+
+    xbits = x.bits
+    print ("x", x, type(x))
+    sq_test = x.sqrt()
+    print ("sqrt", sq_test)
 
+    print (xbits, type(xbits))
+    s, e, m = decode_fp32(xbits)
+    print("x decode", s, e, m, hex(m))
+
+    m |= 1<<23 # set top bit (the missing "1" from mantissa)
+    m <<= 27
+
+    sm, sr, se = main(m, e)
+    lowbits = sm & 0x3
+    sm >>= 2
+    sm = get_mantissa(sm)
+    #sm += 2
+    print("our  sqrt", s, se, sm, hex(sm), bin(sm), "lowbits", lowbits,
+                                                    "rem", hex(sr))
+    if lowbits >= 2:
+        print ("probably needs rounding (+1 on mantissa)")
+
+    sq_xbits = sq_test.bits
+    s, e, m = decode_fp32(sq_xbits)
+    print ("sf32 sqrt", s, e, m, hex(m), bin(m))
+    print ()
 
 if __name__ == '__main__':
 
@@ -91,21 +121,31 @@ if __name__ == '__main__':
     for Q in range(1, int(1e4)):
         print(Q, sqrt(Q), sqrtsimple(Q), int(Q**0.5))
         assert int(Q**0.5) == sqrtsimple(Q), "Q sqrtsimpl fail %d" % Q
-        assert int(Q**0.5) == sqrt(Q), "Q sqrt fail %d" % Q
+        assert int(Q**0.5) == sqrt(Q)[0], "Q sqrt fail %d" % Q
 
     # quick mantissa/exponent demo
     for e in range(26):
         for m in range(26):
-            ms, es = main(m, e)
-            print("m:%d e:%d sqrt: m:%d e:%d" % (m, e, ms, es))
-
-
-
-x = Float32(1234.123456789)
-xbits = x.bits
-    
+            ms, mr, es = main(m, e)
+            print("m:%d e:%d sqrt: m:%d-%d e:%d" % (m, e, ms, mr, es))
+
+    x = Float32(1234.123456789)
+    fsqrt_test(x)
+    x = Float32(32.1)
+    fsqrt_test(x)
+    x = Float32(16.0)
+    fsqrt_test(x)
+    x = Float32(8.0)
+    fsqrt_test(x)
+    x = Float32(8.5)
+    fsqrt_test(x)
+    x = Float32(3.14159265358979323)
+    fsqrt_test(x)
+    x = Float32(12.99392923123123)
+    fsqrt_test(x)
+    x = Float32(0.123456)
+    fsqrt_test(x)
 
-print(decode_fp32(x))
 """
 
 Notes: