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#include <testBitPatterns.h>
#include <half.h>
#include <float.h>
#include <iostream>
#include <string.h>
#include <assert.h>
using namespace std;
namespace {
void
testBits (float f, const char bh[19], const char bg[35])
{
half h (f);
float g (h);
cout.width (15);
cout.precision (8);
cout << f << " ";
printBits (cout, f);
cout << " ";
printBits (cout, h);
cout << '\n';
cout.width (15);
cout << g << " ";
printBits (cout, g);
cout << "\n\n";
if (bh || bg)
{
char ch[19], cg[35];
printBits (ch, h);
printBits (cg, g);
if (strcmp (ch, bh))
{
cout << "error: expected " << bh << ", got " << ch << endl;
assert (false);
}
if (strcmp (cg, bg))
{
cout << "error: expected " << bg << ", got " << cg << endl;
assert (false);
}
}
}
float
floatPosInfinity ()
{
half::uif x;
x.i = 0x7f800000;
return x.f;
}
float
floatNegInfinity ()
{
half::uif x;
x.i = 0xff800000;
return x.f;
}
float
floatPosQNan1 ()
{
half::uif x;
x.i = 0x7fffffff;
return x.f;
}
float
floatNegQNan1 ()
{
half::uif x;
x.i = 0xffffffff;
return x.f;
}
float
floatPosQNan2 ()
{
half::uif x;
x.i = 0x7fd55555;
return x.f;
}
float
floatNegQNan2 ()
{
half::uif x;
x.i = 0xffd55555;
return x.f;
}
} // namespace
void
testBitPatterns()
{
cout << "specific bit patterns\n\n";
//
// Numbers close to 1.0
//
testBits (1.0,
"0 01111 0000000000",
"0 01111111 00000000000000000000000");
testBits (1.0 + HALF_EPSILON,
"0 01111 0000000001",
"0 01111111 00000000010000000000000");
testBits (1.0 + HALF_EPSILON * 0.5,
"0 01111 0000000001",
"0 01111111 00000000010000000000000");
testBits (1.0 + HALF_EPSILON * 0.4999,
"0 01111 0000000000",
"0 01111111 00000000000000000000000");
testBits (1.0 + HALF_EPSILON * 0.5001,
"0 01111 0000000001",
"0 01111111 00000000010000000000000");
testBits (1.0 - HALF_EPSILON * 0.5,
"0 01110 1111111111",
"0 01111110 11111111110000000000000");
testBits (1.0 - HALF_EPSILON * 0.5 * 0.5,
"0 01111 0000000000",
"0 01111111 00000000000000000000000");
testBits (1.0 - HALF_EPSILON * 0.5 * 0.4999,
"0 01111 0000000000",
"0 01111111 00000000000000000000000");
testBits (1.0 - HALF_EPSILON * 0.5 * 0.5001,
"0 01110 1111111111",
"0 01111110 11111111110000000000000");
//
// Numbers close to HALF_MIN
//
testBits (HALF_MIN,
"0 00000 0000000001",
"0 01100111 00000000000000000000000");
testBits (HALF_MIN + HALF_MIN,
"0 00000 0000000010",
"0 01101000 00000000000000000000000");
testBits (HALF_MIN + HALF_MIN * 0.5,
"0 00000 0000000010",
"0 01101000 00000000000000000000000");
testBits (HALF_MIN + HALF_MIN * 0.4999,
"0 00000 0000000001",
"0 01100111 00000000000000000000000");
testBits (HALF_MIN + HALF_MIN * 0.5001,
"0 00000 0000000010",
"0 01101000 00000000000000000000000");
testBits (HALF_MIN - HALF_MIN,
"0 00000 0000000000",
"0 00000000 00000000000000000000000");
testBits (HALF_MIN - HALF_MIN * 0.5,
"0 00000 0000000001",
"0 01100111 00000000000000000000000");
testBits (HALF_MIN - HALF_MIN * 0.4999,
"0 00000 0000000001",
"0 01100111 00000000000000000000000");
testBits (HALF_MIN - HALF_MIN * 0.5001,
"0 00000 0000000000",
"0 00000000 00000000000000000000000");
//
// Numbers close to HALF_NRM_MIN
//
testBits (HALF_NRM_MIN,
"0 00001 0000000000",
"0 01110001 00000000000000000000000");
testBits (HALF_NRM_MIN + HALF_MIN,
"0 00001 0000000001",
"0 01110001 00000000010000000000000");
testBits (HALF_NRM_MIN + HALF_MIN * 0.5,
"0 00001 0000000001",
"0 01110001 00000000010000000000000");
testBits (HALF_NRM_MIN + HALF_MIN * 0.4999,
"0 00001 0000000000",
"0 01110001 00000000000000000000000");
testBits (HALF_NRM_MIN + HALF_MIN * 0.5001,
"0 00001 0000000001",
"0 01110001 00000000010000000000000");
testBits (HALF_NRM_MIN - HALF_MIN,
"0 00000 1111111111",
"0 01110000 11111111100000000000000");
testBits (HALF_NRM_MIN - HALF_MIN * 0.5,
"0 00001 0000000000",
"0 01110001 00000000000000000000000");
testBits (HALF_NRM_MIN - HALF_MIN * 0.49995,
"0 00001 0000000000",
"0 01110001 00000000000000000000000");
testBits (HALF_NRM_MIN - HALF_MIN * 0.50005,
"0 00000 1111111111",
"0 01110000 11111111100000000000000");
//
// Small positive integers and simple decimal fractions
//
testBits (2,
"0 10000 0000000000",
"0 10000000 00000000000000000000000");
testBits (3,
"0 10000 1000000000",
"0 10000000 10000000000000000000000");
testBits (10,
"0 10010 0100000000",
"0 10000010 01000000000000000000000");
testBits (0.1,
"0 01011 1001100110",
"0 01111011 10011001100000000000000");
testBits (0.2,
"0 01100 1001100110",
"0 01111100 10011001100000000000000");
testBits (0.3,
"0 01101 0011001101",
"0 01111101 00110011010000000000000");
//
// Numbers close to HALF_MAX
//
testBits (HALF_MAX,
"0 11110 1111111111",
"0 10001110 11111111110000000000000");
testBits ((1 << HALF_MAX_EXP) * 1.0,
"0 11111 0000000000", // +infinity
"0 11111111 00000000000000000000000"); // +infinity
testBits ((1 << HALF_MAX_EXP) * (1.0 - HALF_EPSILON * 0.25),
"0 11111 0000000000", // +infinity
"0 11111111 00000000000000000000000"); // +infinity
testBits ((1 << HALF_MAX_EXP) * (1.0 - HALF_EPSILON * 0.25005),
"0 11110 1111111111",
"0 10001110 11111111110000000000000");
testBits ((1 << HALF_MAX_EXP) * (1.0 - HALF_EPSILON * 0.24995),
"0 11111 0000000000", // +infinity
"0 11111111 00000000000000000000000"); // +infinity
//
// Large positive numbers, positive infinity and NANs
//
testBits (HALF_MAX * HALF_MAX,
"0 11111 0000000000", // +infinity
"0 11111111 00000000000000000000000"); // +infinity
testBits (FLT_MAX,
"0 11111 0000000000", // +infinity
"0 11111111 00000000000000000000000"); // +infinity
testBits (floatPosInfinity(),
"0 11111 0000000000", // +infinity
"0 11111111 00000000000000000000000"); // +infinity
testBits (floatPosQNan1(),
"0 11111 1111111111", // nan
"0 11111111 11111111110000000000000"); // nan
testBits (floatPosQNan2(),
"0 11111 1010101010", // nan
"0 11111111 10101010100000000000000"); // nan
//
// Numbers close to -1.0
//
testBits (-1.0,
"1 01111 0000000000",
"1 01111111 00000000000000000000000");
testBits (-(1.0 + HALF_EPSILON),
"1 01111 0000000001",
"1 01111111 00000000010000000000000");
testBits (-(1.0 + HALF_EPSILON * 0.5),
"1 01111 0000000001",
"1 01111111 00000000010000000000000");
testBits (-(1.0 + HALF_EPSILON * 0.4999),
"1 01111 0000000000",
"1 01111111 00000000000000000000000");
testBits (-(1.0 + HALF_EPSILON * 0.5001),
"1 01111 0000000001",
"1 01111111 00000000010000000000000");
testBits (-(1.0 - HALF_EPSILON * 0.5),
"1 01110 1111111111",
"1 01111110 11111111110000000000000");
testBits (-(1.0 - HALF_EPSILON * 0.5 * 0.5),
"1 01111 0000000000",
"1 01111111 00000000000000000000000");
testBits (-(1.0 - HALF_EPSILON * 0.5 * 0.4999),
"1 01111 0000000000",
"1 01111111 00000000000000000000000");
testBits (-(1.0 - HALF_EPSILON * 0.5 * 0.5001),
"1 01110 1111111111",
"1 01111110 11111111110000000000000");
//
// Numbers close to -HALF_MIN
//
testBits (-HALF_MIN,
"1 00000 0000000001",
"1 01100111 00000000000000000000000");
testBits (-(HALF_MIN + HALF_MIN),
"1 00000 0000000010",
"1 01101000 00000000000000000000000");
testBits (-(HALF_MIN + HALF_MIN * 0.5),
"1 00000 0000000010",
"1 01101000 00000000000000000000000");
testBits (-(HALF_MIN + HALF_MIN * 0.4999),
"1 00000 0000000001",
"1 01100111 00000000000000000000000");
testBits (-(HALF_MIN + HALF_MIN * 0.5001),
"1 00000 0000000010",
"1 01101000 00000000000000000000000");
testBits (-(HALF_MIN - HALF_MIN),
"0 00000 0000000000",
"0 00000000 00000000000000000000000");
testBits (-(HALF_MIN - HALF_MIN * 0.5),
"1 00000 0000000001",
"1 01100111 00000000000000000000000");
testBits (-(HALF_MIN - HALF_MIN * 0.4999),
"1 00000 0000000001",
"1 01100111 00000000000000000000000");
testBits (-(HALF_MIN - HALF_MIN * 0.5001),
"0 00000 0000000000",
"0 00000000 00000000000000000000000");
//
// Numbers close to -HALF_NRM_MIN
//
testBits (-HALF_NRM_MIN,
"1 00001 0000000000",
"1 01110001 00000000000000000000000");
testBits (-(HALF_NRM_MIN + HALF_MIN),
"1 00001 0000000001",
"1 01110001 00000000010000000000000");
testBits (-(HALF_NRM_MIN + HALF_MIN * 0.5),
"1 00001 0000000001",
"1 01110001 00000000010000000000000");
testBits (-(HALF_NRM_MIN + HALF_MIN * 0.4999),
"1 00001 0000000000",
"1 01110001 00000000000000000000000");
testBits (-(HALF_NRM_MIN + HALF_MIN * 0.5001),
"1 00001 0000000001",
"1 01110001 00000000010000000000000");
testBits (-(HALF_NRM_MIN - HALF_MIN),
"1 00000 1111111111",
"1 01110000 11111111100000000000000");
testBits (-(HALF_NRM_MIN - HALF_MIN * 0.5),
"1 00001 0000000000",
"1 01110001 00000000000000000000000");
testBits (-(HALF_NRM_MIN - HALF_MIN * 0.49995),
"1 00001 0000000000",
"1 01110001 00000000000000000000000");
testBits (-(HALF_NRM_MIN - HALF_MIN * 0.50005),
"1 00000 1111111111",
"1 01110000 11111111100000000000000");
//
// Small negative integers and simple decimal fractions
//
testBits (-2,
"1 10000 0000000000",
"1 10000000 00000000000000000000000");
testBits (-3,
"1 10000 1000000000",
"1 10000000 10000000000000000000000");
testBits (-10,
"1 10010 0100000000",
"1 10000010 01000000000000000000000");
testBits (-0.1,
"1 01011 1001100110",
"1 01111011 10011001100000000000000");
testBits (-0.2,
"1 01100 1001100110",
"1 01111100 10011001100000000000000");
testBits (-0.3,
"1 01101 0011001101",
"1 01111101 00110011010000000000000");
//
// Numbers close to -HALF_MAX
//
testBits (-HALF_MAX,
"1 11110 1111111111",
"1 10001110 11111111110000000000000");
testBits (-(1 << HALF_MAX_EXP) * 1.0,
"1 11111 0000000000", // +infinity
"1 11111111 00000000000000000000000"); // +infinity
testBits (-(1 << HALF_MAX_EXP) * (1.0 - HALF_EPSILON * 0.25),
"1 11111 0000000000", // +infinity
"1 11111111 00000000000000000000000"); // +infinity
testBits (-(1 << HALF_MAX_EXP) * (1.0 - HALF_EPSILON * 0.25005),
"1 11110 1111111111",
"1 10001110 11111111110000000000000");
testBits (-(1 << HALF_MAX_EXP) * (1.0 - HALF_EPSILON * 0.24995),
"1 11111 0000000000", // +infinity
"1 11111111 00000000000000000000000"); // +infinity
//
// Large negative numbers, negative infinity and NANs
//
testBits (-HALF_MAX * HALF_MAX,
"1 11111 0000000000", // +infinity
"1 11111111 00000000000000000000000"); // +infinity
testBits (-FLT_MAX,
"1 11111 0000000000", // +infinity
"1 11111111 00000000000000000000000"); // +infinity
testBits (floatNegInfinity(),
"1 11111 0000000000", // +infinity
"1 11111111 00000000000000000000000"); // +infinity
testBits (floatNegQNan1(),
"1 11111 1111111111", // nan
"1 11111111 11111111110000000000000"); // nan
testBits (floatNegQNan2(),
"1 11111 1010101010", // nan
"1 11111111 10101010100000000000000"); // nan
cout << "ok\n\n" << flush;
}
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