.. function:: fma(x, y, z)

Fused multiply-add operation. Return ``(x * y) + z``, computed as though with

infinite precision and range followed by a single round to the ``float``

format. This operation often provides better accuracy than the direct

expression ``(x * y) + z``.

This function follows the specification of the fusedMultiplyAdd operation

described in the IEEE 754 standard. The standard leaves one case

implementation-defined, namely the result of ``fma(0, inf, nan)``

and ``fma(inf, 0, nan)``. In these cases, ``math.fma`` returns a NaN,

and does not raise any exception.

.. versionadded:: 3.13

math

A new function :func:`~math.fma` for fused multiply-add operations has been

added. This function computes ``x * y + z`` with only a single round, and so

avoids any intermediate loss of precision. It wraps the ``fma()`` function

provided by C99, and follows the specification of the IEEE 754

"fusedMultiplyAdd" operation for special cases.

(Contributed by Mark Dickinson and Victor Stinner in :gh:`73468`.)

class FMATests(unittest.TestCase):

""" Tests for math.fma. """

def test_fma_nan_results(self):

# Selected representative values.

values = [

-math.inf, -1e300, -2.3, -1e-300, -0.0,

0.0, 1e-300, 2.3, 1e300, math.inf, math.nan

]

# If any input is a NaN, the result should be a NaN, too.

for a, b in itertools.product(values, repeat=2):

self.assertIsNaN(math.fma(math.nan, a, b))

self.assertIsNaN(math.fma(a, math.nan, b))

self.assertIsNaN(math.fma(a, b, math.nan))

def test_fma_infinities(self):

# Cases involving infinite inputs or results.

positives = [1e-300, 2.3, 1e300, math.inf]

finites = [-1e300, -2.3, -1e-300, -0.0, 0.0, 1e-300, 2.3, 1e300]

non_nans = [-math.inf, -2.3, -0.0, 0.0, 2.3, math.inf]

# ValueError due to inf * 0 computation.

for c in non_nans:

for infinity in [math.inf, -math.inf]:

for zero in [0.0, -0.0]:

with self.assertRaises(ValueError):

math.fma(infinity, zero, c)

with self.assertRaises(ValueError):

math.fma(zero, infinity, c)

# ValueError when a*b and c both infinite of opposite signs.

for b in positives:

with self.assertRaises(ValueError):

math.fma(math.inf, b, -math.inf)

with self.assertRaises(ValueError):

math.fma(math.inf, -b, math.inf)

with self.assertRaises(ValueError):

math.fma(-math.inf, -b, -math.inf)

with self.assertRaises(ValueError):

math.fma(-math.inf, b, math.inf)

with self.assertRaises(ValueError):

math.fma(b, math.inf, -math.inf)

with self.assertRaises(ValueError):

math.fma(-b, math.inf, math.inf)

with self.assertRaises(ValueError):

math.fma(-b, -math.inf, -math.inf)

with self.assertRaises(ValueError):

math.fma(b, -math.inf, math.inf)

# Infinite result when a*b and c both infinite of the same sign.

for b in positives:

self.assertEqual(math.fma(math.inf, b, math.inf), math.inf)

self.assertEqual(math.fma(math.inf, -b, -math.inf), -math.inf)

self.assertEqual(math.fma(-math.inf, -b, math.inf), math.inf)

self.assertEqual(math.fma(-math.inf, b, -math.inf), -math.inf)

self.assertEqual(math.fma(b, math.inf, math.inf), math.inf)

self.assertEqual(math.fma(-b, math.inf, -math.inf), -math.inf)

self.assertEqual(math.fma(-b, -math.inf, math.inf), math.inf)

self.assertEqual(math.fma(b, -math.inf, -math.inf), -math.inf)

# Infinite result when a*b finite, c infinite.

for a, b in itertools.product(finites, finites):

self.assertEqual(math.fma(a, b, math.inf), math.inf)

self.assertEqual(math.fma(a, b, -math.inf), -math.inf)

# Infinite result when a*b infinite, c finite.

for b, c in itertools.product(positives, finites):

self.assertEqual(math.fma(math.inf, b, c), math.inf)

self.assertEqual(math.fma(-math.inf, b, c), -math.inf)

self.assertEqual(math.fma(-math.inf, -b, c), math.inf)

self.assertEqual(math.fma(math.inf, -b, c), -math.inf)

self.assertEqual(math.fma(b, math.inf, c), math.inf)

self.assertEqual(math.fma(b, -math.inf, c), -math.inf)

self.assertEqual(math.fma(-b, -math.inf, c), math.inf)

self.assertEqual(math.fma(-b, math.inf, c), -math.inf)

# gh-73468: On WASI and FreeBSD, libc fma() doesn't implement IEE 754-2008

# properly: it doesn't use the right sign when the result is zero.

@unittest.skipIf(support.is_wasi,

@unittest.skipIf(sys.platform.startswith('freebsd'),

def test_fma_zero_result(self):

nonnegative_finites = [0.0, 1e-300, 2.3, 1e300]

# Zero results from exact zero inputs.

for b in nonnegative_finites:

self.assertIsPositiveZero(math.fma(0.0, b, 0.0))

self.assertIsPositiveZero(math.fma(0.0, b, -0.0))

self.assertIsNegativeZero(math.fma(0.0, -b, -0.0))

self.assertIsPositiveZero(math.fma(0.0, -b, 0.0))

self.assertIsPositiveZero(math.fma(-0.0, -b, 0.0))

self.assertIsPositiveZero(math.fma(-0.0, -b, -0.0))

self.assertIsNegativeZero(math.fma(-0.0, b, -0.0))

self.assertIsPositiveZero(math.fma(-0.0, b, 0.0))

self.assertIsPositiveZero(math.fma(b, 0.0, 0.0))

self.assertIsPositiveZero(math.fma(b, 0.0, -0.0))

self.assertIsNegativeZero(math.fma(-b, 0.0, -0.0))

self.assertIsPositiveZero(math.fma(-b, 0.0, 0.0))

self.assertIsPositiveZero(math.fma(-b, -0.0, 0.0))

self.assertIsPositiveZero(math.fma(-b, -0.0, -0.0))

self.assertIsNegativeZero(math.fma(b, -0.0, -0.0))

self.assertIsPositiveZero(math.fma(b, -0.0, 0.0))

# Exact zero result from nonzero inputs.

self.assertIsPositiveZero(math.fma(2.0, 2.0, -4.0))

self.assertIsPositiveZero(math.fma(2.0, -2.0, 4.0))

self.assertIsPositiveZero(math.fma(-2.0, -2.0, -4.0))

self.assertIsPositiveZero(math.fma(-2.0, 2.0, 4.0))

# Underflow to zero.

tiny = 1e-300

self.assertIsPositiveZero(math.fma(tiny, tiny, 0.0))

self.assertIsNegativeZero(math.fma(tiny, -tiny, 0.0))

self.assertIsPositiveZero(math.fma(-tiny, -tiny, 0.0))

self.assertIsNegativeZero(math.fma(-tiny, tiny, 0.0))

self.assertIsPositiveZero(math.fma(tiny, tiny, -0.0))

self.assertIsNegativeZero(math.fma(tiny, -tiny, -0.0))

self.assertIsPositiveZero(math.fma(-tiny, -tiny, -0.0))

self.assertIsNegativeZero(math.fma(-tiny, tiny, -0.0))

# Corner case where rounding the multiplication would

# give the wrong result.

x = float.fromhex('0x1p-500')

y = float.fromhex('0x1p-550')

z = float.fromhex('0x1p-1000')

self.assertIsNegativeZero(math.fma(x-y, x+y, -z))

self.assertIsPositiveZero(math.fma(y-x, x+y, z))

self.assertIsNegativeZero(math.fma(y-x, -(x+y), -z))

self.assertIsPositiveZero(math.fma(x-y, -(x+y), z))

def test_fma_overflow(self):

a = b = float.fromhex('0x1p512')

c = float.fromhex('0x1p1023')

# Overflow from multiplication.

with self.assertRaises(OverflowError):

math.fma(a, b, 0.0)

self.assertEqual(math.fma(a, b/2.0, 0.0), c)

# Overflow from the addition.

with self.assertRaises(OverflowError):

math.fma(a, b/2.0, c)

# No overflow, even though a*b overflows a float.

self.assertEqual(math.fma(a, b, -c), c)

# Extreme case: a * b is exactly at the overflow boundary, so the

# tiniest offset makes a difference between overflow and a finite

# result.

a = float.fromhex('0x1.ffffffc000000p+511')

b = float.fromhex('0x1.0000002000000p+512')

c = float.fromhex('0x0.0000000000001p-1022')

with self.assertRaises(OverflowError):

math.fma(a, b, 0.0)

with self.assertRaises(OverflowError):

math.fma(a, b, c)

self.assertEqual(math.fma(a, b, -c),

float.fromhex('0x1.fffffffffffffp+1023'))

# Another extreme case: here a*b is about as large as possible subject

# to math.fma(a, b, c) being finite.

a = float.fromhex('0x1.ae565943785f9p+512')

b = float.fromhex('0x1.3094665de9db8p+512')

c = float.fromhex('0x1.fffffffffffffp+1023')

self.assertEqual(math.fma(a, b, -c), c)

def test_fma_single_round(self):

a = float.fromhex('0x1p-50')

self.assertEqual(math.fma(a - 1.0, a + 1.0, 1.0), a*a)

def test_random(self):

# A collection of randomly generated inputs for which the naive FMA

# (with two rounds) gives a different result from a singly-rounded FMA.

# tuples (a, b, c, expected)

test_values = [

('0x1.694adde428b44p-1', '0x1.371b0d64caed7p-1',

'0x1.f347e7b8deab8p-4', '0x1.19f10da56c8adp-1'),

('0x1.605401ccc6ad6p-2', '0x1.ce3a40bf56640p-2',

'0x1.96e3bf7bf2e20p-2', '0x1.1af6d8aa83101p-1'),

('0x1.e5abd653a67d4p-2', '0x1.a2e400209b3e6p-1',

'0x1.a90051422ce13p-1', '0x1.37d68cc8c0fbbp+0'),

('0x1.f94e8efd54700p-2', '0x1.123065c812cebp-1',

'0x1.458f86fb6ccd0p-1', '0x1.ccdcee26a3ff3p-1'),

('0x1.bd926f1eedc96p-1', '0x1.eee9ca68c5740p-1',

'0x1.960c703eb3298p-2', '0x1.3cdcfb4fdb007p+0'),

('0x1.27348350fbccdp-1', '0x1.3b073914a53f1p-1',

'0x1.e300da5c2b4cbp-1', '0x1.4c51e9a3c4e29p+0'),

('0x1.2774f00b3497bp-1', '0x1.7038ec336bff0p-2',

'0x1.2f6f2ccc3576bp-1', '0x1.99ad9f9c2688bp-1'),

('0x1.51d5a99300e5cp-1', '0x1.5cd74abd445a1p-1',

'0x1.8880ab0bbe530p-1', '0x1.3756f96b91129p+0'),

('0x1.73cb965b821b8p-2', '0x1.218fd3d8d5371p-1',

'0x1.d1ea966a1f758p-2', '0x1.5217b8fd90119p-1'),

('0x1.4aa98e890b046p-1', '0x1.954d85dff1041p-1',

'0x1.122b59317ebdfp-1', '0x1.0bf644b340cc5p+0'),

('0x1.e28f29e44750fp-1', '0x1.4bcc4fdcd18fep-1',

'0x1.fd47f81298259p-1', '0x1.9b000afbc9995p+0'),

('0x1.d2e850717fe78p-3', '0x1.1dd7531c303afp-1',

'0x1.e0869746a2fc2p-2', '0x1.316df6eb26439p-1'),

('0x1.cf89c75ee6fbap-2', '0x1.b23decdc66825p-1',

'0x1.3d1fe76ac6168p-1', '0x1.00d8ea4c12abbp+0'),

('0x1.3265ae6f05572p-2', '0x1.16d7ec285f7a2p-1',

'0x1.0b8405b3827fbp-1', '0x1.5ef33c118a001p-1'),

('0x1.c4d1bf55ec1a5p-1', '0x1.bc59618459e12p-2',

'0x1.ce5b73dc1773dp-1', '0x1.496cf6164f99bp+0'),

('0x1.d350026ac3946p-1', '0x1.9a234e149a68cp-2',

'0x1.f5467b1911fd6p-2', '0x1.b5cee3225caa5p-1'),

]

for a_hex, b_hex, c_hex, expected_hex in test_values:

a = float.fromhex(a_hex)

b = float.fromhex(b_hex)

c = float.fromhex(c_hex)

expected = float.fromhex(expected_hex)

self.assertEqual(math.fma(a, b, c), expected)

self.assertEqual(math.fma(b, a, c), expected)

# Custom assertions.

def assertIsNaN(self, value):

self.assertTrue(

math.isnan(value),

msg="Expected a NaN, got {!r}".format(value)

)

def assertIsPositiveZero(self, value):

self.assertTrue(

value == 0 and math.copysign(1, value) > 0,

msg="Expected a positive zero, got {!r}".format(value)

)

def assertIsNegativeZero(self, value):

self.assertTrue(

value == 0 and math.copysign(1, value) < 0,

msg="Expected a negative zero, got {!r}".format(value)

)

Added new :func:`math.fma` function, wrapping C99's ``fma()`` operation:

fused multiply-add function. Patch by Mark Dickinson and Victor Stinner.