def test_pyfunc_works_with_invalid_python_names():
x = symbol("x-y.z", "int")
f = lambdify([x], x + 1)
assert f(1) == 2
t = symbol("t", '{"x.y": int, "y z": int}')
f = lambdify([t], t.x_y + t.y_z)
assert f((1, 2)) == 3
def test_pyfunc_works_with_invalid_python_names():
x = symbol('x-y.z', 'int')
f = lambdify([x], x + 1)
assert f(1) == 2
t = symbol('t', '{"x.y": int, "y z": int}')
f = lambdify([t], t.x_y + t.y_z)
assert f((1, 2)) == 3
def test_not():
x = symbol("x", "bool")
f = lambdify([x], ~x)
r = f(True)
assert isinstance(r, bool) and not r
r = f(False)
assert isinstance(r, bool) and r
def test_not():
x = symbol('x', 'bool')
f = lambdify([x], ~x)
r = f(True)
assert isinstance(r, bool) and not r
r = f(False)
assert isinstance(r, bool) and r
def test_broadcast_collect():
t = symbol("t", "var * {x: int, y: int, z: int, when: datetime}")
expr = t.distinct()
expr = expr.x + 2 * expr.y
expr = expr.distinct()
result = broadcast_collect(expr)
expected = t.distinct()
expected = broadcast(expected.x + 2 * expected.y, [expected])
expected = expected.distinct()
assert result.isidentical(expected)
def test_broadcast_collect():
t = symbol('t', 'var * {x: int, y: int, z: int, when: datetime}')
expr = t.distinct()
expr = expr.x + 2 * expr.y
expr = expr.distinct()
result = broadcast_collect(expr)
expected = t.distinct()
expected = broadcast(expected.x + 2 * expected.y, [expected])
expected = expected.distinct()
assert result.isidentical(expected)
def test_usub():
x = symbol("x", "float64")
f = lambdify([x], -x)
assert f(1.0) == -1.0
import datetime
from blaze.compute.pyfunc import symbol, lambdify, cos, math, broadcast
from blaze.compute.pyfunc import _print_python
from blaze.expr.broadcast import broadcast_collect
t = symbol("t", "{x: int, y: int, z: int, when: datetime}")
def test_simple():
f = lambdify([t], t.x + t.y)
assert f((1, 2, 3, 4)) == 1 + 2
f = lambdify([t.x, t.y], t.x + t.y)
assert f(1, 2) == 1 + 2
def test_datetime():
f = lambdify([t], t.x + t.when.year)
assert f((1, 2, 3, datetime.datetime(2000, 1, 1))) == 1 + 2000
def inc(x):
return x + 1
def test_map():
f = lambdify([t], t.x + t.y.map(inc, "int"))
assert f((1, 2, 3, 4)) == 1 + inc(2)
def test_usub():
x = symbol('x', 'float64')
f = lambdify([x], -x)
assert f(1.0) == -1.0
import datetime
from blaze.compute.pyfunc import symbol, lambdify, cos, math, broadcast
from blaze.compute.pyfunc import _print_python
from blaze.expr.broadcast import broadcast_collect
t = symbol('t', '{x: int, y: int, z: int, when: datetime}')
def test_simple():
f = lambdify([t], t.x + t.y)
assert f((1, 2, 3, 4)) == 1 + 2
f = lambdify([t.x, t.y], t.x + t.y)
assert f(1, 2) == 1 + 2
def test_datetime():
f = lambdify([t], t.x + t.when.year)
assert f((1, 2, 3, datetime.datetime(2000, 1, 1))) == 1 + 2000
def inc(x):
return x + 1
def test_map():
f = lambdify([t], t.x + t.y.map(inc, 'int'))
assert f((1, 2, 3, 4)) == 1 + inc(2)
def test_usub():
x = symbol('x', 'float64')
f = lambdify([x], -x)
assert f(1.0) == -1.0
import datetime
from blaze.compute.pyfunc import symbol, lambdify, cos, math, broadcast
from blaze.compute.pyfunc import _print_python
from blaze.expr.broadcast import broadcast_collect
t = symbol('t', '{x: int, y: int, z: int, when: datetime}')
def test_simple():
f = lambdify([t], t.x + t.y)
assert f((1, 2, 3, 4)) == 1 + 2
f = lambdify([t.x, t.y], t.x + t.y)
assert f(1, 2) == 1 + 2
def test_datetime():
f = lambdify([t], t.x + t.when.year)
assert f((1, 2, 3, datetime.datetime(2000, 1, 1))) == 1 + 2000
def inc(x):
return x + 1
def test_map():
f = lambdify([t], t.x + t.y.map(inc, 'int'))
assert f((1, 2, 3, 4)) == 1 + inc(2)
