def test_simple():
ffi = FFI(backend=FakeBackend())
ffi.cdef("double sin(double x);")
m = ffi.load("m")
func = m.sin # should be a callable on real backends
assert func.name == 'sin'
assert func.BType == '<func (<double>), <double>, False>'
def test_simple():
ffi = FFI(backend=FakeBackend())
ffi.cdef("double sin(double x);")
m = ffi.load("m")
func = m.sin # should be a callable on real backends
assert func.name == 'sin'
assert func.BType == '<func (<double>), <double>, False>'
def add_ffi(self, nominal_vf, E_matrix, nu_matrix, use_ti, global_sf=None):
"""Adds Fiber Fraction Imperfection (FFI)
There can be only one of these, so calling this function overrides the
previous imperfection, if any.
Parameters
----------
nominal_vf : float
Nominal fiber volume fraction of the material
E_matrix : float
Young's modulus of the matrix material
nu_matrix : float
Poisson's ratio of the matrix material
use_ti : bool
If ``True``, create varying material properties according to the
thickness imperfection data (if present).
global_sf : float or ``None``
Global scaling factor to apply to the material thickness.
Set to ``None`` to disable. The global scaling may be overridden
by a thickness imperfection, if ``use_ti`` (see above) is ``True``.
Returns
-------
ffi : :class:`.FFI` object.
"""
if self.ffi is not None:
warn('FFI object already set, overriding...')
self.ffi = FFI(nominal_vf, E_matrix, nu_matrix, use_ti, global_sf)
self.ffi.impconf = self
return self.ffi
def test_char(self):
ffi = FFI(backend=self.Backend())
assert ffi.new("char", "\xff")[0] == '\xff'
assert ffi.new("char")[0] == '\x00'
assert int(ffi.cast("char", 300)) == 300 - 256
assert bool(ffi.new("char"))
py.test.raises(TypeError, ffi.new, "char", 32)
py.test.raises(TypeError, ffi.new, "char", "foo")
#
p = ffi.new("char[]", ['a', 'b', '\x9c'])
assert len(p) == 3
assert p[0] == 'a'
assert p[1] == 'b'
assert p[2] == '\x9c'
p[0] = '\xff'
assert p[0] == '\xff'
p = ffi.new("char[]", "abcd")
assert len(p) == 5
assert p[4] == '\x00' # like in C, with: char[] p = "abcd";
#
p = ffi.new("char[4]", "ab")
assert len(p) == 4
assert [p[i] for i in range(4)] == ['a', 'b', '\x00', '\x00']
p = ffi.new("char[2]", "ab")
assert len(p) == 2
assert [p[i] for i in range(2)] == ['a', 'b']
py.test.raises(IndexError, ffi.new, "char[2]", "abc")
def test_constructor_struct_from_dict(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a; short b, c; };")
s = ffi.new("struct foo", {'b': 123, 'c': 456})
assert s.a == 0
assert s.b == 123
assert s.c == 456
py.test.raises(KeyError, ffi.new, "struct foo", {'d': 456})
def test_sin(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
double sin(double x);
""")
m = ffi.load("m")
x = m.sin(1.23)
assert x == math.sin(1.23)
def test_strchr(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
char *strchr(const char *s, int c);
""")
p = ffi.new("char[]", "hello world!")
q = ffi.C.strchr(p, ord('w'))
assert str(q) == "world!"
def test_passing_array(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int strlen(char[]);
""")
p = ffi.new("char[]", "hello")
res = ffi.C.strlen(p)
assert res == 5
def test_constructor_struct_from_dict(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a; short b, c; };")
s = ffi.new("struct foo", {'b': 123, 'c': 456})
assert s.a == 0
assert s.b == 123
assert s.c == 456
py.test.raises(KeyError, ffi.new, "struct foo", {'d': 456})
def test_pointer_init(self):
ffi = FFI(backend=self.Backend())
n = ffi.new("int", 24)
a = ffi.new("int *[10]", [None, None, n, n, None])
for i in range(10):
if i not in (2, 3):
assert a[i] is None
assert a[2] == a[3] == n
def test_new_array_of_pointer_2(self):
ffi = FFI(backend=self.Backend())
n = ffi.new("int[1]", [99])
p = ffi.new("int*[4]")
p[3] = n
a = p[3]
assert repr(a) == "<cdata 'int *'>"
assert a[0] == 99
def test_new_array_of_array(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int[3][4]")
p[0][0] = 10
p[2][3] = 33
assert p[0][0] == 10
assert p[2][3] == 33
py.test.raises(IndexError, "p[1][-1]")
def test_new_array_of_array(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int[3][4]")
p[0][0] = 10
p[2][3] = 33
assert p[0][0] == 10
assert p[2][3] == 33
py.test.raises(IndexError, "p[1][-1]")
def test_passing_array(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int strlen(char[]);
""")
p = ffi.new("char[]", "hello")
res = ffi.C.strlen(p)
assert res == 5
def test_sin(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
double sin(double x);
""")
m = ffi.load("m")
x = m.sin(1.23)
assert x == math.sin(1.23)
def test_strchr(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
char *strchr(const char *s, int c);
""")
p = ffi.new("char[]", "hello world!")
q = ffi.C.strchr(p, ord('w'))
assert str(q) == "world!"
def test_pointer_init(self):
ffi = FFI(backend=self.Backend())
n = ffi.new("int", 24)
a = ffi.new("int *[10]", [None, None, n, n, None])
for i in range(10):
if i not in (2, 3):
assert a[i] is None
assert a[2] == a[3] == n
def test_new_array_of_pointer_2(self):
ffi = FFI(backend=self.Backend())
n = ffi.new("int[1]", [99])
p = ffi.new("int*[4]")
p[3] = n
a = p[3]
assert repr(a) == "<cdata 'int *'>"
assert a[0] == 99
def test_must_specify_type_of_vararg(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int printf(const char *format, ...);
""")
e = py.test.raises(TypeError, ffi.C.printf, "hello %d\n", 42)
assert str(e.value) == ("argument 2 passed in the variadic part "
"needs to be a cdata object (got int)")
def test_must_specify_type_of_vararg(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int printf(const char *format, ...);
""")
e = py.test.raises(TypeError, ffi.C.printf, "hello %d\n", 42)
assert str(e.value) == ("argument 2 passed in the variadic part "
"needs to be a cdata object (got int)")
def test_ffi_string(self):
ffi = FFI(backend=self.Backend())
a = ffi.new("int[]", range(100, 110))
s = ffi.string(ffi.cast("void *", a), 8)
assert type(s) is str
if sys.byteorder == 'little':
assert s == '\x64\x00\x00\x00\x65\x00\x00\x00'
else:
assert s == '\x00\x00\x00\x64\x00\x00\x00\x65'
def test_new_single_integer(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int") # similar to ffi.new("int[1]")
assert p[0] == 0
p[0] = -123
assert p[0] == -123
p = ffi.new("int", -42)
assert p[0] == -42
assert repr(p) == "<cdata 'int *' owning %d bytes>" % SIZE_OF_INT
def test_ffi_string(self):
ffi = FFI(backend=self.Backend())
a = ffi.new("int[]", range(100, 110))
s = ffi.string(ffi.cast("void *", a), 8)
assert type(s) is str
if sys.byteorder == 'little':
assert s == '\x64\x00\x00\x00\x65\x00\x00\x00'
else:
assert s == '\x00\x00\x00\x64\x00\x00\x00\x65'
def test_function_with_struct_argument(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
struct in_addr { unsigned int s_addr; };
char *inet_ntoa(struct in_addr in);
""")
ina = ffi.new("struct in_addr", [0x04040404])
a = ffi.C.inet_ntoa(ina[0])
assert str(a) == '4.4.4.4'
def test_function_with_struct_argument(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
struct in_addr { unsigned int s_addr; };
char *inet_ntoa(struct in_addr in);
""")
ina = ffi.new("struct in_addr", [0x04040404])
a = ffi.C.inet_ntoa(ina[0])
assert str(a) == '4.4.4.4'
def test_struct_pointer(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a; short b, c; };")
s = ffi.new("struct foo")
assert s[0].a == s[0].b == s[0].c == 0
s[0].b = -23
assert s[0].b == s.b == -23
py.test.raises(OverflowError, "s[0].b = -32769")
py.test.raises(IndexError, "s[1]")
def test_function_has_a_c_type(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int puts(const char *);
""")
fptr = ffi.C.puts
assert ffi.typeof(fptr) == ffi.typeof("int(*)(const char*)")
if self.Backend is CTypesBackend:
assert repr(fptr) == "<cdata 'int puts(char *)'>"
def test_typedef():
ffi = FFI(backend=FakeBackend())
ffi.cdef("""
typedef unsigned int UInt;
typedef UInt UIntReally;
UInt foo(void);
""")
assert ffi.typeof("UIntReally") == '<unsigned int>'
assert ffi.C.foo.BType == '<func (), <unsigned int>, False>'
def test_typedef():
ffi = FFI(backend=FakeBackend())
ffi.cdef("""
typedef unsigned int UInt;
typedef UInt UIntReally;
UInt foo(void);
""")
assert ffi.typeof("UIntReally") == '<unsigned int>'
assert ffi.C.foo.BType == '<func (), <unsigned int>, False>'
def test_cast_array_to_charp(self):
ffi = FFI(backend=self.Backend())
a = ffi.new("short int[]", [0x1234, 0x5678])
p = ffi.cast("char*", a)
data = ''.join([p[i] for i in range(4)])
if sys.byteorder == 'little':
assert data == '\x34\x12\x78\x56'
else:
assert data == '\x12\x34\x56\x78'
def test_array_of_struct(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a, b; };")
s = ffi.new("struct foo[1]")
py.test.raises(AttributeError, 's.b')
py.test.raises(AttributeError, 's.b = 412')
s[0].b = 412
assert s[0].b == 412
py.test.raises(IndexError, 's[1]')
def test_getting_errno(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int test_getting_errno(void);
""")
ownlib = ffi.load(self.module)
res = ownlib.test_getting_errno()
assert res == -1
assert ffi.C.errno == 123
def test_new_single_integer(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int") # similar to ffi.new("int[1]")
assert p[0] == 0
p[0] = -123
assert p[0] == -123
p = ffi.new("int", -42)
assert p[0] == -42
assert repr(p) == "<cdata 'int *' owning %d bytes>" % SIZE_OF_INT
def test_getting_errno(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int test_getting_errno(void);
""")
ownlib = ffi.load(self.module)
res = ownlib.test_getting_errno()
assert res == -1
assert ffi.C.errno == 123
def test_array_of_struct(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a, b; };")
s = ffi.new("struct foo[1]")
py.test.raises(AttributeError, 's.b')
py.test.raises(AttributeError, 's.b = 412')
s[0].b = 412
assert s[0].b == 412
py.test.raises(IndexError, 's[1]')
def test_cast_array_to_charp(self):
ffi = FFI(backend=self.Backend())
a = ffi.new("short int[]", [0x1234, 0x5678])
p = ffi.cast("char*", a)
data = ''.join([p[i] for i in range(4)])
if sys.byteorder == 'little':
assert data == '\x34\x12\x78\x56'
else:
assert data == '\x12\x34\x56\x78'
def test_struct_pointer(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a; short b, c; };")
s = ffi.new("struct foo")
assert s[0].a == s[0].b == s[0].c == 0
s[0].b = -23
assert s[0].b == s.b == -23
py.test.raises(OverflowError, "s[0].b = -32769")
py.test.raises(IndexError, "s[1]")
def test_typedef_more_complex():
ffi = FFI(backend=FakeBackend())
ffi.cdef("""
typedef struct { int a, b; } foo_t, *foo_p;
int foo(foo_p[]);
""")
assert str(ffi.typeof("foo_t")) == '<int>a, <int>b'
assert ffi.typeof("foo_p") == '<pointer to <int>a, <int>b>'
assert ffi.C.foo.BType == ('<func (<pointer to <pointer to '
'<int>a, <int>b>>), <int>, False>')
def test_sinf(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
float sinf(float x);
""")
m = ffi.load("m")
x = m.sinf(1.23)
assert type(x) is float
assert x != math.sin(1.23) # rounding effects
assert abs(x - math.sin(1.23)) < 1E-6
def test_fetch_const_char_p_field(self):
# 'const' is ignored so far
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { const char *name; };")
t = ffi.new("const char[]", "testing")
s = ffi.new("struct foo", [t])
assert type(s.name) is not str
assert str(s.name) == "testing"
s.name = None
assert s.name is None
def test_recursive_struct(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int value; struct foo *next; };")
s = ffi.new("struct foo")
t = ffi.new("struct foo")
s.value = 123
s.next = t
t.value = 456
assert s.value == 123
assert s.next.value == 456
def test_constructor_struct_of_array(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a[2]; char b[3]; };")
s = ffi.new("struct foo", [[10, 11], ['a', 'b', 'c']])
assert s.a[1] == 11
assert s.b[2] == 'c'
s.b[1] = 'X'
assert s.b[0] == 'a'
assert s.b[1] == 'X'
assert s.b[2] == 'c'
def test_fputs(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int fputs(const char *, void *);
void *stdout, *stderr;
""")
with FdWriteCapture(2) as fd:
ffi.C.fputs("hello from stderr\n", ffi.C.stderr)
res = fd.getvalue()
assert res == 'hello from stderr\n'
def test_none_as_null(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int*[1]")
assert p[0] is None
#
n = ffi.new("int", 99)
p = ffi.new("int*[]", [n])
assert p[0][0] == 99
p[0] = None
assert p[0] is None
def test_none_as_null(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int*[1]")
assert p[0] is None
#
n = ffi.new("int", 99)
p = ffi.new("int*[]", [n])
assert p[0][0] == 99
p[0] = None
assert p[0] is None
def test_constructor_struct_of_array(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int a[2]; char b[3]; };")
s = ffi.new("struct foo", [[10, 11], ['a', 'b', 'c']])
assert s.a[1] == 11
assert s.b[2] == 'c'
s.b[1] = 'X'
assert s.b[0] == 'a'
assert s.b[1] == 'X'
assert s.b[2] == 'c'
def test_recursive_struct(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("struct foo { int value; struct foo *next; };")
s = ffi.new("struct foo")
t = ffi.new("struct foo")
s.value = 123
s.next = t
t.value = 456
assert s.value == 123
assert s.next.value == 456
def test_fputs(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int fputs(const char *, void *);
void *stdout, *stderr;
""")
with FdWriteCapture(2) as fd:
ffi.C.fputs("hello from stderr\n", ffi.C.stderr)
res = fd.getvalue()
assert res == 'hello from stderr\n'
def test_sinf(self):
ffi = FFI(backend=self.Backend())
ffi.cdef("""
float sinf(float x);
""")
m = ffi.load("m")
x = m.sinf(1.23)
assert type(x) is float
assert x != math.sin(1.23) # rounding effects
assert abs(x - math.sin(1.23)) < 1E-6
def test_char(self):
ffi = FFI(backend=self.Backend())
assert ffi.new("char", "\xff")[0] == '\xff'
assert ffi.new("char")[0] == '\x00'
assert int(ffi.cast("char", 300)) == 300 - 256
assert bool(ffi.new("char"))
py.test.raises(TypeError, ffi.new, "char", 32)
py.test.raises(TypeError, ffi.new, "char", "foo")
#
p = ffi.new("char[]", ['a', 'b', '\x9c'])
assert len(p) == 3
assert p[0] == 'a'
assert p[1] == 'b'
assert p[2] == '\x9c'
p[0] = '\xff'
assert p[0] == '\xff'
p = ffi.new("char[]", "abcd")
assert len(p) == 5
assert p[4] == '\x00' # like in C, with: char[] p = "abcd";
#
p = ffi.new("char[4]", "ab")
assert len(p) == 4
assert [p[i] for i in range(4)] == ['a', 'b', '\x00', '\x00']
p = ffi.new("char[2]", "ab")
assert len(p) == 2
assert [p[i] for i in range(2)] == ['a', 'b']
py.test.raises(IndexError, ffi.new, "char[2]", "abc")
def test_char_cast(self):
ffi = FFI(backend=self.Backend())
p = ffi.cast("int", '\x01')
assert ffi.typeof(p) is ffi.typeof("int")
assert int(p) == 1
p = ffi.cast("int", ffi.cast("char", "a"))
assert int(p) == ord("a")
p = ffi.cast("int", ffi.cast("char", "\x80"))
assert int(p) == 0x80 # "char" is considered unsigned in this case
p = ffi.cast("int", "\x81")
assert int(p) == 0x81
def test_array_indexing(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int[10]")
p[0] = 42
p[9] = 43
assert p[0] == 42
assert p[9] == 43
py.test.raises(IndexError, "p[10]")
py.test.raises(IndexError, "p[10] = 44")
py.test.raises(IndexError, "p[-1]")
py.test.raises(IndexError, "p[-1] = 44")
def test_new_pointer_to_array(self):
ffi = FFI(backend=self.Backend())
a = ffi.new("int[4]", [100, 102, 104, 106])
p = ffi.new("int *", a)
assert p[0] == ffi.cast("int *", a)
assert p[0][2] == 104
p = ffi.cast("int *", a)
assert p[0] == 100
assert p[1] == 102
assert p[2] == 104
assert p[3] == 106
def test_cast_between_pointers(self):
ffi = FFI(backend=self.Backend())
a = ffi.new("short int[]", [0x1234, 0x5678])
p = ffi.cast("short*", a)
p2 = ffi.cast("int*", p)
q = ffi.cast("char*", p2)
data = ''.join([q[i] for i in range(4)])
if sys.byteorder == 'little':
assert data == '\x34\x12\x78\x56'
else:
assert data == '\x12\x34\x56\x78'
def test_cast_functionptr_and_int(self):
ffi = FFI(backend=self.Backend())
def cb(n):
return n + 1
a = ffi.callback("int(*)(int)", cb)
p = ffi.cast("void *", a)
assert p
b = ffi.cast("int(*)(int)", p)
assert b(41) == 42
assert a == b
assert hash(a) == hash(b)
def test_array_indexing(self):
ffi = FFI(backend=self.Backend())
p = ffi.new("int[10]")
p[0] = 42
p[9] = 43
assert p[0] == 42
assert p[9] == 43
py.test.raises(IndexError, "p[10]")
py.test.raises(IndexError, "p[10] = 44")
py.test.raises(IndexError, "p[-1]")
py.test.raises(IndexError, "p[-1] = 44")
def test_setting_errno(self):
if self.Backend is CTypesBackend and '__pypy__' in sys.modules:
py.test.skip("XXX errno issue with ctypes on pypy?")
ffi = FFI(backend=self.Backend())
ffi.cdef("""
int test_setting_errno(void);
""")
ownlib = ffi.load(self.module)
ffi.C.errno = 42
res = ownlib.test_setting_errno()
assert res == 42
assert ffi.C.errno == 42
def test_simple_verify():
ffi = FFI()
ffi.cdef("void some_completely_unknown_function();")
py.test.raises(CompilationError, ffi.verify)
ffi = FFI()
ffi.cdef("double sin(double x);")
# omission of math.h
py.test.raises(CompilationError, ffi.verify)
assert ffi.verify('#include <math.h>') is None
def test_cast_functionptr_and_int(self):
ffi = FFI(backend=self.Backend())
def cb(n):
return n + 1
a = ffi.callback("int(*)(int)", cb)
p = ffi.cast("void *", a)
assert p
b = ffi.cast("int(*)(int)", p)
assert b(41) == 42
assert a == b
assert hash(a) == hash(b)
def test_pointer_arithmetic(self):
ffi = FFI(backend=self.Backend())
s = ffi.new("short[]", range(100, 110))
p = ffi.cast("short *", s)
assert p[2] == 102
assert p + 1 == p + 1
assert p + 1 != p + 0
assert p == p + 0 == p - 0
assert (p + 1)[0] == 101
assert (p + 19)[-10] == 109
assert (p + 5) - (p + 1) == 4
assert p == s + 0
assert p + 1 == s + 1
