def __init__(self, values, *, slopes=None, grid=None): values, values_ptr = _make_buffer(1, values, 'values') if grid is None: grid = _np.arange(len(values), dtype='float32') grid, grid_ptr = _make_buffer(1, grid, 'grid') if slopes is None: ptr = _ffi.gc( _lib.asdf_monotonecubic( values_ptr, len(values), grid_ptr, len(grid), ), _lib.asdf_monotonecubic_free) else: slopes, slopes_ptr = _make_buffer(1, slopes, 'slopes') ptr = _ffi.gc( _lib.asdf_monotonecubic_with_slopes( values_ptr, len(values), slopes_ptr, len(slopes), grid_ptr, len(grid), ), _lib.asdf_monotonecubic_free) super().__init__(ptr) # Just for error-handling self._monotone_ptr = ptr super().__init__(_lib.asdf_monotonecubic_inner(ptr))
def __init__(self, values, *, slopes=None, grid=None, closed=False): values, values_ptr = _make_buffer(1, values, 'values') if grid is None: grid = _np.arange(len(values) + closed, dtype='float32') grid, grid_ptr = _make_buffer(1, grid, 'grid') if slopes is None: ptr = _ffi.gc( _lib.asdf_shapepreservingcubicspline( values_ptr, len(values), grid_ptr, len(grid), closed, ), _lib.asdf_cubiccurve1_free) else: slopes, slopes_ptr = _make_buffer(1, slopes, 'slopes') ptr = _ffi.gc( _lib.asdf_shapepreservingcubicspline_with_slopes( values_ptr, len(values), slopes_ptr, len(slopes), grid_ptr, len(grid), closed, ), _lib.asdf_cubiccurve1_free) super().__init__(ptr)
def __init__(self, positions, tcb=None, closed=False): positions = _np.ascontiguousarray(positions, dtype='float32') if positions.ndim != 2: raise ValueError( "Positions must be two-dimensional (list of coordinate pairs)") if positions.shape[1] != 2: raise ValueError("Positions must be a list of coordinate pairs") if tcb is None: tcb = 0, 0, 0 tcb = _np.ascontiguousarray(tcb, dtype='float32') if tcb.ndim == 1: N = len(positions) if closed else len(positions) - 2 tcb = _np.tile(tcb, (N, 1)) if tcb.ndim != 2: raise ValueError( "TCB values must be two-dimensional (list of triples)") if tcb.shape[1] != 3: raise ValueError("TCB values must be a list of triples") ptr = _ffi.gc( _lib.asdf_centripetalkochanekbartelsspline2( _ffi.from_buffer('float[]', positions), len(positions), _ffi.from_buffer('float[]', tcb), len(tcb), closed, ), _lib.asdf_cubiccurve2_free) super().__init__(ptr)
def __init__(self, positions, *, tcb=None, closed=False): positions, positions_ptr = _make_buffer(2, positions, 'positions') tcb, tcb_ptr = _check_tcb(tcb, closed, len(positions)) ptr = _ffi.gc( _lib.asdf_centripetalkochanekbartelsspline2( positions_ptr, len(positions), tcb_ptr, len(tcb), closed, ), _lib.asdf_cubiccurve2_free) super().__init__(ptr)
def __init__(self, values, slopes=None, grid=None): # TODO: code re-use? values = _np.ascontiguousarray(values, dtype='float32') if values.ndim != 1: raise ValueError("Values must be one-dimensional") if grid is None: grid = _np.arange(len(values), dtype='float32') grid = _np.ascontiguousarray(grid, dtype='float32') if grid.ndim != 1: raise ValueError("Grid must be one-dimensional") values_ptr = _ffi.from_buffer('float[]', values) grid_ptr = _ffi.from_buffer('float[]', grid) if slopes is None: ptr = _ffi.gc( _lib.asdf_monotonecubic( values_ptr, len(values), grid_ptr, len(grid), ), _lib.asdf_monotonecubic_free) else: # TODO: code re-use? slopes = _np.ascontiguousarray(slopes, dtype='float32') if slopes.ndim != 1: raise ValueError("Slopes must be one-dimensional") slopes_ptr = _ffi.from_buffer('float[]', slopes) ptr = _ffi.gc( _lib.asdf_monotonecubic_with_slopes( values_ptr, len(values), slopes_ptr, len(slopes), grid_ptr, len(grid), ), _lib.asdf_monotonecubic_free) if ptr == _ffi.NULL: raise ValueError(_ffi.string(_lib.asdf_last_error()).decode()) self._monotone_ptr = ptr super().__init__(_lib.asdf_monotonecubic_inner(ptr))
def __init__(self, values, slopes=None, grid=None, closed=False): values = _np.ascontiguousarray(values, dtype='float32') if values.ndim != 1: raise ValueError("Values must be one-dimensional") if grid is None: grid = _np.arange(len(values) + closed, dtype='float32') grid = _np.ascontiguousarray(grid, dtype='float32') if grid.ndim != 1: raise ValueError("Grid must be one-dimensional") values_ptr = _ffi.from_buffer('float[]', values) grid_ptr = _ffi.from_buffer('float[]', grid) if slopes is None: ptr = _ffi.gc( _lib.asdf_shapepreservingcubicspline( values_ptr, len(values), grid_ptr, len(grid), closed, ), _lib.asdf_cubiccurve1_free) else: slopes = _np.ascontiguousarray(slopes, dtype='float32') if slopes.ndim != 1: raise ValueError("Slopes must be one-dimensional") slopes_ptr = _ffi.from_buffer('float[]', slopes) ptr = _ffi.gc( _lib.asdf_shapepreservingcubicspline_with_slopes( values_ptr, len(values), slopes_ptr, len(slopes), grid_ptr, len(grid), closed, ), _lib.asdf_cubiccurve1_free) super().__init__(ptr)
def __init__(self, data): positions = [] times = [] speeds = [] tcb = [] closed = False for vertex in data: vertex = dict(vertex) # Make a copy position = vertex.pop('position', None) if position is None: raise ValueError('every vertex must have a position') time = vertex.pop('time', _np.nan) if not _np.isscalar(time): raise TypeError('time values must be scalars') times.append(time) if position == 'closed': if vertex: raise ValueError( 'when position is "closed", only time is allowed') closed = True break position = _np.asarray(position, dtype='float32') if position.ndim != 1: raise ValueError('positions must be one-dimensional') if len(position) == 2: position = _np.append(position, 0) if len(position) != 3: raise ValueError('positions must be 2- or 3-dimensional') positions.append(position) speed = vertex.pop('speed', _np.nan) if not _np.isscalar(speed): raise TypeError('speed values must be scalars') speeds.append(speed) tension = vertex.pop('tension', 0) if not _np.isscalar(tension): raise TypeError('tension values must be scalars') continuity = vertex.pop('continuity', 0) if not _np.isscalar(continuity): raise TypeError('continuity values must be scalars') bias = vertex.pop('bias', 0) if not _np.isscalar(bias): raise TypeError('bias values must be scalars') tcb.append((tension, continuity, bias)) if vertex: raise ValueError('invalid key(s): {}'.format(set(vertex))) if len(positions) < 2: raise ValueError('at least two vertices are needed') if not closed: assert len(tcb) >= 2 if tcb.pop(0) != (0, 0, 0): raise ValueError( 'first vertex cannot have tension/continuity/bias ' '(except for closed curves') if tcb.pop(-1) != (0, 0, 0): raise ValueError( 'last vertex cannot have tension/continuity/bias ' '(except for closed curves)') positions, positions_ptr = _make_buffer(3, positions) if _np.isnan(times[0]): # NB: NaN <= 0 returns False if any(t <= 0 for t in times): raise ValueError('first time defaults to 0 if other times > 0') times[0] = 0 times, times_ptr = _make_buffer(1, times) speeds, speeds_ptr = _make_buffer(1, speeds) tcb = _np.ascontiguousarray(tcb, dtype='float32') tcb_ptr = _ffi.from_buffer('float[]', tcb) ptr = _ffi.gc( _lib.asdf_asdfposspline3( positions_ptr, len(positions), times_ptr, len(times), speeds_ptr, len(speeds), tcb_ptr, len(tcb), closed, ), _lib.asdf_asdfposspline3_free) super().__init__(ptr)
def __init__(self, data): positions = [] times = [] speeds = [] tcb = [] closed = False for vertex in data: vertex = dict(vertex) # Make a copy position = vertex.pop('position', None) if position is None: raise ValueError('Every vertex must have a position') time = vertex.pop('time', _np.nan) if not _np.isscalar(time): raise TypeError('Time values must be scalars') times.append(time) if position == 'closed': if vertex: raise ValueError( 'When position is "closed", only time is allowed') closed = True break position = _np.asarray(position, dtype='float32') if position.ndim != 1: raise ValueError("Positions must be one-dimensional") if len(position) == 2: position = _np.append(position, 0) if len(position) != 3: raise ValueError("Positions must be 2- or 3-dimensional") positions.append(position) speed = vertex.pop('speed', _np.nan) if not _np.isscalar(speed): raise TypeError('Speed values must be scalars') speeds.append(speed) tension = vertex.pop('tension', 0) if not _np.isscalar(tension): raise TypeError('Tension values must be scalars') continuity = vertex.pop('continuity', 0) if not _np.isscalar(continuity): raise TypeError('Continuity values must be scalars') bias = vertex.pop('bias', 0) if not _np.isscalar(bias): raise TypeError('Bias values must be scalars') tcb.append((tension, continuity, bias)) if vertex: raise ValueError('Invalid key(s): {}'.format(set(vertex))) if len(positions) < 2: raise ValueError('At least two vertices are needed') if not closed: assert len(tcb) >= 2 if tcb.pop(0) != (0, 0, 0): raise ValueError( 'First vertex cannot have tension/continuity/bias (except for closed curves' ) if tcb.pop(-1) != (0, 0, 0): raise ValueError( 'Last vertex cannot have tension/continuity/bias (except for closed curves)' ) positions = _np.ascontiguousarray(positions, dtype='float32') assert positions.ndim == 2 assert positions.shape[1] == 3 positions_ptr = _ffi.from_buffer('float[]', positions) times = _np.ascontiguousarray(times, dtype='float32') assert times.ndim == 1 times_ptr = _ffi.from_buffer('float[]', times) speeds = _np.ascontiguousarray(speeds, dtype='float32') assert speeds.ndim == 1 speeds_ptr = _ffi.from_buffer('float[]', speeds) tcb = _np.ascontiguousarray(tcb, dtype='float32') tcb_ptr = _ffi.from_buffer('float[]', tcb) ptr = _ffi.gc( _lib.asdf_asdfspline( positions_ptr, len(positions), times_ptr, len(times), speeds_ptr, len(speeds), tcb_ptr, len(tcb), closed, ), _lib.asdf_asdfspline_free) if ptr == _ffi.NULL: raise ValueError(_ffi.string(_lib.asdf_last_error()).decode()) self._ptr = ptr