python-plplot 5.13.0+dfsg-6ubuntu2 / usr / lib / python2.7 / dist-packages / plplotc.py

# This file was automatically generated by SWIG (http://www.swig.org).  It uses coding: utf-8
# Version 3.0.12
#
# Do not make changes to this file unless you know what you are doing--modify
# the SWIG interface file instead.

from sys import version_info as _swig_python_version_info
if _swig_python_version_info >= (2, 7, 0):
    def swig_import_helper():
        import importlib
        pkg = __name__.rpartition('.')[0]
        mname = '.'.join((pkg, '_plplotc')).lstrip('.')
        try:
            return importlib.import_module(mname)
        except ImportError:
            return importlib.import_module('_plplotc')
    _plplotc = swig_import_helper()
    del swig_import_helper
elif _swig_python_version_info >= (2, 6, 0):
    def swig_import_helper():
        from os.path import dirname
        import imp
        fp = None
        try:
            fp, pathname, description = imp.find_module('_plplotc', [dirname(__file__)])
        except ImportError:
            import _plplotc
            return _plplotc
        try:
            _mod = imp.load_module('_plplotc', fp, pathname, description)
        finally:
            if fp is not None:
                fp.close()
        return _mod
    _plplotc = swig_import_helper()
    del swig_import_helper
else:
    import _plplotc
del _swig_python_version_info

try:
    _swig_property = property
except NameError:
    pass  # Python < 2.2 doesn't have 'property'.

try:
    import builtins as __builtin__
except ImportError:
    import __builtin__

def _swig_setattr_nondynamic(self, class_type, name, value, static=1):
    if (name == "thisown"):
        return self.this.own(value)
    if (name == "this"):
        if type(value).__name__ == 'SwigPyObject':
            self.__dict__[name] = value
            return
    method = class_type.__swig_setmethods__.get(name, None)
    if method:
        return method(self, value)
    if (not static):
        if _newclass:
            object.__setattr__(self, name, value)
        else:
            self.__dict__[name] = value
    else:
        raise AttributeError("You cannot add attributes to %s" % self)


def _swig_setattr(self, class_type, name, value):
    return _swig_setattr_nondynamic(self, class_type, name, value, 0)


def _swig_getattr(self, class_type, name):
    if (name == "thisown"):
        return self.this.own()
    method = class_type.__swig_getmethods__.get(name, None)
    if method:
        return method(self)
    raise AttributeError("'%s' object has no attribute '%s'" % (class_type.__name__, name))


def _swig_repr(self):
    try:
        strthis = "proxy of " + self.this.__repr__()
    except __builtin__.Exception:
        strthis = ""
    return "<%s.%s; %s >" % (self.__class__.__module__, self.__class__.__name__, strthis,)

try:
    _object = object
    _newclass = 1
except __builtin__.Exception:
    class _object:
        pass
    _newclass = 0


def pltr0(x, y):
    return _plplotc.pltr0(x, y)
pltr0 = _plplotc.pltr0

def pltr1(x, y, cgrid):
    return _plplotc.pltr1(x, y, cgrid)
pltr1 = _plplotc.pltr1

def pltr2(x, y, cgrid):
    return _plplotc.pltr2(x, y, cgrid)
pltr2 = _plplotc.pltr2
PLESC_SET_RGB = _plplotc.PLESC_SET_RGB
PLESC_ALLOC_NCOL = _plplotc.PLESC_ALLOC_NCOL
PLESC_SET_LPB = _plplotc.PLESC_SET_LPB
PLESC_EXPOSE = _plplotc.PLESC_EXPOSE
PLESC_RESIZE = _plplotc.PLESC_RESIZE
PLESC_REDRAW = _plplotc.PLESC_REDRAW
PLESC_TEXT = _plplotc.PLESC_TEXT
PLESC_GRAPH = _plplotc.PLESC_GRAPH
PLESC_FILL = _plplotc.PLESC_FILL
PLESC_DI = _plplotc.PLESC_DI
PLESC_FLUSH = _plplotc.PLESC_FLUSH
PLESC_EH = _plplotc.PLESC_EH
PLESC_GETC = _plplotc.PLESC_GETC
PLESC_SWIN = _plplotc.PLESC_SWIN
PLESC_DOUBLEBUFFERING = _plplotc.PLESC_DOUBLEBUFFERING
PLESC_XORMOD = _plplotc.PLESC_XORMOD
PLESC_SET_COMPRESSION = _plplotc.PLESC_SET_COMPRESSION
PLESC_CLEAR = _plplotc.PLESC_CLEAR
PLESC_DASH = _plplotc.PLESC_DASH
PLESC_HAS_TEXT = _plplotc.PLESC_HAS_TEXT
PLESC_IMAGE = _plplotc.PLESC_IMAGE
PLESC_IMAGEOPS = _plplotc.PLESC_IMAGEOPS
PLESC_PL2DEVCOL = _plplotc.PLESC_PL2DEVCOL
PLESC_DEV2PLCOL = _plplotc.PLESC_DEV2PLCOL
PLESC_SETBGFG = _plplotc.PLESC_SETBGFG
PLESC_DEVINIT = _plplotc.PLESC_DEVINIT
PLESC_GETBACKEND = _plplotc.PLESC_GETBACKEND
PLESC_BEGIN_TEXT = _plplotc.PLESC_BEGIN_TEXT
PLESC_TEXT_CHAR = _plplotc.PLESC_TEXT_CHAR
PLESC_CONTROL_CHAR = _plplotc.PLESC_CONTROL_CHAR
PLESC_END_TEXT = _plplotc.PLESC_END_TEXT
PLESC_START_RASTERIZE = _plplotc.PLESC_START_RASTERIZE
PLESC_END_RASTERIZE = _plplotc.PLESC_END_RASTERIZE
PLESC_ARC = _plplotc.PLESC_ARC
PLESC_GRADIENT = _plplotc.PLESC_GRADIENT
PLESC_MODESET = _plplotc.PLESC_MODESET
PLESC_MODEGET = _plplotc.PLESC_MODEGET
PLESC_FIXASPECT = _plplotc.PLESC_FIXASPECT
PLESC_IMPORT_BUFFER = _plplotc.PLESC_IMPORT_BUFFER
PLESC_APPEND_BUFFER = _plplotc.PLESC_APPEND_BUFFER
PLESC_FLUSH_REMAINING_BUFFER = _plplotc.PLESC_FLUSH_REMAINING_BUFFER
PLTEXT_FONTCHANGE = _plplotc.PLTEXT_FONTCHANGE
PLTEXT_SUPERSCRIPT = _plplotc.PLTEXT_SUPERSCRIPT
PLTEXT_SUBSCRIPT = _plplotc.PLTEXT_SUBSCRIPT
PLTEXT_BACKCHAR = _plplotc.PLTEXT_BACKCHAR
PLTEXT_OVERLINE = _plplotc.PLTEXT_OVERLINE
PLTEXT_UNDERLINE = _plplotc.PLTEXT_UNDERLINE
ZEROW2B = _plplotc.ZEROW2B
ZEROW2D = _plplotc.ZEROW2D
ONEW2B = _plplotc.ONEW2B
ONEW2D = _plplotc.ONEW2D
PLSWIN_DEVICE = _plplotc.PLSWIN_DEVICE
PLSWIN_WORLD = _plplotc.PLSWIN_WORLD
PL_X_AXIS = _plplotc.PL_X_AXIS
PL_Y_AXIS = _plplotc.PL_Y_AXIS
PL_Z_AXIS = _plplotc.PL_Z_AXIS
PL_OPT_ENABLED = _plplotc.PL_OPT_ENABLED
PL_OPT_ARG = _plplotc.PL_OPT_ARG
PL_OPT_NODELETE = _plplotc.PL_OPT_NODELETE
PL_OPT_INVISIBLE = _plplotc.PL_OPT_INVISIBLE
PL_OPT_DISABLED = _plplotc.PL_OPT_DISABLED
PL_OPT_FUNC = _plplotc.PL_OPT_FUNC
PL_OPT_BOOL = _plplotc.PL_OPT_BOOL
PL_OPT_INT = _plplotc.PL_OPT_INT
PL_OPT_FLOAT = _plplotc.PL_OPT_FLOAT
PL_OPT_STRING = _plplotc.PL_OPT_STRING
PL_PARSE_PARTIAL = _plplotc.PL_PARSE_PARTIAL
PL_PARSE_FULL = _plplotc.PL_PARSE_FULL
PL_PARSE_QUIET = _plplotc.PL_PARSE_QUIET
PL_PARSE_NODELETE = _plplotc.PL_PARSE_NODELETE
PL_PARSE_SHOWALL = _plplotc.PL_PARSE_SHOWALL
PL_PARSE_OVERRIDE = _plplotc.PL_PARSE_OVERRIDE
PL_PARSE_NOPROGRAM = _plplotc.PL_PARSE_NOPROGRAM
PL_PARSE_NODASH = _plplotc.PL_PARSE_NODASH
PL_PARSE_SKIP = _plplotc.PL_PARSE_SKIP
PL_FCI_MARK = _plplotc.PL_FCI_MARK
PL_FCI_IMPOSSIBLE = _plplotc.PL_FCI_IMPOSSIBLE
PL_FCI_HEXDIGIT_MASK = _plplotc.PL_FCI_HEXDIGIT_MASK
PL_FCI_HEXPOWER_MASK = _plplotc.PL_FCI_HEXPOWER_MASK
PL_FCI_HEXPOWER_IMPOSSIBLE = _plplotc.PL_FCI_HEXPOWER_IMPOSSIBLE
PL_FCI_FAMILY = _plplotc.PL_FCI_FAMILY
PL_FCI_STYLE = _plplotc.PL_FCI_STYLE
PL_FCI_WEIGHT = _plplotc.PL_FCI_WEIGHT
PL_FCI_SANS = _plplotc.PL_FCI_SANS
PL_FCI_SERIF = _plplotc.PL_FCI_SERIF
PL_FCI_MONO = _plplotc.PL_FCI_MONO
PL_FCI_SCRIPT = _plplotc.PL_FCI_SCRIPT
PL_FCI_SYMBOL = _plplotc.PL_FCI_SYMBOL
PL_FCI_UPRIGHT = _plplotc.PL_FCI_UPRIGHT
PL_FCI_ITALIC = _plplotc.PL_FCI_ITALIC
PL_FCI_OBLIQUE = _plplotc.PL_FCI_OBLIQUE
PL_FCI_MEDIUM = _plplotc.PL_FCI_MEDIUM
PL_FCI_BOLD = _plplotc.PL_FCI_BOLD
PL_MAXKEY = _plplotc.PL_MAXKEY
PL_MASK_SHIFT = _plplotc.PL_MASK_SHIFT
PL_MASK_CAPS = _plplotc.PL_MASK_CAPS
PL_MASK_CONTROL = _plplotc.PL_MASK_CONTROL
PL_MASK_ALT = _plplotc.PL_MASK_ALT
PL_MASK_NUM = _plplotc.PL_MASK_NUM
PL_MASK_ALTGR = _plplotc.PL_MASK_ALTGR
PL_MASK_WIN = _plplotc.PL_MASK_WIN
PL_MASK_SCROLL = _plplotc.PL_MASK_SCROLL
PL_MASK_BUTTON1 = _plplotc.PL_MASK_BUTTON1
PL_MASK_BUTTON2 = _plplotc.PL_MASK_BUTTON2
PL_MASK_BUTTON3 = _plplotc.PL_MASK_BUTTON3
PL_MASK_BUTTON4 = _plplotc.PL_MASK_BUTTON4
PL_MASK_BUTTON5 = _plplotc.PL_MASK_BUTTON5
PL_MAXWINDOWS = _plplotc.PL_MAXWINDOWS
PL_NOTSET = _plplotc.PL_NOTSET
PLESC_DOUBLEBUFFERING_ENABLE = _plplotc.PLESC_DOUBLEBUFFERING_ENABLE
PLESC_DOUBLEBUFFERING_DISABLE = _plplotc.PLESC_DOUBLEBUFFERING_DISABLE
PLESC_DOUBLEBUFFERING_QUERY = _plplotc.PLESC_DOUBLEBUFFERING_QUERY
PL_BIN_DEFAULT = _plplotc.PL_BIN_DEFAULT
PL_BIN_CENTRED = _plplotc.PL_BIN_CENTRED
PL_BIN_NOEXPAND = _plplotc.PL_BIN_NOEXPAND
PL_BIN_NOEMPTY = _plplotc.PL_BIN_NOEMPTY
GRID_CSA = _plplotc.GRID_CSA
GRID_DTLI = _plplotc.GRID_DTLI
GRID_NNI = _plplotc.GRID_NNI
GRID_NNIDW = _plplotc.GRID_NNIDW
GRID_NNLI = _plplotc.GRID_NNLI
GRID_NNAIDW = _plplotc.GRID_NNAIDW
PL_HIST_DEFAULT = _plplotc.PL_HIST_DEFAULT
PL_HIST_NOSCALING = _plplotc.PL_HIST_NOSCALING
PL_HIST_IGNORE_OUTLIERS = _plplotc.PL_HIST_IGNORE_OUTLIERS
PL_HIST_NOEXPAND = _plplotc.PL_HIST_NOEXPAND
PL_HIST_NOEMPTY = _plplotc.PL_HIST_NOEMPTY
PL_POSITION_LEFT = _plplotc.PL_POSITION_LEFT
PL_POSITION_RIGHT = _plplotc.PL_POSITION_RIGHT
PL_POSITION_TOP = _plplotc.PL_POSITION_TOP
PL_POSITION_BOTTOM = _plplotc.PL_POSITION_BOTTOM
PL_POSITION_INSIDE = _plplotc.PL_POSITION_INSIDE
PL_POSITION_OUTSIDE = _plplotc.PL_POSITION_OUTSIDE
PL_POSITION_VIEWPORT = _plplotc.PL_POSITION_VIEWPORT
PL_POSITION_SUBPAGE = _plplotc.PL_POSITION_SUBPAGE
PL_LEGEND_NONE = _plplotc.PL_LEGEND_NONE
PL_LEGEND_COLOR_BOX = _plplotc.PL_LEGEND_COLOR_BOX
PL_LEGEND_LINE = _plplotc.PL_LEGEND_LINE
PL_LEGEND_SYMBOL = _plplotc.PL_LEGEND_SYMBOL
PL_LEGEND_TEXT_LEFT = _plplotc.PL_LEGEND_TEXT_LEFT
PL_LEGEND_BACKGROUND = _plplotc.PL_LEGEND_BACKGROUND
PL_LEGEND_BOUNDING_BOX = _plplotc.PL_LEGEND_BOUNDING_BOX
PL_LEGEND_ROW_MAJOR = _plplotc.PL_LEGEND_ROW_MAJOR
PL_COLORBAR_LABEL_LEFT = _plplotc.PL_COLORBAR_LABEL_LEFT
PL_COLORBAR_LABEL_RIGHT = _plplotc.PL_COLORBAR_LABEL_RIGHT
PL_COLORBAR_LABEL_TOP = _plplotc.PL_COLORBAR_LABEL_TOP
PL_COLORBAR_LABEL_BOTTOM = _plplotc.PL_COLORBAR_LABEL_BOTTOM
PL_COLORBAR_IMAGE = _plplotc.PL_COLORBAR_IMAGE
PL_COLORBAR_SHADE = _plplotc.PL_COLORBAR_SHADE
PL_COLORBAR_GRADIENT = _plplotc.PL_COLORBAR_GRADIENT
PL_COLORBAR_CAP_NONE = _plplotc.PL_COLORBAR_CAP_NONE
PL_COLORBAR_CAP_LOW = _plplotc.PL_COLORBAR_CAP_LOW
PL_COLORBAR_CAP_HIGH = _plplotc.PL_COLORBAR_CAP_HIGH
PL_COLORBAR_SHADE_LABEL = _plplotc.PL_COLORBAR_SHADE_LABEL
PL_COLORBAR_ORIENT_RIGHT = _plplotc.PL_COLORBAR_ORIENT_RIGHT
PL_COLORBAR_ORIENT_TOP = _plplotc.PL_COLORBAR_ORIENT_TOP
PL_COLORBAR_ORIENT_LEFT = _plplotc.PL_COLORBAR_ORIENT_LEFT
PL_COLORBAR_ORIENT_BOTTOM = _plplotc.PL_COLORBAR_ORIENT_BOTTOM
PL_COLORBAR_BACKGROUND = _plplotc.PL_COLORBAR_BACKGROUND
PL_COLORBAR_BOUNDING_BOX = _plplotc.PL_COLORBAR_BOUNDING_BOX
PL_DRAWMODE_UNKNOWN = _plplotc.PL_DRAWMODE_UNKNOWN
PL_DRAWMODE_DEFAULT = _plplotc.PL_DRAWMODE_DEFAULT
PL_DRAWMODE_REPLACE = _plplotc.PL_DRAWMODE_REPLACE
PL_DRAWMODE_XOR = _plplotc.PL_DRAWMODE_XOR
DRAW_LINEX = _plplotc.DRAW_LINEX
DRAW_LINEY = _plplotc.DRAW_LINEY
DRAW_LINEXY = _plplotc.DRAW_LINEXY
MAG_COLOR = _plplotc.MAG_COLOR
BASE_CONT = _plplotc.BASE_CONT
TOP_CONT = _plplotc.TOP_CONT
SURF_CONT = _plplotc.SURF_CONT
DRAW_SIDES = _plplotc.DRAW_SIDES
FACETED = _plplotc.FACETED
MESH = _plplotc.MESH
class PLGraphicsIn(_object):
    __swig_setmethods__ = {}
    __setattr__ = lambda self, name, value: _swig_setattr(self, PLGraphicsIn, name, value)
    __swig_getmethods__ = {}
    __getattr__ = lambda self, name: _swig_getattr(self, PLGraphicsIn, name)
    __repr__ = _swig_repr
    __swig_setmethods__["type"] = _plplotc.PLGraphicsIn_type_set
    __swig_getmethods__["type"] = _plplotc.PLGraphicsIn_type_get
    if _newclass:
        type = _swig_property(_plplotc.PLGraphicsIn_type_get, _plplotc.PLGraphicsIn_type_set)
    __swig_setmethods__["state"] = _plplotc.PLGraphicsIn_state_set
    __swig_getmethods__["state"] = _plplotc.PLGraphicsIn_state_get
    if _newclass:
        state = _swig_property(_plplotc.PLGraphicsIn_state_get, _plplotc.PLGraphicsIn_state_set)
    __swig_setmethods__["keysym"] = _plplotc.PLGraphicsIn_keysym_set
    __swig_getmethods__["keysym"] = _plplotc.PLGraphicsIn_keysym_get
    if _newclass:
        keysym = _swig_property(_plplotc.PLGraphicsIn_keysym_get, _plplotc.PLGraphicsIn_keysym_set)
    __swig_setmethods__["button"] = _plplotc.PLGraphicsIn_button_set
    __swig_getmethods__["button"] = _plplotc.PLGraphicsIn_button_get
    if _newclass:
        button = _swig_property(_plplotc.PLGraphicsIn_button_get, _plplotc.PLGraphicsIn_button_set)
    __swig_setmethods__["subwindow"] = _plplotc.PLGraphicsIn_subwindow_set
    __swig_getmethods__["subwindow"] = _plplotc.PLGraphicsIn_subwindow_get
    if _newclass:
        subwindow = _swig_property(_plplotc.PLGraphicsIn_subwindow_get, _plplotc.PLGraphicsIn_subwindow_set)
    __swig_setmethods__["string"] = _plplotc.PLGraphicsIn_string_set
    __swig_getmethods__["string"] = _plplotc.PLGraphicsIn_string_get
    if _newclass:
        string = _swig_property(_plplotc.PLGraphicsIn_string_get, _plplotc.PLGraphicsIn_string_set)
    __swig_setmethods__["pX"] = _plplotc.PLGraphicsIn_pX_set
    __swig_getmethods__["pX"] = _plplotc.PLGraphicsIn_pX_get
    if _newclass:
        pX = _swig_property(_plplotc.PLGraphicsIn_pX_get, _plplotc.PLGraphicsIn_pX_set)
    __swig_setmethods__["pY"] = _plplotc.PLGraphicsIn_pY_set
    __swig_getmethods__["pY"] = _plplotc.PLGraphicsIn_pY_get
    if _newclass:
        pY = _swig_property(_plplotc.PLGraphicsIn_pY_get, _plplotc.PLGraphicsIn_pY_set)
    __swig_setmethods__["dX"] = _plplotc.PLGraphicsIn_dX_set
    __swig_getmethods__["dX"] = _plplotc.PLGraphicsIn_dX_get
    if _newclass:
        dX = _swig_property(_plplotc.PLGraphicsIn_dX_get, _plplotc.PLGraphicsIn_dX_set)
    __swig_setmethods__["dY"] = _plplotc.PLGraphicsIn_dY_set
    __swig_getmethods__["dY"] = _plplotc.PLGraphicsIn_dY_get
    if _newclass:
        dY = _swig_property(_plplotc.PLGraphicsIn_dY_get, _plplotc.PLGraphicsIn_dY_set)
    __swig_setmethods__["wX"] = _plplotc.PLGraphicsIn_wX_set
    __swig_getmethods__["wX"] = _plplotc.PLGraphicsIn_wX_get
    if _newclass:
        wX = _swig_property(_plplotc.PLGraphicsIn_wX_get, _plplotc.PLGraphicsIn_wX_set)
    __swig_setmethods__["wY"] = _plplotc.PLGraphicsIn_wY_set
    __swig_getmethods__["wY"] = _plplotc.PLGraphicsIn_wY_get
    if _newclass:
        wY = _swig_property(_plplotc.PLGraphicsIn_wY_get, _plplotc.PLGraphicsIn_wY_set)

    def __init__(self):
        this = _plplotc.new_PLGraphicsIn()
        try:
            self.this.append(this)
        except __builtin__.Exception:
            self.this = this
    __swig_destroy__ = _plplotc.delete_PLGraphicsIn
    __del__ = lambda self: None
PLGraphicsIn_swigregister = _plplotc.PLGraphicsIn_swigregister
PLGraphicsIn_swigregister(PLGraphicsIn)


def plsxwin(window_id):
    return _plplotc.plsxwin(window_id)
plsxwin = _plplotc.plsxwin

def pl_setcontlabelformat(lexp, sigdig):
    """
    Set format of numerical label for contours

    DESCRIPTION:

        Set format of numerical label for contours.

        Redacted form: pl_setcontlabelformat(lexp, sigdig)

        This function is used example 9.



    SYNOPSIS:

    pl_setcontlabelformat(lexp, sigdig)

    ARGUMENTS:

        lexp (PLINT, input) :    If the contour numerical label is greater
            than 10^(lexp) or less than 10^(-lexp), then the exponential
            format is used.  Default value of lexp is 4.

        sigdig (PLINT, input) :    Number of significant digits.  Default
            value is 2.

    """
    return _plplotc.pl_setcontlabelformat(lexp, sigdig)

def pl_setcontlabelparam(offset, size, spacing, active):
    """
    Set parameters of contour labelling other than format of numerical label

    DESCRIPTION:

        Set parameters of contour labelling other than those handled by
        pl_setcontlabelformat.

        Redacted form: pl_setcontlabelparam(offset, size, spacing, active)

        This function is used in example 9.



    SYNOPSIS:

    pl_setcontlabelparam(offset, size, spacing, active)

    ARGUMENTS:

        offset (PLFLT, input) :    Offset of label from contour line (if set
            to 0.0, labels are printed on the lines).  Default value is 0.006.

        size (PLFLT, input) :    Font height for contour labels (normalized).
            Default value is 0.3.

        spacing (PLFLT, input) :    Spacing parameter for contour labels.
            Default value is 0.1.

        active (PLINT, input) :    Activate labels.  Set to 1 if you want
            contour labels on. Default is off (0).

    """
    return _plplotc.pl_setcontlabelparam(offset, size, spacing, active)

def pladv(page):
    """
    Advance the (sub-)page

    DESCRIPTION:

        Advances to the next subpage if sub=0, performing a page advance if
        there are no remaining subpages on the current page.  If subpages
        aren't being used, pladv(0) will always advance the page.  If page>0,
        PLplot switches to the specified subpage.  Note that this allows you
        to overwrite a plot on the specified subpage; if this is not what you
        intended, use pleop followed by plbop to first advance the page.  This
        routine is called automatically (with page=0) by plenv, but if plenv
        is not used, pladv must be called after initializing PLplot but before
        defining the viewport.

        Redacted form: pladv(page)

        This function is used in examples 1, 2, 4, 6-12, 14-18, 20, 21, 23-27,
        29, and 31.



    SYNOPSIS:

    pladv(page)

    ARGUMENTS:

        page (PLINT, input) :    Specifies the subpage number (starting from 1
            in the top left corner and increasing along the rows) to which to
            advance.  Set to zero to advance to the next subpage (or to the
            next page if subpages are not being used).

    """
    return _plplotc.pladv(page)

def plarc(x, y, a, b, angle1, angle2, rotate, fill):
    """
    Draw a circular or elliptical arc

    DESCRIPTION:

        Draw a possibly filled arc centered at x, y with semimajor axis a and
        semiminor axis b, starting at angle1 and ending at angle2.

        Redacted form: General: plarc(x, y, a, b, angle1, angle2, rotate,
        fill)


        This function is used in examples 3 and 27.



    SYNOPSIS:

    plarc(x, y, a, b, angle1, angle2, rotate, fill)

    ARGUMENTS:

        x (PLFLT, input) :    X coordinate of arc center.

        y (PLFLT, input) :    Y coordinate of arc center.

        a (PLFLT, input) :    Length of the semimajor axis of the arc.

        b (PLFLT, input) :    Length of the semiminor axis of the arc.

        angle1 (PLFLT, input) :    Starting angle of the arc relative to the
            semimajor axis.

        angle2 (PLFLT, input) :    Ending angle of the arc relative to the
            semimajor axis.

        rotate (PLFLT, input) :    Angle of the semimajor axis relative to the
            X-axis.

        fill (PLBOOL, input) :    Draw a filled arc.

    """
    return _plplotc.plarc(x, y, a, b, angle1, angle2, rotate, fill)

def plaxes(x0, y0, xopt, xtick, nxsub, yopt, ytick, nysub):
    """
    Draw a box with axes, etc. with arbitrary origin

    DESCRIPTION:

        Draws a box around the currently defined viewport with arbitrary
        world-coordinate origin specified by x0 and y0 and labels it with
        world coordinate values appropriate to the window.  Thus plaxes should
        only be called after defining both viewport and window.  The ascii
        character strings xopt and yopt specify how the box should be drawn as
        described below.  If ticks and/or subticks are to be drawn for a
        particular axis, the tick intervals and number of subintervals may be
        specified explicitly, or they may be defaulted by setting the
        appropriate arguments to zero.

        Redacted form: General: plaxes(x0, y0, xopt, xtick, nxsub, yopt,
        ytick, nysub)
                Perl/PDL: plaxes(x0, y0, xtick, nxsub, ytick, nysub, xopt,
        yopt)


        This function is not used in any examples.



    SYNOPSIS:

    plaxes(x0, y0, xopt, xtick, nxsub, yopt, ytick, nysub)

    ARGUMENTS:

        x0 (PLFLT, input) :    World X coordinate of origin.

        y0 (PLFLT, input) :    World Y coordinate of origin.

        xopt (PLCHAR_VECTOR, input) :    An ascii character string specifying
            options for the x axis.  The string can include any combination of
            the following letters (upper or lower case) in any order: a: Draws
            axis, X-axis is horizontal line (y=0), and Y-axis is vertical line
            (x=0).
                b: Draws bottom (X) or left (Y) edge of frame.
                c: Draws top (X) or right (Y) edge of frame.
                d: Plot labels as date / time. Values are assumed to be
                seconds since the epoch (as used by gmtime).
                f:  Always use fixed point numeric labels.
                g: Draws a grid at the major tick interval.
                h: Draws a grid at the minor tick interval.
                i: Inverts tick marks, so they are drawn outwards, rather than
                inwards.
                l: Labels axis logarithmically.  This only affects the labels,
                not the data, and so it is necessary to compute the logarithms
                of data points before passing them to any of the drawing
                routines.
                m: Writes numeric labels at major tick intervals in the
                unconventional location (above box for X, right of box for Y).
                n: Writes numeric labels at major tick intervals in the
                conventional location (below box for X, left of box for Y).
                o: Use custom labelling function to generate axis label text.
                The custom labelling function can be defined with the
                plslabelfunc command.
                s: Enables subticks between major ticks, only valid if t is
                also specified.
                t: Draws major ticks.
                u: Exactly like "b" except don't draw edge line.
                w: Exactly like "c" except don't draw edge line.
                x: Exactly like "t" (including the side effect of the
                numerical labels for the major ticks) except exclude drawing
                the major and minor tick marks.


        xtick (PLFLT, input) :    World coordinate interval between major
            ticks on the x axis. If it is set to zero, PLplot automatically
            generates a suitable tick interval.

        nxsub (PLINT, input) :    Number of subintervals between major x axis
            ticks for minor ticks.  If it is set to zero, PLplot automatically
            generates a suitable minor tick interval.

        yopt (PLCHAR_VECTOR, input) :    An ascii character string specifying
            options for the y axis.  The string can include any combination of
            the letters defined above for xopt, and in addition may contain:
            v: Write numeric labels for the y axis parallel to the base of the
            graph, rather than parallel to the axis.


        ytick (PLFLT, input) :    World coordinate interval between major
            ticks on the y axis. If it is set to zero, PLplot automatically
            generates a suitable tick interval.

        nysub (PLINT, input) :    Number of subintervals between major y axis
            ticks for minor ticks.  If it is set to zero, PLplot automatically
            generates a suitable minor tick interval.

    """
    return _plplotc.plaxes(x0, y0, xopt, xtick, nxsub, yopt, ytick, nysub)

def plbin(n, ArrayCk, center):
    """
    Plot a histogram from binned data

    DESCRIPTION:

        Plots a histogram consisting of nbin bins.  The value associated with
        the i'th bin is placed in x[i], and the number of points in the bin is
        placed in y[i].  For proper operation, the values in x[i] must form a
        strictly increasing sequence.  By default, x[i] is the left-hand edge
        of the i'th bin. If opt=PL_BIN_CENTRED is used, the bin boundaries are
        placed midway between the values in the x vector.  Also see plhist for
        drawing histograms from unbinned data.

        Redacted form: General: plbin(x, y, opt)
                Perl/PDL: plbin(nbin, x, y, opt)
                Python: plbin(nbin, x, y, opt)


        This function is not used in any examples.



    SYNOPSIS:

    plbin(nbin, x, y, opt)

    ARGUMENTS:

        nbin (PLINT, input) :    Number of bins (i.e., number of values in x
            and y vectors.)

        x (PLFLT_VECTOR, input) :    A vector containing values associated
            with bins.  These must form a strictly increasing sequence.

        y (PLFLT_VECTOR, input) :    A vector containing a number which is
            proportional to the number of points in each bin.  This is a PLFLT
            (instead of PLINT) vector so as to allow histograms of
            probabilities, etc.

        opt (PLINT, input) :    Is a combination of several flags:
            opt=PL_BIN_DEFAULT: The x represent the lower bin boundaries, the
            outer bins are expanded to fill up the entire x-axis and bins of
            zero height are simply drawn.
                opt=PL_BIN_CENTRED|...: The bin boundaries are to be midway
                between the x values. If the values in x are equally spaced,
                the values are the center values of the bins.
                opt=PL_BIN_NOEXPAND|...: The outer bins are drawn with equal
                size as the ones inside.
                opt=PL_BIN_NOEMPTY|...: Bins with zero height are not drawn
                (there is a gap for such bins).

    """
    return _plplotc.plbin(n, ArrayCk, center)

def plbtime(ctime):
    """
    Calculate broken-down time from continuous time for the current stream

    DESCRIPTION:

        Calculate broken-down time; year, month, day, hour, min, sec; from
        continuous time, ctime for the current stream.  This function is the
        inverse of plctime.

        The PLplot definition of broken-down time is a calendar time that
        completely ignores all time zone offsets, i.e., it is the user's
        responsibility to apply those offsets (if so desired) before using the
        PLplot time API.  By default broken-down time is defined using the
        proleptic Gregorian calendar without the insertion of leap seconds and
        continuous time is defined as the number of seconds since the Unix
        epoch of 1970-01-01T00:00:00Z. However, other definitions of
        broken-down and continuous time are possible, see plconfigtime.

        Redacted form: General: plbtime(year, month, day, hour, min, sec,
        ctime)
                Perl/PDL: Not available?


        This function is used in example 29.



    SYNOPSIS:

    plbtime(year, month, day, hour, min, sec, ctime)

    ARGUMENTS:

        year (PLINT_NC_SCALAR, output) :    Returned value of years with
            positive values corresponding to CE (i.e., 1 = 1 CE, etc.) and
            non-negative values corresponding to BCE (e.g., 0 = 1 BCE, -1 = 2
            BCE, etc.)

        month (PLINT_NC_SCALAR, output) :    Returned value of month within
            the year in the range from 0 (January) to 11 (December).

        day (PLINT_NC_SCALAR, output) :    Returned value of day within the
            month in the range from 1 to 31.

        hour (PLINT_NC_SCALAR, output) :    Returned value of hour within the
            day in the range from 0 to 23.

        min (PLINT_NC_SCALAR, output) :    Returned value of minute within the
            hour in the range from 0 to 59

        sec (PLFLT_NC_SCALAR, output) :    Returned value of second within the
            minute in range from 0. to 60.

        ctime (PLFLT, input) :    Continuous time from which the broken-down
            time is calculated.

    """
    return _plplotc.plbtime(ctime)

def plbop():
    """
    Begin a new page

    DESCRIPTION:

        Begins a new page.  For a file driver, the output file is opened if
        necessary.  Advancing the page via pleop and plbop is useful when a
        page break is desired at a particular point when plotting to subpages.
         Another use for pleop and plbop is when plotting pages to different
        files, since you can manually set the file name by calling plsfnam
        after the call to pleop. (In fact some drivers may only support a
        single page per file, making this a necessity.)  One way to handle
        this case automatically is to page advance via pladv, but enable
        familying (see plsfam) with a small limit on the file size so that a
        new family member file will be created on each page break.

        Redacted form: plbop()

        This function is used in examples 2 and 20.



    SYNOPSIS:

    plbop()

    """
    return _plplotc.plbop()

def plbox(xopt, xtick, nxsub, yopt, ytick, nysub):
    """
    Draw a box with axes, etc

    DESCRIPTION:

        Draws a box around the currently defined viewport, and labels it with
        world coordinate values appropriate to the window.  Thus plbox should
        only be called after defining both viewport and window.  The ascii
        character strings xopt and yopt specify how the box should be drawn as
        described below.  If ticks and/or subticks are to be drawn for a
        particular axis, the tick intervals and number of subintervals may be
        specified explicitly, or they may be defaulted by setting the
        appropriate arguments to zero.

        Redacted form: General: plbox(xopt, xtick, nxsub, yopt, ytick, nysub)
                Perl/PDL: plbox(xtick, nxsub, ytick, nysub, xopt, yopt)


        This function is used in examples 1, 2, 4, 6, 6-12, 14-18, 21, 23-26,
        and 29.



    SYNOPSIS:

    plbox(xopt, xtick, nxsub, yopt, ytick, nysub)

    ARGUMENTS:

        xopt (PLCHAR_VECTOR, input) :    An ascii character string specifying
            options for the x axis.  The string can include any combination of
            the following letters (upper or lower case) in any order: a: Draws
            axis, X-axis is horizontal line (y=0), and Y-axis is vertical line
            (x=0).
                b: Draws bottom (X) or left (Y) edge of frame.
                c: Draws top (X) or right (Y) edge of frame.
                d: Plot labels as date / time. Values are assumed to be
                seconds since the epoch (as used by gmtime).
                f:  Always use fixed point numeric labels.
                g: Draws a grid at the major tick interval.
                h: Draws a grid at the minor tick interval.
                i: Inverts tick marks, so they are drawn outwards, rather than
                inwards.
                l: Labels axis logarithmically.  This only affects the labels,
                not the data, and so it is necessary to compute the logarithms
                of data points before passing them to any of the drawing
                routines.
                m: Writes numeric labels at major tick intervals in the
                unconventional location (above box for X, right of box for Y).
                n: Writes numeric labels at major tick intervals in the
                conventional location (below box for X, left of box for Y).
                o: Use custom labelling function to generate axis label text.
                The custom labelling function can be defined with the
                plslabelfunc command.
                s: Enables subticks between major ticks, only valid if t is
                also specified.
                t: Draws major ticks.
                u: Exactly like "b" except don't draw edge line.
                w: Exactly like "c" except don't draw edge line.
                x: Exactly like "t" (including the side effect of the
                numerical labels for the major ticks) except exclude drawing
                the major and minor tick marks.


        xtick (PLFLT, input) :    World coordinate interval between major
            ticks on the x axis. If it is set to zero, PLplot automatically
            generates a suitable tick interval.

        nxsub (PLINT, input) :    Number of subintervals between major x axis
            ticks for minor ticks.  If it is set to zero, PLplot automatically
            generates a suitable minor tick interval.

        yopt (PLCHAR_VECTOR, input) :    An ascii character string specifying
            options for the y axis.  The string can include any combination of
            the letters defined above for xopt, and in addition may contain:
            v: Write numeric labels for the y axis parallel to the base of the
            graph, rather than parallel to the axis.


        ytick (PLFLT, input) :    World coordinate interval between major
            ticks on the y axis. If it is set to zero, PLplot automatically
            generates a suitable tick interval.

        nysub (PLINT, input) :    Number of subintervals between major y axis
            ticks for minor ticks.  If it is set to zero, PLplot automatically
            generates a suitable minor tick interval.

    """
    return _plplotc.plbox(xopt, xtick, nxsub, yopt, ytick, nysub)

def plbox3(xopt, xlabel, xtick, nsubx, yopt, ylabel, ytick, nsuby, zopt, zlabel, ztick, nsubz):
    """
    Draw a box with axes, etc, in 3-d

    DESCRIPTION:

        Draws axes, numeric and text labels for a three-dimensional surface
        plot.  For a more complete description of three-dimensional plotting
        see the PLplot documentation.

        Redacted form: General: plbox3(xopt, xlabel, xtick, nxsub, yopt,
        ylabel, ytick, nysub, zopt, zlabel, ztick, nzsub)
                Perl/PDL: plbox3(xtick, nxsub, ytick, nysub, ztick, nzsub,
        xopt, xlabel, yopt, ylabel, zopt, zlabel)


        This function is used in examples 8, 11, 18, and 21.



    SYNOPSIS:

    plbox3(xopt, xlabel, xtick, nxsub, yopt, ylabel, ytick, nysub, zopt, zlabel, ztick, nzsub)

    ARGUMENTS:

        xopt (PLCHAR_VECTOR, input) :    An ascii character string specifying
            options for the x axis.  The string can include any combination of
            the following letters (upper or lower case) in any order: b: Draws
            axis at base, at height z=
        zmin where zmin is defined by call to plw3d.  This character must be
            specified in order to use any of the other options.
                d: Plot labels as date / time. Values are assumed to be
                seconds since the epoch (as used by gmtime).
                f: Always use fixed point numeric labels.
                i: Inverts tick marks, so they are drawn downwards, rather
                than upwards.
                l: Labels axis logarithmically.  This only affects the labels,
                not the data, and so it is necessary to compute the logarithms
                of data points before passing them to any of the drawing
                routines.
                n: Writes numeric labels at major tick intervals.
                o: Use custom labelling function to generate axis label text.
                The custom labelling function can be defined with the
                plslabelfunc command.
                s: Enables subticks between major ticks, only valid if t is
                also specified.
                t: Draws major ticks.
                u: If this is specified, the text label for the axis is
                written under the axis.


        xlabel (PLCHAR_VECTOR, input) :    A UTF-8 character string specifying
            the text label for the x axis.  It is only drawn if u is in the
            xopt string.

        xtick (PLFLT, input) :    World coordinate interval between major
            ticks on the x axis. If it is set to zero, PLplot automatically
            generates a suitable tick interval.

        nxsub (PLINT, input) :    Number of subintervals between major x axis
            ticks for minor ticks.  If it is set to zero, PLplot automatically
            generates a suitable minor tick interval.

        yopt (PLCHAR_VECTOR, input) :    An ascii character string specifying
            options for the y axis. The string is interpreted in the same way
            as xopt.

        ylabel (PLCHAR_VECTOR, input) :    A UTF-8 character string specifying
            the text label for the y axis.  It is only drawn if u is in the
            yopt string.

        ytick (PLFLT, input) :    World coordinate interval between major
            ticks on the y axis. If it is set to zero, PLplot automatically
            generates a suitable tick interval.

        nysub (PLINT, input) :    Number of subintervals between major y axis
            ticks for minor ticks.  If it is set to zero, PLplot automatically
            generates a suitable minor tick interval.

        zopt (PLCHAR_VECTOR, input) :    An ascii character string specifying
            options for the z axis. The string can include any combination of
            the following letters (upper or lower case) in any order: b: Draws
            z axis to the left of the surface plot.
                c: Draws z axis to the right of the surface plot.
                d: Draws grid lines parallel to the x-y plane behind the
                figure.  These lines are not drawn until after plot3d or
                plmesh are called because of the need for hidden line removal.
                e: Plot labels as date / time. Values are assumed to be
                seconds since the epoch (as used by gmtime).  Note this
                suboption is interpreted the same as the d suboption for xopt
                and yopt, but it has to be identified as e for zopt since d
                has already been used for the different purpose above.
                f: Always use fixed point numeric labels.
                i: Inverts tick marks, so they are drawn away from the center.
                l: Labels axis logarithmically.  This only affects the labels,
                not the data, and so it is necessary to compute the logarithms
                of data points before passing them to any of the drawing
                routines.
                m: Writes numeric labels at major tick intervals on the
                right-hand z axis.
                n: Writes numeric labels at major tick intervals on the
                left-hand z axis.
                o: Use custom labelling function to generate axis label text.
                The custom labelling function can be defined with the
                plslabelfunc command.
                s: Enables subticks between major ticks, only valid if t is
                also specified.
                t: Draws major ticks.
                u: If this is specified, the text label is written beside the
                left-hand axis.
                v: If this is specified, the text label is written beside the
                right-hand axis.


        zlabel (PLCHAR_VECTOR, input) :    A UTF-8 character string specifying
            the text label for the z axis.  It is only drawn if u or v are in
            the zopt string.

        ztick (PLFLT, input) :    World coordinate interval between major
            ticks on the z axis. If it is set to zero, PLplot automatically
            generates a suitable tick interval.

        nzsub (PLINT, input) :    Number of subintervals between major z axis
            ticks for minor ticks.  If it is set to zero, PLplot automatically
            generates a suitable minor tick interval.

    """
    return _plplotc.plbox3(xopt, xlabel, xtick, nsubx, yopt, ylabel, ytick, nsuby, zopt, zlabel, ztick, nsubz)

def plcalc_world(rx, ry):
    """
    Calculate world coordinates and corresponding window index from relative device coordinates

    DESCRIPTION:

        Calculate world coordinates, wx and wy, and corresponding window index
        from relative device coordinates, rx and ry.

        Redacted form: General: plcalc_world(rx, ry, wx, wy, window)
                Perl/PDL: Not available?


        This function is used in example 31.



    SYNOPSIS:

    plcalc_world(rx, ry, wx, wy, window)

    ARGUMENTS:

        rx (PLFLT, input) :    Input relative device coordinate (0.0-1.0) for
            the x coordinate.

        ry (PLFLT, input) :    Input relative device coordinate (0.0-1.0) for
            the y coordinate.

        wx (PLFLT_NC_SCALAR, output) :    Returned value of the x world
            coordinate corresponding to the relative device coordinates rx and
            ry.

        wy (PLFLT_NC_SCALAR, output) :    Returned value of the y world
            coordinate corresponding to the relative device coordinates rx and
            ry.

        window (PLINT_NC_SCALAR, output) :    Returned value of the last
            defined window index that corresponds to the input relative device
            coordinates (and the returned world coordinates).  To give some
            background on the window index, for each page the initial window
            index is set to zero, and each time plwind is called within the
            page, world and device coordinates are stored for the window and
            the window index is incremented.  Thus, for a simple page layout
            with non-overlapping viewports and one window per viewport, window
            corresponds to the viewport index (in the order which the
            viewport/windows were created) of the only viewport/window
            corresponding to rx and ry.  However, for more complicated layouts
            with potentially overlapping viewports and possibly more than one
            window (set of world coordinates) per viewport, window and the
            corresponding output world coordinates corresponds to the last
            window created that fulfills the criterion that the relative
            device coordinates are inside it.  Finally, in all cases where the
            input relative device coordinates are not inside any
            viewport/window, then the returned value of the last defined
            window index is set to -1.

    """
    return _plplotc.plcalc_world(rx, ry)

def plclear():
    """
    Clear current (sub)page

    DESCRIPTION:

        Clears the current page, effectively erasing everything that have been
        drawn.  This command only works with interactive drivers; if the
        driver does not support this, the page is filled with the background
        color in use. If the current page is divided into subpages, only the
        current subpage is erased.  The nth subpage can be selected with
        pladv(n).

        Redacted form: General: plclear()
                Perl/PDL: Not available?


        This function is not used in any examples.



    SYNOPSIS:

    plclear()

    """
    return _plplotc.plclear()

def plcol0(icol0):
    """
    Set color, cmap0

    DESCRIPTION:

        Sets the color index for cmap0 (see the PLplot documentation).

        Redacted form: plcol0(icol0)

        This function is used in examples 1-9, 11-16, 18-27, and 29.



    SYNOPSIS:

    plcol0(icol0)

    ARGUMENTS:

        icol0 (PLINT, input) :    Integer representing the color.  The
            defaults at present are (these may change):
        0      black (default background)
        1      red (default foreground)
        2      yellow
        3      green
        4      aquamarine
        5      pink
        6      wheat
        7      grey
        8      brown
        9      blue
        10      BlueViolet
        11      cyan
        12      turquoise
        13      magenta
        14      salmon
        15      white

          Use plscmap0 to change the entire cmap0 color palette and plscol0 to
             change an individual color in the cmap0 color palette.

    """
    return _plplotc.plcol0(icol0)

def plcol1(col1):
    """
    Set color, cmap1

    DESCRIPTION:

        Sets the color for cmap1 (see the PLplot documentation).

        Redacted form: plcol1(col1)

        This function is used in examples 12 and 21.



    SYNOPSIS:

    plcol1(col1)

    ARGUMENTS:

        col1 (PLFLT, input) :    This value must be in the range (0.0-1.0) and
            is mapped to color using the continuous cmap1 palette which by
            default ranges from blue to the background color to red.  The
            cmap1 palette can also be straightforwardly changed by the user
            with plscmap1 or plscmap1l.

    """
    return _plplotc.plcol1(col1)

def plconfigtime(scale, offset1, offset2, ccontrol, ifbtime_offset, year, month, day, hour, min, sec):
    """
    Configure the transformation between continuous and broken-down time for the current stream

    DESCRIPTION:

        Configure the transformation between continuous and broken-down time
        for the current stream.  This transformation is used by both plbtime
        and plctime.

        Redacted form: General: plconfigtime(scale, offset1, offset2,
        ccontrol, ifbtime_offset, year, month, day, hour, min, sec)
                Perl/PDL: Not available?


        This function is used in example 29.



    SYNOPSIS:

    plconfigtime(scale, offset1, offset2, ccontrol, ifbtime_offset, year, month, day, hour, min, sec)

    ARGUMENTS:

        scale (PLFLT, input) :    The number of days per continuous time unit.
             As a special case, if
        scale is 0., then all other arguments are ignored, and the result (the
            default used by PLplot) is the equivalent of a call to
            plconfigtime(1./86400., 0., 0., 0x0, 1, 1970, 0, 1, 0, 0, 0.).
            That is, for this special case broken-down time is calculated with
            the proleptic Gregorian calendar with no leap seconds inserted,
            and the continuous time is defined as the number of seconds since
            the Unix epoch of 1970-01-01T00:00:00Z.

        offset1 (PLFLT, input) :    If
        ifbtime_offset is true, the parameters
        offset1 and
        offset2 are completely ignored. Otherwise, the sum of these parameters
            (with units in days) specify the epoch of the continuous time
            relative to the MJD epoch corresponding to the Gregorian calendar
            date of 1858-11-17T00:00:00Z or JD = 2400000.5.  Two PLFLT numbers
            are used to specify the origin to allow users (by specifying
        offset1 as an integer that can be exactly represented by a
            floating-point variable and specifying
        offset2 as a number in the range from 0. to 1) the chance to minimize
            the numerical errors of the continuous time representation.

        offset2 (PLFLT, input) :    See documentation of
        offset1.

        ccontrol (PLINT, input) :    ccontrol contains bits controlling the
            transformation.  If the 0x1 bit is set, then the proleptic Julian
            calendar is used for broken-down time rather than the proleptic
            Gregorian calendar.  If the 0x2 bit is set, then leap seconds that
            have been historically used to define UTC are inserted into the
            broken-down time. Other possibilities for additional control bits
            for ccontrol exist such as making the historical time corrections
            in the broken-down time corresponding to ET (ephemeris time) or
            making the (slightly non-constant) corrections from international
            atomic time (TAI) to what astronomers define as terrestrial time
            (TT).  But those additional possibilities have not been
            implemented yet in the qsastime library (one of the PLplot utility
            libraries).

        ifbtime_offset (PLBOOL, input) :    ifbtime_offset controls how the
            epoch of the continuous time scale is specified by the user. If
        ifbtime_offset is false, then
        offset1 and
        offset2 are used to specify the epoch, and the following broken-down
            time parameters are completely ignored.  If
        ifbtime_offset is true, then
        offset1 and
        offset2 are completely ignored, and the following broken-down time
            parameters are used to specify the epoch.

        year (PLINT, input) :    Year of epoch.

        month (PLINT, input) :    Month of epoch in range from 0 (January) to
            11 (December).

        day (PLINT, input) :    Day of epoch in range from 1 to 31.

        hour (PLINT, input) :    Hour of epoch in range from 0 to 23

        min (PLINT, input) :    Minute of epoch in range from 0 to 59.

        sec (PLFLT, input) :    Second of epoch in range from 0. to 60.

    """
    return _plplotc.plconfigtime(scale, offset1, offset2, ccontrol, ifbtime_offset, year, month, day, hour, min, sec)

def plcont(*args):
    """
    Contour plot

    DESCRIPTION:

        Draws a contour plot of the data in f[
        nx][
        ny], using the nlevel contour levels specified by clevel. Only the
        region of the matrix from kx to lx and from ky to ly is plotted out
        where all these index ranges are interpreted as one-based for
        historical reasons.  A transformation routine pointed to by pltr with
        a generic pointer pltr_data for additional data required by the
        transformation routine is used to map indices within the matrix to the
        world coordinates.

        Redacted form: plcont(f, kx, lx, ky, ly, clevel, pltr, pltr_data)
        where (see above discussion) the pltr, pltr_data callback arguments
        are sometimes replaced by a tr vector with 6 elements; xg and yg
        vectors; or xg and yg matrices.

        This function is used in examples 9, 14, 16, and 22.



    SYNOPSIS:

    plcont(f, nx, ny, kx, lx, ky, ly, clevel, nlevel, pltr, pltr_data)

    ARGUMENTS:

        f (PLFLT_MATRIX, input) :    A matrix containing data to be contoured.

        nx, ny (PLINT, input) :    The dimensions of the matrix f.

        kx, lx (PLINT, input) :    Range of x indices to consider where 0 <=
            kx-1 < lx-1 < nx.  Values of kx and lx are one-based rather than
            zero-based for historical backwards-compatibility reasons.

        ky, ly (PLINT, input) :    Range of y indices to consider where 0 <=
            ky-1 < ly-1 < ny.  Values of ky and ly are one-based rather than
            zero-based for historical backwards-compatibility reasons.

        clevel (PLFLT_VECTOR, input) :    A vector specifying the levels at
            which to draw contours.

        nlevel (PLINT, input) :    Number of contour levels to draw.

        pltr (PLTRANSFORM_callback, input) :    A callback function that
            defines the transformation between the zero-based indices of the
            matrix f and the world coordinates.For the C case, transformation
            functions are provided in the PLplot library: pltr0 for the
            identity mapping, and pltr1 and pltr2 for arbitrary mappings
            respectively defined by vectors and matrices.  In addition, C
            callback routines for the transformation can be supplied by the
            user such as the mypltr function in examples/c/x09c.c which
            provides a general linear transformation between index coordinates
            and world coordinates.For languages other than C you should
            consult the PLplot documentation for the details concerning how
            PLTRANSFORM_callback arguments are interfaced. However, in
            general, a particular pattern of callback-associated arguments
            such as a tr vector with 6 elements; xg and yg vectors; or xg and
            yg matrices are respectively interfaced to a linear-transformation
            routine similar to the above mypltr function; pltr1; and pltr2.
            Furthermore, some of our more sophisticated bindings (see, e.g.,
            the PLplot documentation) support native language callbacks for
            handling index to world-coordinate transformations.  Examples of
            these various approaches are given in examples/<language>x09*,
            examples/<language>x16*, examples/<language>x20*,
            examples/<language>x21*, and examples/<language>x22*, for all our
            supported languages.

        pltr_data (PLPointer, input) :    Extra parameter to help pass
            information to pltr0, pltr1, pltr2, or whatever callback routine
            that is externally supplied.

    """
    return _plplotc.plcont(*args)

def plctime(year, month, day, hour, min, sec):
    """
    Calculate continuous time from broken-down time for the current stream

    DESCRIPTION:

        Calculate continuous time, ctime, from broken-down time for the
        current stream.  The broken-down
        time is specified by the following parameters: year, month, day, hour,
        min, and sec. This function is the inverse of plbtime.

        The PLplot definition of broken-down time is a calendar time that
        completely ignores all time zone offsets, i.e., it is the user's
        responsibility to apply those offsets (if so desired) before using the
        PLplot time API.  By default broken-down time is defined using the
        proleptic Gregorian calendar without the insertion of leap seconds and
        continuous time is defined as the number of seconds since the Unix
        epoch of 1970-01-01T00:00:00Z. However, other definitions of
        broken-down and continuous time are possible, see plconfigtime which
        specifies that transformation for the current stream.

        Redacted form: General: plctime(year, month, day, hour, min, sec,
        ctime)
                Perl/PDL: Not available?


        This function is used in example 29.



    SYNOPSIS:

    plctime(year, month, day, hour, min, sec, ctime)

    ARGUMENTS:

        year (PLINT, input) :    Input year.

        month (PLINT, input) :    Input month in range from 0 (January) to 11
            (December).

        day (PLINT, input) :    Input day in range from 1 to 31.

        hour (PLINT, input) :    Input hour in range from 0 to 23

        min (PLINT, input) :    Input minute in range from 0 to 59.

        sec (PLFLT, input) :    Input second in range from 0. to 60.

        ctime (PLFLT_NC_SCALAR, output) :    Returned value of the continuous
            time calculated from the broken-down time specified by the
            previous parameters.

    """
    return _plplotc.plctime(year, month, day, hour, min, sec)

def plcpstrm(iplsr, flags):
    """
    Copy state parameters from the reference stream to the current stream

    DESCRIPTION:

        Copies state parameters from the reference stream to the current
        stream. Tell driver interface to map device coordinates unless flags
        == 1.

        This function is used for making save files of selected plots (e.g.
        from the TK driver).  After initializing, you can get a copy of the
        current plot to the specified device by switching to this stream and
        issuing a plcpstrm and a plreplot, with calls to plbop and pleop as
        appropriate.  The plot buffer must have previously been enabled (done
        automatically by some display drivers, such as X).

        Redacted form: plcpstrm(iplsr, flags)

        This function is used in example 1,20.



    SYNOPSIS:

    plcpstrm(iplsr, flags)

    ARGUMENTS:

        iplsr (PLINT, input) :    Number of reference stream.

        flags (PLBOOL, input) :    If flags is set to true the device
            coordinates are not copied from the reference to current stream.

    """
    return _plplotc.plcpstrm(iplsr, flags)

def plend():
    """
    End plotting session

    DESCRIPTION:

        Ends a plotting session, tidies up all the output files, switches
        interactive devices back into text mode and frees up any memory that
        was allocated.  Must be called before end of program.

        By default, PLplot's interactive devices (Xwin, TK, etc.) go into a
        wait state after a call to plend or other functions which trigger the
        end of a plot page. To avoid this, use the plspause function.

        Redacted form: plend()

        This function is used in all of the examples.



    SYNOPSIS:

    plend()

    """
    return _plplotc.plend()

def plend1():
    """
    End plotting session for current stream

    DESCRIPTION:

        Ends a plotting session for the current output stream only.  See
        plsstrm for more info.

        Redacted form: plend1()

        This function is used in examples 1 and 20.



    SYNOPSIS:

    plend1()

    """
    return _plplotc.plend1()

def plenv(xmin, xmax, ymin, ymax, just, axis):
    """
    Set up standard window and draw box

    DESCRIPTION:

        Sets up plotter environment for simple graphs by calling pladv and
        setting up viewport and window to sensible default values. plenv
        leaves a standard margin (left-hand margin of eight character heights,
        and a margin around the other three sides of five character heights)
        around most graphs for axis labels and a title.  When these defaults
        are not suitable, use the individual routines plvpas, plvpor, or
        plvasp for setting up the viewport, plwind for defining the window,
        and plbox for drawing the box.

        Redacted form: plenv(xmin, xmax, ymin, ymax, just, axis)

        This function is used in example 1,3,9,13,14,19-22,29.



    SYNOPSIS:

    plenv(xmin, xmax, ymin, ymax, just, axis)

    ARGUMENTS:

        xmin (PLFLT, input) :    Value of x at left-hand edge of window (in
            world coordinates).

        xmax (PLFLT, input) :    Value of x at right-hand edge of window (in
            world coordinates).

        ymin (PLFLT, input) :    Value of y at bottom edge of window (in world
            coordinates).

        ymax (PLFLT, input) :    Value of y at top edge of window (in world
            coordinates).

        just (PLINT, input) :    Controls how the axes will be scaled: -1: the
            scales will not be set, the user must set up the scale before
            calling plenv using plsvpa, plvasp or other.
                0: the x and y axes are scaled independently to use as much of
                the screen as possible.
                1: the scales of the x and y axes are made equal.
                2: the axis of the x and y axes are made equal, and the plot
                box will be square.


        axis (PLINT, input) :    Controls drawing of the box around the plot:
            -2: draw no box, no tick marks, no numeric tick labels, no axes.
                -1: draw box only.
                0: draw box, ticks, and numeric tick labels.
                1: also draw coordinate axes at x=0 and y=0.
                2: also draw a grid at major tick positions in both
                coordinates.
                3: also draw a grid at minor tick positions in both
                coordinates.
                10: same as 0 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                11: same as 1 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                12: same as 2 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                13: same as 3 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                20: same as 0 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                21: same as 1 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                22: same as 2 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                23: same as 3 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                30: same as 0 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                31: same as 1 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                32: same as 2 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                33: same as 3 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                40: same as 0 except date / time x labels.
                41: same as 1 except date / time x labels.
                42: same as 2 except date / time x labels.
                43: same as 3 except date / time x labels.
                50: same as 0 except date / time y labels.
                51: same as 1 except date / time y labels.
                52: same as 2 except date / time y labels.
                53: same as 3 except date / time y labels.
                60: same as 0 except date / time x and y labels.
                61: same as 1 except date / time x and y labels.
                62: same as 2 except date / time x and y labels.
                63: same as 3 except date / time x and y labels.
                70: same as 0 except custom x and y labels.
                71: same as 1 except custom x and y labels.
                72: same as 2 except custom x and y labels.
                73: same as 3 except custom x and y labels.

    """
    return _plplotc.plenv(xmin, xmax, ymin, ymax, just, axis)

def plenv0(xmin, xmax, ymin, ymax, just, axis):
    """
    Same as plenv but if in multiplot mode does not advance the subpage, instead clears it

    DESCRIPTION:

        Sets up plotter environment for simple graphs by calling pladv and
        setting up viewport and window to sensible default values. plenv0
        leaves a standard margin (left-hand margin of eight character heights,
        and a margin around the other three sides of five character heights)
        around most graphs for axis labels and a title.  When these defaults
        are not suitable, use the individual routines plvpas, plvpor, or
        plvasp for setting up the viewport, plwind for defining the window,
        and plbox for drawing the box.

        Redacted form: plenv0(xmin, xmax, ymin, ymax, just, axis)

        This function is used in example 21.



    SYNOPSIS:

    plenv0(xmin, xmax, ymin, ymax, just, axis)

    ARGUMENTS:

        xmin (PLFLT, input) :    Value of x at left-hand edge of window (in
            world coordinates).

        xmax (PLFLT, input) :    Value of x at right-hand edge of window (in
            world coordinates).

        ymin (PLFLT, input) :    Value of y at bottom edge of window (in world
            coordinates).

        ymax (PLFLT, input) :    Value of y at top edge of window (in world
            coordinates).

        just (PLINT, input) :    Controls how the axes will be scaled: -1: the
            scales will not be set, the user must set up the scale before
            calling plenv0 using plsvpa, plvasp or other.
                0: the x and y axes are scaled independently to use as much of
                the screen as possible.
                1: the scales of the x and y axes are made equal.
                2: the axis of the x and y axes are made equal, and the plot
                box will be square.


        axis (PLINT, input) :    Controls drawing of the box around the plot:
            -2: draw no box, no tick marks, no numeric tick labels, no axes.
                -1: draw box only.
                0: draw box, ticks, and numeric tick labels.
                1: also draw coordinate axes at x=0 and y=0.
                2: also draw a grid at major tick positions in both
                coordinates.
                3: also draw a grid at minor tick positions in both
                coordinates.
                10: same as 0 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                11: same as 1 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                12: same as 2 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                13: same as 3 except logarithmic x tick marks. (The x data
                have to be converted to logarithms separately.)
                20: same as 0 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                21: same as 1 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                22: same as 2 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                23: same as 3 except logarithmic y tick marks. (The y data
                have to be converted to logarithms separately.)
                30: same as 0 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                31: same as 1 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                32: same as 2 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                33: same as 3 except logarithmic x and y tick marks. (The x
                and y data have to be converted to logarithms separately.)
                40: same as 0 except date / time x labels.
                41: same as 1 except date / time x labels.
                42: same as 2 except date / time x labels.
                43: same as 3 except date / time x labels.
                50: same as 0 except date / time y labels.
                51: same as 1 except date / time y labels.
                52: same as 2 except date / time y labels.
                53: same as 3 except date / time y labels.
                60: same as 0 except date / time x and y labels.
                61: same as 1 except date / time x and y labels.
                62: same as 2 except date / time x and y labels.
                63: same as 3 except date / time x and y labels.
                70: same as 0 except custom x and y labels.
                71: same as 1 except custom x and y labels.
                72: same as 2 except custom x and y labels.
                73: same as 3 except custom x and y labels.

    """
    return _plplotc.plenv0(xmin, xmax, ymin, ymax, just, axis)

def pleop():
    """
    Eject current page

    DESCRIPTION:

        Clears the graphics screen of an interactive device, or ejects a page
        on a plotter.  See plbop for more information.

        Redacted form: pleop()

        This function is used in example 2,14.



    SYNOPSIS:

    pleop()

    """
    return _plplotc.pleop()

def plerrx(n, arg2, arg3):
    """
    Draw error bars in x direction

    DESCRIPTION:

        Draws a set of n error bars in x direction, the i'th error bar
        extending from xmin[i] to xmax[i] at y coordinate y[i].  The terminals
        of the error bars are of length equal to the minor tick length
        (settable using plsmin).

        Redacted form: General: plerrx(xmin, ymax, y)
                Perl/PDL: plerrx(n, xmin, xmax, y)


        This function is used in example 29.



    SYNOPSIS:

    plerrx(n, xmin, xmax, y)

    ARGUMENTS:

        n (PLINT, input) :    Number of error bars to draw.

        xmin (PLFLT_VECTOR, input) :    A vector containing the x coordinates
            of the left-hand endpoints of the error bars.

        xmax (PLFLT_VECTOR, input) :    A vector containing the x coordinates
            of the right-hand endpoints of the error bars.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            the error bars.

    """
    return _plplotc.plerrx(n, arg2, arg3)

def plerry(n, arg2, arg3):
    """
    Draw error bars in the y direction

    DESCRIPTION:

        Draws a set of n error bars in the y direction, the i'th error bar
        extending from ymin[i] to ymax[i] at x coordinate x[i].  The terminals
        of the error bars are of length equal to the minor tick length
        (settable using plsmin).

        Redacted form: General: plerry(x, ymin, ymax)
                Perl/PDL: plerry(n, x, ymin, ymax)


        This function is used in example 29.



    SYNOPSIS:

    plerry(n, x, ymin, ymax)

    ARGUMENTS:

        n (PLINT, input) :    Number of error bars to draw.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            the error bars.

        ymin (PLFLT_VECTOR, input) :    A vector containing the y coordinates
            of the lower endpoints of the error bars.

        ymax (PLFLT_VECTOR, input) :    A vector containing the y coordinates
            of the upper endpoints of the error bars.

    """
    return _plplotc.plerry(n, arg2, arg3)

def plfamadv():
    """
    Advance to the next family file on the next new page

    DESCRIPTION:

        Advance to the next family file on the next new page.

        Redacted form: plfamadv()

        This function is not used in any examples.



    SYNOPSIS:

    plfamadv()

    """
    return _plplotc.plfamadv()

def plfill(n, ArrayCk):
    """
    Draw filled polygon

    DESCRIPTION:

        Fills the polygon defined by the n points (
        x[i],
        y[i]) using the pattern defined by plpsty or plpat.  The default fill
        style is a solid fill. The routine will automatically close the
        polygon between the last and first vertices.  If multiple closed
        polygons are passed in x and y then plfill will fill in between them.

        Redacted form: plfill(x,y)

        This function is used in examples 12, 13, 15, 16, 21, 24, and 25.



    SYNOPSIS:

    plfill(n, x, y)

    ARGUMENTS:

        n (PLINT, input) :    Number of vertices in polygon.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            vertices.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            vertices.

    """
    return _plplotc.plfill(n, ArrayCk)

def plfill3(n, arg2, arg3):
    """
    Draw filled polygon in 3D

    DESCRIPTION:

        Fills the 3D polygon defined by the n points in the x, y, and z
        vectors using the pattern defined by plpsty or plpat.  The routine
        will automatically close the polygon between the last and first
        vertices.  If multiple closed polygons are passed in x, y, and z then
        plfill3 will fill in between them.

        Redacted form: General: plfill3(x, y, z)
                Perl/PDL: plfill3(n, x, y, z)


        This function is used in example 15.



    SYNOPSIS:

    plfill3(n, x, y, z)

    ARGUMENTS:

        n (PLINT, input) :    Number of vertices in polygon.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            vertices.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            vertices.

        z (PLFLT_VECTOR, input) :    A vector containing the z coordinates of
            vertices.

    """
    return _plplotc.plfill3(n, arg2, arg3)

def plgradient(n, ArrayCk, angle):
    """
    Draw linear gradient inside polygon

    DESCRIPTION:

        Draw a linear gradient using cmap1 inside the polygon defined by the n
        points (
        x[i],
        y[i]).  Interpretation of the polygon is the same as for plfill.  The
        polygon coordinates and the gradient angle are all expressed in world
        coordinates.  The angle from the x axis for both the rotated
        coordinate system and the gradient vector is specified by angle.  The
        magnitude of the gradient vector is the difference between the maximum
        and minimum values of x for the vertices in the rotated coordinate
        system.  The origin of the gradient vector can be interpreted as being
        anywhere on the line corresponding to the minimum x value for the
        vertices in the rotated coordinate system.  The distance along the
        gradient vector is linearly transformed to the independent variable of
        color map 1 which ranges from 0. at the tail of the gradient vector to
        1. at the head of the gradient vector.  What is drawn is the RGBA
        color corresponding to the independent variable of cmap1.  For more
        information about cmap1 (see the PLplot documentation).

        Redacted form: plgradient(x,y,angle)

        This function is used in examples 25 and 30.



    SYNOPSIS:

    plgradient(n, x, y, angle)

    ARGUMENTS:

        n (PLINT, input) :    Number of vertices in polygon.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            vertices.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            vertices.

        angle (PLFLT, input) :    Angle (degrees) of gradient vector from x
            axis.

    """
    return _plplotc.plgradient(n, ArrayCk, angle)

def plflush():
    """
    Flushes the output stream

    DESCRIPTION:

        Flushes the output stream. Use sparingly, if at all.

        Redacted form: plflush()

        This function is used in examples 1 and 14.



    SYNOPSIS:

    plflush()

    """
    return _plplotc.plflush()

def plfont(ifont):
    """
    Set font

    DESCRIPTION:

        Sets the font used for subsequent text and symbols.  For devices that
        still use Hershey fonts this routine has no effect unless the Hershey
        fonts with extended character set are loaded (see plfontld). For
        unicode-aware devices that use system fonts instead of Hershey fonts,
        this routine calls the plsfci routine with argument set up
        appropriately for the various cases below.  However, this method of
        specifying the font for unicode-aware devices is deprecated, and the
        much more flexible method of calling plsfont directly is recommended
        instead (where plsfont provides a user-friendly interface to plsfci),

        Redacted form: plfont(ifont)

        This function is used in examples 1, 2, 4, 7, 13, 24, and 26.



    SYNOPSIS:

    plfont(ifont)

    ARGUMENTS:

        ifont (PLINT, input) :    Specifies the font: 1: Sans serif font
            (simplest and fastest)
                2: Serif font
                3: Italic font
                4: Script font

    """
    return _plplotc.plfont(ifont)

def plfontld(fnt):
    """
    Load Hershey fonts

    DESCRIPTION:

        Loads the Hershey fonts used for text and symbols.  This routine may
        be called before or after initializing PLplot.  If not explicitly
        called before PLplot initialization, then by default that
        initialization loads Hershey fonts with the extended character set.
        This routine only has a practical effect for devices that still use
        Hershey fonts (as opposed to modern devices that use unicode-aware
        system fonts instead of Hershey fonts).

        Redacted form: plfontld(fnt)

        This function is used in examples 1 and 7.



    SYNOPSIS:

    plfontld(fnt)

    ARGUMENTS:

        fnt (PLINT, input) :    Specifies the type of Hershey fonts to load.
            A zero value specifies Hershey fonts with the standard character
            set and a non-zero value (the default assumed if plfontld is never
            called) specifies Hershey fonts with the extended character set.

    """
    return _plplotc.plfontld(fnt)

def plgchr():
    """
    Get character default height and current (scaled) height

    DESCRIPTION:

        Get character default height and current (scaled) height.

        Redacted form: plgchr(p_def, p_ht)

        This function is used in example 23.



    SYNOPSIS:

    plgchr(p_def, p_ht)

    ARGUMENTS:

        p_def (PLFLT_NC_SCALAR, output) :    Returned value of the default
            character height (mm).

        p_ht (PLFLT_NC_SCALAR, output) :    Returned value of the scaled
            character height (mm).

    """
    return _plplotc.plgchr()

def plgcol0(icol0):
    """
    Returns 8-bit RGB values for given color index from cmap0

    DESCRIPTION:

        Returns 8-bit RGB values (0-255) for given color from cmap0 (see the
        PLplot documentation).  Values are negative if an invalid color id is
        given.

        Redacted form: plgcol0(icol0, r, g, b)

        This function is used in example 2.



    SYNOPSIS:

    plgcol0(icol0, r, g, b)

    ARGUMENTS:

        icol0 (PLINT, input) :    Index of desired cmap0 color.

        r (PLINT_NC_SCALAR, output) :    Returned value of the 8-bit red
            value.

        g (PLINT_NC_SCALAR, output) :    Returned value of the 8-bit green
            value.

        b (PLINT_NC_SCALAR, output) :    Returned value of the 8-bit blue
            value.

    """
    return _plplotc.plgcol0(icol0)

def plgcol0a(icol0):
    """
    Returns 8-bit RGB values and PLFLT alpha transparency value for given color index from cmap0

    DESCRIPTION:

        Returns 8-bit RGB values (0-255) and PLFLT alpha transparency value
        (0.0-1.0) for given color from cmap0 (see the PLplot documentation).
        Values are negative if an invalid color id is given.

        Redacted form: plgcola(r, g, b)

        This function is used in example 30.



    SYNOPSIS:

    plgcol0a(icol0, r, g, b, alpha)

    ARGUMENTS:

        icol0 (PLINT, input) :    Index of desired cmap0 color.

        r (PLINT_NC_SCALAR, output) :    Returned value of the red intensity
            in the range from 0 to 255.

        g (PLINT_NC_SCALAR, output) :    Returned value of the green intensity
            in the range from 0 to 255.

        b (PLINT_NC_SCALAR, output) :    Returned value of the blue intensity
            in the range from 0 to 255.

        alpha (PLFLT_NC_SCALAR, output) :    Returned value of the alpha
            transparency in the range from (0.0-1.0).

    """
    return _plplotc.plgcol0a(icol0)

def plgcolbg():
    """
    Returns the background color (cmap0[0]) by 8-bit RGB value

    DESCRIPTION:

        Returns the background color (cmap0[0]) by 8-bit RGB value.

        Redacted form: plgcolbg(r, g, b)

        This function is used in example 31.



    SYNOPSIS:

    plgcolbg(r, g, b)

    ARGUMENTS:

        r (PLINT_NC_SCALAR, output) :    Returned value of the red intensity
            in the range from 0 to 255.

        g (PLINT_NC_SCALAR, output) :    Returned value of the green intensity
            in the range from 0 to 255.

        b (PLINT_NC_SCALAR, output) :    Returned value of the blue intensity
            in the range from 0 to 255.

    """
    return _plplotc.plgcolbg()

def plgcolbga():
    """
    Returns the background color (cmap0[0]) by 8-bit RGB value and PLFLT alpha transparency value

    DESCRIPTION:

        Returns the background color (cmap0[0]) by 8-bit RGB value and PLFLT
        alpha transparency value.

        This function is used in example 31.



    SYNOPSIS:

    plgcolbga(r, g, b, alpha)

    ARGUMENTS:

        r (PLINT_NC_SCALAR, output) :    Returned value of the red intensity
            in the range from 0 to 255.

        g (PLINT_NC_SCALAR, output) :    Returned value of the green intensity
            in the range from 0 to 255.

        b (PLINT_NC_SCALAR, output) :    Returned value of the blue intensity
            in the range from 0 to 255.

        alpha (PLFLT_NC_SCALAR, output) :    Returned value of the alpha
            transparency in the range (0.0-1.0).

    """
    return _plplotc.plgcolbga()

def plgcompression():
    """
    Get the current device-compression setting

    DESCRIPTION:

        Get the current device-compression setting.  This parameter is only
        used for drivers that provide compression.

        Redacted form: plgcompression(compression)

        This function is used in example 31.



    SYNOPSIS:

    plgcompression(compression)

    ARGUMENTS:

        compression (PLINT_NC_SCALAR, output) :    Returned value of the
            compression setting for the current device.

    """
    return _plplotc.plgcompression()

def plgdev():
    """
    Get the current device (keyword) name

    DESCRIPTION:

        Get the current device (keyword) name.  Note: you must have allocated
        space for this (80 characters is safe).

        Redacted form: plgdev(p_dev)

        This function is used in example 14.



    SYNOPSIS:

    plgdev(p_dev)

    ARGUMENTS:

        p_dev (PLCHAR_NC_VECTOR, output) :    Returned ascii character string
            (with preallocated length of 80 characters or more) containing the
            device (keyword) name.

    """
    return _plplotc.plgdev()

def plgdidev():
    """
    Get parameters that define current device-space window

    DESCRIPTION:

        Get relative margin width, aspect ratio, and relative justification
        that define current device-space window. If plsdidev has not been
        called the default values pointed to by p_mar, p_aspect, p_jx, and
        p_jy will all be 0.

        Redacted form: plgdidev(p_mar, p_aspect, p_jx, p_jy)

        This function is used in example 31.



    SYNOPSIS:

    plgdidev(p_mar, p_aspect, p_jx, p_jy)

    ARGUMENTS:

        p_mar (PLFLT_NC_SCALAR, output) :    Returned value of the relative
            margin width.

        p_aspect (PLFLT_NC_SCALAR, output) :    Returned value of the aspect
            ratio.

        p_jx (PLFLT_NC_SCALAR, output) :    Returned value of the relative
            justification in x.

        p_jy (PLFLT_NC_SCALAR, output) :    Returned value of the relative
            justification in y.

    """
    return _plplotc.plgdidev()

def plgdiori():
    """
    Get plot orientation

    DESCRIPTION:

        Get plot orientation parameter which is multiplied by 90 degrees to
        obtain the angle of rotation.  Note, arbitrary rotation parameters
        such as 0.2 (corresponding to 18 degrees) are possible, but the usual
        values for the rotation parameter are 0., 1., 2., and 3. corresponding
        to 0 degrees (landscape mode), 90 degrees (portrait mode), 180 degrees
        (seascape mode), and 270 degrees (upside-down mode). If plsdiori has
        not been called the default value pointed to by p_rot will be 0.

        Redacted form: plgdiori(p_rot)

        This function is not used in any examples.



    SYNOPSIS:

    plgdiori(p_rot)

    ARGUMENTS:

        p_rot (PLFLT_NC_SCALAR, output) :    Returned value of the orientation
            parameter.

    """
    return _plplotc.plgdiori()

def plgdiplt():
    """
    Get parameters that define current plot-space window

    DESCRIPTION:

        Get relative minima and maxima that define current plot-space window.
        If plsdiplt has not been called the default values pointed to by
        p_xmin, p_ymin, p_xmax, and p_ymax will be 0., 0., 1., and 1.

        Redacted form: plgdiplt(p_xmin, p_ymin, p_xmax, p_ymax)

        This function is used in example 31.



    SYNOPSIS:

    plgdiplt(p_xmin, p_ymin, p_xmax, p_ymax)

    ARGUMENTS:

        p_xmin (PLFLT_NC_SCALAR, output) :    Returned value of the relative
            minimum in x.

        p_ymin (PLFLT_NC_SCALAR, output) :    Returned value of the relative
            minimum in y.

        p_xmax (PLFLT_NC_SCALAR, output) :    Returned value of the relative
            maximum in x.

        p_ymax (PLFLT_NC_SCALAR, output) :    Returned value of the relative
            maximum in y.

    """
    return _plplotc.plgdiplt()

def plgfam():
    """
    Get family file parameters

    DESCRIPTION:

        Gets information about current family file, if familying is enabled.
        See the PLplot documentation for more information.

        Redacted form: plgfam(p_fam, p_num, p_bmax)

        This function is used in examples 14 and 31.



    SYNOPSIS:

    plgfam(p_fam, p_num, p_bmax)

    ARGUMENTS:

        p_fam (PLINT_NC_SCALAR, output) :    Returned value of the current
            family flag value.  If nonzero, familying is enabled for the
            current device.

        p_num (PLINT_NC_SCALAR, output) :    Returned value of the current
            family file number.

        p_bmax (PLINT_NC_SCALAR, output) :    Returned value of the maximum
            file size (in bytes) for a family file.

    """
    return _plplotc.plgfam()

def plgfci():
    """
    Get FCI (font characterization integer)

    DESCRIPTION:

        Gets information about the current font using the FCI approach. See
        the PLplot documentation for more information.

        Redacted form: plgfci(p_fci)

        This function is used in example 23.



    SYNOPSIS:

    plgfci(p_fci)

    ARGUMENTS:

        p_fci (PLUNICODE_NC_SCALAR, output) :    Returned value of the current
            FCI value.

    """
    return _plplotc.plgfci()

def plgfnam():
    """
    Get output file name

    DESCRIPTION:

        Gets the current output file name, if applicable.

        Redacted form: plgfnam(fnam)

        This function is used in example 31.



    SYNOPSIS:

    plgfnam(fnam)

    ARGUMENTS:

        fnam (PLCHAR_NC_VECTOR, output) :    Returned ascii character string
            (with preallocated length of 80 characters or more) containing the
            file name.

    """
    return _plplotc.plgfnam()

def plgfont():
    """
    Get family, style and weight of the current font

    DESCRIPTION:

        Gets information about current font.  See the PLplot documentation for
        more information on font selection.

        Redacted form: plgfont(p_family, p_style, p_weight)

        This function is used in example 23.



    SYNOPSIS:

    plgfont(p_family, p_style, p_weight)

    ARGUMENTS:

        p_family (PLINT_NC_SCALAR, output) :    Returned value of the current
            font family. The available values are given by the PL_FCI_*
            constants in plplot.h. Current options are PL_FCI_SANS,
            PL_FCI_SERIF, PL_FCI_MONO, PL_FCI_SCRIPT and PL_FCI_SYMBOL. If
            p_family is NULL then the font family is not returned.

        p_style (PLINT_NC_SCALAR, output) :    Returned value of the current
            font style. The available values are given by the PL_FCI_*
            constants in plplot.h.  Current options are PL_FCI_UPRIGHT,
            PL_FCI_ITALIC and PL_FCI_OBLIQUE. If p_style is NULL then the font
            style is not returned.

        p_weight (PLINT_NC_SCALAR, output) :    Returned value of the current
            font weight. The available values are given by the PL_FCI_*
            constants in plplot.h.  Current options are PL_FCI_MEDIUM and
            PL_FCI_BOLD. If p_weight is NULL then the font weight is not
            returned.

    """
    return _plplotc.plgfont()

def plglevel():
    """
    Get the (current) run level

    DESCRIPTION:

        Get the (current) run level. Valid settings are: 0,  uninitialized
                1,  initialized
                2,  viewport defined
                3,  world coordinates defined


        Redacted form: plglevel(p_level)

        This function is used in example 31.



    SYNOPSIS:

    plglevel(p_level)

    ARGUMENTS:

        p_level (PLINT_NC_SCALAR, output) :    Returned value of the run
            level.

    """
    return _plplotc.plglevel()

def plgpage():
    """
    Get page parameters

    DESCRIPTION:

        Gets the current page configuration. The length and offset values are
        expressed in units that are specific to the current driver. For
        instance: screen drivers will usually interpret them as number of
        pixels, whereas printer drivers will usually use mm.

        Redacted form: plgpage(p_xp, p_yp, p_xleng, p_yleng, p_xoff, p_yoff)

        This function is used in examples 14 and 31.



    SYNOPSIS:

    plgpage(p_xp, p_yp, p_xleng, p_yleng, p_xoff, p_yoff)

    ARGUMENTS:

        p_xp (PLFLT_NC_SCALAR, output) :    Returned value of the number of
            pixels/inch (DPI) in x.

        p_yp (PLFLT_NC_SCALAR, output) :    Returned value of the number of
            pixels/inch (DPI) in y.

        p_xleng (PLINT_NC_SCALAR, output) :    Returned value of the x page
            length.

        p_yleng (PLINT_NC_SCALAR, output) :    Returned value of the y page
            length.

        p_xoff (PLINT_NC_SCALAR, output) :    Returned value of the x page
            offset.

        p_yoff (PLINT_NC_SCALAR, output) :    Returned value of the y page
            offset.

    """
    return _plplotc.plgpage()

def plgra():
    """
    Switch to graphics screen

    DESCRIPTION:

        Sets an interactive device to graphics mode, used in conjunction with
        pltext to allow graphics and text to be interspersed.  On a device
        which supports separate text and graphics windows, this command causes
        control to be switched to the graphics window.  If already in graphics
        mode, this command is ignored.  It is also ignored on devices which
        only support a single window or use a different method for shifting
        focus.  See also pltext.

        Redacted form: plgra()

        This function is used in example 1.



    SYNOPSIS:

    plgra()

    """
    return _plplotc.plgra()

def plgriddata(Array, arg2, arg3, ArrayX, ArrayY, type, data):
    """
    Grid data from irregularly sampled data

    DESCRIPTION:

        Real world data is frequently irregularly sampled, but PLplot 3D plots
        require data organized as a grid, i.e., with x sample point values
        independent of y coordinate and vice versa.  This function takes
        irregularly sampled data from the x[npts], y[npts], and z[npts]
        vectors; reads the desired grid location from the input vectors
        xg[nptsx] and yg[nptsy]; and returns the interpolated result on that
        grid using the output matrix zg[nptsx][nptsy].  The algorithm used to
        interpolate the data to the grid is specified with the argument type
        which can have one parameter specified in argument data.

        Redacted form: General: plgriddata(x, y, z, xg, yg, zg, type, data)
                Perl/PDL: Not available?
                Python: zg=plgriddata(x, y, z, xg, yg, type, data)


        This function is used in example 21.



    SYNOPSIS:

    plgriddata(x, y, z, npts, xg, nptsx, yg, nptsy, zg, type, data)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    The input x vector.

        y (PLFLT_VECTOR, input) :    The input y vector.

        z (PLFLT_VECTOR, input) :    The input z vector. Each triple x[i],
            y[i], z[i] represents one data sample coordinate.

        npts (PLINT, input) :    The number of data samples in the x, y and z
            vectors.

        xg (PLFLT_VECTOR, input) :    A vector that specifies the grid spacing
            in the x direction. Usually xg has nptsx equally spaced values
            from the minimum to the maximum values of the x input vector.

        nptsx (PLINT, input) :    The number of points in the xg vector.

        yg (PLFLT_VECTOR, input) :    A vector that specifies the grid spacing
            in the y direction. Similar to the xg parameter.

        nptsy (PLINT, input) :    The number of points in the yg vector.

        zg (PLFLT_NC_MATRIX, output) :    The matrix of interpolated results
            where data lies in the grid specified by xg and yg. Therefore the
            zg matrix must be dimensioned
        nptsx by
        nptsy.

        type (PLINT, input) :    The type of grid interpolation algorithm to
            use, which can be: GRID_CSA: Bivariate Cubic Spline approximation
                GRID_DTLI: Delaunay Triangulation Linear Interpolation
                GRID_NNI: Natural Neighbors Interpolation
                GRID_NNIDW: Nearest Neighbors Inverse Distance Weighted
                GRID_NNLI: Nearest Neighbors Linear Interpolation
                GRID_NNAIDW:  Nearest Neighbors Around Inverse Distance
                Weighted
        For details of the algorithms read the source file plgridd.c.

        data (PLFLT, input) :    Some gridding algorithms require extra data,
            which can be specified through this argument. Currently, for
            algorithm: GRID_NNIDW, data specifies the number of neighbors to
            use, the lower the value, the noisier (more local) the
            approximation is.
                GRID_NNLI, data specifies what a thin triangle is, in the
                range [1. .. 2.]. High values enable the usage of very thin
                triangles for interpolation, possibly resulting in error in
                the approximation.
                GRID_NNI, only weights greater than data will be accepted. If
                0, all weights will be accepted.

    """
    return _plplotc.plgriddata(Array, arg2, arg3, ArrayX, ArrayY, type, data)

def plgspa():
    """
    Get current subpage parameters

    DESCRIPTION:

        Gets the size of the current subpage in millimeters measured from the
        bottom left hand corner of the output device page or screen.  Can be
        used in conjunction with plsvpa for setting the size of a viewport in
        absolute coordinates (millimeters).

        Redacted form: plgspa(xmin, xmax, ymin, ymax)

        This function is used in example 23.



    SYNOPSIS:

    plgspa(xmin, xmax, ymin, ymax)

    ARGUMENTS:

        xmin (PLFLT_NC_SCALAR, output) :    Returned value of the position of
            the left hand edge of the subpage in millimeters.

        xmax (PLFLT_NC_SCALAR, output) :    Returned value of the position of
            the right hand edge of the subpage in millimeters.

        ymin (PLFLT_NC_SCALAR, output) :    Returned value of the position of
            the bottom edge of the subpage in millimeters.

        ymax (PLFLT_NC_SCALAR, output) :    Returned value of the position of
            the top edge of the subpage in millimeters.

    """
    return _plplotc.plgspa()

def plgstrm():
    """
    Get current stream number

    DESCRIPTION:

        Gets the number of the current output stream. See also plsstrm.

        Redacted form: plgstrm(p_strm)

        This function is used in example 1,20.



    SYNOPSIS:

    plgstrm(p_strm)

    ARGUMENTS:

        p_strm (PLINT_NC_SCALAR, output) :    Returned value of the current
            stream value.

    """
    return _plplotc.plgstrm()

def plgver():
    """
    Get the current library version number

    DESCRIPTION:

        Get the current library version number.  Note: you must have allocated
        space for this (80 characters is safe).

        Redacted form: plgver(p_ver)

        This function is used in example 1.



    SYNOPSIS:

    plgver(p_ver)

    ARGUMENTS:

        p_ver (PLCHAR_NC_VECTOR, output) :    Returned ascii character string
            (with preallocated length of 80 characters or more) containing the
            PLplot version number.

    """
    return _plplotc.plgver()

def plgvpd():
    """
    Get viewport limits in normalized device coordinates

    DESCRIPTION:

        Get viewport limits in normalized device coordinates.

        Redacted form: General: plgvpd(p_xmin, p_xmax, p_ymin, p_ymax)
                Perl/PDL: Not available?


        This function is used in example 31.



    SYNOPSIS:

    plgvpd(p_xmin, p_xmax, p_ymin, p_ymax)

    ARGUMENTS:

        p_xmin (PLFLT_NC_SCALAR, output) :    Returned value of the lower
            viewport limit of the normalized device coordinate in x.

        p_xmax (PLFLT_NC_SCALAR, output) :    Returned value of the upper
            viewport limit of the normalized device coordinate in x.

        p_ymin (PLFLT_NC_SCALAR, output) :    Returned value of the lower
            viewport limit of the normalized device coordinate in y.

        p_ymax (PLFLT_NC_SCALAR, output) :    Returned value of the upper
            viewport limit of the normalized device coordinate in y.

    """
    return _plplotc.plgvpd()

def plgvpw():
    """
    Get viewport limits in world coordinates

    DESCRIPTION:

        Get viewport limits in world coordinates.

        Redacted form: General: plgvpw(p_xmin, p_xmax, p_ymin, p_ymax)
                Perl/PDL: Not available?


        This function is used in example 31.



    SYNOPSIS:

    plgvpw(p_xmin, p_xmax, p_ymin, p_ymax)

    ARGUMENTS:

        p_xmin (PLFLT_NC_SCALAR, output) :    Returned value of the lower
            viewport limit of the world coordinate in x.

        p_xmax (PLFLT_NC_SCALAR, output) :    Returned value of the upper
            viewport limit of the world coordinate in x.

        p_ymin (PLFLT_NC_SCALAR, output) :    Returned value of the lower
            viewport limit of the world coordinate in y.

        p_ymax (PLFLT_NC_SCALAR, output) :    Returned value of the upper
            viewport limit of the world coordinate in y.

    """
    return _plplotc.plgvpw()

def plgxax():
    """
    Get x axis parameters

    DESCRIPTION:

        Returns current values of the p_digmax and p_digits flags for the x
        axis.  p_digits is updated after the plot is drawn, so this routine
        should only be called after the call to plbox (or plbox3) is complete.
         See the PLplot documentation for more information.

        Redacted form: plgxax(p_digmax, p_digits)

        This function is used in example 31.



    SYNOPSIS:

    plgxax(p_digmax, p_digits)

    ARGUMENTS:

        p_digmax (PLINT_NC_SCALAR, output) :    Returned value of the maximum
            number of digits for the x axis.  If nonzero, the printed label
            has been switched to a floating-point representation when the
            number of digits exceeds this value.

        p_digits (PLINT_NC_SCALAR, output) :    Returned value of the actual
            number of digits for the numeric labels (x axis) from the last
            plot.

    """
    return _plplotc.plgxax()

def plgyax():
    """
    Get y axis parameters

    DESCRIPTION:

        Identical to plgxax, except that arguments are flags for y axis. See
        the description of plgxax for more detail.

        Redacted form: plgyax(p_digmax, p_digits)

        This function is used in example 31.



    SYNOPSIS:

    plgyax(p_digmax, p_digits)

    ARGUMENTS:

        p_digmax (PLINT_NC_SCALAR, output) :    Returned value of the maximum
            number of digits for the y axis.  If nonzero, the printed label
            has been switched to a floating-point representation when the
            number of digits exceeds this value.

        p_digits (PLINT_NC_SCALAR, output) :    Returned value of the actual
            number of digits for the numeric labels (y axis) from the last
            plot.

    """
    return _plplotc.plgyax()

def plgzax():
    """
    Get z axis parameters

    DESCRIPTION:

        Identical to plgxax, except that arguments are flags for z axis. See
        the description of plgxax for more detail.

        Redacted form: plgzax(p_digmax, p_digits)

        This function is used in example 31.



    SYNOPSIS:

    plgzax(p_digmax, p_digits)

    ARGUMENTS:

        p_digmax (PLINT_NC_SCALAR, output) :    Returned value of the maximum
            number of digits for the z axis.  If nonzero, the printed label
            has been switched to a floating-point representation when the
            number of digits exceeds this value.

        p_digits (PLINT_NC_SCALAR, output) :    Returned value of the actual
            number of digits for the numeric labels (z axis) from the last
            plot.

    """
    return _plplotc.plgzax()

def plhist(n, datmin, datmax, nbin, oldwin):
    """
    Plot a histogram from unbinned data

    DESCRIPTION:

        Plots a histogram from n data points stored in the data vector.  This
        routine bins the data into nbin bins equally spaced between datmin and
        datmax, and calls plbin to draw the resulting histogram.  Parameter
        opt allows, among other things, the histogram either to be plotted in
        an existing window or causes plhist to call plenv with suitable limits
        before plotting the histogram.

        Redacted form: plhist(data, datmin, datmax, nbin, opt)

        This function is used in example 5.



    SYNOPSIS:

    plhist(n, data, datmin, datmax, nbin, opt)

    ARGUMENTS:

        n (PLINT, input) :    Number of data points.

        data (PLFLT_VECTOR, input) :    A vector containing the values of the
            n data points.

        datmin (PLFLT, input) :    Left-hand edge of lowest-valued bin.

        datmax (PLFLT, input) :    Right-hand edge of highest-valued bin.

        nbin (PLINT, input) :    Number of (equal-sized) bins into which to
            divide the interval xmin to xmax.

        opt (PLINT, input) :    Is a combination of several flags:
            opt=PL_HIST_DEFAULT: The axes are automatically rescaled to fit
            the histogram data, the outer bins are expanded to fill up the
            entire x-axis, data outside the given extremes are assigned to the
            outer bins and bins of zero height are simply drawn.
                opt=PL_HIST_NOSCALING|...: The existing axes are not rescaled
                to fit the histogram data, without this flag, plenv is called
                to set the world coordinates.
                opt=PL_HIST_IGNORE_OUTLIERS|...: Data outside the given
                extremes are not taken into account. This option should
                probably be combined with opt=PL_HIST_NOEXPAND|..., so as to
                properly present the data.
                opt=PL_HIST_NOEXPAND|...: The outer bins are drawn with equal
                size as the ones inside.
                opt=PL_HIST_NOEMPTY|...: Bins with zero height are not drawn
                (there is a gap for such bins).

    """
    return _plplotc.plhist(n, datmin, datmax, nbin, oldwin)

def plhlsrgb(h, l, s):
    """
    Convert HLS color to RGB

    DESCRIPTION:

        Convert HLS color coordinates to RGB.

        Redacted form: General: plhlsrgb(h, l, s, p_r, p_g, p_b)
                Perl/PDL: Not available? Implemented as plhls?


        This function is used in example 2.



    SYNOPSIS:

    plhlsrgb(h, l, s, p_r, p_g, p_b)

    ARGUMENTS:

        h (PLFLT, input) :    Hue in degrees (0.0-360.0) on the color
            cylinder.

        l (PLFLT, input) :    Lightness expressed as a fraction (0.0-1.0) of
            the axis of the color cylinder.

        s (PLFLT, input) :    Saturation expressed as a fraction (0.0-1.0) of
            the radius of the color cylinder.

        p_r (PLFLT_NC_SCALAR, output) :    Returned value of the red intensity
            (0.0-1.0) of the color.

        p_g (PLFLT_NC_SCALAR, output) :    Returned value of the green
            intensity (0.0-1.0) of the color.

        p_b (PLFLT_NC_SCALAR, output) :    Returned value of the blue
            intensity (0.0-1.0) of the color.

    """
    return _plplotc.plhlsrgb(h, l, s)

def plinit():
    """
    Initialize PLplot

    DESCRIPTION:

        Initializing the plotting package.  The program prompts for the device
        keyword or number of the desired output device.  Hitting a RETURN in
        response to the prompt is the same as selecting the first device.
        plinit will issue no prompt if either the device was specified
        previously (via command line flag, the plsetopt function, or the
        plsdev function), or if only one device is enabled when PLplot is
        installed.  If subpages have been specified, the output device is
        divided into nx by ny subpages, each of which may be used
        independently.  If plinit is called again during a program, the
        previously opened file will be closed.  The subroutine pladv is used
        to advance from one subpage to the next.

        Redacted form: plinit()

        This function is used in all of the examples.



    SYNOPSIS:

    plinit()

    """
    return _plplotc.plinit()

def pljoin(x1, y1, x2, y2):
    """
    Draw a line between two points

    DESCRIPTION:

        Joins the point (
        x1,
        y1) to (
        x2,
        y2).

        Redacted form: pljoin(x1,y1,x2,y2)

        This function is used in examples 3 and 14.



    SYNOPSIS:

    pljoin(x1, y1, x2, y2)

    ARGUMENTS:

        x1 (PLFLT, input) :    x coordinate of first point.

        y1 (PLFLT, input) :    y coordinate of first point.

        x2 (PLFLT, input) :    x coordinate of second point.

        y2 (PLFLT, input) :    y coordinate of second point.

    """
    return _plplotc.pljoin(x1, y1, x2, y2)

def pllab(xlabel, ylabel, tlabel):
    """
    Simple routine to write labels

    DESCRIPTION:

        Routine for writing simple labels. Use plmtex for more complex labels.

        Redacted form: pllab(xlabel, ylabel, tlabel)

        This function is used in examples 1, 5, 9, 12, 14-16, 20-22, and 29.



    SYNOPSIS:

    pllab(xlabel, ylabel, tlabel)

    ARGUMENTS:

        xlabel (PLCHAR_VECTOR, input) :    A UTF-8 character string specifying
            the label for the x axis.

        ylabel (PLCHAR_VECTOR, input) :    A UTF-8 character string specifying
            the label for the y axis.

        tlabel (PLCHAR_VECTOR, input) :    A UTF-8 character string specifying
            the title of the plot.

    """
    return _plplotc.pllab(xlabel, ylabel, tlabel)

def pllegend(opt, position, x, y, plot_width, bg_color, bb_color, bb_style, nrow, ncolumn, n, text_offset, text_scale, text_spacing, text_justification, arg18, arg19, arg20, arg21, arg22, arg23, arg24, arg25, arg26, arg27, arg28, arg29, arg30):
    """
    Plot legend using discretely annotated filled boxes, lines, and/or lines of symbols

    DESCRIPTION:

        Routine for creating a discrete plot legend with a plotted filled box,
        line, and/or line of symbols for each annotated legend entry.  (See
        plcolorbar for similar functionality for creating continuous color
        bars.)  The arguments of pllegend provide control over the location
        and size of the legend as well as the location and characteristics of
        the elements (most of which are optional) within that legend.  The
        resulting legend is clipped at the boundaries of the current subpage.
        (N.B. the adopted coordinate system used for some of the parameters is
        defined in the documentation of the position parameter.)

        Redacted form: pllegend(p_legend_width, p_legend_height, opt,
        position, x, y, plot_width, bg_color, bb_color, bb_style, nrow,
        ncolumn, opt_array, text_offset, text_scale, text_spacing,
        test_justification, text_colors, text, box_colors, box_patterns,
        box_scales, box_line_widths, line_colors, line_styles, line_widths,
        symbol_colors, symbol_scales, symbol_numbers, symbols)

        This function is used in examples 4, 26, and 33.



    SYNOPSIS:

    pllegend(p_legend_width, p_legend_height, opt, position, x, y, plot_width, bg_color, bb_color, bb_style, nrow, ncolumn, nlegend, opt_array, text_offset, text_scale, text_spacing, test_justification, text_colors, text, box_colors, box_patterns, box_scales, box_line_widths, line_colors, line_styles, line_widths, symbol_colors, symbol_scales, symbol_numbers, symbols)

    ARGUMENTS:

        p_legend_width (PLFLT_NC_SCALAR, output) :    Returned value of the
            legend width in adopted coordinates. This quantity is calculated
            from plot_width, text_offset, ncolumn (possibly modified inside
            the routine depending on nlegend and nrow), and the length
            (calculated internally) of the longest text string.

        p_legend_height (PLFLT_NC_SCALAR, output) :    Returned value of the
            legend height in adopted coordinates. This quantity is calculated
            from text_scale, text_spacing, and nrow (possibly modified inside
            the routine depending on nlegend and nrow).

        opt (PLINT, input) :    opt contains bits controlling the overall
            legend. If the PL_LEGEND_TEXT_LEFT bit is set, put the text area
            on the left of the legend and the plotted area on the right.
            Otherwise, put the text area on the right of the legend and the
            plotted area on the left. If the PL_LEGEND_BACKGROUND bit is set,
            plot a (semitransparent) background for the legend. If the
            PL_LEGEND_BOUNDING_BOX bit is set, plot a bounding box for the
            legend. If the PL_LEGEND_ROW_MAJOR bit is set and (both of the
            possibly internally transformed) nrow > 1 and ncolumn > 1, then
            plot the resulting array of legend entries in row-major order.
            Otherwise, plot the legend entries in column-major order.

        position (PLINT, input) :    position contains bits which control the
            overall position of the legend and the definition of the adopted
            coordinates used for positions just like what is done for the
            position argument for plcolorbar. However, note that the defaults
            for the position bits (see below) are different than the
            plcolorbar case.  The combination of the PL_POSITION_LEFT,
            PL_POSITION_RIGHT, PL_POSITION_TOP, PL_POSITION_BOTTOM,
            PL_POSITION_INSIDE, and PL_POSITION_OUTSIDE bits specifies one of
            the 16 possible standard positions (the 4 corners and centers of
            the 4 sides for both the inside and outside cases) of the legend
            relative to the adopted coordinate system. The corner positions
            are specified by the appropriate combination of two of the
            PL_POSITION_LEFT, PL_POSITION_RIGHT, PL_POSITION_TOP, and
            PL_POSITION_BOTTOM bits while the sides are specified by a single
            value of one of those bits.  The adopted coordinates are
            normalized viewport coordinates if the PL_POSITION_VIEWPORT bit is
            set or normalized subpage coordinates if the PL_POSITION_SUBPAGE
            bit is set. Default position bits: If none of PL_POSITION_LEFT,
            PL_POSITION_RIGHT, PL_POSITION_TOP, or PL_POSITION_BOTTOM are set,
            then use the combination of PL_POSITION_RIGHT and PL_POSITION_TOP.
            If neither of PL_POSITION_INSIDE or PL_POSITION_OUTSIDE is set,
            use PL_POSITION_INSIDE. If neither of PL_POSITION_VIEWPORT or
            PL_POSITION_SUBPAGE is set, use PL_POSITION_VIEWPORT.

        x (PLFLT, input) :    X offset of the legend position in adopted
            coordinates from the specified standard position of the legend.
            For positive x, the direction of motion away from the standard
            position is inward/outward from the standard corner positions or
            standard left or right positions if the
            PL_POSITION_INSIDE/PL_POSITION_OUTSIDE bit is set in position.
            For the standard top or bottom positions, the direction of motion
            is toward positive X.

        y (PLFLT, input) :    Y offset of the legend position in adopted
            coordinates from the specified standard position of the legend.
            For positive y, the direction of motion away from the standard
            position is inward/outward from the standard corner positions or
            standard top or bottom positions if the
            PL_POSITION_INSIDE/PL_POSITION_OUTSIDE bit is set in position. For
            the standard left or right positions, the direction of motion is
            toward positive Y.

        plot_width (PLFLT, input) :    Horizontal width in adopted coordinates
            of the plot area (where the colored boxes, lines, and/or lines of
            symbols are drawn) of the legend.

        bg_color (PLINT, input) :    The cmap0 color of the background for the
            legend (PL_LEGEND_BACKGROUND).

        bb_color (PLINT, input) :    The cmap0 color of the bounding-box line
            for the legend (PL_LEGEND_BOUNDING_BOX).

        bb_style (PLINT, input) :    The pllsty style number for the
            bounding-box line for the legend (PL_LEGEND_BACKGROUND).

        nrow (PLINT, input) :    The cmap0 index of the background color for
            the legend (PL_LEGEND_BACKGROUND).

        ncolumn (PLINT, input) :    The cmap0 index of the background color
            for the legend (PL_LEGEND_BACKGROUND).

        nlegend (PLINT, input) :    Number of legend entries.  N.B.  The total
            vertical height of the legend in adopted coordinates is calculated
            internally from nlegend, text_scale (see below), and text_spacing
            (see below).

        opt_array (PLINT_VECTOR, input) :    A vector of
        nlegend values of options to control each individual plotted area
            corresponding to a legend entry.  If the
        PL_LEGEND_NONE bit is set, then nothing is plotted in the plotted
            area.  If the
        PL_LEGEND_COLOR_BOX,
        PL_LEGEND_LINE, and/or
        PL_LEGEND_SYMBOL bits are set, the area corresponding to a legend
            entry is plotted with a colored box; a line; and/or a line of
            symbols.

        text_offset (PLFLT, input) :    Offset of the text area from the plot
            area in units of character width.  N.B.  The total horizontal
            width of the legend in adopted coordinates is calculated
            internally from
        plot_width (see above),
        text_offset, and length (calculated internally) of the longest text
            string.

        text_scale (PLFLT, input) :    Character height scale for text
            annotations.  N.B.  The total vertical height of the legend in
            adopted coordinates is calculated internally from
        nlegend (see above),
        text_scale, and
        text_spacing (see below).

        text_spacing (PLFLT, input) :    Vertical spacing in units of the
            character height from one legend entry to the next.  N.B.  The
            total vertical height of the legend in adopted coordinates is
            calculated internally from
        nlegend (see above),
        text_scale (see above), and
        text_spacing.

        text_justification (PLFLT, input) :    Justification parameter used
            for text justification.  The most common values of
            text_justification are 0., 0.5, or 1. corresponding to a text that
            is left justified, centred, or right justified within the text
            area, but other values are allowed as well.

        text_colors (PLINT_VECTOR, input) :    A vector containing
        nlegend cmap0 text colors.

        text (PLCHAR_MATRIX, input) :    A vector of
        nlegend UTF-8 character strings containing the legend annotations.

        box_colors (PLINT_VECTOR, input) :    A vector containing
        nlegend cmap0 colors for the discrete colored boxes (
        PL_LEGEND_COLOR_BOX).

        box_patterns (PLINT_VECTOR, input) :    A vector containing
        nlegend patterns (plpsty indices) for the discrete colored boxes (
        PL_LEGEND_COLOR_BOX).

        box_scales (PLFLT_VECTOR, input) :    A vector containing
        nlegend scales (units of fraction of character height) for the height
            of the discrete colored boxes (
        PL_LEGEND_COLOR_BOX).

        box_line_widths (PLFLT_VECTOR, input) :    A vector containing
        nlegend line widths for the patterns specified by box_patterns (
        PL_LEGEND_COLOR_BOX).

        line_colors (PLINT_VECTOR, input) :    A vector containing
        nlegend cmap0 line colors (
        PL_LEGEND_LINE).

        line_styles (PLINT_VECTOR, input) :    A vector containing
        nlegend line styles (plsty indices) (
        PL_LEGEND_LINE).

        line_widths (PLFLT_VECTOR, input) :    A vector containing
        nlegend line widths (
        PL_LEGEND_LINE).

        symbol_colors (PLINT_VECTOR, input) :    A vector containing
        nlegend cmap0 symbol colors (
        PL_LEGEND_SYMBOL).

        symbol_scales (PLFLT_VECTOR, input) :    A vector containing
        nlegend scale values for the symbol height (
        PL_LEGEND_SYMBOL).

        symbol_numbers (PLINT_VECTOR, input) :    A vector containing
        nlegend numbers of symbols to be drawn across the width of the plotted
            area (
        PL_LEGEND_SYMBOL).

        symbols (PLCHAR_MATRIX, input) :    A vector of
        nlegend UTF-8 character strings containing the legend symbols. (
        PL_LEGEND_SYMBOL).

    """
    return _plplotc.pllegend(opt, position, x, y, plot_width, bg_color, bb_color, bb_style, nrow, ncolumn, n, text_offset, text_scale, text_spacing, text_justification, arg18, arg19, arg20, arg21, arg22, arg23, arg24, arg25, arg26, arg27, arg28, arg29, arg30)

def plcolorbar(opt, position, x, y, x_length, y_length, bg_color, bb_color, bb_style, low_cap_color, high_cap_color, cont_color, cont_width, arg16, arg17, arg18, arg19, arg20, ArrayN, MatrixCk):
    """
    Plot color bar for image, shade or gradient plots

    DESCRIPTION:

        Routine for creating a continuous color bar for image, shade, or
        gradient plots. (See pllegend for similar functionality for creating
        legends with discrete elements). The arguments of plcolorbar provide
        control over the location and size of the color bar as well as the
        location and characteristics of the elements (most of which are
        optional) within that color bar.  The resulting color bar is clipped
        at the boundaries of the current subpage. (N.B. the adopted coordinate
        system used for some of the parameters is defined in the documentation
        of the position parameter.)

        Redacted form: plcolorbar(p_colorbar_width, p_colorbar_height, opt,
        position, x, y, x_length, y_length, bg_color, bb_color, bb_style,
        low_cap_color, high_cap_color, cont_color, cont_width, label_opts,
        labels, axis_opts, ticks, sub_ticks, values)

        This function is used in examples 16 and 33.



    SYNOPSIS:

    plcolorbar(p_colorbar_width, p_colorbar_height, opt, position, x, y, x_length, y_length, bg_color, bb_color, bb_style, low_cap_color, high_cap_color, cont_color, cont_width, n_labels, label_opts, labels, naxes, axis_opts, ticks, sub_ticks, n_values, values)

    ARGUMENTS:

        p_colorbar_width (PLFLT_NC_SCALAR, output) :    Returned value of the
            labelled and decorated color bar width in adopted coordinates.

        p_colorbar_height (PLFLT_NC_SCALAR, output) :    Returned value of the
            labelled and decorated color bar height in adopted coordinates.

        opt (PLINT, input) :    opt contains bits controlling the overall
            color bar.  The orientation (direction of the maximum value) of
            the color bar is specified with PL_ORIENT_RIGHT, PL_ORIENT_TOP,
            PL_ORIENT_LEFT, or PL_ORIENT_BOTTOM.  If none of these bits are
            specified, the default orientation is toward the top if the
            colorbar is placed on the left or right of the viewport or toward
            the right if the colorbar is placed on the top or bottom of the
            viewport. If the PL_COLORBAR_BACKGROUND bit is set, plot a
            (semitransparent) background for the color bar. If the
            PL_COLORBAR_BOUNDING_BOX bit is set, plot a bounding box for the
            color bar. The type of color bar must be specified with one of
            PL_COLORBAR_IMAGE, PL_COLORBAR_SHADE, or PL_COLORBAR_GRADIENT. If
            more than one of those bits is set only the first one in the above
            list is honored. The position of the (optional) label/title can be
            specified with PL_LABEL_RIGHT, PL_LABEL_TOP, PL_LABEL_LEFT, or
            PL_LABEL_BOTTOM.  If no label position bit is set then no label
            will be drawn. If more than one of this list of bits is specified,
            only the first one on the list is honored. End-caps for the color
            bar can added with PL_COLORBAR_CAP_LOW and PL_COLORBAR_CAP_HIGH.
            If a particular color bar cap option is not specified then no cap
            will be drawn for that end. As a special case for
            PL_COLORBAR_SHADE, the option PL_COLORBAR_SHADE_LABEL can be
            specified. If this option is provided then any tick marks and tick
            labels will be placed at the breaks between shaded segments. TODO:
            This should be expanded to support custom placement of tick marks
            and tick labels at custom value locations for any color bar type.

        position (PLINT, input) :    position contains bits which control the
            overall position of the color bar and the definition of the
            adopted coordinates used for positions just like what is done for
            the position argument for pllegend. However, note that the
            defaults for the position bits (see below) are different than the
            pllegend case. The combination of the PL_POSITION_LEFT,
            PL_POSITION_RIGHT, PL_POSITION_TOP, PL_POSITION_BOTTOM,
            PL_POSITION_INSIDE, and PL_POSITION_OUTSIDE bits specifies one of
            the 16 possible standard positions (the 4 corners and centers of
            the 4 sides for both the inside and outside cases) of the color
            bar relative to the adopted coordinate system. The corner
            positions are specified by the appropriate combination of two of
            the PL_POSITION_LEFT, PL_POSITION_RIGHT, PL_POSITION_TOP, and
            PL_POSITION_BOTTOM bits while the sides are specified by a single
            value of one of those bits.  The adopted coordinates are
            normalized viewport coordinates if the PL_POSITION_VIEWPORT bit is
            set or normalized subpage coordinates if the PL_POSITION_SUBPAGE
            bit is set. Default position bits: If none of PL_POSITION_LEFT,
            PL_POSITION_RIGHT, PL_POSITION_TOP, or PL_POSITION_BOTTOM are set,
            then use PL_POSITION_RIGHT. If neither of PL_POSITION_INSIDE or
            PL_POSITION_OUTSIDE is set, use PL_POSITION_OUTSIDE. If neither of
            PL_POSITION_VIEWPORT or PL_POSITION_SUBPAGE is set, use
            PL_POSITION_VIEWPORT.

        x (PLFLT, input) :    X offset of the color bar position in adopted
            coordinates from the specified standard position of the color bar.
            For positive x, the direction of motion away from the standard
            position is inward/outward from the standard corner positions or
            standard left or right positions if the
            PL_POSITION_INSIDE/PL_POSITION_OUTSIDE bit is set in position.
            For the standard top or bottom positions, the direction of motion
            is toward positive X.

        y (PLFLT, input) :    Y offset of the color bar position in adopted
            coordinates from the specified standard position of the color bar.
            For positive y, the direction of motion away from the standard
            position is inward/outward from the standard corner positions or
            standard top or bottom positions if the
            PL_POSITION_INSIDE/PL_POSITION_OUTSIDE bit is set in position.
            For the standard left or right positions, the direction of motion
            is toward positive Y.

        x_length (PLFLT, input) :    Length of the body of the color bar in
            the X direction in adopted coordinates.

        y_length (PLFLT, input) :    Length of the body of the color bar in
            the Y direction in adopted coordinates.

        bg_color (PLINT, input) :    The cmap0 color of the background for the
            color bar (PL_COLORBAR_BACKGROUND).

        bb_color (PLINT, input) :    The cmap0 color of the bounding-box line
            for the color bar (PL_COLORBAR_BOUNDING_BOX).

        bb_style (PLINT, input) :    The pllsty style number for the
            bounding-box line for the color bar (PL_COLORBAR_BACKGROUND).

        low_cap_color (PLFLT, input) :    The cmap1 color of the low-end color
            bar cap, if it is drawn (PL_COLORBAR_CAP_LOW).

        high_cap_color (PLFLT, input) :    The cmap1 color of the high-end
            color bar cap, if it is drawn (PL_COLORBAR_CAP_HIGH).

        cont_color (PLINT, input) :    The cmap0 contour color for
            PL_COLORBAR_SHADE plots. This is passed directly to plshades, so
            it will be interpreted according to the design of plshades.

        cont_width (PLFLT, input) :    Contour width for PL_COLORBAR_SHADE
            plots. This is passed directly to plshades, so it will be
            interpreted according to the design of plshades.

        n_labels (PLINT, input) :    Number of labels to place around the
            color bar.

        label_opts (PLINT_VECTOR, input) :    A vector of options for each of
        n_labels labels.

        labels (PLCHAR_MATRIX, input) :    A vector of
        n_labels UTF-8 character strings containing the labels for the color
            bar.  Ignored if no label position is specified with one of the
            PL_COLORBAR_LABEL_RIGHT, PL_COLORBAR_LABEL_TOP,
            PL_COLORBAR_LABEL_LEFT, or PL_COLORBAR_LABEL_BOTTOM bits in the
            corresponding label_opts field.

        n_axes (PLINT, input) :    Number of axis definitions provided. This
            value must be greater than 0. It is typically 1 (numerical axis
            labels are provided for one of the long edges of the color bar),
            but it can be larger if multiple numerical axis labels for the
            long edges of the color bar are desired.

        axis_opts (PLCHAR_MATRIX, input) :    A vector of
        n_axes ascii character strings containing options (interpreted as for
            plbox) for the color bar's axis definitions.

        ticks (PLFLT_VECTOR, input) :    A vector of n_axes values of the
            spacing of the major tick marks (interpreted as for plbox) for the
            color bar's axis definitions.

        sub_ticks (PLINT_VECTOR, input) :    A vector of n_axes values of the
            number of subticks (interpreted as for plbox) for the color bar's
            axis definitions.

        n_values (PLINT_VECTOR, input) :    A vector containing the number of
            elements in each of the n_axes rows of the values matrix.

        values (PLFLT_MATRIX, input) :    A matrix containing the numeric
            values for the data range represented by the color bar. For a row
            index of i_axis (where 0 < i_axis < n_axes), the number of
            elements in the row is specified by n_values[i_axis]. For
            PL_COLORBAR_IMAGE and PL_COLORBAR_GRADIENT the number of elements
            is 2, and the corresponding row elements of the values matrix are
            the minimum and maximum value represented by the colorbar.  For
            PL_COLORBAR_SHADE, the number and values of the elements of a row
            of the values matrix is interpreted the same as the nlevel and
            clevel arguments of plshades.

    """
    return _plplotc.plcolorbar(opt, position, x, y, x_length, y_length, bg_color, bb_color, bb_style, low_cap_color, high_cap_color, cont_color, cont_width, arg16, arg17, arg18, arg19, arg20, ArrayN, MatrixCk)

def pllightsource(x, y, z):
    """
    Sets the 3D position of the light source

    DESCRIPTION:

        Sets the 3D position of the light source for use with plsurf3d and
        plsurf3dl

        Redacted form: pllightsource(x, y, z)

        This function is used in example 8.



    SYNOPSIS:

    pllightsource(x, y, z)

    ARGUMENTS:

        x (PLFLT, input) :    X-coordinate of the light source.

        y (PLFLT, input) :    Y-coordinate of the light source.

        z (PLFLT, input) :    Z-coordinate of the light source.

    """
    return _plplotc.pllightsource(x, y, z)

def plline(n, ArrayCk):
    """
    Draw a line

    DESCRIPTION:

        Draws line defined by n points in x and y.

        Redacted form: plline(x, y)

        This function is used in examples 1, 3, 4, 9, 12-14, 16, 18, 20, 22,
        25-27, and 29.



    SYNOPSIS:

    plline(n, x, y)

    ARGUMENTS:

        n (PLINT, input) :    Number of points defining line.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            points.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            points.

    """
    return _plplotc.plline(n, ArrayCk)

def plline3(n, arg2, arg3):
    """
    Draw a line in 3 space

    DESCRIPTION:

        Draws line in 3 space defined by n points in x, y, and z. You must
        first set up the viewport, the 2d viewing window (in world
        coordinates), and the 3d normalized coordinate box.  See x18c.c for
        more info.

        Redacted form: plline3(x, y, z)

        This function is used in example 18.



    SYNOPSIS:

    plline3(n, x, y, z)

    ARGUMENTS:

        n (PLINT, input) :    Number of points defining line.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            points.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            points.

        z (PLFLT_VECTOR, input) :    A vector containing the z coordinates of
            points.

    """
    return _plplotc.plline3(n, arg2, arg3)

def pllsty(lin):
    """
    Select line style

    DESCRIPTION:

        This sets the line style according to one of eight predefined patterns
        (also see plstyl).

        Redacted form: pllsty(lin)

        This function is used in examples 9, 12, 22, and 25.



    SYNOPSIS:

    pllsty(lin)

    ARGUMENTS:

        lin (PLINT, input) :    Integer value between 1 and 8. Line style 1 is
            a continuous line, line style 2 is a line with short dashes and
            gaps, line style 3 is a line with long dashes and gaps, line style
            4 has long dashes and short gaps and so on.

    """
    return _plplotc.pllsty(lin)

def plmesh(ArrayX, ArrayY, MatrixCk, opt):
    """
    Plot surface mesh

    DESCRIPTION:

        Plots a surface mesh within the environment set up by plw3d.  The
        surface is defined by the matrix z[
        nx][
        ny] , the point z[i][j] being the value of the function at (
        x[i],
        y[j]). Note that the points in vectors x and y do not need to be
        equally spaced, but must be stored in ascending order.  The parameter
        opt controls the way in which the surface is displayed.  For further
        details see the PLplot documentation.

        Redacted form: plmesh(x, y, z, opt)

        This function is used in example 11.



    SYNOPSIS:

    plmesh(x, y, z, nx, ny, opt)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates at
            which the function is evaluated.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates at
            which the function is evaluated.

        z (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    Number of x values at which function has been
            evaluated.

        ny (PLINT, input) :    Number of y values at which function has been
            evaluated.

        opt (PLINT, input) :    Determines the way in which the surface is
            represented: opt=DRAW_LINEX : Lines are drawn showing z as a
            function of x for each value of y[j] .
                opt=DRAW_LINEY : Lines are drawn showing z as a function of y
                for each value of x[i] .
                opt=DRAW_LINEXY : Network of lines is drawn connecting points
                at which function is defined.

    """
    return _plplotc.plmesh(ArrayX, ArrayY, MatrixCk, opt)

def plmeshc(ArrayX, ArrayY, MatrixCk, opt, Array):
    """
    Magnitude colored plot surface mesh with contour

    DESCRIPTION:

        A more powerful form of plmesh: the surface mesh can be colored
        accordingly to the current z value being plotted, a contour plot can
        be drawn at the base XY plane, and a curtain can be drawn between the
        plotted function border and the base XY plane.

        Redacted form: plmeshc(x, y, z, opt, clevel)

        This function is used in example 11.



    SYNOPSIS:

    plmeshc(x, y, z, nx, ny, opt, clevel, nlevel)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates at
            which the function is evaluated.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates at
            which the function is evaluated.

        z (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    Number of x values at which function is
            evaluated.

        ny (PLINT, input) :    Number of y values at which function is
            evaluated.

        opt (PLINT, input) :    Determines the way in which the surface is
            represented. To specify more than one option just add the options,
            e.g. DRAW_LINEXY + MAG_COLOR opt=DRAW_LINEX : Lines are drawn
            showing z as a function of x for each value of y[j] .
                opt=DRAW_LINEY : Lines are drawn showing z as a function of y
                for each value of x[i] .
                opt=DRAW_LINEXY : Network of lines is drawn connecting points
                at which function is defined.
                opt=MAG_COLOR : Each line in the mesh is colored according to
                the z value being plotted. The color is used from the current
                cmap1.
                opt=BASE_CONT : A contour plot is drawn at the base XY plane
                using parameters
        nlevel and
        clevel.
                opt=DRAW_SIDES : draws a curtain between the base XY plane and
                the borders of the plotted function.


        clevel (PLFLT_VECTOR, input) :    A vector containing the contour
            levels.

        nlevel (PLINT, input) :    Number of elements in the clevel vector.

    """
    return _plplotc.plmeshc(ArrayX, ArrayY, MatrixCk, opt, Array)

def plmkstrm():
    """
    Creates a new stream and makes it the default

    DESCRIPTION:

        Creates a new stream and makes it the default.  Differs from using
        plsstrm, in that a free stream number is found, and returned.
        Unfortunately, I have to start at stream 1 and work upward, since
        stream 0 is preallocated.  One of the big flaws in the PLplot API is
        that no initial, library-opening call is required.  So stream 0 must
        be preallocated, and there is no simple way of determining whether it
        is already in use or not.

        Redacted form: plmkstrm(p_strm)

        This function is used in examples 1 and 20.



    SYNOPSIS:

    plmkstrm(p_strm)

    ARGUMENTS:

        p_strm (PLINT_NC_SCALAR, output) :    Returned value of the stream
            number of the created stream.

    """
    return _plplotc.plmkstrm()

def plmtex(side, disp, pos, just, text):
    """
    Write text relative to viewport boundaries

    DESCRIPTION:

        Writes text at a specified position relative to the viewport
        boundaries.  Text may be written inside or outside the viewport, but
        is clipped at the subpage boundaries.  The reference point of a string
        lies along a line passing through the string at half the height of a
        capital letter.  The position of the reference point along this line
        is determined by just, and the position of the reference point
        relative to the viewport is set by disp and pos.

        Redacted form: General: plmtex(side, disp, pos, just, text)
                Perl/PDL: plmtex(disp, pos, just, side, text)


        This function is used in examples 3, 4, 6-8, 11, 12, 14, 18, 23, and
        26.



    SYNOPSIS:

    plmtex(side, disp, pos, just, text)

    ARGUMENTS:

        side (PLCHAR_VECTOR, input) :    An ascii character string specifying
            the side of the viewport along which the text is to be written.
            The string must be one of: b: Bottom of viewport, text written
            parallel to edge.
                bv: Bottom of viewport, text written at right angles to edge.
                l: Left of viewport, text written parallel to edge.
                lv: Left of viewport, text written at right angles to edge.
                r: Right of viewport, text written parallel to edge.
                rv: Right of viewport, text written at right angles to edge.
                t: Top of viewport, text written parallel to edge.
                tv: Top of viewport, text written at right angles to edge.


        disp (PLFLT, input) :    Position of the reference point of string,
            measured outwards from the specified viewport edge in units of the
            current character height.  Use negative disp to write within the
            viewport.

        pos (PLFLT, input) :    Position of the reference point of string
            along the specified edge, expressed as a fraction of the length of
            the edge.

        just (PLFLT, input) :    Specifies the position of the string relative
            to its reference point.  If just=0. , the reference point is at
            the left and if just=1. , it is at the right of the string.  Other
            values of just give intermediate justifications.

        text (PLCHAR_VECTOR, input) :    A UTF-8 character string to be
            written out.

    """
    return _plplotc.plmtex(side, disp, pos, just, text)

def plmtex3(side, disp, pos, just, text):
    """
    Write text relative to viewport boundaries in 3D plots

    DESCRIPTION:

        Writes text at a specified position relative to the viewport
        boundaries.  Text may be written inside or outside the viewport, but
        is clipped at the subpage boundaries.  The reference point of a string
        lies along a line passing through the string at half the height of a
        capital letter.  The position of the reference point along this line
        is determined by just, and the position of the reference point
        relative to the viewport is set by disp and pos.

        Redacted form: plmtex3(side, disp, pos, just, text)

        This function is used in example 28.



    SYNOPSIS:

    plmtex3(side, disp, pos, just, text)

    ARGUMENTS:

        side (PLCHAR_VECTOR, input) :    An ascii character string specifying
            the side of the viewport along which the text is to be written.
            The string should contain one or more of the following characters:
            [xyz][ps][v]. Only one label is drawn at a time, i.e. xyp will
            only label the X axis, not both the X and Y axes. x: Label the X
            axis.
                y: Label the Y axis.
                z: Label the Z axis.
                p: Label the primary axis. For Z this is the leftmost Z axis.
                For X it is the axis that starts at y-min. For Y it is the
                axis that starts at x-min.
                s: Label the secondary axis.
                v: Draw the text perpendicular to the axis.


        disp (PLFLT, input) :    Position of the reference point of string,
            measured outwards from the specified viewport edge in units of the
            current character height.  Use negative disp to write within the
            viewport.

        pos (PLFLT, input) :    Position of the reference point of string
            along the specified edge, expressed as a fraction of the length of
            the edge.

        just (PLFLT, input) :    Specifies the position of the string relative
            to its reference point.  If just=0. , the reference point is at
            the left and if just=1. , it is at the right of the string.  Other
            values of just give intermediate justifications.

        text (PLCHAR_VECTOR, input) :    A UTF-8 character string to be
            written out.

    """
    return _plplotc.plmtex3(side, disp, pos, just, text)

def plot3d(ArrayX, ArrayY, MatrixCk, opt, side):
    """
    Plot 3-d surface plot

    DESCRIPTION:

        Plots a three-dimensional surface plot within the environment set up
        by plw3d.  The surface is defined by the matrix z[
        nx][
        ny] , the point z[i][j] being the value of the function at (
        x[i],
        y[j]). Note that the points in vectors x and y do not need to be
        equally spaced, but must be stored in ascending order.  The parameter
        opt controls the way in which the surface is displayed.  For further
        details see the PLplot documentation. The only difference between
        plmesh and plot3d is that plmesh draws the bottom side of the surface,
        while plot3d only draws the surface as viewed from the top.

        Redacted form: plot3d(x, y, z, opt, side)

        This function is used in examples 11 and 21.



    SYNOPSIS:

    plot3d(x, y, z, nx, ny, opt, side)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates at
            which the function is evaluated.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates at
            which the function is evaluated.

        z (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    Number of x values at which function is
            evaluated.

        ny (PLINT, input) :    Number of y values at which function is
            evaluated.

        opt (PLINT, input) :    Determines the way in which the surface is
            represented: opt=DRAW_LINEX : Lines are drawn showing z as a
            function of x for each value of y[j] .
                opt=DRAW_LINEY : Lines are drawn showing z as a function of y
                for each value of x[i] .
                opt=DRAW_LINEXY : Network of lines is drawn connecting points
                at which function is defined.


        side (PLBOOL, input) :    Flag to indicate whether or not ``sides''
            should be draw on the figure.  If side is true sides are drawn,
            otherwise no sides are drawn.

    """
    return _plplotc.plot3d(ArrayX, ArrayY, MatrixCk, opt, side)

def plot3dc(ArrayX, ArrayY, MatrixCk, opt, Array):
    """
    Magnitude colored plot surface with contour

    DESCRIPTION:

        Aside from dropping the
        side functionality this is a more powerful form of plot3d: the surface
        mesh can be colored accordingly to the current z value being plotted,
        a contour plot can be drawn at the base XY plane, and a curtain can be
        drawn between the plotted function border and the base XY plane. The
        arguments are identical to those of plmeshc. The only difference
        between plmeshc and plot3dc is that plmeshc draws the bottom side of
        the surface, while plot3dc only draws the surface as viewed from the
        top.

        Redacted form: General: plot3dc(x, y, z, opt, clevel)
                Perl/PDL: Not available?


        This function is used in example 21.



    SYNOPSIS:

    plot3dc(x, y, z, nx, ny, opt, clevel, nlevel)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates at
            which the function is evaluated.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates at
            which the function is evaluated.

        z (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    Number of x values at which function is
            evaluated.

        ny (PLINT, input) :    Number of y values at which function is
            evaluated.

        opt (PLINT, input) :    Determines the way in which the surface is
            represented. To specify more than one option just add the options,
            e.g. DRAW_LINEXY + MAG_COLOR opt=DRAW_LINEX : Lines are drawn
            showing z as a function of x for each value of y[j] .
                opt=DRAW_LINEY : Lines are drawn showing z as a function of y
                for each value of x[i] .
                opt=DRAW_LINEXY : Network of lines is drawn connecting points
                at which function is defined.
                opt=MAG_COLOR : Each line in the mesh is colored according to
                the z value being plotted. The color is used from the current
                cmap1.
                opt=BASE_CONT : A contour plot is drawn at the base XY plane
                using parameters
        nlevel and
        clevel.
                opt=DRAW_SIDES : draws a curtain between the base XY plane and
                the borders of the plotted function.


        clevel (PLFLT_VECTOR, input) :    A vector containing the contour
            levels.

        nlevel (PLINT, input) :    Number of elements in the clevel vector.

    """
    return _plplotc.plot3dc(ArrayX, ArrayY, MatrixCk, opt, Array)

def plot3dcl(ArrayX, ArrayY, MatrixCk, opt, arg5, ixstart, arg7, ArrayCk):
    """
    Magnitude colored plot surface with contour for z[x][y] with y index limits

    DESCRIPTION:

        When the implementation is completed this variant of plot3dc (see that
        function's documentation for more details) should be suitable for the
        case where the area of the x, y coordinate grid where z is defined can
        be non-rectangular. The implementation is incomplete so the last 4
        parameters of plot3dcl; indexxmin, indexxmax, indexymin, and
        indexymax; are currently ignored and the functionality is otherwise
        identical to that of plot3dc.

        Redacted form: General: plot3dcl(x, y, z, opt, clevel, indexxmin,
        indexymin, indexymax)
                Perl/PDL: Not available?


        This function is not used in any example.



    SYNOPSIS:

    plot3dcl(x, y, z, nx, ny, opt, clevel, nlevel, indexxmin, indexxmax, indexymin, indexymax)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates at
            which the function is evaluated.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates at
            which the function is evaluated.

        z (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    Number of x values at which the function is
            evaluated.

        ny (PLINT, input) :    Number of y values at which the function is
            evaluated.

        opt (PLINT, input) :    Determines the way in which the surface is
            represented. To specify more than one option just add the options,
            e.g. DRAW_LINEXY + MAG_COLOR opt=DRAW_LINEX : Lines are drawn
            showing z as a function of x for each value of y[j] .
                opt=DRAW_LINEY : Lines are drawn showing z as a function of y
                for each value of x[i] .
                opt=DRAW_LINEXY : Network of lines is drawn connecting points
                at which function is defined.
                opt=MAG_COLOR : Each line in the mesh is colored according to
                the z value being plotted. The color is used from the current
                cmap1.
                opt=BASE_CONT : A contour plot is drawn at the base XY plane
                using parameters
        nlevel and
        clevel.
                opt=DRAW_SIDES : draws a curtain between the base XY plane and
                the borders of the plotted function.


        clevel (PLFLT_VECTOR, input) :    A vector containing the contour
            levels.

        nlevel (PLINT, input) :    Number of elements in the clevel vector.

        indexxmin (PLINT, input) :    The index value (which must be ≥ 0) that
            corresponds to the first x index where z is defined.

        indexxmax (PLINT, input) :    The index value (which must be ≤ nx)
            which corresponds (by convention) to one more than the last x
            index value where z is defined.

        indexymin (PLINT_VECTOR, input) :    A vector containing y index
            values which all must be ≥ 0.  These values are the first y index
            where z is defined for a particular x index in the range from
            indexxmin to indexxmax - 1. The dimension of indexymin is
            indexxmax.

        indexymax (PLINT_VECTOR, input) :    A vector containing y index
            values which all must be ≤ ny. These values correspond (by
            convention) to one more than the last y index where z is defined
            for a particular x index in the range from indexxmin to indexxmax
            - 1.  The dimension of indexymax is indexxmax.

    """
    return _plplotc.plot3dcl(ArrayX, ArrayY, MatrixCk, opt, arg5, ixstart, arg7, ArrayCk)

def plsurf3d(ArrayX, ArrayY, MatrixCk, opt, Array):
    """
    Plot shaded 3-d surface plot

    DESCRIPTION:

        Plots a three-dimensional shaded surface plot within the environment
        set up by plw3d.  The surface is defined by the two-dimensional matrix
        z[
        nx][
        ny], the point z[i][j] being the value of the function at (
        x[i],
        y[j]). Note that the points in vectors x and y do not need to be
        equally spaced, but must be stored in ascending order. For further
        details see the PLplot documentation.

        Redacted form: plsurf3d(x, y, z, opt, clevel)

        This function is not used in any examples.



    SYNOPSIS:

    plsurf3d(x, y, z, nx, ny, opt, clevel, nlevel)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates at
            which the function is evaluated.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates at
            which the function is evaluated.

        z (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    Number of x values at which function is
            evaluated.

        ny (PLINT, input) :    Number of y values at which function is
            evaluated.

        opt (PLINT, input) :    Determines the way in which the surface is
            represented. To specify more than one option just add the options,
            e.g. FACETED + SURF_CONT opt=FACETED : Network of lines is drawn
            connecting points at which function is defined.
                opt=BASE_CONT : A contour plot is drawn at the base XY plane
                using parameters
        nlevel and
        clevel.
                opt=SURF_CONT : A contour plot is drawn at the surface plane
                using parameters
        nlevel and
        clevel.
                opt=DRAW_SIDES : draws a curtain between the base XY plane and
                the borders of the plotted function.
                opt=MAG_COLOR : the surface is colored according to the value
                of Z; if MAG_COLOR is not used, then the surface is colored
                according to the intensity of the reflected light in the
                surface from a light source whose position is set using
                pllightsource.


        clevel (PLFLT_VECTOR, input) :    A vector containing the contour
            levels.

        nlevel (PLINT, input) :    Number of elements in the clevel vector.

    """
    return _plplotc.plsurf3d(ArrayX, ArrayY, MatrixCk, opt, Array)

def plsurf3dl(ArrayX, ArrayY, MatrixCk, opt, arg5, ixstart, arg7, ArrayCk):
    """
    Plot shaded 3-d surface plot for z[x][y] with y index limits

    DESCRIPTION:

        This variant of plsurf3d (see that function's documentation for more
        details) should be suitable for the case where the area of the x, y
        coordinate grid where z is defined can be non-rectangular.  The limits
        of that grid are provided by the parameters indexxmin, indexxmax,
        indexymin, and indexymax.

        Redacted form: plsurf3dl(x, y, z, opt, clevel, indexxmin, indexymin,
        indexymax)

        This function is used in example 8.



    SYNOPSIS:

    plsurf3dl(x, y, z, nx, ny, opt, clevel, nlevel, indexxmin, indexxmax, indexymin, indexymax)

    ARGUMENTS:

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates at
            which the function is evaluated.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates at
            which the function is evaluated.

        z (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    Number of x values at which function is
            evaluated.

        ny (PLINT, input) :    Number of y values at which function is
            evaluated.

        opt (PLINT, input) :    Determines the way in which the surface is
            represented. To specify more than one option just add the options,
            e.g. FACETED + SURF_CONT opt=FACETED : Network of lines is drawn
            connecting points at which function is defined.
                opt=BASE_CONT : A contour plot is drawn at the base XY plane
                using parameters
        nlevel and
        clevel.
                opt=SURF_CONT : A contour plot is drawn at the surface plane
                using parameters
        nlevel and
        clevel.
                opt=DRAW_SIDES : draws a curtain between the base XY plane and
                the borders of the plotted function.
                opt=MAG_COLOR : the surface is colored according to the value
                of Z; if MAG_COLOR is not used, then the surface is colored
                according to the intensity of the reflected light in the
                surface from a light source whose position is set using
                pllightsource.


        clevel (PLFLT_VECTOR, input) :    A vector containing the contour
            levels.

        nlevel (PLINT, input) :    Number of elements in the clevel vector.

        indexxmin (PLINT, input) :    The index value (which must be ≥ 0) that
            corresponds to the first x index where z is defined.

        indexxmax (PLINT, input) :    The index value (which must be ≤ nx)
            which corresponds (by convention) to one more than the last x
            index value where z is defined.

        indexymin (PLINT_VECTOR, input) :    A vector containing the y index
            values which all must be ≥ 0.  These values are the first y index
            where z is defined for a particular x index in the range from
            indexxmin to indexxmax - 1.  The dimension of indexymin is
            indexxmax.

        indexymax (PLINT_VECTOR, input) :    A vector containing the y index
            values which all must be ≤ ny.  These values correspond (by
            convention) to one more than the last y index where z is defined
            for a particular x index in the range from indexxmin to indexxmax
            - 1.  The dimension of indexymax is indexxmax.

    """
    return _plplotc.plsurf3dl(ArrayX, ArrayY, MatrixCk, opt, arg5, ixstart, arg7, ArrayCk)

def plparseopts(p_argc, mode):
    """
    Parse command-line arguments

    DESCRIPTION:

        Parse command-line arguments.

        plparseopts removes all recognized flags (decreasing argc
        accordingly), so that invalid input may be readily detected.  It can
        also be used to process user command line flags.  The user can merge
        an option table of type PLOptionTable into the internal option table
        info structure using plMergeOpts.  Or, the user can specify that ONLY
        the external table(s) be parsed by calling plClearOpts before
        plMergeOpts.

        The default action taken by plparseopts is as follows:
        Returns with an error if an unrecognized option or badly formed
        option-value pair are encountered.
        Returns immediately (return code 0) when the first non-option command
        line argument is found.
        Returns with the return code of the option handler, if one was called.

        Deletes command line arguments from argv list as they are found, and
        decrements argc accordingly.
        Does not show "invisible" options in usage or help messages.
        Assumes the program name is contained in argv[0].

        These behaviors may be controlled through the
        mode argument.

        Redacted form: General: plparseopts(argv, mode)
                Perl/PDL: Not available?


        This function is used in all of the examples.



    SYNOPSIS:

    PLINT plparseopts(p_argc, argv, mode)

    ARGUMENTS:

        p_argc (int *, input/output) :    Number of arguments.

        argv (PLCHAR_NC_MATRIX, input/output) :    A vector of character
            strings containing *p_argc command-line arguments.

        mode (PLINT, input) :    Parsing mode with the following
            possibilities: PL_PARSE_FULL (1) -- Full parsing of command line
            and all error messages enabled, including program exit when an
            error occurs.  Anything on the command line that isn't recognized
            as a valid option or option argument is flagged as an error.
                PL_PARSE_QUIET (2) -- Turns off all output except in the case
                of errors.
                PL_PARSE_NODELETE (4) -- Turns off deletion of processed
                arguments.
                PL_PARSE_SHOWALL (8) -- Show invisible options
                PL_PARSE_NOPROGRAM (32) -- Specified if argv[0] is NOT a
                pointer to the program name.
                PL_PARSE_NODASH (64) -- Set if leading dash is NOT required.
                PL_PARSE_SKIP (128) -- Set to quietly skip over any
                unrecognized arguments.

    """
    return _plplotc.plparseopts(p_argc, mode)

def plpat(n, ArrayCk):
    """
    Set area line fill pattern

    DESCRIPTION:

        Sets the area line fill pattern to be used, e.g., for calls to plfill.
        The pattern consists of 1 or 2 sets of parallel lines with specified
        inclinations and spacings.  The arguments to this routine are the
        number of sets to use (1 or 2) followed by two vectors (with 1 or 2
        elements) specifying the inclinations in tenths of a degree and the
        spacing in micrometers.  (See also plpsty)

        Redacted form: General: plpat(inc, del)
                Perl/PDL: plpat(nlin, inc, del)


        This function is used in example 15.



    SYNOPSIS:

    plpat(nlin, inc, del)

    ARGUMENTS:

        nlin (PLINT, input) :    Number of sets of lines making up the
            pattern, either 1 or 2.

        inc (PLINT_VECTOR, input) :    A vector containing nlin values of the
            inclination in tenths of a degree.  (Should be between -900 and
            900).

        del (PLINT_VECTOR, input) :    A vector containing nlin values of the
            spacing in micrometers between the lines making up the pattern.

    """
    return _plplotc.plpat(n, ArrayCk)

def plpath(n, x1, y1, x2, y2):
    """
    Draw a line between two points, accounting for coordinate transforms

    DESCRIPTION:

        Joins the point (
        x1,
        y1)  to (
        x2,
        y2) .  If a global coordinate transform is defined then the line is
        broken in to n segments to approximate the path.  If no transform is
        defined then this simply acts like a call to pljoin.

        Redacted form: plpath(n,x1,y1,x2,y2)

        This function is used in example 22.



    SYNOPSIS:

    plpath(n, x1, y1, x2, y2)

    ARGUMENTS:

        n (PLINT, input) :    number of points to use to approximate the path.

        x1 (PLFLT, input) :    x coordinate of first point.

        y1 (PLFLT, input) :    y coordinate of first point.

        x2 (PLFLT, input) :    x coordinate of second point.

        y2 (PLFLT, input) :    y coordinate of second point.

    """
    return _plplotc.plpath(n, x1, y1, x2, y2)

def plpoin(n, ArrayCk, code):
    """
    Plot a glyph at the specified points

    DESCRIPTION:

        Plot a glyph at the specified points.  (This function is largely
        superseded by plstring which gives access to many[!] more glyphs.)
        code=-1  means try to just draw a point.  Right now it's just a move
        and a draw at the same place.  Not ideal, since a sufficiently
        intelligent output device may optimize it away, or there may be faster
        ways of doing it.  This is OK for now, though, and offers a 4X speedup
        over drawing a Hershey font "point" (which is actually diamond shaped
        and therefore takes 4 strokes to draw).  If 0 < code < 32, then a
        useful (but small subset) of Hershey symbols is plotted.  If 32 <=
        code <= 127 the corresponding printable ASCII character is plotted.

        Redacted form: plpoin(x, y, code)

        This function is used in examples 1, 6, 14, and 29.



    SYNOPSIS:

    plpoin(n, x, y, code)

    ARGUMENTS:

        n (PLINT, input) :    Number of points in the x and y vectors.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            points.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            points.

        code (PLINT, input) :    Hershey symbol code (in "ascii-indexed" form
            with -1 <= code <= 127) corresponding to a glyph to be plotted at
            each of the n points.

    """
    return _plplotc.plpoin(n, ArrayCk, code)

def plpoin3(n, arg2, arg3, code):
    """
    Plot a glyph at the specified 3D points

    DESCRIPTION:

        Plot a glyph at the specified 3D points.  (This function is largely
        superseded by plstring3 which gives access to many[!] more glyphs.)
        Set up the call to this function similar to what is done for plline3.
        code=-1  means try to just draw a point.  Right now it's just a move
        and a draw at the same place.  Not ideal, since a sufficiently
        intelligent output device may optimize it away, or there may be faster
        ways of doing it.  This is OK for now, though, and offers a 4X speedup
        over drawing a Hershey font "point" (which is actually diamond shaped
        and therefore takes 4 strokes to draw).  If 0 < code < 32, then a
        useful (but small subset) of Hershey symbols is plotted.  If 32 <=
        code <= 127 the corresponding printable ASCII character is plotted.

        Redacted form: plpoin3(x, y, z, code)

        This function is not used in any example.



    SYNOPSIS:

    plpoin3(n, x, y, z, code)

    ARGUMENTS:

        n (PLINT, input) :    Number of points in the x and y vectors.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            points.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            points.

        z (PLFLT_VECTOR, input) :    A vector containing the z coordinates of
            points.

        code (PLINT, input) :    Hershey symbol code (in "ascii-indexed" form
            with -1 <= code <= 127) corresponding to a glyph to be plotted at
            each of the n points.

    """
    return _plplotc.plpoin3(n, arg2, arg3, code)

def plpoly3(n, arg2, arg3, ArrayCkMinus1, flag):
    """
    Draw a polygon in 3 space

    DESCRIPTION:

        Draws a polygon in 3 space defined by n points in x, y, and z. Setup
        like plline3, but differs from that function in that plpoly3 attempts
        to determine if the polygon is viewable depending on the order of the
        points within the vector and the value of ifcc.  If the back of
        polygon is facing the viewer, then it isn't drawn.  If this isn't what
        you want, then use plline3 instead.

        The points are assumed to be in a plane, and the directionality of the
        plane is determined from the first three points.  Additional points do
        not have to lie on the plane defined by the first three, but if they
        do not, then the determination of visibility obviously can't be 100%
        accurate... So if you're 3 space polygons are too far from planar,
        consider breaking them into smaller polygons.  3 points define a plane
        :-).

        Bugs:  If one of the first two segments is of zero length, or if they
        are co-linear, the calculation of visibility has a 50/50 chance of
        being correct.  Avoid such situations :-).  See x18c.c for an example
        of this problem. (Search for 20.1).

        Redacted form: plpoly3(x, y, z, code)

        This function is used in example 18.



    SYNOPSIS:

    plpoly3(n, x, y, z, draw, ifcc)

    ARGUMENTS:

        n (PLINT, input) :    Number of points defining line.

        x (PLFLT_VECTOR, input) :    A vector containing
        n x coordinates of points.

        y (PLFLT_VECTOR, input) :    A vector containing
        n y coordinates of points.

        z (PLFLT_VECTOR, input) :    A vector containing
        n z coordinates of points.

        draw (PLBOOL_VECTOR, input) :    A vector containing
        n-1 Boolean values which control drawing the segments of the polygon.
            If draw[i] is true, then the polygon segment from index [i] to
            [i+1] is drawn, otherwise, not.

        ifcc (PLBOOL, input) :    If ifcc is true the directionality of the
            polygon is determined by assuming the points are laid out in a
            counter-clockwise order.  Otherwise, the directionality of the
            polygon is determined by assuming the points are laid out in a
            clockwise order.

    """
    return _plplotc.plpoly3(n, arg2, arg3, ArrayCkMinus1, flag)

def plprec(setp, prec):
    """
    Set precision in numeric labels

    DESCRIPTION:

        Sets the number of places after the decimal point in numeric labels.

        Redacted form: plprec(setp, prec)

        This function is used in example 29.



    SYNOPSIS:

    plprec(setp, prec)

    ARGUMENTS:

        setp (PLINT, input) :    If setp is equal to 0 then PLplot
            automatically determines the number of places to use after the
            decimal point in numeric labels (like those used to label axes).
            If setp is 1 then prec sets the number of places.

        prec (PLINT, input) :    The number of characters to draw after the
            decimal point in numeric labels.

    """
    return _plplotc.plprec(setp, prec)

def plpsty(patt):
    """
    Select area fill pattern

    DESCRIPTION:

        If
        patt is zero or less use either a hardware solid fill if the drivers
        have that capability (virtually all do) or fall back to a software
        emulation of a solid fill using the eighth area line fill pattern.  If
        0 <
        patt <= 8, then select one of eight predefined area line fill patterns
        to use (see plpat if you desire other patterns).

        Redacted form: plpsty(patt)

        This function is used in examples 12, 13, 15, 16, and 25.



    SYNOPSIS:

    plpsty(patt)

    ARGUMENTS:

        patt (PLINT, input) :    The desired pattern index. If
        patt is zero or less, then a solid fill is (normally, see qualifiers
            above) used.  For
        patt in the range from 1 to 8 and assuming the driver has not supplied
            line fill capability itself (most deliberately do not so that line
            fill patterns look identical for those drivers), the patterns
            consist of (1) horizontal lines, (2) vertical lines, (3) lines at
            45 degrees, (4) lines at -45 degrees, (5) lines at 30 degrees, (6)
            lines at -30 degrees, (7) both vertical and horizontal lines, and
            (8) lines at both 45 degrees and -45 degrees.

    """
    return _plplotc.plpsty(patt)

def plptex(x, y, dx, dy, just, text):
    """
    Write text inside the viewport

    DESCRIPTION:

        Writes text at a specified position and inclination within the
        viewport.  Text is clipped at the viewport boundaries.  The reference
        point of a string lies along a line passing through the string at half
        the height of a capital letter.  The position of the reference point
        along this line is determined by just, the reference point is placed
        at world coordinates (
        x,
        y)  within the viewport.  The inclination of the string is specified
        in terms of differences of world coordinates making it easy to write
        text parallel to a line in a graph.

        Redacted form: plptex(x, y, dx, dy, just, text)

        This function is used in example 2-4,10,12-14,20,23,24,26.



    SYNOPSIS:

    plptex(x, y, dx, dy, just, text)

    ARGUMENTS:

        x (PLFLT, input) :    x coordinate of reference point of string.

        y (PLFLT, input) :    y coordinate of reference point of string.

        dx (PLFLT, input) :    Together with dy, this specifies the
            inclination of the string.  The baseline of the string is parallel
            to a line joining (
        x,
        y)  to (
        x+
        dx,
        y+
        dy) .

        dy (PLFLT, input) :    Together with dx, this specifies the
            inclination of the string.

        just (PLFLT, input) :    Specifies the position of the string relative
            to its reference point.  If just=0. , the reference point is at
            the left and if just=1. , it is at the right of the string.  Other
            values of just give intermediate justifications.

        text (PLCHAR_VECTOR, input) :    A UTF-8 character string to be
            written out.

    """
    return _plplotc.plptex(x, y, dx, dy, just, text)

def plptex3(x, y, z, dx, dy, dz, sx, sy, sz, just, text):
    """
    Write text inside the viewport of a 3D plot

    DESCRIPTION:

        Writes text at a specified position and inclination and with a
        specified shear within the viewport.  Text is clipped at the viewport
        boundaries.  The reference point of a string lies along a line passing
        through the string at half the height of a capital letter.  The
        position of the reference point along this line is determined by just,
        and the reference point is placed at world coordinates (
        wx,
        wy,
        wz)  within the viewport. The inclination and shear of the string is
        specified in terms of differences of world coordinates making it easy
        to write text parallel to a line in a graph.

        Redacted form: plptex3(x, y, z, dx, dy, dz, sx, sy, sz, just, text)

        This function is used in example 28.



    SYNOPSIS:

    plptex3(wx, wy, wz, dx, dy, dz, sx, sy, sz, just, text)

    ARGUMENTS:

        wx (PLFLT, input) :    x world coordinate of reference point of
            string.

        wy (PLFLT, input) :    y world coordinate of reference point of
            string.

        wz (PLFLT, input) :    z world coordinate of reference point of
            string.

        dx (PLFLT, input) :    Together with dy and
        dz , this specifies the inclination of the string.  The baseline of
            the string is parallel to a line joining (
        x,
        y,
        z)  to (
        x+
        dx,
        y+
        dy,
        z+
        dz) .

        dy (PLFLT, input) :    Together with dx and
        dz, this specifies the inclination of the string.

        dz (PLFLT, input) :    Together with dx and
        dy, this specifies the inclination of the string.

        sx (PLFLT, input) :    Together with sy and
        sz , this specifies the shear of the string.  The string is sheared so
            that the characters are vertically parallel to a line joining (
        x,
        y,
        z)  to (
        x+
        sx,
        y+
        sy,
        z+
        sz) . If sx =
        sy =
        sz = 0.)  then the text is not sheared.

        sy (PLFLT, input) :    Together with sx and
        sz, this specifies shear of the string.

        sz (PLFLT, input) :    Together with sx and
        sy, this specifies shear of the string.

        just (PLFLT, input) :    Specifies the position of the string relative
            to its reference point.  If just=0. , the reference point is at
            the left and if just=1. , it is at the right of the string.  Other
            values of just give intermediate justifications.

        text (PLCHAR_VECTOR, input) :    A UTF-8 character string to be
            written out.

    """
    return _plplotc.plptex3(x, y, z, dx, dy, dz, sx, sy, sz, just, text)

def plrandd():
    """
    Random number generator returning a real random number in the range [0,1]

    DESCRIPTION:

        Random number generator returning a real random number in the range
        [0,1]. The generator is based on the Mersenne Twister. Most languages
        / compilers provide their own random number generator, and so this is
        provided purely for convenience and to give a consistent random number
        generator across all languages supported by PLplot. This is
        particularly useful for comparing results from the test suite of
        examples.

        Redacted form: plrandd()

        This function is used in examples 17 and 21.



    SYNOPSIS:

    plrandd()

    """
    return _plplotc.plrandd()

def plreplot():
    """
    Replays contents of plot buffer to current device/file

    DESCRIPTION:

        Replays contents of plot buffer to current device/file.

        Redacted form: plreplot()

        This function is used in example 1,20.



    SYNOPSIS:

    plreplot()

    """
    return _plplotc.plreplot()

def plrgbhls(r, g, b):
    """
    Convert RGB color to HLS

    DESCRIPTION:

        Convert RGB color coordinates to HLS

        Redacted form: General: plrgbhls(r, g, b, p_h, p_l, p_s)
                Perl/PDL: Not available? Implemented as plrgb/plrgb1?


        This function is used in example 2.



    SYNOPSIS:

    plrgbhls(r, g, b, p_h, p_l, p_s)

    ARGUMENTS:

        r (PLFLT, input) :    Red intensity (0.0-1.0) of the color.

        g (PLFLT, input) :    Green intensity (0.0-1.0) of the color.

        b (PLFLT, input) :    Blue intensity (0.0-1.0) of the color.

        p_h (PLFLT_NC_SCALAR, output) :    Returned value of the hue in
            degrees (0.0-360.0) on the color cylinder.

        p_l (PLFLT_NC_SCALAR, output) :    Returned value of the lightness
            expressed as a fraction (0.0-1.0) of the axis of the color
            cylinder.

        p_s (PLFLT_NC_SCALAR, output) :    Returned value of the saturation
            expressed as a fraction (0.0-1.0) of the radius of the color
            cylinder.

    """
    return _plplotc.plrgbhls(r, g, b)

def plschr(arg1, scale):
    """
    Set character size

    DESCRIPTION:

        This sets up the size of all subsequent characters drawn.  The actual
        height of a character is the product of the default character size and
        a scaling factor.

        Redacted form: plschr(def, scale)

        This function is used in examples 2, 13, 23, and 24.



    SYNOPSIS:

    plschr(def, scale)

    ARGUMENTS:

        def (PLFLT, input) :    The default height of a character in
            millimeters, should be set to zero if the default height is to
            remain unchanged. For rasterized drivers the dx and dy values
            specified in plspage are used to convert from mm to pixels (note
            the different unit systems used).  This dpi aware scaling is not
            implemented for all drivers yet.

        scale (PLFLT, input) :    Scale factor to be applied to default to get
            actual character height.

    """
    return _plplotc.plschr(arg1, scale)

def plscmap0(Array, arg2, arg3):
    """
    Set cmap0 colors by 8-bit RGB values

    DESCRIPTION:

        Set cmap0 colors using 8-bit RGB values (see the PLplot
        documentation).  This sets the entire color map -- only as many colors
        as specified will be allocated.

        Redacted form: plscmap0(r, g, b)

        This function is used in examples 2 and 24.



    SYNOPSIS:

    plscmap0(r, g, b, ncol0)

    ARGUMENTS:

        r (PLINT_VECTOR, input) :    A vector containing unsigned 8-bit
            integers (0-255) representing the degree of red in the color.

        g (PLINT_VECTOR, input) :    A vector containing unsigned 8-bit
            integers (0-255) representing the degree of green in the color.

        b (PLINT_VECTOR, input) :    A vector containing unsigned 8-bit
            integers (0-255) representing the degree of blue in the color.

        ncol0 (PLINT, input) :    Number of items in the r, g, and b vectors.

    """
    return _plplotc.plscmap0(Array, arg2, arg3)

def plscmap0a(Array, arg2, arg3, arg4):
    """
    Set cmap0 colors by 8-bit RGB values and PLFLT alpha transparency value

    DESCRIPTION:

        Set cmap0 colors using 8-bit RGB values (see the PLplot documentation)
        and PLFLT alpha transparency value.  This sets the entire color map --
        only as many colors as specified will be allocated.

        Redacted form: plscmap0a(r, g, b, alpha)

        This function is used in examples 30.



    SYNOPSIS:

    plscmap0a(r, g, b, alpha, ncol0)

    ARGUMENTS:

        r (PLINT_VECTOR, input) :    A vector containing unsigned 8-bit
            integers (0-255) representing the degree of red in the color.

        g (PLINT_VECTOR, input) :    A vector containing unsigned 8-bit
            integers (0-255) representing the degree of green in the color.

        b (PLINT_VECTOR, input) :    A vector containing unsigned 8-bit
            integers (0-255) representing the degree of blue in the color.

        alpha (PLFLT_VECTOR, input) :    A vector containing values (0.0-1.0)
            representing the alpha transparency of the color.

        ncol0 (PLINT, input) :    Number of items in the r, g, b, and alpha
            vectors.

    """
    return _plplotc.plscmap0a(Array, arg2, arg3, arg4)

def plscmap0n(ncol0):
    """
    Set number of colors in cmap0

    DESCRIPTION:

        Set number of colors in cmap0 (see the PLplot documentation). Allocate
        (or reallocate) cmap0, and fill with default values for those colors
        not previously allocated.  The first 16 default colors are given in
        the plcol0 documentation.  For larger indices the default color is
        red.

        The drivers are not guaranteed to support more than 16 colors.

        Redacted form: plscmap0n(ncol0)

        This function is used in examples 15, 16, and 24.



    SYNOPSIS:

    plscmap0n(ncol0)

    ARGUMENTS:

        ncol0 (PLINT, input) :    Number of colors that will be allocated in
            the cmap0 palette. If this number is zero or less, then the value
            from the previous call to plscmap0n is used and if there is no
            previous call, then a default value is used.

    """
    return _plplotc.plscmap0n(ncol0)

def plscmap1(Array, arg2, arg3):
    """
    Set opaque RGB cmap1 colors values

    DESCRIPTION:

        Set opaque cmap1 colors (see the PLplot documentation) using RGB
        vector values.  This function also sets the number of cmap1 colors.
        N.B. Continuous cmap1 colors are indexed with a floating-point index
        in the range from 0.0-1.0 which is linearly transformed (e.g., by
        plcol1) to an integer index of these RGB vectors in the range from 0
        to
        ncol1-1.  So in order for this continuous color model to work
        properly, it is the responsibility of the user of plscmap1 to insure
        that these RGB vectors are continuous functions of their integer
        indices.

        Redacted form: plscmap1(r, g, b)

        This function is used in example 31.



    SYNOPSIS:

    plscmap1(r, g, b, ncol1)

    ARGUMENTS:

        r (PLINT_VECTOR, input) :    A vector that represents (using unsigned
            8-bit integers in the range from 0-255) the degree of red in the
            color as a continuous function of the integer index of the vector.

        g (PLINT_VECTOR, input) :    A vector that represents (using unsigned
            8-bit integers in the range from 0-255) the degree of green in the
            color as a continuous function of the integer index of the vector.

        b (PLINT_VECTOR, input) :    A vector that represents (using unsigned
            8-bit integers in the range from 0-255) the degree of blue in the
            color as a continuous function of the integer index of the vector.

        ncol1 (PLINT, input) :    Number of items in the r, g, and b vectors.

    """
    return _plplotc.plscmap1(Array, arg2, arg3)

def plscmap1a(Array, arg2, arg3, arg4):
    """
    Set semitransparent cmap1 RGBA colors.

    DESCRIPTION:

        Set semitransparent cmap1 colors (see the PLplot documentation) using
        RGBA vector values.  This function also sets the number of cmap1
        colors.  N.B. Continuous cmap1 colors are indexed with a
        floating-point index in the range from 0.0-1.0 which is linearly
        transformed (e.g., by plcol1) to an integer index of these RGBA
        vectors in the range from 0 to
        ncol1-1.  So in order for this continuous color model to work
        properly, it is the responsibility of the user of plscmap1 to insure
        that these RGBA vectors are continuous functions of their integer
        indices.

        Redacted form: plscmap1a(r, g, b, alpha)

        This function is used in example 31.



    SYNOPSIS:

    plscmap1a(r, g, b, alpha, ncol1)

    ARGUMENTS:

        r (PLINT_VECTOR, input) :    A vector that represents (using unsigned
            8-bit integers in the range from 0-255) the degree of red in the
            color as a continuous function of the integer index of the vector.

        g (PLINT_VECTOR, input) :    A vector that represents (using unsigned
            8-bit integers in the range from 0-255) the degree of green in the
            color as a continuous function of the integer index of the vector.

        b (PLINT_VECTOR, input) :    A vector that represents (using unsigned
            8-bit integers in the range from 0-255) the degree of blue in the
            color as a continuous function of the integer index of the vector.

        alpha (PLFLT_VECTOR, input) :    A vector that represents (using PLFLT
            values in the range from 0.0-1.0 where 0.0 corresponds to
            completely transparent and 1.0 corresponds to completely opaque)
            the alpha transparency of the color as a continuous function of
            the integer index of the vector.

        ncol1 (PLINT, input) :    Number of items in the r, g, b, and alpha
            vectors.

    """
    return _plplotc.plscmap1a(Array, arg2, arg3, arg4)

def plscmap1l(itype, n, arg3, arg4, arg5, ArrayCkMinus1Null):
    """
    Set cmap1 colors using a piece-wise linear relationship

    DESCRIPTION:

        Set cmap1 colors using a piece-wise linear relationship between the
        cmap1 intensity index (0.0-1.0) and position in HLS or RGB color space
        (see the PLplot documentation).  May be called at any time.

        The idea here is to specify a number of control points that define the
        mapping between input cmap1 intensity indices and HLS (or RGB).
        Between these points, linear interpolation is used which gives a
        smooth variation of color with intensity index.  Any number of control
        points may be specified, located at arbitrary positions, although
        typically 2 - 4 are enough. Another way of stating this is that we are
        traversing a given number of lines through HLS (or RGB) space as we
        move through cmap1 intensity indices.  The control points at the
        minimum and maximum position (0 and 1) must always be specified.  By
        adding more control points you can get more variation.  One good
        technique for plotting functions that vary about some expected average
        is to use an additional 2 control points in the center (position ~=
        0.5) that are the same lightness as the background (typically white
        for paper output, black for crt), and same hue as the boundary control
        points.  This allows the highs and lows to be very easily
        distinguished.

        Each control point must specify the cmap1 intensity index and the
        associated three coordinates in HLS or RGB space.  The first point
        must correspond to position = 0, and the last to position = 1.

        The default behaviour is for the hue to be linearly interpolated
        between the control points. Since the hue lies in the range [0, 360]
        this corresponds to interpolation around the "front" of the color
        wheel (red<->green<->blue<->red). If alt_hue_path[i] is true, then an
        alternative interpolation is used between control points i and i+1. If
        hue[i+1]-hue[i] > 0 then interpolation is between hue[i] and hue[i+1]
        - 360, otherwise between hue[i] and hue[i+1] + 360. You can consider
        this as interpolation around the "back" or "reverse" of the color
        wheel. Specifying alt_hue_path=NULL is equivalent to setting
        alt_hue_path[] = false for every control point.

        Examples of interpolation Huealt_hue_pathcolor scheme[120
        240]falsegreen-cyan-blue[240 120]falseblue-cyan-green[120
        240]truegreen-yellow-red-magenta-blue[240
        120]trueblue-magenta-red-yellow-green

        Bounds on coordinatesRGBR[0, 1]magnitudeRGBG[0, 1]magnitudeRGBB[0,
        1]magnitudeHLShue[0, 360]degreesHLSlightness[0,
        1]magnitudeHLSsaturation[0, 1]magnitude

        Redacted form: plscmap1l(itype, intensity, coord1, coord2, coord3,
        alt_hue_path)

        This function is used in examples 8, 11, 12, 15, 20, and 21.



    SYNOPSIS:

    plscmap1l(itype, npts, intensity, coord1, coord2, coord3, alt_hue_path)

    ARGUMENTS:

        itype (PLBOOL, input) :    true: RGB, false: HLS.

        npts (PLINT, input) :    number of control points

        intensity (PLFLT_VECTOR, input) :    A vector containing the cmap1
            intensity index (0.0-1.0) in ascending order for each control
            point.

        coord1 (PLFLT_VECTOR, input) :    A vector containing the first
            coordinate (H or R) for each control point.

        coord2 (PLFLT_VECTOR, input) :    A vector containing the second
            coordinate (L or G) for each control point.

        coord3 (PLFLT_VECTOR, input) :    A vector containing the third
            coordinate (S or B) for each control point.

        alt_hue_path (PLBOOL_VECTOR, input) :    A vector (with
        npts - 1 elements) containing the alternative interpolation method
            Boolean value for each control point interval.  (alt_hue_path[i]
            refers to the interpolation interval between the i and i + 1
            control points).

    """
    return _plplotc.plscmap1l(itype, n, arg3, arg4, arg5, ArrayCkMinus1Null)

def plscmap1la(itype, n, arg3, arg4, arg5, arg6, ArrayCkMinus1Null):
    """
    Set cmap1 colors and alpha transparency using a piece-wise linear relationship

    DESCRIPTION:

        This is a variant of plscmap1l that supports alpha channel
        transparency. It sets cmap1 colors using a piece-wise linear
        relationship between cmap1 intensity index (0.0-1.0) and position in
        HLS or RGB color space (see the PLplot documentation) with alpha
        transparency value (0.0-1.0). It may be called at any time.

        Redacted form: plscmap1la(itype, intensity, coord1, coord2, coord3,
        alpha, alt_hue_path)

        This function is used in example 30.



    SYNOPSIS:

    plscmap1la(itype, npts, intensity, coord1, coord2, coord3, alpha, alt_hue_path)

    ARGUMENTS:

        itype (PLBOOL, input) :    true: RGB, false: HLS.

        npts (PLINT, input) :    number of control points.

        intensity (PLFLT_VECTOR, input) :    A vector containing the cmap1
            intensity index (0.0-1.0) in ascending order for each control
            point.

        coord1 (PLFLT_VECTOR, input) :    A vector containing the first
            coordinate (H or R) for each control point.

        coord2 (PLFLT_VECTOR, input) :    A vector containing the second
            coordinate (L or G) for each control point.

        coord3 (PLFLT_VECTOR, input) :    A vector containing the third
            coordinate (S or B) for each control point.

        alpha (PLFLT_VECTOR, input) :    A vector containing the alpha
            transparency value (0.0-1.0) for each control point.

        alt_hue_path (PLBOOL_VECTOR, input) :    A vector (with
        npts - 1 elements) containing the alternative interpolation method
            Boolean value for each control point interval.  (alt_hue_path[i]
            refers to the interpolation interval between the i and i + 1
            control points).

    """
    return _plplotc.plscmap1la(itype, n, arg3, arg4, arg5, arg6, ArrayCkMinus1Null)

def plscmap1n(ncol1):
    """
    Set number of colors in cmap1

    DESCRIPTION:

        Set number of colors in cmap1, (re-)allocate cmap1, and set default
        values if this is the first allocation (see the PLplot documentation).

        Redacted form: plscmap1n(ncol1)

        This function is used in examples 8, 11, 20, and 21.



    SYNOPSIS:

    plscmap1n(ncol1)

    ARGUMENTS:

        ncol1 (PLINT, input) :    Number of colors that will be allocated in
            the cmap1 palette. If this number is zero or less, then the value
            from the previous call to plscmap1n is used and if there is no
            previous call, then a default value is used.

    """
    return _plplotc.plscmap1n(ncol1)

def plscmap1_range(min_color, max_color):
    """
    Set the cmap1 argument range for continuous color plots

    DESCRIPTION:

        Set the cmap1 argument range for continuous color plots that
        corresponds to the range of data values.  The maximum range
        corresponding to the entire cmap1 palette is 0.0-1.0, and the smaller
        the cmap1 argument range that is specified with this routine, the
        smaller the subset of the cmap1 color palette that is used to
        represent the continuous data being plotted.  If
        min_color is greater than
        max_color or
        max_color is greater than 1.0 or
        min_color is less than 0.0 then no change is made to the cmap1
        argument range.  (Use plgcmap1_range to get the cmap1 argument range.)

        Redacted form: plscmap1_range(min_color, max_color)

        This function is currently used in example 33.



    SYNOPSIS:

    plscmap1_range(min_color, max_color)

    ARGUMENTS:

        min_color (PLFLT, input) :    The minimum cmap1 argument.  If less
            than 0.0, then 0.0 is used instead.

        max_color (PLFLT, input) :    The maximum cmap1 argument.  If greater
            than 1.0, then 1.0 is used instead.

    """
    return _plplotc.plscmap1_range(min_color, max_color)

def plgcmap1_range():
    """
    Get the cmap1 argument range for continuous color plots

    DESCRIPTION:

        Get the cmap1 argument range for continuous color plots. (Use
        plscmap1_range to set the cmap1 argument range.)

        Redacted form: plgcmap1_range(min_color, max_color)

        This function is currently not used in any example.



    SYNOPSIS:

    plgcmap1_range(min_color, max_color)

    ARGUMENTS:

        min_color (PLFLT_NC_SCALAR, output) :    Returned value of the current
            minimum cmap1 argument.

        max_color (PLFLT_NC_SCALAR, output) :    Returned value of the current
            maximum cmap1 argument.

    """
    return _plplotc.plgcmap1_range()

def plscol0(icol0, r, g, b):
    """
    Set 8-bit RGB values for given cmap0 color index

    DESCRIPTION:

        Set 8-bit RGB values for given cmap0 (see the PLplot documentation)
        index.  Overwrites the previous color value for the given index and,
        thus, does not result in any additional allocation of space for
        colors.

        Redacted form: plscol0(icol0, r, g, b)

        This function is used in any example 31.



    SYNOPSIS:

    plscol0(icol0, r, g, b)

    ARGUMENTS:

        icol0 (PLINT, input) :    Color index.  Must be less than the maximum
            number of colors (which is set by default, by plscmap0n, or even
            by plscmap0).

        r (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of red in the color.

        g (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of green in the color.

        b (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of blue in the color.

    """
    return _plplotc.plscol0(icol0, r, g, b)

def plscol0a(icol0, r, g, b, a):
    """
    Set 8-bit RGB values and PLFLT alpha transparency value for given cmap0 color index

    DESCRIPTION:

        Set 8-bit RGB value and PLFLT alpha transparency value for given cmap0
        (see the PLplot documentation) index.  Overwrites the previous color
        value for the given index and, thus, does not result in any additional
        allocation of space for colors.

        This function is used in example 30.



    SYNOPSIS:

    plscol0a(icol0, r, g, b, alpha)

    ARGUMENTS:

        icol0 (PLINT, input) :    Color index.  Must be less than the maximum
            number of colors (which is set by default, by plscmap0n, or even
            by plscmap0).

        r (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of red in the color.

        g (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of green in the color.

        b (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of blue in the color.

        alpha (PLFLT, input) :    Value of the alpha transparency in the range
            (0.0-1.0).

    """
    return _plplotc.plscol0a(icol0, r, g, b, a)

def plscolbg(r, g, b):
    """
    Set the background color by 8-bit RGB value

    DESCRIPTION:

        Set the background color (color 0 in cmap0) by 8-bit RGB value (see
        the PLplot documentation).

        Redacted form: plscolbg(r, g, b)

        This function is used in examples 15 and 31.



    SYNOPSIS:

    plscolbg(r, g, b)

    ARGUMENTS:

        r (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of red in the color.

        g (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of green in the color.

        b (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of blue in the color.

    """
    return _plplotc.plscolbg(r, g, b)

def plscolbga(r, g, b, a):
    """
    Set the background color by 8-bit RGB value and PLFLT alpha transparency value.

    DESCRIPTION:

        Set the background color (color 0 in cmap0) by 8-bit RGB value and
        PLFLT alpha transparency value (see the PLplot documentation).

        This function is used in example 31.



    SYNOPSIS:

    plscolbga(r, g, b, alpha)

    ARGUMENTS:

        r (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of red in the color.

        g (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of green in the color.

        b (PLINT, input) :    Unsigned 8-bit integer (0-255) representing the
            degree of blue in the color.

        alpha (PLFLT, input) :    Value of the alpha transparency in the range
            (0.0-1.0).

    """
    return _plplotc.plscolbga(r, g, b, a)

def plscolor(color):
    """
    Used to globally turn color output on/off

    DESCRIPTION:

        Used to globally turn color output on/off for those drivers/devices
        that support it.

        Redacted form: plscolor(color)

        This function is used in example 31.



    SYNOPSIS:

    plscolor(color)

    ARGUMENTS:

        color (PLINT, input) :    Color flag (Boolean).  If zero, color is
            turned off.  If non-zero, color is turned on.

    """
    return _plplotc.plscolor(color)

def plscompression(compression):
    """
    Set device-compression level

    DESCRIPTION:

        Set device-compression level.  Only used for drivers that provide
        compression.  This function, if used, should be invoked before a call
        to plinit.

        Redacted form: plscompression(compression)

        This function is used in example 31.



    SYNOPSIS:

    plscompression(compression)

    ARGUMENTS:

        compression (PLINT, input) :    The desired compression level. This is
            a device-dependent value. Currently only the jpeg and png devices
            use these values. For jpeg value is the jpeg quality which should
            normally be in the range 0-95. Higher values denote higher quality
            and hence larger image sizes. For png values are in the range -1
            to 99. Values of 0-9 are taken as the compression level for zlib.
            A value of -1 denotes the default zlib compression level. Values
            in the range 10-99 are divided by 10 and then used as the zlib
            compression level. Higher compression levels correspond to greater
            compression and small file sizes at the expense of more
            computation.

    """
    return _plplotc.plscompression(compression)

def plsdev(devname):
    """
    Set the device (keyword) name

    DESCRIPTION:

        Set the device (keyword) name.

        Redacted form: plsdev(devname)

        This function is used in examples 1, 14, and 20.



    SYNOPSIS:

    plsdev(devname)

    ARGUMENTS:

        devname (PLCHAR_VECTOR, input) :    An ascii character string
            containing the device name keyword of the required output device.
            If
        devname is NULL or if the first character of the string is a ``?'',
            the normal (prompted) start up is used.

    """
    return _plplotc.plsdev(devname)

def plsdidev(mar, aspect, jx, jy):
    """
    Set parameters that define current device-space window

    DESCRIPTION:

        Set relative margin width, aspect ratio, and relative justification
        that define current device-space window.  If you want to just use the
        previous value for any of these, just pass in the magic value
        PL_NOTSET. It is unlikely that one should ever need to change the
        aspect ratio but it's in there for completeness. If plsdidev is not
        called the default values of mar, jx, and jy are all 0. aspect is set
        to a device-specific value.

        Redacted form: plsdidev(mar, aspect, jx, jy)

        This function is used in example 31.



    SYNOPSIS:

    plsdidev(mar, aspect, jx, jy)

    ARGUMENTS:

        mar (PLFLT, input) :    Relative margin width.

        aspect (PLFLT, input) :    Aspect ratio.

        jx (PLFLT, input) :    Relative justification in x. Value must lie in
            the range -0.5 to 0.5.

        jy (PLFLT, input) :    Relative justification in y. Value must lie in
            the range -0.5 to 0.5.

    """
    return _plplotc.plsdidev(mar, aspect, jx, jy)

def plsdimap(dimxmin, dimxmax, dimymin, dimymax, dimxpmm, dimypmm):
    """
    Set up transformation from metafile coordinates

    DESCRIPTION:

        Set up transformation from metafile coordinates.  The size of the plot
        is scaled so as to preserve aspect ratio.  This isn't intended to be a
        general-purpose facility just yet (not sure why the user would need
        it, for one).

        Redacted form: plsdimap(dimxmin, dimxmax, dimymin, dimymax, dimxpmm,
        dimypmm)

        This function is not used in any examples.



    SYNOPSIS:

    plsdimap(dimxmin, dimxmax, dimymin, dimymax, dimxpmm, dimypmm)

    ARGUMENTS:

        dimxmin (PLINT, input) :    NEEDS DOCUMENTATION

        dimxmax (PLINT, input) :    NEEDS DOCUMENTATION

        dimymin (PLINT, input) :    NEEDS DOCUMENTATION

        dimymax (PLINT, input) :    NEEDS DOCUMENTATION

        dimxpmm (PLFLT, input) :    NEEDS DOCUMENTATION

        dimypmm (PLFLT, input) :    NEEDS DOCUMENTATION

    """
    return _plplotc.plsdimap(dimxmin, dimxmax, dimymin, dimymax, dimxpmm, dimypmm)

def plsdiori(rot):
    """
    Set plot orientation

    DESCRIPTION:

        Set plot orientation parameter which is multiplied by 90 degrees to
        obtain the angle of rotation.  Note, arbitrary rotation parameters
        such as 0.2 (corresponding to 18 degrees) are possible, but the usual
        values for the rotation parameter are 0., 1., 2., and 3. corresponding
        to 0 degrees (landscape mode), 90 degrees (portrait mode), 180 degrees
        (seascape mode), and 270 degrees (upside-down mode).  If plsdiori is
        not called the default value of rot is 0.

        N.B. aspect ratio is unaffected by calls to plsdiori.  So you will
        probably want to change the aspect ratio to a value suitable for the
        plot orientation using a call to plsdidev or the command-line options
        -a or -freeaspect.  For more documentation of those options see the
        PLplot documentation.  Such command-line options can be set internally
        using plsetopt or set directly using the command line and parsed using
        a call to plparseopts.

        Redacted form: plsdiori(rot)

        This function is not used in any examples.



    SYNOPSIS:

    plsdiori(rot)

    ARGUMENTS:

        rot (PLFLT, input) :    Plot orientation parameter.

    """
    return _plplotc.plsdiori(rot)

def plsdiplt(xmin, ymin, xmax, ymax):
    """
    Set parameters that define current plot-space window

    DESCRIPTION:

        Set relative minima and maxima that define the current plot-space
        window.  If plsdiplt is not called the default values of xmin, ymin,
        xmax, and ymax are 0., 0., 1., and 1.

        Redacted form: plsdiplt(xmin, ymin, xmax, ymax)

        This function is used in example 31.



    SYNOPSIS:

    plsdiplt(xmin, ymin, xmax, ymax)

    ARGUMENTS:

        xmin (PLFLT, input) :    Relative minimum in x.

        ymin (PLFLT, input) :    Relative minimum in y.

        xmax (PLFLT, input) :    Relative maximum in x.

        ymax (PLFLT, input) :    Relative maximum in y.

    """
    return _plplotc.plsdiplt(xmin, ymin, xmax, ymax)

def plsdiplz(xmin, ymin, xmax, ymax):
    """
    Set parameters incrementally (zoom mode) that define current plot-space window

    DESCRIPTION:

        Set relative minima and maxima incrementally (zoom mode) that define
        the current plot-space window.  This function has the same effect as
        plsdiplt if that function has not been previously called.  Otherwise,
        this function implements zoom mode using the transformation min_used =
        old_min + old_length*min  and max_used = old_min + old_length*max  for
        each axis.  For example, if min = 0.05 and max = 0.95 for each axis,
        repeated calls to plsdiplz will zoom in by 10 per cent for each call.

        Redacted form: plsdiplz(xmin, ymin, xmax, ymax)

        This function is used in example 31.



    SYNOPSIS:

    plsdiplz(xmin, ymin, xmax, ymax)

    ARGUMENTS:

        xmin (PLFLT, input) :    Relative (incremental) minimum in x.

        ymin (PLFLT, input) :    Relative (incremental) minimum in y.

        xmax (PLFLT, input) :    Relative (incremental) maximum in x.

        ymax (PLFLT, input) :    Relative (incremental) maximum in y.

    """
    return _plplotc.plsdiplz(xmin, ymin, xmax, ymax)

def plseed(s):
    """
    Set seed for internal random number generator.

    DESCRIPTION:

        Set the seed for the internal random number generator. See plrandd for
        further details.

        Redacted form: plseed(seed)

        This function is used in example 21.



    SYNOPSIS:

    plseed(seed)

    ARGUMENTS:

        seed (unsigned int, input) :    Seed for random number generator.

    """
    return _plplotc.plseed(s)

def plsesc(esc):
    """
    Set the escape character for text strings

    DESCRIPTION:

        Set the escape character for text strings.  From C (in contrast to
        Fortran, see plsescfortran) you pass esc as a character. Only selected
        characters are allowed to prevent the user from shooting himself in
        the foot (For example, a \ isn't allowed since it conflicts with C's
        use of backslash as a character escape).  Here are the allowed escape
        characters and their corresponding decimal ASCII values: !, ASCII 33
                #, ASCII 35
                $, ASCII 36
                %, ASCII 37
                &, ASCII 38
                *, ASCII 42
                @, ASCII 64
                ^, ASCII 94
                ~, ASCII 126


        Redacted form: General: plsesc(esc)
                Perl/PDL: Not available?


        This function is used in example 29.



    SYNOPSIS:

    plsesc(esc)

    ARGUMENTS:

        esc (char, input) :    Escape character.

    """
    return _plplotc.plsesc(esc)

def plsetopt(opt, optarg):
    """
    Set any command-line option

    DESCRIPTION:

        Set any command-line option internally from a program before it
        invokes plinit. opt is the name of the command-line option and optarg
        is the corresponding command-line option argument.

        This function returns 0 on success.

        Redacted form: plsetopt(opt, optarg)

        This function is used in example 14.



    SYNOPSIS:

    PLINT plsetopt(opt, optarg)

    ARGUMENTS:

        opt (PLCHAR_VECTOR, input) :    An ascii character string containing
            the command-line option.

        optarg (PLCHAR_VECTOR, input) :    An ascii character string
            containing the argument of the command-line option.

    """
    return _plplotc.plsetopt(opt, optarg)

def plsfam(fam, num, bmax):
    """
    Set family file parameters

    DESCRIPTION:

        Sets variables dealing with output file familying.  Does nothing if
        familying not supported by the driver.  This routine, if used, must be
        called before initializing PLplot.  See the PLplot documentation for
        more information.

        Redacted form: plsfam(fam, num, bmax)

        This function is used in examples 14 and 31.



    SYNOPSIS:

    plsfam(fam, num, bmax)

    ARGUMENTS:

        fam (PLINT, input) :    Family flag (Boolean).  If nonzero, familying
            is enabled.

        num (PLINT, input) :    Current family file number.

        bmax (PLINT, input) :    Maximum file size (in bytes) for a family
            file.

    """
    return _plplotc.plsfam(fam, num, bmax)

def plsfci(fci):
    """
    Set FCI (font characterization integer)

    DESCRIPTION:

        Sets font characteristics to be used at the start of the next string
        using the FCI approach.  See the PLplot documentation for more
        information.  Note, plsfont (which calls plsfci internally) provides a
        more user-friendly API for setting the font characterisitics.

        Redacted form: General: plsfci(fci)
                Perl/PDL: Not available?


        This function is used in example 23.



    SYNOPSIS:

    plsfci(fci)

    ARGUMENTS:

        fci (PLUNICODE, input) :    PLUNICODE (unsigned 32-bit integer) value
            of FCI.

    """
    return _plplotc.plsfci(fci)

def plsfnam(fnam):
    """
    Set output file name

    DESCRIPTION:

        Sets the current output file name, if applicable.  If the file name
        has not been specified and is required by the driver, the user will be
        prompted for it.  If using the X-windows output driver, this sets the
        display name.  This routine, if used, must be called before
        initializing PLplot.

        Redacted form: plsfnam(fnam)

        This function is used in examples 1 and 20.



    SYNOPSIS:

    plsfnam(fnam)

    ARGUMENTS:

        fnam (PLCHAR_VECTOR, input) :    An ascii character string containing
            the file name.

    """
    return _plplotc.plsfnam(fnam)

def plsfont(family, style, weight):
    """
    Set family, style and weight of the current font

    DESCRIPTION:

        Sets the current font.  See the PLplot documentation for more
        information on font selection.

        Redacted form: plsfont(family, style, weight)

        This function is used in example 23.



    SYNOPSIS:

    plsfont(family, style, weight)

    ARGUMENTS:

        family (PLINT, input) :    Font family to select for the current font.
            The available values are given by the PL_FCI_* constants in
            plplot.h.  Current options are PL_FCI_SANS, PL_FCI_SERIF,
            PL_FCI_MONO, PL_FCI_SCRIPT and PL_FCI_SYMBOL. A negative value
            signifies that the font family should not be altered.

        style (PLINT, input) :    Font style to select for the current font.
            The available values are given by the PL_FCI_* constants in
            plplot.h.  Current options are PL_FCI_UPRIGHT, PL_FCI_ITALIC and
            PL_FCI_OBLIQUE. A negative value signifies that the font style
            should not be altered.

        weight (PLINT, input) :    Font weight to select for the current font.
            The available values are given by the PL_FCI_* constants in
            plplot.h.  Current options are PL_FCI_MEDIUM and PL_FCI_BOLD. A
            negative value signifies that the font weight should not be
            altered.

    """
    return _plplotc.plsfont(family, style, weight)

def plshades(*args):
    """
    Shade regions on the basis of value

    DESCRIPTION:

        Shade regions on the basis of value.  This is the high-level routine
        for making continuous color shaded plots with cmap1 while plshade
        should be used to plot individual shaded regions using either cmap0 or
        cmap1. examples/;<language>/x16* shows how to use plshades for each of
        our supported languages.

        Redacted form: General: plshades(a, defined, xmin, xmax, ymin, ymax,
        clevel, fill_width, cont_color, cont_width, fill, rectangular, pltr,
        pltr_data)
                Perl/PDL: plshades(a, xmin, xmax, ymin, ymax, clevel,
        fill_width, cont_color, cont_width, fill, rectangular, defined, pltr,
        pltr_data)


        This function is used in examples 16, 21, and 22.



    SYNOPSIS:

    plshades(a, nx, ny, defined, xmin, xmax, ymin, ymax, clevel, nlevel, fill_width, cont_color, cont_width, fill, rectangular, pltr, pltr_data)

    ARGUMENTS:

        a (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    First dimension of matrix "a".

        ny (PLINT, input) :    Second dimension of matrix "a".

        defined (PLDEFINED_callback, input) :    Callback function specifying
            the region that should be plotted in the shade plot.  This
            function accepts x and y coordinates as input arguments and must
            return 1 if the point is to be included in the shade plot and 0
            otherwise.  If you want to plot the entire shade plot (the usual
            case), this argument should be set to NULL.

        xmin, xmax, ymin, ymax (PLFLT, input) :    See the discussion of
        pltr below for how these arguments are used (only for the special case
            when the callback function
        pltr is not supplied).

        clevel (PLFLT_VECTOR, input) :    A vector containing the data levels
            corresponding to the edges of each shaded region that will be
            plotted by this function.  To work properly the levels should be
            monotonic.

        nlevel (PLINT, input) :    Number of shades plus 1 (i.e., the number
            of shade edge values in clevel).

        fill_width (PLFLT, input) :    Defines the line width used by the fill
            pattern.

        cont_color (PLINT, input) :    Defines cmap0 pen color used for
            contours defining edges of shaded regions.  The pen color is only
            temporary set for the contour drawing.  Set this value to zero or
            less if no shade edge contours are wanted.

        cont_width (PLFLT, input) :    Defines line width used for contours
            defining edges of shaded regions.  This value may not be honored
            by all drivers. The pen width is only temporary set for the
            contour drawing.  Set this value to zero or less if no shade edge
            contours are wanted.

        fill (PLFILL_callback, input) :    Callback routine used to fill the
            region.  Use plfill for this purpose.

        rectangular (PLBOOL, input) :    Set rectangular to true if rectangles
            map to rectangles after coordinate transformation with pltrl.
            Otherwise, set rectangular to false. If rectangular is set to
            true, plshade tries to save time by filling large rectangles.
            This optimization fails if the coordinate transformation distorts
            the shape of rectangles.  For example a plot in polar coordinates
            has to have rectangular set to false.

        pltr (PLTRANSFORM_callback, input) :    A callback function that
            defines the transformation between the zero-based indices of the
            matrix a and world coordinates. If
        pltr is not supplied (e.g., is set to NULL in the C case), then the x
            indices of a are mapped to the range
        xmin through
        xmax and the y indices of a are mapped to the range
        ymin through
        ymax.For the C case, transformation functions are provided in the
            PLplot library: pltr0 for the identity mapping, and pltr1 and
            pltr2 for arbitrary mappings respectively defined by vectors and
            matrices.  In addition, C callback routines for the transformation
            can be supplied by the user such as the mypltr function in
            examples/c/x09c.c which provides a general linear transformation
            between index coordinates and world coordinates.For languages
            other than C you should consult the PLplot documentation for the
            details concerning how PLTRANSFORM_callback arguments are
            interfaced. However, in general, a particular pattern of
            callback-associated arguments such as a tr vector with 6 elements;
            xg and yg vectors; or xg and yg matrices are respectively
            interfaced to a linear-transformation routine similar to the above
            mypltr function; pltr1; and pltr2. Furthermore, some of our more
            sophisticated bindings (see, e.g., the PLplot documentation)
            support native language callbacks for handling index to
            world-coordinate transformations.  Examples of these various
            approaches are given in examples/<language>x09*,
            examples/<language>x16*, examples/<language>x20*,
            examples/<language>x21*, and examples/<language>x22*, for all our
            supported languages.

        pltr_data (PLPointer, input) :    Extra parameter to help pass
            information to pltr0, pltr1, pltr2, or whatever routine that is
            externally supplied.

    """
    return _plplotc.plshades(*args)

def plshade(*args):
    """
    Shade individual region on the basis of value

    DESCRIPTION:

        Shade individual region on the basis of value.  Use plshades if you
        want to shade a number of contiguous regions using continuous colors.
        In particular the edge contours are treated properly in plshades.  If
        you attempt to do contiguous regions with plshade the contours at the
        edge of the shade are partially obliterated by subsequent plots of
        contiguous shaded regions.

        Redacted form: General: plshade(a, defined, xmin, xmax, ymin, ymax,
        shade_min, shade_max, sh_cmap, sh_color, sh_width, min_color,
        min_width, max_color, max_width, fill, rectangular, pltr, pltr_data)


        This function is used in example 15.



    SYNOPSIS:

    plshade(a, nx, ny, defined, xmin, xmax, ymin, ymax, shade_min, shade_max, sh_cmap, sh_color, sh_width, min_color, min_width, max_color, max_width, fill, rectangular, pltr, pltr_data)

    ARGUMENTS:

        a (PLFLT_MATRIX, input) :    A matrix containing function values to
            plot.  Should have dimensions of
        nx by
        ny.

        nx (PLINT, input) :    First dimension of the matrix "a".

        ny (PLINT, input) :    Second dimension of the matrix "a".

        defined (PLDEFINED_callback, input) :    Callback function specifying
            the region that should be plotted in the shade plot.  This
            function accepts x and y coordinates as input arguments and must
            return 1 if the point is to be included in the shade plot and 0
            otherwise.  If you want to plot the entire shade plot (the usual
            case), this argument should be set to NULL.

        xmin, xmax, ymin, ymax (PLFLT, input) :    See the discussion of
        pltr below for how these arguments are used (only for the special case
            when the callback function
        pltr is not supplied).

        shade_min (PLFLT, input) :    Defines the lower end of the interval to
            be shaded. If shade_max <= shade_min, plshade does nothing.

        shade_max (PLFLT, input) :    Defines the upper end of the interval to
            be shaded. If shade_max <= shade_min, plshade does nothing.

        sh_cmap (PLINT, input) :    Defines color map. If sh_cmap=0, then
            sh_color is interpreted as a cmap0 (integer) index.  If sh_cmap=1,
            then sh_color is interpreted as a cmap1 argument in the range
            (0.0-1.0).

        sh_color (PLFLT, input) :    Defines color map index with integer
            value if cmap0 or value in range (0.0-1.0) if cmap1.

        sh_width (PLFLT, input) :    Defines width used by the fill pattern.

        min_color (PLINT, input) :    Defines pen color, width used by the
            boundary of shaded region. The min values are used for the
            shade_min boundary, and the max values are used on the shade_max
            boundary.  Set color and width to zero for no plotted boundaries.

        min_width (PLFLT, input) :    Defines pen color, width used by the
            boundary of shaded region. The min values are used for the
            shade_min boundary, and the max values are used on the shade_max
            boundary.  Set color and width to zero for no plotted boundaries.

        max_color (PLINT, input) :    Defines pen color, width used by the
            boundary of shaded region. The min values are used for the
            shade_min boundary, and the max values are used on the shade_max
            boundary.  Set color and width to zero for no plotted boundaries.

        max_width (PLFLT, input) :    Defines pen color, width used by the
            boundary of shaded region. The min values are used for the
            shade_min boundary, and the max values are used on the shade_max
            boundary.  Set color and width to zero for no plotted boundaries.

        fill (PLFILL_callback, input) :    Routine used to fill the region.
            Use plfill.  Future version of PLplot may have other fill
            routines.

        rectangular (PLBOOL, input) :    Set rectangular to true if rectangles
            map to rectangles after coordinate transformation with pltrl.
            Otherwise, set rectangular to false. If rectangular is set to
            true, plshade tries to save time by filling large rectangles.
            This optimization fails if the coordinate transformation distorts
            the shape of rectangles. For example a plot in polar coordinates
            has to have rectangular set to false.

        pltr (PLTRANSFORM_callback, input) :    A callback function that
            defines the transformation between the zero-based indices of the
            matrix a and world coordinates. If
        pltr is not supplied (e.g., is set to NULL in the C case), then the x
            indices of a are mapped to the range
        xmin through
        xmax and the y indices of a are mapped to the range
        ymin through
        ymax.For the C case, transformation functions are provided in the
            PLplot library: pltr0 for the identity mapping, and pltr1 and
            pltr2 for arbitrary mappings respectively defined by vectors and
            matrices.  In addition, C callback routines for the transformation
            can be supplied by the user such as the mypltr function in
            examples/c/x09c.c which provides a general linear transformation
            between index coordinates and world coordinates.For languages
            other than C you should consult the PLplot documentation for the
            details concerning how PLTRANSFORM_callback arguments are
            interfaced. However, in general, a particular pattern of
            callback-associated arguments such as a tr vector with 6 elements;
            xg and yg vectors; or xg and yg matrices are respectively
            interfaced to a linear-transformation routine similar to the above
            mypltr function; pltr1; and pltr2. Furthermore, some of our more
            sophisticated bindings (see, e.g., the PLplot documentation)
            support native language callbacks for handling index to
            world-coordinate transformations.  Examples of these various
            approaches are given in examples/<language>x09*,
            examples/<language>x16*, examples/<language>x20*,
            examples/<language>x21*, and examples/<language>x22*, for all our
            supported languages.

        pltr_data (PLPointer, input) :    Extra parameter to help pass
            information to pltr0, pltr1, pltr2, or whatever routine that is
            externally supplied.

    """
    return _plplotc.plshade(*args)

def plslabelfunc(lf, data):
    """
    Assign a function to use for generating custom axis labels

    DESCRIPTION:

        This function allows a user to provide their own function to provide
        axis label text.  The user function is given the numeric value for a
        point on an axis and returns a string label to correspond with that
        value.  Custom axis labels can be enabled by passing appropriate
        arguments to plenv, plbox, plbox3 and similar functions.

        This function is used in example 19.



    SYNOPSIS:

    plslabelfunc(label_func, label_data)

    ARGUMENTS:

        label_func (PLLABEL_FUNC_callback, input) :    This is the custom
            label function.  In order to reset to the default labelling, set
            this to NULL. The labelling function parameters are, in order:
            axis:    This indicates which axis a label is being requested for.
            The value will be one of PL_X_AXIS, PL_Y_AXIS or PL_Z_AXIS.

        value:    This is the value along the axis which is being labelled.

        label_text:    The string representation of the label value.

        length:    The maximum length in characters allowed for label_text.


        label_data (PLPointer, input) :    This parameter may be used to pass
            data to the label_func function.

    """
    return _plplotc.plslabelfunc(lf, data)

def plsmaj(arg1, scale):
    """
    Set length of major ticks

    DESCRIPTION:

        This sets up the length of the major ticks.  The actual length is the
        product of the default length and a scaling factor as for character
        height.

        Redacted form: plsmaj(def, scale)

        This function is used in example 29.



    SYNOPSIS:

    plsmaj(def, scale)

    ARGUMENTS:

        def (PLFLT, input) :    The default length of a major tick in
            millimeters, should be set to zero if the default length is to
            remain unchanged.

        scale (PLFLT, input) :    Scale factor to be applied to default to get
            actual tick length.

    """
    return _plplotc.plsmaj(arg1, scale)

def plsmem(maxx, maxy, plotmem):
    """
    Set the memory area to be plotted (RGB)

    DESCRIPTION:

        Set the memory area to be plotted (with the mem or memcairo driver) as
        the dev member of the stream structure.  Also set the number of pixels
        in the memory passed in
        plotmem, which is a block of memory
        maxy by
        maxx by 3 bytes long, say: 480 x 640 x 3 (Y, X, RGB)

        This memory will have to be freed by the user!

        Redacted form: plsmem(maxx, maxy, plotmem)

        This function is not used in any examples.



    SYNOPSIS:

    plsmem(maxx, maxy, plotmem)

    ARGUMENTS:

        maxx (PLINT, input) :    Size of memory area in the X coordinate.

        maxy (PLINT, input) :    Size of memory area in the Y coordinate.

        plotmem (PLPointer, input) :    Pointer to the beginning of a
            user-supplied writeable memory area.

    """
    return _plplotc.plsmem(maxx, maxy, plotmem)

def plsmema(maxx, maxy, plotmem):
    """
    Set the memory area to be plotted (RGBA)

    DESCRIPTION:

        Set the memory area to be plotted (with the memcairo driver) as the
        dev member of the stream structure. Also set the number of pixels in
        the memory passed in
        plotmem, which is a block of memory
        maxy by
        maxx by 4 bytes long, say: 480 x 640 x 4 (Y, X, RGBA)

        This memory will have to be freed by the user!

        Redacted form: plsmema(maxx, maxy, plotmem)

        This function is not used in any examples.



    SYNOPSIS:

    plsmema(maxx, maxy, plotmem)

    ARGUMENTS:

        maxx (PLINT, input) :    Size of memory area in the X coordinate.

        maxy (PLINT, input) :    Size of memory area in the Y coordinate.

        plotmem (PLPointer, input) :    Pointer to the beginning of a
            user-supplied writeable memory area.

    """
    return _plplotc.plsmema(maxx, maxy, plotmem)

def plsmin(arg1, scale):
    """
    Set length of minor ticks

    DESCRIPTION:

        This sets up the length of the minor ticks and the length of the
        terminals on error bars.  The actual length is the product of the
        default length and a scaling factor as for character height.

        Redacted form: plsmin(def, scale)

        This function is used in example 29.



    SYNOPSIS:

    plsmin(def, scale)

    ARGUMENTS:

        def (PLFLT, input) :    The default length of a minor tick in
            millimeters, should be set to zero if the default length is to
            remain unchanged.

        scale (PLFLT, input) :    Scale factor to be applied to default to get
            actual tick length.

    """
    return _plplotc.plsmin(arg1, scale)

def plsori(ori):
    """
    Set orientation

    DESCRIPTION:

        Set integer plot orientation parameter.  This function is identical to
        plsdiori except for the type of the argument, and should be used in
        the same way.  See the documentation of plsdiori for details.

        Redacted form: plsori(ori)

        This function is used in example 3.



    SYNOPSIS:

    plsori(ori)

    ARGUMENTS:

        ori (PLINT, input) :    Orientation value (0 for landscape, 1 for
            portrait, etc.) The value is multiplied by 90 degrees to get the
            angle.

    """
    return _plplotc.plsori(ori)

def plspage(xp, yp, xleng, yleng, xoff, yoff):
    """
    Set page parameters

    DESCRIPTION:

        Sets the page configuration (optional).  If an individual parameter is
        zero then that parameter value is not updated.  Not all parameters are
        recognized by all drivers and the interpretation is device-dependent.
        The X-window driver uses the length and offset parameters to determine
        the window size and location.  The length and offset values are
        expressed in units that are specific to the current driver.  For
        instance: screen drivers will usually interpret them as number of
        pixels, whereas printer drivers will usually use mm.

        This routine, if used, must be called before initializing PLplot.  It
        may be called at later times for interactive drivers to change only
        the dpi for subsequent redraws which you can force via a call to
        plreplot.  If this function is not called then the page size defaults
        to landscape A4 for drivers which use real world page sizes and 744
        pixels wide by 538 pixels high for raster drivers. The default value
        for dx and dy is 90 pixels per inch for raster drivers.



        Redacted form: plspage(xp, yp, xleng, yleng, xoff, yoff)

        This function is used in examples 14 and 31.



    SYNOPSIS:

    plspage(xp, yp, xleng, yleng, xoff, yoff)

    ARGUMENTS:

        xp (PLFLT, input) :    Number of pixels per inch (DPI), x. Used only
            by raster drivers, ignored by drivers which use "real world" units
            (e.g. mm).

        yp (PLFLT, input) :    Number of pixels per inch (DPI), y.  Used only
            by raster drivers, ignored by drivers which use "real world" units
            (e.g. mm).

        xleng (PLINT, input) :    Page length, x.

        yleng (PLINT, input) :    Page length, y.

        xoff (PLINT, input) :    Page offset, x.

        yoff (PLINT, input) :    Page offset, y.

    """
    return _plplotc.plspage(xp, yp, xleng, yleng, xoff, yoff)

def plspal0(filename):
    """
    Set the cmap0 palette using the specified cmap0*.pal format file

    DESCRIPTION:

        Set the cmap0 palette using the specified cmap0*.pal format file.

        Redacted form: plspal0(filename)

        This function is in example 16.



    SYNOPSIS:

    plspal0(filename)

    ARGUMENTS:

        filename (PLCHAR_VECTOR, input) :    An ascii character string
            containing the name of the cmap0*.pal file.  If this string is
            empty, use the default cmap0*.pal file.

    """
    return _plplotc.plspal0(filename)

def plspal1(filename, interpolate):
    """
    Set the cmap1 palette using the specified cmap1*.pal format file

    DESCRIPTION:

        Set the cmap1 palette using the specified cmap1*.pal format file.

        Redacted form: plspal1(filename, interpolate)

        This function is used in example 16.



    SYNOPSIS:

    plspal1(filename, interpolate)

    ARGUMENTS:

        filename (PLCHAR_VECTOR, input) :    An ascii character string
            containing the name of the cmap1*.pal file.  If this string is
            empty, use the default cmap1*.pal file.

        interpolate (PLBOOL, input) :    If this parameter is true, the
            columns containing the intensity index, r, g, b, alpha and
            alt_hue_path in the cmap1*.pal file are used to set the cmap1
            palette with a call to plscmap1la. (The cmap1*.pal header contains
            a flag which controls whether the r, g, b data sent to plscmap1la
            are interpreted as HLS or RGB.) If this parameter is false, the
            intensity index and alt_hue_path columns are ignored and the r, g,
            b (interpreted as RGB), and alpha columns of the cmap1*.pal file
            are used instead to set the cmap1 palette directly with a call to
            plscmap1a.

    """
    return _plplotc.plspal1(filename, interpolate)

def plspause(pause):
    """
    Set the pause (on end-of-page) status

    DESCRIPTION:

        Set the pause (on end-of-page) status.

        Redacted form: plspause(pause)

        This function is in examples 14,20.



    SYNOPSIS:

    plspause(pause)

    ARGUMENTS:

        pause (PLBOOL, input) :    If pause is true there will be a pause on
            end-of-page for those drivers which support this.  Otherwise there
            is no pause.

    """
    return _plplotc.plspause(pause)

def plsstrm(strm):
    """
    Set current output stream

    DESCRIPTION:

        Sets the number of the current output stream.  The stream number
        defaults to 0 unless changed by this routine.  The first use of this
        routine must be followed by a call initializing PLplot (e.g. plstar).

        Redacted form: plsstrm(strm)

        This function is examples 1,14,20.



    SYNOPSIS:

    plsstrm(strm)

    ARGUMENTS:

        strm (PLINT, input) :    The current stream number.

    """
    return _plplotc.plsstrm(strm)

def plssub(nx, ny):
    """
    Set the number of subpages in x and y

    DESCRIPTION:

        Set the number of subpages in x and y.

        Redacted form: plssub(nx, ny)

        This function is examples 1,2,14,21,25,27.



    SYNOPSIS:

    plssub(nx, ny)

    ARGUMENTS:

        nx (PLINT, input) :    Number of windows in x direction (i.e., number
            of window columns).

        ny (PLINT, input) :    Number of windows in y direction (i.e., number
            of window rows).

    """
    return _plplotc.plssub(nx, ny)

def plssym(arg1, scale):
    """
    Set symbol size

    DESCRIPTION:

        This sets up the size of all subsequent symbols drawn by plpoin and
        plsym.  The actual height of a symbol is the product of the default
        symbol size and a scaling factor as for the character height.

        Redacted form: plssym(def, scale)

        This function is used in example 29.



    SYNOPSIS:

    plssym(def, scale)

    ARGUMENTS:

        def (PLFLT, input) :    The default height of a symbol in millimeters,
            should be set to zero if the default height is to remain
            unchanged.

        scale (PLFLT, input) :    Scale factor to be applied to default to get
            actual symbol height.

    """
    return _plplotc.plssym(arg1, scale)

def plstar(nx, ny):
    """
    Initialization

    DESCRIPTION:

        Initializing the plotting package.  The program prompts for the device
        keyword or number of the desired output device.  Hitting a RETURN in
        response to the prompt is the same as selecting the first device.  If
        only one device is enabled when PLplot is installed, plstar will issue
        no prompt.  The output device is divided into nx by ny subpages, each
        of which may be used independently.  The subroutine pladv is used to
        advance from one subpage to the next.

        Redacted form: plstar(nx, ny)

        This function is used in example 1.



    SYNOPSIS:

    plstar(nx, ny)

    ARGUMENTS:

        nx (PLINT, input) :    Number of subpages to divide output page in the
            x direction.

        ny (PLINT, input) :    Number of subpages to divide output page in the
            y direction.

    """
    return _plplotc.plstar(nx, ny)

def plstart(devname, nx, ny):
    """
    Initialization

    DESCRIPTION:

        Alternative to plstar for initializing the plotting package.  The
        device name keyword for the desired output device must be supplied as
        an argument.  These keywords are the same as those printed out by
        plstar.  If the requested device is not available, or if the input
        string is empty or begins with ``?'', the prompted start up of plstar
        is used.  This routine also divides the output device page into nx by
        ny subpages, each of which may be used independently.  The subroutine
        pladv is used to advance from one subpage to the next.

        Redacted form: General: plstart(devname, nx, ny)
                Perl/PDL: plstart(nx, ny, devname)


        This function is not used in any examples.



    SYNOPSIS:

    plstart(devname, nx, ny)

    ARGUMENTS:

        devname (PLCHAR_VECTOR, input) :    An ascii character string
            containing the device name keyword of the required output device.
            If
        devname is NULL or if the first character of the string is a ``?'',
            the normal (prompted) start up is used.

        nx (PLINT, input) :    Number of subpages to divide output page in the
            x direction.

        ny (PLINT, input) :    Number of subpages to divide output page in the
            y direction.

    """
    return _plplotc.plstart(devname, nx, ny)

def plstransform(*args):
    """
    Set a global coordinate transform function

    DESCRIPTION:

        This function can be used to define a coordinate transformation which
        affects all elements drawn within the current plot window.  The
        coordinate_transform callback function is similar to that provided for
        the plmap and plmeridians functions.  The coordinate_transform_data
        parameter may be used to pass extra data to coordinate_transform.

        Redacted form: General: plstransform(coordinate_transform,
        coordinate_transform_data)


        This function is used in examples 19 and 22.



    SYNOPSIS:

    plstransform(coordinate_transform, coordinate_transform_data)

    ARGUMENTS:

        coordinate_transform (PLTRANSFORM_callback, input) :    A callback
            function that defines the transformation from the input (x, y)
            world coordinates to new PLplot world coordinates.  If
        coordinate_transform is not supplied (e.g., is set to NULL in the C
            case), then no transform is applied.

        coordinate_transform_data (PLPointer, input) :    Optional extra data
            for
        coordinate_transform.

    """
    return _plplotc.plstransform(*args)

def plstring(n, ArrayCk, string):
    """
    Plot a glyph at the specified points

    DESCRIPTION:

        Plot a glyph at the specified points. (Supersedes plpoin and plsym
        because many[!] more glyphs are accessible with plstring.) The glyph
        is specified with a PLplot user string.  Note that the user string is
        not actually limited to one glyph so it is possible (but not normally
        useful) to plot more than one glyph at the specified points with this
        function.  As with plmtex and plptex, the user string can contain FCI
        escapes to determine the font, UTF-8 code to determine the glyph or
        else PLplot escapes for Hershey or unicode text to determine the
        glyph.

        Redacted form: plstring(x, y, string)

        This function is used in examples 4, 21 and 26.



    SYNOPSIS:

    plstring(n, x, y, string)

    ARGUMENTS:

        n (PLINT, input) :    Number of points in the x and y vectors.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            the points.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            the points.

        string (PLCHAR_VECTOR, input) :    A UTF-8 character string containing
            the glyph(s) to be plotted at each of the n points.

    """
    return _plplotc.plstring(n, ArrayCk, string)

def plstring3(n, arg2, arg3, string):
    """
    Plot a glyph at the specified 3D points

    DESCRIPTION:

        Plot a glyph at the specified 3D points. (Supersedes plpoin3 because
        many[!] more glyphs are accessible with plstring3.) Set up the call to
        this function similar to what is done for plline3. The glyph is
        specified with a PLplot user string.  Note that the user string is not
        actually limited to one glyph so it is possible (but not normally
        useful) to plot more than one glyph at the specified points with this
        function.  As with plmtex and plptex, the user string can contain FCI
        escapes to determine the font, UTF-8 code to determine the glyph or
        else PLplot escapes for Hershey or unicode text to determine the
        glyph.

        Redacted form: plstring3(x, y, z, string)

        This function is used in example 18.



    SYNOPSIS:

    plstring3(n, x, y, z, string)

    ARGUMENTS:

        n (PLINT, input) :    Number of points in the x, y, and z vectors.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            the points.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            the points.

        z (PLFLT_VECTOR, input) :    A vector containing the z coordinates of
            the points.

        string (PLCHAR_VECTOR, input) :    A UTF-8 character string containing
            the glyph(s) to be plotted at each of the n points. points.

    """
    return _plplotc.plstring3(n, arg2, arg3, string)

def plstripa(id, pen, x, y):
    """
    Add a point to a strip chart

    DESCRIPTION:

        Add a point to a given pen of a given strip chart. There is no need
        for all pens to have the same number of points or to be equally
        sampled in the x coordinate. Allocates memory and rescales as
        necessary.

        Redacted form: plstripa(id, pen, x, y)

        This function is used in example 17.



    SYNOPSIS:

    plstripa(id, pen, x, y)

    ARGUMENTS:

        id (PLINT, input) :    Identification number of the strip chart (set
            up in plstripc).

        pen (PLINT, input) :    Pen number (ranges from 0 to 3).

        x (PLFLT, input) :    X coordinate of point to plot.

        y (PLFLT, input) :    Y coordinate of point to plot.

    """
    return _plplotc.plstripa(id, pen, x, y)

def plstripc(xspec, yspec, xmin, xmax, xjump, ymin, ymax, xlpos, ylpos, y_ascl, acc, colbox, collab, Array, ArrayCk, legline, labx, laby, labtop):
    """
    Create a 4-pen strip chart

    DESCRIPTION:

        Create a 4-pen strip chart, to be used afterwards by plstripa

        Redacted form: General: plstripc(id, xspec, yspec, xmin, xmax, xjump,
        ymin, ymax, xlpos, ylpos, y_ascl, acc, colbox, collab, colline,
        styline, legline, labx, laby, labz)
                Perl/PDL: plstripc(xmin, xmax, xjump, ymin, ymax, xlpos,
        ylpos, y_ascl, acc, colbox, collab, colline, styline, id, xspec,
        ypsec, legline, labx, laby, labtop)


        This function is used in example 17.



    SYNOPSIS:

    plstripc(id, xspec, yspec, xmin, xmax, xjump, ymin, ymax, xlpos, ylpos, y_ascl, acc, colbox, collab, colline, styline, legline[], labx, laby, labtop)

    ARGUMENTS:

        id (PLINT_NC_SCALAR, output) :    Returned value of the identification
            number of the strip chart to use on plstripa and plstripd.

        xspec (PLCHAR_VECTOR, input) :    An ascii character string containing
            the x-axis specification as in plbox.

        yspec (PLCHAR_VECTOR, input) :    An ascii character string containing
            the y-axis specification as in plbox.

        xmin (PLFLT, input) :    Initial coordinates of plot box; they will
            change as data are added.

        xmax (PLFLT, input) :    Initial coordinates of plot box; they will
            change as data are added.

        xjump (PLFLT, input) :    When x attains xmax, the length of the plot
            is multiplied by the factor (1 +
        xjump) .

        ymin (PLFLT, input) :    Initial coordinates of plot box; they will
            change as data are added.

        ymax (PLFLT, input) :    Initial coordinates of plot box; they will
            change as data are added.

        xlpos (PLFLT, input) :    X legend box position (range from 0 to 1).

        ylpos (PLFLT, input) :    Y legend box position (range from 0 to 1).

        y_ascl (PLBOOL, input) :    Autoscale y between x jumps if y_ascl is
            true, otherwise not.

        acc (PLBOOL, input) :    Accumulate strip plot if acc is true,
            otherwise slide display.

        colbox (PLINT, input) :    Plot box color index (cmap0).

        collab (PLINT, input) :    Legend color index (cmap0).

        colline (PLINT_VECTOR, input) :    A vector containing the cmap0 color
            indices for the 4 pens.

        styline (PLINT_VECTOR, input) :    A vector containing the line style
            indices for the 4 pens.

        legline (PLCHAR_MATRIX, input) :    A vector of UTF-8 character
            strings containing legends for the 4 pens.

        labx (PLCHAR_VECTOR, input) :    A UTF-8 character string containing
            the label for the x axis.

        laby (PLCHAR_VECTOR, input) :    A UTF-8 character string containing
            the label for the y axis.

        labtop (PLCHAR_VECTOR, input) :    A UTF-8 character string containing
            the plot title.

    """
    return _plplotc.plstripc(xspec, yspec, xmin, xmax, xjump, ymin, ymax, xlpos, ylpos, y_ascl, acc, colbox, collab, Array, ArrayCk, legline, labx, laby, labtop)

def plstripd(id):
    """
    Deletes and releases memory used by a strip chart

    DESCRIPTION:

        Deletes and releases memory used by a strip chart.

        Redacted form: plstripd(id)

        This function is used in example 17.



    SYNOPSIS:

    plstripd(id)

    ARGUMENTS:

        id (PLINT, input) :    Identification number of strip chart to delete.

    """
    return _plplotc.plstripd(id)

def plstyl(n, ArrayCk):
    """
    Set line style

    DESCRIPTION:

        This sets up the line style for all lines subsequently drawn.  A line
        consists of segments in which the pen is alternately down and up. The
        lengths of these segments are passed in the vectors mark and space
        respectively.  The number of mark-space pairs is specified by nms.  In
        order to return the line style to the default continuous line, plstyl
        should be called with nms =0 .(see also pllsty)

        Redacted form: plstyl(mark, space)

        This function is used in examples 1, 9, and 14.



    SYNOPSIS:

    plstyl(nms, mark, space)

    ARGUMENTS:

        nms (PLINT, input) :    The number of mark and space elements in a
            line.  Thus a simple broken line can be obtained by setting nms=1
            .  A continuous line is specified by setting nms=0 .

        mark (PLINT_VECTOR, input) :    A vector containing the lengths of the
            segments during which the pen is down, measured in micrometers.

        space (PLINT_VECTOR, input) :    A vector containing the lengths of
            the segments during which the pen is up, measured in micrometers.

    """
    return _plplotc.plstyl(n, ArrayCk)

def plsvect(ArrayNull, ArrayCkNull, deffalse):
    """
    Set arrow style for vector plots

    DESCRIPTION:

        Set the style for the arrow used by plvect to plot vectors.

        Redacted form: plsvect(arrowx, arrowy, fill)

        This function is used in example 22.



    SYNOPSIS:

    plsvect(arrowx, arrowy, npts, fill)

    ARGUMENTS:

        arrowx, arrowy (PLFLT_VECTOR, input) :    A pair of vectors containing
            the x and y points which make up the arrow. The arrow is plotted
            by joining these points to form a polygon. The scaling assumes
            that the x and y points in the arrow lie in the range -0.5 <= x,y
            <= 0.5. If both arrowx and arrowy are NULL then the arrow style
            will be reset to its default.

        npts (PLINT, input) :    Number of points in the vectors arrowx and
            arrowy.

        fill (PLBOOL, input) :    If fill is true then the arrow is closed, if
            fill is false then the arrow is open.

    """
    return _plplotc.plsvect(ArrayNull, ArrayCkNull, deffalse)

def plsvpa(xmin, xmax, ymin, ymax):
    """
    Specify viewport in absolute coordinates

    DESCRIPTION:

        Alternate routine to plvpor for setting up the viewport.  This routine
        should be used only if the viewport is required to have a definite
        size in millimeters.  The routine plgspa is useful for finding out the
        size of the current subpage.

        Redacted form: plsvpa(xmin, xmax, ymin, ymax)

        This function is used in example 10.



    SYNOPSIS:

    plsvpa(xmin, xmax, ymin, ymax)

    ARGUMENTS:

        xmin (PLFLT, input) :    The distance of the left-hand edge of the
            viewport from the left-hand edge of the subpage in millimeters.

        xmax (PLFLT, input) :    The distance of the right-hand edge of the
            viewport from the left-hand edge of the subpage in millimeters.

        ymin (PLFLT, input) :    The distance of the bottom edge of the
            viewport from the bottom edge of the subpage in millimeters.

        ymax (PLFLT, input) :    The distance of the top edge of the viewport
            from the bottom edge of the subpage in millimeters.

    """
    return _plplotc.plsvpa(xmin, xmax, ymin, ymax)

def plsxax(digmax, digits):
    """
    Set x axis parameters

    DESCRIPTION:

        Sets values of the digmax and digits flags for the x axis.  See the
        PLplot documentation for more information.

        Redacted form: plsxax(digmax, digits)

        This function is used in example 31.



    SYNOPSIS:

    plsxax(digmax, digits)

    ARGUMENTS:

        digmax (PLINT, input) :    Variable to set the maximum number of
            digits for the x axis.  If nonzero, the printed label will be
            switched to a floating-point representation when the number of
            digits exceeds digmax.

        digits (PLINT, input) :    Field digits value.  Currently, changing
            its value here has no effect since it is set only by plbox or
            plbox3.  However, the user may obtain its value after a call to
            either of these functions by calling plgxax.

    """
    return _plplotc.plsxax(digmax, digits)

def plsyax(digmax, digits):
    """
    Set y axis parameters

    DESCRIPTION:

        Identical to plsxax, except that arguments are flags for y axis. See
        the description of plsxax for more detail.

        Redacted form: plsyax(digmax, digits)

        This function is used in examples 1, 14, and 31.



    SYNOPSIS:

    plsyax(digmax, digits)

    ARGUMENTS:

        digmax (PLINT, input) :    Variable to set the maximum number of
            digits for the y axis.  If nonzero, the printed label will be
            switched to a floating-point representation when the number of
            digits exceeds digmax.

        digits (PLINT, input) :    Field digits value.  Currently, changing
            its value here has no effect since it is set only by plbox or
            plbox3.  However, the user may obtain its value after a call to
            either of these functions by calling plgyax.

    """
    return _plplotc.plsyax(digmax, digits)

def plsym(n, ArrayCk, code):
    """
    Plot a glyph at the specified points

    DESCRIPTION:

        Plot a glyph at the specified points.  (This function is largely
        superseded by plstring which gives access to many[!] more glyphs.)

        Redacted form: plsym(x, y, code)

        This function is used in example 7.



    SYNOPSIS:

    plsym(n, x, y, code)

    ARGUMENTS:

        n (PLINT, input) :    Number of points in the x and y vectors.

        x (PLFLT_VECTOR, input) :    A vector containing the x coordinates of
            the points.

        y (PLFLT_VECTOR, input) :    A vector containing the y coordinates of
            the points.

        code (PLINT, input) :    Hershey symbol code corresponding to a glyph
            to be plotted at each of the n points.

    """
    return _plplotc.plsym(n, ArrayCk, code)

def plszax(digmax, digits):
    """
    Set z axis parameters

    DESCRIPTION:

        Identical to plsxax, except that arguments are flags for z axis. See
        the description of plsxax for more detail.

        Redacted form: plszax(digmax, digits)

        This function is used in example 31.



    SYNOPSIS:

    plszax(digmax, digits)

    ARGUMENTS:

        digmax (PLINT, input) :    Variable to set the maximum number of
            digits for the z axis.  If nonzero, the printed label will be
            switched to a floating-point representation when the number of
            digits exceeds digmax.

        digits (PLINT, input) :    Field digits value.  Currently, changing
            its value here has no effect since it is set only by plbox or
            plbox3.  However, the user may obtain its value after a call to
            either of these functions by calling plgzax.

    """
    return _plplotc.plszax(digmax, digits)

def pltext():
    """
    Switch to text screen

    DESCRIPTION:

        Sets an interactive device to text mode, used in conjunction with
        plgra to allow graphics and text to be interspersed.  On a device
        which supports separate text and graphics windows, this command causes
        control to be switched to the text window.  This can be useful for
        printing diagnostic messages or getting user input, which would
        otherwise interfere with the plots.  The program must switch back to
        the graphics window before issuing plot commands, as the text (or
        console) device will probably become quite confused otherwise.  If
        already in text mode, this command is ignored.  It is also ignored on
        devices which only support a single window or use a different method
        for shifting focus (see also plgra).

        Redacted form: pltext()

        This function is used in example 1.



    SYNOPSIS:

    pltext()

    """
    return _plplotc.pltext()

def pltimefmt(fmt):
    """
    Set format for date / time labels

    DESCRIPTION:

        Sets the format for date / time labels. To enable date / time format
        labels see the options to plbox, plbox3, and plenv.

        Redacted form: pltimefmt(fmt)

        This function is used in example 29.



    SYNOPSIS:

    pltimefmt(fmt)

    ARGUMENTS:

        fmt (PLCHAR_VECTOR, input) :    An ascii character string which is
            interpreted similarly to the format specifier of typical system
            strftime routines except that PLplot ignores locale and also
            supplies some useful extensions in the context of plotting.  All
            text in the string is printed as-is other than conversion
            specifications which take the form of a '%' character followed by
            further conversion specification character.  The conversion
            specifications which are similar to those provided by system
            strftime routines are the following: %a: The abbreviated (English)
            weekday name.
                %A: The full (English) weekday name.
                %b: The abbreviated (English) month name.
                %B: The full (English) month name.
                %c: Equivalent to %a %b %d %T %Y (non-ISO).
                %C: The century number (year/100) as a 2-digit integer.
                %d: The day of the month as a decimal number (range 01 to 31).
                %D: Equivalent to %m/%d/%y (non-ISO).
                %e: Like %d, but a leading zero is replaced by a space.
                %F: Equivalent to %Y-%m-%d (the ISO 8601 date format).
                %h: Equivalent to %b.
                %H: The hour as a decimal number using a 24-hour clock (range
                00 to 23).
                %I: The hour as a decimal number using a 12-hour clock (range
                01 to 12).
                %j: The day of the year as a decimal number (range 001 to
                366).
                %k: The hour (24-hour clock) as a decimal number (range 0 to
                23); single digits are preceded by a blank.  (See also %H.)
                %l: The hour (12-hour clock) as a decimal number (range 1 to
                12); single digits are preceded by a blank.  (See also %I.)
                %m: The month as a decimal number (range 01 to 12).
                %M: The minute as a decimal number (range 00 to 59).
                %n: A newline character.
                %p: Either "AM" or "PM" according to the given time value.
                Noon is treated as "PM" and midnight as "AM".
                %r: Equivalent to %I:%M:%S %p.
                %R: The time in 24-hour notation (%H:%M). For a version
                including the seconds, see %T below.
                %s: The number of seconds since the Epoch, 1970-01-01 00:00:00
                +0000 (UTC).
                %S: The second as a decimal number (range 00 to 60).  (The
                range is up to 60 to allow for occasional leap seconds.)
                %t: A tab character.
                %T: The time in 24-hour notation (%H:%M:%S).
                %u: The day of the week as a decimal, range 1 to 7, Monday
                being 1.  See also %w.
                %U: The week number of the current year as a decimal number,
                range 00 to 53, starting with the first Sunday as the first
                day of week 01.  See also %V and %W.
                %v: Equivalent to %e-%b-%Y.
                %V: The ISO 8601 week number of the current year as a decimal
                number, range 01 to 53, where week 1 is the first week that
                has at least 4 days in the new year.  See also %U and %W.
                %w: The day of the week as a decimal, range 0 to 6, Sunday
                being 0.  See also %u.
                %W: The week number of the current year as a decimal number,
                range 00 to 53, starting with the first Monday as the first
                day of week 01.
                %x: Equivalent to %a %b %d %Y.
                %X: Equivalent to %T.
                %y: The year as a decimal number without a century (range 00
                to 99).
                %Y: The year as a decimal number including a century.
                %z: The UTC time-zone string = "+0000".
                %Z: The UTC time-zone abbreviation = "UTC".
                %+: The UTC date and time in default format of the Unix date
                command which is equivalent to %a %b %d %T %Z %Y.
                %%: A literal "%" character.
          The conversion specifications which are extensions to those normally
             provided by system strftime routines are the following: %(0-9):
             The fractional part of the seconds field (including leading
             decimal point) to the specified accuracy. Thus %S%3 would give
             seconds to millisecond accuracy (00.000).
                %.: The fractional part of the seconds field (including
                leading decimal point) to the maximum available accuracy. Thus
                %S%. would give seconds with fractional part up to 9 decimal
                places if available.

    """
    return _plplotc.pltimefmt(fmt)

def plvasp(aspect):
    """
    Specify viewport using aspect ratio only

    DESCRIPTION:

        Selects the largest viewport with the given aspect ratio within the
        subpage that leaves a standard margin (left-hand margin of eight
        character heights, and a margin around the other three sides of five
        character heights).

        Redacted form: plvasp(aspect)

        This function is used in example 13.



    SYNOPSIS:

    plvasp(aspect)

    ARGUMENTS:

        aspect (PLFLT, input) :    Ratio of length of y axis to length of x
            axis of resulting viewport.

    """
    return _plplotc.plvasp(aspect)

def plvect(*args):
    """
    Vector plot

    DESCRIPTION:

        Draws a plot of vector data contained in the matrices (
        u[
        nx][
        ny],
        v[
        nx][
        ny]) . The scaling factor for the vectors is given by scale. A
        transformation routine pointed to by pltr with a pointer pltr_data for
        additional data required by the transformation routine to map indices
        within the matrices to the world coordinates. The style of the vector
        arrow may be set using plsvect.

        Redacted form: plvect(u, v, scale, pltr, pltr_data) where (see above
        discussion) the pltr, pltr_data callback arguments are sometimes
        replaced by a tr vector with 6 elements, or xg and yg array arguments
        with either one or two dimensions.

        This function is used in example 22.



    SYNOPSIS:

    plvect(u, v, nx, ny, scale, pltr, pltr_data)

    ARGUMENTS:

        u, v (PLFLT_MATRIX, input) :    A pair of matrices containing the x
            and y components of the vector data to be plotted.

        nx, ny (PLINT, input) :    Dimensions of the matrices u and v.

        scale (PLFLT, input) :    Parameter to control the scaling factor of
            the vectors for plotting. If scale = 0  then the scaling factor is
            automatically calculated for the data. If scale < 0 then the
            scaling factor is automatically calculated for the data and then
            multiplied by -
        scale. If scale > 0 then the scaling factor is set to scale.

        pltr (PLTRANSFORM_callback, input) :    A callback function that
            defines the transformation between the zero-based indices of the
            matrices u and v and world coordinates.For the C case,
            transformation functions are provided in the PLplot library: pltr0
            for the identity mapping, and pltr1 and pltr2 for arbitrary
            mappings respectively defined by vectors and matrices.  In
            addition, C callback routines for the transformation can be
            supplied by the user such as the mypltr function in
            examples/c/x09c.c which provides a general linear transformation
            between index coordinates and world coordinates.For languages
            other than C you should consult the PLplot documentation for the
            details concerning how PLTRANSFORM_callback arguments are
            interfaced. However, in general, a particular pattern of
            callback-associated arguments such as a tr vector with 6 elements;
            xg and yg vectors; or xg and yg matrices are respectively
            interfaced to a linear-transformation routine similar to the above
            mypltr function; pltr1; and pltr2. Furthermore, some of our more
            sophisticated bindings (see, e.g., the PLplot documentation)
            support native language callbacks for handling index to
            world-coordinate transformations.  Examples of these various
            approaches are given in examples/<language>x09*,
            examples/<language>x16*, examples/<language>x20*,
            examples/<language>x21*, and examples/<language>x22*, for all our
            supported languages.

        pltr_data (PLPointer, input) :    Extra parameter to help pass
            information to pltr0, pltr1, pltr2, or whatever callback routine
            that is externally supplied.

    """
    return _plplotc.plvect(*args)

def plvpas(xmin, xmax, ymin, ymax, aspect):
    """
    Specify viewport using coordinates and aspect ratio

    DESCRIPTION:

        Device-independent routine for setting up the viewport.  The viewport
        is chosen to be the largest with the given aspect ratio that fits
        within the specified region (in terms of normalized subpage
        coordinates).  This routine is functionally equivalent to plvpor when
        a ``natural'' aspect ratio (0.0) is chosen.  Unlike plvasp, this
        routine reserves no extra space at the edges for labels.

        Redacted form: plvpas(xmin, xmax, ymin, ymax, aspect)

        This function is used in example 9.



    SYNOPSIS:

    plvpas(xmin, xmax, ymin, ymax, aspect)

    ARGUMENTS:

        xmin (PLFLT, input) :    The normalized subpage coordinate of the
            left-hand edge of the viewport.

        xmax (PLFLT, input) :    The normalized subpage coordinate of the
            right-hand edge of the viewport.

        ymin (PLFLT, input) :    The normalized subpage coordinate of the
            bottom edge of the viewport.

        ymax (PLFLT, input) :    The normalized subpage coordinate of the top
            edge of the viewport.

        aspect (PLFLT, input) :    Ratio of length of y axis to length of x
            axis.

    """
    return _plplotc.plvpas(xmin, xmax, ymin, ymax, aspect)

def plvpor(xmin, xmax, ymin, ymax):
    """
    Specify viewport using normalized subpage coordinates

    DESCRIPTION:

        Device-independent routine for setting up the viewport.  This defines
        the viewport in terms of normalized subpage coordinates which run from
        0.0 to 1.0 (left to right and bottom to top) along each edge of the
        current subpage.  Use the alternate routine plsvpa in order to create
        a viewport of a definite size.

        Redacted form: plvpor(xmin, xmax, ymin, ymax)

        This function is used in examples 2, 6-8, 10, 11, 15, 16, 18, 21, 23,
        24, 26, 27, and 31.



    SYNOPSIS:

    plvpor(xmin, xmax, ymin, ymax)

    ARGUMENTS:

        xmin (PLFLT, input) :    The normalized subpage coordinate of the
            left-hand edge of the viewport.

        xmax (PLFLT, input) :    The normalized subpage coordinate of the
            right-hand edge of the viewport.

        ymin (PLFLT, input) :    The normalized subpage coordinate of the
            bottom edge of the viewport.

        ymax (PLFLT, input) :    The normalized subpage coordinate of the top
            edge of the viewport.

    """
    return _plplotc.plvpor(xmin, xmax, ymin, ymax)

def plvsta():
    """
    Select standard viewport

    DESCRIPTION:

        Selects the largest viewport within the subpage that leaves a standard
        margin (left-hand margin of eight character heights, and a margin
        around the other three sides of five character heights).

        Redacted form: plvsta()

        This function is used in examples 1, 12, 14, 17, 25, and 29.



    SYNOPSIS:

    plvsta()

    """
    return _plplotc.plvsta()

def plw3d(basex, basey, height, xmin0, xmax0, ymin0, ymax0, zmin0, zmax0, alt, az):
    """
    Configure the transformations required for projecting a 3D surface on a 2D window

    DESCRIPTION:

        Configure the transformations required for projecting a 3D surface on
        an existing 2D window.  Those transformations (see the PLplot
        documentation) are done to a rectangular cuboid enclosing the 3D
        surface which has its limits expressed in 3D world coordinates and
        also normalized 3D coordinates (used for interpreting the altitude and
        azimuth of the viewing angle).  The transformations consist of the
        linear transform from 3D world coordinates to normalized 3D
        coordinates, and the 3D rotation of normalized coordinates required to
        align the pole of the new 3D coordinate system with the viewing
        direction specified by altitude and azimuth so that x and y of the
        surface elements in that transformed coordinate system are the
        projection of the 3D surface with given viewing direction on the 2D
        window.

        The enclosing rectangular cuboid for the surface plot is defined by
        xmin, xmax, ymin, ymax, zmin and zmax in 3D world coordinates.  It is
        mapped into the same rectangular cuboid with normalized 3D coordinate
        sizes of basex by basey by height so that xmin maps to -
        basex/2, xmax maps to basex/2, ymin maps to -
        basey/2, ymax maps to basey/2, zmin maps to 0 and zmax maps to height.
         The resulting rectangular cuboid in normalized coordinates is then
        viewed by an observer at altitude alt and azimuth az.  This routine
        must be called before plbox3 or any of the 3D surface plotting
        routines; plmesh, plmeshc, plot3d, plot3dc, plot3dcl, plsurf3d,
        plsurf3dl or plfill3.

        Redacted form: plw3d(basex, basey, height, xmin, xmax, ymin, ymax,
        zmin, zmax, alt, az)

        This function is examples 8, 11, 18, and 21.



    SYNOPSIS:

    plw3d(basex, basey, height, xmin, xmax, ymin, ymax, zmin, zmax, alt, az)

    ARGUMENTS:

        basex (PLFLT, input) :    The normalized x coordinate size of the
            rectangular cuboid.

        basey (PLFLT, input) :    The normalized y coordinate size of the
            rectangular cuboid.

        height (PLFLT, input) :    The normalized z coordinate size of the
            rectangular cuboid.

        xmin (PLFLT, input) :    The minimum x world coordinate of the
            rectangular cuboid.

        xmax (PLFLT, input) :    The maximum x world coordinate of the
            rectangular cuboid.

        ymin (PLFLT, input) :    The minimum y world coordinate of the
            rectangular cuboid.

        ymax (PLFLT, input) :    The maximum y world coordinate of the
            rectangular cuboid.

        zmin (PLFLT, input) :    The minimum z world coordinate of the
            rectangular cuboid.

        zmax (PLFLT, input) :    The maximum z world coordinate of the
            rectangular cuboid.

        alt (PLFLT, input) :    The viewing altitude in degrees above the xy
            plane of the rectangular cuboid in normalized coordinates.

        az (PLFLT, input) :    The viewing azimuth in degrees of the
            rectangular cuboid in normalized coordinates.  When az=0, the
            observer is looking face onto the zx plane of the rectangular
            cuboid in normalized coordinates, and as az is increased, the
            observer moves clockwise around that cuboid when viewed from above
            the xy plane.

    """
    return _plplotc.plw3d(basex, basey, height, xmin0, xmax0, ymin0, ymax0, zmin0, zmax0, alt, az)

def plwidth(width):
    """
    Set pen width

    DESCRIPTION:

        Sets the pen width.

        Redacted form: plwidth(width)

        This function is used in examples 1 and 2.



    SYNOPSIS:

    plwidth(width)

    ARGUMENTS:

        width (PLFLT, input) :    The desired pen width.  If width is negative
            or the same as the previous value no action is taken. width = 0.
            should be interpreted as as the minimum valid pen width for the
            device.  The interpretation of positive width values is also
            device dependent.

    """
    return _plplotc.plwidth(width)

def plwind(xmin, xmax, ymin, ymax):
    """
    Specify window

    DESCRIPTION:

        Specify the window, i.e., the world coordinates of the edges of the
        viewport.

        Redacted form: plwind(xmin, xmax, ymin, ymax)

        This function is used in examples 1, 2, 4, 6-12, 14-16, 18, 21, 23-27,
        29, and 31.



    SYNOPSIS:

    plwind(xmin, xmax, ymin, ymax)

    ARGUMENTS:

        xmin (PLFLT, input) :    The world x coordinate of the left-hand edge
            of the viewport.

        xmax (PLFLT, input) :    The world x coordinate of the right-hand edge
            of the viewport.

        ymin (PLFLT, input) :    The world y coordinate of the bottom edge of
            the viewport.

        ymax (PLFLT, input) :    The world y coordinate of the top edge of the
            viewport.

    """
    return _plplotc.plwind(xmin, xmax, ymin, ymax)

def plxormod(mode):
    """
    Enter or leave xor mode

    DESCRIPTION:

        Enter (when mode is true) or leave (when mode is false) xor mode for
        those drivers (e.g., the xwin driver) that support it.  Enables
        erasing plots by drawing twice the same line, symbol, etc.  If driver
        is not capable of xor operation it returns a status of false.

        Redacted form: plxormod(mode, status)

        This function is used in examples 1 and 20.



    SYNOPSIS:

    plxormod(mode, status)

    ARGUMENTS:

        mode (PLBOOL, input) :    mode is true means enter xor mode and mode
            is false means leave xor mode.

        status (PLBOOL_NC_SCALAR, output) :    Returned value of the status.
            modestatus of true (false) means driver is capable (incapable) of
            xor mode.

    """
    return _plplotc.plxormod(mode)

def plmap(mapform, type, minx, maxx, miny, maxy):
    """
    Plot continental outline or shapefile data in world coordinates

    DESCRIPTION:

        Plots continental outlines or shapefile data in world coordinates. A
        demonstration of how to use this function to create different
        projections can be found in examples/c/x19c. PLplot is provided with
        basic coastal outlines and USA state borders. These can be used
        irrespective of whether Shapefile support is built into PLplot. With
        Shapefile support this function can also be used with user Shapefiles,
        in which case it will plot the entire contents of a Shapefile joining
        each point of each Shapefile element with a line. Shapefiles have
        become a popular standard for geographical data and data in this
        format can be easily found from a number of online sources. Shapefile
        data is actually provided as three or more files with the same
        filename, but different extensions. The .shp and .shx files are
        required for plotting Shapefile data with PLplot.

        Redacted form: plmap(mapform, name, minx, maxx, miny, maxy)

        This function is used in example 19.



    SYNOPSIS:

    plmap(mapform, name, minx, maxx, miny, maxy)

    ARGUMENTS:

        mapform (PLMAPFORM_callback, input) :    A user supplied function to
            transform the original map data coordinates to a new coordinate
            system. The PLplot-supplied map data is provided as latitudes and
            longitudes; other Shapefile data may be provided in other
            coordinate systems as can be found in their .prj plain text files.
            For example, by using this transform we can change from a
            longitude, latitude coordinate to a polar stereographic
            projection. Initially, x[0]..[n-1] are the original x coordinates
            (longitudes for the PLplot-supplied data) and y[0]..y[n-1] are the
            corresponding y coordinates (latitudes for the PLplot supplied
            data).  After the call to mapform(), x[] and y[] should be
            replaced by the corresponding plot coordinates. If no transform is
            desired, mapform can be replaced by NULL.

        name (PLCHAR_VECTOR, input) :    An ascii character string specifying
            the type of map plotted. This is either one of the PLplot built-in
            maps or the file name of a set of Shapefile files without the file
            extensions. For the PLplot built-in maps the possible values are:
            "globe" -- continental outlines
                "usa" -- USA and state boundaries
                "cglobe" -- continental outlines and countries
                "usaglobe" -- USA, state boundaries and continental outlines


        minx (PLFLT, input) :    The minimum x value of map elements to be
            drawn. For the built in maps this is a measure of longitude. For
            Shapefiles the units must match the projection. The value of minx
            must be less than the value of maxx. Specifying a useful limit for
            these limits provides a useful optimization for complex or
            detailed maps.

        maxx (PLFLT, input) :    The maximum x value of map elements to be
            drawn

        miny (PLFLT, input) :    The minimum y value of map elements to be
            drawn. For the built in maps this is a measure of latitude. For
            Shapefiles the units must match the projection. The value of miny
            must be less than the value of maxy.

        maxy (PLFLT, input) :    The maximum y value of map elements to be
            drawn.

    """
    return _plplotc.plmap(mapform, type, minx, maxx, miny, maxy)

def plmapline(mapform, type, minx, maxx, miny, maxy, ArrayNull):
    """
    Plot all or a subset of Shapefile data using lines in world coordinates

    DESCRIPTION:

        Plot all or a subset of Shapefile data using lines in world
        coordinates. Our 19th standard example demonstrates how to use this
        function. This function plots data from a Shapefile using lines as in
        plmap, however it also has the option of also only drawing specified
        elements from the Shapefile. The vector of indices of the required
        elements are passed as a function argument. The Shapefile data should
        include a metadata file (extension.dbf) listing all items within the
        Shapefile. This file can be opened by most popular spreadsheet
        programs and can be used to decide which indices to pass to this
        function.

        Redacted form: plmapline(mapform, name, minx, maxx, miny, maxy,
        plotentries)

        This function is used in example 19.



    SYNOPSIS:

    plmapline(mapform, name, minx, maxx, miny, maxy, plotentries, nplotentries)

    ARGUMENTS:

        mapform (PLMAPFORM_callback, input) :    A user supplied function to
            transform the coordinates given in the shapefile into a plot
            coordinate system. By using this transform, we can change from a
            longitude, latitude coordinate to a polar stereographic project,
            for example.  Initially, x[0]..[n-1] are the longitudes and
            y[0]..y[n-1] are the corresponding latitudes.  After the call to
            mapform(), x[] and y[] should be replaced by the corresponding
            plot coordinates. If no transform is desired, mapform can be
            replaced by NULL.

        name (PLCHAR_VECTOR, input) :    An ascii character string specifying
            the file name of a set of Shapefile files without the file
            extension.

        minx (PLFLT, input) :    The minimum x value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example longitude or
            distance. The value of minx must be less than the value of maxx.

        maxx (PLFLT, input) :    The maximum x value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        miny (PLFLT, input) :    The minimum y value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example latitude or
            distance. The value of miny must be less than the value of maxy.

        maxy (PLFLT, input) :    The maximum y value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        plotentries (PLINT_VECTOR, input) :    A vector containing the
            zero-based indices of the Shapefile elements which will be drawn.
            Setting
        plotentries to NULL will plot all elements of the Shapefile.

        nplotentries (PLINT, input) :    The number of items in
        plotentries.  Ignored if
        plotentries is NULL.

    """
    return _plplotc.plmapline(mapform, type, minx, maxx, miny, maxy, ArrayNull)

def plmapstring(mapform, type, string, minx, maxx, miny, maxy, ArrayNull):
    """
    Plot all or a subset of Shapefile data using strings or points in world coordinates

    DESCRIPTION:

        As per plmapline, however the items are plotted as strings or points
        in the same way as plstring.

        Redacted form: plmapstring(mapform, name, string, minx, maxx, miny,
        maxy, plotentries)

        This function is not used in any examples.



    SYNOPSIS:

    plmapstring(mapform, name, string, minx, maxx, miny, maxy, plotentries, nplotentries)

    ARGUMENTS:

        mapform (PLMAPFORM_callback, input) :    A user supplied function to
            transform the coordinates given in the shapefile into a plot
            coordinate system. By using this transform, we can change from a
            longitude, latitude coordinate to a polar stereographic project,
            for example.  Initially, x[0]..[n-1] are the longitudes and
            y[0]..y[n-1] are the corresponding latitudes.  After the call to
            mapform(), x[] and y[] should be replaced by the corresponding
            plot coordinates. If no transform is desired, mapform can be
            replaced by NULL.

        name (PLCHAR_VECTOR, input) :    An ascii character string specifying
            the file name of a set of Shapefile files without the file
            extension.

        string (PLCHAR_VECTOR, input) :    A UTF-8 character string to be
            drawn.

        minx (PLFLT, input) :    The minimum x value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example longitude or
            distance. The value of minx must be less than the value of maxx.

        maxx (PLFLT, input) :    The maximum x value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        miny (PLFLT, input) :    The minimum y value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example latitude or
            distance. The value of miny must be less than the value of maxy.

        maxy (PLFLT, input) :    The maximum y value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        plotentries (PLINT_VECTOR, input) :    A vector containing the
            zero-based indices of the Shapefile elements which will be drawn.
            Setting
        plotentries to NULL will plot all elements of the Shapefile.

        nplotentries (PLINT, input) :    The number of items in
        plotentries.  Ignored if
        plotentries is NULL.

    """
    return _plplotc.plmapstring(mapform, type, string, minx, maxx, miny, maxy, ArrayNull)

def plmaptex(mapform, type, dx, dy, just, text, minx, maxx, miny, maxy, plotentry):
    """
    Draw text at points defined by Shapefile data in world coordinates

    DESCRIPTION:

        As per plmapline, however the items are plotted as text in the same
        way as plptex.

        Redacted form: plmaptex(mapform, name, dx, dy, just, text, minx, maxx,
        miny, maxy, plotentry)

        This function is used in example 19.



    SYNOPSIS:

    plmaptex(mapform, name, dx, dy, just, text, minx, maxx, miny, maxy, plotentry)

    ARGUMENTS:

        mapform (PLMAPFORM_callback, input) :    A user supplied function to
            transform the coordinates given in the shapefile into a plot
            coordinate system. By using this transform, we can change from a
            longitude, latitude coordinate to a polar stereographic project,
            for example.  Initially, x[0]..[n-1] are the longitudes and
            y[0]..y[n-1] are the corresponding latitudes.  After the call to
            mapform(), x[] and y[] should be replaced by the corresponding
            plot coordinates. If no transform is desired, mapform can be
            replaced by NULL.

        name (PLCHAR_VECTOR, input) :    An ascii character string specifying
            the file name of a set of Shapefile files without the file
            extension.

        dx (PLFLT, input) :    Used to define the slope of the texts which is
            dy/dx.

        dy (PLFLT, input) :    Used to define the slope of the texts which is
            dy/dx.

        just (PLFLT, input) :    Set the justification of the text. The value
            given will be the fraction of the distance along the string that
            sits at the given point. 0.0 gives left aligned text, 0.5 gives
            centralized text and 1.0 gives right aligned text.

        text (PLCHAR_VECTOR, input) :    A UTF-8 character string to be drawn.

        minx (PLFLT, input) :    The minimum x value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example longitude or
            distance. The value of minx must be less than the value of maxx.

        maxx (PLFLT, input) :    The maximum x value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        miny (PLFLT, input) :    The minimum y value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example latitude or
            distance. The value of miny must be less than the value of maxy.

        maxy (PLFLT, input) :    The maximum y value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        plotentry (PLINT, input) :    An integer indicating which text string
            of the Shapefile (zero indexed) will be drawn.

    """
    return _plplotc.plmaptex(mapform, type, dx, dy, just, text, minx, maxx, miny, maxy, plotentry)

def plmapfill(mapform, type, minx, maxx, miny, maxy, ArrayNull):
    """
    Plot all or a subset of Shapefile data, filling the polygons

    DESCRIPTION:

        As per plmapline, however the items are filled in the same way as
        plfill.

        Redacted form: plmapfill(mapform, name, minx, maxx, miny, maxy,
        plotentries)

        This function is used in example 19.



    SYNOPSIS:

    plmapfill(mapform, name, minx, maxx, miny, maxy, plotentries, nplotentries)

    ARGUMENTS:

        mapform (PLMAPFORM_callback, input) :    A user supplied function to
            transform the coordinates given in the shapefile into a plot
            coordinate system. By using this transform, we can change from a
            longitude, latitude coordinate to a polar stereographic project,
            for example.  Initially, x[0]..[n-1] are the longitudes and
            y[0]..y[n-1] are the corresponding latitudes.  After the call to
            mapform(), x[] and y[] should be replaced by the corresponding
            plot coordinates. If no transform is desired, mapform can be
            replaced by NULL.

        name (PLCHAR_VECTOR, input) :    An ascii character string specifying
            the file name of a set of Shapefile files without the file
            extension.

        minx (PLFLT, input) :    The minimum x value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example longitude or
            distance. The value of minx must be less than the value of maxx.

        maxx (PLFLT, input) :    The maximum x value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        miny (PLFLT, input) :    The minimum y value to be plotted. This must
            be in the same units as used by the Shapefile. You could use a
            very large negative number to plot everything, but you can improve
            performance by limiting the area drawn. The units must match those
            of the Shapefile projection, which may be for example latitude or
            distance. The value of miny must be less than the value of maxy.

        maxy (PLFLT, input) :    The maximum y value to be plotted. You could
            use a very large number to plot everything, but you can improve
            performance by limiting the area drawn.

        plotentries (PLINT_VECTOR, input) :    A vector containing the
            zero-based indices of the Shapefile elements which will be drawn.
            Setting
        plotentries to NULL will plot all elements of the Shapefile.

        nplotentries (PLINT, input) :    The number of items in
        plotentries. Ignored if
        plotentries is NULL.

    """
    return _plplotc.plmapfill(mapform, type, minx, maxx, miny, maxy, ArrayNull)

def plmeridians(mapform, dlong, dlat, minlong, maxlong, minlat, maxlat):
    """
    Plot latitude and longitude lines

    DESCRIPTION:

        Displays latitude and longitude on the current plot.  The lines are
        plotted in the current color and line style.

        Redacted form: plmeridians(mapform, dlong, dlat, minlong, maxlong,
        minlat, maxlat)

        This function is used in example 19.



    SYNOPSIS:

    plmeridians(mapform, dlong, dlat, minlong, maxlong, minlat, maxlat)

    ARGUMENTS:

        mapform (PLMAPFORM_callback, input) :    A user supplied function to
            transform the coordinate longitudes and latitudes to a plot
            coordinate system. By using this transform, we can change from a
            longitude, latitude coordinate to a polar stereographic project,
            for example.  Initially, x[0]..[n-1] are the longitudes and
            y[0]..y[n-1] are the corresponding latitudes.  After the call to
            mapform(), x[] and y[] should be replaced by the corresponding
            plot coordinates. If no transform is desired, mapform can be
            replaced by NULL.

        dlong (PLFLT, input) :    The interval in degrees at which the
            longitude lines are to be plotted.

        dlat (PLFLT, input) :    The interval in degrees at which the latitude
            lines are to be plotted.

        minlong (PLFLT, input) :    The value of the longitude on the left
            side of the plot. The value of minlong must be less than the value
            of maxlong, and the quantity maxlong-minlong must be less than or
            equal to 360.

        maxlong (PLFLT, input) :    The value of the longitude on the right
            side of the plot.

        minlat (PLFLT, input) :    The minimum latitude to be plotted on the
            background. One can always use -90.0 as the boundary outside the
            plot window will be automatically eliminated.  However, the
            program will be faster if one can reduce the size of the
            background plotted.

        maxlat (PLFLT, input) :    The maximum latitudes to be plotted on the
            background. One can always use 90.0 as the boundary outside the
            plot window will be automatically eliminated.

    """
    return _plplotc.plmeridians(mapform, dlong, dlat, minlong, maxlong, minlat, maxlat)

def plimage(Matrix, xmin, xmax, ymin, ymax, zmin, zmax, Dxmin, Dxmax, Dymin, Dymax):
    """
    Plot a 2D matrix using cmap1 with automatic color adjustment

    DESCRIPTION:

        Plot a 2D matrix using the cmap1 palette.  The color scale is
        automatically adjusted to use the maximum and minimum values in idata
        as valuemin and valuemax in a call to plimagefr.

        Redacted form: General: plimage(idata, xmin, xmax, ymin, ymax, zmin,
        zmax, Dxmin, Dxmax, Dymin, Dymax)


        This function is used in example 20.



    SYNOPSIS:

    plimage(idata, nx, ny, xmin, xmax, ymin, ymax, zmin, zmax, Dxmin, Dxmax, Dymin, Dymax)

    ARGUMENTS:

        idata (PLFLT_MATRIX, input) :    A matrix containing function values
            to plot.  Should have dimensions of
        nx by
        ny.

        nx, ny (PLINT, input) :    Dimensions of idata

        xmin, xmax, ymin, ymax (PLFLT, input) :    The x and y index ranges
            are linearly transformed to these world coordinate ranges such
            that idata[0][0] corresponds to (xmin, ymin) and idata[nx - 1][ny
            - 1] corresponds to (xmax, ymax).

        zmin, zmax (PLFLT, input) :    Only data between zmin and zmax
            (inclusive) will be plotted.

        Dxmin, Dxmax, Dymin, Dymax (PLFLT, input) :    Plot only the window of
            points whose plot coordinates fall inside the window of (Dxmin,
            Dymin) to (Dxmax, Dymax).

    """
    return _plplotc.plimage(Matrix, xmin, xmax, ymin, ymax, zmin, zmax, Dxmin, Dxmax, Dymin, Dymax)

def plimagefr(*args):
    """
    Plot a 2D matrix using cmap1

    DESCRIPTION:

        Plot a 2D matrix using cmap1.

        Redacted form: General: plimagefr(idata, xmin, xmax, ymin, ymax, zmin,
        zmax, valuemin, valuemax, pltr, pltr_data)


        This function is used in example 20.



    SYNOPSIS:

    plimagefr(idata, nx, ny, xmin, xmax, ymin, ymax, zmin, zmax, valuemin, valuemax, pltr, pltr_data)

    ARGUMENTS:

        idata (PLFLT_MATRIX, input) :    A matrix of values (intensities) to
            plot.  Should have dimensions of
        nx by
        ny.

        nx, ny (PLINT, input) :    Dimensions of idata

        xmin, xmax, ymin, ymax (PLFLT, input) :    See the discussion of
        pltr below for how these arguments are used (only for the special case
            when the callback function
        pltr is not supplied).

        zmin, zmax (PLFLT, input) :    Only data between zmin and zmax
            (inclusive) will be plotted.

        valuemin, valuemax (PLFLT, input) :    The minimum and maximum data
            values to use for value to color mappings.  A datum equal to or
            less than valuemin will be plotted with color 0.0, while a datum
            equal to or greater than valuemax will be plotted with color 1.0.
            Data between valuemin and valuemax map linearly to colors in the
            range (0.0-1.0).

        pltr (PLTRANSFORM_callback, input) :    A callback function that
            defines the transformation between the zero-based indices of the
            matrix idata and world coordinates. If
        pltr is not supplied (e.g., is set to NULL in the C case), then the x
            indices of idata are mapped to the range
        xmin through
        xmax and the y indices of idata are mapped to the range
        ymin through
        ymax.For the C case, transformation functions are provided in the
            PLplot library: pltr0 for the identity mapping, and pltr1 and
            pltr2 for arbitrary mappings respectively defined by vectors and
            matrices.  In addition, C callback routines for the transformation
            can be supplied by the user such as the mypltr function in
            examples/c/x09c.c which provides a general linear transformation
            between index coordinates and world coordinates.For languages
            other than C you should consult the PLplot documentation for the
            details concerning how PLTRANSFORM_callback arguments are
            interfaced. However, in general, a particular pattern of
            callback-associated arguments such as a tr vector with 6 elements;
            xg and yg vectors; or xg and yg matrices are respectively
            interfaced to a linear-transformation routine similar to the above
            mypltr function; pltr1; and pltr2. Furthermore, some of our more
            sophisticated bindings (see, e.g., the PLplot documentation)
            support native language callbacks for handling index to
            world-coordinate transformations.  Examples of these various
            approaches are given in examples/<language>x09*,
            examples/<language>x16*, examples/<language>x20*,
            examples/<language>x21*, and examples/<language>x22*, for all our
            supported languages.

        pltr_data (PLPointer, input) :    Extra parameter to help pass
            information to pltr0, pltr1, pltr2, or whatever routine is
            externally supplied.

    """
    return _plplotc.plimagefr(*args)

def plClearOpts():
    return _plplotc.plClearOpts()
plClearOpts = _plplotc.plClearOpts

def plResetOpts():
    return _plplotc.plResetOpts()
plResetOpts = _plplotc.plResetOpts

def plSetUsage(program_string, usage_string):
    return _plplotc.plSetUsage(program_string, usage_string)
plSetUsage = _plplotc.plSetUsage

def plOptUsage():
    return _plplotc.plOptUsage()
plOptUsage = _plplotc.plOptUsage

def plMinMax2dGrid(Matrix):
    return _plplotc.plMinMax2dGrid(Matrix)
plMinMax2dGrid = _plplotc.plMinMax2dGrid

def plGetCursor(gin):
    """
    Wait for graphics input event and translate to world coordinates.

    DESCRIPTION:

        Wait for graphics input event and translate to world coordinates.
        Returns 0 if no translation to world coordinates is possible.

        This function returns 1 on success and 0 if no translation to world
        coordinates is possible.

        Redacted form: plGetCursor(gin)

        This function is used in examples 1 and 20.



    SYNOPSIS:

    PLINT plGetCursor(gin)

    ARGUMENTS:

        gin (PLGraphicsIn *, output) :    Pointer to PLGraphicsIn structure
            which will contain the output. The structure is not allocated by
            the routine and must exist before the function is called.

    """
    return _plplotc.plGetCursor(gin)
# This file is compatible with both classic and new-style classes.