# Copyright Crown and Cartopy Contributors # # This file is part of Cartopy and is released under the BSD 3-clause license. # See LICENSE in the root of the repository for full licensing details. """Tools for handling tick marks in cartopy.""" import matplotlib as mpl from matplotlib.ticker import Formatter, MaxNLocator import numpy as np import cartopy.crs as ccrs from cartopy.mpl.geoaxes import GeoAxes class _PlateCarreeFormatter(Formatter): """ Base class for formatting ticks on geographical axes using a rectangular projection (e.g. Plate Carree, Mercator). """ def __init__(self, direction_label=True, degree_symbol='°', number_format='g', transform_precision=1e-8, dms=False, minute_symbol='′', second_symbol='″', seconds_number_format='g', auto_hide=True, decimal_point=None, cardinal_labels=None): """ Base class for simpler implementation of specialised formatters for latitude and longitude axes. """ self._direction_labels = direction_label self._degree_symbol = degree_symbol self._degrees_number_format = number_format self._transform_precision = transform_precision self._dms = dms self._minute_symbol = minute_symbol self._second_symbol = second_symbol self._seconds_num_format = seconds_number_format self._auto_hide = auto_hide self._auto_hide_degrees = False self._auto_hide_minutes = False self._precision = 5 # locator precision if (decimal_point is None and mpl.rcParams['axes.formatter.use_locale']): import locale decimal_point = locale.localeconv()["decimal_point"] if cardinal_labels is None: cardinal_labels = {} self._cardinal_labels = cardinal_labels self._decimal_point = decimal_point self._source_projection = None self._target_projection = None def __call__(self, value, pos=None): if self._source_projection is not None: projected_value = self._apply_transform(value, self._target_projection, self._source_projection) # Round the transformed value using a given precision for display # purposes. Transforms can introduce minor rounding errors that # make the tick values look bad, these need to be accounted for. f = 1. / self._transform_precision projected_value = round(f * projected_value) / f else: # There is no projection so we assume it is already PlateCarree projected_value = value # Return the formatted values, the formatter has both the re-projected # tick value and the original axis value available to it. return self._format_value(projected_value, value) def _format_value(self, value, original_value): hemisphere = '' sign = '' if self._direction_labels: hemisphere = self._hemisphere(value, original_value) else: if (value != 0 and self._hemisphere(value, original_value) in ['W', 'S']): sign = '-' if not self._dms: return (sign + self._format_degrees(abs(value)) + hemisphere) value, deg, mn, sec = self._get_dms(abs(value)) # Format label = '' if sec: label = self._format_seconds(sec) if mn or (not self._auto_hide_minutes and label): label = self._format_minutes(mn) + label if not self._auto_hide_degrees or not label: label = sign + self._format_degrees(deg) + label + hemisphere return label def _get_dms(self, x): """Convert to degrees, minutes, seconds Parameters ---------- x: float or array of floats Degrees Return ------ x: degrees rounded to the requested precision degs: degrees mins: minutes secs: seconds """ self._precision = 6 x = np.asarray(x, 'd') degs = np.round(x, self._precision).astype('i') y = (x - degs) * 60 mins = np.round(y, self._precision).astype('i') secs = np.round((y - mins) * 60, self._precision - 3) return x, degs, mins, secs def set_axis(self, axis): super().set_axis(axis) # Set the source and target projections for the formatter # setting them to None if we aren't interacting with a GeoAxes if self.axis is None or not isinstance(self.axis.axes, GeoAxes): self._source_projection = None self._target_projection = None return self._source_projection = self.axis.axes.projection if not isinstance(self._source_projection, (ccrs._RectangularProjection, ccrs.Mercator)): raise TypeError("This formatter cannot be used with " "non-rectangular projections.") # The transforms need to use the same globe self._target_projection = ccrs.PlateCarree(globe=self._source_projection.globe) def set_locs(self, locs): Formatter.set_locs(self, locs) if not self._auto_hide: return self.locs, degs, mins, secs = self._get_dms(self.locs) secs = np.round(secs, self._precision - 3).astype('i') secs0 = secs == 0 mins0 = mins == 0 def auto_hide(valid, values): """Should I switch on auto_hide?""" if not valid.any(): return False if valid.sum() == 1: return True return np.diff(values.compress(valid)).max() == 1 # Potentially hide minutes labels when pure minutes are all displayed self._auto_hide_minutes = auto_hide(secs0, mins) # Potentially hide degrees labels when pure degrees are all displayed self._auto_hide_degrees = auto_hide(secs0 & mins0, degs) def _format_degrees(self, deg): """Format degrees as an integer""" if self._dms: deg = int(deg) number_format = 'd' else: number_format = self._degrees_number_format value = f"{abs(deg):{number_format}}{self._degree_symbol}" if self._decimal_point is not None: value = value.replace(".", self._decimal_point) return value def _format_minutes(self, mn): """Format minutes as an integer""" return f'{int(mn):d}{self._minute_symbol}' def _format_seconds(self, sec): """Format seconds as an float""" return f'{sec:{self._seconds_num_format}}{self._second_symbol}' def _apply_transform(self, value, target_proj, source_crs): """ Given a single value, a target projection and a source CRS, transform the value from the source CRS to the target projection, returning a single value. """ raise NotImplementedError("A subclass must implement this method.") def _hemisphere(self, value, value_source_crs): """ Given both a tick value in the Plate Carree projection and the same value in the source CRS, return a string indicating the hemisphere that the value is in. Must be over-ridden by the derived class. """ raise NotImplementedError("A subclass must implement this method.") class LatitudeFormatter(_PlateCarreeFormatter): """Tick formatter for latitude axes.""" def __init__(self, direction_label=True, degree_symbol='°', number_format='g', transform_precision=1e-8, dms=False, minute_symbol='′', second_symbol='″', seconds_number_format='g', auto_hide=True, decimal_point=None, cardinal_labels=None ): """ Tick formatter for latitudes. When bound to an axis, the axis must be part of an axes defined on a rectangular projection (e.g. Plate Carree, Mercator). Parameters ---------- direction_label: optional If *True* a direction label (N or S) will be drawn next to latitude labels. If *False* then these labels will not be drawn. Defaults to *True* (draw direction labels). degree_symbol: optional The character(s) used to represent the degree symbol in the tick labels. Defaults to '°'. Can be an empty string if no degree symbol is desired. number_format: optional Format string to represent the longitude values when `dms` is set to False. Defaults to 'g'. transform_precision: optional Sets the precision (in degrees) to which transformed tick values are rounded. The default is 1e-7, and should be suitable for most use cases. To control the appearance of tick labels use the *number_format* keyword. dms: bool, optional Whether or not formatting as degrees-minutes-seconds and not as decimal degrees. minute_symbol: str, optional The character(s) used to represent the minute symbol. second_symbol: str, optional The character(s) used to represent the second symbol. seconds_number_format: optional Format string to represent the "seconds" component of the longitude values. Defaults to 'g'. auto_hide: bool, optional Auto-hide degrees or minutes when redundant. decimal_point: bool, optional Decimal point character. If not provided and ``mpl.rcParams['axes.formatter.use_locale'] == True``, the locale decimal point is used. cardinal_labels: dict, optional A dictionary with "south" and/or "north" keys to replace south and north cardinal labels, which defaults to "S" and "N". Note ---- A formatter can only be used for one axis. A new formatter must be created for every axis that needs formatted labels. Examples -------- Label latitudes from -90 to 90 on a Plate Carree projection:: ax = plt.axes(projection=PlateCarree()) ax.set_global() ax.set_yticks([-90, -60, -30, 0, 30, 60, 90], crs=ccrs.PlateCarree()) lat_formatter = LatitudeFormatter() ax.yaxis.set_major_formatter(lat_formatter) Label latitudes from -80 to 80 on a Mercator projection, this time omitting the degree symbol:: ax = plt.axes(projection=Mercator()) ax.set_global() ax.set_yticks([-90, -60, -30, 0, 30, 60, 90], crs=ccrs.PlateCarree()) lat_formatter = LatitudeFormatter(degree_symbol='') ax.yaxis.set_major_formatter(lat_formatter) When not bound to an axis:: lat_formatter = LatitudeFormatter() ticks = [-90, -60, -30, 0, 30, 60, 90] lat_formatter.set_locs(ticks) labels = [lat_formatter(value) for value in ticks] """ super().__init__( direction_label=direction_label, degree_symbol=degree_symbol, number_format=number_format, transform_precision=transform_precision, dms=dms, minute_symbol=minute_symbol, second_symbol=second_symbol, seconds_number_format=seconds_number_format, auto_hide=auto_hide, decimal_point=decimal_point, cardinal_labels=cardinal_labels ) def _apply_transform(self, value, target_proj, source_crs): return target_proj.transform_point(0, value, source_crs)[1] def _hemisphere(self, value, value_source_crs): if value > 0: hemisphere = self._cardinal_labels.get('north', 'N') elif value < 0: hemisphere = self._cardinal_labels.get('south', 'S') else: hemisphere = '' return hemisphere class LongitudeFormatter(_PlateCarreeFormatter): """Tick formatter for a longitude axis.""" def __init__(self, direction_label=True, zero_direction_label=False, dateline_direction_label=False, degree_symbol='°', number_format='g', transform_precision=1e-8, dms=False, minute_symbol='′', second_symbol='″', seconds_number_format='g', auto_hide=True, decimal_point=None, cardinal_labels=None ): """ Create a formatter for longitudes. When bound to an axis, the axis must be part of an axes defined on a rectangular projection (e.g. Plate Carree, Mercator). Parameters ---------- direction_label: optional If *True* a direction label (E or W) will be drawn next to longitude labels. If *False* then these labels will not be drawn. Defaults to *True* (draw direction labels). zero_direction_label: optional If *True* a direction label (E or W) will be drawn next to longitude labels with the value 0. If *False* then these labels will not be drawn. Defaults to *False* (no direction labels). dateline_direction_label: optional If *True* a direction label (E or W) will be drawn next to longitude labels with the value 180. If *False* then these labels will not be drawn. Defaults to *False* (no direction labels). degree_symbol: optional The symbol used to represent degrees. Defaults to '°'. number_format: optional Format string to represent the latitude values when `dms` is set to False. Defaults to 'g'. transform_precision: optional Sets the precision (in degrees) to which transformed tick values are rounded. The default is 1e-7, and should be suitable for most use cases. To control the appearance of tick labels use the *number_format* keyword. dms: bool, optional Whether or not formatting as degrees-minutes-seconds and not as decimal degrees. minute_symbol: str, optional The character(s) used to represent the minute symbol. second_symbol: str, optional The character(s) used to represent the second symbol. seconds_number_format: optional Format string to represent the "seconds" component of the latitude values. Defaults to 'g'. auto_hide: bool, optional Auto-hide degrees or minutes when redundant. decimal_point: bool, optional Decimal point character. If not provided and ``mpl.rcParams['axes.formatter.use_locale'] == True``, the locale decimal point is used. cardinal_labels: dict, optional A dictionary with "west" and/or "east" keys to replace west and east cardinal labels, which defaults to "W" and "E". Note ---- A formatter can only be used for one axis. A new formatter must be created for every axis that needs formatted labels. Examples -------- Label longitudes from -180 to 180 on a Plate Carree projection with a central longitude of 0:: ax = plt.axes(projection=PlateCarree()) ax.set_global() ax.set_xticks([-180, -120, -60, 0, 60, 120, 180], crs=ccrs.PlateCarree()) lon_formatter = LongitudeFormatter() ax.xaxis.set_major_formatter(lon_formatter) Label longitudes from 0 to 360 on a Plate Carree projection with a central longitude of 180:: ax = plt.axes(projection=PlateCarree(central_longitude=180)) ax.set_global() ax.set_xticks([0, 60, 120, 180, 240, 300, 360], crs=ccrs.PlateCarree()) lon_formatter = LongitudeFormatter() ax.xaxis.set_major_formatter(lon_formatter) When not bound to an axis:: lon_formatter = LongitudeFormatter() ticks = [0, 60, 120, 180, 240, 300, 360] lon_formatter.set_locs(ticks) labels = [lon_formatter(value) for value in ticks] """ super().__init__( direction_label=direction_label, degree_symbol=degree_symbol, number_format=number_format, transform_precision=transform_precision, dms=dms, minute_symbol=minute_symbol, second_symbol=second_symbol, seconds_number_format=seconds_number_format, auto_hide=auto_hide, decimal_point=decimal_point, cardinal_labels=cardinal_labels ) self._zero_direction_labels = zero_direction_label self._dateline_direction_labels = dateline_direction_label def _apply_transform(self, value, target_proj, source_crs): return target_proj.transform_point(value, 0, source_crs)[0] @classmethod def _fix_lons(cls, lons): if isinstance(lons, list): return [cls._fix_lons(lon) for lon in lons] p180 = lons == 180 m180 = lons == -180 # Wrap lons = ((lons + 180) % 360) - 180 # Keep -180 and 180 when requested for mp180, value in [(m180, -180), (p180, 180)]: if np.any(mp180): if isinstance(lons, np.ndarray): lons = np.where(mp180, value, lons) else: lons = value return lons def set_locs(self, locs): _PlateCarreeFormatter.set_locs(self, self._fix_lons(locs)) def _format_degrees(self, deg): return _PlateCarreeFormatter._format_degrees(self, self._fix_lons(deg)) def _hemisphere(self, value, value_source_crs): value = self._fix_lons(value) # Perform basic hemisphere detection. if value < 0: hemisphere = self._cardinal_labels.get('west', 'W') elif value > 0: hemisphere = self._cardinal_labels.get('east', 'E') else: hemisphere = '' # Correct for user preferences: if value == 0 and self._zero_direction_labels: # Use the original tick value to determine the hemisphere. if value_source_crs < 0: hemisphere = self._cardinal_labels.get('east', 'E') else: hemisphere = self._cardinal_labels.get('west', 'W') if value in (-180, 180) and not self._dateline_direction_labels: hemisphere = '' return hemisphere class LongitudeLocator(MaxNLocator): """ A locator for longitudes that works even at very small scale. Parameters ---------- dms: bool Allow the locator to stop on minutes and seconds (False by default) """ def __init__(self, nbins=8, *, dms=False, **kwargs): super().__init__(nbins=nbins, dms=dms, **kwargs) def set_params(self, **kwargs): """Set parameters within this locator.""" if 'dms' in kwargs: self._dms = kwargs.pop('dms') MaxNLocator.set_params(self, **kwargs) def _guess_steps(self, vmin, vmax): dv = abs(vmax - vmin) if dv > 180: dv -= 180 if dv > 50.: steps = np.array([1, 2, 3, 6, 10]) elif not self._dms or dv > 3.: steps = np.array([1, 1.5, 2, 2.5, 3, 5, 10]) else: steps = np.array([1, 10 / 6., 15 / 6., 20 / 6., 30 / 6., 10]) self.set_params(steps=np.array(steps)) def _raw_ticks(self, vmin, vmax): self._guess_steps(vmin, vmax) return MaxNLocator._raw_ticks(self, vmin, vmax) def bin_boundaries(self, vmin, vmax): self._guess_steps(vmin, vmax) return MaxNLocator.bin_boundaries(self, vmin, vmax) class LatitudeLocator(LongitudeLocator): """ A locator for latitudes that works even at very small scale. Parameters ---------- dms: bool Allow the locator to stop on minutes and seconds (False by default) """ def tick_values(self, vmin, vmax): vmin = max(vmin, -90.) vmax = min(vmax, 90.) return LongitudeLocator.tick_values(self, vmin, vmax) def _guess_steps(self, vmin, vmax): vmin = max(vmin, -90.) vmax = min(vmax, 90.) LongitudeLocator._guess_steps(self, vmin, vmax) def _raw_ticks(self, vmin, vmax): ticks = LongitudeLocator._raw_ticks(self, vmin, vmax) return [t for t in ticks if -90 <= t <= 90] def bin_boundaries(self, vmin, vmax): ticks = LongitudeLocator.bin_boundaries(self, vmin, vmax) return [t for t in ticks if -90 <= t <= 90]