def _plotly_color_map(names: List[str]) -> Mapping[str, str]: """ Private plot helper method for generating colors for similar groups across subplots. Parameters ---------- names: List of levels in a group. Returns ------- Dictionary assigning group names to a color. """ if len(names) > 1: linear_purple_scale = n_colors(lowcolor='rgb(218,183,193)', highcolor='rgb(64,19,98)', n_colors=len(names), colortype='rgb') hex_scale = [ rgb_to_hex(*unlabel_rgb(rgb)) for rgb in linear_purple_scale ] # From https://github.com/plotly/plotly.py/issues/1026 color_generator = cycle(hex_scale) return dict(zip(names, color_generator)) else: return dict(zip(names, ['rgb(64,19,98)']))
def to_rgb_tuple(color): from plotly.colors import unlabel_rgb if isinstance(color, tuple): pass elif color.startswith("#"): color = hex_to_rgb(color) else: color = unlabel_rgb(color) return tuple(int(c) for c in color)
def add_alpha_channel(rgb_color: str, alpha: float) -> str: """ Add an alpha channel to a rgb color string. Test: >>> add_alpha_channel("rgb(0.0 ,0.0 ,0.0)", 0.0) 'rgba(0.0, 0.0, 0.0, 0.0)' >>> add_alpha_channel("rgb(0.0 ,0.0 ,0.0)", 0.7) 'rgba(0.0, 0.0, 0.0, 0.7)' """ red, green, blue = colors.unlabel_rgb(rgb_color) return f"rgba({red}, {green}, {blue}, {alpha})"
def plotly_color_map(names): """ Private plot helper method for generating colors for similar groups across subplots. Parameters ---------- names: List of levels in a group. Returns ------- Dictionary assigning group names to a color. """ if len(names) > 1: d3_category_20 = [ "#1f77b4", "#aec7e8", "#ff7f0e", "#ffbb78", "#2ca02c", "#98df8a", "#d62728", "#ff9896", "#9467bd", "#c5b0d5", "#8c564b", "#c49c94", "#e377c2", "#f7b6d2", "#7f7f7f", "#c7c7c7", "#bcbd22", "#dbdb8d", "#17becf", "#9edae5" ] color_generator = cycle(d3_category_20) return dict(zip(names, color_generator)) else: return dict(zip(names, [rgb_to_hex(*unlabel_rgb('rgb(64,19,98)'))]))
def create_choropleth(fips, values, scope=["usa"], binning_endpoints=None, colorscale=None, order=None, simplify_county=0.02, simplify_state=0.02, asp=None, show_hover=True, show_state_data=True, state_outline=None, county_outline=None, centroid_marker=None, round_legend_values=False, exponent_format=False, legend_title="", **layout_options): """ Returns figure for county choropleth. Uses data from package_data. :param (list) fips: list of FIPS values which correspond to the con catination of state and county ids. An example is '01001'. :param (list) values: list of numbers/strings which correspond to the fips list. These are the values that will determine how the counties are colored. :param (list) scope: list of states and/or states abbreviations. Fits all states in the camera tightly. Selecting ['usa'] is the equivalent of appending all 50 states into your scope list. Selecting only 'usa' does not include 'Alaska', 'Puerto Rico', 'American Samoa', 'Commonwealth of the Northern Mariana Islands', 'Guam', 'United States Virgin Islands'. These must be added manually to the list. Default = ['usa'] :param (list) binning_endpoints: ascending numbers which implicitly define real number intervals which are used as bins. The colorscale used must have the same number of colors as the number of bins and this will result in a categorical colormap. :param (list) colorscale: a list of colors with length equal to the number of categories of colors. The length must match either all unique numbers in the 'values' list or if endpoints is being used, the number of categories created by the endpoints.\n For example, if binning_endpoints = [4, 6, 8], then there are 4 bins: [-inf, 4), [4, 6), [6, 8), [8, inf) :param (list) order: a list of the unique categories (numbers/bins) in any desired order. This is helpful if you want to order string values to a chosen colorscale. :param (float) simplify_county: determines the simplification factor for the counties. The larger the number, the fewer vertices and edges each polygon has. See http://toblerity.org/shapely/manual.html#object.simplify for more information. Default = 0.02 :param (float) simplify_state: simplifies the state outline polygon. See http://toblerity.org/shapely/manual.html#object.simplify for more information. Default = 0.02 :param (float) asp: the width-to-height aspect ratio for the camera. Default = 2.5 :param (bool) show_hover: show county hover and centroid info :param (bool) show_state_data: reveals state boundary lines :param (dict) state_outline: dict of attributes of the state outline including width and color. See https://plot.ly/python/reference/#scatter-marker-line for all valid params :param (dict) county_outline: dict of attributes of the county outline including width and color. See https://plot.ly/python/reference/#scatter-marker-line for all valid params :param (dict) centroid_marker: dict of attributes of the centroid marker. The centroid markers are invisible by default and appear visible on selection. See https://plot.ly/python/reference/#scatter-marker for all valid params :param (bool) round_legend_values: automatically round the numbers that appear in the legend to the nearest integer. Default = False :param (bool) exponent_format: if set to True, puts numbers in the K, M, B number format. For example 4000.0 becomes 4.0K Default = False :param (str) legend_title: title that appears above the legend :param **layout_options: a **kwargs argument for all layout parameters Example 1: Florida ``` import plotly.plotly as py import plotly.figure_factory as ff import numpy as np import pandas as pd df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/minoritymajority.csv' ) df_sample_r = df_sample[df_sample['STNAME'] == 'Florida'] values = df_sample_r['TOT_POP'].tolist() fips = df_sample_r['FIPS'].tolist() binning_endpoints = list(np.mgrid[min(values):max(values):4j]) colorscale = ["#030512","#1d1d3b","#323268","#3d4b94","#3e6ab0", "#4989bc","#60a7c7","#85c5d3","#b7e0e4","#eafcfd"] fig = ff.create_choropleth( fips=fips, values=values, scope=['Florida'], show_state_data=True, colorscale=colorscale, binning_endpoints=binning_endpoints, round_legend_values=True, plot_bgcolor='rgb(229,229,229)', paper_bgcolor='rgb(229,229,229)', legend_title='Florida Population', county_outline={'color': 'rgb(255,255,255)', 'width': 0.5}, exponent_format=True, ) py.iplot(fig, filename='choropleth_florida') ``` Example 2: New England ``` import plotly.plotly as py import plotly.figure_factory as ff import pandas as pd NE_states = ['Connecticut', 'Maine', 'Massachusetts', 'New Hampshire', 'Rhode Island'] df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/minoritymajority.csv' ) df_sample_r = df_sample[df_sample['STNAME'].isin(NE_states)] colorscale = ['rgb(68.0, 1.0, 84.0)', 'rgb(66.0, 64.0, 134.0)', 'rgb(38.0, 130.0, 142.0)', 'rgb(63.0, 188.0, 115.0)', 'rgb(216.0, 226.0, 25.0)'] values = df_sample_r['TOT_POP'].tolist() fips = df_sample_r['FIPS'].tolist() fig = ff.create_choropleth( fips=fips, values=values, scope=NE_states, show_state_data=True ) py.iplot(fig, filename='choropleth_new_england') ``` Example 3: California and Surrounding States ``` import plotly.plotly as py import plotly.figure_factory as ff import pandas as pd df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/minoritymajority.csv' ) df_sample_r = df_sample[df_sample['STNAME'] == 'California'] values = df_sample_r['TOT_POP'].tolist() fips = df_sample_r['FIPS'].tolist() colorscale = [ 'rgb(193, 193, 193)', 'rgb(239,239,239)', 'rgb(195, 196, 222)', 'rgb(144,148,194)', 'rgb(101,104,168)', 'rgb(65, 53, 132)' ] fig = ff.create_choropleth( fips=fips, values=values, colorscale=colorscale, scope=['CA', 'AZ', 'Nevada', 'Oregon', ' Idaho'], binning_endpoints=[14348, 63983, 134827, 426762, 2081313], county_outline={'color': 'rgb(255,255,255)', 'width': 0.5}, legend_title='California Counties', title='California and Nearby States' ) py.iplot(fig, filename='choropleth_california_and_surr_states_outlines') ``` Example 4: USA ``` import plotly.plotly as py import plotly.figure_factory as ff import numpy as np import pandas as pd df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/laucnty16.csv' ) df_sample['State FIPS Code'] = df_sample['State FIPS Code'].apply( lambda x: str(x).zfill(2) ) df_sample['County FIPS Code'] = df_sample['County FIPS Code'].apply( lambda x: str(x).zfill(3) ) df_sample['FIPS'] = ( df_sample['State FIPS Code'] + df_sample['County FIPS Code'] ) binning_endpoints = list(np.linspace(1, 12, len(colorscale) - 1)) colorscale = ["#f7fbff", "#ebf3fb", "#deebf7", "#d2e3f3", "#c6dbef", "#b3d2e9", "#9ecae1", "#85bcdb", "#6baed6", "#57a0ce", "#4292c6", "#3082be", "#2171b5", "#1361a9", "#08519c", "#0b4083","#08306b"] fips = df_sample['FIPS'] values = df_sample['Unemployment Rate (%)'] fig = ff.create_choropleth( fips=fips, values=values, scope=['usa'], binning_endpoints=binning_endpoints, colorscale=colorscale, show_hover=True, centroid_marker={'opacity': 0}, asp=2.9, title='USA by Unemployment %', legend_title='Unemployment %' ) py.iplot(fig, filename='choropleth_full_usa') ``` """ # ensure optional modules imported if not _plotly_geo: raise ValueError(""" The create_choropleth figure factory requires the plotly-geo package. Install using pip with: $ pip install plotly-geo Or, install using conda with $ conda install -c plotly plotly-geo """) if not gp or not shapefile or not shapely: raise ImportError( "geopandas, pyshp and shapely must be installed for this figure " "factory.\n\nRun the following commands to install the correct " "versions of the following modules:\n\n" "```\n" "$ pip install geopandas==0.3.0\n" "$ pip install pyshp==1.2.10\n" "$ pip install shapely==1.6.3\n" "```\n" "If you are using Windows, follow this post to properly " "install geopandas and dependencies:" "http://geoffboeing.com/2014/09/using-geopandas-windows/\n\n" "If you are using Anaconda, do not use PIP to install the " "packages above. Instead use conda to install them:\n\n" "```\n" "$ conda install plotly\n" "$ conda install geopandas\n" "```") df, df_state = _create_us_counties_df(st_to_state_name_dict, state_to_st_dict) fips_polygon_map = dict(zip(df["FIPS"].tolist(), df["geometry"].tolist())) if not state_outline: state_outline = {"color": "rgb(240, 240, 240)", "width": 1} if not county_outline: county_outline = {"color": "rgb(0, 0, 0)", "width": 0} if not centroid_marker: centroid_marker = {"size": 3, "color": "white", "opacity": 1} # ensure centroid markers appear on selection if "opacity" not in centroid_marker: centroid_marker.update({"opacity": 1}) if len(fips) != len(values): raise PlotlyError("fips and values must be the same length") # make fips, values into lists if isinstance(fips, pd.core.series.Series): fips = fips.tolist() if isinstance(values, pd.core.series.Series): values = values.tolist() # make fips numeric fips = map(lambda x: int(x), fips) if binning_endpoints: intervals = utils.endpts_to_intervals(binning_endpoints) LEVELS = _intervals_as_labels(intervals, round_legend_values, exponent_format) else: if not order: LEVELS = sorted(list(set(values))) else: # check if order is permutation # of unique color col values same_sets = sorted(list(set(values))) == set(order) no_duplicates = not any(order.count(x) > 1 for x in order) if same_sets and no_duplicates: LEVELS = order else: raise PlotlyError( "if you are using a custom order of unique values from " "your color column, you must: have all the unique values " "in your order and have no duplicate items") if not colorscale: colorscale = [] viridis_colors = clrs.colorscale_to_colors( clrs.PLOTLY_SCALES["Viridis"]) viridis_colors = clrs.color_parser(viridis_colors, clrs.hex_to_rgb) viridis_colors = clrs.color_parser(viridis_colors, clrs.label_rgb) viri_len = len(viridis_colors) + 1 viri_intervals = utils.endpts_to_intervals( list(np.linspace(0, 1, viri_len)))[1:-1] for L in np.linspace(0, 1, len(LEVELS)): for idx, inter in enumerate(viri_intervals): if L == 0: break elif inter[0] < L <= inter[1]: break intermed = (L - viri_intervals[idx][0]) / (viri_intervals[idx][1] - viri_intervals[idx][0]) float_color = clrs.find_intermediate_color(viridis_colors[idx], viridis_colors[idx], intermed, colortype="rgb") # make R,G,B into int values float_color = clrs.unlabel_rgb(float_color) float_color = clrs.unconvert_from_RGB_255(float_color) int_rgb = clrs.convert_to_RGB_255(float_color) int_rgb = clrs.label_rgb(int_rgb) colorscale.append(int_rgb) if len(colorscale) < len(LEVELS): raise PlotlyError( "You have {} LEVELS. Your number of colors in 'colorscale' must " "be at least the number of LEVELS: {}. If you are " "using 'binning_endpoints' then 'colorscale' must have at " "least len(binning_endpoints) + 2 colors".format( len(LEVELS), min(LEVELS, LEVELS[:20]))) color_lookup = dict(zip(LEVELS, colorscale)) x_traces = dict(zip(LEVELS, [[] for i in range(len(LEVELS))])) y_traces = dict(zip(LEVELS, [[] for i in range(len(LEVELS))])) # scope if isinstance(scope, str): raise PlotlyError("'scope' must be a list/tuple/sequence") scope_names = [] extra_states = [ "Alaska", "Commonwealth of the Northern Mariana Islands", "Puerto Rico", "Guam", "United States Virgin Islands", "American Samoa", ] for state in scope: if state.lower() == "usa": scope_names = df["STATE_NAME"].unique() scope_names = list(scope_names) for ex_st in extra_states: try: scope_names.remove(ex_st) except ValueError: pass else: if state in st_to_state_name_dict.keys(): state = st_to_state_name_dict[state] scope_names.append(state) df_state = df_state[df_state["STATE_NAME"].isin(scope_names)] plot_data = [] x_centroids = [] y_centroids = [] centroid_text = [] fips_not_in_shapefile = [] if not binning_endpoints: for index, f in enumerate(fips): level = values[index] try: fips_polygon_map[f].type ( x_traces, y_traces, x_centroids, y_centroids, centroid_text, ) = _calculations( df, fips, values, index, f, simplify_county, level, x_centroids, y_centroids, centroid_text, x_traces, y_traces, fips_polygon_map, ) except KeyError: fips_not_in_shapefile.append(f) else: for index, f in enumerate(fips): for j, inter in enumerate(intervals): if inter[0] < values[index] <= inter[1]: break level = LEVELS[j] try: fips_polygon_map[f].type ( x_traces, y_traces, x_centroids, y_centroids, centroid_text, ) = _calculations( df, fips, values, index, f, simplify_county, level, x_centroids, y_centroids, centroid_text, x_traces, y_traces, fips_polygon_map, ) except KeyError: fips_not_in_shapefile.append(f) if len(fips_not_in_shapefile) > 0: msg = ("Unrecognized FIPS Values\n\nWhoops! It looks like you are " "trying to pass at least one FIPS value that is not in " "our shapefile of FIPS and data for the counties. Your " "choropleth will still show up but these counties cannot " "be shown.\nUnrecognized FIPS are: {}".format( fips_not_in_shapefile)) warnings.warn(msg) x_states = [] y_states = [] for index, row in df_state.iterrows(): if df_state["geometry"][index].type == "Polygon": x = row.geometry.simplify(simplify_state).exterior.xy[0].tolist() y = row.geometry.simplify(simplify_state).exterior.xy[1].tolist() x_states = x_states + x y_states = y_states + y elif df_state["geometry"][index].type == "MultiPolygon": x = [ poly.simplify(simplify_state).exterior.xy[0].tolist() for poly in df_state["geometry"][index] ] y = [ poly.simplify(simplify_state).exterior.xy[1].tolist() for poly in df_state["geometry"][index] ] for segment in range(len(x)): x_states = x_states + x[segment] y_states = y_states + y[segment] x_states.append(np.nan) y_states.append(np.nan) x_states.append(np.nan) y_states.append(np.nan) for lev in LEVELS: county_data = dict( type="scatter", mode="lines", x=x_traces[lev], y=y_traces[lev], line=county_outline, fill="toself", fillcolor=color_lookup[lev], name=lev, hoverinfo="none", ) plot_data.append(county_data) if show_hover: hover_points = dict( type="scatter", showlegend=False, legendgroup="centroids", x=x_centroids, y=y_centroids, text=centroid_text, name="US Counties", mode="markers", marker={ "color": "white", "opacity": 0 }, hoverinfo="text", ) centroids_on_select = dict( selected=dict(marker=centroid_marker), unselected=dict(marker=dict(opacity=0)), ) hover_points.update(centroids_on_select) plot_data.append(hover_points) if show_state_data: state_data = dict( type="scatter", legendgroup="States", line=state_outline, x=x_states, y=y_states, hoverinfo="text", showlegend=False, mode="lines", ) plot_data.append(state_data) DEFAULT_LAYOUT = dict( hovermode="closest", xaxis=dict( autorange=False, range=USA_XRANGE, showgrid=False, zeroline=False, fixedrange=True, showticklabels=False, ), yaxis=dict( autorange=False, range=USA_YRANGE, showgrid=False, zeroline=False, fixedrange=True, showticklabels=False, ), margin=dict(t=40, b=20, r=20, l=20), width=900, height=450, dragmode="select", legend=dict(traceorder="reversed", xanchor="right", yanchor="top", x=1, y=1), annotations=[], ) fig = dict(data=plot_data, layout=DEFAULT_LAYOUT) fig["layout"].update(layout_options) fig["layout"]["annotations"].append( dict( x=1, y=1.05, xref="paper", yref="paper", xanchor="right", showarrow=False, text="<b>" + legend_title + "</b>", )) if len(scope) == 1 and scope[0].lower() == "usa": xaxis_range_low = -125.0 xaxis_range_high = -55.0 yaxis_range_low = 25.0 yaxis_range_high = 49.0 else: xaxis_range_low = float("inf") xaxis_range_high = float("-inf") yaxis_range_low = float("inf") yaxis_range_high = float("-inf") for trace in fig["data"]: if all(isinstance(n, Number) for n in trace["x"]): calc_x_min = min(trace["x"] or [float("inf")]) calc_x_max = max(trace["x"] or [float("-inf")]) if calc_x_min < xaxis_range_low: xaxis_range_low = calc_x_min if calc_x_max > xaxis_range_high: xaxis_range_high = calc_x_max if all(isinstance(n, Number) for n in trace["y"]): calc_y_min = min(trace["y"] or [float("inf")]) calc_y_max = max(trace["y"] or [float("-inf")]) if calc_y_min < yaxis_range_low: yaxis_range_low = calc_y_min if calc_y_max > yaxis_range_high: yaxis_range_high = calc_y_max # camera zoom fig["layout"]["xaxis"]["range"] = [xaxis_range_low, xaxis_range_high] fig["layout"]["yaxis"]["range"] = [yaxis_range_low, yaxis_range_high] # aspect ratio if asp is None: usa_x_range = USA_XRANGE[1] - USA_XRANGE[0] usa_y_range = USA_YRANGE[1] - USA_YRANGE[0] asp = usa_x_range / usa_y_range # based on your figure width = float(fig["layout"]["xaxis"]["range"][1] - fig["layout"]["xaxis"]["range"][0]) height = float(fig["layout"]["yaxis"]["range"][1] - fig["layout"]["yaxis"]["range"][0]) center = ( sum(fig["layout"]["xaxis"]["range"]) / 2.0, sum(fig["layout"]["yaxis"]["range"]) / 2.0, ) if height / width > (1 / asp): new_width = asp * height fig["layout"]["xaxis"]["range"][0] = center[0] - new_width * 0.5 fig["layout"]["xaxis"]["range"][1] = center[0] + new_width * 0.5 else: new_height = (1 / asp) * width fig["layout"]["yaxis"]["range"][0] = center[1] - new_height * 0.5 fig["layout"]["yaxis"]["range"][1] = center[1] + new_height * 0.5 return go.Figure(fig)
def unlabel_rgbs(cmap): from plotly import colors return [colors.unlabel_rgb(c) for c in cmap]
def create_choropleth(fips, values, scope=['usa'], binning_endpoints=None, colorscale=None, order=None, simplify_county=0.02, simplify_state=0.02, asp=None, show_hover=True, show_state_data=True, state_outline=None, county_outline=None, centroid_marker=None, round_legend_values=False, exponent_format=False, legend_title='', **layout_options): """ Returns figure for county choropleth. Uses data from package_data. :param (list) fips: list of FIPS values which correspond to the con catination of state and county ids. An example is '01001'. :param (list) values: list of numbers/strings which correspond to the fips list. These are the values that will determine how the counties are colored. :param (list) scope: list of states and/or states abbreviations. Fits all states in the camera tightly. Selecting ['usa'] is the equivalent of appending all 50 states into your scope list. Selecting only 'usa' does not include 'Alaska', 'Puerto Rico', 'American Samoa', 'Commonwealth of the Northern Mariana Islands', 'Guam', 'United States Virgin Islands'. These must be added manually to the list. Default = ['usa'] :param (list) binning_endpoints: ascending numbers which implicitly define real number intervals which are used as bins. The colorscale used must have the same number of colors as the number of bins and this will result in a categorical colormap. :param (list) colorscale: a list of colors with length equal to the number of categories of colors. The length must match either all unique numbers in the 'values' list or if endpoints is being used, the number of categories created by the endpoints.\n For example, if binning_endpoints = [4, 6, 8], then there are 4 bins: [-inf, 4), [4, 6), [6, 8), [8, inf) :param (list) order: a list of the unique categories (numbers/bins) in any desired order. This is helpful if you want to order string values to a chosen colorscale. :param (float) simplify_county: determines the simplification factor for the counties. The larger the number, the fewer vertices and edges each polygon has. See http://toblerity.org/shapely/manual.html#object.simplify for more information. Default = 0.02 :param (float) simplify_state: simplifies the state outline polygon. See http://toblerity.org/shapely/manual.html#object.simplify for more information. Default = 0.02 :param (float) asp: the width-to-height aspect ratio for the camera. Default = 2.5 :param (bool) show_hover: show county hover and centroid info :param (bool) show_state_data: reveals state boundary lines :param (dict) state_outline: dict of attributes of the state outline including width and color. See https://plot.ly/python/reference/#scatter-marker-line for all valid params :param (dict) county_outline: dict of attributes of the county outline including width and color. See https://plot.ly/python/reference/#scatter-marker-line for all valid params :param (dict) centroid_marker: dict of attributes of the centroid marker. The centroid markers are invisible by default and appear visible on selection. See https://plot.ly/python/reference/#scatter-marker for all valid params :param (bool) round_legend_values: automatically round the numbers that appear in the legend to the nearest integer. Default = False :param (bool) exponent_format: if set to True, puts numbers in the K, M, B number format. For example 4000.0 becomes 4.0K Default = False :param (str) legend_title: title that appears above the legend :param **layout_options: a **kwargs argument for all layout parameters Example 1: Florida ``` import plotly.plotly as py import plotly.figure_factory as ff import numpy as np import pandas as pd df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/minoritymajority.csv' ) df_sample_r = df_sample[df_sample['STNAME'] == 'Florida'] values = df_sample_r['TOT_POP'].tolist() fips = df_sample_r['FIPS'].tolist() binning_endpoints = list(np.mgrid[min(values):max(values):4j]) colorscale = ["#030512","#1d1d3b","#323268","#3d4b94","#3e6ab0", "#4989bc","#60a7c7","#85c5d3","#b7e0e4","#eafcfd"] fig = ff.create_choropleth( fips=fips, values=values, scope=['Florida'], show_state_data=True, colorscale=colorscale, binning_endpoints=binning_endpoints, round_legend_values=True, plot_bgcolor='rgb(229,229,229)', paper_bgcolor='rgb(229,229,229)', legend_title='Florida Population', county_outline={'color': 'rgb(255,255,255)', 'width': 0.5}, exponent_format=True, ) py.iplot(fig, filename='choropleth_florida') ``` Example 2: New England ``` import plotly.plotly as py import plotly.figure_factory as ff import pandas as pd NE_states = ['Connecticut', 'Maine', 'Massachusetts', 'New Hampshire', 'Rhode Island'] df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/minoritymajority.csv' ) df_sample_r = df_sample[df_sample['STNAME'].isin(NE_states)] colorscale = ['rgb(68.0, 1.0, 84.0)', 'rgb(66.0, 64.0, 134.0)', 'rgb(38.0, 130.0, 142.0)', 'rgb(63.0, 188.0, 115.0)', 'rgb(216.0, 226.0, 25.0)'] values = df_sample_r['TOT_POP'].tolist() fips = df_sample_r['FIPS'].tolist() fig = ff.create_choropleth( fips=fips, values=values, scope=NE_states, show_state_data=True ) py.iplot(fig, filename='choropleth_new_england') ``` Example 3: California and Surrounding States ``` import plotly.plotly as py import plotly.figure_factory as ff import pandas as pd df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/minoritymajority.csv' ) df_sample_r = df_sample[df_sample['STNAME'] == 'California'] values = df_sample_r['TOT_POP'].tolist() fips = df_sample_r['FIPS'].tolist() colorscale = [ 'rgb(193, 193, 193)', 'rgb(239,239,239)', 'rgb(195, 196, 222)', 'rgb(144,148,194)', 'rgb(101,104,168)', 'rgb(65, 53, 132)' ] fig = ff.create_choropleth( fips=fips, values=values, colorscale=colorscale, scope=['CA', 'AZ', 'Nevada', 'Oregon', ' Idaho'], binning_endpoints=[14348, 63983, 134827, 426762, 2081313], county_outline={'color': 'rgb(255,255,255)', 'width': 0.5}, legend_title='California Counties', title='California and Nearby States' ) py.iplot(fig, filename='choropleth_california_and_surr_states_outlines') ``` Example 4: USA ``` import plotly.plotly as py import plotly.figure_factory as ff import numpy as np import pandas as pd df_sample = pd.read_csv( 'https://raw.githubusercontent.com/plotly/datasets/master/laucnty16.csv' ) df_sample['State FIPS Code'] = df_sample['State FIPS Code'].apply( lambda x: str(x).zfill(2) ) df_sample['County FIPS Code'] = df_sample['County FIPS Code'].apply( lambda x: str(x).zfill(3) ) df_sample['FIPS'] = ( df_sample['State FIPS Code'] + df_sample['County FIPS Code'] ) binning_endpoints = list(np.linspace(1, 12, len(colorscale) - 1)) colorscale = ["#f7fbff", "#ebf3fb", "#deebf7", "#d2e3f3", "#c6dbef", "#b3d2e9", "#9ecae1", "#85bcdb", "#6baed6", "#57a0ce", "#4292c6", "#3082be", "#2171b5", "#1361a9", "#08519c", "#0b4083","#08306b"] fips = df_sample['FIPS'] values = df_sample['Unemployment Rate (%)'] fig = ff.create_choropleth( fips=fips, values=values, scope=['usa'], binning_endpoints=binning_endpoints, colorscale=colorscale, show_hover=True, centroid_marker={'opacity': 0}, asp=2.9, title='USA by Unemployment %', legend_title='Unemployment %' ) py.iplot(fig, filename='choropleth_full_usa') ``` """ # ensure optional modules imported if not gp or not shapefile or not shapely: raise ImportError( "geopandas, pyshp and shapely must be installed for this figure " "factory.\n\nRun the following commands to install the correct " "versions of the following modules:\n\n" "```\n" "pip install geopandas==0.3.0\n" "pip install pyshp==1.2.10\n" "pip install shapely==1.6.3\n" "```\n" "If you are using Windows, follow this post to properly " "install geopandas and dependencies:" "http://geoffboeing.com/2014/09/using-geopandas-windows/\n\n" "If you are using Anaconda, do not use PIP to install the " "packages above. Instead use conda to install them:\n\n" "```\n" "conda install plotly\n" "conda install geopandas\n" "```" ) df, df_state = _create_us_counties_df(st_to_state_name_dict, state_to_st_dict) fips_polygon_map = dict( zip( df['FIPS'].tolist(), df['geometry'].tolist() ) ) if not state_outline: state_outline = {'color': 'rgb(240, 240, 240)', 'width': 1} if not county_outline: county_outline = {'color': 'rgb(0, 0, 0)', 'width': 0} if not centroid_marker: centroid_marker = {'size': 3, 'color': 'white', 'opacity': 1} # ensure centroid markers appear on selection if 'opacity' not in centroid_marker: centroid_marker.update({'opacity': 1}) if len(fips) != len(values): raise PlotlyError( 'fips and values must be the same length' ) # make fips, values into lists if isinstance(fips, pd.core.series.Series): fips = fips.tolist() if isinstance(values, pd.core.series.Series): values = values.tolist() # make fips numeric fips = map(lambda x: int(x), fips) if binning_endpoints: intervals = utils.endpts_to_intervals(binning_endpoints) LEVELS = _intervals_as_labels(intervals, round_legend_values, exponent_format) else: if not order: LEVELS = sorted(list(set(values))) else: # check if order is permutation # of unique color col values same_sets = sorted(list(set(values))) == set(order) no_duplicates = not any(order.count(x) > 1 for x in order) if same_sets and no_duplicates: LEVELS = order else: raise PlotlyError( 'if you are using a custom order of unique values from ' 'your color column, you must: have all the unique values ' 'in your order and have no duplicate items' ) if not colorscale: colorscale = [] viridis_colors = clrs.colorscale_to_colors( clrs.PLOTLY_SCALES['Viridis'] ) viridis_colors = clrs.color_parser( viridis_colors, clrs.hex_to_rgb ) viridis_colors = clrs.color_parser( viridis_colors, clrs.label_rgb ) viri_len = len(viridis_colors) + 1 viri_intervals = utils.endpts_to_intervals( list(np.linspace(0, 1, viri_len)) )[1:-1] for L in np.linspace(0, 1, len(LEVELS)): for idx, inter in enumerate(viri_intervals): if L == 0: break elif inter[0] < L <= inter[1]: break intermed = ((L - viri_intervals[idx][0]) / (viri_intervals[idx][1] - viri_intervals[idx][0])) float_color = clrs.find_intermediate_color( viridis_colors[idx], viridis_colors[idx], intermed, colortype='rgb' ) # make R,G,B into int values float_color = clrs.unlabel_rgb(float_color) float_color = clrs.unconvert_from_RGB_255(float_color) int_rgb = clrs.convert_to_RGB_255(float_color) int_rgb = clrs.label_rgb(int_rgb) colorscale.append(int_rgb) if len(colorscale) < len(LEVELS): raise PlotlyError( "You have {} LEVELS. Your number of colors in 'colorscale' must " "be at least the number of LEVELS: {}. If you are " "using 'binning_endpoints' then 'colorscale' must have at " "least len(binning_endpoints) + 2 colors".format( len(LEVELS), min(LEVELS, LEVELS[:20]) ) ) color_lookup = dict(zip(LEVELS, colorscale)) x_traces = dict(zip(LEVELS, [[] for i in range(len(LEVELS))])) y_traces = dict(zip(LEVELS, [[] for i in range(len(LEVELS))])) # scope if isinstance(scope, str): raise PlotlyError( "'scope' must be a list/tuple/sequence" ) scope_names = [] extra_states = ['Alaska', 'Commonwealth of the Northern Mariana Islands', 'Puerto Rico', 'Guam', 'United States Virgin Islands', 'American Samoa'] for state in scope: if state.lower() == 'usa': scope_names = df['STATE_NAME'].unique() scope_names = list(scope_names) for ex_st in extra_states: try: scope_names.remove(ex_st) except ValueError: pass else: if state in st_to_state_name_dict.keys(): state = st_to_state_name_dict[state] scope_names.append(state) df_state = df_state[df_state['STATE_NAME'].isin(scope_names)] plot_data = [] x_centroids = [] y_centroids = [] centroid_text = [] fips_not_in_shapefile = [] if not binning_endpoints: for index, f in enumerate(fips): level = values[index] try: fips_polygon_map[f].type (x_traces, y_traces, x_centroids, y_centroids, centroid_text) = _calculations( df, fips, values, index, f, simplify_county, level, x_centroids, y_centroids, centroid_text, x_traces, y_traces, fips_polygon_map ) except KeyError: fips_not_in_shapefile.append(f) else: for index, f in enumerate(fips): for j, inter in enumerate(intervals): if inter[0] < values[index] <= inter[1]: break level = LEVELS[j] try: fips_polygon_map[f].type (x_traces, y_traces, x_centroids, y_centroids, centroid_text) = _calculations( df, fips, values, index, f, simplify_county, level, x_centroids, y_centroids, centroid_text, x_traces, y_traces, fips_polygon_map ) except KeyError: fips_not_in_shapefile.append(f) if len(fips_not_in_shapefile) > 0: msg = ( 'Unrecognized FIPS Values\n\nWhoops! It looks like you are ' 'trying to pass at least one FIPS value that is not in ' 'our shapefile of FIPS and data for the counties. Your ' 'choropleth will still show up but these counties cannot ' 'be shown.\nUnrecognized FIPS are: {}'.format( fips_not_in_shapefile ) ) warnings.warn(msg) x_states = [] y_states = [] for index, row in df_state.iterrows(): if df_state['geometry'][index].type == 'Polygon': x = row.geometry.simplify(simplify_state).exterior.xy[0].tolist() y = row.geometry.simplify(simplify_state).exterior.xy[1].tolist() x_states = x_states + x y_states = y_states + y elif df_state['geometry'][index].type == 'MultiPolygon': x = ([poly.simplify(simplify_state).exterior.xy[0].tolist() for poly in df_state['geometry'][index]]) y = ([poly.simplify(simplify_state).exterior.xy[1].tolist() for poly in df_state['geometry'][index]]) for segment in range(len(x)): x_states = x_states + x[segment] y_states = y_states + y[segment] x_states.append(np.nan) y_states.append(np.nan) x_states.append(np.nan) y_states.append(np.nan) for lev in LEVELS: county_data = dict( type='scatter', mode='lines', x=x_traces[lev], y=y_traces[lev], line=county_outline, fill='toself', fillcolor=color_lookup[lev], name=lev, hoverinfo='none', ) plot_data.append(county_data) if show_hover: hover_points = dict( type='scatter', showlegend=False, legendgroup='centroids', x=x_centroids, y=y_centroids, text=centroid_text, name='US Counties', mode='markers', marker={'color': 'white', 'opacity': 0}, hoverinfo='text' ) centroids_on_select = dict( selected=dict(marker=centroid_marker), unselected=dict(marker=dict(opacity=0)) ) hover_points.update(centroids_on_select) plot_data.append(hover_points) if show_state_data: state_data = dict( type='scatter', legendgroup='States', line=state_outline, x=x_states, y=y_states, hoverinfo='text', showlegend=False, mode='lines' ) plot_data.append(state_data) DEFAULT_LAYOUT = dict( hovermode='closest', xaxis=dict( autorange=False, range=USA_XRANGE, showgrid=False, zeroline=False, fixedrange=True, showticklabels=False ), yaxis=dict( autorange=False, range=USA_YRANGE, showgrid=False, zeroline=False, fixedrange=True, showticklabels=False ), margin=dict(t=40, b=20, r=20, l=20), width=900, height=450, dragmode='select', legend=dict( traceorder='reversed', xanchor='right', yanchor='top', x=1, y=1 ), annotations=[] ) fig = dict(data=plot_data, layout=DEFAULT_LAYOUT) fig['layout'].update(layout_options) fig['layout']['annotations'].append( dict( x=1, y=1.05, xref='paper', yref='paper', xanchor='right', showarrow=False, text='<b>' + legend_title + '</b>' ) ) if len(scope) == 1 and scope[0].lower() == 'usa': xaxis_range_low = -125.0 xaxis_range_high = -55.0 yaxis_range_low = 25.0 yaxis_range_high = 49.0 else: xaxis_range_low = float('inf') xaxis_range_high = float('-inf') yaxis_range_low = float('inf') yaxis_range_high = float('-inf') for trace in fig['data']: if all(isinstance(n, Number) for n in trace['x']): calc_x_min = min(trace['x'] or [float('inf')]) calc_x_max = max(trace['x'] or [float('-inf')]) if calc_x_min < xaxis_range_low: xaxis_range_low = calc_x_min if calc_x_max > xaxis_range_high: xaxis_range_high = calc_x_max if all(isinstance(n, Number) for n in trace['y']): calc_y_min = min(trace['y'] or [float('inf')]) calc_y_max = max(trace['y'] or [float('-inf')]) if calc_y_min < yaxis_range_low: yaxis_range_low = calc_y_min if calc_y_max > yaxis_range_high: yaxis_range_high = calc_y_max # camera zoom fig['layout']['xaxis']['range'] = [xaxis_range_low, xaxis_range_high] fig['layout']['yaxis']['range'] = [yaxis_range_low, yaxis_range_high] # aspect ratio if asp is None: usa_x_range = USA_XRANGE[1] - USA_XRANGE[0] usa_y_range = USA_YRANGE[1] - USA_YRANGE[0] asp = usa_x_range / usa_y_range # based on your figure width = float(fig['layout']['xaxis']['range'][1] - fig['layout']['xaxis']['range'][0]) height = float(fig['layout']['yaxis']['range'][1] - fig['layout']['yaxis']['range'][0]) center = (sum(fig['layout']['xaxis']['range']) / 2., sum(fig['layout']['yaxis']['range']) / 2.) if height / width > (1 / asp): new_width = asp * height fig['layout']['xaxis']['range'][0] = center[0] - new_width * 0.5 fig['layout']['xaxis']['range'][1] = center[0] + new_width * 0.5 else: new_height = (1 / asp) * width fig['layout']['yaxis']['range'][0] = center[1] - new_height * 0.5 fig['layout']['yaxis']['range'][1] = center[1] + new_height * 0.5 return fig
def __init__( self, position: Position, foreign_time_window_controller: StartAndDurationController = None, ): super().__init__() self.position = position joint_keys = list(position.spatial_series.keys()) self.joint_colors = [] for (joint, c) in zip(joint_keys, DEFAULT_PLOTLY_COLORS): self.joint_colors.append(c) self.spatial_series = position.spatial_series[joint_keys[0]] if foreign_time_window_controller is None: self.time_window_controller = StartAndDurationController( tmax=get_timeseries_maxt(self.spatial_series), tmin=get_timeseries_mint(self.spatial_series), start=0, duration=5, ) show_time_controller = True else: show_time_controller = False self.time_window_controller = foreign_time_window_controller frame_ind = timeseries_time_to_ind( self.spatial_series, self.time_window_controller.value[0]) self.sample_period = 1 / list( self.position.spatial_series.values())[0].rate self.play = Play( value=0, min=0, max=int(self.time_window_controller.duration.value / self.sample_period), step=1, interval=self.sample_period * 1000, ) joint_colors = [ to_hex(np.array(unlabel_rgb(x)) / 255) for x in DEFAULT_PLOTLY_COLORS ] self.joint_keys = POSITION_KEYS self.joint_colors = [ joint_colors[0], # l_wrist joint_colors[1], # l_elbow joint_colors[2], # l_shoulder joint_colors[9], # neck joint_colors[4], # nose joint_colors[3], # l_ear joint_colors[5], # r_ear joint_colors[4], # nose joint_colors[9], # neck joint_colors[6], # r_shoulder joint_colors[7], # r_elbow joint_colors[8], # r_wrist ] self.skeleton_labels = [ "L_Wrist", "L_Elbow", "L_Shoulder", "Neck", "Nose", "L_Ear", "R_Ear", "Nose", "Neck", "R_Shoulder", "R_Elbow", "R_Wrist", ] self.fig = (go.FigureWidget() ) # animation_duration=int(1/spatial_series.rate*1000) self.plot_skeleton(frame_ind) self.updated_time_range({"new": None}) # Updates list of valid spike times at each change in time range self.time_window_controller.observe(self.updated_time_range) self.play.observe(self.animate_scatter_chart) if show_time_controller: self.children = [self.time_window_controller, self.fig, self.play] else: self.children = [self.fig, self.play]