"""
A collection of modules for collecting, analyzing and plotting
financial data. User contributions welcome!
"""
#from __future__ import division
import sys, os, math, time
from urllib import urlopen
try: import datetime
except ImportError:
raise SystemExit('The finance module requires datetime support (python2.3)')
from matplotlib import verbose
from artist import Artist
from dates import date2num, num2date
from matplotlib.collections import LineCollection, PolyCollection
from matplotlib.colors import colorConverter
from lines import Line2D, TICKLEFT, TICKRIGHT
from patches import Rectangle
from matplotlib.transforms import scale_transform, Value, zero, one, \
scale_sep_transform, blend_xy_sep_transform
from matplotlib.matlab import gca
def quotes_historical_yahoo(ticker, date1, date2):
"""
Get historical data for ticker between date1 and date2. date1 and
date2 are datetime instances
results are a list of
d, open, close, high, low, volume
where d is a floating poing representation of date, as returned by date2num
"""
d1 = (date1.month-1, date1.day, date1.year)
d2 = (date2.month-1, date2.day, date2.year)
urlFmt = 'http://table.finance.yahoo.com/table.csv?a=%d&b=%d&c=%d&d=%d&e=%d&f=%d&s=%s&y=0&g=d&ignore=.csv'
url = urlFmt % (d1[0], d1[1], d1[2],
d2[0], d2[1], d2[2], ticker)
ticker = ticker.upper()
results = []
try:
lines = urlopen(url).readlines()
except IOError, exc:
verbose.report_error('urlopen() failure\n' + url + '\n' + exc.strerror[1])
return None
for line in lines[1:]:
vals = line.split(',')
if len(vals)!=7: continue
datestr = vals[0]
dt = datetime.date(*time.strptime(datestr, '%d-%b-%y')[:3])
d = date2num(dt)
open, high, low, close = [float(val) for val in vals[1:5]]
volume = int(vals[5])
results.append((d, open, close, high, low, volume))
results.reverse()
return results
def plot_day_summary(ax, quotes, ticksize=3,
colorup='k', colordown='r',
):
"""
quotes is a list of (time, open, close, high, low, ...) tuples
Represent the time, open, close, high, low as a vertical line
ranging from low to high. The left tick is the open and the right
tick is the close.
time must be in float date format - see date2num
ax : an Axes instance to plot to
ticksize : open/close tick marker in points
colorup : the color of the lines where close >= open
colordown : the color of the lines where close < open
return value is a list of lines added
"""
lines = []
for q in quotes:
t, open, close, high, low = q[:5]
if close>=open : color = colorup
else : color = colordown
vline = Line2D(
xdata=(t, t), ydata=(low, high),
color=color,
antialiased=False, # no need to antialias vert lines
)
oline = Line2D(
xdata=(t, t), ydata=(open, open),
color=color,
antialiased=False,
marker=TICKLEFT,
markersize=ticksize,
)
cline = Line2D(
xdata=(t, t), ydata=(close, close),
color=color,
antialiased=False,
markersize=ticksize,
marker=TICKRIGHT)
lines.extend((vline, oline, cline))
ax.add_line(vline)
ax.add_line(oline)
ax.add_line(cline)
ax.autoscale_view()
return lines
def candlestick(ax, quotes, width=0.2, colorup='k', colordown='r',
alpha=1.0):
"""
quotes is a list of (time, open, close, high, low, ...) tuples.
As long as the first 5 elements of the tuples are these values,
the tuple can be as long as you want (eg it may store volume).
time must be in float days format - see date2num
Plot the time, open, close, high, low as a vertical line ranging
from low to high. Use a rectangular bar to represent the
open-close span. If close >= open, use colorup to color the bar,
otherwise use colordown
ax : an Axes instance to plot to
width : fraction of a day for the rectangle width
colorup : the color of the rectangle where close >= open
colordown : the color of the rectangle where close < open
alpha : the rectangle alpha level
return value is lines, patches where lines is a list of lines
added and patches is a list of the rectangle patches added
"""
OFFSET = width/2.0
lines = []
patches = []
for q in quotes:
t, open, close, high, low = q[:5]
if close>=open :
color = colorup
lower = open
height = close-open
else :
color = colordown
lower = close
height = open-close
vline = Line2D(
xdata=(t, t), ydata=(low, high),
color='k',
linewidth=0.5,
antialiased=True,
)
rect = Rectangle(
xy = (t-OFFSET, lower),
width = width,
height = height,
facecolor = color,
edgecolor = color,
)
rect.set_alpha(alpha)
lines.append(vline)
patches.append(rect)
ax.add_line(vline)
ax.add_patch(rect)
ax.autoscale_view()
return lines, patches
def plot_day_summary2(ax, opens, closes, highs, lows, ticksize=4,
colorup='k', colordown='r',
):
"""
Represent the time, open, close, high, low as a vertical line
ranging from low to high. The left tick is the open and the right
tick is the close.
ax : an Axes instance to plot to
ticksize : size of open and close ticks in points
colorup : the color of the lines where close >= open
colordown : the color of the lines where close < open
return value is a list of lines added
"""
# note this code assumes if any value open, close, low, high is
# missing they all are missing
rangeSegments = [ ((i, low), (i, high)) for i, low, high in zip(xrange(len(lows)), lows, highs) if low != -1 ]
# the ticks will be from ticksize to 0 in points at the origin and
# we'll translate these to the i, close location
openSegments = [ ((-ticksize, 0), (0, 0)) ]
# the ticks will be from 0 to ticksize in points at the origin and
# we'll translate these to the i, close location
closeSegments = [ ((0, 0), (ticksize, 0)) ]
offsetsOpen = [ (i, open) for i, open in zip(xrange(len(opens)), opens) if open != -1 ]
offsetsClose = [ (i, close) for i, close in zip(xrange(len(closes)), closes) if close != -1 ]
scale = ax.figure.dpi * Value(1/72.0)
tickTransform = scale_transform( scale, zero())
r,g,b = colorConverter.to_rgb(colorup)
colorup = r,g,b,1
r,g,b = colorConverter.to_rgb(colordown)
colordown = r,g,b,1
colord = { True : colorup,
False : colordown,
}
colors = [colord[open>=close] for open, close in zip(opens, closes) if open!=-1 and close !=-1]
assert(len(rangeSegments)==len(offsetsOpen))
assert(len(offsetsOpen)==len(offsetsClose))
assert(len(offsetsClose)==len(colors))
useAA = 0, # use tuple here
lw = 1, # and here
rangeCollection = LineCollection(rangeSegments,
colors = colors,
linewidths = lw,
antialiaseds = useAA,
)
openCollection = LineCollection(openSegments,
colors = colors,
antialiaseds = useAA,
linewidths = lw,
offsets = offsetsOpen,
transOffset = ax.transData,
)
openCollection.set_transform(tickTransform)
closeCollection = LineCollection(closeSegments,
colors = colors,
antialiaseds = useAA,
linewidths = lw,
offsets = offsetsClose,
transOffset = ax.transData,
)
closeCollection.set_transform(tickTransform)
minx, maxx = (0, len(rangeSegments))
miny = min([low for low in lows if low !=-1])
maxy = max([high for high in highs if high != -1])
corners = (minx, miny), (maxx, maxy)
ax.update_datalim(corners)
ax.autoscale_view()
# add these last
ax.add_collection(rangeCollection)
ax.add_collection(openCollection)
ax.add_collection(closeCollection)
return rangeCollection, openCollection, closeCollection
def candlestick2(ax, opens, closes, highs, lows, width=4,
colorup='k', colordown='r',
alpha=0.75,
):
"""
Represent the open, close as a bar line and high low range as a
vertical line.
ax : an Axes instance to plot to
width : the bar width in points
colorup : the color of the lines where close >= open
colordown : the color of the lines where close < open
alpha : bar transparency
return value is lineCollection, barCollection
"""
# note this code assumes if any value open, close, low, high is
# missing they all are missing
right = width/2.0
left = -width/2.0
barVerts = [ ( (left, 0), (left, close-open), (right, close-open), (right, 0) ) for open, close in zip(opens, closes) if open != -1 and close!=-1 ]
rangeSegments = [ ((i, low), (i, high)) for i, low, high in zip(xrange(len(lows)), lows, highs) if low != -1 ]
offsetsBars = [ (i, open) for i,open in zip(xrange(len(opens)), opens) if open != -1 ]
sx = ax.figure.dpi * Value(1/72.0) # scale for points
sy = (ax.bbox.ur().y() - ax.bbox.ll().y()) / (ax.viewLim.ur().y() - ax.viewLim.ll().y())
barTransform = scale_sep_transform(sx,sy)
r,g,b = colorConverter.to_rgb(colorup)
colorup = r,g,b,alpha
r,g,b = colorConverter.to_rgb(colordown)
colordown = r,g,b,alpha
colord = { True : colorup,
False : colordown,
}
colors = [colord[open>=close] for open, close in zip(opens, closes) if open!=-1 and close !=-1]
assert(len(barVerts)==len(rangeSegments))
assert(len(rangeSegments)==len(offsetsBars))
assert(len(offsetsBars)==len(colors))
useAA = 0, # use tuple here
lw = 0.5, # and here
rangeCollection = LineCollection(rangeSegments,
colors = ( (0,0,0,1), ),
linewidths = lw,
antialiaseds = useAA,
)
barCollection = PolyCollection(barVerts,
facecolors = colors,
edgecolors = ( (0,0,0,1), ),
antialiaseds = useAA,
linewidths = lw,
offsets = offsetsBars,
transOffset = ax.transData,
)
barCollection.set_transform(barTransform)
minx, maxx = (0, len(rangeSegments))
miny = min([low for low in lows if low !=-1])
maxy = max([high for high in highs if high != -1])
corners = (minx, miny), (maxx, maxy)
ax.update_datalim(corners)
ax.autoscale_view()
# add these last
ax.add_collection(barCollection)
ax.add_collection(rangeCollection)
return rangeCollection, barCollection
def volume_overlay(ax, opens, closes, volumes,
colorup='k', colordown='r',
width=4, alpha=1.0):
"""
Add a volume overlay to the current axes. The opens and closes
are used to determine the color of the bar. -1 is missing. If a
value is missing on one it must be missing on all
ax : an Axes instance to plot to
width : the bar width in points
colorup : the color of the lines where close >= open
colordown : the color of the lines where close < open
alpha : bar transparency
"""
r,g,b = colorConverter.to_rgb(colorup)
colorup = r,g,b,alpha
r,g,b = colorConverter.to_rgb(colordown)
colordown = r,g,b,alpha
colord = { True : colorup,
False : colordown,
}
colors = [colord[open>=close] for open, close in zip(opens, closes) if open!=-1 and close !=-1]
right = width/2.0
left = -width/2.0
bars = [ ( (left, 0), (left, v), (right, v), (right, 0)) for v in volumes if v != -1 ]
sx = ax.figure.dpi * Value(1/72.0) # scale for points
sy = (ax.bbox.ur().y() - ax.bbox.ll().y()) / (ax.viewLim.ur().y() - ax.viewLim.ll().y())
barTransform = scale_sep_transform(sx,sy)
offsetsBars = [ (i, 0) for i,v in enumerate(volumes) if v != -1 ]
barCollection = PolyCollection(bars,
facecolors = colors,
edgecolors = ( (0,0,0,1), ),
antialiaseds = (0,),
linewidths = (0.5,),
offsets = offsetsBars,
transOffset = ax.transData,
)
barCollection.set_transform(barTransform)
minx, maxx = (0, len(offsetsBars))
miny = 0
maxy = max([v for v in volumes if v!=-1])
corners = (minx, miny), (maxx, maxy)
ax.update_datalim(corners)
ax.autoscale_view()
# add these last
return barCollection
def index_bar(ax, vals,
facecolor='b', edgecolor='l',
width=4, alpha=1.0, ):
"""
Add a bar collection graph with height vals (-1 is missing).
ax : an Axes instance to plot to
width : the bar width in points
alpha : bar transparency
"""
facecolors = (colorConverter.to_rgba(facecolor, alpha),)
edgecolors = (colorConverter.to_rgba(edgecolor, alpha),)
right = width/2.0
left = -width/2.0
bars = [ ( (left, 0), (left, v), (right, v), (right, 0)) for v in vals if v != -1 ]
sx = ax.figure.dpi * Value(1/72.0) # scale for points
sy = (ax.bbox.ur().y() - ax.bbox.ll().y()) / (ax.viewLim.ur().y() - ax.viewLim.ll().y())
barTransform = scale_sep_transform(sx,sy)
offsetsBars = [ (i, 0) for i,v in enumerate(vals) if v != -1 ]
barCollection = PolyCollection(bars,
facecolors = facecolors,
edgecolors = edgecolors,
antialiaseds = (0,),
linewidths = (0.5,),
offsets = offsetsBars,
transOffset = ax.transData,
)
barCollection.set_transform(barTransform)
minx, maxx = (0, len(offsetsBars))
miny = 0
maxy = max([v for v in vals if v!=-1])
corners = (minx, miny), (maxx, maxy)
ax.update_datalim(corners)
ax.autoscale_view()
# add these last
ax.add_collection(barCollection)
return barCollection
