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import sys
#don't do this at home
sys.path.append("..")
from analytics import Swaption, BlackSwaption, Index, VolatilitySurface, Portfolio
from analytics.scenarios import run_swaption_scenarios, run_index_scenarios, run_portfolio_scenarios
from pandas.tseries.offsets import BDay
import datetime
import numpy as np
import pandas as pd
from scipy.interpolate import SmoothBivariateSpline
from matplotlib import cm
from mpl_toolkits.mplot3d import Axes3D
import matplotlib.pyplot as plt
import os
import numpy as np
import matplotlib
import matplotlib.pyplot as plt
from mpl_toolkits.axes_grid1 import AxesGrid
import re
from db import dbengine
engine = dbengine('serenitasdb')
def shiftedColorMap(cmap, start=0, midpoint=0.5, stop=1.0, name='shiftedcmap'):
'''
Function to offset the "center" of a colormap. Useful for
data with a negative min and positive max and you want the
middle of the colormap's dynamic range to be at zero
Input
-----
cmap : The matplotlib colormap to be altered
start : Offset from lowest point in the colormap's range.
Defaults to 0.0 (no lower ofset). Should be between
0.0 and `midpoint`.
midpoint : The new center of the colormap. Defaults to
0.5 (no shift). Should be between 0.0 and 1.0. In
general, this should be 1 - vmax/(vmax + abs(vmin))
For example if your data range from -15.0 to +5.0 and
you want the center of the colormap at 0.0, `midpoint`
should be set to 1 - 5/(5 + 15)) or 0.75
stop : Offset from highets point in the colormap's range.
Defaults to 1.0 (no upper ofset). Should be between
`midpoint` and 1.0.
'''
cdict = {
'red': [],
'green': [],
'blue': [],
'alpha': []
}
# regular index to compute the colors
reg_index = np.linspace(start, stop, 257)
# shifted index to match the data
shift_index = np.hstack([
np.linspace(0.0, midpoint, 128, endpoint=False),
np.linspace(midpoint, 1.0, 129, endpoint=True)
])
for ri, si in zip(reg_index, shift_index):
r, g, b, a = cmap(ri)
cdict['red'].append((si, r, r))
cdict['green'].append((si, g, g))
cdict['blue'].append((si, b, b))
cdict['alpha'].append((si, a, a))
newcmap = matplotlib.colors.LinearSegmentedColormap(name, cdict)
plt.register_cmap(cmap=newcmap)
return newcmap
def plot_df(df, spread_shock, vol_shock, attr="pnl"):
val_date = df.index[0].date()
fig = plt.figure()
ax = fig.gca(projection='3d')
## use smoothing spline on a finer grid
series = df[attr]
f = SmoothBivariateSpline(df.vol_shock.values, df.spread_shock.values, series.values)
xx, yy = np.meshgrid(vol_shock, spread_shock)
surf = ax.plot_surface(xx, yy, f(vol_shock, spread_shock).T, cmap=cm.viridis)
ax.set_xlabel("Volatility shock")
ax.set_ylabel("Spread")
ax.set_zlabel("PnL")
ax.set_title('{} of Trade on {}'.format(attr.title(), val_date))
def plot_color_map(df, spread_shock, vol_shock, attr="pnl", path="."):
val_date = df.index[0].date()
#rows are spread, columns are volatility surface shift
fig, ax = plt.subplots()
#We are plotting an image, so we have to sort from high to low on the Y axis
df.sort_values(by=['spread','vol_shock'], ascending = [True,False], inplace = True)
series = df[attr]
#import pdb; pdb.set_trace()
midpoint = 1 - series.max() / (series.max() + abs(series.min()))
shifted_cmap = shiftedColorMap(cm.RdYlGn, midpoint=midpoint, name='shifted')
chart = ax.imshow(series.values.reshape(spread_shock.size, vol_shock.size).T,
extent=(spread_shock.min(), spread_shock.max(),
vol_shock.min(), vol_shock.max()),
aspect='auto', interpolation='bilinear', cmap=shifted_cmap)
ax.set_xlabel('Spread')
ax.set_ylabel('Volatility shock')
ax.set_title('{} of Trade on {}'.format(attr.title(), val_date))
fig.colorbar(chart, shrink=.8)
#fig.savefig(os.path.join(path, "vol_spread_color_map"+ attr+ "_{}.png".format(val_date)))
def plot_time_color_map(df, spread_shock, attr="pnl", path=".", color_map = cm.RdYlGn):
val_date = df.index[0].date()
df = df.reset_index()
df['days'] = (df['date'] - val_date).dt.days
df.sort_values(by=['date','spread'], ascending = [True,False], inplace = True)
date_range = df.days.unique()
fig, ax = plt.subplots()
series = df[attr]
midpoint = 1 - series.max() / (series.max() + abs(series.min()))
shifted_cmap = shiftedColorMap(color_map, midpoint=midpoint, name='shifted')
chart = ax.imshow(series.values.reshape(date_range.size, spread_shock.size).T,
extent=(date_range.min(), date_range.max(),
spread_shock.min(), spread_shock.max()),
aspect='auto', interpolation='bilinear', cmap=shifted_cmap)
ax.set_xlabel('Days')
ax.set_ylabel('Spread')
ax.set_title('{} of Trade'.format(attr.title()))
fig.colorbar(chart, shrink=.8)
#fig.savefig(os.path.join(path, "spread_time_color_map_"+ attr+ "_{}.png".format(val_date)))
def dec_jan_2017_trade():
option_delta = Index.from_tradeid(864)
option1 = BlackSwaption.from_tradeid(3, option_delta)
option2 = BlackSwaption.from_tradeid(4, option_delta)
portf = Portfolio([option1, option2, option_delta])
date_range = pd.bdate_range(option_delta.trade_date, pd.Timestamp('2017-01-18') - BDay(), freq = '2B')
vol_shock = np.arange(-0.15, 0.3, 0.01)
spread_shock = np.arange(-0.2, 0.3, 0.01)
vs = VolatilitySurface("IG", 27, trade_date=option_delta.trade_date)
vol_select = vs.list('BAML', 'payer', 'black')[-1]
vol_surface = vs[vol_select]
df = run_portfolio_scenarios(portf, date_range, spread_shock, vol_shock,
vol_surface, params=["pnl", "delta"], vol_time_roll=False)
plot_time_color_map(df[round(df.vol_shock,2)==0], option_delta.spread * (1 + spread_shock), 'pnl')
def april_may_2017_trade(what='pnl'):
option_delta = Index.from_tradeid(870)
option1 = BlackSwaption.from_tradeid(5, option_delta)
option2 = BlackSwaption.from_tradeid(6, option_delta)
portf = Portfolio([option1, option2, option_delta])
date_range = pd.bdate_range(option_delta.trade_date, pd.Timestamp('2017-04-19') - BDay(), freq = '2B')
vol_shock = np.arange(-0.15, 0.3, 0.01)
spread_shock = np.arange(-0.2, 0.3, 0.01)
vs = VolatilitySurface("IG", 27, trade_date=option_delta.trade_date)
vol_select = vs.list('BAML', 'payer', 'black')[-1]
vol_surface = vs[vol_select]
df = run_portfolio_scenarios(portf, date_range, spread_shock, vol_shock,
vol_surface, params=[what], vol_time_roll=False)
plot_time_color_map(df[abs(df.vol_shock)<1e-3], option_delta.spread * (1 + spread_shock), what)
def june_july_2017_trade():
option_delta_pf = Index.from_tradeid(874)
option_delta2_pf = Index.from_tradeid(879)
option1_pf = BlackSwaption.from_tradeid(7, option_delta_pf)
option2_pf = BlackSwaption.from_tradeid(9, option_delta_pf)
#option_delta.notional = option_delta.notional - option_delta2.notional
option_delta_pf.notional = 50_335_169
portf = Portfolio([option1_pf, option2_pf, option_delta_pf])
portf.trade_date = datetime.date(2017, 5, 17)
portf.mark()
portf.reset_pv()
date_range = pd.bdate_range(option_delta_pf.trade_date, pd.Timestamp('2017-06-21') - BDay(), freq = '2B')
vol_shock = np.arange(-0.15, 0.3, 0.01)
spread_shock = np.arange(-0.2, 0.3, 0.01)
vs = VolatilitySurface("IG", 28, trade_date=option_delta_pf.trade_date)
vol_select = vs.list('BAML', 'payer', 'black')[-1]
vol_surface = vs[vol_select]
df = run_portfolio_scenarios(portf, date_range, spread_shock, vol_shock, vol_surface,
params=["pnl", "delta"], vol_time_roll=True)
#period = -4
#plot_df(df.loc[date_range[period]], spread_plot_range, vol_shock_range)
#plot_color_map(df.loc[date_range[period]], option_delta.spread * (1 + spread_shock), vol_shock, 'pnl')
plot_time_color_map(df[round(df.vol_shock,2)==0], option_delta_pf.spread * (1 + spread_shock), 'pnl')
#plot_time_color_map(df[round(df.vol_shock,2)==0], ref * (1 + spread_shock), 'delta', color_map = cm.coolwarm_r)
return df
def hy_trade_scenario():
#Manually Load trades
option_delta = Index.from_name('hy', 28, '5yr')
option_delta.price = 107.5
option1 = BlackSwaption(option_delta, datetime.date(2017, 8, 16), 106, option_type="payer")
option2 = BlackSwaption(option_delta, datetime.date(2017, 8, 16), 104, option_type="payer")
option1.sigma = .331
option2.sigma = .388
option1.notional = 20_000_000
option2.notional = 40_000_000
option2.direction = 'Short'
option_delta.notional = -(option1.delta * option1.notional + option2.delta*option2.notional)
if option_delta.notional < 0:
option_delta.direction = 'Seller'
option_delta.notional = abs(option_delta.notional)
portf = Portfolio([option1, option2, option_delta])
portf.reset_pv()
date_range = pd.bdate_range(option_delta.trade_date, pd.Timestamp('2017-08-16') - BDay(), freq = '5B')
vol_shock = np.arange(-0.15, 0.3, 0.01)
spread_shock = np.arange(-0.1, 0.4, 0.01)
vs = VolatilitySurface("HY", 28, trade_date=option_delta.trade_date)
vol_select = vs.list('BAML', 'payer', 'black')[-1]
vol_surface = vs[vol_select]
df = run_portfolio_scenarios(portf, date_range, spread_shock, vol_shock, vol_surface, params=["pnl", "delta"], vol_time_roll=True)
#period = -4
#plot_df(df.loc[date_range[period]], spread_plot_range, vol_shock_range)
#plot_color_map(df.loc[date_range[period]], option_delta.spread * (1 + spread_shock), vol_shock, 'pnl')
#plot_time_color_map(df[round(df.vol_shock,2)==0], option_delta.spread * (1 + spread_shock), 'pnl')
hy_plot_range = 100 + (500- option_delta.spread * (1 + spread_shock))*option_delta.DV01/option_delta.notional*100
plot_time_color_map(df[round(df.vol_shock,2)==0], hy_plot_range, 'pnl')
#Delta in protection terms: Blue = going short, red = going long
#plot_time_color_map(df[round(df.vol_shock,2)==0], option_delta.spread * (1 + spread_shock), 'delta', color_map = cm.coolwarm_r)
return df
def portfolio():
option_delta = Index.from_tradeid(874)
option1 = BlackSwaption.from_tradeid(7, option_delta)
option2 = BlackSwaption.from_tradeid(8, option_delta)
portf = Portfolio([option1, option2, option3, option_delta, option_delta1, option_delta2, option_delta3])
date_range = pd.bdate_range(option_delta.trade_date, pd.Timestamp('2017-05-17') - BDay(), freq = '2B')
vol_shock = np.arange(-0.15, 0.3, 0.01)
spread_shock = np.arange(-0.2, 0.3, 0.01)
vs = VolatilitySurface("IG", 28, trade_date=option_delta.trade_date)
vol_select = vs.list('BAML', 'payer', 'black')[-1]
vol_surface = vs[vol_select]
df = run_portfolio_scenarios(portf, date_range, spread_shock, vol_shock, vol_surface, params=["pnl", "delta"], vol_time_roll=False)
#plot it
period = -4
#plot_df(df.loc[date_range[period]], spread_plot_range, vol_shock_range)
plot_color_map(df.loc[date_range[period]], option_delta.spread * (1 + spread_shock), vol_shock, 'pnl')
plot_time_color_map(df[round(df.vol_shock,2)==0], option_delta.spread * (1 + spread_shock), 'pnl')
plot_time_color_map(df[round(df.vol_shock,2)==0], ref * (1 + spread_shock), 'delta', color_map = cm.coolwarm_r)
def probabilities():
from scipy.stats import lognorm
option_delta = Index.from_tradeid(874)
vs = VolatilitySurface("IG", 28, trade_date=option_delta.trade_date)
vol_select = max([t for t in vs.list() if t[1] == 'BAML' and t[2] == 'payer' and t[3] == 'black'])
vol_surface = vs[vol_select]
t = .1
mon = 1
date_range = pd.bdate_range(option_delta.trade_date, pd.Timestamp('2017-05-17') - BDay(), freq = 'B')
curr_vols = np.maximum(vol_surface.ev(t, mon), 0)
dist = lognorm(curr_vols, scale)
lognorm.ppf(.5, curr_vols, scale = np.exp(64))
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