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TA-Lib logota-lib-python

Python wrapper for TA-Lib (http://ta-lib.org/).

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Top Related Projects

Python wrapper for TA-Lib (http://ta-lib.org/).

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Common financial technical indicators implemented in Pandas.

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Technical Analysis Library using Pandas and Numpy

Quick Overview

TA-Lib/ta-lib-python is a Python wrapper for TA-LIB, a popular technical analysis library. It provides a comprehensive set of technical indicators and oscillators for financial market analysis, making it easier for Python developers to perform advanced technical analysis on financial data.

Pros

  • Extensive collection of technical indicators and functions
  • High performance due to C implementation with Python bindings
  • Well-documented and widely used in the financial analysis community
  • Seamless integration with popular data analysis libraries like pandas and numpy

Cons

  • Installation can be challenging on some systems due to C dependencies
  • Limited support for newer Python versions (as of the last update)
  • Steeper learning curve for beginners unfamiliar with technical analysis concepts
  • Some functions may have inconsistent naming conventions

Code Examples

  1. Simple Moving Average (SMA) calculation:
import numpy as np
import talib

close_prices = np.random.random(100)
sma = talib.SMA(close_prices, timeperiod=20)
print(sma)
  1. Relative Strength Index (RSI) calculation:
import numpy as np
import talib

close_prices = np.random.random(100)
rsi = talib.RSI(close_prices, timeperiod=14)
print(rsi)
  1. Bollinger Bands calculation:
import numpy as np
import talib

close_prices = np.random.random(100)
upper, middle, lower = talib.BBANDS(close_prices, timeperiod=20, nbdevup=2, nbdevdn=2, matype=0)
print(f"Upper: {upper}\nMiddle: {middle}\nLower: {lower}")

Getting Started

  1. Install TA-Lib:

    pip install TA-Lib
    
  2. Import the library and use it in your code:

    import talib
    import numpy as np
    
    # Example: Calculate EMA
    data = np.random.random(100)
    ema = talib.EMA(data, timeperiod=30)
    print(ema)
    

Note: On some systems, you may need to install the TA-Lib C library separately before installing the Python wrapper. Refer to the project's documentation for detailed installation instructions specific to your operating system.

Competitor Comparisons

Python wrapper for TA-Lib (http://ta-lib.org/).

Pros of ta-lib-python

  • More actively maintained with recent updates
  • Better documentation and examples
  • Wider range of technical indicators implemented

Cons of ta-lib-python

  • Requires compilation of C extensions, which can be challenging on some systems
  • Slightly more complex installation process
  • May have performance overhead due to Python wrappers around C code

Code Comparison

ta-lib-python:

import talib
import numpy as np

close = np.random.random(100)
output = talib.SMA(close, timeperiod=10)

TA-Lib/ta-lib-python:

from talipp.indicators import SMA
from talipp.ohlcv import OHLCVFactory

ohlcv = OHLCVFactory.from_dict({'close': [1, 2, 3, 4, 5]})
sma = SMA(10)
sma.add_input_value(ohlcv)

The main difference in usage is that ta-lib-python works directly with NumPy arrays, while TA-Lib/ta-lib-python uses custom data structures and a more object-oriented approach. ta-lib-python may be more familiar to users of NumPy and scientific Python libraries, while TA-Lib/ta-lib-python might be more intuitive for those preferring a pure Python implementation.

Technical Analysis Indicators - Pandas TA is an easy to use Python 3 Pandas Extension with 150+ Indicators

Pros of pandas-ta

  • Pure Python implementation, easier to install and maintain
  • Seamless integration with pandas DataFrames
  • More extensive set of technical indicators (130+)

Cons of pandas-ta

  • Generally slower performance compared to ta-lib
  • Less established and potentially less stable
  • Smaller community and fewer resources available

Code Comparison

ta-lib-python:

import talib
import numpy as np

close = np.random.random(100)
output = talib.SMA(close, timeperiod=10)

pandas-ta:

import pandas as pd
import pandas_ta as ta

df = pd.DataFrame(np.random.random(100), columns=['close'])
df.ta.sma(length=10, append=True)

Both libraries offer similar functionality, but pandas-ta integrates more naturally with pandas DataFrames. ta-lib-python uses NumPy arrays and requires separate function calls, while pandas-ta extends pandas functionality directly.

ta-lib-python is a wrapper around the C-based TA-Lib, which generally offers better performance. However, pandas-ta provides a more Pythonic approach and easier integration with existing pandas workflows.

2,127

Common financial technical indicators implemented in Pandas.

Pros of finta

  • Pure Python implementation, no C dependencies
  • Easier installation process
  • More modern codebase with active development

Cons of finta

  • Fewer indicators and functions compared to ta-lib-python
  • Potentially slower performance for complex calculations
  • Less established and widely used in the industry

Code Comparison

ta-lib-python:

import talib
import numpy as np

close_prices = np.random.random(100)
sma = talib.SMA(close_prices, timeperiod=20)

finta:

from finta import TA
import pandas as pd

df = pd.DataFrame({'close': np.random.random(100)})
sma = TA.SMA(df, period=20)

Both libraries provide similar functionality for calculating technical indicators, but ta-lib-python uses NumPy arrays directly, while finta works with Pandas DataFrames. ta-lib-python offers a wider range of functions and is generally faster due to its C implementation. However, finta's pure Python approach makes it easier to install and potentially more accessible for beginners or those who prefer working with Pandas.

4,295

Technical Analysis Library using Pandas and Numpy

Pros of ta

  • Pure Python implementation, easier to install and use
  • More extensive set of technical indicators and utility functions
  • Active development and regular updates

Cons of ta

  • Slower performance compared to ta-lib-python's C-based implementation
  • Less established and potentially less stable than ta-lib-python
  • May have fewer advanced features for professional traders

Code Comparison

ta:

import pandas as pd
from ta import add_all_ta_features

df = pd.DataFrame(your_data)
df = add_all_ta_features(df, open="Open", high="High", low="Low", close="Close", volume="Volume")

ta-lib-python:

import talib
import numpy as np

close_prices = np.array(your_close_prices)
sma = talib.SMA(close_prices, timeperiod=20)
rsi = talib.RSI(close_prices, timeperiod=14)

ta offers a more straightforward approach to adding multiple indicators at once, while ta-lib-python requires individual function calls for each indicator. ta-lib-python's syntax is more concise for single indicator calculations, but may require more setup for data preparation.

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README

TA-Lib

Tests

This is a Python wrapper for TA-LIB based on Cython instead of SWIG. From the homepage:

TA-Lib is widely used by trading software developers requiring to perform technical analysis of financial market data.

  • Includes 150+ indicators such as ADX, MACD, RSI, Stochastic, Bollinger Bands, etc.
  • Candlestick pattern recognition
  • Open-source API for C/C++, Java, Perl, Python and 100% Managed .NET

The original Python bindings included with TA-Lib use SWIG which unfortunately are difficult to install and aren't as efficient as they could be. Therefore this project uses Cython and Numpy to efficiently and cleanly bind to TA-Lib -- producing results 2-4 times faster than the SWIG interface.

In addition, this project also supports the use of the Polars and Pandas libraries.

Installation

You can install from PyPI:

$ python -m pip install TA-Lib

Or checkout the sources and run setup.py yourself:

$ python setup.py install

It also appears possible to install via Conda Forge:

$ conda install -c conda-forge ta-lib

Dependencies

To use TA-Lib for python, you need to have the TA-Lib already installed. You should probably follow their installation directions for your platform, but some suggestions are included below for reference.

Some Conda Forge users have reported success installing the underlying TA-Lib C library using the libta-lib package:

$ conda install -c conda-forge libta-lib

Mac OS X

You can simply install using Homebrew:

$ brew install ta-lib

If you are using Apple Silicon, such as the M1 processors, and building mixed architecture Homebrew projects, you might want to make sure it's being built for your architecture:

$ arch -arm64 brew install ta-lib

And perhaps you can set these before installing with pip:

$ export TA_INCLUDE_PATH="$(brew --prefix ta-lib)/include"
$ export TA_LIBRARY_PATH="$(brew --prefix ta-lib)/lib"

You might also find this helpful, particularly if you have tried several different installations without success:

$ your-arm64-python -m pip install --no-cache-dir ta-lib
Windows

Download ta-lib-0.4.0-msvc.zip and unzip to C:\ta-lib.

This is a 32-bit binary release. If you want to use 64-bit Python, you will need to build a 64-bit version of the library. Some unofficial instructions for building on 64-bit Windows 10 or Windows 11, here for reference:

  1. Download and Unzip ta-lib-0.4.0-msvc.zip
  2. Move the Unzipped Folder ta-lib to C:\
  3. Download and Install Visual Studio Community (2015 or later)
    • Remember to Select [Visual C++] Feature
  4. Build TA-Lib Library
    • From Windows Start Menu, Start [VS2015 x64 Native Tools Command Prompt]
    • Move to C:\ta-lib\c\make\cdr\win32\msvc
    • Build the Library nmake

You might also try these unofficial windows binary wheels for both 32-bit and 64-bit:

https://github.com/cgohlke/talib-build/

Linux

Download ta-lib-0.4.0-src.tar.gz and:

$ tar -xzf ta-lib-0.4.0-src.tar.gz
$ cd ta-lib/
$ ./configure --prefix=/usr
$ make
$ sudo make install

If you build TA-Lib using make -jX it will fail but that's OK! Simply rerun make -jX followed by [sudo] make install.

Note: if your directory path includes spaces, the installation will probably fail with No such file or directory errors.

Troubleshooting

If you get a warning that looks like this:

setup.py:79: UserWarning: Cannot find ta-lib library, installation may fail.
warnings.warn('Cannot find ta-lib library, installation may fail.')

This typically means setup.py can't find the underlying TA-Lib library, a dependency which needs to be installed.


If you installed the underlying TA-Lib library with a custom prefix (e.g., with ./configure --prefix=$PREFIX), then when you go to install this python wrapper you can specify additional search paths to find the library and include files for the underlying TA-Lib library using the TA_LIBRARY_PATH and TA_INCLUDE_PATH environment variables:

$ export TA_LIBRARY_PATH=$PREFIX/lib
$ export TA_INCLUDE_PATH=$PREFIX/include
$ python setup.py install # or pip install ta-lib

Sometimes installation will produce build errors like this:

talib/_ta_lib.c:601:10: fatal error: ta-lib/ta_defs.h: No such file or directory
  601 | #include "ta-lib/ta_defs.h"
      |          ^~~~~~~~~~~~~~~~~~
compilation terminated.

or:

common.obj : error LNK2001: unresolved external symbol TA_SetUnstablePeriod
common.obj : error LNK2001: unresolved external symbol TA_Shutdown
common.obj : error LNK2001: unresolved external symbol TA_Initialize
common.obj : error LNK2001: unresolved external symbol TA_GetUnstablePeriod
common.obj : error LNK2001: unresolved external symbol TA_GetVersionString

This typically means that it can't find the underlying TA-Lib library, a dependency which needs to be installed. On Windows, this could be caused by installing the 32-bit binary distribution of the underlying TA-Lib library, but trying to use it with 64-bit Python.


Sometimes installation will fail with errors like this:

talib/common.c:8:22: fatal error: pyconfig.h: No such file or directory
 #include "pyconfig.h"
                      ^
compilation terminated.
error: command 'x86_64-linux-gnu-gcc' failed with exit status 1

This typically means that you need the Python headers, and should run something like:

$ sudo apt-get install python3-dev

Sometimes building the underlying TA-Lib library has errors running make that look like this:

../libtool: line 1717: cd: .libs/libta_lib.lax/libta_abstract.a: No such file or directory
make[2]: *** [libta_lib.la] Error 1
make[1]: *** [all-recursive] Error 1
make: *** [all-recursive] Error 1

This might mean that the directory path to the underlying TA-Lib library has spaces in the directory names. Try putting it in a path that does not have any spaces and trying again.


Sometimes you might get this error running setup.py:

/usr/include/limits.h:26:10: fatal error: bits/libc-header-start.h: No such file or directory
#include <bits/libc-header-start.h>
         ^~~~~~~~~~~~~~~~~~~~~~~~~~

This is likely an issue with trying to compile for 32-bit platform but without the appropriate headers. You might find some success looking at the first answer to this question.


If you get an error on macOS like this:

code signature in <141BC883-189B-322C-AE90-CBF6B5206F67>
'python3.9/site-packages/talib/_ta_lib.cpython-39-darwin.so' not valid for
use in process: Trying to load an unsigned library)

You might look at this question and use xcrun codesign to fix it.


If you wonder why STOCHRSI gives you different results than you expect, probably you want STOCH applied to RSI, which is a little different than the STOCHRSI which is STOCHF applied to RSI:

>>> import talib
>>> import numpy as np
>>> c = np.random.randn(100)

# this is the library function
>>> k, d = talib.STOCHRSI(c)

# this produces the same result, calling STOCHF
>>> rsi = talib.RSI(c)
>>> k, d = talib.STOCHF(rsi, rsi, rsi)

# you might want this instead, calling STOCH
>>> rsi = talib.RSI(c)
>>> k, d = talib.STOCH(rsi, rsi, rsi)

If the build appears to hang, you might be running on a VM with not enough memory -- try 1 GB or 2 GB.


If you get "permission denied" errors such as this, you might need to give your user access to the location where the underlying TA-Lib C library is installed -- or install it to a user-accessible location.

talib/_ta_lib.c:747:28: fatal error: /usr/include/ta-lib/ta_defs.h: Permission denied
 #include "ta-lib/ta-defs.h"
                            ^
compilation terminated
error: command 'gcc' failed with exit status 1

If you're having trouble compiling the underlying TA-Lib C library on ARM64, you might need to configure it with an explicit build type before running make and make install, for example:

$ ./configure --build=aarch64-unknown-linux-gnu

This is caused by old config.guess file, so another way to solve this is to copy a newer version of config.guess into the underlying TA-Lib C library sources:

$ cp /usr/share/automake-1.16/config.guess /path/to/extracted/ta-lib/config.guess

And then re-run configure:

$ ./configure

If you're having trouble using PyInstaller and get an error that looks like this:

...site-packages\PyInstaller\loader\pyimod03_importers.py", line 493, in exec_module
    exec(bytecode, module.__dict__)
  File "talib\__init__.py", line 72, in <module>
ModuleNotFoundError: No module named 'talib.stream'

Then, perhaps you can use the --hidden-import argument to fix this:

$ pyinstaller --hidden-import talib.stream "replaceToYourFileName.py"

Function API

Similar to TA-Lib, the Function API provides a lightweight wrapper of the exposed TA-Lib indicators.

Each function returns an output array and have default values for their parameters, unless specified as keyword arguments. Typically, these functions will have an initial "lookback" period (a required number of observations before an output is generated) set to NaN.

For convenience, the Function API supports both numpy.ndarray and pandas.Series and polars.Series inputs.

All of the following examples use the Function API:

import numpy as np
import talib

close = np.random.random(100)

Calculate a simple moving average of the close prices:

output = talib.SMA(close)

Calculating bollinger bands, with triple exponential moving average:

from talib import MA_Type

upper, middle, lower = talib.BBANDS(close, matype=MA_Type.T3)

Calculating momentum of the close prices, with a time period of 5:

output = talib.MOM(close, timeperiod=5)
NaN's

The underlying TA-Lib C library handles NaN's in a sometimes surprising manner by typically propagating NaN's to the end of the output, for example:

>>> c = np.array([1.0, 2.0, 3.0, np.nan, 4.0, 5.0, 6.0])

>>> talib.SMA(c, 3)
array([nan, nan,  2., nan, nan, nan, nan])

You can compare that to a Pandas rolling mean, where their approach is to output NaN until enough "lookback" values are observed to generate new outputs:

>>> c = pandas.Series([1.0, 2.0, 3.0, np.nan, 4.0, 5.0, 6.0])

>>> c.rolling(3).mean()
0    NaN
1    NaN
2    2.0
3    NaN
4    NaN
5    NaN
6    5.0
dtype: float64

Abstract API

If you're already familiar with using the function API, you should feel right at home using the Abstract API.

Every function takes a collection of named inputs, either a dict of numpy.ndarray or pandas.Series or polars.Series, or a pandas.DataFrame or polars.DataFrame. If a pandas.DataFrame or polars.DataFrame is provided, the output is returned as the same type with named output columns.

For example, inputs could be provided for the typical "OHLCV" data:

import numpy as np

# note that all ndarrays must be the same length!
inputs = {
    'open': np.random.random(100),
    'high': np.random.random(100),
    'low': np.random.random(100),
    'close': np.random.random(100),
    'volume': np.random.random(100)
}

Functions can either be imported directly or instantiated by name:

from talib import abstract

# directly
SMA = abstract.SMA

# or by name
SMA = abstract.Function('sma')

From there, calling functions is basically the same as the function API:

from talib.abstract import *

# uses close prices (default)
output = SMA(inputs, timeperiod=25)

# uses open prices
output = SMA(inputs, timeperiod=25, price='open')

# uses close prices (default)
upper, middle, lower = BBANDS(inputs, 20, 2.0, 2.0)

# uses high, low, close (default)
slowk, slowd = STOCH(inputs, 5, 3, 0, 3, 0) # uses high, low, close by default

# uses high, low, open instead
slowk, slowd = STOCH(inputs, 5, 3, 0, 3, 0, prices=['high', 'low', 'open'])

Streaming API

An experimental Streaming API was added that allows users to compute the latest value of an indicator. This can be faster than using the Function API, for example in an application that receives streaming data, and wants to know just the most recent updated indicator value.

import talib
from talib import stream

close = np.random.random(100)

# the Function API
output = talib.SMA(close)

# the Streaming API
latest = stream.SMA(close)

# the latest value is the same as the last output value
assert (output[-1] - latest) < 0.00001

Supported Indicators and Functions

We can show all the TA functions supported by TA-Lib, either as a list or as a dict sorted by group (e.g. "Overlap Studies", "Momentum Indicators", etc):

import talib

# list of functions
for name in talib.get_functions():
    print(name)

# dict of functions by group
for group, names in talib.get_function_groups().items():
    print(group)
    for name in names:
        print(f"  {name}")

Indicator Groups

  • Overlap Studies
  • Momentum Indicators
  • Volume Indicators
  • Volatility Indicators
  • Price Transform
  • Cycle Indicators
  • Pattern Recognition
Overlap Studies
BBANDS               Bollinger Bands
DEMA                 Double Exponential Moving Average
EMA                  Exponential Moving Average
HT_TRENDLINE         Hilbert Transform - Instantaneous Trendline
KAMA                 Kaufman Adaptive Moving Average
MA                   Moving average
MAMA                 MESA Adaptive Moving Average
MAVP                 Moving average with variable period
MIDPOINT             MidPoint over period
MIDPRICE             Midpoint Price over period
SAR                  Parabolic SAR
SAREXT               Parabolic SAR - Extended
SMA                  Simple Moving Average
T3                   Triple Exponential Moving Average (T3)
TEMA                 Triple Exponential Moving Average
TRIMA                Triangular Moving Average
WMA                  Weighted Moving Average
Momentum Indicators
ADX                  Average Directional Movement Index
ADXR                 Average Directional Movement Index Rating
APO                  Absolute Price Oscillator
AROON                Aroon
AROONOSC             Aroon Oscillator
BOP                  Balance Of Power
CCI                  Commodity Channel Index
CMO                  Chande Momentum Oscillator
DX                   Directional Movement Index
MACD                 Moving Average Convergence/Divergence
MACDEXT              MACD with controllable MA type
MACDFIX              Moving Average Convergence/Divergence Fix 12/26
MFI                  Money Flow Index
MINUS_DI             Minus Directional Indicator
MINUS_DM             Minus Directional Movement
MOM                  Momentum
PLUS_DI              Plus Directional Indicator
PLUS_DM              Plus Directional Movement
PPO                  Percentage Price Oscillator
ROC                  Rate of change : ((price/prevPrice)-1)*100
ROCP                 Rate of change Percentage: (price-prevPrice)/prevPrice
ROCR                 Rate of change ratio: (price/prevPrice)
ROCR100              Rate of change ratio 100 scale: (price/prevPrice)*100
RSI                  Relative Strength Index
STOCH                Stochastic
STOCHF               Stochastic Fast
STOCHRSI             Stochastic Relative Strength Index
TRIX                 1-day Rate-Of-Change (ROC) of a Triple Smooth EMA
ULTOSC               Ultimate Oscillator
WILLR                Williams' %R
Volume Indicators
AD                   Chaikin A/D Line
ADOSC                Chaikin A/D Oscillator
OBV                  On Balance Volume
Cycle Indicators
HT_DCPERIOD          Hilbert Transform - Dominant Cycle Period
HT_DCPHASE           Hilbert Transform - Dominant Cycle Phase
HT_PHASOR            Hilbert Transform - Phasor Components
HT_SINE              Hilbert Transform - SineWave
HT_TRENDMODE         Hilbert Transform - Trend vs Cycle Mode
Price Transform
AVGPRICE             Average Price
MEDPRICE             Median Price
TYPPRICE             Typical Price
WCLPRICE             Weighted Close Price
Volatility Indicators
ATR                  Average True Range
NATR                 Normalized Average True Range
TRANGE               True Range
Pattern Recognition
CDL2CROWS            Two Crows
CDL3BLACKCROWS       Three Black Crows
CDL3INSIDE           Three Inside Up/Down
CDL3LINESTRIKE       Three-Line Strike
CDL3OUTSIDE          Three Outside Up/Down
CDL3STARSINSOUTH     Three Stars In The South
CDL3WHITESOLDIERS    Three Advancing White Soldiers
CDLABANDONEDBABY     Abandoned Baby
CDLADVANCEBLOCK      Advance Block
CDLBELTHOLD          Belt-hold
CDLBREAKAWAY         Breakaway
CDLCLOSINGMARUBOZU   Closing Marubozu
CDLCONCEALBABYSWALL  Concealing Baby Swallow
CDLCOUNTERATTACK     Counterattack
CDLDARKCLOUDCOVER    Dark Cloud Cover
CDLDOJI              Doji
CDLDOJISTAR          Doji Star
CDLDRAGONFLYDOJI     Dragonfly Doji
CDLENGULFING         Engulfing Pattern
CDLEVENINGDOJISTAR   Evening Doji Star
CDLEVENINGSTAR       Evening Star
CDLGAPSIDESIDEWHITE  Up/Down-gap side-by-side white lines
CDLGRAVESTONEDOJI    Gravestone Doji
CDLHAMMER            Hammer
CDLHANGINGMAN        Hanging Man
CDLHARAMI            Harami Pattern
CDLHARAMICROSS       Harami Cross Pattern
CDLHIGHWAVE          High-Wave Candle
CDLHIKKAKE           Hikkake Pattern
CDLHIKKAKEMOD        Modified Hikkake Pattern
CDLHOMINGPIGEON      Homing Pigeon
CDLIDENTICAL3CROWS   Identical Three Crows
CDLINNECK            In-Neck Pattern
CDLINVERTEDHAMMER    Inverted Hammer
CDLKICKING           Kicking
CDLKICKINGBYLENGTH   Kicking - bull/bear determined by the longer marubozu
CDLLADDERBOTTOM      Ladder Bottom
CDLLONGLEGGEDDOJI    Long Legged Doji
CDLLONGLINE          Long Line Candle
CDLMARUBOZU          Marubozu
CDLMATCHINGLOW       Matching Low
CDLMATHOLD           Mat Hold
CDLMORNINGDOJISTAR   Morning Doji Star
CDLMORNINGSTAR       Morning Star
CDLONNECK            On-Neck Pattern
CDLPIERCING          Piercing Pattern
CDLRICKSHAWMAN       Rickshaw Man
CDLRISEFALL3METHODS  Rising/Falling Three Methods
CDLSEPARATINGLINES   Separating Lines
CDLSHOOTINGSTAR      Shooting Star
CDLSHORTLINE         Short Line Candle
CDLSPINNINGTOP       Spinning Top
CDLSTALLEDPATTERN    Stalled Pattern
CDLSTICKSANDWICH     Stick Sandwich
CDLTAKURI            Takuri (Dragonfly Doji with very long lower shadow)
CDLTASUKIGAP         Tasuki Gap
CDLTHRUSTING         Thrusting Pattern
CDLTRISTAR           Tristar Pattern
CDLUNIQUE3RIVER      Unique 3 River
CDLUPSIDEGAP2CROWS   Upside Gap Two Crows
CDLXSIDEGAP3METHODS  Upside/Downside Gap Three Methods
Statistic Functions
BETA                 Beta
CORREL               Pearson's Correlation Coefficient (r)
LINEARREG            Linear Regression
LINEARREG_ANGLE      Linear Regression Angle
LINEARREG_INTERCEPT  Linear Regression Intercept
LINEARREG_SLOPE      Linear Regression Slope
STDDEV               Standard Deviation
TSF                  Time Series Forecast
VAR                  Variance