• Python调用R编程——rpy2


    在Python调用R,最常见的方式是使用rpy2模块。

    简介

    模块

    The package is made of several sub-packages or modules:

    • rpy2.rinterface —— Low-level interface to R, when speed and flexibility matter most. Close to R’s C-level API.
    • rpy2.robjects —— High-level interface, when ease-of-use matters most. Should be the right pick for casual and general use. Based on the previous one.
    • rpy2.interactive —— High-level interface, with an eye for interactive work. Largely based on rpy2.robjects.
    • rpy2.rpy_classic —— High-level interface similar to the one in RPy-1.x. This is provided for compatibility reasons, as well as to facilitate the migration to RPy2.
    • rpy2.rlike —— Data structures and functions to mimic some of R’s features and specificities in pure Python (no embedded R process).

    在Python导入R进程

    import rpy2.robjects as robjects
    

    Python中的R包

    导入R包

    Importing R packages is often the first step when running R code, and rpy2 is providing a function rpy2.robjects.packages.importr() that makes that step very similar to importing Python packages.

    from rpy2.robjects.packages import importr
    
    # import R's "base" package
    base = importr('base')
    

    r实例

    We mentioned earlier that rpy2 is running an embedded R. This is may be a little abstract, so there is an object rpy2.robjects.r to make it tangible.

    在Python获得R对象

    The __getitem__() method of rpy2.robjects.r, gets the R object associated with a given symbol

    >>> pi = robjects.r['pi']
    >>> pi[0]
    3.14159265358979
    

    执行R语句

    The object r is also callable, and the string passed in a call is evaluated as R code.

    >>> piplus2 = robjects.r('pi') + 2
    >>> piplus2.r_repr()
    c(3.14159265358979, 2)
    >>> pi0plus2 = robjects.r('pi')[0] + 2
    >>> print(pi0plus2)
    5.1415926535897931
    

    R对象的表达方式

    An R object has a string representation that can be used directly into R code to be evaluated.

    >>> letters = robjects.r['letters']
    >>> rcode = 'paste(%s, collapse="-")' %(letters.r_repr())
    >>> res = robjects.r(rcode)
    >>> print(res)
    "a-b-c-d-e-f-g-h-i-j-k-l-m-n-o-p-q-r-s-t-u-v-w-x-y-z"
    

    R向量

    In R, data are mostly represented by vectors, even when looking like scalars. When looking closely at the R object pi used previously, we can observe that this is in fact a vector of length 1.

    >>> len(robjects.r['pi'])
    
    >>> robjects.r['pi'][0]
    3.1415926535897931
    

    创建R向量

    Creating R vectors can be achieved simply.

    >>> res = robjects.StrVector(['abc', 'def'])
    >>> print(res.r_repr())
    c("abc", "def")
    >>> res = robjects.IntVector([1, 2, 3])
    >>> print(res.r_repr())
    1:3
    >>> res = robjects.FloatVector([1.1, 2.2, 3.3])
    >>> print(res.r_repr())
    c(1.1, 2.2, 3.3)
    

    The easiest way to create such objects is to do it through R functions.

    >>> v = robjects.FloatVector([1.1, 2.2, 3.3, 4.4, 5.5, 6.6])
    >>> m = robjects.r['matrix'](v, nrow = 2)
    >>> print(m)
         [,1] [,2] [,3]
    [1,]  1.1  3.3  5.5
    [2,]  2.2  4.4  6.6
    

    调用R函数

    Calling R functions is disappointingly similar to calling Python functions.

    >>> rsort = robjects.r['sort']
    >>> res = rsort(robjects.IntVector([1,2,3]), decreasing=True)
    >>> print(res.r_repr())
    c(3L, 2L, 1L)
    

    By default, calling R functions return R objects.

    一些例子

    Linear models

    from rpy2.robjects import FloatVector
    from rpy2.robjects.packages import importr
    stats = importr('stats')
    base = importr('base')
    
    ctl = FloatVector([4.17,5.58,5.18,6.11,4.50,4.61,5.17,4.53,5.33,5.14])
    trt = FloatVector([4.81,4.17,4.41,3.59,5.87,3.83,6.03,4.89,4.32,4.69])
    group = base.gl(2, 10, 20, labels = ["Ctl","Trt"])
    weight = ctl + trt
    
    robjects.globalenv["weight"] = weight
    robjects.globalenv["group"] = group
    lm_D9 = stats.lm("weight ~ group")
    print(stats.anova(lm_D9))
    
    # omitting the intercept
    lm_D90 = stats.lm("weight ~ group - 1")
    print(base.summary(lm_D90))
    
    >>> print(lm_D9.names)
     [1] "coefficients"  "residuals"     "effects"       "rank"
     [5] "fitted.values" "assign"        "qr"            "df.residual" 
     [9] "contrasts"     "xlevels"       "call"          "terms"
    [13] "model"
    
    >>> print(lm_D9.rx2('coefficients'))
    (Intercept)    groupTrt
          5.032      -0.371
    
    >>> print(lm_D9.rx('coefficients'))
    $coefficients
    (Intercept)    groupTrt
          5.032      -0.371
    

    Creating an R vector or matrix, and filling its cells using Python code

    from rpy2.robjects import NA_Real
    from rpy2.rlike.container import TaggedList
    from rpy2.robjects.packages import importr
    
    base = importr('base')
    
    # create a numerical matrix of size 100x10 filled with NAs
    m = base.matrix(NA_Real, nrow=100, ncol=10)
    
    # fill the matrix
    for row_i in xrange(1, 100+1):
        for col_i in xrange(1, 10+1):
            m.rx[TaggedList((row_i, ), (col_i, ))] = row_i + col_i * 100
    

    R的高级接口

    robject包

    This module should be the right pick for casual and general use. Its aim is to abstract some of the details and provide an intuitive interface to both Python and R programmers.

    >>> import rpy2.robjects as robjects
    

    r:R的实例

    The instance can be seen as the entry point to an embedded R process. The elements that would be accessible from an equivalent R environment are accessible as attributes of the instance.

    >>> pi = robjects.r.pi
    >>> letters = robjects.r.letters
    >>> plot = robjects.r.plot
    >>> dir = robjects.r.dir
    

    When safety matters most, we recommend using __getitem__() to get a given R object.

    >>> as_null = robjects.r['as.null']
    

    Storing the object in a python variable will protect it from garbage collection, even if deleted from the objects visible to an R user.

    >>> robjects.globalenv['foo'] = 1.2
    >>> foo = robjects.r['foo']
    >>> foo[0]
    1.2
    
    >>> robjects.r['rm']('foo')
    >>> robjects.r['foo']
    LookupError: 'foo' not found
    
    >>> foo[0]
    1.2
    

    执行字符串中的R代码

    Just like it is the case with RPy-1.x, on-the-fly evaluation of R code contained in a string can be performed by calling the r instance.

    >>> print(robjects.r('1+2'))
    [1] 3
    >>> sqr = robjects.r('function(x) x^2')
    
    >>> print(sqr)
    function (x)
    x^2
    >>> print(sqr(2))
    [1] 4
    

    The astute reader will quickly realize that R objects named by python variables can be plugged into code through their R representation.

    >>> x = robjects.r.rnorm(100)
    >>> robjects.r('hist(%s, xlab="x", main="hist(x)")' %x.r_repr())
    

    R语言环境

    R environments can be described to the Python user as an hybrid of a dictionary and a scope.

    The first of all environments is called the Global Environment, that can also be referred to as the R workspace.

    Assigning a value to a symbol in an environment has been made as simple as assigning a value to a key in a Python dictionary.

    >>> robjects.r.ls(globalenv)
    >>> robjects.globalenv["a"] = 123
    >>> print(robjects.r.ls(globalenv))
    

    An environment is also iter-able, returning all the symbols (keys) it contains.

    >>> env = robjects.r.baseenv()
    >>> [x for x in env]
    <a long list returned>
    

    函数

    R functions exposed by rpy2's high-level interface can be used:

    • like any regular Python function as they are callable objects
    • through their method rcall()

    可调用性callable

    from rpy2.robjects.packages import importr
    base = importr('base')
    stats = importr('stats')
    graphics = importr('graphics')
    
    plot = graphics.plot
    rnorm = stats.rnorm
    plot(rnorm(100), ylab="random")
    

    This is all looking fine and simple until R arguments with names such as na.rm are encountered. By default, this is addressed by having a translation of ‘.’ (dot) in the R argument name into a ‘_’ in the Python argument name.

    In Python one can write:

    from rpy2.robjects.packages import importr
    base = importr('base')
    
    base.rank(0, na_last = True)
    

    R is capable of introspection, and can return the arguments accepted by a function through the function formals().

    >>> from rpy2.robjects.packages import importr
    >>> stats = importr('stats')
    >>> rnorm = stats.rnorm
    >>> rnorm.formals()
    <Vector - Python:0x8790bcc / R:0x93db250>
    >>> tuple(rnorm.formals().names)
    ('n', 'mean', 'sd')
    

    rcall()

    The method Function.rcall() is an alternative way to call an underlying R function.

    R的表达式——Formulae

    For tasks such as modelling and plotting, an R formula can be a terse, yet readable, way of expressing what is wanted.

    The class robjects.Formula is representing an R formula.

    import array
    from rpy2.robjects import IntVector, Formula
    from rpy2.robjects.packages import importr
    stats = importr('stats')
    
    x = IntVector(range(1, 11))
    y = x.ro + stats.rnorm(10, sd=0.2)
    
    fmla = Formula('y ~ x')
    env = fmla.environment
    env['x'] = x
    env['y'] = y
    
    fit = stats.lm(fmla)
    

    Other options are:

    • Evaluate R code on the fly so we that model fitting function has a symbol in R
    fit = robjects.r('lm(%s)' %fmla.r_repr())
    
    • Evaluate R code where all symbols are defined

    R包

    导入R包

    This is achieved by the R functions library() and require() (attaching the namespace of the package to the R search path).

    from rpy2.robjects.packages import importr
    utils = importr("utils")
    

    向量和数组

    Beside functions and environments, most of the objects an R user is interacting with are vector-like. For example, this means that any scalar is in fact a vector of length one.

    The class Vector has a constructor:

    >>> x = robjects.Vector(3)
    

    创建向量

    Creating vectors can be achieved either from R or from Python.

    When the vectors are created from R, one should not worry much as they will be exposed as they should by rpy2.robjects.

    When one wants to create a vector from Python, either the class Vector or the convenience classes IntVector, FloatVector, BoolVector, StrVector can be used.

    因素向量 —— FactorVector

    >>> sv = ro.StrVector('ababbc')
    >>> fac = ro.FactorVector(sv)
    >>> print(fac)
    [1] a b a b b c
    Levels: a b c
    >>> tuple(fac)
    (1, 2, 1, 2, 2, 3)
    >>> tuple(fac.levels)
    ('a', 'b', 'c')
    

    解析向量元素

    Extracting, Python-style

    The python __getitem__() method behaves like a Python user would expect it for a vector (and indexing starts at zero).

    >>> x = robjects.r.seq(1, 5)
    >>> tuple(x)
    (1, 2, 3, 4, 5)
    >>> x.names = robjects.StrVector('abcde')
    >>> print(x)
    a b c d e
    1 2 3 4 5
    >>> x[0]
    1
    >>> x[4]
    5
    >>> x[-1]
    5
    

    Extracting, R-style

    Access to R-style extracting/subsetting is granted though the two delegators rx and rx2, representing the R functions [ and [[ respectively.

    >>> print(x.rx(1))
    [1] 1
    >>> print(x.rx('a'))
    a
    1
    

    向量赋值

    Assigning, Python-style

    Since vectors are exposed as Python mutable sequences, the assignment works as for regular Python lists.

    >>> x = robjects.IntVector((1,2,3))
    >>> print(x)
    [1] 1 2 3
    >>> x[0] = 9
    >>> print(x)
    [1] 9 2 3
    

    In R vectors can be named, that is elements of the vector have a name.

    >>> x = robjects.ListVector({'a': 1, 'b': 2, 'c': 3})
    >>> x[x.names.index('b')] = 9
    

    Assigning, R-style

    The attributes rx and rx2 used previously can again be used:

    >>> x = robjects.IntVector(range(1, 4))
    >>> print(x)
    [1] 1 2 3
    >>> x.rx[1] = 9
    >>> print(x)
    [1] 9 2 3
    

    For the sake of complete compatibility with R, arguments can be named (and passed as a dict or rpy2.rlike.container.TaggedList).

    >>> x = robjects.ListVector({'a': 1, 'b': 2, 'c': 3})
    >>> x.rx2[{'i': x.names.index('b')}] = 9
    

    缺失值

    In S/Splus/R special NA values can be used in a data vector to indicate that fact, and rpy2.robjects makes aliases for those available as data objects NA_Logical, NA_Real, NA_Integer, NA_Character, NA_Complex.

    >>> x = robjects.IntVector(range(3))
    >>> x[0] = robjects.NA_Integer
    >>> print(x)
    [1] NA  1  2
    
    >>> x[0] is robjects.NA_Integer
    True
    >>> x[0] == robjects.NA_Integer
    True
    >>> [y for y in x if y is not robjects.NA_Integer]
    [1, 2]
    

    运算

    To expose that to Python, a delegating attribute ro is provided for vector-like objects.

    >>> x = robjects.r.seq(1, 10)
    >>> print(x.ro + 1)
    2:11
    

    名字 —— Names

    R vectors can have a name given to all or some of the elements. The property names can be used to get, or set, those names.

    >>> x = robjects.r.seq(1, 5)
    >>> x.names = robjects.StrVector('abcde')
    >>> x.names[0]
    'a'
    >>> x.names[0] = 'z'
    >>> tuple(x.names)
    ('z', 'b', 'c', 'd', 'e')
    

    Array

    In R, arrays are simply vectors with a dimension attribute. That fact was reflected in the class hierarchy with robjects.Array inheriting from robjects.Vector.

    Matrix

    A Matrix is a special case of Array. As with arrays, one must remember that this is just a vector with dimension attributes (number of rows, number of columns).

    >>> m = robjects.r.matrix(robjects.IntVector(range(10)), nrow=5)
    >>> print(m)
         [,1] [,2]
    [1,]    0    5
    [2,]    1    6
    [3,]    2    7
    [4,]    3    8
    [5,]    4    9
    
    >>> m = ro.r.matrix(ro.IntVector(range(2, 8)), nrow=3)
    >>> print(m)
         [,1] [,2]
    [1,]    2    5
    [2,]    3    6
    [3,]    4    7
    >>> m[0]
    2
    >>> m[5]
    7
    >>> print(m.rx(1))
    [1] 2
    >>> print(m.rx(6))
    [1] 7
    

    DataFrame

    In rpy2.robjects, DataFrame represents the R class data.frame.

    Creating a DataFrame can be done by:

    • Using the constructor for the class
    • Create the data.frame through R
    • Read data from a file using the instance method from_csvfile()

    The DataFrame constructor accepts either an rinterface.SexpVector (with typeof equal to VECSXP, that is, an R list) or any Python object implementing the method items() (for example dict or rpy2.rlike.container.OrdDict).

    >>> d = {'a': robjects.IntVector((1,2,3)), 'b': robjects.IntVector((4,5,6))}
    >>> dataf = robject.DataFrame(d)
    

    To create a DataFrame and be certain of the clumn order order, an ordered dictionary can be used:

    >>> import rpy2.rlike.container as rlc
    >>> od = rlc.OrdDict([('value', robjects.IntVector((1,2,3))),
                          ('letter', robjects.StrVector(('x', 'y', 'z')))])
    >>> dataf = robjects.DataFrame(od)
    >>> print(dataf.colnames)
    [1] "letter" "value"
    

    Here again, Python’s __getitem__() will work as a Python programmer will expect it to:

    >>> len(dataf)
    2
    >>> dataf[0]
    <Vector - Python:0x8a58c2c / R:0x8e7dd08>
    

    The DataFrame is composed of columns, with each column being possibly of a different type:

    >>> [column.rclass[0] for column in dataf]
    ['factor', 'integer']
    
    >>> dataf.rx(1)
    <DataFrame - Python:0x8a584ac / R:0x95a6fb8>
    >>> print(dataf.rx(1))
      letter
    1      x
    2      y
    3      z
    
    >>> dataf.rx2(1)
    <Vector - Python:0x8a4bfcc / R:0x8e7dd08>
    >>> print(dataf.rx2(1))
    [1] x y z
    Levels: x y z
    

    转换R对象到Python对象

    The approach followed in rpy2 has 2 levels (rinterface and robjects), and conversion functions help moving between them.

    协议 —— Protocols

    R vectors are mapped to Python objects implementing the methods __getitem__() / __setitem__() in the sequence protocol so elements can be accessed easily.

    R functions are mapped to Python objects implementing the __call__() so they can be called just as if they were functions.

    R environments are mapped to Python objects implementing __getitem__() / __setitem__() in the mapping protocol so elements can be accessed similarly to in a Python dict.

    转换 —— Conversion

    In its high-level interface rpy2 is using a conversion system that has the task of convertion objects between the following 3 representations: - lower-level interface to R (rpy2.rinterface level), - higher-level interface to R (rpy2.robjects level) - other (no rpy2) representations

    Numpy包

    高级接口

    From rpy2 to numpy

    R vectors or arrays can be converted to numpy arrays using numpy.array() or numpy.asarray().

    import numpy
    
    ltr = robjects.r.letters
    ltr_np = numpy.array(ltr)
    

    From numpy to rpy2

    The activation (and deactivation) of the automatic conversion of numpy objects into rpy2 objects can be made with:

    from rpy2.robjects import numpy2ri
    numpy2ri.activate()
    numpy2ri.deactivate()


    作者:plutoese
    链接:https://www.jianshu.com/p/d8578362245a
    來源:简书
    简书著作权归作者所有,任何形式的转载都请联系作者获得授权并注明出处。
  • 相关阅读:
    python全栈开发day76-博客主页
    python全栈开发day75-用户注册页面ajax实现,用户头像上传、预览、展示
    python全栈开发day74-普通验证码和滑块验证码
    python全栈开发day73-Django认证系统
    python全栈开发day72-django之Form组件
    python全栈开发day70-Django中间件
    python全栈开发day69-cookie、session
    python全栈开发day68-ORM操作:一般操作、ForeignKey操作、ManyToManyField、聚合查询和分组查询、F查询和Q查询等
    选择排序
    冒泡排序
  • 原文地址:https://www.cnblogs.com/lantingg/p/9600280.html
Copyright © 2020-2023  润新知