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Old engine for Continuous Time Bayesian Networks. Superseded by reCTBN. 🐍 https://github.com/madlabunimib/PyCTBN
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PyCTBN/venv/lib/python3.9/site-packages/pandas/io/parsers.py

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"""
Module contains tools for processing files into DataFrames or other objects
"""
from collections import abc, defaultdict
import csv
import datetime
from io import StringIO, TextIOWrapper
import itertools
import re
import sys
from textwrap import fill
from typing import Any, Dict, Iterable, List, Optional, Sequence, Set
import warnings
import numpy as np
import pandas._libs.lib as lib
import pandas._libs.ops as libops
import pandas._libs.parsers as parsers
from pandas._libs.parsers import STR_NA_VALUES
from pandas._libs.tslibs import parsing
from pandas._typing import FilePathOrBuffer, Union
from pandas.errors import (
AbstractMethodError,
EmptyDataError,
ParserError,
ParserWarning,
)
from pandas.util._decorators import Appender
from pandas.core.dtypes.cast import astype_nansafe
from pandas.core.dtypes.common import (
ensure_object,
ensure_str,
is_bool_dtype,
is_categorical_dtype,
is_dict_like,
is_dtype_equal,
is_extension_array_dtype,
is_file_like,
is_float,
is_integer,
is_integer_dtype,
is_list_like,
is_object_dtype,
is_scalar,
is_string_dtype,
pandas_dtype,
)
from pandas.core.dtypes.dtypes import CategoricalDtype
from pandas.core.dtypes.missing import isna
from pandas.core import algorithms
from pandas.core.arrays import Categorical
from pandas.core.frame import DataFrame
from pandas.core.indexes.api import (
Index,
MultiIndex,
RangeIndex,
ensure_index_from_sequences,
)
from pandas.core.series import Series
from pandas.core.tools import datetimes as tools
from pandas.io.common import (
get_filepath_or_buffer,
get_handle,
infer_compression,
validate_header_arg,
)
from pandas.io.date_converters import generic_parser
# BOM character (byte order mark)
# This exists at the beginning of a file to indicate endianness
# of a file (stream). Unfortunately, this marker screws up parsing,
# so we need to remove it if we see it.
_BOM = "\ufeff"
_doc_read_csv_and_table = (
r"""
{summary}
Also supports optionally iterating or breaking of the file
into chunks.
Additional help can be found in the online docs for
`IO Tools <https://pandas.pydata.org/pandas-docs/stable/user_guide/io.html>`_.
Parameters
----------
filepath_or_buffer : str, path object or file-like object
Any valid string path is acceptable. The string could be a URL. Valid
URL schemes include http, ftp, s3, gs, and file. For file URLs, a host is
expected. A local file could be: file://localhost/path/to/table.csv.
If you want to pass in a path object, pandas accepts any ``os.PathLike``.
By file-like object, we refer to objects with a ``read()`` method, such as
a file handler (e.g. via builtin ``open`` function) or ``StringIO``.
sep : str, default {_default_sep}
Delimiter to use. If sep is None, the C engine cannot automatically detect
the separator, but the Python parsing engine can, meaning the latter will
be used and automatically detect the separator by Python's builtin sniffer
tool, ``csv.Sniffer``. In addition, separators longer than 1 character and
different from ``'\s+'`` will be interpreted as regular expressions and
will also force the use of the Python parsing engine. Note that regex
delimiters are prone to ignoring quoted data. Regex example: ``'\r\t'``.
delimiter : str, default ``None``
Alias for sep.
header : int, list of int, default 'infer'
Row number(s) to use as the column names, and the start of the
data. Default behavior is to infer the column names: if no names
are passed the behavior is identical to ``header=0`` and column
names are inferred from the first line of the file, if column
names are passed explicitly then the behavior is identical to
``header=None``. Explicitly pass ``header=0`` to be able to
replace existing names. The header can be a list of integers that
specify row locations for a multi-index on the columns
e.g. [0,1,3]. Intervening rows that are not specified will be
skipped (e.g. 2 in this example is skipped). Note that this
parameter ignores commented lines and empty lines if
``skip_blank_lines=True``, so ``header=0`` denotes the first line of
data rather than the first line of the file.
names : array-like, optional
List of column names to use. If the file contains a header row,
then you should explicitly pass ``header=0`` to override the column names.
Duplicates in this list are not allowed.
index_col : int, str, sequence of int / str, or False, default ``None``
Column(s) to use as the row labels of the ``DataFrame``, either given as
string name or column index. If a sequence of int / str is given, a
MultiIndex is used.
Note: ``index_col=False`` can be used to force pandas to *not* use the first
column as the index, e.g. when you have a malformed file with delimiters at
the end of each line.
usecols : list-like or callable, optional
Return a subset of the columns. If list-like, all elements must either
be positional (i.e. integer indices into the document columns) or strings
that correspond to column names provided either by the user in `names` or
inferred from the document header row(s). For example, a valid list-like
`usecols` parameter would be ``[0, 1, 2]`` or ``['foo', 'bar', 'baz']``.
Element order is ignored, so ``usecols=[0, 1]`` is the same as ``[1, 0]``.
To instantiate a DataFrame from ``data`` with element order preserved use
``pd.read_csv(data, usecols=['foo', 'bar'])[['foo', 'bar']]`` for columns
in ``['foo', 'bar']`` order or
``pd.read_csv(data, usecols=['foo', 'bar'])[['bar', 'foo']]``
for ``['bar', 'foo']`` order.
If callable, the callable function will be evaluated against the column
names, returning names where the callable function evaluates to True. An
example of a valid callable argument would be ``lambda x: x.upper() in
['AAA', 'BBB', 'DDD']``. Using this parameter results in much faster
parsing time and lower memory usage.
squeeze : bool, default False
If the parsed data only contains one column then return a Series.
prefix : str, optional
Prefix to add to column numbers when no header, e.g. 'X' for X0, X1, ...
mangle_dupe_cols : bool, default True
Duplicate columns will be specified as 'X', 'X.1', ...'X.N', rather than
'X'...'X'. Passing in False will cause data to be overwritten if there
are duplicate names in the columns.
dtype : Type name or dict of column -> type, optional
Data type for data or columns. E.g. {{'a': np.float64, 'b': np.int32,
'c': 'Int64'}}
Use `str` or `object` together with suitable `na_values` settings
to preserve and not interpret dtype.
If converters are specified, they will be applied INSTEAD
of dtype conversion.
engine : {{'c', 'python'}}, optional
Parser engine to use. The C engine is faster while the python engine is
currently more feature-complete.
converters : dict, optional
Dict of functions for converting values in certain columns. Keys can either
be integers or column labels.
true_values : list, optional
Values to consider as True.
false_values : list, optional
Values to consider as False.
skipinitialspace : bool, default False
Skip spaces after delimiter.
skiprows : list-like, int or callable, optional
Line numbers to skip (0-indexed) or number of lines to skip (int)
at the start of the file.
If callable, the callable function will be evaluated against the row
indices, returning True if the row should be skipped and False otherwise.
An example of a valid callable argument would be ``lambda x: x in [0, 2]``.
skipfooter : int, default 0
Number of lines at bottom of file to skip (Unsupported with engine='c').
nrows : int, optional
Number of rows of file to read. Useful for reading pieces of large files.
na_values : scalar, str, list-like, or dict, optional
Additional strings to recognize as NA/NaN. If dict passed, specific
per-column NA values. By default the following values are interpreted as
NaN: '"""
+ fill("', '".join(sorted(STR_NA_VALUES)), 70, subsequent_indent=" ")
+ """'.
keep_default_na : bool, default True
Whether or not to include the default NaN values when parsing the data.
Depending on whether `na_values` is passed in, the behavior is as follows:
* If `keep_default_na` is True, and `na_values` are specified, `na_values`
is appended to the default NaN values used for parsing.
* If `keep_default_na` is True, and `na_values` are not specified, only
the default NaN values are used for parsing.
* If `keep_default_na` is False, and `na_values` are specified, only
the NaN values specified `na_values` are used for parsing.
* If `keep_default_na` is False, and `na_values` are not specified, no
strings will be parsed as NaN.
Note that if `na_filter` is passed in as False, the `keep_default_na` and
`na_values` parameters will be ignored.
na_filter : bool, default True
Detect missing value markers (empty strings and the value of na_values). In
data without any NAs, passing na_filter=False can improve the performance
of reading a large file.
verbose : bool, default False
Indicate number of NA values placed in non-numeric columns.
skip_blank_lines : bool, default True
If True, skip over blank lines rather than interpreting as NaN values.
parse_dates : bool or list of int or names or list of lists or dict, \
default False
The behavior is as follows:
* boolean. If True -> try parsing the index.
* list of int or names. e.g. If [1, 2, 3] -> try parsing columns 1, 2, 3
each as a separate date column.
* list of lists. e.g. If [[1, 3]] -> combine columns 1 and 3 and parse as
a single date column.
* dict, e.g. {{'foo' : [1, 3]}} -> parse columns 1, 3 as date and call
result 'foo'
If a column or index cannot be represented as an array of datetimes,
say because of an unparseable value or a mixture of timezones, the column
or index will be returned unaltered as an object data type. For
non-standard datetime parsing, use ``pd.to_datetime`` after
``pd.read_csv``. To parse an index or column with a mixture of timezones,
specify ``date_parser`` to be a partially-applied
:func:`pandas.to_datetime` with ``utc=True``. See
:ref:`io.csv.mixed_timezones` for more.
Note: A fast-path exists for iso8601-formatted dates.
infer_datetime_format : bool, default False
If True and `parse_dates` is enabled, pandas will attempt to infer the
format of the datetime strings in the columns, and if it can be inferred,
switch to a faster method of parsing them. In some cases this can increase
the parsing speed by 5-10x.
keep_date_col : bool, default False
If True and `parse_dates` specifies combining multiple columns then
keep the original columns.
date_parser : function, optional
Function to use for converting a sequence of string columns to an array of
datetime instances. The default uses ``dateutil.parser.parser`` to do the
conversion. Pandas will try to call `date_parser` in three different ways,
advancing to the next if an exception occurs: 1) Pass one or more arrays
(as defined by `parse_dates`) as arguments; 2) concatenate (row-wise) the
string values from the columns defined by `parse_dates` into a single array
and pass that; and 3) call `date_parser` once for each row using one or
more strings (corresponding to the columns defined by `parse_dates`) as
arguments.
dayfirst : bool, default False
DD/MM format dates, international and European format.
cache_dates : bool, default True
If True, use a cache of unique, converted dates to apply the datetime
conversion. May produce significant speed-up when parsing duplicate
date strings, especially ones with timezone offsets.
.. versionadded:: 0.25.0
iterator : bool, default False
Return TextFileReader object for iteration or getting chunks with
``get_chunk()``.
chunksize : int, optional
Return TextFileReader object for iteration.
See the `IO Tools docs
<https://pandas.pydata.org/pandas-docs/stable/io.html#io-chunking>`_
for more information on ``iterator`` and ``chunksize``.
compression : {{'infer', 'gzip', 'bz2', 'zip', 'xz', None}}, default 'infer'
For on-the-fly decompression of on-disk data. If 'infer' and
`filepath_or_buffer` is path-like, then detect compression from the
following extensions: '.gz', '.bz2', '.zip', or '.xz' (otherwise no
decompression). If using 'zip', the ZIP file must contain only one data
file to be read in. Set to None for no decompression.
thousands : str, optional
Thousands separator.
decimal : str, default '.'
Character to recognize as decimal point (e.g. use ',' for European data).
lineterminator : str (length 1), optional
Character to break file into lines. Only valid with C parser.
quotechar : str (length 1), optional
The character used to denote the start and end of a quoted item. Quoted
items can include the delimiter and it will be ignored.
quoting : int or csv.QUOTE_* instance, default 0
Control field quoting behavior per ``csv.QUOTE_*`` constants. Use one of
QUOTE_MINIMAL (0), QUOTE_ALL (1), QUOTE_NONNUMERIC (2) or QUOTE_NONE (3).
doublequote : bool, default ``True``
When quotechar is specified and quoting is not ``QUOTE_NONE``, indicate
whether or not to interpret two consecutive quotechar elements INSIDE a
field as a single ``quotechar`` element.
escapechar : str (length 1), optional
One-character string used to escape other characters.
comment : str, optional
Indicates remainder of line should not be parsed. If found at the beginning
of a line, the line will be ignored altogether. This parameter must be a
single character. Like empty lines (as long as ``skip_blank_lines=True``),
fully commented lines are ignored by the parameter `header` but not by
`skiprows`. For example, if ``comment='#'``, parsing
``#empty\\na,b,c\\n1,2,3`` with ``header=0`` will result in 'a,b,c' being
treated as the header.
encoding : str, optional
Encoding to use for UTF when reading/writing (ex. 'utf-8'). `List of Python
standard encodings
<https://docs.python.org/3/library/codecs.html#standard-encodings>`_ .
dialect : str or csv.Dialect, optional
If provided, this parameter will override values (default or not) for the
following parameters: `delimiter`, `doublequote`, `escapechar`,
`skipinitialspace`, `quotechar`, and `quoting`. If it is necessary to
override values, a ParserWarning will be issued. See csv.Dialect
documentation for more details.
error_bad_lines : bool, default True
Lines with too many fields (e.g. a csv line with too many commas) will by
default cause an exception to be raised, and no DataFrame will be returned.
If False, then these "bad lines" will dropped from the DataFrame that is
returned.
warn_bad_lines : bool, default True
If error_bad_lines is False, and warn_bad_lines is True, a warning for each
"bad line" will be output.
delim_whitespace : bool, default False
Specifies whether or not whitespace (e.g. ``' '`` or ``'\t'``) will be
used as the sep. Equivalent to setting ``sep='\\s+'``. If this option
is set to True, nothing should be passed in for the ``delimiter``
parameter.
low_memory : bool, default True
Internally process the file in chunks, resulting in lower memory use
while parsing, but possibly mixed type inference. To ensure no mixed
types either set False, or specify the type with the `dtype` parameter.
Note that the entire file is read into a single DataFrame regardless,
use the `chunksize` or `iterator` parameter to return the data in chunks.
(Only valid with C parser).
memory_map : bool, default False
If a filepath is provided for `filepath_or_buffer`, map the file object
directly onto memory and access the data directly from there. Using this
option can improve performance because there is no longer any I/O overhead.
float_precision : str, optional
Specifies which converter the C engine should use for floating-point
values. The options are `None` for the ordinary converter,
`high` for the high-precision converter, and `round_trip` for the
round-trip converter.
Returns
-------
DataFrame or TextParser
A comma-separated values (csv) file is returned as two-dimensional
data structure with labeled axes.
See Also
--------
DataFrame.to_csv : Write DataFrame to a comma-separated values (csv) file.
read_csv : Read a comma-separated values (csv) file into DataFrame.
read_fwf : Read a table of fixed-width formatted lines into DataFrame.
Examples
--------
>>> pd.{func_name}('data.csv') # doctest: +SKIP
"""
)
def _validate_integer(name, val, min_val=0):
"""
Checks whether the 'name' parameter for parsing is either
an integer OR float that can SAFELY be cast to an integer
without losing accuracy. Raises a ValueError if that is
not the case.
Parameters
----------
name : string
Parameter name (used for error reporting)
val : int or float
The value to check
min_val : int
Minimum allowed value (val < min_val will result in a ValueError)
"""
msg = f"'{name:s}' must be an integer >={min_val:d}"
if val is not None:
if is_float(val):
if int(val) != val:
raise ValueError(msg)
val = int(val)
elif not (is_integer(val) and val >= min_val):
raise ValueError(msg)
return val
def _validate_names(names):
"""
Raise ValueError if the `names` parameter contains duplicates or has an
invalid data type.
Parameters
----------
names : array-like or None
An array containing a list of the names used for the output DataFrame.
Raises
------
ValueError
If names are not unique or are not ordered (e.g. set).
"""
if names is not None:
if len(names) != len(set(names)):
raise ValueError("Duplicate names are not allowed.")
if not (
is_list_like(names, allow_sets=False) or isinstance(names, abc.KeysView)
):
raise ValueError("Names should be an ordered collection.")
def _read(filepath_or_buffer: FilePathOrBuffer, kwds):
"""Generic reader of line files."""
encoding = kwds.get("encoding", None)
if encoding is not None:
encoding = re.sub("_", "-", encoding).lower()
kwds["encoding"] = encoding
compression = kwds.get("compression", "infer")
compression = infer_compression(filepath_or_buffer, compression)
# TODO: get_filepath_or_buffer could return
# Union[FilePathOrBuffer, s3fs.S3File, gcsfs.GCSFile]
# though mypy handling of conditional imports is difficult.
# See https://github.com/python/mypy/issues/1297
fp_or_buf, _, compression, should_close = get_filepath_or_buffer(
filepath_or_buffer, encoding, compression
)
kwds["compression"] = compression
if kwds.get("date_parser", None) is not None:
if isinstance(kwds["parse_dates"], bool):
kwds["parse_dates"] = True
# Extract some of the arguments (pass chunksize on).
iterator = kwds.get("iterator", False)
chunksize = _validate_integer("chunksize", kwds.get("chunksize", None), 1)
nrows = kwds.get("nrows", None)
# Check for duplicates in names.
_validate_names(kwds.get("names", None))
# Create the parser.
parser = TextFileReader(fp_or_buf, **kwds)
if chunksize or iterator:
return parser
try:
data = parser.read(nrows)
finally:
parser.close()
if should_close:
try:
fp_or_buf.close()
except ValueError:
pass
return data
_parser_defaults = {
"delimiter": None,
"escapechar": None,
"quotechar": '"',
"quoting": csv.QUOTE_MINIMAL,
"doublequote": True,
"skipinitialspace": False,
"lineterminator": None,
"header": "infer",
"index_col": None,
"names": None,
"prefix": None,
"skiprows": None,
"skipfooter": 0,
"nrows": None,
"na_values": None,
"keep_default_na": True,
"true_values": None,
"false_values": None,
"converters": None,
"dtype": None,
"cache_dates": True,
"thousands": None,
"comment": None,
"decimal": ".",
# 'engine': 'c',
"parse_dates": False,
"keep_date_col": False,
"dayfirst": False,
"date_parser": None,
"usecols": None,
# 'iterator': False,
"chunksize": None,
"verbose": False,
"encoding": None,
"squeeze": False,
"compression": None,
"mangle_dupe_cols": True,
"infer_datetime_format": False,
"skip_blank_lines": True,
}
_c_parser_defaults = {
"delim_whitespace": False,
"na_filter": True,
"low_memory": True,
"memory_map": False,
"error_bad_lines": True,
"warn_bad_lines": True,
"float_precision": None,
}
_fwf_defaults = {"colspecs": "infer", "infer_nrows": 100, "widths": None}
_c_unsupported = {"skipfooter"}
_python_unsupported = {"low_memory", "float_precision"}
_deprecated_defaults: Dict[str, Any] = {}
_deprecated_args: Set[str] = set()
@Appender(
_doc_read_csv_and_table.format(
func_name="read_csv",
summary="Read a comma-separated values (csv) file into DataFrame.",
_default_sep="','",
)
)
def read_csv(
filepath_or_buffer: FilePathOrBuffer,
sep=",",
delimiter=None,
# Column and Index Locations and Names
header="infer",
names=None,
index_col=None,
usecols=None,
squeeze=False,
prefix=None,
mangle_dupe_cols=True,
# General Parsing Configuration
dtype=None,
engine=None,
converters=None,
true_values=None,
false_values=None,
skipinitialspace=False,
skiprows=None,
skipfooter=0,
nrows=None,
# NA and Missing Data Handling
na_values=None,
keep_default_na=True,
na_filter=True,
verbose=False,
skip_blank_lines=True,
# Datetime Handling
parse_dates=False,
infer_datetime_format=False,
keep_date_col=False,
date_parser=None,
dayfirst=False,
cache_dates=True,
# Iteration
iterator=False,
chunksize=None,
# Quoting, Compression, and File Format
compression="infer",
thousands=None,
decimal: str = ".",
lineterminator=None,
quotechar='"',
quoting=csv.QUOTE_MINIMAL,
doublequote=True,
escapechar=None,
comment=None,
encoding=None,
dialect=None,
# Error Handling
error_bad_lines=True,
warn_bad_lines=True,
# Internal
delim_whitespace=False,
low_memory=_c_parser_defaults["low_memory"],
memory_map=False,
float_precision=None,
):
# gh-23761
#
# When a dialect is passed, it overrides any of the overlapping
# parameters passed in directly. We don't want to warn if the
# default parameters were passed in (since it probably means
# that the user didn't pass them in explicitly in the first place).
#
# "delimiter" is the annoying corner case because we alias it to
# "sep" before doing comparison to the dialect values later on.
# Thus, we need a flag to indicate that we need to "override"
# the comparison to dialect values by checking if default values
# for BOTH "delimiter" and "sep" were provided.
default_sep = ","
if dialect is not None:
sep_override = delimiter is None and sep == default_sep
kwds = dict(sep_override=sep_override)
else:
kwds = dict()
# Alias sep -> delimiter.
if delimiter is None:
delimiter = sep
if delim_whitespace and delimiter != default_sep:
raise ValueError(
"Specified a delimiter with both sep and "
"delim_whitespace=True; you can only specify one."
)
if engine is not None:
engine_specified = True
else:
engine = "c"
engine_specified = False
kwds.update(
delimiter=delimiter,
engine=engine,
dialect=dialect,
compression=compression,
engine_specified=engine_specified,
doublequote=doublequote,
escapechar=escapechar,
quotechar=quotechar,
quoting=quoting,
skipinitialspace=skipinitialspace,
lineterminator=lineterminator,
header=header,
index_col=index_col,
names=names,
prefix=prefix,
skiprows=skiprows,
skipfooter=skipfooter,
na_values=na_values,
true_values=true_values,
false_values=false_values,
keep_default_na=keep_default_na,
thousands=thousands,
comment=comment,
decimal=decimal,
parse_dates=parse_dates,
keep_date_col=keep_date_col,
dayfirst=dayfirst,
date_parser=date_parser,
cache_dates=cache_dates,
nrows=nrows,
iterator=iterator,
chunksize=chunksize,
converters=converters,
dtype=dtype,
usecols=usecols,
verbose=verbose,
encoding=encoding,
squeeze=squeeze,
memory_map=memory_map,
float_precision=float_precision,
na_filter=na_filter,
delim_whitespace=delim_whitespace,
warn_bad_lines=warn_bad_lines,
error_bad_lines=error_bad_lines,
low_memory=low_memory,
mangle_dupe_cols=mangle_dupe_cols,
infer_datetime_format=infer_datetime_format,
skip_blank_lines=skip_blank_lines,
)
return _read(filepath_or_buffer, kwds)
@Appender(
_doc_read_csv_and_table.format(
func_name="read_table",
summary="Read general delimited file into DataFrame.",
_default_sep=r"'\\t' (tab-stop)",
)
)
def read_table(
filepath_or_buffer: FilePathOrBuffer,
sep="\t",
delimiter=None,
# Column and Index Locations and Names
header="infer",
names=None,
index_col=None,
usecols=None,
squeeze=False,
prefix=None,
mangle_dupe_cols=True,
# General Parsing Configuration
dtype=None,
engine=None,
converters=None,
true_values=None,
false_values=None,
skipinitialspace=False,
skiprows=None,
skipfooter=0,
nrows=None,
# NA and Missing Data Handling
na_values=None,
keep_default_na=True,
na_filter=True,
verbose=False,
skip_blank_lines=True,
# Datetime Handling
parse_dates=False,
infer_datetime_format=False,
keep_date_col=False,
date_parser=None,
dayfirst=False,
cache_dates=True,
# Iteration
iterator=False,
chunksize=None,
# Quoting, Compression, and File Format
compression="infer",
thousands=None,
decimal: str = ".",
lineterminator=None,
quotechar='"',
quoting=csv.QUOTE_MINIMAL,
doublequote=True,
escapechar=None,
comment=None,
encoding=None,
dialect=None,
# Error Handling
error_bad_lines=True,
warn_bad_lines=True,
# Internal
delim_whitespace=False,
low_memory=_c_parser_defaults["low_memory"],
memory_map=False,
float_precision=None,
):
# TODO: validation duplicated in read_csv
if delim_whitespace and (delimiter is not None or sep != "\t"):
raise ValueError(
"Specified a delimiter with both sep and "
"delim_whitespace=True; you can only specify one."
)
if delim_whitespace:
# In this case sep is not used so we set it to the read_csv
# default to avoid a ValueError
sep = ","
return read_csv(**locals())
def read_fwf(
filepath_or_buffer: FilePathOrBuffer,
colspecs="infer",
widths=None,
infer_nrows=100,
**kwds,
):
r"""
Read a table of fixed-width formatted lines into DataFrame.
Also supports optionally iterating or breaking of the file
into chunks.
Additional help can be found in the `online docs for IO Tools
<https://pandas.pydata.org/pandas-docs/stable/user_guide/io.html>`_.
Parameters
----------
filepath_or_buffer : str, path object or file-like object
Any valid string path is acceptable. The string could be a URL. Valid
URL schemes include http, ftp, s3, and file. For file URLs, a host is
expected. A local file could be:
``file://localhost/path/to/table.csv``.
If you want to pass in a path object, pandas accepts any
``os.PathLike``.
By file-like object, we refer to objects with a ``read()`` method,
such as a file handler (e.g. via builtin ``open`` function)
or ``StringIO``.
colspecs : list of tuple (int, int) or 'infer'. optional
A list of tuples giving the extents of the fixed-width
fields of each line as half-open intervals (i.e., [from, to[ ).
String value 'infer' can be used to instruct the parser to try
detecting the column specifications from the first 100 rows of
the data which are not being skipped via skiprows (default='infer').
widths : list of int, optional
A list of field widths which can be used instead of 'colspecs' if
the intervals are contiguous.
infer_nrows : int, default 100
The number of rows to consider when letting the parser determine the
`colspecs`.
.. versionadded:: 0.24.0
**kwds : optional
Optional keyword arguments can be passed to ``TextFileReader``.
Returns
-------
DataFrame or TextParser
A comma-separated values (csv) file is returned as two-dimensional
data structure with labeled axes.
See Also
--------
DataFrame.to_csv : Write DataFrame to a comma-separated values (csv) file.
read_csv : Read a comma-separated values (csv) file into DataFrame.
Examples
--------
>>> pd.read_fwf('data.csv') # doctest: +SKIP
"""
# Check input arguments.
if colspecs is None and widths is None:
raise ValueError("Must specify either colspecs or widths")
elif colspecs not in (None, "infer") and widths is not None:
raise ValueError("You must specify only one of 'widths' and 'colspecs'")
# Compute 'colspecs' from 'widths', if specified.
if widths is not None:
colspecs, col = [], 0
for w in widths:
colspecs.append((col, col + w))
col += w
kwds["colspecs"] = colspecs
kwds["infer_nrows"] = infer_nrows
kwds["engine"] = "python-fwf"
return _read(filepath_or_buffer, kwds)
class TextFileReader(abc.Iterator):
"""
Passed dialect overrides any of the related parser options
"""
def __init__(self, f, engine=None, **kwds):
self.f = f
if engine is not None:
engine_specified = True
else:
engine = "python"
engine_specified = False
self._engine_specified = kwds.get("engine_specified", engine_specified)
if kwds.get("dialect") is not None:
dialect = kwds["dialect"]
if dialect in csv.list_dialects():
dialect = csv.get_dialect(dialect)
# Any valid dialect should have these attributes.
# If any are missing, we will raise automatically.
for param in (
"delimiter",
"doublequote",
"escapechar",
"skipinitialspace",
"quotechar",
"quoting",
):
try:
dialect_val = getattr(dialect, param)
except AttributeError as err:
raise ValueError(
f"Invalid dialect {kwds['dialect']} provided"
) from err
parser_default = _parser_defaults[param]
provided = kwds.get(param, parser_default)
# Messages for conflicting values between the dialect
# instance and the actual parameters provided.
conflict_msgs = []
# Don't warn if the default parameter was passed in,
# even if it conflicts with the dialect (gh-23761).
if provided != parser_default and provided != dialect_val:
msg = (
f"Conflicting values for '{param}': '{provided}' was "
f"provided, but the dialect specifies '{dialect_val}'. "
"Using the dialect-specified value."
)
# Annoying corner case for not warning about
# conflicts between dialect and delimiter parameter.
# Refer to the outer "_read_" function for more info.
if not (param == "delimiter" and kwds.pop("sep_override", False)):
conflict_msgs.append(msg)
if conflict_msgs:
warnings.warn(
"\n\n".join(conflict_msgs), ParserWarning, stacklevel=2
)
kwds[param] = dialect_val
if kwds.get("skipfooter"):
if kwds.get("iterator") or kwds.get("chunksize"):
raise ValueError("'skipfooter' not supported for 'iteration'")
if kwds.get("nrows"):
raise ValueError("'skipfooter' not supported with 'nrows'")
if kwds.get("header", "infer") == "infer":
kwds["header"] = 0 if kwds.get("names") is None else None
self.orig_options = kwds
# miscellanea
self.engine = engine
self._engine = None
self._currow = 0
options = self._get_options_with_defaults(engine)
self.chunksize = options.pop("chunksize", None)
self.nrows = options.pop("nrows", None)
self.squeeze = options.pop("squeeze", False)
# might mutate self.engine
self.engine = self._check_file_or_buffer(f, engine)
self.options, self.engine = self._clean_options(options, engine)
if "has_index_names" in kwds:
self.options["has_index_names"] = kwds["has_index_names"]
self._make_engine(self.engine)
def close(self):
self._engine.close()
def _get_options_with_defaults(self, engine):
kwds = self.orig_options
options = {}
for argname, default in _parser_defaults.items():
value = kwds.get(argname, default)
# see gh-12935
if argname == "mangle_dupe_cols" and not value:
raise ValueError("Setting mangle_dupe_cols=False is not supported yet")
else:
options[argname] = value
for argname, default in _c_parser_defaults.items():
if argname in kwds:
value = kwds[argname]
if engine != "c" and value != default:
if "python" in engine and argname not in _python_unsupported:
pass
elif value == _deprecated_defaults.get(argname, default):
pass
else:
raise ValueError(
f"The {repr(argname)} option is not supported with the "
f"{repr(engine)} engine"
)
else:
value = _deprecated_defaults.get(argname, default)
options[argname] = value
if engine == "python-fwf":
for argname, default in _fwf_defaults.items():
options[argname] = kwds.get(argname, default)
return options
def _check_file_or_buffer(self, f, engine):
# see gh-16530
if is_file_like(f):
next_attr = "__next__"
# The C engine doesn't need the file-like to have the "next" or
# "__next__" attribute. However, the Python engine explicitly calls
# "next(...)" when iterating through such an object, meaning it
# needs to have that attribute ("next" for Python 2.x, "__next__"
# for Python 3.x)
if engine != "c" and not hasattr(f, next_attr):
msg = "The 'python' engine cannot iterate through this file buffer."
raise ValueError(msg)
return engine
def _clean_options(self, options, engine):
result = options.copy()
engine_specified = self._engine_specified
fallback_reason = None
sep = options["delimiter"]
delim_whitespace = options["delim_whitespace"]
# C engine not supported yet
if engine == "c":
if options["skipfooter"] > 0:
fallback_reason = "the 'c' engine does not support skipfooter"
engine = "python"
encoding = sys.getfilesystemencoding() or "utf-8"
if sep is None and not delim_whitespace:
if engine == "c":
fallback_reason = (
"the 'c' engine does not support "
"sep=None with delim_whitespace=False"
)
engine = "python"
elif sep is not None and len(sep) > 1:
if engine == "c" and sep == r"\s+":
result["delim_whitespace"] = True
del result["delimiter"]
elif engine not in ("python", "python-fwf"):
# wait until regex engine integrated
fallback_reason = (
"the 'c' engine does not support "
"regex separators (separators > 1 char and "
r"different from '\s+' are interpreted as regex)"
)
engine = "python"
elif delim_whitespace:
if "python" in engine:
result["delimiter"] = r"\s+"
elif sep is not None:
encodeable = True
try:
if len(sep.encode(encoding)) > 1:
encodeable = False
except UnicodeDecodeError:
encodeable = False
if not encodeable and engine not in ("python", "python-fwf"):
fallback_reason = (
f"the separator encoded in {encoding} "
"is > 1 char long, and the 'c' engine "
"does not support such separators"
)
engine = "python"
quotechar = options["quotechar"]
if quotechar is not None and isinstance(quotechar, (str, bytes)):
if (
len(quotechar) == 1
and ord(quotechar) > 127
and engine not in ("python", "python-fwf")
):
fallback_reason = (
"ord(quotechar) > 127, meaning the "
"quotechar is larger than one byte, "
"and the 'c' engine does not support such quotechars"
)
engine = "python"
if fallback_reason and engine_specified:
raise ValueError(fallback_reason)
if engine == "c":
for arg in _c_unsupported:
del result[arg]
if "python" in engine:
for arg in _python_unsupported:
if fallback_reason and result[arg] != _c_parser_defaults[arg]:
raise ValueError(
"Falling back to the 'python' engine because "
f"{fallback_reason}, but this causes {repr(arg)} to be "
"ignored as it is not supported by the 'python' engine."
)
del result[arg]
if fallback_reason:
warnings.warn(
(
"Falling back to the 'python' engine because "
f"{fallback_reason}; you can avoid this warning by specifying "
"engine='python'."
),
ParserWarning,
stacklevel=5,
)
index_col = options["index_col"]
names = options["names"]
converters = options["converters"]
na_values = options["na_values"]
skiprows = options["skiprows"]
validate_header_arg(options["header"])
depr_warning = ""
for arg in _deprecated_args:
parser_default = _c_parser_defaults[arg]
depr_default = _deprecated_defaults[arg]
msg = (
f"The {repr(arg)} argument has been deprecated and will be "
"removed in a future version."
)
if result.get(arg, depr_default) != depr_default:
depr_warning += msg + "\n\n"
else:
result[arg] = parser_default
if depr_warning != "":
warnings.warn(depr_warning, FutureWarning, stacklevel=2)
if index_col is True:
raise ValueError("The value of index_col couldn't be 'True'")
if _is_index_col(index_col):
if not isinstance(index_col, (list, tuple, np.ndarray)):
index_col = [index_col]
result["index_col"] = index_col
names = list(names) if names is not None else names
# type conversion-related
if converters is not None:
if not isinstance(converters, dict):
raise TypeError(
"Type converters must be a dict or subclass, "
f"input was a {type(converters).__name__}"
)
else:
converters = {}
# Converting values to NA
keep_default_na = options["keep_default_na"]
na_values, na_fvalues = _clean_na_values(na_values, keep_default_na)
# handle skiprows; this is internally handled by the
# c-engine, so only need for python parsers
if engine != "c":
if is_integer(skiprows):
skiprows = list(range(skiprows))
if skiprows is None:
skiprows = set()
elif not callable(skiprows):
skiprows = set(skiprows)
# put stuff back
result["names"] = names
result["converters"] = converters
result["na_values"] = na_values
result["na_fvalues"] = na_fvalues
result["skiprows"] = skiprows
return result, engine
def __next__(self):
try:
return self.get_chunk()
except StopIteration:
self.close()
raise
def _make_engine(self, engine="c"):
if engine == "c":
self._engine = CParserWrapper(self.f, **self.options)
else:
if engine == "python":
klass = PythonParser
elif engine == "python-fwf":
klass = FixedWidthFieldParser
else:
raise ValueError(
f"Unknown engine: {engine} (valid options "
'are "c", "python", or "python-fwf")'
)
self._engine = klass(self.f, **self.options)
def _failover_to_python(self):
raise AbstractMethodError(self)
def read(self, nrows=None):
nrows = _validate_integer("nrows", nrows)
ret = self._engine.read(nrows)
# May alter columns / col_dict
index, columns, col_dict = self._create_index(ret)
if index is None:
if col_dict:
# Any column is actually fine:
new_rows = len(next(iter(col_dict.values())))
index = RangeIndex(self._currow, self._currow + new_rows)
else:
new_rows = 0
else:
new_rows = len(index)
df = DataFrame(col_dict, columns=columns, index=index)
self._currow += new_rows
if self.squeeze and len(df.columns) == 1:
return df[df.columns[0]].copy()
return df
def _create_index(self, ret):
index, columns, col_dict = ret
return index, columns, col_dict
def get_chunk(self, size=None):
if size is None:
size = self.chunksize
if self.nrows is not None:
if self._currow >= self.nrows:
raise StopIteration
size = min(size, self.nrows - self._currow)
return self.read(nrows=size)
def _is_index_col(col):
return col is not None and col is not False
def _is_potential_multi_index(
columns, index_col: Optional[Union[bool, Sequence[int]]] = None
):
"""
Check whether or not the `columns` parameter
could be converted into a MultiIndex.
Parameters
----------
columns : array-like
Object which may or may not be convertible into a MultiIndex
index_col : None, bool or list, optional
Column or columns to use as the (possibly hierarchical) index
Returns
-------
boolean : Whether or not columns could become a MultiIndex
"""
if index_col is None or isinstance(index_col, bool):
index_col = []
return (
len(columns)
and not isinstance(columns, MultiIndex)
and all(isinstance(c, tuple) for c in columns if c not in list(index_col))
)
def _evaluate_usecols(usecols, names):
"""
Check whether or not the 'usecols' parameter
is a callable. If so, enumerates the 'names'
parameter and returns a set of indices for
each entry in 'names' that evaluates to True.
If not a callable, returns 'usecols'.
"""
if callable(usecols):
return {i for i, name in enumerate(names) if usecols(name)}
return usecols
def _validate_usecols_names(usecols, names):
"""
Validates that all usecols are present in a given
list of names. If not, raise a ValueError that
shows what usecols are missing.
Parameters
----------
usecols : iterable of usecols
The columns to validate are present in names.
names : iterable of names
The column names to check against.
Returns
-------
usecols : iterable of usecols
The `usecols` parameter if the validation succeeds.
Raises
------
ValueError : Columns were missing. Error message will list them.
"""
missing = [c for c in usecols if c not in names]
if len(missing) > 0:
raise ValueError(
f"Usecols do not match columns, columns expected but not found: {missing}"
)
return usecols
def _validate_skipfooter_arg(skipfooter):
"""
Validate the 'skipfooter' parameter.
Checks whether 'skipfooter' is a non-negative integer.
Raises a ValueError if that is not the case.
Parameters
----------
skipfooter : non-negative integer
The number of rows to skip at the end of the file.
Returns
-------
validated_skipfooter : non-negative integer
The original input if the validation succeeds.
Raises
------
ValueError : 'skipfooter' was not a non-negative integer.
"""
if not is_integer(skipfooter):
raise ValueError("skipfooter must be an integer")
if skipfooter < 0:
raise ValueError("skipfooter cannot be negative")
return skipfooter
def _validate_usecols_arg(usecols):
"""
Validate the 'usecols' parameter.
Checks whether or not the 'usecols' parameter contains all integers
(column selection by index), strings (column by name) or is a callable.
Raises a ValueError if that is not the case.
Parameters
----------
usecols : list-like, callable, or None
List of columns to use when parsing or a callable that can be used
to filter a list of table columns.
Returns
-------
usecols_tuple : tuple
A tuple of (verified_usecols, usecols_dtype).
'verified_usecols' is either a set if an array-like is passed in or
'usecols' if a callable or None is passed in.
'usecols_dtype` is the inferred dtype of 'usecols' if an array-like
is passed in or None if a callable or None is passed in.
"""
msg = (
"'usecols' must either be list-like of all strings, all unicode, "
"all integers or a callable."
)
if usecols is not None:
if callable(usecols):
return usecols, None
if not is_list_like(usecols):
# see gh-20529
#
# Ensure it is iterable container but not string.
raise ValueError(msg)
usecols_dtype = lib.infer_dtype(usecols, skipna=False)
if usecols_dtype not in ("empty", "integer", "string"):
raise ValueError(msg)
usecols = set(usecols)
return usecols, usecols_dtype
return usecols, None
def _validate_parse_dates_arg(parse_dates):
"""
Check whether or not the 'parse_dates' parameter
is a non-boolean scalar. Raises a ValueError if
that is the case.
"""
msg = (
"Only booleans, lists, and dictionaries are accepted "
"for the 'parse_dates' parameter"
)
if parse_dates is not None:
if is_scalar(parse_dates):
if not lib.is_bool(parse_dates):
raise TypeError(msg)
elif not isinstance(parse_dates, (list, dict)):
raise TypeError(msg)
return parse_dates
class ParserBase:
def __init__(self, kwds):
self.names = kwds.get("names")
self.orig_names = None
self.prefix = kwds.pop("prefix", None)
self.index_col = kwds.get("index_col", None)
self.unnamed_cols = set()
self.index_names = None
self.col_names = None
self.parse_dates = _validate_parse_dates_arg(kwds.pop("parse_dates", False))
self.date_parser = kwds.pop("date_parser", None)
self.dayfirst = kwds.pop("dayfirst", False)
self.keep_date_col = kwds.pop("keep_date_col", False)
self.na_values = kwds.get("na_values")
self.na_fvalues = kwds.get("na_fvalues")
self.na_filter = kwds.get("na_filter", False)
self.keep_default_na = kwds.get("keep_default_na", True)
self.true_values = kwds.get("true_values")
self.false_values = kwds.get("false_values")
self.mangle_dupe_cols = kwds.get("mangle_dupe_cols", True)
self.infer_datetime_format = kwds.pop("infer_datetime_format", False)
self.cache_dates = kwds.pop("cache_dates", True)
self._date_conv = _make_date_converter(
date_parser=self.date_parser,
dayfirst=self.dayfirst,
infer_datetime_format=self.infer_datetime_format,
cache_dates=self.cache_dates,
)
# validate header options for mi
self.header = kwds.get("header")
if isinstance(self.header, (list, tuple, np.ndarray)):
if not all(map(is_integer, self.header)):
raise ValueError("header must be integer or list of integers")
if any(i < 0 for i in self.header):
raise ValueError(
"cannot specify multi-index header with negative integers"
)
if kwds.get("usecols"):
raise ValueError(
"cannot specify usecols when specifying a multi-index header"
)
if kwds.get("names"):
raise ValueError(
"cannot specify names when specifying a multi-index header"
)
# validate index_col that only contains integers
if self.index_col is not None:
is_sequence = isinstance(self.index_col, (list, tuple, np.ndarray))
if not (
is_sequence
and all(map(is_integer, self.index_col))
or is_integer(self.index_col)
):
raise ValueError(
"index_col must only contain row numbers "
"when specifying a multi-index header"
)
elif self.header is not None:
# GH 27394
if self.prefix is not None:
raise ValueError(
"Argument prefix must be None if argument header is not None"
)
# GH 16338
elif not is_integer(self.header):
raise ValueError("header must be integer or list of integers")
# GH 27779
elif self.header < 0:
raise ValueError(
"Passing negative integer to header is invalid. "
"For no header, use header=None instead"
)
self._name_processed = False
self._first_chunk = True
# GH 13932
# keep references to file handles opened by the parser itself
self.handles = []
def _validate_parse_dates_presence(self, columns: List[str]) -> None:
"""
Check if parse_dates are in columns.
If user has provided names for parse_dates, check if those columns
are available.
Parameters
----------
columns : list
List of names of the dataframe.
Raises
------
ValueError
If column to parse_date is not in dataframe.
"""
cols_needed: Iterable
if is_dict_like(self.parse_dates):
cols_needed = itertools.chain(*self.parse_dates.values())
elif is_list_like(self.parse_dates):
# a column in parse_dates could be represented
# ColReference = Union[int, str]
# DateGroups = List[ColReference]
# ParseDates = Union[DateGroups, List[DateGroups],
# Dict[ColReference, DateGroups]]
cols_needed = itertools.chain.from_iterable(
col if is_list_like(col) else [col] for col in self.parse_dates
)
else:
cols_needed = []
# get only columns that are references using names (str), not by index
missing_cols = ", ".join(
sorted(
{
col
for col in cols_needed
if isinstance(col, str) and col not in columns
}
)
)
if missing_cols:
raise ValueError(
f"Missing column provided to 'parse_dates': '{missing_cols}'"
)
def close(self):
for f in self.handles:
f.close()
@property
def _has_complex_date_col(self):
return isinstance(self.parse_dates, dict) or (
isinstance(self.parse_dates, list)
and len(self.parse_dates) > 0
and isinstance(self.parse_dates[0], list)
)
def _should_parse_dates(self, i):
if isinstance(self.parse_dates, bool):
return self.parse_dates
else:
if self.index_names is not None:
name = self.index_names[i]
else:
name = None
j = self.index_col[i]
if is_scalar(self.parse_dates):
return (j == self.parse_dates) or (
name is not None and name == self.parse_dates
)
else:
return (j in self.parse_dates) or (
name is not None and name in self.parse_dates
)
def _extract_multi_indexer_columns(
self, header, index_names, col_names, passed_names=False
):
"""
extract and return the names, index_names, col_names
header is a list-of-lists returned from the parsers
"""
if len(header) < 2:
return header[0], index_names, col_names, passed_names
# the names are the tuples of the header that are not the index cols
# 0 is the name of the index, assuming index_col is a list of column
# numbers
ic = self.index_col
if ic is None:
ic = []
if not isinstance(ic, (list, tuple, np.ndarray)):
ic = [ic]
sic = set(ic)
# clean the index_names
index_names = header.pop(-1)
index_names, names, index_col = _clean_index_names(
index_names, self.index_col, self.unnamed_cols
)
# extract the columns
field_count = len(header[0])
def extract(r):
return tuple(r[i] for i in range(field_count) if i not in sic)
columns = list(zip(*(extract(r) for r in header)))
names = ic + columns
# If we find unnamed columns all in a single
# level, then our header was too long.
for n in range(len(columns[0])):
if all(ensure_str(col[n]) in self.unnamed_cols for col in columns):
header = ",".join(str(x) for x in self.header)
raise ParserError(
f"Passed header=[{header}] are too many rows "
"for this multi_index of columns"
)
# Clean the column names (if we have an index_col).
if len(ic):
col_names = [
r[0] if ((r[0] is not None) and r[0] not in self.unnamed_cols) else None
for r in header
]
else:
col_names = [None] * len(header)
passed_names = True
return names, index_names, col_names, passed_names
def _maybe_dedup_names(self, names):
# see gh-7160 and gh-9424: this helps to provide
# immediate alleviation of the duplicate names
# issue and appears to be satisfactory to users,
# but ultimately, not needing to butcher the names
# would be nice!
if self.mangle_dupe_cols:
names = list(names) # so we can index
counts = defaultdict(int)
is_potential_mi = _is_potential_multi_index(names, self.index_col)
for i, col in enumerate(names):
cur_count = counts[col]
while cur_count > 0:
counts[col] = cur_count + 1
if is_potential_mi:
col = col[:-1] + (f"{col[-1]}.{cur_count}",)
else:
col = f"{col}.{cur_count}"
cur_count = counts[col]
names[i] = col
counts[col] = cur_count + 1
return names
def _maybe_make_multi_index_columns(self, columns, col_names=None):
# possibly create a column mi here
if _is_potential_multi_index(columns):
columns = MultiIndex.from_tuples(columns, names=col_names)
return columns
def _make_index(self, data, alldata, columns, indexnamerow=False):
if not _is_index_col(self.index_col) or not self.index_col:
index = None
elif not self._has_complex_date_col:
index = self._get_simple_index(alldata, columns)
index = self._agg_index(index)
elif self._has_complex_date_col:
if not self._name_processed:
(self.index_names, _, self.index_col) = _clean_index_names(
list(columns), self.index_col, self.unnamed_cols
)
self._name_processed = True
index = self._get_complex_date_index(data, columns)
index = self._agg_index(index, try_parse_dates=False)
# add names for the index
if indexnamerow:
coffset = len(indexnamerow) - len(columns)
index = index.set_names(indexnamerow[:coffset])
# maybe create a mi on the columns
columns = self._maybe_make_multi_index_columns(columns, self.col_names)
return index, columns
_implicit_index = False
def _get_simple_index(self, data, columns):
def ix(col):
if not isinstance(col, str):
return col
raise ValueError(f"Index {col} invalid")
to_remove = []
index = []
for idx in self.index_col:
i = ix(idx)
to_remove.append(i)
index.append(data[i])
# remove index items from content and columns, don't pop in
# loop
for i in sorted(to_remove, reverse=True):
data.pop(i)
if not self._implicit_index:
columns.pop(i)
return index
def _get_complex_date_index(self, data, col_names):
def _get_name(icol):
if isinstance(icol, str):
return icol
if col_names is None:
raise ValueError(f"Must supply column order to use {icol!s} as index")
for i, c in enumerate(col_names):
if i == icol:
return c
to_remove = []
index = []
for idx in self.index_col:
name = _get_name(idx)
to_remove.append(name)
index.append(data[name])
# remove index items from content and columns, don't pop in
# loop
for c in sorted(to_remove, reverse=True):
data.pop(c)
col_names.remove(c)
return index
def _agg_index(self, index, try_parse_dates=True):
arrays = []
for i, arr in enumerate(index):
if try_parse_dates and self._should_parse_dates(i):
arr = self._date_conv(arr)
if self.na_filter:
col_na_values = self.na_values
col_na_fvalues = self.na_fvalues
else:
col_na_values = set()
col_na_fvalues = set()
if isinstance(self.na_values, dict):
col_name = self.index_names[i]
if col_name is not None:
col_na_values, col_na_fvalues = _get_na_values(
col_name, self.na_values, self.na_fvalues, self.keep_default_na
)
arr, _ = self._infer_types(arr, col_na_values | col_na_fvalues)
arrays.append(arr)
names = self.index_names
index = ensure_index_from_sequences(arrays, names)
return index
def _convert_to_ndarrays(
self, dct, na_values, na_fvalues, verbose=False, converters=None, dtypes=None
):
result = {}
for c, values in dct.items():
conv_f = None if converters is None else converters.get(c, None)
if isinstance(dtypes, dict):
cast_type = dtypes.get(c, None)
else:
# single dtype or None
cast_type = dtypes
if self.na_filter:
col_na_values, col_na_fvalues = _get_na_values(
c, na_values, na_fvalues, self.keep_default_na
)
else:
col_na_values, col_na_fvalues = set(), set()
if conv_f is not None:
# conv_f applied to data before inference
if cast_type is not None:
warnings.warn(
(
"Both a converter and dtype were specified "
f"for column {c} - only the converter will be used"
),
ParserWarning,
stacklevel=7,
)
try:
values = lib.map_infer(values, conv_f)
except ValueError:
mask = algorithms.isin(values, list(na_values)).view(np.uint8)
values = lib.map_infer_mask(values, conv_f, mask)
cvals, na_count = self._infer_types(
values, set(col_na_values) | col_na_fvalues, try_num_bool=False
)
else:
is_str_or_ea_dtype = is_string_dtype(
cast_type
) or is_extension_array_dtype(cast_type)
# skip inference if specified dtype is object
# or casting to an EA
try_num_bool = not (cast_type and is_str_or_ea_dtype)
# general type inference and conversion
cvals, na_count = self._infer_types(
values, set(col_na_values) | col_na_fvalues, try_num_bool
)
# type specified in dtype param or cast_type is an EA
if cast_type and (
not is_dtype_equal(cvals, cast_type)
or is_extension_array_dtype(cast_type)
):
try:
if (
is_bool_dtype(cast_type)
and not is_categorical_dtype(cast_type)
and na_count > 0
):
raise ValueError(f"Bool column has NA values in column {c}")
except (AttributeError, TypeError):
# invalid input to is_bool_dtype
pass
cvals = self._cast_types(cvals, cast_type, c)
result[c] = cvals
if verbose and na_count:
print(f"Filled {na_count} NA values in column {c!s}")
return result
def _infer_types(self, values, na_values, try_num_bool=True):
"""
Infer types of values, possibly casting
Parameters
----------
values : ndarray
na_values : set
try_num_bool : bool, default try
try to cast values to numeric (first preference) or boolean
Returns
-------
converted : ndarray
na_count : int
"""
na_count = 0
if issubclass(values.dtype.type, (np.number, np.bool_)):
mask = algorithms.isin(values, list(na_values))
na_count = mask.sum()
if na_count > 0:
if is_integer_dtype(values):
values = values.astype(np.float64)
np.putmask(values, mask, np.nan)
return values, na_count
if try_num_bool and is_object_dtype(values.dtype):
# exclude e.g DatetimeIndex here
try:
result = lib.maybe_convert_numeric(values, na_values, False)
except (ValueError, TypeError):
# e.g. encountering datetime string gets ValueError
# TypeError can be raised in floatify
result = values
na_count = parsers.sanitize_objects(result, na_values, False)
else:
na_count = isna(result).sum()
else:
result = values
if values.dtype == np.object_:
na_count = parsers.sanitize_objects(values, na_values, False)
if result.dtype == np.object_ and try_num_bool:
result = libops.maybe_convert_bool(
np.asarray(values),
true_values=self.true_values,
false_values=self.false_values,
)
return result, na_count
def _cast_types(self, values, cast_type, column):
"""
Cast values to specified type
Parameters
----------
values : ndarray
cast_type : string or np.dtype
dtype to cast values to
column : string
column name - used only for error reporting
Returns
-------
converted : ndarray
"""
if is_categorical_dtype(cast_type):
known_cats = (
isinstance(cast_type, CategoricalDtype)
and cast_type.categories is not None
)
if not is_object_dtype(values) and not known_cats:
# TODO: this is for consistency with
# c-parser which parses all categories
# as strings
values = astype_nansafe(values, str)
cats = Index(values).unique().dropna()
values = Categorical._from_inferred_categories(
cats, cats.get_indexer(values), cast_type, true_values=self.true_values
)
# use the EA's implementation of casting
elif is_extension_array_dtype(cast_type):
# ensure cast_type is an actual dtype and not a string
cast_type = pandas_dtype(cast_type)
array_type = cast_type.construct_array_type()
try:
return array_type._from_sequence_of_strings(values, dtype=cast_type)
except NotImplementedError as err:
raise NotImplementedError(
f"Extension Array: {array_type} must implement "
"_from_sequence_of_strings in order to be used in parser methods"
) from err
else:
try:
values = astype_nansafe(values, cast_type, copy=True, skipna=True)
except ValueError as err:
raise ValueError(
f"Unable to convert column {column} to type {cast_type}"
) from err
return values
def _do_date_conversions(self, names, data):
# returns data, columns
if self.parse_dates is not None:
data, names = _process_date_conversion(
data,
self._date_conv,
self.parse_dates,
self.index_col,
self.index_names,
names,
keep_date_col=self.keep_date_col,
)
return names, data
class CParserWrapper(ParserBase):
"""
"""
def __init__(self, src, **kwds):
self.kwds = kwds
kwds = kwds.copy()
ParserBase.__init__(self, kwds)
encoding = kwds.get("encoding")
if kwds.get("compression") is None and encoding:
if isinstance(src, str):
src = open(src, "rb")
self.handles.append(src)
# Handle the file object with universal line mode enabled.
# We will handle the newline character ourselves later on.
if hasattr(src, "read") and not hasattr(src, "encoding"):
src = TextIOWrapper(src, encoding=encoding, newline="")
kwds["encoding"] = "utf-8"
# #2442
kwds["allow_leading_cols"] = self.index_col is not False
# GH20529, validate usecol arg before TextReader
self.usecols, self.usecols_dtype = _validate_usecols_arg(kwds["usecols"])
kwds["usecols"] = self.usecols
self._reader = parsers.TextReader(src, **kwds)
self.unnamed_cols = self._reader.unnamed_cols
passed_names = self.names is None
if self._reader.header is None:
self.names = None
else:
if len(self._reader.header) > 1:
# we have a multi index in the columns
(
self.names,
self.index_names,
self.col_names,
passed_names,
) = self._extract_multi_indexer_columns(
self._reader.header, self.index_names, self.col_names, passed_names
)
else:
self.names = list(self._reader.header[0])
if self.names is None:
if self.prefix:
self.names = [
f"{self.prefix}{i}" for i in range(self._reader.table_width)
]
else:
self.names = list(range(self._reader.table_width))
# gh-9755
#
# need to set orig_names here first
# so that proper indexing can be done
# with _set_noconvert_columns
#
# once names has been filtered, we will
# then set orig_names again to names
self.orig_names = self.names[:]
if self.usecols:
usecols = _evaluate_usecols(self.usecols, self.orig_names)
# GH 14671
if self.usecols_dtype == "string" and not set(usecols).issubset(
self.orig_names
):
_validate_usecols_names(usecols, self.orig_names)
if len(self.names) > len(usecols):
self.names = [
n
for i, n in enumerate(self.names)
if (i in usecols or n in usecols)
]
if len(self.names) < len(usecols):
_validate_usecols_names(usecols, self.names)
self._validate_parse_dates_presence(self.names)
self._set_noconvert_columns()
self.orig_names = self.names
if not self._has_complex_date_col:
if self._reader.leading_cols == 0 and _is_index_col(self.index_col):
self._name_processed = True
(index_names, self.names, self.index_col) = _clean_index_names(
self.names, self.index_col, self.unnamed_cols
)
if self.index_names is None:
self.index_names = index_names
if self._reader.header is None and not passed_names:
self.index_names = [None] * len(self.index_names)
self._implicit_index = self._reader.leading_cols > 0
def close(self):
for f in self.handles:
f.close()
# close additional handles opened by C parser (for compression)
try:
self._reader.close()
except ValueError:
pass
def _set_noconvert_columns(self):
"""
Set the columns that should not undergo dtype conversions.
Currently, any column that is involved with date parsing will not
undergo such conversions.
"""
names = self.orig_names
if self.usecols_dtype == "integer":
# A set of integers will be converted to a list in
# the correct order every single time.
usecols = list(self.usecols)
usecols.sort()
elif callable(self.usecols) or self.usecols_dtype not in ("empty", None):
# The names attribute should have the correct columns
# in the proper order for indexing with parse_dates.
usecols = self.names[:]
else:
# Usecols is empty.
usecols = None
def _set(x):
if usecols is not None and is_integer(x):
x = usecols[x]
if not is_integer(x):
x = names.index(x)
self._reader.set_noconvert(x)
if isinstance(self.parse_dates, list):
for val in self.parse_dates:
if isinstance(val, list):
for k in val:
_set(k)
else:
_set(val)
elif isinstance(self.parse_dates, dict):
for val in self.parse_dates.values():
if isinstance(val, list):
for k in val:
_set(k)
else:
_set(val)
elif self.parse_dates:
if isinstance(self.index_col, list):
for k in self.index_col:
_set(k)
elif self.index_col is not None:
_set(self.index_col)
def set_error_bad_lines(self, status):
self._reader.set_error_bad_lines(int(status))
def read(self, nrows=None):
try:
data = self._reader.read(nrows)
except StopIteration:
if self._first_chunk:
self._first_chunk = False
names = self._maybe_dedup_names(self.orig_names)
index, columns, col_dict = _get_empty_meta(
names,
self.index_col,
self.index_names,
dtype=self.kwds.get("dtype"),
)
columns = self._maybe_make_multi_index_columns(columns, self.col_names)
if self.usecols is not None:
columns = self._filter_usecols(columns)
col_dict = dict(
filter(lambda item: item[0] in columns, col_dict.items())
)
return index, columns, col_dict
else:
raise
# Done with first read, next time raise StopIteration
self._first_chunk = False
names = self.names
if self._reader.leading_cols:
if self._has_complex_date_col:
raise NotImplementedError("file structure not yet supported")
# implicit index, no index names
arrays = []
for i in range(self._reader.leading_cols):
if self.index_col is None:
values = data.pop(i)
else:
values = data.pop(self.index_col[i])
values = self._maybe_parse_dates(values, i, try_parse_dates=True)
arrays.append(values)
index = ensure_index_from_sequences(arrays)
if self.usecols is not None:
names = self._filter_usecols(names)
names = self._maybe_dedup_names(names)
# rename dict keys
data = sorted(data.items())
data = {k: v for k, (i, v) in zip(names, data)}
names, data = self._do_date_conversions(names, data)
else:
# rename dict keys
data = sorted(data.items())
# ugh, mutation
names = list(self.orig_names)
names = self._maybe_dedup_names(names)
if self.usecols is not None:
names = self._filter_usecols(names)
# columns as list
alldata = [x[1] for x in data]
data = {k: v for k, (i, v) in zip(names, data)}
names, data = self._do_date_conversions(names, data)
index, names = self._make_index(data, alldata, names)
# maybe create a mi on the columns
names = self._maybe_make_multi_index_columns(names, self.col_names)
return index, names, data
def _filter_usecols(self, names):
# hackish
usecols = _evaluate_usecols(self.usecols, names)
if usecols is not None and len(names) != len(usecols):
names = [
name for i, name in enumerate(names) if i in usecols or name in usecols
]
return names
def _get_index_names(self):
names = list(self._reader.header[0])
idx_names = None
if self._reader.leading_cols == 0 and self.index_col is not None:
(idx_names, names, self.index_col) = _clean_index_names(
names, self.index_col, self.unnamed_cols
)
return names, idx_names
def _maybe_parse_dates(self, values, index, try_parse_dates=True):
if try_parse_dates and self._should_parse_dates(index):
values = self._date_conv(values)
return values
def TextParser(*args, **kwds):
"""
Converts lists of lists/tuples into DataFrames with proper type inference
and optional (e.g. string to datetime) conversion. Also enables iterating
lazily over chunks of large files
Parameters
----------
data : file-like object or list
delimiter : separator character to use
dialect : str or csv.Dialect instance, optional
Ignored if delimiter is longer than 1 character
names : sequence, default
header : int, default 0
Row to use to parse column labels. Defaults to the first row. Prior
rows will be discarded
index_col : int or list, optional
Column or columns to use as the (possibly hierarchical) index
has_index_names: bool, default False
True if the cols defined in index_col have an index name and are
not in the header.
na_values : scalar, str, list-like, or dict, optional
Additional strings to recognize as NA/NaN.
keep_default_na : bool, default True
thousands : str, optional
Thousands separator
comment : str, optional
Comment out remainder of line
parse_dates : bool, default False
keep_date_col : bool, default False
date_parser : function, optional
skiprows : list of integers
Row numbers to skip
skipfooter : int
Number of line at bottom of file to skip
converters : dict, optional
Dict of functions for converting values in certain columns. Keys can
either be integers or column labels, values are functions that take one
input argument, the cell (not column) content, and return the
transformed content.
encoding : str, optional
Encoding to use for UTF when reading/writing (ex. 'utf-8')
squeeze : bool, default False
returns Series if only one column.
infer_datetime_format: bool, default False
If True and `parse_dates` is True for a column, try to infer the
datetime format based on the first datetime string. If the format
can be inferred, there often will be a large parsing speed-up.
float_precision : str, optional
Specifies which converter the C engine should use for floating-point
values. The options are None for the ordinary converter,
'high' for the high-precision converter, and 'round_trip' for the
round-trip converter.
"""
kwds["engine"] = "python"
return TextFileReader(*args, **kwds)
def count_empty_vals(vals):
return sum(1 for v in vals if v == "" or v is None)
class PythonParser(ParserBase):
def __init__(self, f, **kwds):
"""
Workhorse function for processing nested list into DataFrame
"""
ParserBase.__init__(self, kwds)
self.data = None
self.buf = []
self.pos = 0
self.line_pos = 0
self.encoding = kwds["encoding"]
self.compression = kwds["compression"]
self.memory_map = kwds["memory_map"]
self.skiprows = kwds["skiprows"]
if callable(self.skiprows):
self.skipfunc = self.skiprows
else:
self.skipfunc = lambda x: x in self.skiprows
self.skipfooter = _validate_skipfooter_arg(kwds["skipfooter"])
self.delimiter = kwds["delimiter"]
self.quotechar = kwds["quotechar"]
if isinstance(self.quotechar, str):
self.quotechar = str(self.quotechar)
self.escapechar = kwds["escapechar"]
self.doublequote = kwds["doublequote"]
self.skipinitialspace = kwds["skipinitialspace"]
self.lineterminator = kwds["lineterminator"]
self.quoting = kwds["quoting"]
self.usecols, _ = _validate_usecols_arg(kwds["usecols"])
self.skip_blank_lines = kwds["skip_blank_lines"]
self.warn_bad_lines = kwds["warn_bad_lines"]
self.error_bad_lines = kwds["error_bad_lines"]
self.names_passed = kwds["names"] or None
self.has_index_names = False
if "has_index_names" in kwds:
self.has_index_names = kwds["has_index_names"]
self.verbose = kwds["verbose"]
self.converters = kwds["converters"]
self.dtype = kwds["dtype"]
self.thousands = kwds["thousands"]
self.decimal = kwds["decimal"]
self.comment = kwds["comment"]
self._comment_lines = []
f, handles = get_handle(
f,
"r",
encoding=self.encoding,
compression=self.compression,
memory_map=self.memory_map,
)
self.handles.extend(handles)
# Set self.data to something that can read lines.
if hasattr(f, "readline"):
self._make_reader(f)
else:
self.data = f
# Get columns in two steps: infer from data, then
# infer column indices from self.usecols if it is specified.
self._col_indices = None
try:
(
self.columns,
self.num_original_columns,
self.unnamed_cols,
) = self._infer_columns()
except (TypeError, ValueError):
self.close()
raise
# Now self.columns has the set of columns that we will process.
# The original set is stored in self.original_columns.
if len(self.columns) > 1:
# we are processing a multi index column
(
self.columns,
self.index_names,
self.col_names,
_,
) = self._extract_multi_indexer_columns(
self.columns, self.index_names, self.col_names
)
# Update list of original names to include all indices.
self.num_original_columns = len(self.columns)
else:
self.columns = self.columns[0]
# get popped off for index
self.orig_names = list(self.columns)
# needs to be cleaned/refactored
# multiple date column thing turning into a real spaghetti factory
if not self._has_complex_date_col:
(index_names, self.orig_names, self.columns) = self._get_index_name(
self.columns
)
self._name_processed = True
if self.index_names is None:
self.index_names = index_names
self._validate_parse_dates_presence(self.columns)
if self.parse_dates:
self._no_thousands_columns = self._set_no_thousands_columns()
else:
self._no_thousands_columns = None
if len(self.decimal) != 1:
raise ValueError("Only length-1 decimal markers supported")
if self.thousands is None:
self.nonnum = re.compile(fr"[^-^0-9^{self.decimal}]+")
else:
self.nonnum = re.compile(fr"[^-^0-9^{self.thousands}^{self.decimal}]+")
def _set_no_thousands_columns(self):
# Create a set of column ids that are not to be stripped of thousands
# operators.
noconvert_columns = set()
def _set(x):
if is_integer(x):
noconvert_columns.add(x)
else:
noconvert_columns.add(self.columns.index(x))
if isinstance(self.parse_dates, list):
for val in self.parse_dates:
if isinstance(val, list):
for k in val:
_set(k)
else:
_set(val)
elif isinstance(self.parse_dates, dict):
for val in self.parse_dates.values():
if isinstance(val, list):
for k in val:
_set(k)
else:
_set(val)
elif self.parse_dates:
if isinstance(self.index_col, list):
for k in self.index_col:
_set(k)
elif self.index_col is not None:
_set(self.index_col)
return noconvert_columns
def _make_reader(self, f):
sep = self.delimiter
if sep is None or len(sep) == 1:
if self.lineterminator:
raise ValueError(
"Custom line terminators not supported in python parser (yet)"
)
class MyDialect(csv.Dialect):
delimiter = self.delimiter
quotechar = self.quotechar
escapechar = self.escapechar
doublequote = self.doublequote
skipinitialspace = self.skipinitialspace
quoting = self.quoting
lineterminator = "\n"
dia = MyDialect
if sep is not None:
dia.delimiter = sep
else:
# attempt to sniff the delimiter from the first valid line,
# i.e. no comment line and not in skiprows
line = f.readline()
lines = self._check_comments([[line]])[0]
while self.skipfunc(self.pos) or not lines:
self.pos += 1
line = f.readline()
lines = self._check_comments([[line]])[0]
# since `line` was a string, lines will be a list containing
# only a single string
line = lines[0]
self.pos += 1
self.line_pos += 1
sniffed = csv.Sniffer().sniff(line)
dia.delimiter = sniffed.delimiter
# Note: self.encoding is irrelevant here
line_rdr = csv.reader(StringIO(line), dialect=dia)
self.buf.extend(list(line_rdr))
# Note: self.encoding is irrelevant here
reader = csv.reader(f, dialect=dia, strict=True)
else:
def _read():
line = f.readline()
pat = re.compile(sep)
yield pat.split(line.strip())
for line in f:
yield pat.split(line.strip())
reader = _read()
self.data = reader
def read(self, rows=None):
try:
content = self._get_lines(rows)
except StopIteration:
if self._first_chunk:
content = []
else:
raise
# done with first read, next time raise StopIteration
self._first_chunk = False
columns = list(self.orig_names)
if not len(content): # pragma: no cover
# DataFrame with the right metadata, even though it's length 0
names = self._maybe_dedup_names(self.orig_names)
index, columns, col_dict = _get_empty_meta(
names, self.index_col, self.index_names, self.dtype
)
columns = self._maybe_make_multi_index_columns(columns, self.col_names)
return index, columns, col_dict
# handle new style for names in index
count_empty_content_vals = count_empty_vals(content[0])
indexnamerow = None
if self.has_index_names and count_empty_content_vals == len(columns):
indexnamerow = content[0]
content = content[1:]
alldata = self._rows_to_cols(content)
data = self._exclude_implicit_index(alldata)
columns = self._maybe_dedup_names(self.columns)
columns, data = self._do_date_conversions(columns, data)
data = self._convert_data(data)
index, columns = self._make_index(data, alldata, columns, indexnamerow)
return index, columns, data
def _exclude_implicit_index(self, alldata):
names = self._maybe_dedup_names(self.orig_names)
if self._implicit_index:
excl_indices = self.index_col
data = {}
offset = 0
for i, col in enumerate(names):
while i + offset in excl_indices:
offset += 1
data[col] = alldata[i + offset]
else:
data = {k: v for k, v in zip(names, alldata)}
return data
# legacy
def get_chunk(self, size=None):
if size is None:
size = self.chunksize
return self.read(rows=size)
def _convert_data(self, data):
# apply converters
def _clean_mapping(mapping):
"""converts col numbers to names"""
clean = {}
for col, v in mapping.items():
if isinstance(col, int) and col not in self.orig_names:
col = self.orig_names[col]
clean[col] = v
return clean
clean_conv = _clean_mapping(self.converters)
if not isinstance(self.dtype, dict):
# handles single dtype applied to all columns
clean_dtypes = self.dtype
else:
clean_dtypes = _clean_mapping(self.dtype)
# Apply NA values.
clean_na_values = {}
clean_na_fvalues = {}
if isinstance(self.na_values, dict):
for col in self.na_values:
na_value = self.na_values[col]
na_fvalue = self.na_fvalues[col]
if isinstance(col, int) and col not in self.orig_names:
col = self.orig_names[col]
clean_na_values[col] = na_value
clean_na_fvalues[col] = na_fvalue
else:
clean_na_values = self.na_values
clean_na_fvalues = self.na_fvalues
return self._convert_to_ndarrays(
data,
clean_na_values,
clean_na_fvalues,
self.verbose,
clean_conv,
clean_dtypes,
)
def _infer_columns(self):
names = self.names
num_original_columns = 0
clear_buffer = True
unnamed_cols = set()
if self.header is not None:
header = self.header
if isinstance(header, (list, tuple, np.ndarray)):
have_mi_columns = len(header) > 1
# we have a mi columns, so read an extra line
if have_mi_columns:
header = list(header) + [header[-1] + 1]
else:
have_mi_columns = False
header = [header]
columns = []
for level, hr in enumerate(header):
try:
line = self._buffered_line()
while self.line_pos <= hr:
line = self._next_line()
except StopIteration as err:
if self.line_pos < hr:
raise ValueError(
f"Passed header={hr} but only {self.line_pos + 1} lines in "
"file"
) from err
# We have an empty file, so check
# if columns are provided. That will
# serve as the 'line' for parsing
if have_mi_columns and hr > 0:
if clear_buffer:
self._clear_buffer()
columns.append([None] * len(columns[-1]))
return columns, num_original_columns, unnamed_cols
if not self.names:
raise EmptyDataError("No columns to parse from file") from err
line = self.names[:]
this_columns = []
this_unnamed_cols = []
for i, c in enumerate(line):
if c == "":
if have_mi_columns:
col_name = f"Unnamed: {i}_level_{level}"
else:
col_name = f"Unnamed: {i}"
this_unnamed_cols.append(i)
this_columns.append(col_name)
else:
this_columns.append(c)
if not have_mi_columns and self.mangle_dupe_cols:
counts = defaultdict(int)
for i, col in enumerate(this_columns):
cur_count = counts[col]
while cur_count > 0:
counts[col] = cur_count + 1
col = f"{col}.{cur_count}"
cur_count = counts[col]
this_columns[i] = col
counts[col] = cur_count + 1
elif have_mi_columns:
# if we have grabbed an extra line, but its not in our
# format so save in the buffer, and create an blank extra
# line for the rest of the parsing code
if hr == header[-1]:
lc = len(this_columns)
ic = len(self.index_col) if self.index_col is not None else 0
unnamed_count = len(this_unnamed_cols)
if lc != unnamed_count and lc - ic > unnamed_count:
clear_buffer = False
this_columns = [None] * lc
self.buf = [self.buf[-1]]
columns.append(this_columns)
unnamed_cols.update({this_columns[i] for i in this_unnamed_cols})
if len(columns) == 1:
num_original_columns = len(this_columns)
if clear_buffer:
self._clear_buffer()
if names is not None:
if (self.usecols is not None and len(names) != len(self.usecols)) or (
self.usecols is None and len(names) != len(columns[0])
):
raise ValueError(
"Number of passed names did not match "
"number of header fields in the file"
)
if len(columns) > 1:
raise TypeError("Cannot pass names with multi-index columns")
if self.usecols is not None:
# Set _use_cols. We don't store columns because they are
# overwritten.
self._handle_usecols(columns, names)
else:
self._col_indices = None
num_original_columns = len(names)
columns = [names]
else:
columns = self._handle_usecols(columns, columns[0])
else:
try:
line = self._buffered_line()
except StopIteration as err:
if not names:
raise EmptyDataError("No columns to parse from file") from err
line = names[:]
ncols = len(line)
num_original_columns = ncols
if not names:
if self.prefix:
columns = [[f"{self.prefix}{i}" for i in range(ncols)]]
else:
columns = [list(range(ncols))]
columns = self._handle_usecols(columns, columns[0])
else:
if self.usecols is None or len(names) >= num_original_columns:
columns = self._handle_usecols([names], names)
num_original_columns = len(names)
else:
if not callable(self.usecols) and len(names) != len(self.usecols):
raise ValueError(
"Number of passed names did not match number of "
"header fields in the file"
)
# Ignore output but set used columns.
self._handle_usecols([names], names)
columns = [names]
num_original_columns = ncols
return columns, num_original_columns, unnamed_cols
def _handle_usecols(self, columns, usecols_key):
"""
Sets self._col_indices
usecols_key is used if there are string usecols.
"""
if self.usecols is not None:
if callable(self.usecols):
col_indices = _evaluate_usecols(self.usecols, usecols_key)
elif any(isinstance(u, str) for u in self.usecols):
if len(columns) > 1:
raise ValueError(
"If using multiple headers, usecols must be integers."
)
col_indices = []
for col in self.usecols:
if isinstance(col, str):
try:
col_indices.append(usecols_key.index(col))
except ValueError:
_validate_usecols_names(self.usecols, usecols_key)
else:
col_indices.append(col)
else:
col_indices = self.usecols
columns = [
[n for i, n in enumerate(column) if i in col_indices]
for column in columns
]
self._col_indices = col_indices
return columns
def _buffered_line(self):
"""
Return a line from buffer, filling buffer if required.
"""
if len(self.buf) > 0:
return self.buf[0]
else:
return self._next_line()
def _check_for_bom(self, first_row):
"""
Checks whether the file begins with the BOM character.
If it does, remove it. In addition, if there is quoting
in the field subsequent to the BOM, remove it as well
because it technically takes place at the beginning of
the name, not the middle of it.
"""
# first_row will be a list, so we need to check
# that that list is not empty before proceeding.
if not first_row:
return first_row
# The first element of this row is the one that could have the
# BOM that we want to remove. Check that the first element is a
# string before proceeding.
if not isinstance(first_row[0], str):
return first_row
# Check that the string is not empty, as that would
# obviously not have a BOM at the start of it.
if not first_row[0]:
return first_row
# Since the string is non-empty, check that it does
# in fact begin with a BOM.
first_elt = first_row[0][0]
if first_elt != _BOM:
return first_row
first_row_bom = first_row[0]
if len(first_row_bom) > 1 and first_row_bom[1] == self.quotechar:
start = 2
quote = first_row_bom[1]
end = first_row_bom[2:].index(quote) + 2
# Extract the data between the quotation marks
new_row = first_row_bom[start:end]
# Extract any remaining data after the second
# quotation mark.
if len(first_row_bom) > end + 1:
new_row += first_row_bom[end + 1 :]
return [new_row] + first_row[1:]
elif len(first_row_bom) > 1:
return [first_row_bom[1:]]
else:
# First row is just the BOM, so we
# return an empty string.
return [""]
def _is_line_empty(self, line):
"""
Check if a line is empty or not.
Parameters
----------
line : str, array-like
The line of data to check.
Returns
-------
boolean : Whether or not the line is empty.
"""
return not line or all(not x for x in line)
def _next_line(self):
if isinstance(self.data, list):
while self.skipfunc(self.pos):
self.pos += 1
while True:
try:
line = self._check_comments([self.data[self.pos]])[0]
self.pos += 1
# either uncommented or blank to begin with
if not self.skip_blank_lines and (
self._is_line_empty(self.data[self.pos - 1]) or line
):
break
elif self.skip_blank_lines:
ret = self._remove_empty_lines([line])
if ret:
line = ret[0]
break
except IndexError:
raise StopIteration
else:
while self.skipfunc(self.pos):
self.pos += 1
next(self.data)
while True:
orig_line = self._next_iter_line(row_num=self.pos + 1)
self.pos += 1
if orig_line is not None:
line = self._check_comments([orig_line])[0]
if self.skip_blank_lines:
ret = self._remove_empty_lines([line])
if ret:
line = ret[0]
break
elif self._is_line_empty(orig_line) or line:
break
# This was the first line of the file,
# which could contain the BOM at the
# beginning of it.
if self.pos == 1:
line = self._check_for_bom(line)
self.line_pos += 1
self.buf.append(line)
return line
def _alert_malformed(self, msg, row_num):
"""
Alert a user about a malformed row.
If `self.error_bad_lines` is True, the alert will be `ParserError`.
If `self.warn_bad_lines` is True, the alert will be printed out.
Parameters
----------
msg : The error message to display.
row_num : The row number where the parsing error occurred.
Because this row number is displayed, we 1-index,
even though we 0-index internally.
"""
if self.error_bad_lines:
raise ParserError(msg)
elif self.warn_bad_lines:
base = f"Skipping line {row_num}: "
sys.stderr.write(base + msg + "\n")
def _next_iter_line(self, row_num):
"""
Wrapper around iterating through `self.data` (CSV source).
When a CSV error is raised, we check for specific
error messages that allow us to customize the
error message displayed to the user.
Parameters
----------
row_num : The row number of the line being parsed.
"""
try:
return next(self.data)
except csv.Error as e:
if self.warn_bad_lines or self.error_bad_lines:
msg = str(e)
if "NULL byte" in msg or "line contains NUL" in msg:
msg = (
"NULL byte detected. This byte "
"cannot be processed in Python's "
"native csv library at the moment, "
"so please pass in engine='c' instead"
)
if self.skipfooter > 0:
reason = (
"Error could possibly be due to "
"parsing errors in the skipped footer rows "
"(the skipfooter keyword is only applied "
"after Python's csv library has parsed "
"all rows)."
)
msg += ". " + reason
self._alert_malformed(msg, row_num)
return None
def _check_comments(self, lines):
if self.comment is None:
return lines
ret = []
for l in lines:
rl = []
for x in l:
if not isinstance(x, str) or self.comment not in x:
rl.append(x)
else:
x = x[: x.find(self.comment)]
if len(x) > 0:
rl.append(x)
break
ret.append(rl)
return ret
def _remove_empty_lines(self, lines):
"""
Iterate through the lines and remove any that are
either empty or contain only one whitespace value
Parameters
----------
lines : array-like
The array of lines that we are to filter.
Returns
-------
filtered_lines : array-like
The same array of lines with the "empty" ones removed.
"""
ret = []
for l in lines:
# Remove empty lines and lines with only one whitespace value
if (
len(l) > 1
or len(l) == 1
and (not isinstance(l[0], str) or l[0].strip())
):
ret.append(l)
return ret
def _check_thousands(self, lines):
if self.thousands is None:
return lines
return self._search_replace_num_columns(
lines=lines, search=self.thousands, replace=""
)
def _search_replace_num_columns(self, lines, search, replace):
ret = []
for l in lines:
rl = []
for i, x in enumerate(l):
if (
not isinstance(x, str)
or search not in x
or (self._no_thousands_columns and i in self._no_thousands_columns)
or self.nonnum.search(x.strip())
):
rl.append(x)
else:
rl.append(x.replace(search, replace))
ret.append(rl)
return ret
def _check_decimal(self, lines):
if self.decimal == _parser_defaults["decimal"]:
return lines
return self._search_replace_num_columns(
lines=lines, search=self.decimal, replace="."
)
def _clear_buffer(self):
self.buf = []
_implicit_index = False
def _get_index_name(self, columns):
"""
Try several cases to get lines:
0) There are headers on row 0 and row 1 and their
total summed lengths equals the length of the next line.
Treat row 0 as columns and row 1 as indices
1) Look for implicit index: there are more columns
on row 1 than row 0. If this is true, assume that row
1 lists index columns and row 0 lists normal columns.
2) Get index from the columns if it was listed.
"""
orig_names = list(columns)
columns = list(columns)
try:
line = self._next_line()
except StopIteration:
line = None
try:
next_line = self._next_line()
except StopIteration:
next_line = None
# implicitly index_col=0 b/c 1 fewer column names
implicit_first_cols = 0
if line is not None:
# leave it 0, #2442
# Case 1
if self.index_col is not False:
implicit_first_cols = len(line) - self.num_original_columns
# Case 0
if next_line is not None:
if len(next_line) == len(line) + self.num_original_columns:
# column and index names on diff rows
self.index_col = list(range(len(line)))
self.buf = self.buf[1:]
for c in reversed(line):
columns.insert(0, c)
# Update list of original names to include all indices.
orig_names = list(columns)
self.num_original_columns = len(columns)
return line, orig_names, columns
if implicit_first_cols > 0:
# Case 1
self._implicit_index = True
if self.index_col is None:
self.index_col = list(range(implicit_first_cols))
index_name = None
else:
# Case 2
(index_name, columns_, self.index_col) = _clean_index_names(
columns, self.index_col, self.unnamed_cols
)
return index_name, orig_names, columns
def _rows_to_cols(self, content):
col_len = self.num_original_columns
if self._implicit_index:
col_len += len(self.index_col)
max_len = max(len(row) for row in content)
# Check that there are no rows with too many
# elements in their row (rows with too few
# elements are padded with NaN).
if max_len > col_len and self.index_col is not False and self.usecols is None:
footers = self.skipfooter if self.skipfooter else 0
bad_lines = []
iter_content = enumerate(content)
content_len = len(content)
content = []
for (i, l) in iter_content:
actual_len = len(l)
if actual_len > col_len:
if self.error_bad_lines or self.warn_bad_lines:
row_num = self.pos - (content_len - i + footers)
bad_lines.append((row_num, actual_len))
if self.error_bad_lines:
break
else:
content.append(l)
for row_num, actual_len in bad_lines:
msg = (
f"Expected {col_len} fields in line {row_num + 1}, saw "
f"{actual_len}"
)
if (
self.delimiter
and len(self.delimiter) > 1
and self.quoting != csv.QUOTE_NONE
):
# see gh-13374
reason = (
"Error could possibly be due to quotes being "
"ignored when a multi-char delimiter is used."
)
msg += ". " + reason
self._alert_malformed(msg, row_num + 1)
# see gh-13320
zipped_content = list(lib.to_object_array(content, min_width=col_len).T)
if self.usecols:
if self._implicit_index:
zipped_content = [
a
for i, a in enumerate(zipped_content)
if (
i < len(self.index_col)
or i - len(self.index_col) in self._col_indices
)
]
else:
zipped_content = [
a for i, a in enumerate(zipped_content) if i in self._col_indices
]
return zipped_content
def _get_lines(self, rows=None):
lines = self.buf
new_rows = None
# already fetched some number
if rows is not None:
# we already have the lines in the buffer
if len(self.buf) >= rows:
new_rows, self.buf = self.buf[:rows], self.buf[rows:]
# need some lines
else:
rows -= len(self.buf)
if new_rows is None:
if isinstance(self.data, list):
if self.pos > len(self.data):
raise StopIteration
if rows is None:
new_rows = self.data[self.pos :]
new_pos = len(self.data)
else:
new_rows = self.data[self.pos : self.pos + rows]
new_pos = self.pos + rows
# Check for stop rows. n.b.: self.skiprows is a set.
if self.skiprows:
new_rows = [
row
for i, row in enumerate(new_rows)
if not self.skipfunc(i + self.pos)
]
lines.extend(new_rows)
self.pos = new_pos
else:
new_rows = []
try:
if rows is not None:
for _ in range(rows):
new_rows.append(next(self.data))
lines.extend(new_rows)
else:
rows = 0
while True:
new_row = self._next_iter_line(row_num=self.pos + rows + 1)
rows += 1
if new_row is not None:
new_rows.append(new_row)
except StopIteration:
if self.skiprows:
new_rows = [
row
for i, row in enumerate(new_rows)
if not self.skipfunc(i + self.pos)
]
lines.extend(new_rows)
if len(lines) == 0:
raise
self.pos += len(new_rows)
self.buf = []
else:
lines = new_rows
if self.skipfooter:
lines = lines[: -self.skipfooter]
lines = self._check_comments(lines)
if self.skip_blank_lines:
lines = self._remove_empty_lines(lines)
lines = self._check_thousands(lines)
return self._check_decimal(lines)
def _make_date_converter(
date_parser=None, dayfirst=False, infer_datetime_format=False, cache_dates=True
):
def converter(*date_cols):
if date_parser is None:
strs = parsing.concat_date_cols(date_cols)
try:
return tools.to_datetime(
ensure_object(strs),
utc=None,
dayfirst=dayfirst,
errors="ignore",
infer_datetime_format=infer_datetime_format,
cache=cache_dates,
).to_numpy()
except ValueError:
return tools.to_datetime(
parsing.try_parse_dates(strs, dayfirst=dayfirst), cache=cache_dates
)
else:
try:
result = tools.to_datetime(
date_parser(*date_cols), errors="ignore", cache=cache_dates
)
if isinstance(result, datetime.datetime):
raise Exception("scalar parser")
return result
except Exception:
try:
return tools.to_datetime(
parsing.try_parse_dates(
parsing.concat_date_cols(date_cols),
parser=date_parser,
dayfirst=dayfirst,
),
errors="ignore",
)
except Exception:
return generic_parser(date_parser, *date_cols)
return converter
def _process_date_conversion(
data_dict,
converter,
parse_spec,
index_col,
index_names,
columns,
keep_date_col=False,
):
def _isindex(colspec):
return (isinstance(index_col, list) and colspec in index_col) or (
isinstance(index_names, list) and colspec in index_names
)
new_cols = []
new_data = {}
orig_names = columns
columns = list(columns)
date_cols = set()
if parse_spec is None or isinstance(parse_spec, bool):
return data_dict, columns
if isinstance(parse_spec, list):
# list of column lists
for colspec in parse_spec:
if is_scalar(colspec):
if isinstance(colspec, int) and colspec not in data_dict:
colspec = orig_names[colspec]
if _isindex(colspec):
continue
data_dict[colspec] = converter(data_dict[colspec])
else:
new_name, col, old_names = _try_convert_dates(
converter, colspec, data_dict, orig_names
)
if new_name in data_dict:
raise ValueError(f"New date column already in dict {new_name}")
new_data[new_name] = col
new_cols.append(new_name)
date_cols.update(old_names)
elif isinstance(parse_spec, dict):
# dict of new name to column list
for new_name, colspec in parse_spec.items():
if new_name in data_dict:
raise ValueError(f"Date column {new_name} already in dict")
_, col, old_names = _try_convert_dates(
converter, colspec, data_dict, orig_names
)
new_data[new_name] = col
new_cols.append(new_name)
date_cols.update(old_names)
data_dict.update(new_data)
new_cols.extend(columns)
if not keep_date_col:
for c in list(date_cols):
data_dict.pop(c)
new_cols.remove(c)
return data_dict, new_cols
def _try_convert_dates(parser, colspec, data_dict, columns):
colset = set(columns)
colnames = []
for c in colspec:
if c in colset:
colnames.append(c)
elif isinstance(c, int) and c not in columns:
colnames.append(columns[c])
else:
colnames.append(c)
new_name = "_".join(str(x) for x in colnames)
to_parse = [data_dict[c] for c in colnames if c in data_dict]
new_col = parser(*to_parse)
return new_name, new_col, colnames
def _clean_na_values(na_values, keep_default_na=True):
if na_values is None:
if keep_default_na:
na_values = STR_NA_VALUES
else:
na_values = set()
na_fvalues = set()
elif isinstance(na_values, dict):
old_na_values = na_values.copy()
na_values = {} # Prevent aliasing.
# Convert the values in the na_values dictionary
# into array-likes for further use. This is also
# where we append the default NaN values, provided
# that `keep_default_na=True`.
for k, v in old_na_values.items():
if not is_list_like(v):
v = [v]
if keep_default_na:
v = set(v) | STR_NA_VALUES
na_values[k] = v
na_fvalues = {k: _floatify_na_values(v) for k, v in na_values.items()}
else:
if not is_list_like(na_values):
na_values = [na_values]
na_values = _stringify_na_values(na_values)
if keep_default_na:
na_values = na_values | STR_NA_VALUES
na_fvalues = _floatify_na_values(na_values)
return na_values, na_fvalues
def _clean_index_names(columns, index_col, unnamed_cols):
if not _is_index_col(index_col):
return None, columns, index_col
columns = list(columns)
cp_cols = list(columns)
index_names = []
# don't mutate
index_col = list(index_col)
for i, c in enumerate(index_col):
if isinstance(c, str):
index_names.append(c)
for j, name in enumerate(cp_cols):
if name == c:
index_col[i] = j
columns.remove(name)
break
else:
name = cp_cols[c]
columns.remove(name)
index_names.append(name)
# Only clean index names that were placeholders.
for i, name in enumerate(index_names):
if isinstance(name, str) and name in unnamed_cols:
index_names[i] = None
return index_names, columns, index_col
def _get_empty_meta(columns, index_col, index_names, dtype=None):
columns = list(columns)
# Convert `dtype` to a defaultdict of some kind.
# This will enable us to write `dtype[col_name]`
# without worrying about KeyError issues later on.
if not isinstance(dtype, dict):
# if dtype == None, default will be object.
default_dtype = dtype or object
dtype = defaultdict(lambda: default_dtype)
else:
# Save a copy of the dictionary.
_dtype = dtype.copy()
dtype = defaultdict(lambda: object)
# Convert column indexes to column names.
for k, v in _dtype.items():
col = columns[k] if is_integer(k) else k
dtype[col] = v
# Even though we have no data, the "index" of the empty DataFrame
# could for example still be an empty MultiIndex. Thus, we need to
# check whether we have any index columns specified, via either:
#
# 1) index_col (column indices)
# 2) index_names (column names)
#
# Both must be non-null to ensure a successful construction. Otherwise,
# we have to create a generic empty Index.
if (index_col is None or index_col is False) or index_names is None:
index = Index([])
else:
data = [Series([], dtype=dtype[name]) for name in index_names]
index = ensure_index_from_sequences(data, names=index_names)
index_col.sort()
for i, n in enumerate(index_col):
columns.pop(n - i)
col_dict = {col_name: Series([], dtype=dtype[col_name]) for col_name in columns}
return index, columns, col_dict
def _floatify_na_values(na_values):
# create float versions of the na_values
result = set()
for v in na_values:
try:
v = float(v)
if not np.isnan(v):
result.add(v)
except (TypeError, ValueError, OverflowError):
pass
return result
def _stringify_na_values(na_values):
""" return a stringified and numeric for these values """
result = []
for x in na_values:
result.append(str(x))
result.append(x)
try:
v = float(x)
# we are like 999 here
if v == int(v):
v = int(v)
result.append(f"{v}.0")
result.append(str(v))
result.append(v)
except (TypeError, ValueError, OverflowError):
pass
try:
result.append(int(x))
except (TypeError, ValueError, OverflowError):
pass
return set(result)
def _get_na_values(col, na_values, na_fvalues, keep_default_na):
"""
Get the NaN values for a given column.
Parameters
----------
col : str
The name of the column.
na_values : array-like, dict
The object listing the NaN values as strings.
na_fvalues : array-like, dict
The object listing the NaN values as floats.
keep_default_na : bool
If `na_values` is a dict, and the column is not mapped in the
dictionary, whether to return the default NaN values or the empty set.
Returns
-------
nan_tuple : A length-two tuple composed of
1) na_values : the string NaN values for that column.
2) na_fvalues : the float NaN values for that column.
"""
if isinstance(na_values, dict):
if col in na_values:
return na_values[col], na_fvalues[col]
else:
if keep_default_na:
return STR_NA_VALUES, set()
return set(), set()
else:
return na_values, na_fvalues
def _get_col_names(colspec, columns):
colset = set(columns)
colnames = []
for c in colspec:
if c in colset:
colnames.append(c)
elif isinstance(c, int):
colnames.append(columns[c])
return colnames
class FixedWidthReader(abc.Iterator):
"""
A reader of fixed-width lines.
"""
def __init__(self, f, colspecs, delimiter, comment, skiprows=None, infer_nrows=100):
self.f = f
self.buffer = None
self.delimiter = "\r\n" + delimiter if delimiter else "\n\r\t "
self.comment = comment
if colspecs == "infer":
self.colspecs = self.detect_colspecs(
infer_nrows=infer_nrows, skiprows=skiprows
)
else:
self.colspecs = colspecs
if not isinstance(self.colspecs, (tuple, list)):
raise TypeError(
"column specifications must be a list or tuple, "
f"input was a {type(colspecs).__name__}"
)
for colspec in self.colspecs:
if not (
isinstance(colspec, (tuple, list))
and len(colspec) == 2
and isinstance(colspec[0], (int, np.integer, type(None)))
and isinstance(colspec[1], (int, np.integer, type(None)))
):
raise TypeError(
"Each column specification must be "
"2 element tuple or list of integers"
)
def get_rows(self, infer_nrows, skiprows=None):
"""
Read rows from self.f, skipping as specified.
We distinguish buffer_rows (the first <= infer_nrows
lines) from the rows returned to detect_colspecs
because it's simpler to leave the other locations
with skiprows logic alone than to modify them to
deal with the fact we skipped some rows here as
well.
Parameters
----------
infer_nrows : int
Number of rows to read from self.f, not counting
rows that are skipped.
skiprows: set, optional
Indices of rows to skip.
Returns
-------
detect_rows : list of str
A list containing the rows to read.
"""
if skiprows is None:
skiprows = set()
buffer_rows = []
detect_rows = []
for i, row in enumerate(self.f):
if i not in skiprows:
detect_rows.append(row)
buffer_rows.append(row)
if len(detect_rows) >= infer_nrows:
break
self.buffer = iter(buffer_rows)
return detect_rows
def detect_colspecs(self, infer_nrows=100, skiprows=None):
# Regex escape the delimiters
delimiters = "".join(fr"\{x}" for x in self.delimiter)
pattern = re.compile(f"([^{delimiters}]+)")
rows = self.get_rows(infer_nrows, skiprows)
if not rows:
raise EmptyDataError("No rows from which to infer column width")
max_len = max(map(len, rows))
mask = np.zeros(max_len + 1, dtype=int)
if self.comment is not None:
rows = [row.partition(self.comment)[0] for row in rows]
for row in rows:
for m in pattern.finditer(row):
mask[m.start() : m.end()] = 1
shifted = np.roll(mask, 1)
shifted[0] = 0
edges = np.where((mask ^ shifted) == 1)[0]
edge_pairs = list(zip(edges[::2], edges[1::2]))
return edge_pairs
def __next__(self):
if self.buffer is not None:
try:
line = next(self.buffer)
except StopIteration:
self.buffer = None
line = next(self.f)
else:
line = next(self.f)
# Note: 'colspecs' is a sequence of half-open intervals.
return [line[fromm:to].strip(self.delimiter) for (fromm, to) in self.colspecs]
class FixedWidthFieldParser(PythonParser):
"""
Specialization that Converts fixed-width fields into DataFrames.
See PythonParser for details.
"""
def __init__(self, f, **kwds):
# Support iterators, convert to a list.
self.colspecs = kwds.pop("colspecs")
self.infer_nrows = kwds.pop("infer_nrows")
PythonParser.__init__(self, f, **kwds)
def _make_reader(self, f):
self.data = FixedWidthReader(
f,
self.colspecs,
self.delimiter,
self.comment,
self.skiprows,
self.infer_nrows,
)