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# Copyright (c) 2011-2018, Ulf Magnusson
# SPDX-License-Identifier: ISC
"""
Overview
========
Kconfiglib is a Python 2/3 library for scripting and extracting information
from Kconfig (https://www.kernel.org/doc/Documentation/kbuild/kconfig-language.txt)
configuration systems.
See the homepage at https://github.com/ulfalizer/Kconfiglib for a longer
overview.
Using Kconfiglib on the Linux kernel with the Makefile targets
==============================================================
For the Linux kernel, a handy interface is provided by the
scripts/kconfig/Makefile patch, which can be applied with either 'git am' or
the 'patch' utility:
$ wget -qO- https://raw.githubusercontent.com/ulfalizer/Kconfiglib/master/makefile.patch | git am
$ wget -qO- https://raw.githubusercontent.com/ulfalizer/Kconfiglib/master/makefile.patch | patch -p1
Warning: Not passing -p1 to patch will cause the wrong file to be patched.
Please tell me if the patch does not apply. It should be trivial to apply
manually, as it's just a block of text that needs to be inserted near the other
*conf: targets in scripts/kconfig/Makefile.
Look further down for a motivation for the Makefile patch and for instructions
on how you can use Kconfiglib without it.
If you do not wish to install Kconfiglib via pip, the Makefile patch is set up
so that you can also just clone Kconfiglib into the kernel root:
$ git clone git://github.com/ulfalizer/Kconfiglib.git
$ git am Kconfiglib/makefile.patch (or 'patch -p1 < Kconfiglib/makefile.patch')
Warning: The directory name Kconfiglib/ is significant in this case, because
it's added to PYTHONPATH by the new targets in makefile.patch.
The targets added by the Makefile patch are described in the following
sections.
make [ARCH=<arch>] iscriptconfig
--------------------------------
This target gives an interactive Python prompt where a Kconfig instance has
been preloaded and is available in 'kconf'. To change the Python interpreter
used, pass PYTHONCMD=<executable> to make. The default is "python".
To get a feel for the API, try evaluating and printing the symbols in
kconf.defined_syms, and explore the MenuNode menu tree starting at
kconf.top_node by following 'next' and 'list' pointers.
The item contained in a menu node is found in MenuNode.item (note that this can
be one of the constants kconfiglib.MENU and kconfiglib.COMMENT), and all
symbols and choices have a 'nodes' attribute containing their menu nodes
(usually only one). Printing a menu node will print its item, in Kconfig
format.
If you want to look up a symbol by name, use the kconf.syms dictionary.
make scriptconfig SCRIPT=<script> [SCRIPT_ARG=<arg>]
----------------------------------------------------
This target runs the Python script given by the SCRIPT parameter on the
configuration. sys.argv[1] holds the name of the top-level Kconfig file
(currently always "Kconfig" in practice), and sys.argv[2] holds the SCRIPT_ARG
argument, if given.
See the examples/ subdirectory for example scripts.
Using Kconfiglib without the Makefile targets
=============================================
The make targets are only needed to pick up environment variables exported from
the Kbuild makefiles and referenced inside Kconfig files, via e.g.
'source "arch/$(SRCARCH)/Kconfig" and '$(shell,...)'.
These variables are referenced as of writing (Linux 4.18), together with sample
values:
srctree (.)
ARCH (x86)
SRCARCH (x86)
KERNELVERSION (4.18.0)
CC (gcc)
HOSTCC (gcc)
HOSTCXX (g++)
CC_VERSION_TEXT (gcc (Ubuntu 7.3.0-16ubuntu3) 7.3.0)
To run Kconfiglib without the Makefile patch, set the environment variables
manually:
$ srctree=. ARCH=x86 SRCARCH=x86 KERNELVERSION=`make kernelversion` ... python(3)
>>> import kconfiglib
>>> kconf = kconfiglib.Kconfig() # filename defaults to "Kconfig"
Search the top-level Makefile for "Additional ARCH settings" to see other
possibilities for ARCH and SRCARCH.
To see a list of all referenced environment variables together with their
values, run this code from e.g. 'make iscriptconfig':
import os
for var in kconf.env_vars:
print(var, os.environ[var])
Intro to symbol values
======================
Kconfiglib has the same assignment semantics as the C implementation.
Any symbol can be assigned a value by the user (via Kconfig.load_config() or
Symbol.set_value()), but this user value is only respected if the symbol is
visible, which corresponds to it (currently) being visible in the menuconfig
interface.
For symbols with prompts, the visibility of the symbol is determined by the
condition on the prompt. Symbols without prompts are never visible, so setting
a user value on them is pointless. A warning will be printed by default if
Symbol.set_value() is called on a promptless symbol. Assignments to promptless
symbols are normal within a .config file, so no similar warning will be printed
by load_config().
Dependencies from parents and 'if'/'depends on' are propagated to properties,
including prompts, so these two configurations are logically equivalent:
(1)
menu "menu"
depends on A
if B
config FOO
tristate "foo" if D
default y
depends on C
endif
endmenu
(2)
menu "menu"
depends on A
config FOO
tristate "foo" if A && B && C && D
default y if A && B && C
endmenu
In this example, A && B && C && D (the prompt condition) needs to be non-n for
FOO to be visible (assignable). If its value is m, the symbol can only be
assigned the value m: The visibility sets an upper bound on the value that can
be assigned by the user, and any higher user value will be truncated down.
'default' properties are independent of the visibility, though a 'default' will
often get the same condition as the prompt due to dependency propagation.
'default' properties are used if the symbol is not visible or has no user
value.
Symbols with no user value (or that have a user value but are not visible) and
no (active) 'default' default to n for bool/tristate symbols, and to the empty
string for other symbol types.
'select' works similarly to symbol visibility, but sets a lower bound on the
value of the symbol. The lower bound is determined by the value of the
select*ing* symbol. 'select' does not respect visibility, so non-visible
symbols can be forced to a particular (minimum) value by a select as well.
For non-bool/tristate symbols, it only matters whether the visibility is n or
non-n: m visibility acts the same as y visibility.
Conditions on 'default' and 'select' work in mostly intuitive ways. If the
condition is n, the 'default' or 'select' is disabled. If it is m, the
'default' or 'select' value (the value of the selecting symbol) is truncated
down to m.
When writing a configuration with Kconfig.write_config(), only symbols that are
visible, have an (active) default, or are selected will get written out (note
that this includes all symbols that would accept user values). Kconfiglib
matches the .config format produced by the C implementations down to the
character. This eases testing.
For a visible bool/tristate symbol FOO with value n, this line is written to
.config:
# CONFIG_FOO is not set
The point is to remember the user n selection (which might differ from the
default value the symbol would get), while at the same sticking to the rule
that undefined corresponds to n (.config uses Makefile format, making the line
above a comment). When the .config file is read back in, this line will be
treated the same as the following assignment:
CONFIG_FOO=n
In Kconfiglib, the set of (currently) assignable values for a bool/tristate
symbol appear in Symbol.assignable. For other symbol types, just check if
sym.visibility is non-0 (non-n) to see whether the user value will have an
effect.
Intro to the menu tree
======================
The menu structure, as seen in e.g. menuconfig, is represented by a tree of
MenuNode objects. The top node of the configuration corresponds to an implicit
top-level menu, the title of which is shown at the top in the standard
menuconfig interface. (The title is also available in Kconfig.mainmenu_text in
Kconfiglib.)
The top node is found in Kconfig.top_node. From there, you can visit child menu
nodes by following the 'list' pointer, and any following menu nodes by
following the 'next' pointer. Usually, a non-None 'list' pointer indicates a
menu or Choice, but menu nodes for symbols can sometimes have a non-None 'list'
pointer too due to submenus created implicitly from dependencies.
MenuNode.item is either a Symbol or a Choice object, or one of the constants
MENU and COMMENT. The prompt of the menu node can be found in MenuNode.prompt,
which also holds the title for menus and comments. For Symbol and Choice,
MenuNode.help holds the help text (if any, otherwise None).
Most symbols will only have a single menu node. A symbol defined in multiple
locations will have one menu node for each location. The list of menu nodes for
a Symbol or Choice can be found in the Symbol/Choice.nodes attribute.
Note that prompts and help texts for symbols and choices are stored in their
menu node(s) rather than in the Symbol or Choice objects themselves. This makes
it possible to define a symbol in multiple locations with a different prompt or
help text in each location. To get the help text or prompt for a symbol with a
single menu node, do sym.nodes[0].help and sym.nodes[0].prompt, respectively.
The prompt is a (text, condition) tuple, where condition determines the
visibility (see 'Intro to expressions' below).
This organization mirrors the C implementation. MenuNode is called
'struct menu' there, but I thought "menu" was a confusing name.
It is possible to give a Choice a name and define it in multiple locations,
hence why Choice.nodes is also a list.
As a convenience, the properties added at a particular definition location are
available on the MenuNode itself, in e.g. MenuNode.defaults. This is helpful
when generating documentation, so that symbols/choices defined in multiple
locations can be shown with the correct properties at each location.
Intro to expressions
====================
Expressions can be evaluated with the expr_value() function and printed with
the expr_str() function (these are used internally as well). Evaluating an
expression always yields a tristate value, where n, m, and y are represented as
0, 1, and 2, respectively.
The following table should help you figure out how expressions are represented.
A, B, C, ... are symbols (Symbol instances), NOT is the kconfiglib.NOT
constant, etc.
Expression Representation
---------- --------------
A A
"A" A (constant symbol)
!A (NOT, A)
A && B (AND, A, B)
A && B && C (AND, A, (AND, B, C))
A || B (OR, A, B)
A || (B && C && D) (OR, A, (AND, B, (AND, C, D)))
A = B (EQUAL, A, B)
A != "foo" (UNEQUAL, A, foo (constant symbol))
A && B = C && D (AND, A, (AND, (EQUAL, B, C), D))
n Kconfig.n (constant symbol)
m Kconfig.m (constant symbol)
y Kconfig.y (constant symbol)
"y" Kconfig.y (constant symbol)
Strings like "foo" in 'default "foo"' or 'depends on SYM = "foo"' are
represented as constant symbols, so the only values that appear in expressions
are symbols***. This mirrors the C implementation.
***For choice symbols, the parent Choice will appear in expressions as well,
but it's usually invisible as the value interfaces of Symbol and Choice are
identical. This mirrors the C implementation and makes different choice modes
"just work".
Manual evaluation examples:
- The value of A && B is min(A.tri_value, B.tri_value)
- The value of A || B is max(A.tri_value, B.tri_value)
- The value of !A is 2 - A.tri_value
- The value of A = B is 2 (y) if A.str_value == B.str_value, and 0 (n)
otherwise. Note that str_value is used here instead of tri_value.
For constant (as well as undefined) symbols, str_value matches the name of
the symbol. This mirrors the C implementation and explains why
'depends on SYM = "foo"' above works as expected.
n/m/y are automatically converted to the corresponding constant symbols
"n"/"m"/"y" (Kconfig.n/m/y) during parsing.
Kconfig.const_syms is a dictionary like Kconfig.syms but for constant symbols.
If a condition is missing (e.g., <cond> when the 'if <cond>' is removed from
'default A if <cond>'), it is actually Kconfig.y. The standard __str__()
functions just avoid printing 'if y' conditions to give cleaner output.
Kconfig extensions
==================
Kconfiglib implements two Kconfig extensions related to 'source':
'source' with relative path
---------------------------
Kconfiglib supports a custom 'rsource' statement that sources Kconfig files
with a path relative to directory of the Kconfig file containing the 'rsource'
statement, instead of relative to the project root. This extension is not
supported by Linux kernel tools as of writing.
Consider following directory tree:
Project
+--Kconfig
|
+--src
+--Kconfig
|
+--SubSystem1
+--Kconfig
|
+--ModuleA
+--Kconfig
In this example, assume that src/SubSystem1/Kconfig wants to source
src/SubSystem1/ModuleA/Kconfig.
With 'source', the following statement would be used:
source "src/SubSystem1/ModuleA/Kconfig"
Using 'rsource', it can be rewritten as:
rsource "ModuleA/Kconfig"
If an absolute path is given to 'rsource', it acts the same as 'source'.
'rsource' can be used to create "position-independent" Kconfig trees that can
be moved around freely.
Globbed sourcing
----------------
'source' and 'rsource' accept glob patterns, sourcing all matching Kconfig
files. They require at least one matching file, throwing a KconfigError
otherwise.
For example, the following statement might source sub1/foofoofoo and
sub2/foobarfoo:
source "sub[12]/foo*foo"
The glob patterns accepted are the same as for the standard glob.glob()
function.
Two additional statements are provided for cases where it's acceptable for a
pattern to match no files: 'osource' and 'orsource' (the o is for "optional").
For example, the following statements will be no-ops if neither "foo" nor any
files matching "bar*" exist:
osource "foo"
osource "bar*"
'orsource' does a relative optional source.
'source' and 'osource' are analogous to 'include' and '-include' in Make.
Feedback
========
Send bug reports, suggestions, and questions to ulfalizer a.t Google's email
service, or open a ticket on the GitHub page.
"""
import errno
import glob
import os
import platform
import re
import subprocess
import sys
import textwrap
# File layout:
#
# Public classes
# Public functions
# Internal functions
# Public global constants
# Internal global constants
# Line length: 79 columns
#
# Public classes
#
class Kconfig(object):
"""
Represents a Kconfig configuration, e.g. for x86 or ARM. This is the set of
symbols, choices, and menu nodes appearing in the configuration. Creating
any number of Kconfig objects (including for different architectures) is
safe. Kconfiglib doesn't keep any global state.
The following attributes are available. They should be treated as
read-only, and some are implemented through @property magic.
syms:
A dictionary with all symbols in the configuration, indexed by name. Also
includes all symbols that are referenced in expressions but never
defined, except for constant (quoted) symbols.
Undefined symbols can be recognized by Symbol.nodes being empty -- see
the 'Intro to the menu tree' section in the module docstring.
const_syms:
A dictionary like 'syms' for constant (quoted) symbols
named_choices:
A dictionary like 'syms' for named choices (choice FOO)
defined_syms:
A list with all defined symbols, in the same order as they appear in the
Kconfig files. Symbols defined in multiple locations appear multiple
times.
Note: You probably want to use 'unique_defined_syms' instead. This
attribute is mostly maintained for backwards compatibility.
unique_defined_syms:
A list like 'defined_syms', but with duplicates removed. Just the first
instance is kept for symbols defined in multiple locations. Kconfig order
is preserved otherwise.
Using this attribute instead of 'defined_syms' can save work, and
automatically gives reasonable behavior when writing configuration output
(symbols defined in multiple locations only generate output once, while
still preserving Kconfig order for readability).
choices:
A list with all choices, in the same order as they appear in the Kconfig
files.
Note: You probably want to use 'unique_choices' instead. This attribute
is mostly maintained for backwards compatibility.
unique_choices:
Analogous to 'unique_defined_syms', for choices. Named choices can have
multiple definition locations.
menus:
A list with all menus, in the same order as they appear in the Kconfig
files
comments:
A list with all comments, in the same order as they appear in the Kconfig
files
kconfig_filenames:
A list with the filenames of all Kconfig files included in the
configuration, relative to $srctree (or relative to the current directory
if $srctree isn't set).
The files are listed in the order they are source'd, starting with the
top-level Kconfig file. If a file is source'd multiple times, it will
appear multiple times. Use set() to get unique filenames.
Note: Using this for incremental builds is redundant. Kconfig.sync_deps()
already indirectly catches any file modifications that change the
configuration output.
env_vars:
A set() with the names of all environment variables referenced in the
Kconfig files.
Only environment variables referenced with the preprocessor $(FOO) syntax
will be registered. The older $FOO syntax is only supported for backwards
compatibility.
Also note that $(FOO) won't be registered unless the environment variable
$FOO is actually set. If it isn't, $(FOO) is an expansion of an unset
preprocessor variable (which gives the empty string).
Another gotcha is that environment variables referenced in the values of
recursively expanded preprocessor variables (those defined with =) will
only be registered if the variable is actually used (expanded) somewhere.
The note from the 'kconfig_filenames' documentation applies here too.
n/m/y:
The predefined constant symbols n/m/y. Also available in const_syms.
modules:
The Symbol instance for the modules symbol. Currently hardcoded to
MODULES, which is backwards compatible. Kconfiglib will warn if
'option modules' is set on some other symbol. Tell me if you need proper
'option modules' support.
'modules' is never None. If the MODULES symbol is not explicitly defined,
its tri_value will be 0 (n), as expected.
A simple way to enable modules is to do 'kconf.modules.set_value(2)'
(provided the MODULES symbol is defined and visible). Modules are
disabled by default in the kernel Kconfig files as of writing, though
nearly all defconfig files enable them (with 'CONFIG_MODULES=y').
defconfig_list:
The Symbol instance for the 'option defconfig_list' symbol, or None if no
defconfig_list symbol exists. The defconfig filename derived from this
symbol can be found in Kconfig.defconfig_filename.
defconfig_filename:
The filename given by the defconfig_list symbol. This is taken from the
first 'default' with a satisfied condition where the specified file
exists (can be opened for reading). If a defconfig file foo/defconfig is
not found and $srctree was set when the Kconfig was created,
$srctree/foo/defconfig is looked up as well.
'defconfig_filename' is None if either no defconfig_list symbol exists,
or if the defconfig_list symbol has no 'default' with a satisfied
condition that specifies a file that exists.
Gotcha: scripts/kconfig/Makefile might pass --defconfig=<defconfig> to
scripts/kconfig/conf when running e.g. 'make defconfig'. This option
overrides the defconfig_list symbol, meaning defconfig_filename might not
always match what 'make defconfig' would use.
top_node:
The menu node (see the MenuNode class) of the implicit top-level menu.
Acts as the root of the menu tree.
mainmenu_text:
The prompt (title) of the top menu (top_node). Defaults to "Main menu".
Can be changed with the 'mainmenu' statement (see kconfig-language.txt).
variables:
A dictionary with all preprocessor variables, indexed by name. See the
Variable class.
warnings:
A list of strings containing all warnings that have been generated. This
allows flexibility in how warnings are printed and processed.
See the 'warn_to_stderr' parameter to Kconfig.__init__() and the
Kconfig.enable/disable_stderr_warnings() functions as well. Note that
warnings still get added to Kconfig.warnings when 'warn_to_stderr' is
True.
Just as for warnings printed to stderr, only optional warnings that are
enabled will get added to Kconfig.warnings. See the various
Kconfig.enable/disable_*_warnings() functions.
srctree:
The value of the $srctree environment variable when the configuration was
loaded, or the empty string if $srctree wasn't set. This gives nice
behavior with os.path.join(), which treats "" as the current directory,
without adding "./".
Kconfig files are looked up relative to $srctree (unless absolute paths
are used), and .config files are looked up relative to $srctree if they
are not found in the current directory. This is used to support
out-of-tree builds. The C tools use this environment variable in the same
way.
Changing $srctree after creating the Kconfig instance has no effect. Only
the value when the configuration is loaded matters. This avoids surprises
if multiple configurations are loaded with different values for $srctree.
config_prefix:
The value of the $CONFIG_ environment variable when the configuration was
loaded. This is the prefix used (and expected) on symbol names in .config
files and C headers. Defaults to "CONFIG_". Used in the same way in the C
tools.
Like for srctree, only the value of $CONFIG_ when the configuration is
loaded matters.
"""
__slots__ = (
"_encoding",
"_functions",
"_set_match",
"_unset_match",
"_warn_for_no_prompt",
"_warn_for_redun_assign",
"_warn_for_undef_assign",
"_warn_to_stderr",
"_warnings_enabled",
"choices",
"comments",
"config_prefix",
"const_syms",
"defconfig_list",
"defined_syms",
"env_vars",
"kconfig_filenames",
"m",
"mainmenu_text",
"menus",
"modules",
"n",
"named_choices",
"srctree",
"syms",
"top_node",
"unique_choices",
"unique_defined_syms",
"variables",
"warnings",
"y",
# Parsing-related
"_parsing_kconfigs",
"_file",
"_filename",
"_linenr",
"_include_path",
"_filestack",
"_line",
"_saved_line",
"_tokens",
"_tokens_i",
"_has_tokens",
)
#
# Public interface
#
def __init__(self, filename="Kconfig", warn=True, warn_to_stderr=True,
encoding="utf-8"):
"""
Creates a new Kconfig object by parsing Kconfig files. Raises
KconfigError on syntax errors. Note that Kconfig files are not the same
as .config files (which store configuration symbol values).
If the environment variable KCONFIG_STRICT is set to "y", warnings will
be generated for all references to undefined symbols within Kconfig
files. The reason this isn't the default is that some projects (e.g.
the Linux kernel) use multiple Kconfig trees (one per architecture)
with many shared Kconfig files, leading to some safe references to
undefined symbols.
KCONFIG_STRICT relies on literal hex values being prefixed with 0x/0X.
They are indistinguishable from references to undefined symbols
otherwise.
KCONFIG_STRICT might enable other warnings that depend on there being
just a single Kconfig tree in the future.
filename (default: "Kconfig"):
The Kconfig file to load. For the Linux kernel, you'll want "Kconfig"
from the top-level directory, as environment variables will make sure
the right Kconfig is included from there (arch/$SRCARCH/Kconfig as of
writing).
If $srctree is set, 'filename' will be looked up relative to it.
$srctree is also used to look up source'd files within Kconfig files.
See the class documentation.
If you are using Kconfiglib via 'make scriptconfig', the filename of
the base base Kconfig file will be in sys.argv[1]. It's currently
always "Kconfig" in practice.
warn (default: True):
True if warnings related to this configuration should be generated.
This can be changed later with Kconfig.enable/disable_warnings(). It
is provided as a constructor argument since warnings might be
generated during parsing.
See the other Kconfig.enable_*_warnings() functions as well, which
enable or suppress certain warnings when warnings are enabled.
All generated warnings are added to the Kconfig.warnings list. See
the class documentation.
warn_to_stderr (default: True):
True if warnings should be printed to stderr in addition to being
added to Kconfig.warnings.
This can be changed later with
Kconfig.enable/disable_stderr_warnings().
encoding (default: "utf-8"):
The encoding to use when reading and writing files. If None, the
encoding specified in the current locale will be used.
The "utf-8" default avoids exceptions on systems that are configured
to use the C locale, which implies an ASCII encoding.
This parameter has no effect on Python 2, due to implementation
issues (regular strings turning into Unicode strings, which are
distinct in Python 2). Python 2 doesn't decode regular strings
anyway.
Related PEP: https://www.python.org/dev/peps/pep-0538/
"""
self.srctree = os.environ.get("srctree", "")
self.config_prefix = os.environ.get("CONFIG_", "CONFIG_")
# Regular expressions for parsing .config files
self._set_match = _re_match(self.config_prefix + r"([^=]+)=(.*)")
self._unset_match = \
_re_match(r"# {}([^ ]+) is not set".format(self.config_prefix))
self.warnings = []
self._warnings_enabled = warn
self._warn_to_stderr = warn_to_stderr
self._warn_for_undef_assign = False
self._warn_for_redun_assign = True
self._encoding = encoding
self.syms = {}
self.const_syms = {}
self.defined_syms = []
self.named_choices = {}
self.choices = []
self.menus = []
self.comments = []
for nmy in "n", "m", "y":
sym = Symbol()
sym.kconfig = self
sym.name = nmy
sym.is_constant = True
sym.orig_type = TRISTATE
sym._cached_tri_val = STR_TO_TRI[nmy]
self.const_syms[nmy] = sym
self.n = self.const_syms["n"]
self.m = self.const_syms["m"]
self.y = self.const_syms["y"]
# Make n/m/y well-formed symbols
for nmy in "n", "m", "y":
sym = self.const_syms[nmy]
sym.rev_dep = sym.weak_rev_dep = sym.direct_dep = self.n
# Maps preprocessor variables names to Variable instances
self.variables = {}
# Predefined preprocessor functions, with min/max number of arguments
self._functions = {
"info": (_info_fn, 1, 1),
"error-if": (_error_if_fn, 2, 2),
"filename": (_filename_fn, 0, 0),
"lineno": (_lineno_fn, 0, 0),
"shell": (_shell_fn, 1, 1),
"warning-if": (_warning_if_fn, 2, 2),
}
# This is used to determine whether previously unseen symbols should be
# registered. They shouldn't be if we parse expressions after parsing,
# as part of Kconfig.eval_string().
self._parsing_kconfigs = True
self.modules = self._lookup_sym("MODULES")
self.defconfig_list = None
self.top_node = MenuNode()
self.top_node.kconfig = self
self.top_node.item = MENU
self.top_node.is_menuconfig = True
self.top_node.visibility = self.y
self.top_node.prompt = ("Main menu", self.y)
self.top_node.parent = None
self.top_node.dep = self.y
self.top_node.filename = filename
self.top_node.linenr = 1
self.top_node.include_path = ()
# Parse the Kconfig files
# Not used internally. Provided as a convenience.
self.kconfig_filenames = [filename]
self.env_vars = set()
# These implement a single line of "unget" for the parser
self._saved_line = None
self._has_tokens = False
# Keeps track of the location in the parent Kconfig files. Kconfig
# files usually source other Kconfig files. See _enter_file().
self._filestack = []
self._include_path = ()
# The current parsing location
self._filename = filename
self._linenr = 0
# Open the top-level Kconfig file
try:
self._file = self._open(os.path.join(self.srctree, filename), "r")
except IOError as e:
if self.srctree:
print(textwrap.fill(
_INIT_SRCTREE_NOTE.format(self.srctree), 80))
raise
try:
# Parse everything
self._parse_block(None, self.top_node, self.top_node)
except UnicodeDecodeError as e:
_decoding_error(e, self._filename)
# Close the top-level Kconfig file
self._file.close()
self.top_node.list = self.top_node.next
self.top_node.next = None
self._parsing_kconfigs = False
self.unique_defined_syms = _ordered_unique(self.defined_syms)
self.unique_choices = _ordered_unique(self.choices)
# Do various post-processing of the menu tree
self._finalize_tree(self.top_node, self.y)
# Do sanity checks. Some of these depend on everything being
# finalized.
for sym in self.unique_defined_syms:
_check_sym_sanity(sym)
for choice in self.unique_choices:
_check_choice_sanity(choice)
if os.environ.get("KCONFIG_STRICT") == "y":
self._check_undef_syms()
# Build Symbol._dependents for all symbols and choices
self._build_dep()
# Check for dependency loops
for sym in self.unique_defined_syms:
_check_dep_loop_sym(sym, False)
# Add extra dependencies from choices to choice symbols that get
# awkward during dependency loop detection
self._add_choice_deps()
self._warn_for_no_prompt = True
self.mainmenu_text = self.top_node.prompt[0]
@property
def defconfig_filename(self):
"""
See the class documentation.
"""
if self.defconfig_list:
for filename, cond in self.defconfig_list.defaults:
if expr_value(cond):
try:
with self._open_config(filename.str_value) as f:
return f.name
except IOError:
continue
return None
def load_config(self, filename, replace=True):
"""
Loads symbol values from a file in the .config format. Equivalent to
calling Symbol.set_value() to set each of the values.
"# CONFIG_FOO is not set" within a .config file sets the user value of
FOO to n. The C tools work the same way.
The Symbol.user_value attribute can be inspected afterwards to see what
value the symbol was assigned in the .config file (if any). The user
value might differ from Symbol.str/tri_value if there are unsatisfied
dependencies.
filename:
The file to load. Respects $srctree if set (see the class
documentation).
replace (default: True):
True if all existing user values should be cleared before loading the
.config.
"""
# Disable the warning about assigning to symbols without prompts. This
# is normal and expected within a .config file.
self._warn_for_no_prompt = False
# This stub only exists to make sure _warn_for_no_prompt gets reenabled
try:
self._load_config(filename, replace)
except UnicodeDecodeError as e:
_decoding_error(e, filename)
finally:
self._warn_for_no_prompt = True
def _load_config(self, filename, replace):
with self._open_config(filename) as f:
if replace:
# If we're replacing the configuration, keep track of which
# symbols and choices got set so that we can unset the rest
# later. This avoids invalidating everything and is faster.
# Another benefit is that invalidation must be rock solid for
# it to work, making it a good test.
for sym in self.unique_defined_syms:
sym._was_set = False
for choice in self.unique_choices:
choice._was_set = False
# Small optimizations
set_match = self._set_match
unset_match = self._unset_match
syms = self.syms
for linenr, line in enumerate(f, 1):
# The C tools ignore trailing whitespace
line = line.rstrip()
match = set_match(line)
if match:
name, val = match.groups()
if name not in syms:
self._warn_undef_assign_load(name, val, filename,
linenr)
continue
sym = syms[name]
if not sym.nodes:
self._warn_undef_assign_load(name, val, filename,
linenr)
continue
if sym.orig_type in (BOOL, TRISTATE):
# The C implementation only checks the first character
# to the right of '=', for whatever reason
if not ((sym.orig_type is BOOL and
val.startswith(("n", "y"))) or \
(sym.orig_type is TRISTATE and
val.startswith(("n", "m", "y")))):
self._warn("'{}' is not a valid value for the {} "
"symbol {}. Assignment ignored."
.format(val, TYPE_TO_STR[sym.orig_type],
_name_and_loc(sym)),
filename, linenr)
continue
val = val[0]
if sym.choice and val != "n":
# During .config loading, we infer the mode of the
# choice from the kind of values that are assigned
# to the choice symbols
prev_mode = sym.choice.user_value
if prev_mode is not None and \
TRI_TO_STR[prev_mode] != val:
self._warn("both m and y assigned to symbols "
"within the same choice",
filename, linenr)
# Set the choice's mode
sym.choice.set_value(val)
elif sym.orig_type is STRING:
match = _conf_string_match(val)
if not match:
self._warn("malformed string literal in "
"assignment to {}. Assignment ignored."
.format(_name_and_loc(sym)),
filename, linenr)
continue
val = unescape(match.group(1))
else:
match = unset_match(line)
if not match:
# Print a warning for lines that match neither
# set_match() nor unset_match() and that are not blank
# lines or comments. 'line' has already been
# rstrip()'d, so blank lines show up as "" here.
if line and not line.lstrip().startswith("#"):
self._warn("ignoring malformed line '{}'"
.format(line),
filename, linenr)
continue
name = match.group(1)
if name not in syms:
self._warn_undef_assign_load(name, "n", filename,
linenr)
continue
sym = syms[name]
if sym.orig_type not in (BOOL, TRISTATE):
continue
val = "n"
# Done parsing the assignment. Set the value.
if sym._was_set:
# Use strings for bool/tristate user values in the warning
if sym.orig_type in (BOOL, TRISTATE):
display_user_val = TRI_TO_STR[sym.user_value]
else:
display_user_val = sym.user_value
warn_msg = '{} set more than once. Old value: "{}", new value: "{}".'.format(
_name_and_loc(sym), display_user_val, val
)
if display_user_val == val:
self._warn_redun_assign(warn_msg, filename, linenr)
else:
self._warn( warn_msg, filename, linenr)
sym.set_value(val)
if replace:
# If we're replacing the configuration, unset the symbols that
# didn't get set
for sym in self.unique_defined_syms:
if not sym._was_set:
sym.unset_value()
for choice in self.unique_choices:
if not choice._was_set:
choice.unset_value()
def write_autoconf(self, filename,
header="/* Generated by Kconfiglib (https://github.com/ulfalizer/Kconfiglib) */\n"):
r"""
Writes out symbol values as a C header file, matching the format used
by include/generated/autoconf.h in the kernel.
The ordering of the #defines matches the one generated by
write_config(). The order in the C implementation depends on the hash
table implementation as of writing, and so won't match.
filename:
Self-explanatory.
header (default: "/* Generated by Kconfiglib (https://github.com/ulfalizer/Kconfiglib) */\n"):
Text that will be inserted verbatim at the beginning of the file. You
would usually want it enclosed in '/* */' to make it a C comment,
and include a final terminating newline.
"""
with self._open(filename, "w") as f:
f.write(header)
for sym in self.unique_defined_syms:
# Note: _write_to_conf is determined when the value is
# calculated. This is a hidden function call due to
# property magic.
val = sym.str_value
if sym._write_to_conf:
if sym.orig_type in (BOOL, TRISTATE):
if val != "n":
f.write("#define {}{}{} 1\n"
.format(self.config_prefix, sym.name,
"_MODULE" if val == "m" else ""))
elif sym.orig_type is STRING:
f.write('#define {}{} "{}"\n'
.format(self.config_prefix, sym.name,
escape(val)))
elif sym.orig_type in (INT, HEX):
if sym.orig_type is HEX and \
not val.startswith(("0x", "0X")):
val = "0x" + val
f.write("#define {}{} {}\n"
.format(self.config_prefix, sym.name, val))
else:
_internal_error("Internal error while creating C "
'header: unknown type "{}".'
.format(sym.orig_type))
def write_config(self, filename,
header="# Generated by Kconfiglib (https://github.com/ulfalizer/Kconfiglib)\n"):
r"""
Writes out symbol values in the .config format. The format matches the
C implementation, including ordering.
Symbols appear in the same order in generated .config files as they do
in the Kconfig files. For symbols defined in multiple locations, a
single assignment is written out corresponding to the first location
where the symbol is defined.
See the 'Intro to symbol values' section in the module docstring to
understand which symbols get written out.
filename:
Self-explanatory.
header (default: "# Generated by Kconfiglib (https://github.com/ulfalizer/Kconfiglib)\n"):
Text that will be inserted verbatim at the beginning of the file. You
would usually want each line to start with '#' to make it a comment,
and include a final terminating newline.
"""
with self._open(filename, "w") as f:
f.write(header)
# written mainmenu_text
# The prompt (title) of the top_node menu, with Kconfig variable references
# ("$FOO") expanded. Defaults to "Linux Kernel Configuration" (like in the
# C tools). Can be changed with the 'mainmenu' statement (see
# kconfig-language.txt).
f.write("# {}\n#\n".format(self.top_node.prompt[0]))
for node in self.node_iter(unique_syms=True):
item = node.item
if isinstance(item, Symbol):
f.write(item.config_string)
elif expr_value(node.dep) and \
((item is MENU and expr_value(node.visibility)) or
item is COMMENT):
f.write("\n#\n# {}\n#\n".format(node.prompt[0]))
def write_min_config(self, filename,
header="# Generated by Kconfiglib (https://github.com/ulfalizer/Kconfiglib)\n"):
"""
Writes out a "minimal" configuration file, omitting symbols whose value
matches their default value. The format matches the one produced by
'make savedefconfig'.
The resulting configuration file is incomplete, but a complete
configuration can be derived from it by loading it. Minimal
configuration files can serve as a more manageable configuration format
compared to a "full" .config file, especially when configurations files
are merged or edited by hand.
filename:
Self-explanatory.
header (default: "# Generated by Kconfiglib (https://github.com/ulfalizer/Kconfiglib)\n"):
Text that will be inserted verbatim at the beginning of the file. You
would usually want each line to start with '#' to make it a comment,
and include a final terminating newline.
"""
with self._open(filename, "w") as f:
f.write(header)
for sym in self.unique_defined_syms:
# Skip symbols that cannot be changed. Only check
# non-choice symbols, as selects don't affect choice
# symbols.
if not sym.choice and \
sym.visibility <= expr_value(sym.rev_dep):
continue
# Skip symbols whose value matches their default
if sym.str_value == sym._str_default():
continue
# Skip symbols that would be selected by default in a
# choice, unless the choice is optional or the symbol type
# isn't bool (it might be possible to set the choice mode
# to n or the symbol to m in those cases).
if sym.choice and \
not sym.choice.is_optional and \
sym.choice._get_selection_from_defaults() is sym and \
sym.orig_type is BOOL and \
sym.tri_value == 2:
continue
f.write(sym.config_string)
def sync_deps(self, path):
"""
Creates or updates a directory structure that can be used to avoid
doing a full rebuild whenever the configuration is changed, mirroring
include/config/ in the kernel.
This function is intended to be called during each build, before
compiling source files that depend on configuration symbols.
path:
Path to directory
sync_deps(path) does the following:
1. If the directory <path> does not exist, it is created.
2. If <path>/auto.conf exists, old symbol values are loaded from it,
which are then compared against the current symbol values. If a
symbol has changed value (would generate different output in
autoconf.h compared to before), the change is signaled by
touch'ing a file corresponding to the symbol.
The first time sync_deps() is run on a directory, <path>/auto.conf
won't exist, and no old symbol values will be available. This
logically has the same effect as updating the entire
configuration.
The path to a symbol's file is calculated from the symbol's name
by replacing all '_' with '/' and appending '.h'. For example, the
symbol FOO_BAR_BAZ gets the file <path>/foo/bar/baz.h, and FOO
gets the file <path>/foo.h.
This scheme matches the C tools. The point is to avoid having a
single directory with a huge number of files, which the underlying
filesystem might not handle well.
3. A new auto.conf with the current symbol values is written, to keep
track of them for the next build.
The last piece of the puzzle is knowing what symbols each source file
depends on. Knowing that, dependencies can be added from source files
to the files corresponding to the symbols they depends on. The source
file will then get recompiled (only) when the symbol value changes
(provided sync_deps() is run first during each build).
The tool in the kernel that extracts symbol dependencies from source
files is scripts/basic/fixdep.c. Missing symbol files also correspond
to "not changed", which fixdep deals with by using the $(wildcard) Make
function when adding symbol prerequisites to source files.
In case you need a different scheme for your project, the sync_deps()
implementation can be used as a template."""
if not os.path.exists(path):
os.mkdir(path, 0o755)
# This setup makes sure that at least the current working directory
# gets reset if things fail
prev_dir = os.getcwd()
try:
# cd'ing into the symbol file directory simplifies
# _sync_deps() and saves some work
os.chdir(path)
self._sync_deps()
finally:
os.chdir(prev_dir)
def _sync_deps(self):
# Load old values from auto.conf, if any
self._load_old_vals()
for sym in self.unique_defined_syms:
# Note: _write_to_conf is determined when the value is
# calculated. This is a hidden function call due to
# property magic.
val = sym.str_value
# Note: n tristate values do not get written to auto.conf and
# autoconf.h, making a missing symbol logically equivalent to n
if sym._write_to_conf:
if sym._old_val is None and \
sym.orig_type in (BOOL, TRISTATE) and \
val == "n":
# No old value (the symbol was missing or n), new value n.
# No change.
continue
if val == sym._old_val:
# New value matches old. No change.
continue
elif sym._old_val is None:
# The symbol wouldn't appear in autoconf.h (because
# _write_to_conf is false), and it wouldn't have appeared in
# autoconf.h previously either (because it didn't appear in
# auto.conf). No change.
continue
# 'sym' has a new value. Flag it.
sym_path = sym.name.lower().replace("_", os.sep) + ".h"
sym_path_dir = os.path.dirname(sym_path)
if sym_path_dir and not os.path.exists(sym_path_dir):
os.makedirs(sym_path_dir, 0o755)
# A kind of truncating touch, mirroring the C tools
os.close(os.open(
sym_path, os.O_WRONLY | os.O_CREAT | os.O_TRUNC, 0o644))
# Remember the current values as the "new old" values.
#
# This call could go anywhere after the call to _load_old_vals(), but
# putting it last means _sync_deps() can be safely rerun if it fails
# before this point.
self._write_old_vals()
def _write_old_vals(self):
# Helper for writing auto.conf. Basically just a simplified
# write_config() that doesn't write any comments (including
# '# CONFIG_FOO is not set' comments). The format matches the C
# implementation, though the ordering is arbitrary there (depends on
# the hash table implementation).
#
# A separate helper function is neater than complicating write_config()
# by passing a flag to it, plus we only need to look at symbols here.
with self._open("auto.conf", "w") as f:
for sym in self.unique_defined_syms:
if not (sym.orig_type in (BOOL, TRISTATE) and
not sym.tri_value):
f.write(sym.config_string)
def _load_old_vals(self):
# Loads old symbol values from auto.conf into a dedicated
# Symbol._old_val field. Mirrors load_config().
#
# The extra field could be avoided with some trickery involving dumping
# symbol values and restoring them later, but this is simpler and
# faster. The C tools also use a dedicated field for this purpose.
for sym in self.unique_defined_syms:
sym._old_val = None
if not os.path.exists("auto.conf"):
# No old values
return
with self._open("auto.conf", "r") as f:
for line in f:
match = self._set_match(line)
if not match:
# We only expect CONFIG_FOO=... (and possibly a header
# comment) in auto.conf
continue
name, val = match.groups()
if name in self.syms:
sym = self.syms[name]
if sym.orig_type is STRING:
match = _conf_string_match(val)
if not match:
continue
val = unescape(match.group(1))
self.syms[name]._old_val = val
def node_iter(self, unique_syms=False):
"""
Returns a generator for iterating through all MenuNode's in the Kconfig
tree. The iteration is done in Kconfig definition order (the children
of a node are visited before the next node is visited).
The Kconfig.top_node menu node is skipped. It contains an implicit menu
that holds the top-level items.
As an example, the following code will produce a list equal to
Kconfig.defined_syms:
defined_syms = [node.item for node in kconf.node_iter()
if isinstance(node.item, Symbol)]
unique_syms (default: False):
If True, only the first MenuNode will be included for symbols defined
in multiple locations.
Using kconf.node_iter(True) in the example above would give a list
equal to unique_defined_syms.
"""
if unique_syms:
for sym in self.unique_defined_syms:
sym._visited = False
node = self.top_node
while 1:
# Jump to the next node with an iterative tree walk
if node.list:
node = node.list
elif node.next:
node = node.next
else:
while node.parent:
node = node.parent
if node.next:
node = node.next
break
else:
# No more nodes
return
if unique_syms and isinstance(node.item, Symbol):
if node.item._visited:
continue
node.item._visited = True
yield node
def eval_string(self, s):
"""
Returns the tristate value of the expression 's', represented as 0, 1,
and 2 for n, m, and y, respectively. Raises KconfigError if syntax
errors are detected in 's'. Warns if undefined symbols are referenced.
As an example, if FOO and BAR are tristate symbols at least one of
which has the value y, then config.eval_string("y && (FOO || BAR)")
returns 2 (y).
To get the string value of non-bool/tristate symbols, use
Symbol.str_value. eval_string() always returns a tristate value, and
all non-bool/tristate symbols have the tristate value 0 (n).
The expression parsing is consistent with how parsing works for
conditional ('if ...') expressions in the configuration, and matches
the C implementation. m is rewritten to 'm && MODULES', so
eval_string("m") will return 0 (n) unless modules are enabled.
"""
# The parser is optimized to be fast when parsing Kconfig files (where
# an expression can never appear at the beginning of a line). We have
# to monkey-patch things a bit here to reuse it.
self._filename = None
# Don't include the "if " from below to avoid giving confusing error
# messages
self._line = s
# [1:] removes the _T_IF token
self._tokens = self._tokenize("if " + s)[1:]
self._tokens_i = -1
return expr_value(self._expect_expr_and_eol()) # transform_m
def unset_values(self):
"""
Resets the user values of all symbols, as if Kconfig.load_config() or
Symbol.set_value() had never been called.
"""
self._warn_for_no_prompt = False
try:
# set_value() already rejects undefined symbols, and they don't
# need to be invalidated (because their value never changes), so we
# can just iterate over defined symbols
for sym in self.unique_defined_syms:
sym.unset_value()
for choice in self.unique_choices:
choice.unset_value()
finally:
self._warn_for_no_prompt = True
def enable_warnings(self):
"""
See Kconfig.__init__().
"""
self._warnings_enabled = True
def disable_warnings(self):
"""
See Kconfig.__init__().
"""
self._warnings_enabled = False
def enable_stderr_warnings(self):
"""
See Kconfig.__init__().
"""
self._warn_to_stderr = True
def disable_stderr_warnings(self):
"""
See Kconfig.__init__().
"""
self._warn_to_stderr = False
def enable_undef_warnings(self):
"""
Enables warnings for assignments to undefined symbols. Disabled by
default since they tend to be spammy for Kernel configurations (and
mostly suggests cleanups).
"""
self._warn_for_undef_assign = True
def disable_undef_warnings(self):
"""
See enable_undef_assign().
"""
self._warn_for_undef_assign = False
def enable_redun_warnings(self):
"""
Enables warnings for duplicated assignments in .config files that all
set the same value.
These warnings are enabled by default. Disabling them might be helpful
in certain cases when merging configurations.
"""
self._warn_for_redun_assign = True
def disable_redun_warnings(self):
"""
See enable_redun_warnings().
"""
self._warn_for_redun_assign = False
def __repr__(self):
"""
Returns a string with information about the Kconfig object when it is
evaluated on e.g. the interactive Python prompt.
"""
return "<{}>".format(", ".join((
"configuration with {} symbols".format(len(self.syms)),
'main menu prompt "{}"'.format(self.mainmenu_text),
"srctree is current directory" if not self.srctree else
'srctree "{}"'.format(self.srctree),
'config symbol prefix "{}"'.format(self.config_prefix),
"warnings " +
("enabled" if self._warnings_enabled else "disabled"),
"printing of warnings to stderr " +
("enabled" if self._warn_to_stderr else "disabled"),
"undef. symbol assignment warnings " +
("enabled" if self._warn_for_undef_assign else "disabled"),
"redundant symbol assignment warnings " +
("enabled" if self._warn_for_redun_assign else "disabled")
)))
#
# Private methods
#
#
# File reading
#
def _open_config(self, filename):
# Opens a .config file. First tries to open 'filename', then
# '$srctree/filename' if $srctree was set when the configuration was
# loaded.
try:
return self._open(filename, "r")
except IOError as e:
# This will try opening the same file twice if $srctree is unset,
# but it's not a big deal
try:
return self._open(os.path.join(self.srctree, filename), "r")
except IOError as e2:
# This is needed for Python 3, because e2 is deleted after
# the try block:
#
# https://docs.python.org/3/reference/compound_stmts.html#the-try-statement
e = e2
raise IOError("\n" + textwrap.fill(
"Could not open '{}' ({}: {}){}".format(
filename, errno.errorcode[e.errno], e.strerror,
self._srctree_hint()),
80))
def _enter_file(self, full_filename, rel_filename):
# Jumps to the beginning of a sourced Kconfig file, saving the previous
# position and file object.
#
# full_filename:
# Actual path to the file.
#
# rel_filename:
# File path with $srctree prefix stripped, stored in e.g.
# self._filename (which makes it indirectly show up in
# MenuNode.filename). Equals full_filename for absolute paths.
self.kconfig_filenames.append(rel_filename)
# The parent Kconfig files are represented as a list of
# (<include path>, <Python 'file' object for Kconfig file>) tuples.
#
# <include path> is immutable and holds a *tuple* of
# (<filename>, <linenr>) tuples, giving the locations of the 'source'
# statements in the parent Kconfig files. The current include path is
# also available in Kconfig._include_path.
#
# The point of this redundant setup is to allow Kconfig._include_path
# to be assigned directly to MenuNode.include_path without having to
# copy it, sharing it wherever possible.
# Save include path and 'file' object before entering the file
self._filestack.append((self._include_path, self._file))
# _include_path is a tuple, so this rebinds the variable instead of
# doing in-place modification
self._include_path += ((self._filename, self._linenr),)
# Check for recursive 'source'
for name, _ in self._include_path:
if name == rel_filename:
raise KconfigError(
"\n{}:{}: Recursive 'source' of '{}' detected. Check that "
"environment variables are set correctly.\n"
"Include path:\n{}"
.format(self._filename, self._linenr, rel_filename,
"\n".join("{}:{}".format(name, linenr)
for name, linenr in self._include_path)))
# Note: We already know that the file exists
try:
self._file = self._open(full_filename, "r")
except IOError as e:
raise IOError("{}:{}: Could not open '{}' ({}: {})".format(
self._filename, self._linenr, full_filename,
errno.errorcode[e.errno], e.strerror))
self._filename = rel_filename
self._linenr = 0
def _leave_file(self):
# Returns from a Kconfig file to the file that sourced it. See
# _enter_file().
self._file.close()
# Restore location from parent Kconfig file
self._filename, self._linenr = self._include_path[-1]
# Restore include path and 'file' object
self._include_path, self._file = self._filestack.pop()
def _next_line(self):
# Fetches and tokenizes the next line from the current Kconfig file.
# Returns False at EOF and True otherwise.
# _saved_line provides a single line of "unget", currently only used
# for help texts.
#
# This also works as expected if _saved_line is "", indicating EOF:
# "" is falsy, and readline() returns "" over and over at EOF.
if self._saved_line:
self._line = self._saved_line
self._saved_line = None
else:
self._line = self._file.readline()
if not self._line:
return False
self._linenr += 1
# Handle line joining
while self._line.endswith("\\\n"):
self._line = self._line[:-2] + self._file.readline()
self._linenr += 1
self._tokens = self._tokenize(self._line)
self._tokens_i = -1 # Token index (minus one)
return True
#
# Tokenization
#
def _lookup_sym(self, name):
# Fetches the symbol 'name' from the symbol table, creating and
# registering it if it does not exist. If '_parsing_kconfigs' is False,
# it means we're in eval_string(), and new symbols won't be registered.
if name in self.syms:
return self.syms[name]
sym = Symbol()
sym.kconfig = self
sym.name = name
sym.is_constant = False
sym.rev_dep = sym.weak_rev_dep = sym.direct_dep = self.n
if self._parsing_kconfigs:
self.syms[name] = sym
else:
self._warn("no symbol {} in configuration".format(name))
return sym
def _lookup_const_sym(self, name):
# Like _lookup_sym(), for constant (quoted) symbols
if name in self.const_syms:
return self.const_syms[name]
sym = Symbol()
sym.kconfig = self
sym.name = name
sym.is_constant = True
sym.rev_dep = sym.weak_rev_dep = sym.direct_dep = self.n
if self._parsing_kconfigs:
self.const_syms[name] = sym
return sym
def _tokenize(self, s):
# Parses 's', returning a None-terminated list of tokens. Registers any
# new symbols encountered with _lookup(_const)_sym().
#
# Tries to be reasonably speedy by processing chunks of text via
# regexes and string operations where possible. This is the biggest
# hotspot during parsing.
#
# Note: It might be possible to rewrite this to 'yield' tokens instead,
# working across multiple lines. The 'option env' lookback thing below
# complicates things though.
# Initial token on the line
match = _command_match(s)
if not match:
if s.isspace() or s.lstrip().startswith("#"):
return (None,)
self._parse_error("unknown token at start of line")
# Tricky implementation detail: While parsing a token, 'token' refers
# to the previous token. See _STRING_LEX for why this is needed.
token = _get_keyword(match.group(1))
if not token:
# Backwards compatibility with old versions of the C tools, which
# (accidentally) accepted stuff like "--help--" and "-help---".
# This was fixed in the C tools by commit c2264564 ("kconfig: warn
# of unhandled characters in Kconfig commands"), committed in July
# 2015, but it seems people still run Kconfiglib on older kernels.
if s.strip(" \t\n-") == "help":
return (_T_HELP, None)
# If the first token is not a keyword (and not a weird help token),
# we have a preprocessor variable assignment (or a bare macro on a
# line)
self._parse_assignment(s)
return (None,)
tokens = [token]
# The current index in the string being tokenized
i = match.end()
# Main tokenization loop (for tokens past the first one)
while i < len(s):
# Test for an identifier/keyword first. This is the most common
# case.
match = _id_keyword_match(s, i)
if match:
# We have an identifier or keyword
# Jump past it
i = match.end()
# Check what it is. lookup_sym() will take care of allocating
# new symbols for us the first time we see them. Note that
# 'token' still refers to the previous token.
name = match.group(1)
keyword = _get_keyword(name)
if keyword:
# It's a keyword
token = keyword
elif token not in _STRING_LEX:
# It's a non-const symbol, except we translate n, m, and y
# into the corresponding constant symbols, like the C
# implementation
token = self.const_syms[name] \
if name in ("n", "m", "y") else \
self._lookup_sym(name)
else:
# It's a case of missing quotes. For example, the
# following is accepted:
#
# menu unquoted_title
#
# config A
# tristate unquoted_prompt
#
# endmenu
token = name
else:
# Neither a keyword nor a non-const symbol (except
# $()-expansion might still yield a non-const symbol).
# We always strip whitespace after tokens, so it is safe to
# assume that s[i] is the start of a token here.
c = s[i]
if c in "\"'":
s, end_i = self._expand_str(s, i, c)
# os.path.expandvars() and the $UNAME_RELEASE replace() is
# a backwards compatibility hack, which should be
# reasonably safe as expandvars() leaves references to
# undefined env. vars. as is.
#
# The preprocessor functionality changed how environment
# variables are referenced, to $(FOO).
val = os.path.expandvars(
s[i + 1:end_i - 1].replace("$UNAME_RELEASE",
platform.uname()[2]))
i = end_i
# This is the only place where we don't survive with a
# single token of lookback: 'option env="FOO"' does not
# refer to a constant symbol named "FOO".
token = val \
if token in _STRING_LEX or \
tokens[0] is _T_OPTION else \
self._lookup_const_sym(val)
elif s.startswith("&&", i):
token = _T_AND
i += 2
elif s.startswith("||", i):
token = _T_OR
i += 2
elif c == "=":
token = _T_EQUAL
i += 1
elif s.startswith("!=", i):
token = _T_UNEQUAL
i += 2
elif c == "!":
token = _T_NOT
i += 1
elif c == "(":
token = _T_OPEN_PAREN
i += 1
elif c == ")":
token = _T_CLOSE_PAREN
i += 1
elif s.startswith("$(", i):
s, end_i = self._expand_macro(s, i, ())
val = s[i:end_i]
# isspace() is False for empty strings
if not val.strip():
# Avoid creating a Kconfig symbol with a blank name.
# It's almost guaranteed to be an error.
self._parse_error("macro expanded to blank string")
i = end_i
# Compatibility with what the C implementation does. Might
# be unexpected that you can reference non-constant symbols
# this way though...
token = self.const_syms[val] \
if val in ("n", "m", "y") else \
self._lookup_sym(val)
elif s.startswith("$", i):
if token == _T_CONFIG:
s.replace('$', ' ')
i += 1
continue
elif c == "#":
break
# Very rare
elif s.startswith("<=", i):
token = _T_LESS_EQUAL
i += 2
elif c == "<":
token = _T_LESS
i += 1
elif s.startswith(">=", i):
token = _T_GREATER_EQUAL
i += 2
elif c == ">":
token = _T_GREATER
i += 1
else:
self._parse_error("unknown tokens in line")
# Skip trailing whitespace
while i < len(s) and s[i].isspace():
i += 1
# Add the token
tokens.append(token)
# None-terminating the token list makes the token fetching functions
# simpler/faster
tokens.append(None)
return tokens
def _next_token(self):
self._tokens_i += 1
return self._tokens[self._tokens_i]
def _peek_token(self):
return self._tokens[self._tokens_i + 1]
# The functions below are just _next_token() and _parse_expr() with extra
# syntax checking. Inlining _next_token() and _peek_token() into them saves
# a few % of parsing time.
#
# See the 'Intro to expressions' section for what a constant symbol is.
def _expect_sym(self):
self._tokens_i += 1
token = self._tokens[self._tokens_i]
if not isinstance(token, Symbol):
self._parse_error("expected symbol")
return token
def _expect_nonconst_sym(self):
self._tokens_i += 1
token = self._tokens[self._tokens_i]
if not isinstance(token, Symbol) or token.is_constant:
self._parse_error("expected nonconstant symbol")
return token
def _expect_nonconst_sym_and_eol(self):
self._tokens_i += 1
token = self._tokens[self._tokens_i]
if not isinstance(token, Symbol) or token.is_constant:
self._parse_error("expected nonconstant symbol")
if self._tokens[self._tokens_i + 1] is not None:
self._parse_error("extra tokens at end of line")
return token
def _expect_str(self):
self._tokens_i += 1
token = self._tokens[self._tokens_i]
if not isinstance(token, str):
self._parse_error("expected string")
return token
def _expect_str_and_eol(self):
self._tokens_i += 1
token = self._tokens[self._tokens_i]
if not isinstance(token, str):
self._parse_error("expected string")
if self._tokens[self._tokens_i + 1] is not None:
self._parse_error("extra tokens at end of line")
return token
def _expect_expr_and_eol(self):
expr = self._parse_expr(True)
if self._peek_token() is not None:
self._parse_error("extra tokens at end of line")
return expr
def _check_token(self, token):
# If the next token is 'token', removes it and returns True
if self._tokens[self._tokens_i + 1] is token:
self._tokens_i += 1
return True
return False
#
# Preprocessor logic
#
def _parse_assignment(self, s):
# Parses a preprocessor variable assignment, registering the variable
# if it doesn't already exist. Also takes care of bare macros on lines
# (which are allowed, and can be useful for their side effects).
# Expand any macros in the left-hand side of the assignment (the
# variable name)
s = s.lstrip()
i = 0
while 1:
i = _assignment_lhs_fragment_match(s, i).end()
if s.startswith("$(", i):
s, i = self._expand_macro(s, i, ())
else:
break
if s.isspace():
# We also accept a bare macro on a line (e.g.
# $(warning-if,$(foo),ops)), provided it expands to a blank string
return
# Assigned variable
name = s[:i]
# Extract assignment operator (=, :=, or +=) and value
rhs_match = _assignment_rhs_match(s, i)
if not rhs_match:
self._parse_error("syntax error")
op, val = rhs_match.groups()
if name in self.variables:
# Already seen variable
var = self.variables[name]
else:
# New variable
var = Variable()
var.kconfig = self
var.name = name
var._n_expansions = 0
self.variables[name] = var
# += acts like = on undefined variables (defines a recursive
# variable)
if op == "+=":
op = "="
if op == "=":
var.is_recursive = True
var.value = val
elif op == ":=":
var.is_recursive = False
var.value = self._expand_whole(val, ())
else: # op == "+="
# += does immediate expansion if the variable was last set
# with :=
var.value += " " + (val if var.is_recursive else \
self._expand_whole(val, ()))
def _expand_whole(self, s, args):
# Expands preprocessor macros in all of 's'. Used whenever we don't
# have to worry about delimiters. See _expand_macro() re. the 'args'
# parameter.
#
# Returns the expanded string.
i = 0
while 1:
i = s.find("$(", i)
if i == -1:
break
s, i = self._expand_macro(s, i, args)
return s
def _expand_str(self, s, i, quote):
# Expands a quoted string starting at index 'i' in 's'. Handles both
# backslash escapes and macro expansion.
#
# Returns the expanded 's' (including the part before the string) and
# the index of the first character after the expanded string in 's'.
i += 1 # Skip over initial "/'
while 1:
match = _string_special_search(s, i)
if not match:
self._parse_error("unterminated string")
if match.group() == quote:
# Found the end of the string
return (s, match.end())
elif match.group() == "\\":
# Replace '\x' with 'x'. 'i' ends up pointing to the character
# after 'x', which allows macros to be canceled with '\$(foo)'.
i = match.end()
s = s[:match.start()] + s[i:]
elif match.group() == "$(":
# A macro call within the string
s, i = self._expand_macro(s, match.start(), ())
else:
# A ' quote within " quotes or vice versa
i += 1
def _expand_macro(self, s, i, args):
# Expands a macro starting at index 'i' in 's'. If this macro resulted
# from the expansion of another macro, 'args' holds the arguments
# passed to that macro.
#
# Returns the expanded 's' (including the part before the macro) and
# the index of the first character after the expanded macro in 's'.
start = i
i += 2 # Skip over "$("
# Start of current macro argument
arg_start = i
# Arguments of this macro call
new_args = []
while 1:
match = _macro_special_search(s, i)
if not match:
self._parse_error("missing end parenthesis in macro expansion")
if match.group() == ")":
# Found the end of the macro
new_args.append(s[arg_start:match.start()])
prefix = s[:start]
# $(1) is replaced by the first argument to the function, etc.,
# provided at least that many arguments were passed
try:
# Does the macro look like an integer, with a corresponding
# argument? If so, expand it to the value of the argument.
prefix += args[int(new_args[0])]
except (ValueError, IndexError):
# Regular variables are just functions without arguments,
# and also go through the function value path
prefix += self._fn_val(new_args)
return (prefix + s[match.end():],
len(prefix))
elif match.group() == ",":
# Found the end of a macro argument
new_args.append(s[arg_start:match.start()])
arg_start = i = match.end()
else: # match.group() == "$("
# A nested macro call within the macro
s, i = self._expand_macro(s, match.start(), args)
def _fn_val(self, args):
# Returns the result of calling the function args[0] with the arguments
# args[1..len(args)-1]. Plain variables are treated as functions
# without arguments.
fn = args[0]
if fn in self.variables:
var = self.variables[fn]
if len(args) == 1:
# Plain variable
if var._n_expansions:
self._parse_error("Preprocessor variable {} recursively "
"references itself".format(var.name))
elif var._n_expansions > 100:
# Allow functions to call themselves, but guess that functions
# that are overly recursive are stuck
self._parse_error("Preprocessor function {} seems stuck "
"in infinite recursion".format(var.name))
var._n_expansions += 1
res = self._expand_whole(self.variables[fn].value, args)
var._n_expansions -= 1
return res
if fn in self._functions:
# Built-in function
py_fn, min_arg, max_arg = self._functions[fn]
if not min_arg <= len(args) - 1 <= max_arg:
if min_arg == max_arg:
expected_args = min_arg
else:
expected_args = "{}-{}".format(min_arg, max_arg)
raise KconfigError("{}:{}: bad number of arguments in call "
"to {}, expected {}, got {}"
.format(self._filename, self._linenr, fn,
expected_args, len(args) - 1))
return py_fn(self, args)
# Environment variables are tried last
if fn in os.environ:
self.env_vars.add(fn)
return os.environ[fn]
return ""
#
# Parsing
#
def _make_and(self, e1, e2):
# Constructs an AND (&&) expression. Performs trivial simplification.
if e1 is self.y:
return e2
if e2 is self.y:
return e1
if e1 is self.n or e2 is self.n:
return self.n
return (AND, e1, e2)
def _make_or(self, e1, e2):
# Constructs an OR (||) expression. Performs trivial simplification.
if e1 is self.n:
return e2
if e2 is self.n:
return e1
if e1 is self.y or e2 is self.y:
return self.y
return (OR, e1, e2)
def _parse_block(self, end_token, parent, prev):
# Parses a block, which is the contents of either a file or an if,
# menu, or choice statement.
#
# end_token:
# The token that ends the block, e.g. _T_ENDIF ("endif") for ifs.
# None for files.
#
# parent:
# The parent menu node, corresponding to a menu, Choice, or 'if'.
# 'if's are flattened after parsing.
#
# prev:
# The previous menu node. New nodes will be added after this one (by
# modifying their 'next' pointer).
#
# 'prev' is reused to parse a list of child menu nodes (for a menu or
# Choice): After parsing the children, the 'next' pointer is assigned
# to the 'list' pointer to "tilt up" the children above the node.
#
# Returns the final menu node in the block (or 'prev' if the block is
# empty). This allows chaining.
# We might already have tokens from parsing a line to check if it's a
# property and discovering it isn't. self._has_tokens functions as a
# kind of "unget".
while self._has_tokens or self._next_line():
self._has_tokens = False
t0 = self._next_token()
if t0 is None:
continue
if t0 in (_T_CONFIG, _T_MENUCONFIG):
# The tokenizer allocates Symbol objects for us
sym = self._expect_nonconst_sym_and_eol()
self.defined_syms.append(sym)
node = MenuNode()
node.kconfig = self
node.item = sym
node.is_menuconfig = (t0 is _T_MENUCONFIG)
node.prompt = node.help = node.list = None
node.parent = parent
node.filename = self._filename
node.linenr = self._linenr
node.include_path = self._include_path
sym.nodes.append(node)
self._parse_properties(node)
if node.item.env_var:
if node.item.env_var in os.environ:
os.environ[node.item.name] = os.environ[node.item.env_var]
else:
os.environ[node.item.name] = ((node.defaults[0])[0]).name
if node.is_menuconfig and not node.prompt:
self._warn("the menuconfig symbol {} has no prompt"
.format(_name_and_loc(sym)))
# Tricky Python semantics: This assigns prev.next before prev
prev.next = prev = node
elif t0 in (_T_SOURCE, _T_RSOURCE, _T_OSOURCE, _T_ORSOURCE):
pattern = self._expect_str_and_eol()
# Check if the pattern is absolute and avoid stripping srctree
# from it below in that case. We must do the check before
# join()'ing, as srctree might be an absolute path.
isabs = os.path.isabs(pattern)
if t0 in (_T_RSOURCE, _T_ORSOURCE):
# Relative source
pattern = os.path.join(os.path.dirname(self._filename),
pattern)
# Sort the glob results to ensure a consistent ordering of
# Kconfig symbols, which indirectly ensures a consistent
# ordering in e.g. .config files
filenames = \
sorted(glob.iglob(os.path.join(self.srctree, pattern)))
if not filenames and t0 in (_T_SOURCE, _T_RSOURCE):
raise KconfigError("\n" + textwrap.fill(
"{}:{}: '{}' does not exist{}".format(
self._filename, self._linenr, pattern,
self._srctree_hint()),
80))
for filename in filenames:
self._enter_file(
filename,
# Unless an absolute path is passed to *source, strip
# the $srctree prefix from the filename. That way it
# appears without a $srctree prefix in
# MenuNode.filename, which is nice e.g. when generating
# documentation.
filename if isabs else
os.path.relpath(filename, self.srctree))
prev = self._parse_block(None, parent, prev)
self._leave_file()
elif t0 is end_token:
# We have reached the end of the block. Terminate the final
# node and return it.
prev.next = None
return prev
elif t0 is _T_IF:
node = MenuNode()
node.item = node.prompt = None
node.parent = parent
node.filename = self._filename
node.linenr = self._linenr
node.dep = self._expect_expr_and_eol()
self._parse_block(_T_ENDIF, node, node)
node.list = node.next
prev.next = prev = node
elif t0 is _T_MENU:
node = MenuNode()
node.kconfig = self
node.item = MENU
node.is_menuconfig = True
node.prompt = (self._expect_str_and_eol(), self.y)
node.visibility = self.y
node.parent = parent
node.filename = self._filename
node.linenr = self._linenr
node.include_path = self._include_path
self.menus.append(node)
self._parse_properties(node)
self._parse_block(_T_ENDMENU, node, node)
node.list = node.next
prev.next = prev = node
elif t0 is _T_COMMENT:
node = MenuNode()
node.kconfig = self
node.item = COMMENT
node.is_menuconfig = False
node.prompt = (self._expect_str_and_eol(), self.y)
node.list = None
node.parent = parent
node.filename = self._filename
node.linenr = self._linenr
node.include_path = self._include_path
self.comments.append(node)
self._parse_properties(node)
prev.next = prev = node
elif t0 is _T_CHOICE:
if self._peek_token() is None:
choice = Choice()
choice.direct_dep = self.n
self.choices.append(choice)
else:
# Named choice
name = self._expect_str_and_eol()
choice = self.named_choices.get(name)
if not choice:
choice = Choice()
choice.name = name
choice.direct_dep = self.n
self.choices.append(choice)
self.named_choices[name] = choice
choice.kconfig = self
node = MenuNode()
node.kconfig = self
node.item = choice
node.is_menuconfig = True
node.prompt = node.help = None
node.parent = parent
node.filename = self._filename
node.linenr = self._linenr
node.include_path = self._include_path
choice.nodes.append(node)
self._parse_properties(node)
self._parse_block(_T_ENDCHOICE, node, node)
node.list = node.next
prev.next = prev = node
elif t0 is _T_MAINMENU:
self.top_node.prompt = (self._expect_str_and_eol(), self.y)
self.top_node.filename = self._filename
self.top_node.linenr = self._linenr
else:
self._parse_error("unrecognized construct")
# End of file reached. Terminate the final node and return it.
if end_token:
raise KconfigError("Unexpected end of file " + self._filename)
prev.next = None
return prev
def _parse_cond(self):
# Parses an optional 'if <expr>' construct and returns the parsed
# <expr>, or self.y if the next token is not _T_IF
return self._expect_expr_and_eol() if self._check_token(_T_IF) \
else self.y
def _parse_properties(self, node):
# Parses and adds properties to the MenuNode 'node' (type, 'prompt',
# 'default's, etc.) Properties are later copied up to symbols and
# choices in a separate pass after parsing, in _add_props_to_sc().
#
# An older version of this code added properties directly to symbols
# and choices instead of to their menu nodes (and handled dependency
# propagation simultaneously), but that loses information on where a
# property is added when a symbol or choice is defined in multiple
# locations. Some Kconfig configuration systems rely heavily on such
# symbols, and better docs can be generated by keeping track of where
# properties are added.
#
# node:
# The menu node we're parsing properties on
# Dependencies from 'depends on'. Will get propagated to the properties
# below.
node.dep = self.y
while self._next_line():
t0 = self._next_token()
if t0 is None:
continue
if t0 in _TYPE_TOKENS:
self._set_type(node, _TOKEN_TO_TYPE[t0])
if self._peek_token() is not None:
self._parse_prompt(node)
elif t0 is _T_DEPENDS:
if not self._check_token(_T_ON):
self._parse_error('expected "on" after "depends"')
node.dep = self._make_and(node.dep,
self._expect_expr_and_eol())
elif t0 is _T_HELP:
self._parse_help(node)
elif t0 is _T_SELECT:
if not isinstance(node.item, Symbol):
self._parse_error("only symbols can select")
node.selects.append((self._expect_nonconst_sym(),
self._parse_cond()))
elif t0 is _T_IMPLY:
if not isinstance(node.item, Symbol):
self._parse_error("only symbols can imply")
node.implies.append((self._expect_nonconst_sym(),
self._parse_cond()))
elif t0 is _T_DEFAULT:
node.defaults.append((self._parse_expr(False),
self._parse_cond()))
elif t0 in (_T_DEF_BOOL, _T_DEF_TRISTATE, _T_DEF_INT, _T_DEF_HEX,
_T_DEF_STRING):
self._set_type(node, _TOKEN_TO_TYPE[t0])
node.defaults.append((self._parse_expr(False),
self._parse_cond()))
elif t0 is _T_PROMPT:
self._parse_prompt(node)
elif t0 is _T_RANGE:
node.ranges.append((self._expect_sym(),
self._expect_sym(),
self._parse_cond()))
elif t0 is _T_OPTION:
if self._check_token(_T_ENV):
if not self._check_token(_T_EQUAL):
self._parse_error('expected "=" after "env"')
env_var = self._expect_str_and_eol()
node.item.env_var = env_var
if env_var in os.environ:
node.defaults.append(
(self._lookup_const_sym(os.environ[env_var]),
self.y))
else:
self._warn("{1} has 'option env=\"{0}\"', "
"but the environment variable {0} is not "
"set".format(node.item.name, env_var),
self._filename, self._linenr)
if env_var != node.item.name:
self._warn("Kconfiglib expands environment variables "
"in strings directly, meaning you do not "
"need 'option env=...' \"bounce\" symbols. "
"For compatibility with the C tools, "
"rename {} to {} (so that the symbol name "
"matches the environment variable name)."
.format(node.item.name, env_var),
self._filename, self._linenr)
elif self._check_token(_T_DEFCONFIG_LIST):
if not self.defconfig_list:
self.defconfig_list = node.item
else:
self._warn("'option defconfig_list' set on multiple "
"symbols ({0} and {1}). Only {0} will be "
"used.".format(self.defconfig_list.name,
node.item.name),
self._filename, self._linenr)
elif self._check_token(_T_MODULES):
# To reduce warning spam, only warn if 'option modules' is
# set on some symbol that isn't MODULES, which should be
# safe. I haven't run into any projects that make use
# modules besides the kernel yet, and there it's likely to
# keep being called "MODULES".
if node.item is not self.modules:
self._warn("the 'modules' option is not supported. "
"Let me know if this is a problem for you, "
"as it wouldn't be that hard to implement. "
"Note that modules are supported -- "
"Kconfiglib just assumes the symbol name "
"MODULES, like older versions of the C "
"implementation did when 'option modules' "
"wasn't used.",
self._filename, self._linenr)
elif self._check_token(_T_ALLNOCONFIG_Y):
if not isinstance(node.item, Symbol):
self._parse_error("the 'allnoconfig_y' option is only "
"valid for symbols")
node.item.is_allnoconfig_y = True
else:
self._parse_error("unrecognized option")
elif t0 is _T_VISIBLE:
if not self._check_token(_T_IF):
self._parse_error('expected "if" after "visible"')
node.visibility = self._make_and(node.visibility,
self._expect_expr_and_eol())
elif t0 is _T_OPTIONAL:
if not isinstance(node.item, Choice):
self._parse_error('"optional" is only valid for choices')
node.item.is_optional = True
else:
# Reuse the tokens for the non-property line later
self._has_tokens = True
self._tokens_i = -1
return
def _set_type(self, node, new_type):
if node.item.orig_type not in (UNKNOWN, new_type):
self._warn("{} defined with multiple types, {} will be used"
.format(_name_and_loc(node.item),
TYPE_TO_STR[new_type]))
node.item.orig_type = new_type
def _parse_prompt(self, node):
# 'prompt' properties override each other within a single definition of
# a symbol, but additional prompts can be added by defining the symbol
# multiple times
if node.prompt:
self._warn(_name_and_loc(node.item) +
" defined with multiple prompts in single location")
prompt = self._expect_str()
if prompt != prompt.strip():
self._warn(_name_and_loc(node.item) +
" has leading or trailing whitespace in its prompt")
# This avoid issues for e.g. reStructuredText documentation, where
# '*prompt *' is invalid
prompt = prompt.strip()
node.prompt = (prompt, self._parse_cond())
def _parse_help(self, node):
# Find first non-blank (not all-space) line and get its indentation
if node.help is not None:
self._warn(_name_and_loc(node.item) +
" defined with more than one help text -- only the "
"last one will be used")
# Small optimization. This code is pretty hot.
readline = self._file.readline
while 1:
line = readline()
self._linenr += 1
if not line or not line.isspace():
break
if not line:
self._warn(_name_and_loc(node.item) +
" has 'help' but empty help text")
node.help = ""
return
indent = _indentation(line)
if indent == 0:
# If the first non-empty lines has zero indent, there is no help
# text
self._warn(_name_and_loc(node.item) +
" has 'help' but empty help text")
node.help = ""
self._saved_line = line # "Unget" the line
return
# The help text goes on till the first non-empty line with less indent
# than the first line
help_lines = []
# Small optimizations
add_help_line = help_lines.append
indentation = _indentation
while line and (line.isspace() or indentation(line) >= indent):
# De-indent 'line' by 'indent' spaces and rstrip() it to remove any
# newlines (which gets rid of other trailing whitespace too, but
# that's fine).
#
# This prepares help text lines in a speedy way: The [indent:]
# might already remove trailing newlines for lines shorter than
# indent (e.g. empty lines). The rstrip() makes it consistent,
# meaning we can join the lines with "\n" later.
add_help_line(line.expandtabs()[indent:].rstrip())
line = readline()
self._linenr += len(help_lines)
node.help = "\n".join(help_lines).rstrip() + "\n"
self._saved_line = line # "Unget" the line
def _parse_expr(self, transform_m):
# Parses an expression from the tokens in Kconfig._tokens using a
# simple top-down approach. See the module docstring for the expression
# format.
#
# transform_m:
# True if m should be rewritten to m && MODULES. See the
# Kconfig.eval_string() documentation.
# Grammar:
#
# expr: and_expr ['||' expr]
# and_expr: factor ['&&' and_expr]
# factor: <symbol> ['='/'!='/'<'/... <symbol>]
# '!' factor
# '(' expr ')'
#
# It helps to think of the 'expr: and_expr' case as a single-operand OR
# (no ||), and of the 'and_expr: factor' case as a single-operand AND
# (no &&). Parsing code is always a bit tricky.
# Mind dump: parse_factor() and two nested loops for OR and AND would
# work as well. The straightforward implementation there gives a
# (op, (op, (op, A, B), C), D) parse for A op B op C op D. Representing
# expressions as (op, [list of operands]) instead goes nicely with that
# version, but is wasteful for short expressions and complicates
# expression evaluation and other code that works on expressions (more
# complicated code likely offsets any performance gain from less
# recursion too). If we also try to optimize the list representation by
# merging lists when possible (e.g. when ANDing two AND expressions),
# we end up allocating a ton of lists instead of reusing expressions,
# which is bad.
and_expr = self._parse_and_expr(transform_m)
# Return 'and_expr' directly if we have a "single-operand" OR.
# Otherwise, parse the expression on the right and make an OR node.
# This turns A || B || C || D into (OR, A, (OR, B, (OR, C, D))).
return and_expr \
if not self._check_token(_T_OR) else \
(OR, and_expr, self._parse_expr(transform_m))
def _parse_and_expr(self, transform_m):
factor = self._parse_factor(transform_m)
# Return 'factor' directly if we have a "single-operand" AND.
# Otherwise, parse the right operand and make an AND node. This turns
# A && B && C && D into (AND, A, (AND, B, (AND, C, D))).
return factor \
if not self._check_token(_T_AND) else \
(AND, factor, self._parse_and_expr(transform_m))
def _parse_factor(self, transform_m):
token = self._next_token()
if isinstance(token, Symbol):
# Plain symbol or relation
next_token = self._peek_token()
if next_token not in _RELATIONS:
# Plain symbol
# For conditional expressions ('depends on <expr>',
# '... if <expr>', etc.), m is rewritten to m && MODULES.
if transform_m and token is self.m:
return (AND, self.m, self.modules)
return token
# Relation
#
# _T_EQUAL, _T_UNEQUAL, etc., deliberately have the same values as
# EQUAL, UNEQUAL, etc., so we can just use the token directly
return (self._next_token(), token, self._expect_sym())
if token is _T_NOT:
# token == _T_NOT == NOT
return (token, self._parse_factor(transform_m))
if token is _T_OPEN_PAREN:
expr_parse = self._parse_expr(transform_m)
if self._check_token(_T_CLOSE_PAREN):
return expr_parse
self._parse_error("malformed expression")
#
# Caching and invalidation
#
def _build_dep(self):
# Populates the Symbol/Choice._dependents sets, which contain all other
# items (symbols and choices) that immediately depend on the item in
# the sense that changing the value of the item might affect the value
# of the dependent items. This is used for caching/invalidation.
#
# The calculated sets might be larger than necessary as we don't do any
# complex analysis of the expressions.
# Only calculate _dependents for defined symbols. Constant and
# undefined symbols could theoretically be selected/implied, but it
# wouldn't change their value, so it's not a true dependency.
for sym in self.unique_defined_syms:
# Symbols depend on the following:
# The prompt conditions
for node in sym.nodes:
if node.prompt:
_make_depend_on(sym, node.prompt[1])
# The default values and their conditions
for value, cond in sym.defaults:
_make_depend_on(sym, value)
_make_depend_on(sym, cond)
# The reverse and weak reverse dependencies
_make_depend_on(sym, sym.rev_dep)
_make_depend_on(sym, sym.weak_rev_dep)
# The ranges along with their conditions
for low, high, cond in sym.ranges:
_make_depend_on(sym, low)
_make_depend_on(sym, high)
_make_depend_on(sym, cond)
# The direct dependencies. This is usually redundant, as the direct
# dependencies get propagated to properties, but it's needed to get
# invalidation solid for 'imply', which only checks the direct
# dependencies (even if there are no properties to propagate it
# to).
_make_depend_on(sym, sym.direct_dep)
# In addition to the above, choice symbols depend on the choice
# they're in, but that's handled automatically since the Choice is
# propagated to the conditions of the properties before
# _build_dep() runs.
for choice in self.unique_choices:
# Choices depend on the following:
# The prompt conditions
for node in choice.nodes:
if node.prompt:
_make_depend_on(choice, node.prompt[1])
# The default symbol conditions
for _, cond in choice.defaults:
_make_depend_on(choice, cond)
def _add_choice_deps(self):
# Choices also depend on the choice symbols themselves, because the
# y-mode selection of the choice might change if a choice symbol's
# visibility changes.
#
# We add these dependencies separately after dependency loop detection.
# The invalidation algorithm can handle the resulting
# <choice symbol> <-> <choice> dependency loops, but they make loop
# detection awkward.
for choice in self.unique_choices:
# The choice symbols themselves, because the y mode selection might
# change if a choice symbol's visibility changes
for sym in choice.syms:
sym._dependents.add(choice)
def _invalidate_all(self):
# Undefined symbols never change value and don't need to be
# invalidated, so we can just iterate over defined symbols.
# Invalidating constant symbols would break things horribly.
for sym in self.unique_defined_syms:
sym._invalidate()
for choice in self.unique_choices:
choice._invalidate()
#
# Post-parsing menu tree processing, including dependency propagation and
# implicit submenu creation
#
def _finalize_tree(self, node, visible_if):
# Propagates properties and dependencies, creates implicit menus (see
# kconfig-language.txt), removes 'if' nodes, and finalizes choices.
# This pretty closely mirrors menu_finalize() from the C
# implementation, with some minor tweaks (MenuNode holds lists of
# properties instead of each property having a MenuNode pointer, for
# example).
#
# node:
# The current "parent" menu node, from which we propagate
# dependencies
#
# visible_if:
# Dependencies from 'visible if' on parent menus. These are added to
# the prompts of symbols and choices.
if node.list:
# The menu node is a choice, menu, or if. Finalize each child in
# it.
if node.item is MENU:
visible_if = self._make_and(visible_if, node.visibility)
# Propagate the menu node's dependencies to each child menu node.
#
# The recursive _finalize_tree() calls assume that the current
# "level" in the tree has already had dependencies propagated. This
# makes e.g. implicit submenu creation easier, because it needs to
# look ahead.
self._propagate_deps(node, visible_if)
# Finalize the children
cur = node.list
while cur:
self._finalize_tree(cur, visible_if)
cur = cur.next
elif isinstance(node.item, Symbol):
# Add the node's non-node-specific properties (defaults, ranges,
# etc.) to the Symbol
self._add_props_to_sc(node)
# See if we can create an implicit menu rooted at the Symbol and
# finalize each child menu node in that menu if so, like for the
# choice/menu/if case above
cur = node
while cur.next and _auto_menu_dep(node, cur.next):
# This also makes implicit submenu creation work recursively,
# with implicit menus inside implicit menus
self._finalize_tree(cur.next, visible_if)
cur = cur.next
cur.parent = node
if cur is not node:
# Found symbols that should go in an implicit submenu. Tilt
# them up above us.
node.list = node.next
node.next = cur.next
cur.next = None
if node.list:
# We have a parent node with individually finalized child nodes. Do
# final steps to finalize this "level" in the menu tree.
_flatten(node.list)
_remove_ifs(node)
# Empty choices (node.list None) are possible, so this needs to go
# outside
if isinstance(node.item, Choice):
# Add the node's non-node-specific properties to the choice
self._add_props_to_sc(node)
_finalize_choice(node)
def _propagate_deps(self, node, visible_if):
# Propagates 'node's dependencies to its child menu nodes
# If the parent node holds a Choice, we use the Choice itself as the
# parent dependency. This makes sense as the value (mode) of the choice
# limits the visibility of the contained choice symbols. The C
# implementation works the same way.
#
# Due to the similar interface, Choice works as a drop-in replacement
# for Symbol here.
basedep = node.item if isinstance(node.item, Choice) else node.dep
cur = node.list
while cur:
cur.dep = dep = self._make_and(cur.dep, basedep)
# Propagate dependencies to prompt
if cur.prompt:
cur.prompt = (cur.prompt[0],
self._make_and(cur.prompt[1], dep))
if isinstance(cur.item, (Symbol, Choice)):
sc = cur.item
# Propagate 'visible if' dependencies to the prompt
if cur.prompt:
cur.prompt = (cur.prompt[0],
self._make_and(cur.prompt[1], visible_if))
# Propagate dependencies to defaults
if cur.defaults:
cur.defaults = [(default, self._make_and(cond, dep))
for default, cond in cur.defaults]
# Propagate dependencies to ranges
if cur.ranges:
cur.ranges = [(low, high, self._make_and(cond, dep))
for low, high, cond in cur.ranges]
# Propagate dependencies to selects
if cur.selects:
cur.selects = [(target, self._make_and(cond, dep))
for target, cond in cur.selects]
# Propagate dependencies to implies
if cur.implies:
cur.implies = [(target, self._make_and(cond, dep))
for target, cond in cur.implies]
cur = cur.next
def _add_props_to_sc(self, node):
# Copies properties from the menu node 'node' up to its contained
# symbol or choice.
#
# This can't be rolled into _propagate_deps(), because that function
# traverses the menu tree roughly breadth-first order, meaning
# properties on symbols and choices defined in multiple locations could
# end up in the wrong order.
# Symbol or choice
sc = node.item
# See the Symbol class docstring
sc.direct_dep = self._make_or(sc.direct_dep, node.dep)
sc.defaults += node.defaults
# The properties below aren't available on choices
if node.ranges:
sc.ranges += node.ranges
if node.selects:
sc.selects += node.selects
# Modify the reverse dependencies of the selected symbol
for target, cond in node.selects:
target.rev_dep = self._make_or(
target.rev_dep,
self._make_and(sc, cond))
if node.implies:
sc.implies += node.implies
# Modify the weak reverse dependencies of the implied
# symbol
for target, cond in node.implies:
target.weak_rev_dep = self._make_or(
target.weak_rev_dep,
self._make_and(sc, cond))
#
# Misc.
#
def _parse_error(self, msg):
if self._filename is None:
loc = ""
else:
loc = "{}:{}: ".format(self._filename, self._linenr)
raise KconfigError(
"{}couldn't parse '{}': {}".format(loc, self._line.rstrip(), msg))
def _open(self, filename, mode):
# open() wrapper:
#
# - Enable universal newlines mode on Python 2 to ease
# interoperability between Linux and Windows. It's already the
# default on Python 3.
#
# The "U" flag would currently work for both Python 2 and 3, but it's
# deprecated on Python 3, so play it future-safe.
#
# A simpler solution would be to use io.open(), which defaults to
# universal newlines on both Python 2 and 3 (and is an alias for
# open() on Python 3), but it's appreciably slower on Python 2:
#
# Parsing x86 Kconfigs on Python 2
#
# with open(..., "rU"):
#
# real 0m0.930s
# user 0m0.905s
# sys 0m0.025s
#
# with io.open():
#
# real 0m1.069s
# user 0m1.040s
# sys 0m0.029s
#
# There's no appreciable performance difference between "r" and
# "rU" for parsing performance on Python 2.
#
# - For Python 3, force the encoding. Forcing the encoding on Python 2
# turns strings into Unicode strings, which gets messy. Python 2
# doesn't decode regular strings anyway.
return open(filename, "rU" if mode == "r" else mode) if _IS_PY2 else \
open(filename, mode, encoding=self._encoding)
def _check_undef_syms(self):
# Prints warnings for all references to undefined symbols within the
# Kconfig files
for sym in (self.syms.viewvalues if _IS_PY2 else self.syms.values)():
# - sym.nodes empty means the symbol is undefined (has no
# definition locations)
#
# - Due to Kconfig internals, numbers show up as undefined Kconfig
# symbols, but shouldn't be flagged
#
# - The MODULES symbol always exists
if not sym.nodes and not _is_num(sym.name) and \
sym.name != "MODULES":
msg = "undefined symbol {}:".format(sym.name)
for node in self.node_iter():
if sym in node.referenced:
msg += "\n\n- Referenced at {}:{}:\n\n{}" \
.format(node.filename, node.linenr, node)
self._warn(msg)
def _warn(self, msg, filename=None, linenr=None):
# For printing general warnings
if self._warnings_enabled:
msg = "warning: " + msg
if filename is not None:
msg = "{}:{}: {}".format(filename, linenr, msg)
self.warnings.append(msg)
if self._warn_to_stderr:
sys.stderr.write(msg + "\n")
def _warn_undef_assign(self, msg, filename=None, linenr=None):
# See the class documentation
if self._warn_for_undef_assign:
self._warn(msg, filename, linenr)
def _warn_undef_assign_load(self, name, val, filename, linenr):
# Special version for load_config()
self._warn_undef_assign(
'attempt to assign the value "{}" to the undefined symbol {}'
.format(val, name), filename, linenr)
def _warn_redun_assign(self, msg, filename=None, linenr=None):
# See the class documentation
if self._warn_for_redun_assign:
self._warn(msg, filename, linenr)
def _srctree_hint(self):
# Hint printed when Kconfig files can't be found or .config files can't
# be opened
return ". Perhaps the $srctree environment variable ({}) " \
"is set incorrectly. Note that the current value of $srctree " \
"is saved when the Kconfig instance is created (for " \
"consistency and to cleanly separate instances)." \
.format("set to '{}'".format(self.srctree) if self.srctree
else "unset or blank")
class Symbol(object):
"""
Represents a configuration symbol:
(menu)config FOO
...
The following attributes are available. They should be viewed as read-only,
and some are implemented through @property magic (but are still efficient
to access due to internal caching).
Note: Prompts, help texts, and locations are stored in the Symbol's
MenuNode(s) rather than in the Symbol itself. Check the MenuNode class and
the Symbol.nodes attribute. This organization matches the C tools.
name:
The name of the symbol, e.g. "FOO" for 'config FOO'.
type:
The type of the symbol. One of BOOL, TRISTATE, STRING, INT, HEX, UNKNOWN.
UNKNOWN is for undefined symbols, (non-special) constant symbols, and
symbols defined without a type.
When running without modules (MODULES having the value n), TRISTATE
symbols magically change type to BOOL. This also happens for symbols
within choices in "y" mode. This matches the C tools, and makes sense for
menuconfig-like functionality.
orig_type:
The type as given in the Kconfig file, without any magic applied. Used
when printing the symbol.
str_value:
The value of the symbol as a string. Gives the value for string/int/hex
symbols. For bool/tristate symbols, gives "n", "m", or "y".
This is the symbol value that's used in relational expressions
(A = B, A != B, etc.)
Gotcha: For int/hex symbols, the exact format of the value must often be
preserved (e.g., when writing a .config file), hence why you can't get it
directly as an int. Do int(int_sym.str_value) or
int(hex_sym.str_value, 16) to get the integer value.
tri_value:
The tristate value of the symbol as an integer. One of 0, 1, 2,
representing n, m, y. Always 0 (n) for non-bool/tristate symbols.
This is the symbol value that's used outside of relation expressions
(A, !A, A && B, A || B).
assignable:
A tuple containing the tristate user values that can currently be
assigned to the symbol (that would be respected), ordered from lowest (0,
representing n) to highest (2, representing y). This corresponds to the
selections available in the menuconfig interface. The set of assignable
values is calculated from the symbol's visibility and selects/implies.
Returns the empty set for non-bool/tristate symbols and for symbols with
visibility n. The other possible values are (0, 2), (0, 1, 2), (1, 2),
(1,), and (2,). A (1,) or (2,) result means the symbol is visible but
"locked" to m or y through a select, perhaps in combination with the
visibility. menuconfig represents this as -M- and -*-, respectively.
For string/hex/int symbols, check if Symbol.visibility is non-0 (non-n)
instead to determine if the value can be changed.
Some handy 'assignable' idioms:
# Is 'sym' an assignable (visible) bool/tristate symbol?
if sym.assignable:
# What's the highest value it can be assigned? [-1] in Python
# gives the last element.
sym_high = sym.assignable[-1]
# The lowest?
sym_low = sym.assignable[0]
# Can the symbol be set to at least m?
if sym.assignable[-1] >= 1:
...
# Can the symbol be set to m?
if 1 in sym.assignable:
...
visibility:
The visibility of the symbol. One of 0, 1, 2, representing n, m, y. See
the module documentation for an overview of symbol values and visibility.
user_value:
The user value of the symbol. None if no user value has been assigned
(via Kconfig.load_config() or Symbol.set_value()).
Holds 0, 1, or 2 for bool/tristate symbols, and a string for the other
symbol types.
WARNING: Do not assign directly to this. It will break things. Use
Symbol.set_value().
config_string:
The .config assignment string that would get written out for the symbol
by Kconfig.write_config(). Returns the empty string if no .config
assignment would get written out. In general, visible symbols, symbols
with (active) defaults, and selected symbols get written out.
nodes:
A list of MenuNodes for this symbol. Will contain a single MenuNode for
most symbols. Undefined and constant symbols have an empty nodes list.
Symbols defined in multiple locations get one node for each location.
choice:
Holds the parent Choice for choice symbols, and None for non-choice
symbols. Doubles as a flag for whether a symbol is a choice symbol.
defaults:
List of (default, cond) tuples for the symbol's 'default' properties. For
example, 'default A && B if C || D' is represented as
((AND, A, B), (OR, C, D)). If no condition was given, 'cond' is
self.kconfig.y.
Note that 'depends on' and parent dependencies are propagated to
'default' conditions.
selects:
List of (symbol, cond) tuples for the symbol's 'select' properties. For
example, 'select A if B && C' is represented as (A, (AND, B, C)). If no
condition was given, 'cond' is self.kconfig.y.
Note that 'depends on' and parent dependencies are propagated to 'select'
conditions.
implies:
Like 'selects', for imply.
ranges:
List of (low, high, cond) tuples for the symbol's 'range' properties. For
example, 'range 1 2 if A' is represented as (1, 2, A). If there is no
condition, 'cond' is self.config.y.
Note that 'depends on' and parent dependencies are propagated to 'range'
conditions.
Gotcha: 1 and 2 above will be represented as (undefined) Symbols rather
than plain integers. Undefined symbols get their name as their string
value, so this works out. The C tools work the same way.
rev_dep:
Reverse dependency expression from other symbols selecting this symbol.
Multiple selections get ORed together. A condition on a select is ANDed
with the selecting symbol.
For example, if A has 'select FOO' and B has 'select FOO if C', then
FOO's rev_dep will be (OR, A, (AND, B, C)).
weak_rev_dep:
Like rev_dep, for imply.
direct_dep:
The 'depends on' dependencies. If a symbol is defined in multiple
locations, the dependencies at each location are ORed together.
Internally, this is used to implement 'imply', which only applies if the
implied symbol has expr_value(self.direct_dep) != 0. 'depends on' and
parent dependencies are automatically propagated to the conditions of
properties, so normally it's redundant to check the direct dependencies.
referenced:
A set() with all symbols and choices referenced in the properties and
property conditions of the symbol.
Also includes dependencies inherited from surrounding menus and if's.
Choices appear in the dependencies of choice symbols.
env_var:
If the Symbol has an 'option env="FOO"' option, this contains the name
("FOO") of the environment variable. None for symbols without no
'option env'.
'option env="FOO"' acts like a 'default' property whose value is the
value of $FOO.
Symbols with 'option env' are never written out to .config files, even if
they are visible. env_var corresponds to a flag called SYMBOL_AUTO in the
C implementation.
is_allnoconfig_y:
True if the symbol has 'option allnoconfig_y' set on it. This has no
effect internally (except when printing symbols), but can be checked by
scripts.
is_constant:
True if the symbol is a constant (quoted) symbol.
kconfig:
The Kconfig instance this symbol is from.
"""
__slots__ = (
"_cached_assignable",
"_cached_str_val",
"_cached_tri_val",
"_cached_vis",
"_dependents",
"_old_val",
"_visited",
"_was_set",
"_write_to_conf",
"choice",
"defaults",
"direct_dep",
"env_var",
"implies",
"is_allnoconfig_y",
"is_constant",
"kconfig",
"name",
"nodes",
"orig_type",
"ranges",
"rev_dep",
"selects",
"user_value",
"weak_rev_dep",
)
#
# Public interface
#
@property
def type(self):
"""
See the class documentation.
"""
if self.orig_type is TRISTATE and \
((self.choice and self.choice.tri_value == 2) or
not self.kconfig.modules.tri_value):
return BOOL
return self.orig_type
@property
def str_value(self):
"""
See the class documentation.
"""
if self._cached_str_val is not None:
return self._cached_str_val
if self.orig_type in (BOOL, TRISTATE):
# Also calculates the visibility, so invalidation safe
self._cached_str_val = TRI_TO_STR[self.tri_value]
return self._cached_str_val
# As a quirk of Kconfig, undefined symbols get their name as their
# string value. This is why things like "FOO = bar" work for seeing if
# FOO has the value "bar".
if self.orig_type is UNKNOWN:
self._cached_str_val = self.name
return self.name
val = ""
# Warning: See Symbol._rec_invalidate(), and note that this is a hidden
# function call (property magic)
vis = self.visibility
self._write_to_conf = (vis != 0)
if self.orig_type in (INT, HEX):
# The C implementation checks the user value against the range in a
# separate code path (post-processing after loading a .config).
# Checking all values here instead makes more sense for us. It
# requires that we check for a range first.
base = _TYPE_TO_BASE[self.orig_type]
# Check if a range is in effect
for low_expr, high_expr, cond in self.ranges:
if expr_value(cond):
has_active_range = True
# The zeros are from the C implementation running strtoll()
# on empty strings
low = int(low_expr.str_value, base) if \
_is_base_n(low_expr.str_value, base) else 0
high = int(high_expr.str_value, base) if \
_is_base_n(high_expr.str_value, base) else 0
break
else:
has_active_range = False
# Defaults are used if the symbol is invisible, lacks a user value,
# or has an out-of-range user value.
use_defaults = True
if vis and self.user_value:
user_val = int(self.user_value, base)
if has_active_range and not low <= user_val <= high:
num2str = str if base == 10 else hex
self.kconfig._warn(
"user value {} on the {} symbol {} ignored due to "
"being outside the active range ([{}, {}]) -- falling "
"back on defaults"
.format(num2str(user_val), TYPE_TO_STR[self.orig_type],
_name_and_loc(self),
num2str(low), num2str(high)))
else:
# If the user value is well-formed and satisfies range
# contraints, it is stored in exactly the same form as
# specified in the assignment (with or without "0x", etc.)
val = self.user_value
use_defaults = False
if use_defaults:
# No user value or invalid user value. Look at defaults.
# Used to implement the warning below
has_default = False
for val_sym, cond in self.defaults:
if expr_value(cond):
has_default = self._write_to_conf = True
val = val_sym.str_value
if _is_base_n(val, base):
val_num = int(val, base)
else:
val_num = 0 # strtoll() on empty string
break
else:
val_num = 0 # strtoll() on empty string
# This clamping procedure runs even if there's no default
if has_active_range:
clamp = None
if val_num < low:
clamp = low
elif val_num > high:
clamp = high
if clamp is not None:
# The value is rewritten to a standard form if it is
# clamped
val = str(clamp) \
if self.orig_type is INT else \
hex(clamp)
if has_default:
num2str = str if base == 10 else hex
self.kconfig._warn(
"default value {} on {} clamped to {} due to "
"being outside the active range ([{}, {}])"
.format(val_num, _name_and_loc(self),
num2str(clamp), num2str(low),
num2str(high)))
elif self.orig_type is STRING:
if vis and self.user_value is not None:
# If the symbol is visible and has a user value, use that
val = self.user_value
else:
# Otherwise, look at defaults
for val_sym, cond in self.defaults:
if expr_value(cond):
val = val_sym.str_value
self._write_to_conf = True
break
# env_var corresponds to SYMBOL_AUTO in the C implementation, and is
# also set on the defconfig_list symbol there. Test for the
# defconfig_list symbol explicitly instead here, to avoid a nonsensical
# env_var setting and the defconfig_list symbol being printed
# incorrectly. This code is pretty cold anyway.
if self.env_var is not None or self is self.kconfig.defconfig_list:
self._write_to_conf = False
self._cached_str_val = val
return val
@property
def tri_value(self):
"""
See the class documentation.
"""
if self._cached_tri_val is not None:
return self._cached_tri_val
if self.orig_type not in (BOOL, TRISTATE):
if self.orig_type is not UNKNOWN:
# Would take some work to give the location here
self.kconfig._warn(
"The {} symbol {} is being evaluated in a logical context "
"somewhere. It will always evaluate to n."
.format(TYPE_TO_STR[self.orig_type], _name_and_loc(self)))
self._cached_tri_val = 0
return 0
# Warning: See Symbol._rec_invalidate(), and note that this is a hidden
# function call (property magic)
vis = self.visibility
self._write_to_conf = (vis != 0)
val = 0
if not self.choice:
# Non-choice symbol
if vis and self.user_value is not None:
# If the symbol is visible and has a user value, use that
val = min(self.user_value, vis)
else:
# Otherwise, look at defaults and weak reverse dependencies
# (implies)
for default, cond in self.defaults:
cond_val = expr_value(cond)
if cond_val:
val = min(expr_value(default), cond_val)
if val:
self._write_to_conf = True
break
# Weak reverse dependencies are only considered if our
# direct dependencies are met
weak_rev_dep_val = expr_value(self.weak_rev_dep)
if weak_rev_dep_val and expr_value(self.direct_dep):
val = max(weak_rev_dep_val, val)
self._write_to_conf = True
# Reverse (select-related) dependencies take precedence
rev_dep_val = expr_value(self.rev_dep)
if rev_dep_val:
if expr_value(self.direct_dep) < rev_dep_val:
self._warn_select_unsatisfied_deps()
val = max(rev_dep_val, val)
self._write_to_conf = True
# m is promoted to y for (1) bool symbols and (2) symbols with a
# weak_rev_dep (from imply) of y
if val == 1 and \
(self.type is BOOL or expr_value(self.weak_rev_dep) == 2):
val = 2
elif vis == 2:
# Visible choice symbol in y-mode choice. The choice mode limits
# the visibility of choice symbols, so it's sufficient to just
# check the visibility of the choice symbols themselves.
val = 2 if self.choice.selection is self else 0
elif vis and self.user_value:
# Visible choice symbol in m-mode choice, with set non-0 user value
val = 1
self._cached_tri_val = val
return val
@property
def assignable(self):
"""
See the class documentation.
"""
if self._cached_assignable is None:
self._cached_assignable = self._assignable()
return self._cached_assignable
@property
def visibility(self):
"""
See the class documentation.
"""
if self._cached_vis is None:
self._cached_vis = _visibility(self)
return self._cached_vis
@property
def config_string(self):
"""
See the class documentation.
"""
# Note: _write_to_conf is determined when the value is calculated. This
# is a hidden function call due to property magic.
val = self.str_value
if not self._write_to_conf:
return ""
if self.orig_type in (BOOL, TRISTATE):
return "{}{}={}\n" \
.format(self.kconfig.config_prefix, self.name, val) \
if val != "n" else \
"# {}{} is not set\n" \
.format(self.kconfig.config_prefix, self.name)
if self.orig_type in (INT, HEX):
return "{}{}={}\n" \
.format(self.kconfig.config_prefix, self.name, val)
if self.orig_type is STRING:
return '{}{}="{}"\n' \
.format(self.kconfig.config_prefix, self.name, escape(val))
_internal_error("Internal error while creating .config: unknown "
'type "{}".'.format(self.orig_type))
def set_value(self, value):
"""
Sets the user value of the symbol.
Equal in effect to assigning the value to the symbol within a .config
file. For bool and tristate symbols, use the 'assignable' attribute to
check which values can currently be assigned. Setting values outside
'assignable' will cause Symbol.user_value to differ from
Symbol.str/tri_value (be truncated down or up).
Setting a choice symbol to 2 (y) sets Choice.user_selection to the
choice symbol in addition to setting Symbol.user_value.
Choice.user_selection is considered when the choice is in y mode (the
"normal" mode).
Other symbols that depend (possibly indirectly) on this symbol are
automatically recalculated to reflect the assigned value.
value:
The user value to give to the symbol. For bool and tristate symbols,
n/m/y can be specified either as 0/1/2 (the usual format for tristate
values in Kconfiglib) or as one of the strings "n"/"m"/"y". For other
symbol types, pass a string.
Values that are invalid for the type (such as "foo" or 1 (m) for a
BOOL or "0x123" for an INT) are ignored and won't be stored in
Symbol.user_value. Kconfiglib will print a warning by default for
invalid assignments, and set_value() will return False.
Returns True if the value is valid for the type of the symbol, and
False otherwise. This only looks at the form of the value. For BOOL and
TRISTATE symbols, check the Symbol.assignable attribute to see what
values are currently in range and would actually be reflected in the
value of the symbol. For other symbol types, check whether the
visibility is non-n.
"""
# If the new user value matches the old, nothing changes, and we can
# save some work.
#
# This optimization is skipped for choice symbols: Setting a choice
# symbol's user value to y might change the state of the choice, so it
# wouldn't be safe (symbol user values always match the values set in a
# .config file or via set_value(), and are never implicitly updated).
if value == self.user_value and not self.choice:
self._was_set = True
return True
# Check if the value is valid for our type
if not (self.orig_type is BOOL and value in (0, 2, "n", "y") or
self.orig_type is TRISTATE and value in (0, 1, 2, "n", "m", "y") or
(isinstance(value, str) and
(self.orig_type is STRING or
self.orig_type is INT and _is_base_n(value, 10) or
self.orig_type is HEX and _is_base_n(value, 16)
and int(value, 16) >= 0))):
# Display tristate values as n, m, y in the warning
self.kconfig._warn(
"the value {} is invalid for {}, which has type {} -- "
"assignment ignored"
.format(TRI_TO_STR[value] if value in (0, 1, 2) else
"'{}'".format(value),
_name_and_loc(self), TYPE_TO_STR[self.orig_type]))
return False
if self.orig_type in (BOOL, TRISTATE) and value in ("n", "m", "y"):
value = STR_TO_TRI[value]
self.user_value = value
self._was_set = True
if self.choice and value == 2:
# Setting a choice symbol to y makes it the user selection of the
# choice. Like for symbol user values, the user selection is not
# guaranteed to match the actual selection of the choice, as
# dependencies come into play.
self.choice.user_selection = self
self.choice._was_set = True
self.choice._rec_invalidate()
else:
self._rec_invalidate_if_has_prompt()
return True
def unset_value(self):
"""
Resets the user value of the symbol, as if the symbol had never gotten
a user value via Kconfig.load_config() or Symbol.set_value().
"""
if self.user_value is not None:
self.user_value = None
self._rec_invalidate_if_has_prompt()
@property
def referenced(self):
"""
See the class documentation.
"""
res = set()
for node in self.nodes:
res |= node.referenced
return res
def __repr__(self):
"""
Returns a string with information about the symbol (including its name,
value, visibility, and location(s)) when it is evaluated on e.g. the
interactive Python prompt.
"""
fields = []
fields.append("symbol " + self.name)
fields.append(TYPE_TO_STR[self.type])
for node in self.nodes:
if node.prompt:
fields.append('"{}"'.format(node.prompt[0]))
# Only add quotes for non-bool/tristate symbols
fields.append("value " +
(self.str_value
if self.orig_type in (BOOL, TRISTATE) else
'"{}"'.format(self.str_value)))
if not self.is_constant:
# These aren't helpful to show for constant symbols
if self.user_value is not None:
# Only add quotes for non-bool/tristate symbols
fields.append("user value " +
(TRI_TO_STR[self.user_value]
if self.orig_type in (BOOL, TRISTATE) else
'"{}"'.format(self.user_value)))
fields.append("visibility " + TRI_TO_STR[self.visibility])
if self.choice:
fields.append("choice symbol")
if self.is_allnoconfig_y:
fields.append("allnoconfig_y")
if self is self.kconfig.defconfig_list:
fields.append("is the defconfig_list symbol")
if self.env_var is not None:
fields.append("from environment variable " + self.env_var)
if self is self.kconfig.modules:
fields.append("is the modules symbol")
fields.append("direct deps " +
TRI_TO_STR[expr_value(self.direct_dep)])
if self.nodes:
for node in self.nodes:
fields.append("{}:{}".format(node.filename, node.linenr))
else:
if self.is_constant:
fields.append("constant")
else:
fields.append("undefined")
return "<{}>".format(", ".join(fields))
def __str__(self):
"""
Returns a string representation of the symbol when it is printed,
matching the Kconfig format, with parent dependencies propagated.
The string is constructed by joining the strings returned by
MenuNode.__str__() for each of the symbol's menu nodes, so symbols
defined in multiple locations will return a string with all
definitions.
An empty string is returned for undefined and constant symbols.
"""
return self.custom_str(standard_sc_expr_str)
def custom_str(self, sc_expr_str_fn):
"""
Works like Symbol.__str__(), but allows a custom format to be used for
all symbol/choice references. See expr_str().
"""
return "\n".join(node.custom_str(sc_expr_str_fn)
for node in self.nodes)
#
# Private methods
#
def __init__(self):
"""
Symbol constructor -- not intended to be called directly by Kconfiglib
clients.
"""
# These attributes are always set on the instance from outside and
# don't need defaults:
# kconfig
# direct_dep
# is_constant
# name
# rev_dep
# weak_rev_dep
self.orig_type = UNKNOWN
self.defaults = []
self.selects = []
self.implies = []
self.ranges = []
self.nodes = []
self.user_value = \
self.choice = \
self.env_var = \
self._cached_str_val = self._cached_tri_val = self._cached_vis = \
self._cached_assignable = None
# _write_to_conf is calculated along with the value. If True, the
# Symbol gets a .config entry.
self.is_allnoconfig_y = \
self._was_set = \
self._write_to_conf = False
# See Kconfig._build_dep()
self._dependents = set()
# Used during dependency loop detection and (independently) in
# node_iter()
self._visited = 0
def _assignable(self):
# Worker function for the 'assignable' attribute
if self.orig_type not in (BOOL, TRISTATE):
return ()
# Warning: See Symbol._rec_invalidate(), and note that this is a hidden
# function call (property magic)
vis = self.visibility
if not vis:
return ()
rev_dep_val = expr_value(self.rev_dep)
if vis == 2:
if self.choice:
return (2,)
if not rev_dep_val:
if self.type is BOOL or expr_value(self.weak_rev_dep) == 2:
return (0, 2)
return (0, 1, 2)
if rev_dep_val == 2:
return (2,)
# rev_dep_val == 1
if self.type is BOOL or expr_value(self.weak_rev_dep) == 2:
return (2,)
return (1, 2)
# vis == 1
# Must be a tristate here, because bool m visibility gets promoted to y
if not rev_dep_val:
return (0, 1) if expr_value(self.weak_rev_dep) != 2 else (0, 2)
if rev_dep_val == 2:
return (2,)
# vis == rev_dep_val == 1
return (1,)
def _invalidate(self):
# Marks the symbol as needing to be recalculated
self._cached_str_val = self._cached_tri_val = self._cached_vis = \
self._cached_assignable = None
def _rec_invalidate(self):
# Invalidates the symbol and all items that (possibly) depend on it
if self is self.kconfig.modules:
# Invalidating MODULES has wide-ranging effects
self.kconfig._invalidate_all()
else:
self._invalidate()
for item in self._dependents:
# _cached_vis doubles as a flag that tells us whether 'item'
# has cached values, because it's calculated as a side effect
# of calculating all other (non-constant) cached values.
#
# If item._cached_vis is None, it means there can't be cached
# values on other items that depend on 'item', because if there
# were, some value on 'item' would have been calculated and
# item._cached_vis set as a side effect. It's therefore safe to
# stop the invalidation at symbols with _cached_vis None.
#
# This approach massively speeds up scripts that set a lot of
# values, vs simply invalidating all possibly dependent symbols
# (even when you already have a list of all the dependent
# symbols, because some symbols get huge dependency trees).
#
# This gracefully handles dependency loops too, which is nice
# for choices, where the choice depends on the choice symbols
# and vice versa.
if item._cached_vis is not None:
item._rec_invalidate()
def _rec_invalidate_if_has_prompt(self):
# Invalidates the symbol and its dependent symbols, but only if the
# symbol has a prompt. User values never have an effect on promptless
# symbols, so we skip invalidation for them as an optimization.
#
# This also prevents constant (quoted) symbols from being invalidated
# if set_value() is called on them, which would cause them to lose
# their value and break things.
#
# Prints a warning if the symbol has no prompt. In some contexts (e.g.
# when loading a .config files) assignments to promptless symbols are
# normal and expected, so the warning can be disabled.
for node in self.nodes:
if node.prompt:
self._rec_invalidate()
return
if self.kconfig._warn_for_no_prompt:
self.kconfig._warn(_name_and_loc(self) + " has no prompt, meaning "
"user values have no effect on it")
def _str_default(self):
# write_min_config() helper function. Returns the value the symbol
# would get from defaults if it didn't have a user value. Uses exactly
# the same algorithm as the C implementation (though a bit cleaned up),
# for compatibility.
if self.orig_type in (BOOL, TRISTATE):
val = 0
# Defaults, selects, and implies do not affect choice symbols
if not self.choice:
for default, cond in self.defaults:
cond_val = expr_value(cond)
if cond_val:
val = min(expr_value(default), cond_val)
break
val = max(expr_value(self.rev_dep),
expr_value(self.weak_rev_dep),
val)
# Transpose mod to yes if type is bool (possibly due to modules
# being disabled)
if val == 1 and self.type is BOOL:
val = 2
return TRI_TO_STR[val]
if self.orig_type in (STRING, INT, HEX):
for default, cond in self.defaults:
if expr_value(cond):
return default.str_value
return ""
def _warn_select_unsatisfied_deps(self):
# Helper for printing an informative warning when a symbol with
# unsatisfied direct dependencies (dependencies from 'depends on', ifs,
# and menus) is selected by some other symbol. Also warn if a symbol
# whose direct dependencies evaluate to m is selected to y.
msg = "{} has direct dependencies {} with value {}, but is " \
"currently being {}-selected by the following symbols:" \
.format(_name_and_loc(self), expr_str(self.direct_dep),
TRI_TO_STR[expr_value(self.direct_dep)],
TRI_TO_STR[expr_value(self.rev_dep)])
# The reverse dependencies from each select are ORed together
for select in split_expr(self.rev_dep, OR):
if expr_value(select) <= expr_value(self.direct_dep):
# Only include selects that exceed the direct dependencies
continue
# - 'select A if B' turns into A && B
# - 'select A' just turns into A
#
# In both cases, we can split on AND and pick the first operand
selecting_sym = split_expr(select, AND)[0]
msg += "\n - {}, with value {}, direct dependencies {} " \
"(value: {})" \
.format(_name_and_loc(selecting_sym),
selecting_sym.str_value,
expr_str(selecting_sym.direct_dep),
TRI_TO_STR[expr_value(selecting_sym.direct_dep)])
if isinstance(select, tuple):
msg += ", and select condition {} (value: {})" \
.format(expr_str(select[2]),
TRI_TO_STR[expr_value(select[2])])
self.kconfig._warn(msg)
class Choice(object):
"""
Represents a choice statement:
choice
...
endchoice
The following attributes are available on Choice instances. They should be
treated as read-only, and some are implemented through @property magic (but
are still efficient to access due to internal caching).
Note: Prompts, help texts, and locations are stored in the Choice's
MenuNode(s) rather than in the Choice itself. Check the MenuNode class and
the Choice.nodes attribute. This organization matches the C tools.
name:
The name of the choice, e.g. "FOO" for 'choice FOO', or None if the
Choice has no name. I can't remember ever seeing named choices in
practice, but the C tools support them too.
type:
The type of the choice. One of BOOL, TRISTATE, UNKNOWN. UNKNOWN is for
choices defined without a type where none of the contained symbols have a
type either (otherwise the choice inherits the type of the first symbol
defined with a type).
When running without modules (CONFIG_MODULES=n), TRISTATE choices
magically change type to BOOL. This matches the C tools, and makes sense
for menuconfig-like functionality.
orig_type:
The type as given in the Kconfig file, without any magic applied. Used
when printing the choice.
tri_value:
The tristate value (mode) of the choice. A choice can be in one of three
modes:
0 (n) - The choice is disabled and no symbols can be selected. For
visible choices, this mode is only possible for choices with
the 'optional' flag set (see kconfig-language.txt).
1 (m) - Any number of choice symbols can be set to m, the rest will
be n.
2 (y) - One symbol will be y, the rest n.
Only tristate choices can be in m mode. The visibility of the choice is
an upper bound on the mode, and the mode in turn is an upper bound on the
visibility of the choice symbols.
To change the mode, use Choice.set_value().
Implementation note:
The C tools internally represent choices as a type of symbol, with
special-casing in many code paths. This is why there is a lot of
similarity to Symbol. The value (mode) of a choice is really just a
normal symbol value, and an implicit reverse dependency forces its
lower bound to m for visible non-optional choices (the reverse
dependency is 'm && <visibility>').
Symbols within choices get the choice propagated as a dependency to
their properties. This turns the mode of the choice into an upper bound
on e.g. the visibility of choice symbols, and explains the gotcha
related to printing choice symbols mentioned in the module docstring.
Kconfiglib uses a separate Choice class only because it makes the code
and interface less confusing (especially in a user-facing interface).
Corresponding attributes have the same name in the Symbol and Choice
classes, for consistency and compatibility.
assignable:
See the symbol class documentation. Gives the assignable values (modes).
visibility:
See the Symbol class documentation. Acts on the value (mode).
selection:
The Symbol instance of the currently selected symbol. None if the Choice
is not in y mode or has no selected symbol (due to unsatisfied
dependencies on choice symbols).
WARNING: Do not assign directly to this. It will break things. Call
sym.set_value(2) on the choice symbol you want to select instead.
user_value:
The value (mode) selected by the user through Choice.set_value(). Either
0, 1, or 2, or None if the user hasn't selected a mode. See
Symbol.user_value.
WARNING: Do not assign directly to this. It will break things. Use
Choice.set_value() instead.
user_selection:
The symbol selected by the user (by setting it to y). Ignored if the
choice is not in y mode, but still remembered so that the choice "snaps
back" to the user selection if the mode is changed back to y. This might
differ from 'selection' due to unsatisfied dependencies.
WARNING: Do not assign directly to this. It will break things. Call
sym.set_value(2) on the choice symbol to be selected instead.
syms:
List of symbols contained in the choice.
Gotcha: If a symbol depends on the previous symbol within a choice so
that an implicit menu is created, it won't be a choice symbol, and won't
be included in 'syms'. There are real-world examples of this, and it was
a PITA to support in older versions of Kconfiglib that didn't implement
the menu structure.
nodes:
A list of MenuNodes for this choice. In practice, the list will probably
always contain a single MenuNode, but it is possible to give a choice a
name and define it in multiple locations (I've never even seen a named
choice though).
defaults:
List of (symbol, cond) tuples for the choice's 'defaults' properties. For
example, 'default A if B && C' is represented as (A, (AND, B, C)). If
there is no condition, 'cond' is self.config.y.
Note that 'depends on' and parent dependencies are propagated to
'default' conditions.
direct_dep:
See Symbol.direct_dep.
referenced:
A set() with all symbols referenced in the properties and property
conditions of the choice.
Also includes dependencies inherited from surrounding menus and if's.
is_optional:
True if the choice has the 'optional' flag set on it and can be in
n mode.
kconfig:
The Kconfig instance this choice is from.
"""
__slots__ = (
"_cached_assignable",
"_cached_selection",
"_cached_vis",
"_dependents",
"_visited",
"_was_set",
"defaults",
"direct_dep",
"is_constant",
"is_optional",
"kconfig",
"name",
"nodes",
"orig_type",
"syms",
"user_selection",
"user_value",
)
#
# Public interface
#
@property
def type(self):
"""
Returns the type of the choice. See Symbol.type.
"""
if self.orig_type is TRISTATE and not self.kconfig.modules.tri_value:
return BOOL
return self.orig_type
@property
def str_value(self):
"""
See the class documentation.
"""
return TRI_TO_STR[self.tri_value]
@property
def tri_value(self):
"""
See the class documentation.
"""
# This emulates a reverse dependency of 'm && visibility' for
# non-optional choices, which is how the C implementation does it
val = 0 if self.is_optional else 1
if self.user_value is not None:
val = max(val, self.user_value)
# Warning: See Symbol._rec_invalidate(), and note that this is a hidden
# function call (property magic)
val = min(val, self.visibility)
# Promote m to y for boolean choices
return 2 if val == 1 and self.type is BOOL else val
@property
def assignable(self):
"""
See the class documentation.
"""
if self._cached_assignable is None:
self._cached_assignable = self._assignable()
return self._cached_assignable
@property
def visibility(self):
"""
See the class documentation.
"""
if self._cached_vis is None:
self._cached_vis = _visibility(self)
return self._cached_vis
@property
def selection(self):
"""
See the class documentation.
"""
if self._cached_selection is _NO_CACHED_SELECTION:
self._cached_selection = self._selection()
return self._cached_selection
def set_value(self, value):
"""
Sets the user value (mode) of the choice. Like for Symbol.set_value(),
the visibility might truncate the value. Choices without the 'optional'
attribute (is_optional) can never be in n mode, but 0/"n" is still
accepted since it's not a malformed value (though it will have no
effect).
Returns True if the value is valid for the type of the choice, and
False otherwise. This only looks at the form of the value. Check the
Choice.assignable attribute to see what values are currently in range
and would actually be reflected in the mode of the choice.
"""
if value == self.user_value:
# We know the value must be valid if it was successfully set
# previously
self._was_set = True
return True
if not ((self.orig_type is BOOL and value in (0, 2, "n", "y") ) or
(self.orig_type is TRISTATE and value in (0, 1, 2, "n", "m", "y"))):
# Display tristate values as n, m, y in the warning
self.kconfig._warn(
"the value {} is invalid for {}, which has type {} -- "
"assignment ignored"
.format(TRI_TO_STR[value] if value in (0, 1, 2) else
"'{}'".format(value),
_name_and_loc(self),
TYPE_TO_STR[self.orig_type]))
return False
if value in ("n", "m", "y"):
value = STR_TO_TRI[value]
self.user_value = value
self._was_set = True
self._rec_invalidate()
return True
def unset_value(self):
"""
Resets the user value (mode) and user selection of the Choice, as if
the user had never touched the mode or any of the choice symbols.
"""
if self.user_value is not None or self.user_selection:
self.user_value = self.user_selection = None
self._rec_invalidate()
@property
def referenced(self):
"""
See the class documentation.
"""
res = set()
for node in self.nodes:
res |= node.referenced
return res
def __repr__(self):
"""
Returns a string with information about the choice when it is evaluated
on e.g. the interactive Python prompt.
"""
fields = []
fields.append("choice " + self.name if self.name else "choice")
fields.append(TYPE_TO_STR[self.type])
for node in self.nodes:
if node.prompt:
fields.append('"{}"'.format(node.prompt[0]))
fields.append("mode " + self.str_value)
if self.user_value is not None:
fields.append('user mode {}'.format(TRI_TO_STR[self.user_value]))
if self.selection:
fields.append("{} selected".format(self.selection.name))
if self.user_selection:
user_sel_str = "{} selected by user" \
.format(self.user_selection.name)
if self.selection is not self.user_selection:
user_sel_str += " (overridden)"
fields.append(user_sel_str)
fields.append("visibility " + TRI_TO_STR[self.visibility])
if self.is_optional:
fields.append("optional")
for node in self.nodes:
fields.append("{}:{}".format(node.filename, node.linenr))
return "<{}>".format(", ".join(fields))
def __str__(self):
"""
Returns a string representation of the choice when it is printed,
matching the Kconfig format (though without the contained choice
symbols).
See Symbol.__str__() as well.
"""
return self.custom_str(standard_sc_expr_str)
def custom_str(self, sc_expr_str_fn):
"""
Works like Choice.__str__(), but allows a custom format to be used for
all symbol/choice references. See expr_str().
"""
return "\n".join(node.custom_str(sc_expr_str_fn)
for node in self.nodes)
#
# Private methods
#
def __init__(self):
"""
Choice constructor -- not intended to be called directly by Kconfiglib
clients.
"""
# These attributes are always set on the instance from outside and
# don't need defaults:
# direct_dep
# kconfig
self.orig_type = UNKNOWN
self.syms = []
self.defaults = []
self.nodes = []
self.name = \
self.user_value = self.user_selection = \
self._cached_vis = self._cached_assignable = None
self._cached_selection = _NO_CACHED_SELECTION
# is_constant is checked by _make_depend_on(). Just set it to avoid
# having to special-case choices.
self.is_constant = self.is_optional = False
# See Kconfig._build_dep()
self._dependents = set()
# Used during dependency loop detection
self._visited = 0
def _assignable(self):
# Worker function for the 'assignable' attribute
# Warning: See Symbol._rec_invalidate(), and note that this is a hidden
# function call (property magic)
vis = self.visibility
if not vis:
return ()
if vis == 2:
if not self.is_optional:
return (2,) if self.type is BOOL else (1, 2)
return (0, 2) if self.type is BOOL else (0, 1, 2)
# vis == 1
return (0, 1) if self.is_optional else (1,)
def _selection(self):
# Worker function for the 'selection' attribute
# Warning: See Symbol._rec_invalidate(), and note that this is a hidden
# function call (property magic)
if self.tri_value != 2:
# Not in y mode, so no selection
return None
# Use the user selection if it's visible
if self.user_selection and self.user_selection.visibility:
return self.user_selection
# Otherwise, check if we have a default
return self._get_selection_from_defaults()
def _get_selection_from_defaults(self):
# Check if we have a default
for sym, cond in self.defaults:
# The default symbol must be visible too
if expr_value(cond) and sym.visibility:
return sym
# Otherwise, pick the first visible symbol, if any
for sym in self.syms:
if sym.visibility:
return sym
# Couldn't find a selection
return None
def _invalidate(self):
self._cached_vis = self._cached_assignable = None
self._cached_selection = _NO_CACHED_SELECTION
def _rec_invalidate(self):
# See Symbol._rec_invalidate()
self._invalidate()
for item in self._dependents:
if item._cached_vis is not None:
item._rec_invalidate()
class MenuNode(object):
"""
Represents a menu node in the configuration. This corresponds to an entry
in e.g. the 'make menuconfig' interface, though non-visible choices, menus,
and comments also get menu nodes. If a symbol or choice is defined in
multiple locations, it gets one menu node for each location.
The top-level menu node, corresponding to the implicit top-level menu, is
available in Kconfig.top_node.
The menu nodes for a Symbol or Choice can be found in the
Symbol/Choice.nodes attribute. Menus and comments are represented as plain
menu nodes, with their text stored in the prompt attribute (prompt[0]).
This mirrors the C implementation.
The following attributes are available on MenuNode instances. They should
be viewed as read-only.
item:
Either a Symbol, a Choice, or one of the constants MENU and COMMENT.
Menus and comments are represented as plain menu nodes. Ifs are collapsed
(matching the C implementation) and do not appear in the final menu tree.
next:
The following menu node. None if there is no following node.
list:
The first child menu node. None if there are no children.
Choices and menus naturally have children, but Symbols can also have
children because of menus created automatically from dependencies (see
kconfig-language.txt).
parent:
The parent menu node. None if there is no parent.
prompt:
A (string, cond) tuple with the prompt for the menu node and its
conditional expression (which is self.kconfig.y if there is no
condition). None if there is no prompt.
For symbols and choices, the prompt is stored in the MenuNode rather than
the Symbol or Choice instance. For menus and comments, the prompt holds
the text.
defaults:
The 'default' properties for this particular menu node. See
symbol.defaults.
When evaluating defaults, you should use Symbol/Choice.defaults instead,
as it include properties from all menu nodes (a symbol/choice can have
multiple definition locations/menu nodes). MenuNode.defaults is meant for
documentation generation.
selects:
Like MenuNode.defaults, for selects.
implies:
Like MenuNode.defaults, for implies.
ranges:
Like MenuNode.defaults, for ranges.
help:
The help text for the menu node for Symbols and Choices. None if there is
no help text. Always stored in the node rather than the Symbol or Choice.
It is possible to have a separate help text at each location if a symbol
is defined in multiple locations.
dep:
The 'depends on' dependencies for the menu node, or self.kconfig.y if
there are no dependencies. Parent dependencies are propagated to this
attribute, and this attribute is then in turn propagated to the
properties of symbols and choices.
If a symbol or choice is defined in multiple locations, only the
properties defined at a particular location get the corresponding
MenuNode.dep dependencies propagated to them.
visibility:
The 'visible if' dependencies for the menu node (which must represent a
menu), or self.kconfig.y if there are no 'visible if' dependencies.
'visible if' dependencies are recursively propagated to the prompts of
symbols and choices within the menu.
referenced:
A set() with all symbols and choices referenced in the properties and
property conditions of the menu node.
Also includes dependencies inherited from surrounding menus and if's.
Choices appear in the dependencies of choice symbols.
is_menuconfig:
Set to True if the children of the menu node should be displayed in a
separate menu. This is the case for the following items:
- Menus (node.item == MENU)
- Choices
- Symbols defined with the 'menuconfig' keyword. The children come from
implicitly created submenus, and should be displayed in a separate
menu rather than being indented.
'is_menuconfig' is just a hint on how to display the menu node. It's
ignored internally by Kconfiglib, except when printing symbols.
filename/linenr:
The location where the menu node appears. The filename is relative to
$srctree (or to the current directory if $srctree isn't set), except
absolute paths passed to 'source' and Kconfig.__init__() are preserved.
include_path:
A tuple of (filename, linenr) tuples, giving the locations of the
'source' statements via which the Kconfig file containing this menu node
was included. The first element is the location of the 'source' statement
in the top-level Kconfig file passed to Kconfig.__init__(), etc.
Note that the Kconfig file of the menu node itself isn't included. Check
'filename' and 'linenr' for that.
kconfig:
The Kconfig instance the menu node is from.
"""
__slots__ = (
"dep",
"filename",
"help",
"include_path",
"is_menuconfig",
"item",
"kconfig",
"linenr",
"list",
"next",
"parent",
"prompt",
"visibility",
# Properties
"defaults",
"selects",
"implies",
"ranges"
)
def __init__(self):
# Properties defined on this particular menu node. A local 'depends on'
# only applies to these, in case a symbol is defined in multiple
# locations.
self.defaults = []
self.selects = []
self.implies = []
self.ranges = []
@property
def referenced(self):
"""
See the class documentation.
"""
# self.dep is included to catch dependencies from a lone 'depends on'
# when there are no properties to propagate it to
res = expr_items(self.dep)
if self.prompt:
res |= expr_items(self.prompt[1])
if self.item is MENU:
res |= expr_items(self.visibility)
for value, cond in self.defaults:
res |= expr_items(value)
res |= expr_items(cond)
for value, cond in self.selects:
res.add(value)
res |= expr_items(cond)
for value, cond in self.implies:
res.add(value)
res |= expr_items(cond)
for low, high, cond in self.ranges:
res.add(low)
res.add(high)
res |= expr_items(cond)
return res
def __repr__(self):
"""
Returns a string with information about the menu node when it is
evaluated on e.g. the interactive Python prompt.
"""
fields = []
if isinstance(self.item, Symbol):
fields.append("menu node for symbol " + self.item.name)
elif isinstance(self.item, Choice):
s = "menu node for choice"
if self.item.name is not None:
s += " " + self.item.name
fields.append(s)
elif self.item is MENU:
fields.append("menu node for menu")
elif self.item is COMMENT:
fields.append("menu node for comment")
elif self.item is None:
fields.append("menu node for if (should not appear in the final "
" tree)")
else:
_internal_error("unable to determine type in MenuNode.__repr__()")
if self.prompt:
fields.append('prompt "{}" (visibility {})'
.format(self.prompt[0],
TRI_TO_STR[expr_value(self.prompt[1])]))
if isinstance(self.item, Symbol) and self.is_menuconfig:
fields.append("is menuconfig")
fields.append("deps " + TRI_TO_STR[expr_value(self.dep)])
if self.item is MENU:
fields.append("'visible if' deps " + \
TRI_TO_STR[expr_value(self.visibility)])
if isinstance(self.item, (Symbol, Choice)) and self.help is not None:
fields.append("has help")
if self.list:
fields.append("has child")
if self.next:
fields.append("has next")
fields.append("{}:{}".format(self.filename, self.linenr))
return "<{}>".format(", ".join(fields))
def __str__(self):
"""
Returns a string representation of the menu node, matching the Kconfig
format.
The output could (almost) be fed back into a Kconfig parser to redefine
the object associated with the menu node. See the module documentation
for a gotcha related to choice symbols.
For symbols and choices with multiple menu nodes (multiple definition
locations), properties that aren't associated with a particular menu
node are shown on all menu nodes ('option env=...', 'optional' for
choices, etc.).
"""
return self.custom_str(standard_sc_expr_str)
def custom_str(self, sc_expr_str_fn):
"""
Works like MenuNode.__str__(), but allows a custom format to be used
for all symbol/choice references. See expr_str().
"""
return self._menu_comment_node_str(sc_expr_str_fn) \
if self.item in (MENU, COMMENT) else \
self._sym_choice_node_str(sc_expr_str_fn)
def _menu_comment_node_str(self, sc_expr_str_fn):
s = '{} "{}"\n'.format("menu" if self.item is MENU else "comment",
self.prompt[0])
if self.dep is not self.kconfig.y:
s += "\tdepends on {}\n".format(expr_str(self.dep, sc_expr_str_fn))
if self.item is MENU and self.visibility is not self.kconfig.y:
s += "\tvisible if {}\n".format(expr_str(self.visibility,
sc_expr_str_fn))
return s
def _sym_choice_node_str(self, sc_expr_str_fn):
lines = []
def indent_add(s):
lines.append("\t" + s)
def indent_add_cond(s, cond):
if cond is not self.kconfig.y:
s += " if " + expr_str(cond, sc_expr_str_fn)
indent_add(s)
sc = self.item
if isinstance(sc, Symbol):
lines.append(
("menuconfig " if self.is_menuconfig else "config ")
+ sc.name)
else:
lines.append("choice " + sc.name if sc.name else "choice")
if sc.orig_type is not UNKNOWN:
indent_add(TYPE_TO_STR[sc.orig_type])
if self.prompt:
indent_add_cond(
'prompt "{}"'.format(escape(self.prompt[0])),
self.prompt[1])
if isinstance(sc, Symbol):
if sc.is_allnoconfig_y:
indent_add("option allnoconfig_y")
if sc is sc.kconfig.defconfig_list:
indent_add("option defconfig_list")
if sc.env_var is not None:
indent_add('option env="{}"'.format(sc.env_var))
if sc is sc.kconfig.modules:
indent_add("option modules")
for low, high, cond in self.ranges:
indent_add_cond(
"range {} {}".format(sc_expr_str_fn(low),
sc_expr_str_fn(high)),
cond)
for default, cond in self.defaults:
indent_add_cond("default " + expr_str(default, sc_expr_str_fn),
cond)
if isinstance(sc, Choice) and sc.is_optional:
indent_add("optional")
if isinstance(sc, Symbol):
for select, cond in self.selects:
indent_add_cond("select " + sc_expr_str_fn(select), cond)
for imply, cond in self.implies:
indent_add_cond("imply " + sc_expr_str_fn(imply), cond)
if self.dep is not sc.kconfig.y:
indent_add("depends on " + expr_str(self.dep, sc_expr_str_fn))
if self.help is not None:
indent_add("help")
for line in self.help.splitlines():
indent_add(" " + line)
return "\n".join(lines) + "\n"
class Variable(object):
"""
Represents a preprocessor variable/function.
The following attributes are available:
name:
The name of the variable.
value:
The unexpanded value of the variable.
expanded_value:
The expanded value of the variable. For simple variables (those defined
with :=), this will equal 'value'. Accessing this property will raise a
KconfigError if any variable in the expansion expands to itself.
is_recursive:
True if the variable is recursive (defined with =).
"""
__slots__ = (
"_n_expansions",
"is_recursive",
"kconfig",
"name",
"value",
)
@property
def expanded_value(self):
"""
See the class documentation.
"""
return self.kconfig._expand_whole(self.value, ())
class KconfigError(Exception):
"""
Exception raised for Kconfig-related errors.
"""
# Backwards compatibility
KconfigSyntaxError = KconfigError
class InternalError(Exception):
"""
Exception raised for internal errors.
"""
#
# Public functions
#
def expr_value(expr):
"""
Evaluates the expression 'expr' to a tristate value. Returns 0 (n), 1 (m),
or 2 (y).
'expr' must be an already-parsed expression from a Symbol, Choice, or
MenuNode property. To evaluate an expression represented as a string, use
Kconfig.eval_string().
Passing subexpressions of expressions to this function works as expected.
"""
if not isinstance(expr, tuple):
return expr.tri_value
if expr[0] is AND:
v1 = expr_value(expr[1])
# Short-circuit the n case as an optimization (~5% faster
# allnoconfig.py and allyesconfig.py, as of writing)
return 0 if not v1 else min(v1, expr_value(expr[2]))
if expr[0] is OR:
v1 = expr_value(expr[1])
# Short-circuit the y case as an optimization
return 2 if v1 == 2 else max(v1, expr_value(expr[2]))
if expr[0] is NOT:
return 2 - expr_value(expr[1])
if expr[0] in _RELATIONS:
# Implements <, <=, >, >= comparisons as well. These were added to
# kconfig in 31847b67 (kconfig: allow use of relations other than
# (in)equality).
oper, op1, op2 = expr
# If both operands are strings...
if op1.orig_type is STRING and op2.orig_type is STRING:
# ...then compare them lexicographically
comp = _strcmp(op1.str_value, op2.str_value)
else:
# Otherwise, try to compare them as numbers
try:
comp = _sym_to_num(op1) - _sym_to_num(op2)
except ValueError:
# Fall back on a lexicographic comparison if the operands don't
# parse as numbers
comp = _strcmp(op1.str_value, op2.str_value)
if oper is EQUAL: res = comp == 0
elif oper is UNEQUAL: res = comp != 0
elif oper is LESS: res = comp < 0
elif oper is LESS_EQUAL: res = comp <= 0
elif oper is GREATER: res = comp > 0
elif oper is GREATER_EQUAL: res = comp >= 0
return 2*res
_internal_error("Internal error while evaluating expression: "
"unknown operation {}.".format(expr[0]))
def standard_sc_expr_str(sc):
"""
Standard symbol/choice printing function. Uses plain Kconfig syntax, and
displays choices as <choice> (or <choice NAME>, for named choices).
See expr_str().
"""
if isinstance(sc, Symbol):
return '"{}"'.format(escape(sc.name)) if sc.is_constant else sc.name
# Choice
return "<choice {}>".format(sc.name) if sc.name else "<choice>"
def expr_str(expr, sc_expr_str_fn=standard_sc_expr_str):
"""
Returns the string representation of the expression 'expr', as in a Kconfig
file.
Passing subexpressions of expressions to this function works as expected.
sc_expr_str_fn (default: standard_sc_expr_str):
This function is called for every symbol/choice (hence "sc") appearing in
the expression, with the symbol/choice as the argument. It is expected to
return a string to be used for the symbol/choice.
This can be used e.g. to turn symbols/choices into links when generating
documentation, or for printing the value of each symbol/choice after it.
Note that quoted values are represented as constants symbols
(Symbol.is_constant == True).
"""
if not isinstance(expr, tuple):
return sc_expr_str_fn(expr)
if expr[0] is AND:
return "{} && {}".format(_parenthesize(expr[1], OR, sc_expr_str_fn),
_parenthesize(expr[2], OR, sc_expr_str_fn))
if expr[0] is OR:
# This turns A && B || C && D into "(A && B) || (C && D)", which is
# redundant, but more readable
return "{} || {}".format(_parenthesize(expr[1], AND, sc_expr_str_fn),
_parenthesize(expr[2], AND, sc_expr_str_fn))
if expr[0] is NOT:
if isinstance(expr[1], tuple):
return "!({})".format(expr_str(expr[1], sc_expr_str_fn))
return "!" + sc_expr_str_fn(expr[1]) # Symbol
# Relation
#
# Relation operands are always symbols (quoted strings are constant
# symbols)
return "{} {} {}".format(sc_expr_str_fn(expr[1]), _REL_TO_STR[expr[0]],
sc_expr_str_fn(expr[2]))
def expr_items(expr):
"""
Returns a set() of all items (symbols and choices) that appear in the
expression 'expr'.
"""
res = set()
def rec(subexpr):
if isinstance(subexpr, tuple):
# AND, OR, NOT, or relation
rec(subexpr[1])
# NOTs only have a single operand
if subexpr[0] is not NOT:
rec(subexpr[2])
else:
# Symbol or choice
res.add(subexpr)
rec(expr)
return res
def split_expr(expr, op):
"""
Returns a list containing the top-level AND or OR operands in the
expression 'expr', in the same (left-to-right) order as they appear in
the expression.
This can be handy e.g. for splitting (weak) reverse dependencies
from 'select' and 'imply' into individual selects/implies.
op:
Either AND to get AND operands, or OR to get OR operands.
(Having this as an operand might be more future-safe than having two
hardcoded functions.)
Pseudo-code examples:
split_expr( A , OR ) -> [A]
split_expr( A && B , OR ) -> [A && B]
split_expr( A || B , OR ) -> [A, B]
split_expr( A || B , AND ) -> [A || B]
split_expr( A || B || (C && D) , OR ) -> [A, B, C && D]
# Second || is not at the top level
split_expr( A || (B && (C || D)) , OR ) -> [A, B && (C || D)]
# Parentheses don't matter as long as we stay at the top level (don't
# encounter any non-'op' nodes)
split_expr( (A || B) || C , OR ) -> [A, B, C]
split_expr( A || (B || C) , OR ) -> [A, B, C]
"""
res = []
def rec(subexpr):
if isinstance(subexpr, tuple) and subexpr[0] is op:
rec(subexpr[1])
rec(subexpr[2])
else:
res.append(subexpr)
rec(expr)
return res
def escape(s):
r"""
Escapes the string 's' in the same fashion as is done for display in
Kconfig format and when writing strings to a .config file. " and \ are
replaced by \" and \\, respectively.
"""
# \ must be escaped before " to avoid double escaping
return s.replace("\\", r"\\").replace('"', r'\"')
# unescape() helper
_unescape_sub = re.compile(r"\\(.)").sub
def unescape(s):
r"""
Unescapes the string 's'. \ followed by any character is replaced with just
that character. Used internally when reading .config files.
"""
return _unescape_sub(r"\1", s)
def standard_kconfig():
"""
Helper for tools. Loads the top-level Kconfig specified as the first
command-line argument, or "Kconfig" if there are no command-line arguments.
Returns the Kconfig instance.
Exits with sys.exit() (which raises a SystemExit exception) and prints a
usage note to stderr if more than one command-line argument is passed.
"""
if len(sys.argv) > 2:
sys.exit("usage: {} [Kconfig]".format(sys.argv[0]))
return Kconfig("Kconfig" if len(sys.argv) < 2 else sys.argv[1])
def standard_config_filename():
"""
Helper for tools. Returns the value of KCONFIG_CONFIG (which specifies the
.config file to load/save) if it is set, and ".config" otherwise.
"""
return os.environ.get("KCONFIG_CONFIG", ".config")
#
# Internal functions
#
def _visibility(sc):
# Symbols and Choices have a "visibility" that acts as an upper bound on
# the values a user can set for them, corresponding to the visibility in
# e.g. 'make menuconfig'. This function calculates the visibility for the
# Symbol or Choice 'sc' -- the logic is nearly identical.
vis = 0
for node in sc.nodes:
if node.prompt:
vis = max(vis, expr_value(node.prompt[1]))
if isinstance(sc, Symbol) and sc.choice:
if sc.choice.orig_type is TRISTATE and \
sc.orig_type is not TRISTATE and sc.choice.tri_value != 2:
# Non-tristate choice symbols are only visible in y mode
return 0
if sc.orig_type is TRISTATE and vis == 1 and sc.choice.tri_value == 2:
# Choice symbols with m visibility are not visible in y mode
return 0
# Promote m to y if we're dealing with a non-tristate (possibly due to
# modules being disabled)
if vis == 1 and sc.type is not TRISTATE:
return 2
return vis
def _make_depend_on(sc, expr):
# Adds 'sc' (symbol or choice) as a "dependee" to all symbols in 'expr'.
# Constant symbols in 'expr' are skipped as they can never change value
# anyway.
if isinstance(expr, tuple):
# AND, OR, NOT, or relation
_make_depend_on(sc, expr[1])
# NOTs only have a single operand
if expr[0] is not NOT:
_make_depend_on(sc, expr[2])
elif not expr.is_constant:
# Non-constant symbol, or choice
expr._dependents.add(sc)
def _parenthesize(expr, type_, sc_expr_str_fn):
# expr_str() helper. Adds parentheses around expressions of type 'type_'.
if isinstance(expr, tuple) and expr[0] is type_:
return "({})".format(expr_str(expr, sc_expr_str_fn))
return expr_str(expr, sc_expr_str_fn)
def _indentation(line):
# Returns the length of the line's leading whitespace, treating tab stops
# as being spaced 8 characters apart.
line = line.expandtabs()
return len(line) - len(line.lstrip())
def _ordered_unique(lst):
# Returns 'lst' with any duplicates removed, preserving order. This hacky
# version seems to be a common idiom. It relies on short-circuit evaluation
# and set.add() returning None, which is falsy.
seen = set()
seen_add = seen.add
return [x for x in lst if x not in seen and not seen_add(x)]
def _is_base_n(s, n):
try:
int(s, n)
return True
except ValueError:
return False
def _strcmp(s1, s2):
# strcmp()-alike that returns -1, 0, or 1
return (s1 > s2) - (s1 < s2)
def _is_num(s):
# Returns True if the string 's' looks like a number.
#
# Internally, all operands in Kconfig are symbols, only undefined symbols
# (which numbers usually are) get their name as their value.
#
# Only hex numbers that start with 0x/0X are classified as numbers.
# Otherwise, symbols whose names happen to contain only the letters A-F
# would trigger false positives.
try:
int(s)
except ValueError:
if not s.startswith(("0x", "0X")):
return False
try:
int(s, 16)
except ValueError:
return False
return True
def _sym_to_num(sym):
# expr_value() helper for converting a symbol to a number. Raises
# ValueError for symbols that can't be converted.
# For BOOL and TRISTATE, n/m/y count as 0/1/2. This mirrors 9059a3493ef
# ("kconfig: fix relational operators for bool and tristate symbols") in
# the C implementation.
return sym.tri_value if sym.orig_type in (BOOL, TRISTATE) else \
int(sym.str_value, _TYPE_TO_BASE[sym.orig_type])
def _internal_error(msg):
raise InternalError(
msg +
"\nSorry! You may want to send an email to ulfalizer a.t Google's "
"email service to tell me about this. Include the message above and "
"the stack trace and describe what you were doing.")
def _decoding_error(e, filename, macro_linenr=None):
# Gives the filename and context for UnicodeDecodeError's, which are a pain
# to debug otherwise. 'e' is the UnicodeDecodeError object.
#
# If the decoding error is for the output of a $(shell,...) command,
# macro_linenr holds the line number where it was run (the exact line
# number isn't available for decoding errors in files).
if macro_linenr is None:
loc = filename
else:
loc = "output from macro at {}:{}".format(filename, macro_linenr)
raise KconfigError(
"\n"
"Malformed {} in {}\n"
"Context: {}\n"
"Problematic data: {}\n"
"Reason: {}".format(
e.encoding, loc,
e.object[max(e.start - 40, 0):e.end + 40],
e.object[e.start:e.end],
e.reason))
def _name_and_loc(sc):
# Helper for giving the symbol/choice name and location(s) in e.g. warnings
name = sc.name or "<choice>"
if not sc.nodes:
return name + " (undefined)"
return "{} (defined at {})".format(
name,
", ".join("{}:{}".format(node.filename, node.linenr)
for node in sc.nodes))
# Menu manipulation
def _expr_depends_on(expr, sym):
# Reimplementation of expr_depends_symbol() from mconf.c. Used to determine
# if a submenu should be implicitly created. This also influences which
# items inside choice statements are considered choice items.
if not isinstance(expr, tuple):
return expr is sym
if expr[0] in (EQUAL, UNEQUAL):
# Check for one of the following:
# sym = m/y, m/y = sym, sym != n, n != sym
left, right = expr[1:]
if right is sym:
left, right = right, left
elif left is not sym:
return False
return (expr[0] is EQUAL and right is sym.kconfig.m or \
right is sym.kconfig.y) or \
(expr[0] is UNEQUAL and right is sym.kconfig.n)
return expr[0] is AND and \
(_expr_depends_on(expr[1], sym) or
_expr_depends_on(expr[2], sym))
def _auto_menu_dep(node1, node2):
# Returns True if node2 has an "automatic menu dependency" on node1. If
# node2 has a prompt, we check its condition. Otherwise, we look directly
# at node2.dep.
# If node2 has no prompt, use its menu node dependencies instead
return _expr_depends_on(node2.prompt[1] if node2.prompt else node2.dep,
node1.item)
def _flatten(node):
# "Flattens" menu nodes without prompts (e.g. 'if' nodes and non-visible
# symbols with children from automatic menu creation) so that their
# children appear after them instead. This gives a clean menu structure
# with no unexpected "jumps" in the indentation.
#
# Do not flatten promptless choices (which can appear "legitimitely" if a
# named choice is defined in multiple locations to add on symbols). It
# looks confusing, and the menuconfig already shows all choice symbols if
# you enter the choice at some location with a prompt.
while node:
if node.list and not node.prompt and \
not isinstance(node.item, Choice):
last_node = node.list
while 1:
last_node.parent = node.parent
if not last_node.next:
break
last_node = last_node.next
last_node.next = node.next
node.next = node.list
node.list = None
node = node.next
def _remove_ifs(node):
# Removes 'if' nodes (which can be recognized by MenuNode.item being None),
# which are assumed to already have been flattened. The C implementation
# doesn't bother to do this, but we expose the menu tree directly, and it
# makes it nicer to work with.
first = node.list
while first and first.item is None:
first = first.next
cur = first
while cur:
if cur.next and cur.next.item is None:
cur.next = cur.next.next
cur = cur.next
node.list = first
def _finalize_choice(node):
# Finalizes a choice, marking each symbol whose menu node has the choice as
# the parent as a choice symbol, and automatically determining types if not
# specified.
choice = node.item
cur = node.list
while cur:
if isinstance(cur.item, Symbol):
cur.item.choice = choice
choice.syms.append(cur.item)
cur = cur.next
# If no type is specified for the choice, its type is that of
# the first choice item with a specified type
if choice.orig_type is UNKNOWN:
for item in choice.syms:
if item.orig_type is not UNKNOWN:
choice.orig_type = item.orig_type
break
# Each choice item of UNKNOWN type gets the type of the choice
for sym in choice.syms:
if sym.orig_type is UNKNOWN:
sym.orig_type = choice.orig_type
def _check_dep_loop_sym(sym, ignore_choice):
# Detects dependency loops using depth-first search on the dependency graph
# (which is calculated earlier in Kconfig._build_dep()).
#
# Algorithm:
#
# 1. Symbols/choices start out with _visited = 0, meaning unvisited.
#
# 2. When a symbol/choice is first visited, _visited is set to 1, meaning
# "visited, potentially part of a dependency loop". The recursive
# search then continues from the symbol/choice.
#
# 3. If we run into a symbol/choice X with _visited already set to 1,
# there's a dependency loop. The loop is found on the call stack by
# recording symbols while returning ("on the way back") until X is seen
# again.
#
# 4. Once a symbol/choice and all its dependencies (or dependents in this
# case) have been checked recursively without detecting any loops, its
# _visited is set to 2, meaning "visited, not part of a dependency
# loop".
#
# This saves work if we run into the symbol/choice again in later calls
# to _check_dep_loop_sym(). We just return immediately.
#
# Choices complicate things, as every choice symbol depends on every other
# choice symbol in a sense. When a choice is "entered" via a choice symbol
# X, we visit all choice symbols from the choice except X, and prevent
# immediately revisiting the choice with a flag (ignore_choice).
#
# Maybe there's a better way to handle this (different flags or the
# like...)
if not sym._visited:
# sym._visited == 0, unvisited
sym._visited = 1
for dep in sym._dependents:
# Choices show up in Symbol._dependents when the choice has the
# symbol in a 'prompt' or 'default' condition (e.g.
# 'default ... if SYM').
#
# Since we aren't entering the choice via a choice symbol, all
# choice symbols need to be checked, hence the None.
loop = _check_dep_loop_choice(dep, None) \
if isinstance(dep, Choice) \
else _check_dep_loop_sym(dep, False)
if loop:
# Dependency loop found
return _found_dep_loop(loop, sym)
if sym.choice and not ignore_choice:
loop = _check_dep_loop_choice(sym.choice, sym)
if loop:
# Dependency loop found
return _found_dep_loop(loop, sym)
# The symbol is not part of a dependency loop
sym._visited = 2
# No dependency loop found
return None
if sym._visited == 2:
# The symbol was checked earlier and is already known to not be part of
# a dependency loop
return None
# sym._visited == 1, found a dependency loop. Return the symbol as the
# first element in it.
return (sym,)
def _check_dep_loop_choice(choice, skip):
if not choice._visited:
# choice._visited == 0, unvisited
choice._visited = 1
# Check for loops involving choice symbols. If we came here via a
# choice symbol, skip that one, as we'd get a false positive
# '<sym FOO> -> <choice> -> <sym FOO>' loop otherwise.
for sym in choice.syms:
if sym is not skip:
# Prevent the choice from being immediately re-entered via the
# "is a choice symbol" path by passing True
loop = _check_dep_loop_sym(sym, True)
if loop:
# Dependency loop found
return _found_dep_loop(loop, choice)
# The choice is not part of a dependency loop
choice._visited = 2
# No dependency loop found
return None
if choice._visited == 2:
# The choice was checked earlier and is already known to not be part of
# a dependency loop
return None
# choice._visited == 1, found a dependency loop. Return the choice as the
# first element in it.
return (choice,)
def _found_dep_loop(loop, cur):
# Called "on the way back" when we know we have a loop
# Is the symbol/choice 'cur' where the loop started?
if cur is not loop[0]:
# Nope, it's just a part of the loop
return loop + (cur,)
# Yep, we have the entire loop. Throw an exception that shows it.
msg = "\nDependency loop\n" \
"===============\n\n"
for item in loop:
if item is not loop[0]:
msg += "...depends on "
if isinstance(item, Symbol) and item.choice:
msg += "the choice symbol "
msg += "{}, with definition...\n\n{}\n" \
.format(_name_and_loc(item), item)
# Small wart: Since we reuse the already calculated
# Symbol/Choice._dependents sets for recursive dependency detection, we
# lose information on whether a dependency came from a 'select'/'imply'
# condition or e.g. a 'depends on'.
#
# This might cause selecting symbols to "disappear". For example,
# a symbol B having 'select A if C' gives a direct dependency from A to
# C, since it corresponds to a reverse dependency of B && C.
#
# Always print reverse dependencies for symbols that have them to make
# sure information isn't lost. I wonder if there's some neat way to
# improve this.
if isinstance(item, Symbol):
if item.rev_dep is not item.kconfig.n:
msg += "(select-related dependencies: {})\n\n" \
.format(expr_str(item.rev_dep))
if item.weak_rev_dep is not item.kconfig.n:
msg += "(imply-related dependencies: {})\n\n" \
.format(expr_str(item.rev_dep))
msg += "...depends again on {}".format(_name_and_loc(loop[0]))
raise KconfigError(msg)
def _check_sym_sanity(sym):
# Checks various symbol properties that are handiest to check after
# parsing. Only generates errors and warnings.
if sym.orig_type in (BOOL, TRISTATE):
# A helper function could be factored out here, but keep it
# speedy/straightforward for now. bool/tristate symbols are by far the
# most common, and most lack selects and implies.
for target_sym, _ in sym.selects:
if target_sym.orig_type not in (BOOL, TRISTATE, UNKNOWN):
sym.kconfig._warn("{} selects the {} symbol {}, which is not "
"bool or tristate"
.format(_name_and_loc(sym),
TYPE_TO_STR[target_sym.orig_type],
_name_and_loc(target_sym)))
for target_sym, _ in sym.implies:
if target_sym.orig_type not in (BOOL, TRISTATE, UNKNOWN):
sym.kconfig._warn("{} implies the {} symbol {}, which is not "
"bool or tristate"
.format(_name_and_loc(sym),
TYPE_TO_STR[target_sym.orig_type],
_name_and_loc(target_sym)))
elif sym.orig_type in (STRING, INT, HEX):
for default, _ in sym.defaults:
if not isinstance(default, Symbol):
raise KconfigError(
"the {} symbol {} has a malformed default {} -- expected "
"a single symbol"
.format(TYPE_TO_STR[sym.orig_type], _name_and_loc(sym),
expr_str(default)))
if sym.orig_type is STRING:
if not default.is_constant and not default.nodes and \
not default.name.isupper():
# 'default foo' on a string symbol could be either a symbol
# reference or someone leaving out the quotes. Guess that
# the quotes were left out if 'foo' isn't all-uppercase
# (and no symbol named 'foo' exists).
sym.kconfig._warn("style: quotes recommended around "
"default value for string symbol "
+ _name_and_loc(sym))
elif sym.orig_type in (INT, HEX) and \
not _int_hex_ok(default, sym.orig_type):
sym.kconfig._warn("the {0} symbol {1} has a non-{0} default {2}"
.format(TYPE_TO_STR[sym.orig_type],
_name_and_loc(sym),
_name_and_loc(default)))
if sym.selects or sym.implies:
sym.kconfig._warn("the {} symbol {} has selects or implies"
.format(TYPE_TO_STR[sym.orig_type],
_name_and_loc(sym)))
else: # UNKNOWN
sym.kconfig._warn("{} defined without a type"
.format(_name_and_loc(sym)))
if sym.ranges:
if sym.orig_type not in (INT, HEX):
sym.kconfig._warn(
"the {} symbol {} has ranges, but is not int or hex"
.format(TYPE_TO_STR[sym.orig_type], _name_and_loc(sym)))
else:
for low, high, _ in sym.ranges:
if not _int_hex_ok(low, sym.orig_type) or \
not _int_hex_ok(high, sym.orig_type):
sym.kconfig._warn("the {0} symbol {1} has a non-{0} range "
"[{2}, {3}]"
.format(TYPE_TO_STR[sym.orig_type],
_name_and_loc(sym),
_name_and_loc(low),
_name_and_loc(high)))
def _int_hex_ok(sym, type_):
# Returns True if the (possibly constant) symbol 'sym' is valid as a value
# for a symbol of type type_ (INT or HEX)
# 'not sym.nodes' implies a constant or undefined symbol, e.g. a plain
# "123"
if not sym.nodes:
return _is_base_n(sym.name, _TYPE_TO_BASE[type_])
return sym.orig_type is type_
def _check_choice_sanity(choice):
# Checks various choice properties that are handiest to check after
# parsing. Only generates errors and warnings.
if choice.orig_type not in (BOOL, TRISTATE):
choice.kconfig._warn("{} defined with type {}"
.format(_name_and_loc(choice),
TYPE_TO_STR[choice.orig_type]))
for node in choice.nodes:
if node.prompt:
break
else:
choice.kconfig._warn(_name_and_loc(choice) +
" defined without a prompt")
for default, _ in choice.defaults:
if not isinstance(default, Symbol):
raise KconfigError(
"{} has a malformed default {}"
.format(_name_and_loc(choice), expr_str(default)))
if default.choice is not choice:
choice.kconfig._warn("the default selection {} of {} is not "
"contained in the choice"
.format(_name_and_loc(default),
_name_and_loc(choice)))
for sym in choice.syms:
if sym.defaults:
sym.kconfig._warn("default on the choice symbol {} will have "
"no effect".format(_name_and_loc(sym)))
if sym.rev_dep is not sym.kconfig.n:
_warn_choice_select_imply(sym, sym.rev_dep, "selected")
if sym.weak_rev_dep is not sym.kconfig.n:
_warn_choice_select_imply(sym, sym.weak_rev_dep, "implied")
for node in sym.nodes:
if node.parent.item is choice:
if not node.prompt:
sym.kconfig._warn("the choice symbol {} has no prompt"
.format(_name_and_loc(sym)))
elif node.prompt:
sym.kconfig._warn("the choice symbol {} is defined with a "
"prompt outside the choice"
.format(_name_and_loc(sym)))
def _warn_choice_select_imply(sym, expr, expr_type):
msg = "the choice symbol {} is {} by the following symbols, which has " \
"no effect: ".format(_name_and_loc(sym), expr_type)
# si = select/imply
for si in split_expr(expr, OR):
msg += "\n - " + _name_and_loc(split_expr(si, AND)[0])
sym.kconfig._warn(msg)
# Predefined preprocessor functions
def _filename_fn(kconf, args):
return kconf._filename
def _lineno_fn(kconf, args):
return str(kconf._linenr)
def _info_fn(kconf, args):
print("{}:{}: {}".format(kconf._filename, kconf._linenr, args[1]))
return ""
def _warning_if_fn(kconf, args):
if args[1] == "y":
kconf._warn(args[2], kconf._filename, kconf._linenr)
return ""
def _error_if_fn(kconf, args):
if args[1] == "y":
raise KconfigError("{}:{}: {}".format(
kconf._filename, kconf._linenr, args[2]))
return ""
def _shell_fn(kconf, args):
stdout, stderr = subprocess.Popen(
args[1], shell=True, stdout=subprocess.PIPE, stderr=subprocess.PIPE
).communicate()
if not _IS_PY2:
try:
stdout = stdout.decode(kconf._encoding)
stderr = stderr.decode(kconf._encoding)
except UnicodeDecodeError as e:
_decoding_error(e, kconf._filename, kconf._linenr)
if stderr:
kconf._warn("'{}' wrote to stderr: {}".format(
args[1], "\n".join(stderr.splitlines())),
kconf._filename, kconf._linenr)
# Manual universal newlines with splitlines() (to prevent e.g. stray \r's
# in command output on Windows), trailing newline removal, and
# newline-to-space conversion.
#
# On Python 3 versions before 3.6, it's not possible to specify the
# encoding when passing universal_newlines=True to Popen() (the 'encoding'
# parameter was added in 3.6), so we do this manual version instead.
return "\n".join(stdout.splitlines()).rstrip("\n").replace("\n", " ")
#
# Public global constants
#
# Integers representing symbol types
(
BOOL,
HEX,
INT,
STRING,
TRISTATE,
UNKNOWN
) = range(6)
# Integers representing menu and comment menu nodes
(
MENU,
COMMENT,
) = range(2)
# Converts a symbol/choice type to a string
TYPE_TO_STR = {
UNKNOWN: "unknown",
BOOL: "bool",
TRISTATE: "tristate",
STRING: "string",
HEX: "hex",
INT: "int",
}
TRI_TO_STR = {
0: "n",
1: "m",
2: "y",
}
STR_TO_TRI = {
"n": 0,
"m": 1,
"y": 2,
}
#
# Internal global constants (plus public expression type
# constants)
#
# Note:
#
# The token and type constants below are safe to test with 'is', which is a bit
# faster (~30% faster in a microbenchmark with Python 3 on my machine, and a
# few % faster for total parsing time), even without assuming Python's small
# integer optimization (which caches small integer objects). The constants end
# up pointing to unique integer objects, and since we consistently refer to
# them via the names below, we always get the same object.
#
# Client code would also need to use the names below, because the integer
# values can change e.g. when tokens get added. Client code would usually test
# with == too, which would be safe even in super obscure cases involving e.g.
# pickling (where 'is' would be a bad idea anyway) and no small-integer
# optimization.
# Are we running on Python 2?
_IS_PY2 = sys.version_info[0] < 3
# Tokens, with values 1, 2, ... . Avoiding 0 simplifies some checks by making
# all tokens except empty strings truthy.
(
_T_ALLNOCONFIG_Y,
_T_AND,
_T_BOOL,
_T_CHOICE,
_T_CLOSE_PAREN,
_T_COMMENT,
_T_CONFIG,
_T_DEFAULT,
_T_DEFCONFIG_LIST,
_T_DEF_BOOL,
_T_DEF_HEX,
_T_DEF_INT,
_T_DEF_STRING,
_T_DEF_TRISTATE,
_T_DEPENDS,
_T_ENDCHOICE,
_T_ENDIF,
_T_ENDMENU,
_T_ENV,
_T_EQUAL,
_T_GREATER,
_T_GREATER_EQUAL,
_T_HELP,
_T_HEX,
_T_IF,
_T_IMPLY,
_T_INT,
_T_LESS,
_T_LESS_EQUAL,
_T_MAINMENU,
_T_MENU,
_T_MENUCONFIG,
_T_MODULES,
_T_NOT,
_T_ON,
_T_OPEN_PAREN,
_T_OPTION,
_T_OPTIONAL,
_T_OR,
_T_ORSOURCE,
_T_OSOURCE,
_T_PROMPT,
_T_RANGE,
_T_RSOURCE,
_T_SELECT,
_T_SOURCE,
_T_STRING,
_T_TRISTATE,
_T_UNEQUAL,
_T_VISIBLE,
) = range(1, 51)
# Public integers representing expression types
#
# Having these match the value of the corresponding tokens removes the need
# for conversion
AND = _T_AND
OR = _T_OR
NOT = _T_NOT
EQUAL = _T_EQUAL
UNEQUAL = _T_UNEQUAL
LESS = _T_LESS
LESS_EQUAL = _T_LESS_EQUAL
GREATER = _T_GREATER
GREATER_EQUAL = _T_GREATER_EQUAL
# Keyword to token map, with the get() method assigned directly as a small
# optimization
_get_keyword = {
"---help---": _T_HELP,
"allnoconfig_y": _T_ALLNOCONFIG_Y,
"bool": _T_BOOL,
"boolean": _T_BOOL,
"choice": _T_CHOICE,
"comment": _T_COMMENT,
"config": _T_CONFIG,
"def_bool": _T_DEF_BOOL,
"def_hex": _T_DEF_HEX,
"def_int": _T_DEF_INT,
"def_string": _T_DEF_STRING,
"def_tristate": _T_DEF_TRISTATE,
"default": _T_DEFAULT,
"defconfig_list": _T_DEFCONFIG_LIST,
"depends": _T_DEPENDS,
"endchoice": _T_ENDCHOICE,
"endif": _T_ENDIF,
"endmenu": _T_ENDMENU,
"env": _T_ENV,
"grsource": _T_ORSOURCE, # Backwards compatibility
"gsource": _T_OSOURCE, # Backwards compatibility
"help": _T_HELP,
"hex": _T_HEX,
"if": _T_IF,
"imply": _T_IMPLY,
"int": _T_INT,
"mainmenu": _T_MAINMENU,
"menu": _T_MENU,
"menuconfig": _T_MENUCONFIG,
"modules": _T_MODULES,
"on": _T_ON,
"option": _T_OPTION,
"optional": _T_OPTIONAL,
"orsource": _T_ORSOURCE,
"osource": _T_OSOURCE,
"prompt": _T_PROMPT,
"range": _T_RANGE,
"rsource": _T_RSOURCE,
"select": _T_SELECT,
"source": _T_SOURCE,
"string": _T_STRING,
"tristate": _T_TRISTATE,
"visible": _T_VISIBLE,
}.get
# Tokens after which strings are expected. This is used to tell strings from
# constant symbol references during tokenization, both of which are enclosed in
# quotes.
#
# Identifier-like lexemes ("missing quotes") are also treated as strings after
# these tokens. _T_CHOICE is included to avoid symbols being registered for
# named choices.
_STRING_LEX = frozenset((
_T_BOOL,
_T_CHOICE,
_T_COMMENT,
_T_HEX,
_T_INT,
_T_MAINMENU,
_T_MENU,
_T_ORSOURCE,
_T_OSOURCE,
_T_PROMPT,
_T_RSOURCE,
_T_SOURCE,
_T_STRING,
_T_TRISTATE,
))
# Tokens for types, excluding def_bool, def_tristate, etc., for quick
# checks during parsing
_TYPE_TOKENS = frozenset((
_T_BOOL,
_T_TRISTATE,
_T_INT,
_T_HEX,
_T_STRING,
))
# Helper functions for getting compiled regular expressions, with the needed
# matching function returned directly as a small optimization.
#
# Use ASCII regex matching on Python 3. It's already the default on Python 2.
def _re_match(regex):
return re.compile(regex, 0 if _IS_PY2 else re.ASCII).match
def _re_search(regex):
return re.compile(regex, 0 if _IS_PY2 else re.ASCII).search
# Various regular expressions used during parsing
# The initial token on a line. Also eats leading and trailing whitespace, so
# that we can jump straight to the next token (or to the end of the line if
# there is only one token).
#
# This regex will also fail to match for empty lines and comment lines.
#
# '$' is included to detect a variable assignment left-hand side with a $ in it
# (which might be from a macro expansion).
_command_match = _re_match(r"\s*([$A-Za-z0-9_-]+)\s*")
# An identifier/keyword after the first token. Also eats trailing whitespace.
_id_keyword_match = _re_match(r"([A-Za-z0-9_/.-]+)\s*")
# A fragment in the left-hand side of a preprocessor variable assignment. These
# are the portions between macro expansions ($(foo)). Macros are supported in
# the LHS (variable name).
_assignment_lhs_fragment_match = _re_match("[A-Za-z0-9_-]*")
# The assignment operator and value (right-hand side) in a preprocessor
# variable assignment
_assignment_rhs_match = _re_match(r"\s*(=|:=|\+=)\s*(.*)")
# Special characters/strings while expanding a macro (')', ',', and '$(')
_macro_special_search = _re_search(r"\)|,|\$\(")
# Special characters/strings while expanding a string (quotes, '\', and '$(')
_string_special_search = _re_search(r'"|\'|\\|\$\(')
# A valid right-hand side for an assignment to a string symbol in a .config
# file, including escaped characters. Extracts the contents.
_conf_string_match = _re_match(r'"((?:[^\\"]|\\.)*)"')
# Token to type mapping
_TOKEN_TO_TYPE = {
_T_BOOL: BOOL,
_T_DEF_BOOL: BOOL,
_T_DEF_HEX: HEX,
_T_DEF_INT: INT,
_T_DEF_STRING: STRING,
_T_DEF_TRISTATE: TRISTATE,
_T_HEX: HEX,
_T_INT: INT,
_T_STRING: STRING,
_T_TRISTATE: TRISTATE,
}
# Constant representing that there's no cached choice selection. This is
# distinct from a cached None (no selection). We create a unique object (any
# will do) for it so we can test with 'is'.
_NO_CACHED_SELECTION = object()
# Used in comparisons. 0 means the base is inferred from the format of the
# string.
_TYPE_TO_BASE = {
HEX: 16,
INT: 10,
STRING: 0,
UNKNOWN: 0,
}
# Note: These constants deliberately equal the corresponding tokens (_T_EQUAL,
# _T_UNEQUAL, etc.), which removes the need for conversion
_RELATIONS = frozenset((
EQUAL,
UNEQUAL,
LESS,
LESS_EQUAL,
GREATER,
GREATER_EQUAL,
))
_REL_TO_STR = {
EQUAL: "=",
UNEQUAL: "!=",
LESS: "<",
LESS_EQUAL: "<=",
GREATER: ">",
GREATER_EQUAL: ">=",
}
_INIT_SRCTREE_NOTE = """
NOTE: Starting with Kconfiglib 10.0.0, the Kconfig filename passed to
Kconfig.__init__() is looked up relative to $srctree (which is set to '{}')
instead of relative to the working directory. Previously, $srctree only applied
to files being source'd within Kconfig files. This change makes running scripts
out-of-tree work seamlessly, with no special coding required. Sorry for the
backwards compatibility break!
"""[1:]
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