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configure
executable file
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configure
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#!/usr/bin/env bash
#
# BLIS
# An object-based framework for developing high-performance BLAS-like
# libraries.
#
# Copyright (C) 2014, The University of Texas at Austin
# Copyright (C) 2020-2022, Advanced Micro Devices, Inc.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions are
# met:
# - Redistributions of source code must retain the above copyright
# notice, this list of conditions and the following disclaimer.
# - Redistributions in binary form must reproduce the above copyright
# notice, this list of conditions and the following disclaimer in the
# documentation and/or other materials provided with the distribution.
# - Neither the name(s) of the copyright holder(s) nor the names of its
# contributors may be used to endorse or promote products derived
# from this software without specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
# HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#
#
# shellcheck disable=2001,2249,2034,2154,2181,2312,2250,2292
#
# -- Helper functions ----------------------------------------------------------
#
print_usage()
{
# Use the version string in the 'version' file since we don't have
# the patched version string yet.
if [ -z "${version}" ]; then
version=$(<"${version_filepath}")
fi
# Echo usage info.
cat <<EOF
${script_name} (BLIS ${version})
Configure BLIS's build system for compilation using a specified
configuration directory.
Usage:
${script_name} [options] [env. vars.] confname
Arguments:
confname The name of the sub-directory inside of the 'config'
directory containing the desired BLIS configuration.
Note that confname MUST be specified; if it is not,
configure will complain. To build a completely generic
implementation, use the 'generic' configuration
Options:
-p PREFIX, --prefix=PREFIX
The common installation prefix for all files. If given,
this option effectively implies:
--libdir=EXECPREFIX/lib
--includedir=PREFIX/include
--sharedir=PREFIX/share
where EXECPREFIX defaults to PREFIX. If this option is
not given, PREFIX defaults to '${prefix_def}'. If PREFIX
refers to a directory that does not exist, it will be
created.
--exec-prefix=EXECPREFIX
The installation prefix for libraries. Specifically, if
given, this option effectively implies:
--libdir=EXECPREFIX/lib
If not given, EXECPREFIX defaults to PREFIX, which may be
modified by the --prefix option. If EXECPREFIX refers to
a directory that does not exist, it will be created.
--libdir=LIBDIR
The path to which make will install libraries. If not
given, LIBDIR defaults to PREFIX/lib. If LIBDIR refers to
a directory that does not exist, it will be created.
--includedir=INCDIR
The path to which make will install development header
files. If not given, INCDIR defaults to PREFIX/include.
If INCDIR refers to a directory that does not exist, it
will be created.
--sharedir=SHAREDIR
The path to which make will makefile fragments containing
make variables determined by configure (e.g. CC, CFLAGS,
and LDFLAGS). These files allow certain BLIS makefiles,
such as those in the examples or testsuite directories, to
operate on an installed copy of BLIS rather than a local
(and possibly uninstalled) copy. If not given, SHAREDIR
defaults to PREFIX/share. If SHAREDIR refers to a
directory that does not exist, it will be created.
--enable-verbose-make, --disable-verbose-make
Enable (disabled by default) verbose compilation output
during make.
--enable-arg-max-hack --disable-arg-max-hack
Enable (disabled by default) build system logic that
will allow archiving/linking the static/shared library
even if the command plus command line arguments exceeds
the operating system limit (ARG_MAX).
-d DEBUG, --enable-debug[=DEBUG]
Enable debugging symbols in the library. If argument
DEBUG is given as 'opt', then optimization flags are
kept in the framework, otherwise optimization is
turned off.
--disable-static, --enable-static
Disable (enabled by default) building BLIS as a static
library. If the static library build is disabled, the
shared library build must remain enabled.
--disable-shared, --enable-shared
Disable (enabled by default) building BLIS as a shared
library. If the shared library build is disabled, the
static library build must remain enabled.
--omit-symbols=LIST
Omit a custom set of compatibility symbols when building
BLIS. When given, LIST is parsed as a comma-separated
list of symbol names (excluding any trailing underscore).
This option is useful when (1) the user is planning to
link BLIS with another library that provides conflicting
symbols, and (2) the user wishes the symbols in this
other library to prevail at link time without relying on
weak/strong symbol semantics. Note that currently ONLY
the following symbols are supported for omission:
crot zrot lsame
csymv zsymv xerbla
csyr zsyr xerbla_array
csyr2 zsyr2
--enable-lapack-compat, --disable-lapack-compat
Enable strict compatibility with LAPACK. This option
causes BLIS to be built without some routines that we
consider to be BLAS compatibility routines but that
also happen to be provided by LAPACK. This option is
equivalent to using the --omit-symbols=LIST option
where LIST contains the following symbols:
crot zrot lsame
csymv zsymv xerbla
csyr zsyr xerbla_array
csyr2 zsyr2
--enable-scalapack-compat, --disable-scalapack-compat
Enable strict compatibility with ScaLAPACK. This option
causes BLIS to be built without some routines that we
consider to be BLAS compatibility routines but that
also happen to be provided by ScaLAPACK. This option is
equivalent to using the --omit-symbols=LIST option
where LIST contains the following symbols:
csymv zsymv
csyr zsyr
csyr2 zsyr2
--enable-rpath, --disable-rpath
Enable (disabled by default) setting an install_name for
dynamic libraries on macOS which starts with @rpath rather
than the absolute install path.
-e SYMBOLS, --export-shared[=SYMBOLS]
Specify the subset of library symbols that are exported
within a shared library. Valid values for SYMBOLS are:
'public' (the default) and 'all'. By default, only
functions and variables that belong to public APIs are
exported in shared libraries. However, the user may
instead export all symbols in BLIS, even those that were
intended for internal use only. Note that the public APIs
encompass all functions that almost any user would ever
want to call, including the BLAS/CBLAS compatibility APIs
as well as the basic and expert interfaces to the typed
and object APIs that are unique to BLIS. Also note that
changing this option to 'all' will have no effect in some
environments, such as when compiling with clang on
Windows.
-t MODEL, --enable-threading[=MODEL], --disable-threading
Enable threading in the library, using threading model(s)
MODEL={single,openmp,pthreads,hpx,auto}. If multiple values
are specified within MODEL, they will all be compiled into
BLIS, and the choice of which to use will be determined at
runtime. If the user does not express a preference (by
setting the BLIS_THREAD_IMPL environment variable to
'single', 'openmp', 'pthreads', or 'hpx'; by calling the
global runtime API bli_thread_set_thread_impl(); or by
encoding a choice on a per-call basis within a rntm_t
passed into the expert API), then the first model listed
in MODEL will be used by default. Note that 'single' is
silently appended to whatever the user specifies in MODEL,
meaning that single-threaded functionality will always be
available, even if it is not requested and even if it is
not enabled by default. Even --disable-threading is
actually shorthand for --enable-threading=single (which is
the default when the option is not specified).
--enable-system, --disable-system
Enable conventional operating system support, such as
pthreads for thread-safety. The default state is enabled.
However, in rare circumstances you may wish to configure
BLIS for use with a minimal or nonexistent operating
system (e.g. hardware simulators). In these situations,
--disable-system may be used to jettison all compile-time
and link-time dependencies outside of the standard C
library. When disabled, this option also forces the use
of --disable-threading.
--enable-tls, --disable-tls
Enable thread-local storage (TLS) for static variables
in BLIS. The default state is enabled. However, like with
--disable-system, there may be rare situations, such as
when --disable-system is appropriate, where thread-local
storage is unsupported by the compiler. In those cases,
disabling TLS may be a suitable workaround.
WARNING: DISABLING TLS IS DANGEROUS AND MAY CAUSE RACE
CONDITIONS! Please try combining --disable-tls with
--disable-threading if you suspect any correctness or
deadlock issues.
--disable-pba-pools, --enable-pba-pools
--disable-sba-pools, --enable-sba-pools
Disable (enabled by default) use of internal memory pools
within the packing block allocator (pba) and/or the small
block allocator (sba). The former is used to allocate
memory used to pack submatrices while the latter is used
to allocate control/thread tree nodes and thread
communicators. Both allocations take place in the context
of level-3 operations. When the pba is disabled, the
malloc()-like function specified by BLIS_MALLOC_POOL is
called on-demand whenever a packing block is needed, and
when the sba is disabled, the malloc()-like function
specified by BLIS_MALLOC_INTL is called whenever a small
block is needed, with the two allocators calling free()-
like functions BLIS_FREE_POOL and BLIS_FREE_INTL,
respectively when blocks are released. When enabled,
either or both pools are populated via the same functions
mentioned previously, and henceforth blocks are checked
out and in. The library quickly reaches a state in which
it no longer needs to call malloc() or free(), even
across many separate level-3 operation invocations.
--enable-mem-tracing, --disable-mem-tracing
Enable (disabled by default) output to stdout that traces
the allocation and freeing of memory, including the names
of the functions that triggered the allocation/freeing.
Enabling this option WILL NEGATIVELY IMPACT PERFORMANCE.
Please use only for informational/debugging purposes.
--enable-asan, --disable-asan
Enable (disabled by default) compiling and linking BLIS
framework code with the AddressSanitizer (ASan) library.
Optimized kernels are NOT compiled with ASan support due
to limitations of register assignment in inline assembly.
WARNING: ENABLING THIS OPTION WILL NEGATIVELY IMPACT
PERFORMANCE. Please use only for informational/debugging
purposes.
-i SIZE, --int-size=SIZE
Set the size (in bits) of internal BLIS integers and
integer types used in native BLIS interfaces. The
default integer type size is architecture dependent.
(Hint: You can always find this value printed at the
beginning of the testsuite output.)
-b SIZE, --blas-int-size=SIZE
Set the size (in bits) of integer types in external
BLAS and CBLAS interfaces, if enabled. The default
integer type size used in BLAS/CBLAS is 32 bits.
--disable-blas, --enable-blas
Disable (enabled by default) building the BLAS
compatibility layer.
--enable-cblas, --disable-cblas
Enable (disabled by default) building the CBLAS
compatibility layer. This automatically enables the
BLAS compatibility layer as well.
--disable-sup-handling, --enable-sup-handling
Disable (enabled by default) handling of small/skinny
matrix problems via separate code branches. When disabled,
these small/skinny level-3 operations will be performed by
the conventional implementation, which is optimized for
medium and large problems. Note that what qualifies as
"small" depends on thresholds that may vary by sub-
configuration.
--enable-amd-frame-tweaks, --disable-amd-frame-tweaks
Enable building with certain framework files that have
been customized by AMD for Zen-based microarchitectures.
The default counterparts of these files must be portable,
and so these customized files may provide some (typically
modest) performance improvement for some select operations
and/or APIs, though there may a few (tiny dimension) cases
where the improvement is more pronounced. Note that the
target configuration must be Zen-based (or 'amd64') for
this option to have any effect. (Also note that this
option is NOT to be confused with enabling AMD *kernels*,
which are determined by the BLIS subconfiguration used at
runtime.) By default, these customized files are disabled.
-a NAME --enable-addon=NAME
Enable the code provided by an addon. An addon consists
of a separate directory of code that provides additional
APIs, implementations, and/or operations that would
otherwise not be present within a build of BLIS. This
option may be used multiple times to specify the inclusion
of multiple addons. By default, no addons are enabled.
-s NAME --enable-sandbox=NAME
Enable a separate sandbox implementation of gemm. This
option disables BLIS's conventional gemm implementation
(which shares common infrastructure with other level-3
operations) and instead compiles and uses the code in
the NAME directory, which is expected to be a sub-
directory of 'sandbox'. By default, no sandboxes are
enabled.
--with-memkind, --without-memkind
Forcibly enable or disable the use of libmemkind's
hbw_malloc() and hbw_free() as substitutes for malloc()
and free(), respectively, when allocating memory for
BLIS's memory pools, which are used to manage buffers
into which matrices are packed. The default behavior
for this option is environment-dependent; if configure
detects the presence of libmemkind, libmemkind is used
by default, and otherwise it is not used by default.
-r METHOD, --thread-part-jrir=METHOD
Select a strategy for partitioning computation in JR and
IR loops and assigning that computation to threads. Valid
values for METHOD are 'rr', 'slab', and 'tlb':
'rr': Assign the computation associated with whole
columns of microtiles to threads in a round-
robin fashion. When selected, round-robin
assignment is also employed during packing.
'slab': Partition the computation into N contiguous
regions, where each region contains a whole
number of microtile columns, and assign one
region to each thread. For some operations, the
number of microtile columns contained within a
given region may differ from that of other
regions, depending on how much work is implied
by each region. When selected, slab assignment
is also employed during packing.
'tlb': Tile-level load balancing is similar to slab,
except that regions will be divided at a more
granular level (individual microtiles instead
of whole columns of microtiles) to ensure more
equitable assignment of work to threads. When
selected, tlb will only be employed for level-3
operations except trsm; due to practical and
algorithmic limitations, slab partitioning will
be used instead during packing and for trsm.
The default strategy is 'slab'. NOTE: Specifying this
option constitutes a request, which may be ignored in
select situations if implementation has a good reason to
do so. (See description of 'tlb' above for an example of
this.)
--disable-trsm-preinversion, --enable-trsm-preinversion
Disable (enabled by default) pre-inversion of triangular
matrix diagonals when performing trsm. When pre-inversion
is enabled, diagonal elements are inverted outside of the
microkernel (e.g. during packing) so that the microkernel
can use multiply instructions. When disabled, division
instructions are used within the microkernel. Executing
these division instructions within the microkernel will
incur a performance penalty, but numerical robustness will
improve for certain cases involving denormal numbers that
would otherwise result in overflow in the pre-inverted
values.
--force-version=STRING
Force configure to use an arbitrary version string
STRING. This option may be useful when repackaging
custom versions of BLIS by outside organizations.
-c, --show-config-lists
Print the config and kernel lists, and kernel-to-config
map after they are read from file. This can be useful
when debugging certain configuration issues, and/or as
a sanity check to make sure these lists are constituted
as expected.
--complex-return=gnu|intel
Specify the way in which complex numbers are returned
from Fortran functions, either "gnu" (return in
registers) or "intel" (return via hidden argument).
If not specified and the environment variable FC is set,
attempt to determine the return type from the compiler.
Otherwise, the default is "gnu".
-q, --quiet Suppress informational output. By default, configure
is verbose. (NOTE: -q is not yet implemented)
-h, --help Output this information and quit.
Environment Variables:
CC Specifies the C compiler to use.
CXX Specifies the C++ compiler to use (sandbox only).
FC Specifies the Fortran compiler to use (only to determine --complex-return).
AR Specifies the static library archiver to use.
RANLIB Specifies the ranlib (library indexer) executable to use.
PYTHON Specifies the python interpreter to use.
CFLAGS Specifies additional compiler flags to use (prepended).
LDFLAGS Specifies additional linker flags to use (prepended).
LIBPTHREAD Pthreads library to use.
Environment variables are traditionally set prior to running configure:
CC=gcc ./configure [options] haswell
However, they may also be specified as command line options, e.g.:
./configure [options] CC=gcc haswell
Note that not all compilers are compatible with a given
configuration.
EOF
# Exit with non-zero exit status
exit 1
}
query_array()
{
local arr key var_name
arr="$1"
key="$2"
var_name="${arr}_${key}"
echo "${!var_name}"
}
assign_key_value()
{
local arr key val
arr="$1"
key="$2"
val="$3"
printf -v "${arr}_${key}" %s "${val}"
}
fully_eval()
{
local old new
old=""
new="$1"
while [ "x${old}" != "x${new}" ]; do
old="${new}"
new=$(eval echo "${old}")
done
echo "${new}"
}
add_config_var()
{
local sub_var var
sub_var="$1"
var="${2:-${sub_var}}"
#
# Use the | character in the substitution command to avoid mangling variables
# which contain forward slashes (e.g. paths). There *shouldn't* be any variables
# that have | in them...
#
config_substitutions="${config_substitutions} -e \\\"s|\@${sub_var}\@|\${${var}}|g;\\\""
}
generate_config_file()
{
local in_file out_file sub
in_file="$1"
out_file="$2"
echo "${script_name}: creating ${out_file} from ${in_file}"
#
# Use 'eval' to expand the variable references.
#
eval "sub=\"${config_substitutions}\""
#
# 'eval' also has to be used here to get the proper quoting.
# This 'eval' CAN NOT be combined with the one above.
#
eval "perl -p ${sub} <\"${in_file}\" >\"${out_file}\""
}
#
# FGVZ: This commented-out function is being kept as an example how how
# to effectively "pass by reference" in bash. That is, pass the name of
# a variable, instead of its conents, and then let the function use the
# variable by prepending a $, at which time it can evaluate the string
# as if it were a literal variable occurance.
#
#filteradd_to_list()
#{
# local dlist ditem list_c item_c is_blacklisted
#
# # Add $1 to the list identified by $2, but only if $1 is not
# # found in a blacklist.
#
# # Note: $2 can actually be a list of items.
# ditem=\$"$1"
# dlist=\$"$2"
#
# # Acquire the contents of $dlist and $ditem and store them in list_c
# # and item_c, respectively.
# list_c=$(eval "expr \"$dlist\" ")
# item_c=$(eval "expr \"$ditem\" ")
#
# # Iterate over $item_c in case it is actually multiple items.
# for cur_item in $item_c; do
#
# is_blacklisted=$(is_in_list "${cur_item}" "${config_blist}")
# if [ ${is_blacklisted} == "false" ]; then
#
# # If cur_item is not blacklisted, add it to list_c.
# list_c="${list_c} ${cur_item}"
# fi
# done
#
# # Update the argument.
# eval "$2=\"${list_c}\""
#}
pass_config_kernel_registries()
{
local filename passnum
local all_blist
local curline list item config kernels
local cname clist klist
# Read function arguments:
# first argument: the file containing the configuration registry.
# second argument: the pass number: 0 or 1. Pass 0 builds the
# indirect config blacklist (indirect_blist) ONLY. Pass 1 actually
# begins populating the config and kernel registries, and assumes
# the indirect_blist has already been created.
filename="$1"
passnum="$2"
# Initialize a list of indirect blacklisted configurations for the
# current iteration. These are configurations that are invalidated by
# the removal of blacklisted configurations. For example, if haswell
# is registered as needing the 'haswell' and 'zen' kernel sets:
#
# haswell: haswell/haswell/zen
#
# and 'zen' was blacklisted because of the compiler version, then the
# 'haswell' configuration must be omitted from the registry, as it no
# longer has all of the kernel sets it was expecting.
if [ "${passnum}" == "0" ]; then
indirect_blist=""
fi
# For convenience, merge the original and indirect blacklists.
# NOTE: During pass 0, all_blist is equal to config_blist, since
# indirect_blist is still empty.
all_blist="${config_blist} ${indirect_blist}"
# Disable support for indirect blacklisting by returning early during
# pass 0. See issue #214 for details [1]. Basically, I realized that
# indirect blacklisting is not needed in the use case that I envisioned
# in the real-life example above. If a subconfiguration such as haswell
# is defined to require the zen kernel set, it implies that the zen
# kernels can be compiled with haswell compiler flags. That is, just
# because the zen subconfig (and its compiler flags) is blacklisted
# does not mean that the haswell subconfig cannot compile the zen
# kernels with haswell-specific flags.
#
# [1] https://github.com/flame/blis/issues/214
#
if [ "${passnum}" == "0" ]; then
return
fi
while read -r line
do
curline="${line}"
# Remove everything after comment character '#'.
curline=${curline%%#*}
# We've stripped out leading whitespace and trailing comments. If
# the line is now empty, then we can skip it altogether.
if [[ -z ${curline} ]]; then
continue;
fi
# Read the config name and config list for the current line.
cname=${curline%%:*}
list=${curline##*:}
# If we encounter a slash, it means the name of the configuration
# and the kernel set needed by that configuration are different.
if [[ ${list} = */* ]]; then
#echo "Slash found."
klist=""
clist=""
for item in ${list}; do
# The sub-configuration name is always the first sub-word in
# the slash-separated compound word.
config=${item%%/*}
# Delete the sub-configuration name from the front of the
# string, leaving the slash-separated kernel names (or just
# the kernel name, if there is only one).
kernels=${list#*/}
# Replace the slashes with spaces to transform the string
# into a space-separated list of kernel names.
kernels=$(echo -e "${kernels}" | sed -e "s/\// /g")
clist="${clist} ${config}"
klist="${klist} ${kernels}"
done
else
#echo "Slash not found."
clist=${list}
klist=${list}
fi
# Strip out whitespace from the config name and config/kernel list
# on each line.
cname=$(canonicalize_ws "${cname}")
clist=$(canonicalize_ws "${clist}")
klist=$(canonicalize_ws "${klist}")
# Next, we prepare to:
# - pass 0: inspect klist for blacklisted configurations, which may
# reveal configurations as needing to be indirectly blacklisted.
# - pass 1: compare cname to the blacklists and commit clist/klist
# to their respective registries, as appropriate.
# Add cname to full_config_list. Duplicates will
# be filtered out later.
full_config_list="${full_config_list} ${cname}"
# Handle singleton and umbrella configuration entries separately.
if [[ $(is_singleton_family "${cname}" "${clist}") == "true" ]]; then
# Singleton configurations/families.
# Note: for singleton families, clist contains one item, which
# always equals cname, but klist could contain more than one
# item.
# Add the kernels in klist to full_kernel_list. Duplicates will
# be filtered out later.
full_subconfig_list="${full_subconfig_list} ${cname}"
full_kernel_list="${full_kernel_list} ${klist}"
# Only consider updating the indirect blacklist (pass 0) or
# committing clist and klist to the registries (pass 1) if the
# configuration name (cname) is not blacklisted.
if [[ $(is_in_list "${cname}" "${all_blist}") == "false" ]]; then
if [ "${passnum}" == "0" ]; then
# Even if the cname isn't blacklisted, one of the requisite
# kernels might be, so we need to check klist for blacklisted
# items. If we find one, we must assume that the entire entry
# must be thrown out. (Ideally, we would simply fall back to
# reference code for the blacklisted kernels, but that is not
# at all straightforward under the current configuration
# system architecture.) Thus, we add cname to the indirect
# blacklist.
for item in ${klist}; do
if [[ $(is_in_list "${item}" "${config_blist}") == "true" ]]; then
indirect_blist="${indirect_blist} ${cname}"
break
fi
done
fi
if [ "${passnum}" == "1" ]; then
# Store the clist to the cname key of the config registry.
#config_registry[${cname}]=${clist}
#printf -v "config_registry_${cname}" %s "${clist}"
assign_key_value "config_registry" "${cname}" "${clist}"
fi
fi
if [ "${passnum}" == "1" ]; then
# Store the klist to the cname key of the kernel registry.
#kernel_registry[${cname}]=${klist}
#printf -v "kernel_registry_${cname}" %s "${klist}"
assign_key_value "kernel_registry" "${cname}" "${klist}"
fi
else
# Umbrella configurations/families.
# First we check cname, which should generally not be blacklisted
# for umbrella families, but we check anyway just to be safe.
if [[ $(is_in_list "${cname}" "${all_blist}") == "false" ]]; then
if [ "${passnum}" == "1" ]; then
# Check each item in the clist and klist. (At this point,
# clist == klist.) If any sub-config is blacklisted, we
# omit it from clist and klist.
for item in ${clist}; do
if [[ $(is_in_list "${item}" "${all_blist}") == "true" ]]; then
clist=$(remove_from_list "${item}" "${clist}")
klist=$(remove_from_list "${item}" "${klist}")
fi
done
# Store the config and kernel lists to entries that
# corresponds to the config name.
#config_registry[${cname}]=${clist}
#kernel_registry[${cname}]=${klist}
#printf -v "config_registry_${cname}" %s "${clist}"
#printf -v "kernel_registry_${cname}" %s "${klist}"
assign_key_value "config_registry" "${cname}" "${clist}"
assign_key_value "kernel_registry" "${cname}" "${klist}"
fi
fi
fi
done < "${filename}"
if [ "${passnum}" == "0" ]; then
# Assign the final indirect blacklist (with whitespace removed).
indirect_blist=$(canonicalize_ws "${indirect_blist}")
fi
# Remove duplicates and excess whitespace from the full config and
# kernel lists.
full_config_list=$(canonicalize_ws "$(rm_duplicate_words_simple "${full_config_list}")")
full_subconfig_list=$(canonicalize_ws "$(rm_duplicate_words_simple "${full_subconfig_list}")")
full_kernel_list=$(canonicalize_ws "$(rm_duplicate_words_simple "${full_kernel_list}")")
}
read_registry_file()
{
local filename
local clist klist
local iterate_again config
local cr_var mem mems_mem newclist
local kr_var ker kers_ker newklist
filename="$1"
# Execute an initial pass through the config_registry file so that
# we can accumulate a list of indirectly blacklisted configurations,
# if any.
pass_config_kernel_registries "${filename}" "0"
# Now that the indirect_blist has been created, make a second pass
# through the 'config_registry' file, this time creating the actual
# config and kernel registry data structures.
pass_config_kernel_registries "${filename}" "1"
# Now we must go back through the config_registry and subsitute any
# configuration families with their constituents' members. Each time
# one of these substitutions occurs, we set a flag that causes us to
# make one more pass. (Subsituting a singleton definition does not
# prompt additional iterations.) This process stops when a full pass
# does not result in any subsitution.
iterate_again="1"
while [ "${iterate_again}" == "1" ]; do
iterate_again="0"
#for config in "${!config_registry[@]}"; do
for cr_var in ${!config_registry_*}; do
config=${cr_var##config_registry_}
clist=$(query_array "config_registry" "${config}")
# The entries that define singleton families should never need
# any substitution.
if [[ $(is_singleton_family "${config}" "${clist}") == "true" ]]; then
continue
fi
#for mem in ${config_registry[$config]}; do
#for mem in ${!cr_var}; do
for mem in ${clist}; do
#mems_mem="${config_registry[${mem}]}"
mems_mem=$(query_array "config_registry" "${mem}")
# If mems_mem is empty string, then mem was not found as a key
# in the config list associative array. In that case, we continue
# and will echo an error later in the script.
if [ "${mems_mem}" == "" ]; then
#echo " config for ${mem} is empty string! no entry in config list."
continue;
fi
if [ "${mem}" != "${mems_mem}" ]; then
#clist="${config_registry[$config]}"
clisttmp=$(query_array "config_registry" "${config}")
# Replace the current config with its constituent config set,
# canonicalize whitespace, and then remove duplicate config
# set names, if they exist. Finally, update the config registry
# with the new config list.
# NOTE: WE must use substitute_words() rather than a simple sed
# expression because we need to avoid matching partial strings.
# For example, if clist above contains "foo bar barsk" and we use
# sed to substitute "bee boo" as the members of "bar", the
# result would (incorrectly) be "foo bee boo bee boosk",
# which would then get reduced, via rm_duplicate_words(), to
# "foo bee boo boosk".
#newclist=$(echo -e "${clist}" | sed -e "s/${mem}/${mems_mem}/g")
newclist=$(substitute_words "${mem}" "${mems_mem}" "${clisttmp}")
newclist=$(canonicalize_ws "${newclist}")
newclist=$(rm_duplicate_words "${newclist}")
#config_registry[${config}]=${newclist}
#printf -v "config_registry_${config}" %s "${newclist}"
assign_key_value "config_registry" "${config}" "${newclist}"
# Since we performed a substitution and changed the config
# list, mark the iteration flag to continue another round,
# but only if the config (mem) value is NOT present
# in the list of sub-configs. If it is present, then further
# substitution may not necessarily be needed this round.
if [[ $(is_in_list "${mem}" "${mems_mem}") == "false" ]]; then
iterate_again="1"
fi
fi
done
done
done
# Similar to what we just did for the config_registry, we now iterate
# through the kernel_registry and substitute any configuration families
# in the kernel list (right side of ':') with the members of that
# family's kernel set. This process continues iteratively, as before,
# until all families have been replaced with singleton configurations'
# kernel sets.
iterate_again="1"
while [ "${iterate_again}" == "1" ]; do
iterate_again="0"
#for config in "${!kernel_registry[@]}"; do
for kr_var in ${!kernel_registry_*}; do
config=${kr_var##kernel_registry_}
klist=$(query_array "kernel_registry" "${config}")
# The entries that define singleton families should never need
# any substitution. In the kernel registry, we know it's a
# singleton entry when the cname occurs somewhere in the klist.
# (This is slightly different than the same test in the config
# registry, where we test that clist is one word and that
# clist == cname.)
if [[ $(is_in_list "${config}" "${klist}") == "true" ]]; then
#echo "debug: '${config}' not found in '${klist}'; skipping."
continue
fi
#for ker in ${kernel_registry[$config]}; do
#for ker in ${!kr_var}; do
for ker in ${klist}; do
#kers_ker="${kernel_registry[${ker}]}"
kers_ker=$(query_array "kernel_registry" "${ker}")
# If kers_ker is empty string, then ker was not found as a key
# in the kernel registry. While not common, this can happen
# when ker identifies a kernel set that does not correspond to
# any configuration. (Example: armv7a and armv8a kernel sets are
# used by cortexa* configurations, but do not corresond to their
# own configurations.)
if [ "${kers_ker}" == "" ]; then
#echo "debug: ${ker} not found in kernel registry."
continue
fi
# If the current config/kernel (ker) differs from its singleton kernel
# entry (kers_ker), then that singleton entry was specified to use
# a different configuration's kernel set. Thus, we need to replace the
# occurrence in the current config/kernel name with that of the kernel
# set it needs.
if [ "${ker}" != "${kers_ker}" ]; then
#klisttmp="${kernel_registry[$config]}"
klisttmp=$(query_array "kernel_registry" "${config}")
# Replace the current config with its requisite kernels,
# canonicalize whitespace, and then remove duplicate kernel
# set names, if they exist. Finally, update the kernel registry
# with the new kernel list.
# NOTE: WE must use substitute_words() rather than a simple sed
# expression because we need to avoid matching partial strings.
# For example, if klist above contains "foo bar barsk" and we use
# sed to substitute "bee boo" as the members of "bar", the
# result would (incorrectly) be "foo bee boo bee boosk",
# which would then get reduced, via rm_duplicate_words(), to
# "foo bee boo boosk".
#newklist=$(echo -e "${klisttmp}" | sed -e "s/${ker}/${kers_ker}/g")
newklist=$(substitute_words "${ker}" "${kers_ker}" "${klisttmp}")
newklist=$(canonicalize_ws "${newklist}")
newklist=$(rm_duplicate_words "${newklist}")
#kernel_registry[${config}]=${newklist}
#printf -v "kernel_registry_${config}" %s "${newklist}"
assign_key_value "kernel_registry" "${config}" "${newklist}"
# Since we performed a substitution and changed the kernel
# list, mark the iteration flag to continue another round,
# unless we just substituted using a singleton family
# definition, in which case we don't necessarily need to
# iterate further this round.
if [[ $(is_in_list "${ker}" "${kers_ker}") == "false" ]]; then
iterate_again="1"
fi
fi
done
done
done
}
substitute_words()
{