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#!/bin/bash
#
#-----------------------------------------------------------------------------#
# This is a set of (recursive) functions for manipulating a dependency graph. #
# We use algorithms and definitions from chapter 4 (mainly section 4.2) of #
# https://algs4.cs.princeton.edu/. The graph we manipulate is the directed #
# graph of the dependencies: nodes are packages in the BLFS book. A node A is #
# connected to a node B if package A depends on B. A topological order (rev- #
# erted) is exactly what we want for a build order. But a topological order #
# only exists if the graph is acyclic. We'll therefore have to remove cycles. #
# There are a number of other features we want to consider: #
# - edges are weighted according to the dependency requirement: #
# 1 for required #
# 2 for recommended #
# 3 for optional #
# 4 for external #
# We should consider only edges with weight lower or equal to that #
# specified by the user, but see below. #
# - we do not want to build the whole book. The user requests a set of #
# packages, and we'd like to consider only nodes reachable from this set #
# using edges of weight not exceeding the specified weight. #
# - we do not want to rebuild packages already built. But we still have to #
# generate the full dependency graph, because if A depends on B, which is #
# already built, and B depends on C, which is not built, or needs to be #
# updated, then A may depends on C. We therefore have to remove already #
# built (and up to date) packages from the graph, but need to keep the #
# dependency chain. #
# - when doing the topological sort, we want to consider all the edges and #
# not only those not exceeding the specified weight: If a package A in the #
# reachable subgraph depends optionally on another package B in the same #
# subgraph, we want to build B before A if possible. But this means we'll #
# have to remove cycles for all weights. #
# - dependencies have another qualifier: before, after, or first. We use #
# it as follows: for "after", we can build the dependency after the #
# package, but if a package A depends on B with an "after" qualifier, and #
# a package C depends on A with a "before" qualifier, C may need B to be #
# able to use A. So the only safe way to consider "after" qualifiers is to #
# consider that they are "before" deps for any parent of the packages #
# considered. There is an exception to that rule: if B depends on C #
# (possibly through a chain of several dependencies), then C should still #
# be built before B. For "after", the dependency has to be built both #
# before and after the package. So we duplicate the dependency as a #
# "-pass1" package, and change the graph accordingly. #
# We'll therefore have a 3 pass procedure. First build the set of nodes #
# reachable from the root set. Second, remove dangling edges (those pointing #
# to packages outside the node set), and move "after" edges to "before" edges #
# originating from the parents as well as creating the "-pass1" nodes. Third #
# remove cycles and generate a topological sort. #
# #
# Pass 1: graph generation #
# ======================== #
# Data layout for pass 1 #
# ---------------------- #
# A node of the graph is represented by a text file <nodeName>.dep. Each edge #
# starting from this node is represented by a line in this file. We keep #
# those files in the same directory. We introduce a special node named root, #
# whose edges point to the list of nodes requested by the user. Each line #
# contains three fields: #
# - the weight of the edge #
# - the qualifier: "before" (b), "after" (a), or "first" (f) #
# - the name of the destination of the edge (without the ".dep" extension) #
# #
# Recursive function "generate_subgraph" #
# -------------------------------------- #
# This function treats a node of the graph that is not a leaf and that is #
# seen for the first time in the DFS. The dependencies of this node are #
# known, and stored in a .dep file. For each dependency in that file, there #
# are three cases: #
# - the weight of the edge leading to that dependency is higher than #
# requested. This dependency is discarded (some information printed) #
# - the weight of the edge is lower or equal to requested, but the node #
# has already been visited (the .dep file exists). Discard too (some #
# information printed) #
# - the weight of the edge is lower or equal to requested, and the node #
# has not been seen: then the dependencies of that node are generated, #
# and there are two cases: #
# - the node has no dependencies: just create an empty .dep file, so #
# that we know the node has been visited #
# - the node has dependencies: call generate_subgraph for that node #
# #
# This function takes four parameters: #
# - The node filename: this is the only one useful for the algorithm #
# - The depth: number of steps starting from root (for pretty print only) #
# - The weight of the edge leading to that node (for printing) #
# - The qualifier (for printing) #
# #
# Pass 2: graph transformation #
# ============================ #
# We now have three loops over nodes of the graph #
# Loop 1: Remove dead edges #
# ------------------------- #
# Since some nodes have not been created because the edges leading to them #
# had too high a weight, those edges have to be suppressed. #
# For each existing node file, we make a list of lines to remove by #
# testing whether the destination exists. We then remove the lines. #
# Another approach would be to make a temporary file and output only #
# lines that should stay, then rename the file. This would save a loop. #
# All in all it is an N*e process, where N is the number of nodes and e #
# the average number of edges originating from a node. #
# Loop 2: Treat "after" edges #
# --------------------------- #
# If a node is the origin of edges qualified as "after", we want the #
# nodes which are the destination of those edges to be built after #
# the origin node, but before any node that depend on the origin #
# node. For that, the general rule is to change: #
# P---b--->A---a--->D #
# to: #
# P---b--->Agroupxx---b--->A #
# | #
# ---b--->D #
# But there is a problem if D depends on P, possibly through a chain, #
# because we create a cycle which shouldn't exist. If this is the case, #
# we leave A as a dependency of P: #
# P---b--->A #
# #
# Agroupxx---b--->A #
# | #
# ---b--->D #
# Doing so, it may happen that Agroupxx has no parent. We then add #
# Agroupxx as a dependency of root. The problem with this algorithm is #
# the search for paths from D to A, which may be exponential in the #
# number of nodes in the graph. #
# #
# Loop 3: Add -pass1 nodes #
# ------------------------ #
# Sometimes there is no way to escape a cycle. A package A needs B, and B #
# needs A. In that case, it is often possible to build a degraded version #
# of package A, then B, then rebuild A. The book indicates this with the #
# following dependency chain, using a qualifier of "first": #
# B---f--->A---b--->X...Y---b--->B #
# where the X...Y notation represents a chain of dependencies from A to B. #
# So the third loop is over nodes containing "f" qualifiers, and does the #
# following: it creates a new node A-pass1, which is a copy of A, and #
# remove from A-pass1 all the dependencies leading to B through a chain, #
# to obtain: #
# A---b--->X...Y---b--->B---b--->A-pass1 #
# It may then happen that nothing depends on A. So this is tested, and A #
# is added to the root node if it is orphaned. #
# TODO: document the third pass #
# TODO: needs also to document the .tree files #
# TODO: The following is obsolete #
# Circular dependencies: #
# #
# In case we find a cirdular dependency, it has the form : #
# parent->dependency_0->...->dependency_n->dependency_0 #
# If we want to build dependency_n before dependency_0, no problem: #
# we just prune the tree at dependency_n. If we want to build first #
# dependency_0, we need to put dependency_n as a dependency of parent, #
# then erase and rebuild the subtree from there. Now, we may have met #
# another circular dependency in the subtree, and erasing the tree makes #
# us forget the decision which was made. So, after first generating the #
# list of dependencies from packages.xml, we keep the generated list in #
# a file <nodeName>.odep, which we modify according to the decision which #
# was made. #
#---------------------------------------------------------------------------#
# Global variables:
# A string of spaces for indenting:
declare -a spaceSTR=" "
# When we are backing up from a circular dependency, `parentNode'
# contains the node which has an edge entering the cycle
declare parentNode
#---------------------#
generate_subgraph() { #
#---------------------#
: <<inline_doc
function: Create a subgraph of all the nodes reachable from the node
represented by the file whose name is $1. The edges considered
are those with maximal weight DEP_LEVEL (recursive function).
input vars: $1 : file name corresponding to the node whose edges will be
followed for the DFS
$2 : weight of the edge leading to this node
$3 : depth (root is 1)
$4 : qualifier (a for after, b for before, f for first)
externals: vars: DEP_LEVEL contains 1 if we want to build the
tree only for required dependencies,
2 if we want also recommended ones,
3 if we want also optional ones, but only
for the requested packages,
4 if we want all the dependencies
(excluding external of course)
MAIL_SERVER contains the name of the MTA we want to use.
files: ../xsl/dependencies.xsl: stylesheet for creating the
.dep files
../packages.xml: File containing packages id
and dependencies
returns: 0 if the tree has been successfully created
output: files: for each node reachable from $1, a file <node>.dep.
on error: nothing
on success: nothing
inline_doc
local depFile=$1
local -i weight=$2
local -i depth=$3
local qualifier=$4
local -i spacing=0
local priostring
local buildstring
local id_of_dep
local prio_of_dep
local build_of_dep
local dep_level
if (( depth < 10 )); then spacing=1; fi
case $weight in
1) priostring=required ;;
2) priostring=recommended ;;
3) priostring=optional ;;
esac
case $qualifier in
a) buildstring=runtime ;;
b|f) buildstring= ;;
esac
dep_level=$DEP_LEVEL
if [ "$dep_level" = 3 ] && [ "$depth" -gt 2 ]; then dep_level=2; fi
if [ "$dep_level" -gt 3 ]; then dep_level=3; fi
echo -en "\nNode: $depth${spaceSTR:0:$(( depth + spacing ))}${RED}${depFile%.dep}${OFF} $priostring $buildstring"
depth=$(( depth + 1 ))
if (( depth < 10 )); then spacing=1; else spacing=0; fi
# Start of loop
{
while read prio_of_dep build_of_dep id_of_dep; do
case $prio_of_dep in
1) priostring=required ;;
2) priostring=recommended ;;
3) priostring=optional ;;
4) priostring=external ;;
esac
case $build_of_dep in
a ) buildstring=runtime ;;
b|f) buildstring= ;;
esac
# Has this entry already been seen?
# TODO: no there is no special case!
# We have a special case here: if the entry has been seen at depth > 2
# and now depth=2 and DEP_LEVEL=3, optional deps have not been processed.
# If this is the case, just consider it has not been seen.
if [ -f ${id_of_dep}.dep ] ; then
case $depth$DEP_LEVEL in
23) ;;
*)
# Just display it and proceed.
echo -en "\nEdge: $depth${spaceSTR:0:$((depth + spacing))}${MAGENTA}${id_of_dep}${OFF} $priostring $buildstring"
continue
;;
esac
fi
# Is the weight higher than requested?
if [ "$prio_of_dep" -gt $dep_level ]; then
# Just display it and proceed.
echo -en "\n Out: $depth${spaceSTR:0:$((depth + spacing))}${YELLOW}${id_of_dep}${OFF} $priostring $buildstring"
continue
fi
# Otherwise, let's build the corresponding subgraph.
xsltproc --stringparam idofdep "$id_of_dep" \
--stringparam MTA "$MAIL_SERVER" \
-o ${id_of_dep}.dep \
../xsl/dependencies.xsl ../packages.xml
if [[ -s ${id_of_dep}.dep ]]; then # this dependency has dependencies
generate_subgraph ${id_of_dep}.dep $prio_of_dep $depth $build_of_dep
else # id_of_dep has no dependencies, just touch the file and display
touch ${id_of_dep}.dep
echo -en "\nLeaf: $depth${spaceSTR:0:$((depth + spacing))}${CYAN}${id_of_dep}${OFF} $priostring $buildstring"
fi
done
} <$depFile
depth=$(( depth - 1 ))
if (( depth < 10 )); then spacing=1; else spacing=0; fi
echo -en "\n End: $depth${spaceSTR:0:$((depth + spacing))}${GREEN}${depFile%.dep}${OFF}"
return 0
}
#-----------#
path_to() { #
#-----------#
: <<inline_doc
function: check whether there is a path from $1 to $2 on the graph
input vars: $1 contains the filename of the starting node.
$2 contains the name of the node to reach
$3 contains the weight above which we do not want to
follow an edge
$seen (global) contains the list of already seen nodes.
It must ve set to " " prior to calling the function
returns: 0 if the node has been found
1 if not
on error: nothing
on success: nothing
inline_doc
local start=$1
local seek=$2
local prio=$3
local prio_of_dep
local build_of_dep
local id_of_dep
local r
if test "${start%.dep}" = "$seek"; then return 0; fi
seen="$seen${start%.dep} "
if test -s $start; then
{
while read prio_of_dep build_of_dep id_of_dep; do
if test "$prio" -lt "$prio_of_dep"; then continue; fi
if ! test "${seen% $id_of_dep *}" = "$seen"; then continue; fi
if path_to ${id_of_dep}.dep $seek $prio; then return 0; fi
done
} < $start
fi
return 1
}
#------------------#
clean_subgraph() { #
#------------------#
: <<inline_doc
function: Remove dangling edges and create groups of deps for "after"
deps: A-before->B-after->C becomes:
A -before-> Bgroupxx -before-> B
\
-before-> C
the name of the group is chosen so that it is unlikely as
a package name (so that it is removed when building the
xml book).
Also change the "first" qualifier so that a cycle:
A -first-> B ---chain---> A becomes:
B ---chain---> A -before-> B-pass1
and we remove all the dependencies which have a chain to
A in B-pass1.
Since we do not change anything else, it may happen that
nothing depends on B. In that case, B is appended to root.
input vars: None
files: <node>.dep files containing dangling edges and
"after" qualifiers
returns: 0
output: files: <node>.dep files containing no dangling edges and
no "after" qualifiers
on error: nothing
on success: nothing
inline_doc
local node
local id_of_dep
local prio_of_dep
local build_of_dep
local lines_to_remove
local lines_to_change
local parent
local p
local b
local start
local seen
for node in $(ls *.dep); do
if test $node = root.dep; then continue; fi
echo Cleaning $node
lines_to_remove=
{
while read prio_of_dep build_of_dep id_of_dep; do
if ! test -f ${id_of_dep}.dep; then
lines_to_remove="$lines_to_remove $id_of_dep"
continue
fi
done
} <$node
for id_of_dep in $lines_to_remove; do
sed "/\ $id_of_dep\$/d" -i $node
done
done
for node in $(grep -l ' a ' *.dep); do
lines_to_remove=
echo Process "runtime" deps in $node
if ! [ -e ${node%.dep}groupxx.dep ]; then
b=0 # Nothing depends on <node>groupxx
for parent in $(grep -l ${node%.dep}\$ *); do
p=0 # No "after" dependency depends on this parent
for start in $(grep ' a ' $node | cut -d' ' -f3); do
seen=" " # global variable used in "path_to"
if path_to ${start}.dep ${parent%.dep} 3; then p=1; break; fi
done
if test $p = 0; then
b=1
sed -i "s/\ ${node%.dep}\$/&groupxx/" $parent
fi
done
echo "1 b ${node%.dep}" > ${node%.dep}groupxx.dep
if test $b = 0; then echo "1 b ${node%.dep}groupxx" >> root.dep; fi
fi
{
while read prio_of_dep build_of_dep id_of_dep; do
if test $build_of_dep = a; then
if ! grep -q ${id_of_dep} ${node%.dep}groupxx.dep; then
echo "$prio_of_dep b ${id_of_dep}" >> ${node%.dep}groupxx.dep
fi
lines_to_remove="$lines_to_remove $id_of_dep"
fi
done
} <$node
for id_of_dep in $lines_to_remove; do
sed "/a\ $id_of_dep\$/d" -i $node
done
done
for node in $(grep -l ' f ' *); do
echo Process "first" deps in $node
lines_to_change=
{
while read prio_of_dep build_of_dep id_of_dep; do
if test $build_of_dep = f; then
if ! test -f ${id_of_dep}-pass1.dep; then
cp ${id_of_dep}{,-pass1}.dep;
fi
lines_to_change="$lines_to_change $id_of_dep"
unset lr # lines to remove in -pass1
{
while read p b start; do
seen=" " # global variable used in "path_to"
if path_to ${start}.dep ${node%.dep} $p; then
lr="$lr $start"
fi
done
} < ${id_of_dep}-pass1.dep
for p in $lr; do
sed "/\ $p\$/d" -i ${id_of_dep}-pass1.dep
done
fi
done
} <$node
for id_of_dep in $lines_to_change; do
sed "/\ $id_of_dep\$/"'{s/[[:digit:]] f /1 b /;s/$/-pass1/}' -i $node
if ! grep -q " $id_of_dep\$" *.dep; then
echo 1 b $id_of_dep >>root.dep
fi
done
done
} # End clean_subgraph
#----------------------------#
generate_dependency_tree() { #
#----------------------------#
: <<inline_doc
function: Create a subtree of the dependency tree
(recursive function)
input vars: $1 : file with a list of targets (child nodes)
the first line of the file is the link
$2 : priority (1=req, 2=rec, 3=opt)
returns: 0 if the tree has been successfully created
1 if we are backing up to the parent of a circular dep
and there are only required deps in the cycle
2 if we are backing up to the parent of a circular dep
and there are recommended deps and no optional deps in the
cycle
3 if we are backing up to the parent of a circular dep
and there are optiional deps in the cycle
modifies: vars: ParentNode is set when return is not 0
output: files: for each <pkg> with dependencies in $1,
a file <pkg>.tree and its dependencies
on error: nothing
on success: nothing
inline_doc
local depFile=$1
local priority=$2
local -a rootlink
local -a priolink
local -a otherlink
local -i depth
local -i count=0
local id_of_dep
local build_of_dep
local prio_of_dep
local parent
local lines_to_remove=
local srootlink
local priostring
local dpriostring
local i
{
read -a rootlink
depth=${#rootlink[*]}
read -a priolink
srootlink="${rootlink[*]} "
case $priority in
1) priostring=required ;;
2) priostring=recommended ;;
3) priostring=optional ;;
esac
# start of depFile
echo -en "\nNode: $depth${spaceSTR:0:$depth}${RED}${depFile%.tree}${OFF} $priostring"
while read prio_of_dep build_of_dep id_of_dep; do
case $prio_of_dep in
1) dpriostring=required ;;
2) dpriostring=recommended ;;
3) dpriostring=optional ;;
esac
# count entries in file
(( count++ ))
# Has this entry already been seen?
if [ -f ${id_of_dep}.tree ]; then # found ${id_of_dep}.tree already in tree
otherlink=($(head -n 1 ${id_of_dep}.tree))
2018-01-13 10:08:56 +01:00
if [ -z "${otherlink[*]}" ]
then echo otherlink empty for $id_of_dep.tree
echo This should not happen, but happens to happen...
exit 1
fi
#Do not use "${rootlink[*]}" =~ "${otherlink[*]}": case rootlink=(1 11)
# and otherlink=(1 1)
if [[ ${srootlink#"${otherlink[*]} "} != ${srootlink} ]]; then # cir. dep
echo -en "\nCirc: $((depth+1))${spaceSTR:0:$((depth+1))}${YELLOW}${id_of_dep}${OFF} $dpriostring"
# Find lowest priority in branch from parent to depFile:
p2=0
for (( i=${#otherlink[*]}; i < $depth ; i++ )) ; do
if (( ${priolink[i]} > $p2 )); then p2=${priolink[i]}; fi
done
if (( $prio_of_dep >= $p2 )); then # prune
lines_to_remove="$lines_to_remove $id_of_dep"
sed -i "/$id_of_dep/d" ${depFile/.tree/.dep}
else # find and set parent, then return lowest priority
# The parent has the same link without the last entry.
# We do not need otherlink anymore so just destroy the last element
unset otherlink[-1]
parentNode=$(grep ^"${otherlink[*]}"\$ -l *)
return $p2
fi
else # not circular: prune tree (but not .dep, since it may happen that
# the tree is destroyed and rebuilt in another order)
lines_to_remove="$lines_to_remove $id_of_dep"
fi # circular or not
continue # this dependency has already been seen, and the associated
# subtree computed. We are done
fi # Has this entry already been seen?
# So, this entry has not already been seen. Let's build the corresponding
# subtree. First check there is a subtree...
# Use -s, because it may happen that after removing lines, .dep exists
# but is empty.
if [[ -s ${id_of_dep}.dep ]]; then # this dependency has dependencies
sed "1i${rootlink[*]} $count\\
${priolink[*]} $prio_of_dep" < ${id_of_dep}.dep \
> ${id_of_dep}.tree # add link and priolink
generate_dependency_tree ${id_of_dep}.tree $prio_of_dep
# Test return value, in case we exchange dependencies
p2=$?
case $p2 in
0) # Normal return
;;
$prio_of_dep) # we remove this dep, but since it may become unreachable,
# move it to be built later (as a dep of parent).
tree_erase ${id_of_dep}.tree
lines_to_remove="$lines_to_remove $id_of_dep"
sed -i "/${id_of_dep}/d" ${depFile/.tree/.dep}
echo "$prio_of_dep b $id_of_dep" >> $parentNode
# must be added to .dep in case parentNode is destroyed when erasing
# the tree
echo "$prio_of_dep b $id_of_dep" >> ${parentNode/.tree/.dep}
continue
;;
*) # We are backing up
return $p2
;;
esac
else # id_of_dep has no dependencies, just record the link in a file
# and print
echo "${rootlink[*]} $count" > ${id_of_dep}.tree
echo -en "\nLeaf: $(($depth+1))${spaceSTR:0:$(($depth+1))}${CYAN}${id_of_dep}${OFF} $dpriostring"
fi
done
echo -en "\n End: $depth${spaceSTR:0:$depth}${GREEN}${depFile%.tree}${OFF}"
} <$depFile
# It may happen that a file is created with several times
# the same line. Normally, all those lines but one
# would be flagged to be removed (or all of them if
# the dependency appeared before). A simple sed /$line/d
# destroys all the lines. We should instead remove
# only one for each appearance of it in lines_to_remove.
# so first get the position of last line and then delete
# that line
for line in $lines_to_remove
do lineno=$(sed -n /^[[:digit:]]\ b\ $line\$/= $depFile | tail -n1)
sed -i ${lineno}d $depFile
done
return 0
}
#---------------#
tree_browse() { #
#---------------#
local file=$1
local f
#echo file=$file
for f in $(grep '[^0-9 ]' $file | sed 's/.* //'); do
# echo f=$f
if grep -q '[^0-9 ]' ${f}.tree ; then
tree_browse ${f}.tree
fi
echo $f
done
}
#--------------#
tree_erase() { #
#--------------#
local file=$1
local f
local rootlink
local rootlink2
#echo file=$file
rootlink="$(head -n1 $file) "
for f in $(grep '[^0-9 ]' $file | sed 's/.* //'); do
if [ -f ${f}.tree ]; then
rootlink2="$(head -n1 ${f}.tree) "
# We want two things:
# i) do not erase the file if it is in another branch
# ii) do not erase the file if there is a circular dependency
# for case i), we test that rootlink is contained in rootlink2
# for case ii), we test that rootlink2 is not contained in
# rootlink.
# See comment above about srootlink
if [[ ${rootlink2#${rootlink}} != ${rootlink2} &&
${rootlink#${rootlink2}} == ${rootlink} ]] ; then
tree_erase ${f}.tree
fi
fi
done
rm -f $file
}