# Copyright 2003 Dave Abrahams
# Copyright 2002, 2003 Rene Rivera
# Copyright 2002, 2003, 2004 Vladimir Prus
# Distributed under the Boost Software License, Version 1.0.
# (See accompanying file LICENSE_1_0.txt or http://www.boost.org/LICENSE_1_0.txt)
# Various container classes.
# Base for container objects. This lets us construct recursive structures. That
# is containers with containers in them, specifically so we can tell literal
# values from node values.
#
class node
{
rule __init__ (
value ? # Optional value to set node to initially.
)
{
self.value = $(value) ;
}
# Set the value of this node, passing nothing will clear it.
#
rule set ( value * )
{
self.value = $(value) ;
}
# Get the value of this node.
#
rule get ( )
{
return $(self.value) ;
}
}
# A simple vector. Interface mimics the C++ std::vector and std::list, with the
# exception that indices are one (1) based to follow Jam standard.
#
# TODO: Possibly add assertion checks.
#
class vector : node
{
import numbers ;
import utility ;
import sequence ;
rule __init__ (
values * # Initial contents of vector.
)
{
node.__init__ ;
self.value = $(values) ;
}
# Get the value of the first element.
#
rule front ( )
{
return $(self.value[1]) ;
}
# Get the value of the last element.
#
rule back ( )
{
return $(self.value[-1]) ;
}
# Get the value of the element at the given index, one based. Access to
# elements of recursive structures is supported directly. Specifying
# additional index values recursively accesses the elements as containers.
# For example: [ $(v).at 1 : 2 ] would retrieve the second element of our
# first element, assuming the first element is a container.
#
rule at (
index # The element index, one based.
: * # Additional indices to access recursively.
)
{
local r = $(self.value[$(index)]) ;
if $(2)
{
r = [ $(r).at $(2) : $(3) : $(4) : $(5) : $(6) : $(7) : $(8) : $(9) ] ;
}
return $(r) ;
}
# Get the value contained in the given element. This has the same
# functionality and interface as "at" but in addition gets the value of the
# referenced element, assuming it is a "node".
#
rule get-at (
index # The element index, one based.
: * # Additional indices to access recursively.
)
{
local r = $(self.value[$(index)]) ;
if $(2)
{
r = [ $(r).at $(2) : $(3) : $(4) : $(5) : $(6) : $(7) : $(8) : $(9) ] ;
}
return [ $(r).get ] ;
}
# Insert the given value into the front of the vector pushing the rest of
# the elements back.
#
rule push-front (
value # Value to become first element.
)
{
self.value = $(value) $(self.value) ;
}
# Remove the front element from the vector. Does not return the value. No
# effect if vector is empty.
#
rule pop-front ( )
{
self.value = $(self.value[2-]) ;
}
# Add the given value at the end of the vector.
#
rule push-back (
value # Value to become back element.
)
{
self.value += $(value) ;
}
# Remove the back element from the vector. Does not return the value. No
# effect if vector is empty.
#
rule pop-back ( )
{
self.value = $(self.value[1--2]) ;
}
# Insert the given value at the given index, one based. The values at and to
# the right of the index are pushed back to make room for the new value.
# If the index is passed the end of the vector the element is added to the
# end.
#
rule insert (
index # The index to insert at, one based.
: value # The value to insert.
)
{
local left = $(self.value[1-$(index)]) ;
local right = $(self.value[$(index)-]) ;
if $(right)-is-not-empty
{
left = $(left[1--2]) ;
}
self.value = $(left) $(value) $(right) ;
}
# Remove one or more elements from the vector. The range is inclusive, and
# not specifying an end is equivalent to the [start, start] range.
#
rule erase (
start # Index of first element to remove.
end ? # Optional, index of last element to remove.
)
{
end ?= $(start) ;
local left = $(self.value[1-$(start)]) ;
left = $(left[1--2]) ;
local right = $(self.value[$(end)-]) ;
right = $(right[2-]) ;
self.value = $(left) $(right) ;
}
# Remove all elements from the vector.
#
rule clear ( )
{
self.value = ;
}
# The number of elements in the vector.
#
rule size ( )
{
return [ sequence.length $(self.value) ] ;
}
# Returns "true" if there are NO elements in the vector, empty otherwise.
#
rule empty ( )
{
if ! $(self.value)-is-not-empty
{
return true ;
}
}
# Returns the textual representation of content.
#
rule str ( )
{
return "[" [ sequence.transform utility.str : $(self.value) ] "]" ;
}
# Sorts the vector inplace, calling 'utility.less' for comparisons.
#
rule sort ( )
{
self.value = [ sequence.insertion-sort $(self.value) : utility.less ] ;
}
# Returns true if content is equal to the content of other vector. Uses
# 'utility.equal' for comparison.
#
rule equal ( another )
{
local mismatch ;
local size = [ size ] ;
if $(size) = [ $(another).size ]
{
for local i in [ numbers.range 1 $(size) ]
{
if ! [ utility.equal [ at $(i) ] [ $(another).at $(i) ] ]
{
mismatch = true ;
}
}
}
else
{
mismatch = true ;
}
if ! $(mismatch)
{
return true ;
}
}
}
rule __test__ ( )
{
import assert ;
import "class" : new ;
local v1 = [ new vector ] ;
assert.true $(v1).equal $(v1) ;
assert.true $(v1).empty ;
assert.result 0 : $(v1).size ;
assert.result "[" "]" : $(v1).str ;
$(v1).push-back b ;
$(v1).push-front a ;
assert.result "[" a b "]" : $(v1).str ;
assert.result a : $(v1).front ;
assert.result b : $(v1).back ;
$(v1).insert 2 : d ;
$(v1).insert 2 : c ;
$(v1).insert 4 : f ;
$(v1).insert 4 : e ;
$(v1).pop-back ;
assert.result 5 : $(v1).size ;
assert.result d : $(v1).at 3 ;
$(v1).pop-front ;
assert.result c : $(v1).front ;
assert.false $(v1).empty ;
$(v1).erase 3 4 ;
assert.result 2 : $(v1).size ;
local v2 = [ new vector q w e r t y ] ;
assert.result 6 : $(v2).size ;
$(v1).push-back $(v2) ;
assert.result 3 : $(v1).size ;
local v2-alias = [ $(v1).back ] ;
assert.result e : $(v2-alias).at 3 ;
$(v1).clear ;
assert.true $(v1).empty ;
assert.false $(v2-alias).empty ;
$(v2).pop-back ;
assert.result t : $(v2-alias).back ;
local v3 = [ new vector ] ;
$(v3).push-back [ new vector 1 2 3 4 5 ] ;
$(v3).push-back [ new vector a b c ] ;
assert.result "[" "[" 1 2 3 4 5 "]" "[" a b c "]" "]" : $(v3).str ;
$(v3).push-back [ new vector [ new vector x y z ] [ new vector 7 8 9 ] ] ;
assert.result 1 : $(v3).at 1 : 1 ;
assert.result b : $(v3).at 2 : 2 ;
assert.result a b c : $(v3).get-at 2 ;
assert.result 7 8 9 : $(v3).get-at 3 : 2 ;
local v4 = [ new vector 4 3 6 ] ;
$(v4).sort ;
assert.result 3 4 6 : $(v4).get ;
assert.false $(v4).equal $(v3) ;
local v5 = [ new vector 3 4 6 ] ;
assert.true $(v4).equal $(v5) ;
# Check that vectors of different sizes are considered non-equal.
$(v5).pop-back ;
assert.false $(v4).equal $(v5) ;
local v6 = [ new vector [ new vector 1 2 3 ] ] ;
assert.true $(v6).equal [ new vector [ new vector 1 2 3 ] ] ;
local v7 = [ new vector 111 222 333 ] ;
assert.true $(v7).equal $(v7) ;
$(v7).insert 4 : 444 ;
assert.result 111 222 333 444 : $(v7).get ;
$(v7).insert 999 : xxx ;
assert.result 111 222 333 444 xxx : $(v7).get ;
local v8 = [ new vector "" "" "" ] ;
assert.true $(v8).equal $(v8) ;
assert.false $(v8).empty ;
assert.result 3 : $(v8).size ;
assert.result "" : $(v8).at 1 ;
assert.result "" : $(v8).at 2 ;
assert.result "" : $(v8).at 3 ;
assert.result : $(v8).at 4 ;
$(v8).insert 2 : 222 ;
assert.result 4 : $(v8).size ;
assert.result "" 222 "" "" : $(v8).get ;
$(v8).insert 999 : "" ;
assert.result 5 : $(v8).size ;
assert.result "" 222 "" "" "" : $(v8).get ;
$(v8).insert 999 : xxx ;
assert.result 6 : $(v8).size ;
assert.result "" 222 "" "" "" xxx : $(v8).get ;
# Regression test for a bug causing vector.equal to compare only the first
# and the last element in the given vectors.
local v9 = [ new vector 111 xxx 222 ] ;
local v10 = [ new vector 111 yyy 222 ] ;
assert.false $(v9).equal $(v10) ;
}