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#!/usr/bin/env nomsu -V4.8.8.6
#
This file contains code that supports manipulating and using collections like lists
and dictionaries.
use "core/metaprogramming.nom"
use "core/control_flow.nom"
use "core/operators.nom"
# List functionality:
test:
%list = [1, 2, 3, 4, 5]
%visited = {}
for %i = %x in %list:
%visited.%i = (yes)
assume (%visited == {1:yes, 2:yes, 3:yes, 4:yes, 5:yes})
%visited = {}
for %x in %list:
%visited.%x = (yes)
assume (%visited == {1:yes, 2:yes, 3:yes, 4:yes, 5:yes})
assume ((%list::2 nd to last) == 4)
assume ((%list::first) == 1)
assume (%list::has 3)
assume ((%list::index of 3) == 3)
assume ((size of %list) == 5)
%list::add 6
assume ((%list::last) == 6)
%list::pop
assume ((%list::last) == 5)
%list::remove index 1
assume ((%list::first) == 2)
assume (([1, 2] + [3, 4]) == [1, 2, 3, 4])
# Dict functionality
test:
%dict = {x:1, y:2, z:3}
assume ((size of %dict) == 3)
assume ((% for % in {x:1}) == [{key:"x", value:1}])
assume (({key:%k, value:%v} for %k = %v in {x:1}) == [{key:"x", value:1}])
assume (({x:1, y:1} + {y:10, z:10}) == {x:1, y:11, z:10})
assume (({x:1, y:1} | {y:10, z:10}) == {x:1, y:1, z:10})
assume (({x:1, y:1} & {y:10, z:10}) == {y:1})
assume (({x:1, y:1} ~ {y:10, z:10}) == {x:1, z:10})
# List Comprehension
test:
assume (((% * %) for % in [1, 2, 3]) == [1, 4, 9])
parse [%expression for %item in %iterable] as (..)
result of:
%comprehension = []
for %item in %iterable:
%comprehension::add %expression
return %comprehension
parse [..]
%expression for %index in %start to %stop via %step
%expression for %index in %start to %stop by %step
..as (..)
result of:
%comprehension = []
for %index in %start to %stop via %step:
%comprehension::add %expression
return %comprehension
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
test:
assume (((% * %) for % in 1 to 3) == [1, 4, 9])
parse [%expression for %var in %start to %stop] as (..)
%expression for %var in %start to %stop via 1
test:
assume (("\%k,\%v" for %k = %v in {x:1}) == ["x,1"])
parse [..]
%expression for %key = %value in %iterable
%expression for %key %value in %iterable
..as (..)
result of:
%comprehension = []
for %key = %value in %iterable:
%comprehension::add %expression
return %comprehension
# Dict comprehensions
test:
assume (((% * %) = % for % in [1, 2, 3]) == {1:1, 4:2, 9:3})
parse [%key = %value for %item in %iterable, %key %value for %item in %iterable] as
..(..)
result of:
%comprehension = {}
for %item in %iterable:
%comprehension.%key = %value
return %comprehension
test:
assume ((%k = (%v * %v) for %k = %v in {x:1, y:2, z:3}) == {x:1, y:4, z:9})
parse [..]
%key = %value for %src_key = %src_value in %iterable
%key %value for %src_key %src_value in %iterable
..as (..)
result of:
%comprehension = {}
for %src_key = %src_value in %iterable:
%comprehension.%key = %value
return %comprehension
parse [..]
%key = %value for %item in %start to %stop via %step
%key %value for %item in %start to %stop via %step
..as (..)
result of:
%comprehension = {}
for %item in %start to %stop via %step:
%comprehension.%key = %value
return %comprehension
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
test:
assume (((% * %) = % for % in 1 to 3) == {1:1, 4:2, 9:3})
parse [..]
%key = %value for %item in %start to %stop
%key %value for %item in %start to %stop
..as (%key = %value for %item in %start to %stop via 1)
test:
assume (([[1, 2], [3, 4]] flattened) == [1, 2, 3, 4])
action [%lists flattened]:
%flat = []
for %list in %lists:
for %item in %list: %flat::add %item
return %flat
test:
assume ((entries in {x:1}) == [{key:"x", value:1}])
parse [entries in %dict] as ({key:%k, value:%v} for %k = %v in %dict)
test:
assume ((keys in {x:1}) == ["x"])
parse [keys in %dict, keys of %dict] as (%k for %k = %v in %dict)
test:
assume ((values in {x:1}) == [1])
parse [values in %dict, values of %dict] as (%v for %k = %v in %dict)
# Metatable stuff
test:
%t = {}
set %t 's metatable to {__tostring:[%] -> "XXX"}
assume ("\%t" == "XXX")
compile [set %dict 's metatable to %metatable] to (..)
Lua "setmetatable(\(%dict as lua expr), \(%metatable as lua expr));"
test:
assume (({} with fallback % -> (% + 1)).10 == 11)
compile [%dict with fallback %key -> %value] to (..)
Lua value "\
..(function(d)
local mt = {}
for k,v in pairs(getmetatable(d) or {}) do mt[k] = v end
mt.__index = function(self, \(%key as lua expr))
local value = \(%value as lua expr)
self[\(%key as lua expr)] = value
return value
end
return setmetatable(d, mt)
end)(\(%dict as lua expr))"
# Sorting
test:
%x = [3, 1, 2]
sort %x
assume (%x == [1, 2, 3])
sort %x by % = (- %)
assume (%x == [3, 2, 1])
%keys = {1:999, 2:0, 3:50}
sort %x by % = %keys.%
assume (%x == [2, 3, 1])
compile [sort %items] to (Lua "table.sort(\(%items as lua expr));")
parse [sort %items by %item = %key_expr, sort %items by %item -> %key_expr] as (..)
do:
%keys = ({} with fallback %item -> %key_expr)
lua> "table.sort(\%items, function(x,y) return \%keys[x] < \%keys[y] end)"
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
test:
assume ((sorted [3, 1, 2]) == [1, 2, 3])
action [%items sorted, sorted %items]:
%copy = (% for % in %items)
sort %copy
return %copy
parse [%items sorted by %item = %key, %items sorted by %item -> %key] as (..)
result of:
%copy = (% for % in %items)
sort %copy by %item = %key
return %copy
test:
assume ((unique [1, 2, 1, 3, 2, 3]) == [1, 2, 3])
action [unique %items]:
%unique = []
%seen = {}
for % in %items:
unless %seen.%:
%unique::add %
%seen.% = (yes)
return %unique
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