--- Operations on two-dimensional arrays.
-- See @{02-arrays.md.Operations_on_two_dimensional_tables|The Guide}
--
-- The size of the arrays is determined by using the length operator `#` hence
-- the module is not `nil` safe, and the usual precautions apply.
--
-- Note: all functions taking `i1,j1,i2,j2` as arguments will normalize the
-- arguments using `default_range`.
--
-- Dependencies: `pl.utils`, `pl.tablex`, `pl.types`
-- @module pl.array2d
local tonumber,tostring,io,ipairs,string,table =
_G.tonumber,_G.tostring,_G.io,_G.ipairs,_G.string,_G.table
local setmetatable,getmetatable = setmetatable,getmetatable
local tablex = require 'pl.tablex'
local utils = require 'pl.utils'
local types = require 'pl.types'
local imap,tmap,reduce,keys,tmap2,tset,index_by = tablex.imap,tablex.map,tablex.reduce,tablex.keys,tablex.map2,tablex.set,tablex.index_by
local remove = table.remove
local splitv,fprintf,assert_arg = utils.splitv,utils.fprintf,utils.assert_arg
local byte = string.byte
local stdout = io.stdout
local min = math.min
local array2d = {}
local function obj (int,out)
local mt = getmetatable(int)
if mt then
setmetatable(out,mt)
end
return out
end
local function makelist (res)
return setmetatable(res, require('pl.List'))
end
--- return the row and column size.
-- Size is calculated using the Lua length operator #, so usual precautions
-- regarding `nil` values apply.
-- @array2d a a 2d array
-- @treturn int number of rows (`#a`)
-- @treturn int number of cols (`#a[1]`)
function array2d.size (a)
assert_arg(1,a,'table')
return #a,#a[1]
end
do
local function index (t,k)
return t[k]
end
--- extract a column from the 2D array.
-- @array2d a 2d array
-- @param j column index
-- @return 1d array
function array2d.column (a,j)
assert_arg(1,a,'table')
return makelist(imap(index,a,j))
end
end
local column = array2d.column
--- extract a row from the 2D array.
-- Added in line with `column`, for read-only purposes directly
-- accessing a[i] is more performant.
-- @array2d a 2d array
-- @param i row index
-- @return 1d array (copy of the row)
function array2d.row(a,i)
assert_arg(1,a,'table')
local row = a[i]
local r = {}
for n,v in ipairs(row) do
r[n] = v
end
return makelist(r)
end
--- map a function over a 2D array
-- @func f a function of at least one argument
-- @array2d a 2d array
-- @param arg an optional extra argument to be passed to the function.
-- @return 2d array
function array2d.map (f,a,arg)
assert_arg(2,a,'table')
f = utils.function_arg(1,f)
return obj(a,imap(function(row) return imap(f,row,arg) end, a))
end
--- reduce the rows using a function.
-- @func f a binary function
-- @array2d a 2d array
-- @return 1d array
-- @see pl.tablex.reduce
function array2d.reduce_rows (f,a)
assert_arg(1,a,'table')
return tmap(function(row) return reduce(f,row) end, a)
end
--- reduce the columns using a function.
-- @func f a binary function
-- @array2d a 2d array
-- @return 1d array
-- @see pl.tablex.reduce
function array2d.reduce_cols (f,a)
assert_arg(1,a,'table')
return tmap(function(c) return reduce(f,column(a,c)) end, keys(a[1]))
end
--- reduce a 2D array into a scalar, using two operations.
-- @func opc operation to reduce the final result
-- @func opr operation to reduce the rows
-- @param a 2D array
function array2d.reduce2 (opc,opr,a)
assert_arg(3,a,'table')
local tmp = array2d.reduce_rows(opr,a)
return reduce(opc,tmp)
end
--- map a function over two arrays.
-- They can be both or either 2D arrays
-- @func f function of at least two arguments
-- @int ad order of first array (`1` if `a` is a list/array, `2` if it is a 2d array)
-- @int bd order of second array (`1` if `b` is a list/array, `2` if it is a 2d array)
-- @tab a 1d or 2d array
-- @tab b 1d or 2d array
-- @param arg optional extra argument to pass to function
-- @return 2D array, unless both arrays are 1D
function array2d.map2 (f,ad,bd,a,b,arg)
assert_arg(1,a,'table')
assert_arg(2,b,'table')
f = utils.function_arg(1,f)
if ad == 1 and bd == 2 then
return imap(function(row)
return tmap2(f,a,row,arg)
end, b)
elseif ad == 2 and bd == 1 then
return imap(function(row)
return tmap2(f,row,b,arg)
end, a)
elseif ad == 1 and bd == 1 then
return tmap2(f,a,b)
elseif ad == 2 and bd == 2 then
return tmap2(function(rowa,rowb)
return tmap2(f,rowa,rowb,arg)
end, a,b)
end
end
--- cartesian product of two 1d arrays.
-- @func f a function of 2 arguments
-- @array t1 a 1d table
-- @array t2 a 1d table
-- @return 2d table
-- @usage product('..',{1,2},{'a','b'}) == {{'1a','2a'},{'1b','2b'}}
function array2d.product (f,t1,t2)
f = utils.function_arg(1,f)
assert_arg(2,t1,'table')
assert_arg(3,t2,'table')
local res = {}
for i,v in ipairs(t2) do
res[i] = tmap(f,t1,v)
end
return res
end
--- flatten a 2D array.
-- (this goes over columns first.)
-- @array2d t 2d table
-- @return a 1d table
-- @usage flatten {{1,2},{3,4},{5,6}} == {1,2,3,4,5,6}
function array2d.flatten (t)
local res = {}
local k = 1
local rows, cols = array2d.size(t)
for r = 1, rows do
local row = t[r]
for c = 1, cols do
res[k] = row[c]
k = k + 1
end
end
return makelist(res)
end
--- reshape a 2D array. Reshape the aray by specifying a new nr of rows.
-- @array2d t 2d array
-- @int nrows new number of rows
-- @bool co use column-order (Fortran-style) (default false)
-- @return a new 2d array
function array2d.reshape (t,nrows,co)
local nr,nc = array2d.size(t)
local ncols = nr*nc / nrows
local res = {}
local ir,ic = 1,1
for i = 1,nrows do
local row = {}
for j = 1,ncols do
row[j] = t[ir][ic]
if not co then
ic = ic + 1
if ic > nc then
ir = ir + 1
ic = 1
end
else
ir = ir + 1
if ir > nr then
ic = ic + 1
ir = 1
end
end
end
res[i] = row
end
return obj(t,res)
end
--- transpose a 2D array.
-- @array2d t 2d array
-- @return a new 2d array
function array2d.transpose(t)
assert_arg(1,t,'table')
local _, c = array2d.size(t)
return array2d.reshape(t,c,true)
end
--- swap two rows of an array.
-- @array2d t a 2d array
-- @int i1 a row index
-- @int i2 a row index
-- @return t (same, modified 2d array)
function array2d.swap_rows (t,i1,i2)
assert_arg(1,t,'table')
t[i1],t[i2] = t[i2],t[i1]
return t
end
--- swap two columns of an array.
-- @array2d t a 2d array
-- @int j1 a column index
-- @int j2 a column index
-- @return t (same, modified 2d array)
function array2d.swap_cols (t,j1,j2)
assert_arg(1,t,'table')
for _, row in ipairs(t) do
row[j1],row[j2] = row[j2],row[j1]
end
return t
end
--- extract the specified rows.
-- @array2d t 2d array
-- @tparam {int} ridx a table of row indices
-- @return a new 2d array with the extracted rows
function array2d.extract_rows (t,ridx)
return obj(t,index_by(t,ridx))
end
--- extract the specified columns.
-- @array2d t 2d array
-- @tparam {int} cidx a table of column indices
-- @return a new 2d array with the extracted colums
function array2d.extract_cols (t,cidx)
assert_arg(1,t,'table')
local res = {}
for i = 1,#t do
res[i] = index_by(t[i],cidx)
end
return obj(t,res)
end
--- remove a row from an array.
-- @function array2d.remove_row
-- @array2d t a 2d array
-- @int i a row index
array2d.remove_row = remove
--- remove a column from an array.
-- @array2d t a 2d array
-- @int j a column index
function array2d.remove_col (t,j)
assert_arg(1,t,'table')
for i = 1,#t do
remove(t[i],j)
end
end
do
local function _parse (s)
local r, c = s:match 'R(%d+)C(%d+)'
if r then
r,c = tonumber(r),tonumber(c)
return r,c
end
c,r = s:match '(%a+)(%d+)'
if c then
local cv = 0
for i = 1, #c do
cv = cv * 26 + byte(c:sub(i,i)) - byte 'A' + 1
end
return tonumber(r), cv
end
error('bad cell specifier: '..s)
end
--- parse a spreadsheet range.
-- The range can be specified either as 'A1:B2' or 'R1C1:R2C2';
-- a special case is a single element (e.g 'A1' or 'R1C1')
-- @string s a range (case insensitive).
-- @treturn int start row
-- @treturn int start col
-- @treturn int end row
-- @treturn int end col
function array2d.parse_range (s)
assert_arg(1,s,'string')
s = s:upper()
if s:find ':' then
local start,finish = splitv(s,':')
local i1,j1 = _parse(start)
local i2,j2 = _parse(finish)
return i1,j1,i2,j2
else -- single value
local i,j = _parse(s)
return i,j
end
end
end
--- get a slice of a 2D array using spreadsheet range notation. @see parse_range
-- @array2d t a 2D array
-- @string rstr range expression
-- @return a slice
-- @see array2d.parse_range
-- @see array2d.slice
function array2d.range (t,rstr)
assert_arg(1,t,'table')
return array2d.slice(t,array2d.parse_range(rstr))
end
local default_range do
local function norm_value(v, max)
if not v then return v end
if v < 0 then
v = max + v + 1
end
if v < 1 then v = 1 end
if v > max then v = max end
return v
end
--- normalizes coordinates to valid positive entries and defaults.
-- Negative indices will be counted from the end, too low, or too high
-- will be limited by the array sizes.
-- @array2d t a 2D array
-- @int i1 start row (default 1)
-- @int j1 start col (default 1)
-- @int i2 end row (default N)
-- @int j2 end col (default M)
-- return i1, j1, i2, j2
function array2d.default_range (t,i1,j1,i2,j2)
local nr, nc = array2d.size(t)
i1 = norm_value(i1 or 1, nr)
j1 = norm_value(j1 or 1, nc)
i2 = norm_value(i2 or nr, nr)
j2 = norm_value(j2 or nc, nc)
return i1,j1,i2,j2
end
default_range = array2d.default_range
end
--- get a slice of a 2D array. Note that if the specified range has
-- a 1D result, the rank of the result will be 1.
-- @array2d t a 2D array
-- @int i1 start row (default 1)
-- @int j1 start col (default 1)
-- @int i2 end row (default N)
-- @int j2 end col (default M)
-- @return an array, 2D in general but 1D in special cases.
function array2d.slice (t,i1,j1,i2,j2)
assert_arg(1,t,'table')
i1,j1,i2,j2 = default_range(t,i1,j1,i2,j2)
local res = {}
for i = i1,i2 do
local val
local row = t[i]
if j1 == j2 then
val = row[j1]
else
val = {}
for j = j1,j2 do
val[#val+1] = row[j]
end
end
res[#res+1] = val
end
if i1 == i2 then res = res[1] end
return obj(t,res)
end
--- set a specified range of an array to a value.
-- @array2d t a 2D array
-- @param value the value (may be a function, called as `val(i,j)`)
-- @int i1 start row (default 1)
-- @int j1 start col (default 1)
-- @int i2 end row (default N)
-- @int j2 end col (default M)
-- @see tablex.set
function array2d.set (t,value,i1,j1,i2,j2)
i1,j1,i2,j2 = default_range(t,i1,j1,i2,j2)
local i = i1
if types.is_callable(value) then
local old_f = value
value = function(j)
return old_f(i,j)
end
end
while i <= i2 do
tset(t[i],value,j1,j2)
i = i + 1
end
end
--- write a 2D array to a file.
-- @array2d t a 2D array
-- @param f a file object (default stdout)
-- @string fmt a format string (default is just to use tostring)
-- @int i1 start row (default 1)
-- @int j1 start col (default 1)
-- @int i2 end row (default N)
-- @int j2 end col (default M)
function array2d.write (t,f,fmt,i1,j1,i2,j2)
assert_arg(1,t,'table')
f = f or stdout
local rowop
if fmt then
rowop = function(row,j) fprintf(f,fmt,row[j]) end
else
rowop = function(row,j) f:write(tostring(row[j]),' ') end
end
local function newline()
f:write '\n'
end
array2d.forall(t,rowop,newline,i1,j1,i2,j2)
end
--- perform an operation for all values in a 2D array.
-- @array2d t 2D array
-- @func row_op function to call on each value; `row_op(row,j)`
-- @func end_row_op function to call at end of each row; `end_row_op(i)`
-- @int i1 start row (default 1)
-- @int j1 start col (default 1)
-- @int i2 end row (default N)
-- @int j2 end col (default M)
function array2d.forall (t,row_op,end_row_op,i1,j1,i2,j2)
assert_arg(1,t,'table')
i1,j1,i2,j2 = default_range(t,i1,j1,i2,j2)
for i = i1,i2 do
local row = t[i]
for j = j1,j2 do
row_op(row,j)
end
if end_row_op then end_row_op(i) end
end
end
---- move a block from the destination to the source.
-- @array2d dest a 2D array
-- @int di start row in dest
-- @int dj start col in dest
-- @array2d src a 2D array
-- @int i1 start row (default 1)
-- @int j1 start col (default 1)
-- @int i2 end row (default N)
-- @int j2 end col (default M)
function array2d.move (dest,di,dj,src,i1,j1,i2,j2)
assert_arg(1,dest,'table')
assert_arg(4,src,'table')
i1,j1,i2,j2 = default_range(src,i1,j1,i2,j2)
local nr,nc = array2d.size(dest)
i2, j2 = min(nr,i2), min(nc,j2)
--i1, j1 = max(1,i1), max(1,j1)
dj = dj - 1
for i = i1,i2 do
local drow, srow = dest[i+di-1], src[i]
for j = j1,j2 do
drow[j+dj] = srow[j]
end
end
end
--- iterate over all elements in a 2D array, with optional indices.
-- @array2d a 2D array
-- @bool indices with indices (default false)
-- @int i1 start row (default 1)
-- @int j1 start col (default 1)
-- @int i2 end row (default N)
-- @int j2 end col (default M)
-- @return either `value` or `i,j,value` depending on the value of `indices`
function array2d.iter(a,indices,i1,j1,i2,j2)
assert_arg(1,a,'table')
i1,j1,i2,j2 = default_range(a,i1,j1,i2,j2)
local i,j = i1,j1-1
local row = a[i]
return function()
j = j + 1
if j > j2 then
j = j1
i = i + 1
row = a[i]
if i > i2 then
return nil
end
end
if indices then
return i,j,row[j]
else
return row[j]
end
end
end
--- iterate over all columns.
-- @array2d a a 2D array
-- @return column, column-index
function array2d.columns(a)
assert_arg(1,a,'table')
local n = #a[1]
local i = 0
return function()
i = i + 1
if i > n then return nil end
return column(a,i), i
end
end
--- iterate over all rows.
-- Returns a copy of the row, for read-only purrposes directly iterating
-- is more performant; `ipairs(a)`
-- @array2d a a 2D array
-- @return row, row-index
function array2d.rows(a)
assert_arg(1,a,'table')
local n = #a
local i = 0
return function()
i = i + 1
if i > n then return nil end
return array2d.row(a,i), i
end
end
--- new array of specified dimensions
-- @int rows number of rows
-- @int cols number of cols
-- @param val initial value; if it's a function then use `val(i,j)`
-- @return new 2d array
function array2d.new(rows,cols,val)
local res = {}
local fun = types.is_callable(val)
for i = 1,rows do
local row = {}
if fun then
for j = 1,cols do row[j] = val(i,j) end
else
for j = 1,cols do row[j] = val end
end
res[i] = row
end
return res
end
return array2d