Module:JI ratios: Difference between revisions

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-- This module follows [[User:Ganaram inukshuk/Provisional style guide for Lua]]

local getArgs = require("Module:Arguments").getArgs

local med = require("Module:Mediants")

local rat = require("Module:Rational")

local tip = require("Module:Template input parse")

local utils = require("Module:Utils")

~~local tip = require("Module:Template input parse")~~

~~local med = require("Module:Mediants")~~

local yesno = require("Module:Yesno")

~~local getArgs = require("Module:Arguments").getArgs~~

~~p = {}~~

~~-- TODO~~

local p = {}

~~-- - Transfer control over to new "main" function:~~ p~~.ji_ratios()~~

-- Template for handling multiple entry of JI ratios into a template, and for

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-- This is a successor/replacement for JI ratio finder.

-- ~~JI ratios are searched by the following params in a hierarchy~~:

-- TODO: Refactor code such that:

-- - ~~Search by prime~~ limit~~. Int~~ limit is ~~used to limit~~ the ~~num~~/~~den of ratios.~~

-- - For int-limit search, int limit is the first arg, and equave and min/max

-- ~~Prime limit takes precedence over subgroup~~.

-- cents default to 2/1, 0c, and 1200c respectively.

-- ~~- Search by subgroup.~~ (~~Subgroup may contain nonprime numbers~~, ~~but ratios are~~

-- (int_limit, equave)

-- ~~currently not supported.~~) ~~Int~~ limit is ~~used~~ to limit ~~the num~~/~~den of ratios~~.

-- (int_limit, min_cents, max_cents)

-- - ~~If neither~~ prime limit ~~or subgroup~~ is ~~present~~, ~~search by~~ int limit~~. This~~

-- - For odd-limit search, odd limit is the first arg, int limit defaults to

-- ~~is considered~~ the ~~absolute minimum requirement for ratio searching~~.

-- twice the odd limit, and equave and min/max cents default to 2/1, 0c, and

-- ~~NOTES:~~

-- 1200c respectively.

-- - ~~Prime limits are infinite sets~~, so int limit ~~is used~~ to ~~restrain the set~~

-- (odd_limit, int_limit, equave)

-- to ~~a finite size~~. ~~The same is true for~~ subgroup.

-- (odd_limit, int_limit, min_cents, max_cents)

-- - ~~Tenney height~~ is ~~used for further filtering of~~ ratios~~, and~~ is ~~considered~~

-- - For prime-limit search, prime-limit is the first arg, int limit defaults to

-- ~~optional. If omitted,~~ tenney height ~~defaults to infinity~~.

-- twice the largest prime, and equave and min/max cents default to 2/1, 0c,

-- and 1200c respectively.

~~local DEFAULT_FINE_SEARCH_ARGS = {~~

-- (prime_limit, int_limit, equave)

~~["Int Limit"] = 50,~~

-- (prime_limit, int_limit, min_cents, max_cents)

~~["Tenney Height"] = 1/0,~~

-- - For subgroup search, subgroup is the first arg, there's no default value

~~["Complements Only"] = false~~

-- for int limit (due to complexity of subgroups), and equave and min/max

}

-- cents default to 2/1, 0c, and 1200c respectively.

-- (subgroup, int_limit, equave)

-- (subgroup, int_limit, min_cents, max_cents)

-- - Filter ratios function is split into two:

-- - Filter ratios by complement removes ratios from a table if its complement

-- is missing. Complements are octave-complements by default.

-- - Filter ratios by tenney height removes ratios from a table if its tenney

-- height exceeds a passed-in value.

--~~------------------------------------------------------------------------------~~

-- TODO: write filter function for cent range

~~------------------------------ HELPER FUNCTIONS --------------------------------~~

~~--------------------------------------------------------------------------------~~

-- ~~Does not return anything; entries in source~~ are ~~added to destination.~~

-- Module searches for ratios that are, at the minimum, up to an equave and are

~~function p.merge_ratio_tables_without_duplicates(dest_table~~, ~~source_table)~~

-- up to some integer limit. Search hierarchy is as follows:

~~for i = 1~~, ~~#source_table do~~

-- - Search by subgroup (subgroup elements may be nonprime or rational)

~~if not p~~.~~find_ratio_in_table(dest_table, source_table[i]) then~~

-- - Then search by prime limit

~~table.insert~~(~~dest_table, source_table[i]~~)

-- - Then search by odd limit

~~end~~

-- - Then search by int limit

~~end~~

-- ~~Checks whether a ratio was already in a table~~

-- Optional args omit ratios that don't meet certain conditions, and are used

~~function p.find_ratio_in_table(table_~~, ~~ratio)~~

-- to further limit the number of ratios found. Current options include:

~~local~~ found ~~= false~~

-- - Tenney Height: omits ratios that exceed some max Tenney height. Has no

~~for i = 1, #table_ do~~

-- effect if no Tenney height is passed in.

if ~~rat.as_float(table_[i]) == rat~~.~~as_float(ratio) then~~

-- - Complements Only: omits ratios and their equave complements if either would

~~found = true~~

-- be omitted by Tenney height, or if no Tenney height is entered, omits

~~break~~

-- ratios whose complements are missing.

~~end~~

~~return found~~

~~end~~

~~-- Preprocess fine-search args~~

local DEFAULT_EQUAVE = rat.new(2)

~~function p~~.~~preprocess_fine_search_args~~(~~fine_search_args~~)

local DEFAULT_INT_LIMIT = 30

~~local fine_search_args = fine_search_args or DEFAULT_FINE_SEARCH_ARGS~~

~~local tenney_height = fine_search_args["Tenney Height"] or 1/0~~

~~local comps_only = fine_search_args["Complements Only"] or false~~

local ~~int_limit = fine_search_args["Int Limit"] or~~ DEFAULT_INT_LIMIT

~~return {~~

~~["Tenney Height"]~~ = ~~tenney_height,~~

~~["Complements Only"] = comps_only,~~

~~["Int Limit"] = int_limit~~

}

~~end~~

--------------------------------------------------------------------------------

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--------------------------------------------------------------------------------

-- ~~Remove~~ ratios ~~whose complements~~ exceed ~~the int limit and~~ Tenney height.

-- Filter function removes certain ratios that don't meet some requirement.

-- ~~If filtering based on~~ Tenney height ~~is not needed, then Tenney height is set~~

-- Filters currently include:

~~-- to infinity instead, which should be done by the calling function.~~

-- - Removing ratios that exceed a max Tenney height.

function p.~~filter_ratios_by_complements~~(ratios, equave, ~~fine_search_args~~)

-- - Removing ratios whose complement would exceed a max Tenney height or int limit

~~if fine_search_args["Complements Only"] then~~

function p.filter_ratios(ratios, equave, int_limit, tenney_height, complements_only)

local filtered_ratios = {}

for i = 1, #ratios do

local filtered_ratios = {}

local complement = rat.mul(rat.inv(ratios[i]), equave)

for i = 1, #ratios do

if rat.~~int_limit~~(~~complement~~) <= ~~fine_search_args["Int Limit"] and~~ rat.tenney_height(complement) <= ~~fine_search_args~~[~~"Tenney Height"~~] then

local complement = rat.mul(rat.inv(ratios[i]), equave)

local ratio_th = rat.tenney_height(ratios[i])

local compl_th = rat.tenney_height(complement)

-- Are the ratios within the Tenney height?

-- Has no effect (defaults to TRUE) if Tenney height is infinity.

local ratio_within_th = ratio_th <= tenney_height

local compl_within_th = compl_th <= tenney_height

-- Is the ratio's complement within the int limit?

local compl_within_int_limit = rat.is_within_int_limit(complement, int_limit)

if complements_only then

if ratio_within_th and compl_within_th and compl_within_int_limit then

table.insert(filtered_ratios, ratios[i])

end

else

if ratio_within_th then

table.insert(filtered_ratios, ratios[i])

end

~~return filtered_ratios~~

~~else~~

~~return ratios~~

end

return filtered_ratios

end

-- ~~Remove~~ ratios ~~that exceed~~ the ~~Tenney height~~. ~~This does nothing if the Tenney~~

-- Filters ratios from a table of ratios, returning an array of ratios within

-- ~~height is infinity~~.

-- the cent range and preserving the original table. Meant for searching for

function p.~~filter_ratios_by_tenney_height~~(ratios, ~~equave, fine_search_args)~~

-- multiple ranges. TODO: write

~~local filtered_ratios = {}~~

function p.filter_ratios_within_cent_range(ratios, min_cents, max_cents)

~~for i = 1, #ratios do~~

~~if rat.tenney_height(ratios[i]) <= fine_search_args["Tenney Height"] then~~

~~table.insert(filtered_ratios~~, ~~ratios[i]~~)

~~end~~

~~return filtered_ratios~~

end

--------------------------------------------------------------------------------

----------------------- INT-LIMIT~~-BASED~~ SEARCH FUNCTION ------------------------

-------------------------- INT-LIMIT SEARCH FUNCTION ---------------------------

--------------------------------------------------------------------------------

-- Int-limit~~-based~~ search; finds ratios ~~between~~ 1/1 ~~and~~ an equave, ~~within an int~~

-- Int limit search finds ratios from 1/1 to an equave, where each ratio's

-- limit.

-- numerator or denominator don't exceed the int limit.

function p.~~search_within_equave~~(equave, ~~fine_search_args~~)

function p.search_by_int_limit(equave, int_limit)

~~local equave = equave or~~ rat.~~new~~(2,1) -- ~~Defualt equave is 2/1~~.

return p.search_by_int_limit_within_cents(0, rat.cents(equave), int_limit)

~~local fine_search_args =~~ p.~~preprocess_fine_search_args~~(~~fine_search_args~~)

end

-- Cent range search finds ratios within a cent range. Meant for searching for

-- ratios within a single interval range. If searching for ratios within many

-- interval ranges, then try a broad search first.

function p.search_by_int_limit_within_cents(min_cents, max_cents, int_limit)

local init_ratios = {{1,1}, {1,0}}

local ratios = med.~~find_only_mediants_by_int_limit~~(init_ratios, ~~fine_search_args~~[~~"Int Limit"~~])

local ratios = med.find_only_mediants(init_ratios, 2)

for i = 3, int_limit do

ratios = med.find_mediants_by_int_limit(ratios, i)

-- Purge ratios from the beginning.

-- If the first and second ratio are smaller than min_cents, and smaller

-- than max_cents, then remove the first ratio. Keeping the first ratio

-- would add mediants outside the cent range.

local cents_1 = utils.log2(ratios[1][1] / ratios[1][2]) * 1200

local cents_2 = utils.log2(ratios[2][1] / ratios[2][2]) * 1200

if cents_1 < min_cents and cents_2 <= min_cents and cents_1 < max_cents and cents_2 < max_cents then

table.remove(ratios, 1)

end

-- Purge ratios from the end.

-- If the 2nd-last ratio and last ratio are greater than max_cents, and

-- larger than min_cents, then remove the last ratio. Keeping the last

-- ratio would add mediants outside the cent range.

local cents_3 = utils.log2(ratios[#ratios-1][1] / ratios[#ratios-1][2]) * 1200

local cents_4 = utils.log2(ratios[#ratios ][1] / ratios[#ratios ][2]) * 1200

if cents_3 > max_cents and cents_4 >= max_cents and cents_3 > min_cents and cents_4 > min_cents then

table.remove(ratios, #ratios)

end

-- Convert to ratios that Module:Rational can work with

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end

-- Remove ratios that ~~exceed~~ the ~~equave~~.

-- Remove any remaining ratios that fall outside the cent range.

~~-- Note that mediant search returns sorted~~ ratios, ~~so remove them from the~~

while rat.cents(ratios[1]) < min_cents do

-- end ~~until there's no more to remove.~~

table.remove(ratios, 1)

while rat.gt(ratios[#ratios]~~, equave~~) do

end

while rat.cents(ratios[#ratios]) > max_cents do

table.remove(ratios, #ratios)

end

~~-- Filter out ratios that exceed the int limit.~~

~~-- Then filter out ratios if their equave complement would be filtered out.~~

~~ratios = p.filter_ratios_by_tenney_height(ratios, equave, fine_search_args)~~

~~ratios = p.filter_ratios_by_complements(ratios, equave, fine_search_args)~~

return ratios

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--------------------------------------------------------------------------------

------------------------ ~~SUBGROUP~~-~~BASED~~ SEARCH FUNCTION ------------------------

-------------------------- ODD-LIMIT SEARCH FUNCTION ---------------------------

--------------------------------------------------------------------------------

function p.~~search_by_prime_limit~~(~~prime_limit, equave, fine_search_args~~)

-- Convert odd limit into equivalent subgroup.

local ~~prime_limit~~ = ~~prime_limit or 5~~

-- EG, 11-odd-limit becomes 2.3.5.7.9.11

~~local equave = equave or~~ rat.new(2,1)

-- 2 is part of the subgroup by definition.

~~local fine_search_args~~ = p.~~preprocess_fine_search_args~~(~~fine_search_args~~)

function p.odd_limit_to_subgroup(odd_limit)

local subgroup = { rat.new(2) }

for i = 3, odd_limit, 2 do

table.insert(subgroup, rat.new(i))

end

return subgroup

end

-- ~~Find all primes up to the~~ prime limit.

function p.search_by_odd_limit(equave, int_limit, odd_limit)

local ~~primes~~ = {}

local subgroup = p.odd_limit_to_subgroup(odd_limit)

for i = 2, prime_limit do

return p.search_by_subgroup_within_cents(0, rat.cents(equave), int_limit, subgroup)

end

function p.search_by_odd_limit_within_cents(min_cents, max_cents, odd_limit)

local subgroup = p.odd_limit_to_subgroup(odd_limit)

return p.search_by_subgroup_within_cents(min_cents, max_cents, int_limit, subgroup)

end

--------------------------------------------------------------------------------

------------------------- PRIME-LIMIT SEARCH FUNCTION --------------------------

--------------------------------------------------------------------------------

-- Convert prime limit into equivalent subgroup.

-- EG, 11-prime-limit becomes 2.3.5.7.11

function p.prime_limit_to_subgroup(prime_limit)

local subgroup = {}

for i = 3, prime_limit do

local is_prime = true

for j = 2, math.floor(math.sqrt(i)) do

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end

if is_prime then

table.insert(~~primes~~, rat.new(i))

table.insert(subgroup, rat.new(i))

end

return subgroup

-- ~~Perform subgroup~~ search on the ~~primes found~~, as subgroup-search ~~code can~~

end

-- ~~be reused for~~ prime-limit ~~search~~.

return p.search_by_subgroup(~~primes~~, equave, ~~fine_search_args~~)

-- Prime limit search finds ratios with prime factors that don't exceed some

-- prime limit.

-- Upper bounds for searching is the equave and int limit.

function p.search_by_prime_limit(equave, int_limit, prime_limit)

local subgroup = p.prime_limit_to_subgroup(prime_limit)

return p.search_by_subgroup_within_cents(0, rat.cents(equave), int_limit, subgroup)

end

-- Prime limit search finds ratios with prime factors that don't exceed some

-- prime limit. Searches within a cent range.

function p.search_by_prime_limit_within_cents(min_cents, max_cents, int_limit, prime_limit)

local subgroup = p.prime_limit_to_subgroup(prime_limit)

local ratios = p.search_by_subgroup_within_cents(min_cents, max_cents, int_limit, subgroup)

while rat.cents(ratios[1]) < min_cents do

table.remove(ratios, 1)

end

return ratios

end

--------------------------------------------------------------------------------

---------------------------- SUBGROUP SEARCH FUNCTION --------------------------

--------------------------------------------------------------------------------

-- Subgroup search find ratios that are products of at least two non-unique

-- elements from the subgroup.

function p.search_by_subgroup(equave, int_limit, subgroup)

local ratios = p.search_by_subgroup_within_cents(0, rat.cents(equave), int_limit, subgroup)

return ratios

end

~~-- WORK-IN-PROGRESS!!~~

function p.search_by_subgroup_within_cents(min_cents, max_cents, int_limit, subgroup)

function p.~~search_by_subgroup~~(subgroup, equave, ~~fine_search_args~~)

--local equave = equave or rat.new(2,1) -- Defualt equave is 2/1.

local subgroup = subgroup or {rat.new(2), rat.new(3), rat.new(7)}

--local int_limit = int_limit or 50 -- Default is 50

~~local equave = equave or rat~~.~~new(2,1)~~

--local subgroup = subgroup or {rat.new(2), rat.new(3), rat.new(7)} -- Default is 2.3.7 subgroup

~~local fine_search_args = p~~.~~preprocess_fine_search_args(fine_search_args)~~

-- ~~Fine~~ search ~~params for ease of access~~

-- Find all possible ways to multiply subgroup elements with one another

local ~~tenney_height~~ = ~~fine_search_args["Tenney Height"]~~

-- using breadth-first-search. Products found this way should not exceed the

local ~~comps_only~~ = ~~fine_search_args["Complements Only"]~~

-- int limit, and if a subgroup element is rational, neither its numerator

local ~~int_limit~~ = ~~fine_search_args~~[~~"Int Limit"~~]

-- nor denominator should exceed the int limit.

local products = { rat.new(1) }

local i = 1

while i <= #products do

-- Multiply each subgroup element by the current ratio. The table of

-- product ratios created this way is merged with the running table of

-- ratios. This is the Cartesian product of the single ratio as a set,

-- with the subgroup elements as a set, or {p/q} X subgroup.

local new_products = {}

for j = 1, #subgroup do

local new_ratio = rat.mul(products[i], subgroup[j])

if rat.is_within_int_limit(new_ratio, int_limit) and not p.find_ratio_in_table(new_products, new_ratio) then

table.insert(new_products, new_ratio)

end

-- Merge new products with the table of products, omitting duplicates.

p.merge_tables(products, new_products)

i = i + 1

end

-- ~~Search~~ for ~~ratios within int limit within subgroup by multiplication.~~

-- Sort for next step

~~local products = p~~.~~multiply_ratios_using_bfs~~(rat.~~new(1), subgroup, int_limit~~)

table.sort(products, rat.lt)

-- Use the products found to find all ratios between 1 and the equave.

-- For each ratio ~~found~~, ~~have it be the denominator and have the numerator~~

-- For each ratio in the table of products, create a set of new ratios by

-- be all successive ratios ~~after it. For each new ratio found this way, add~~

-- having that ratio be the numerator and all successive ratios be possible

-- ~~it to the~~ table ~~of ratios~~, ~~excluding ratios that exceed the equave or int~~

-- denominators. Store these new ratios in a table, and repeat with all

-- ~~limit~~, ~~and excluding duplicates~~. ~~This~~ is ~~way~~ faster than performing BFS

-- successive products, omitting duplicats. From earlier testing, this is

-- on each ratio and yields the same results.

-- faster than performing BFS on each ratio, and yields the same results.

local ratios = {}

for i = 1, #products do

local new_ratios = {}

for j = i, #products do

local ~~ratio~~ = rat.div(products[j], products[i])

local new_ratio = rat.div(products[j], products[i])

if rat.~~as_float~~(~~ratio~~) > ~~rat.as_float(equave)~~ then break end

if rat.cents(new_ratio) > max_cents then break end

if not p.find_ratio_in_table(new_ratios, ~~ratio~~) and rat.int_limit~~(ratio~~) ~~<= int_limit~~ then

if not p.find_ratio_in_table(new_ratios, new_ratio) and rat.is_within_int_limit(new_ratio, int_limit) then

table.insert(new_ratios, ~~ratio~~)

table.insert(new_ratios, new_ratio)

end

p.~~merge_ratio_tables_without_duplicates~~(ratios, new_ratios)

-- Merge new ratios with the table of ratios, omitting duplicates.

p.merge_tables(ratios, new_ratios)

end

-- Sort~~, then filter out ratios that exceed the int limit.~~

-- Sort

~~-- Then filter out ratios if their equave complement would be filtered out.~~

table.sort(ratios, rat.lt)

ratios ~~= p~~.~~filter_ratios_by_tenney_height~~(ratios~~, equave, fine_search_args~~)

~~ratios = p~~.~~filter_ratios_by_complements~~(ratios, ~~equave, fine_search_args~~)

-- Remove ratios less than minimum

while rat.cents(ratios[1]) < min_cents do

table.remove(ratios, 1)

end

return ratios

end

-- ~~Helper~~ function ~~for subgroup search~~; ~~implementation of BFS~~

--------------------------------------------------------------------------------

function p.~~multiply_ratios_using_bfs~~(~~init_ratio, subgroup~~, ~~int_limit~~)

------------------------------- HELPER FUNCTIONS -------------------------------

~~local ratios = { init_ratio }~~

--------------------------------------------------------------------------------

~~local~~ i = 1

~~while i <=~~ #~~ratios~~ do

-- Heleper function; merges elements from source table with destination table

~~local new_ratios =~~ p.~~multiply_ratio_by_subgroup_elements~~(~~ratios~~[i]~~, subgroup, int_limit~~)

-- while disallowing duplicates.

p.~~merge_ratio_tables_without_duplicates~~(~~ratios~~, ~~new_ratios~~)

function p.merge_tables(dest_table, source_table)

~~i = i + 1~~

for i = 1, #source_table do

if not p.find_ratio_in_table(dest_table, source_table[i]) then

table.insert(dest_table, source_table[i])

end

~~table.sort(ratios, rat.lt)~~

~~return ratios~~

end

-- Helper function for ~~BFS search; returns { ratio } X subgroup~~

-- Helper function for merge function.

function p.~~multiply_ratio_by_subgroup_elements~~(ratio~~, subgroup, int_limit~~)

function p.find_ratio_in_table(table_, ratio)

local ~~ratios~~ = {}

local found = false

for i = 1, #~~subgroup~~ do

for i = 1, #table_ do

~~local new_ratio =~~ rat.~~mul~~(~~ratio, subgroup~~[i])

if rat.as_float(table_[i]) == rat.as_float(ratio) then

if rat.~~int_limit~~(~~new_ratio~~) <= ~~int_limit and not p.find_ratio_in_table(ratios, new_ratio) then~~

found = true

~~table.insert(ratios, new_ratio)~~

break

end

return ~~ratios~~

return found

end

--------------------------------------------------------------------------------

--------------------------- ~~REVERSE~~-~~SEARCH~~ FUNCTIONS ---------------------------

---------------------------- RATIO STRING FUNCTIONS ----------------------------

--------------------------------------------------------------------------------

function p.~~int_limit_of_ratios~~(ratios)

-- Convert a table of ratios into a string, with options for links and delimiter

function p.ratios_as_string(ratios, add_links, delimiter)

local add_links = add_links == true

local delimiter = delimiter or ", "

local text = ""

if #ratios ~= 0 then

text = add_links and string.format("[[%s]]", rat.as_ratio(ratios[1])) or rat.as_ratio(ratios[1])

for i = 2, #ratios do

text = text .. (add_links and string.format("%s[[%s]]", delimiter, rat.as_ratio(ratios[i])) or string.format("%s%s", delimiter, rat.as_ratio(ratios[i])))

end

return text

end

function p.~~prime_limit_of_ratios~~(ratios)

-- Convert a jagged array of ratios into an array of strings

function p.ratios_as_strings(ratios, add_links, delimiter)

local add_links = add_links == true

~~end~~

local delimiter = delimiter or ", "

~~function p.subgroup_of_ratios(ratios~~, ~~is_nonprime)~~

local texts = {}

for i = 1, #ratios do

local text = p.ratios_as_string(ratios[i], add_links, delimiter)

table.insert(texts, text)

end

return texts

end

--------------------------------------------------------------------------------

-------------------------- ARG-~~BASED SEARCH FUNCTIONS~~ --------------------------

---------------------------- ARG-PARSING FUNCTION ------------------------------

--------------------------------------------------------------------------------

-- ~~Search for ratios based on an array of~~ args ~~passed in~~. ~~Certain params have~~

-- Parse search args if entered as one string. Use is to be determined.

~~-- their own function calls~~.

function p.parse_args(search_args)

function p.~~search_by_args_within_equave~~(~~equave,~~ search_args)

local parsed = tip.parse_kv_pairs(search_args)

local ~~equave~~ = ~~equave or rat~~.~~new~~(~~2,1~~)

~~-- For each search method, check whether the corresponding search arg and~~

if parsed["Equave"] ~= nil then

~~-- int limit are both present and pass it and the equave to that function.~~

parsed["Equave"] = rat.parse(parsed["Equave"])

~~-- All other search args are used as finer search args.~~

~~-- Note that search by int limit alone just has the equave and search args~~

~~-- passed in.~~

~~local ratios = {}~~

if ~~search_args["Prime Limit"] ~= nil and search_args~~["~~Int Limit~~"] ~= nil then

~~ratios = p.search_by_prime_limit(search_args["Prime Limit"], equave, search_args)~~

~~elseif search_args["Subgroup"] ~= nil and search_args~~["~~Int Limit~~"] ~= ~~nil then~~

~~ratios = p~~.~~search_by_subgroup~~(~~search_args["Subgroup"], equave, search_args)~~

~~elseif search_args~~["~~Int Limit~~"] ~~~= nil then~~

~~ratios = p.search_within_equave(equave, search_args~~)

end

~~return ratios~~

~~end~~

~~-- Parse search args.~~

~~function p.parse_search_args(search_args)~~

~~local parsed = tip.parse_kv_pairs(search_args)~~

if parsed["Int Limit"] ~= nil then

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end

function p.~~search_footnotes~~(~~search_args~~)

--------------------------------------------------------------------------------

local ~~result~~ = ~~"Other interpretations~~ are ~~possible~~."

----------------------------- INVOKABLE FUNCTIONS ------------------------------

~~local autosearch_text~~ = ~~"Automatic search may~~ be ~~inexact~~."

--------------------------------------------------------------------------------

~~local search_text~~ = ""

-- Function callable by other modules

-- Ratios are returned as a table, for use with other modules.

function p._ji_ratios(args)

-- Args for ease of access

equave = args["Equave" ] or DEFAULT_EQUAVE

int_limit = args["Int Limit" ] or DEFAULT_INT_LIMIT

odd_limit = args["Odd Limit" ]

prime_limit = args["Prime Limit"]

subgroup = args["Subgroup" ]

-- Filtering args

tenney_height = args["Tenney Height" ] or 1/0 -- Default Tenney height is infinity

complements_only = args["Complements Only"] or false -- Default is to include all ratios

local ratios = {}

if subgroup ~= nil then

ratios = p.search_by_subgroup(equave, int_limit, subgroup)

elseif prime_limit ~= nil then

ratios = p.search_by_prime_limit(equave, int_limit, prime_limit)

elseif int_limit ~= nil then

ratios = p.search_by_int_limit(equave, int_limit)

end

-- Filter ratios

ratios = p.filter_ratios(ratios, equave, int_limit, tenney_height, complements_only)

return ratios

end

-- Invokable function; for templates

-- Ratios are returned as a comma-delimited list. For finer control, it's

-- necessary to call the "main" function, then further process the results.

function p.ji_ratios(frame)

args = getArgs(frame)

-- Preprocess equave

-- Ratios are searched from 1/1 to some equave (default 2/1), so an equave

-- must be passed in.

args["Equave"] = args["Equave"] ~= nil and rat.parse(args["Equave"])

if ~~search_args~~["~~Prime Limit~~"] ~= nil then

-- Preprocess int limit

~~search_text~~ = ~~string.format~~("~~Ratios shown are within the %s~~-prime limit."~~, search_args~~["Prime Limit"])

-- Ratios are searched up to some int limit (default 50), so an int limit

~~.. " " .. autosearch_text~~

-- must be passed in.

~~elseif search_args~~["Subgroup"] ~= nil then

args["Int Limit"] = args["Int Limit"] ~= nil and tonumber(args["Int Limit"])

local ~~subgroup_members~~ = {}

for i = 1, #~~search_args["Subgroup"]~~ do

-- Preprocess Tenney height

~~local a, b~~ = rat.~~as_pair~~(~~search_args~~[~~"Subgroup"~~][i])

if args["Tenney Height"] ~= nil then

~~table.insert(subgroup_members, (b == 1 and string.format("%s", a) or string.format("%s/%s", a, b))~~)

args["Tenney Height"] = tonumber(args["Tenney Height"])

end

-- Preprocess prime limit

if args["Prime Limit"] ~= nil then

args["Prime Limit"] = tonumber(args["Prime Limit"])

end

-- Preprocess subgroup

if args["Subgroup"] ~= nil then

local subgroup_elements = tip.parse_numeric_pairs(args["Subgroup"], ".", "/", true)

for i = 1, #subgroup_elements do

subgroup_elements[i] = rat.new(subgroup_elements[i][1], subgroup_elements[i][2])

end

~~search_text = string.format(~~"~~Ratios shown are within the %s subgroup.~~"~~, table.concat(subgroup_members, "."))~~

args["Subgroup"] = subgroup_elements

~~.. " " .. autosearch_text~~

end

~~elseif search_args~~["~~Int Limit~~"] ~= nil then

~~search_text~~ = ~~string.format~~("~~Ratios shown are within the %s~~-~~integer limit~~.~~", search_args~~["~~Int Limit~~"])

if args["Complements Only"] ~= nil then

.. " " ~~.. autosearch_text~~

args["Complements Only"] = yesno(args["Complements Only"], false)

end

-- Find and return ratios

local result = p.ratios_as_string(p._ji_ratios(args))

local debugg = yesno(frame.args["debug"])

if debugg == true then

result = "<syntaxhighlight lang=\"wikitext\">" .. result .. "</syntaxhighlight>"

end

result ~~= search_text~~ .. " " .. ~~result~~

return frame:preprocess(result)

return ~~result~~

end

function p.tester()

--return p.ratios_as_string(p._ji_ratios(p.parse_args("Int Limit: 16; Equave: 3/1; Complements Only: 0")))

--return p.ratios_as_string(p.search_by_prime_limit_within_cents(372, 440, 17, 30))

return p.ratios_as_string(p.search_by_odd_limit(rat.new(2), 15, 15*2))

end

--------------------------------------------------------------------------------

--------------------------- ~~RATIO SORTING~~ FUNCTIONS ----------------------------

---------------------------- FUNCTIONS TO BE MOVED -----------------------------

--------------------------------------------------------------------------------

-- Sorts ratios by closeness to cent values.

-- Parse a list of ratios from a string. String is formatted as follows:

-- "a/b; c/d; e/f; g/h"

function p.parse_ratios(unparsed)

local parsed = tip.parse_numeric_pairs(unparsed)

for i = 1, #parsed do

parsed[i] = rat.new(parsed[i][1], parsed[i][2])

end

return parsed

end

-- Sorts ratios by closeness to cent values. Move to new module?

function p.sort_by_closeness_to_cent_values(ratios, cent_values, tolerance)

local tolerance = tolerance or 30

Line 368:

Line 533:

return sorted_ratios

~~end~~

~~--------------------------------------------------------------------------------~~

~~------------------------ RATIO PARSING/INPUT FUNCTIONS -------------------------~~

~~--------------------------------------------------------------------------------~~

~~-- Parse a list of ratios from a string. String is formatted as follows:~~

~~-- "a/b; c/d; e/f; g/h"~~

~~function p.parse_ratios(unparsed)~~

~~local parsed = tip.parse_numeric_pairs(unparsed)~~

~~for i = 1, #parsed do~~

~~parsed[i] = rat.new(parsed[i][1], parsed[i][2])~~

~~end~~

~~return parsed~~

~~end~~

~~--------------------------------------------------------------------------------~~

~~---------------------------- RATIO STRING FUNCTIONS ----------------------------~~

~~--------------------------------------------------------------------------------~~

~~-- Convert a table of ratios into a string, with options for links and delimiter~~

~~function p.ratios_as_string(ratios, add_links, delimiter)~~

~~local add_links = add_links == true~~

~~local delimiter = delimiter or ", "~~

~~local text = ""~~

~~if #ratios ~= 0 then~~

~~text = add_links and string.format("[[%s]]", rat.as_ratio(ratios[1])) or rat.as_ratio(ratios[1])~~

~~for i = 2, #ratios do~~

~~text = text .. (add_links and string.format("%s[[%s]]", delimiter, rat.as_ratio(ratios[i])) or string.format("%s%s", delimiter, rat.as_ratio(ratios[i])))~~

~~end~~

~~return text~~

~~end~~

~~-- Convert a jagged array of ratios into an array of strings~~

~~function p.ratios_as_strings(ratios, add_links, delimiter)~~

~~local add_links = add_links == true~~

~~local delimiter = delimiter or ", "~~

~~local texts = {}~~

~~for i = 1, #ratios do~~

~~local text = p.ratios_as_string(ratios[i], add_links, delimiter)~~

~~table.insert(texts, text)~~

~~end~~

~~return texts~~

~~end~~

~~function p.tester()~~

~~local equave = rat.new(2,1)~~

~~local fine_search_args = p.parse_search_args("Subgroup: 2.5.9/7.21; Int Limit: 50; Complements Only: 0; Tenney Height: 10")~~

~~local subgroup = {rat.new(2), rat.new(3), rat.new(5), rat.new(7)}~~

~~return p.ratios_as_string(p.search_by_args_within_equave(equave, fine_search_args))~~

~~end~~

~~--------------------------------------------------------------------------------~~

~~----------------------------- INVOKABLE FUNCTIONS ------------------------------~~

~~--------------------------------------------------------------------------------~~

~~-- Function callable by other modules~~

~~function p._ji_ratios(args)~~

~~end~~

~~-- Invokable function; for templates~~

~~function p.ji_ratios(frame)~~

~~args = getArgs(frame)~~

~~args["Equave"] = rat.parse(args["Equave"])~~

~~if args["Int Limit"] ~= nil then~~

~~args["Int Limit"] = tonumber(args["Int Limit"])~~

~~end~~

~~if args["Tenney Height"] ~= nil then~~

~~args["Tenney Height"] = tonumber(args["Tenney Height"])~~

~~end~~

~~if args["Prime Limit"] ~= nil then~~

~~args["Prime Limit"] = tonumber(args["Prime Limit"])~~

~~end~~

~~if args["Subgroup"] ~= nil then~~

~~local subgroup_elements = tip.parse_numeric_pairs(args["Subgroup"], ".", "/", true)~~

~~for i = 1, #subgroup_elements do~~

~~subgroup_elements[i] = rat.new(subgroup_elements[i][1], subgroup_elements[i][2])~~

~~end~~

~~args["Subgroup"] = subgroup_elements~~

~~end~~

~~if args["Complements Only"] ~= nil then~~

~~args["Complements Only"] = yesno(args["Complements Only"])~~

~~end~~

~~ratios = p.search_by_args_within_equave(args["Equave"], args)~~

~~return p.ratios_as_string(ratios)~~

end

return p

@@ Line 1: / Line 1: @@
+-- This module follows [[User:Ganaram inukshuk/Provisional style guide for Lua]]
+local getArgs = require("Module:Arguments").getArgs
+local med = require("Module:Mediants")
 local rat = require("Module:Rational")
+local tip = require("Module:Template input parse")
 local utils = require("Module:Utils")
-local tip = require("Module:Template input parse")
-local med = require("Module:Mediants")
 local yesno = require("Module:Yesno")
-local getArgs = require("Module:Arguments").getArgs
-p = {}
--- TODO
+local p = {}
--- - Transfer control over to new "main" function: p.ji_ratios()
 -- Template for handling multiple entry of JI ratios into a template, and for
@@ Line 14: / Line 13: @@
 -- This is a successor/replacement for JI ratio finder.
--- JI ratios are searched by the following params in a hierarchy:
+-- TODO: Refactor code such that:
--- - Search by prime limit. Int limit is used to limit the num/den of ratios.
+-- - For int-limit search, int limit is the first arg, and equave and min/max
---   Prime limit takes precedence over subgroup.
+--   cents default to 2/1, 0c, and 1200c respectively.
--- - Search by subgroup. (Subgroup may contain nonprime numbers, but ratios are
+--   (int_limit, equave)
---   currently not supported.) Int limit is used to limit the num/den of ratios.
+--   (int_limit, min_cents, max_cents)
--- - If neither prime limit or subgroup is present, search by int limit. This
+-- - For odd-limit search, odd limit is the first arg, int limit defaults to
---   is considered the absolute minimum requirement for ratio searching.
+--   twice the odd limit, and equave and min/max cents default to 2/1, 0c, and
--- NOTES:
+--   1200c respectively.
--- - Prime limits are infinite sets, so int limit is used to restrain the set
+--   (odd_limit, int_limit, equave)
---   to a finite size. The same is true for subgroup.
+--   (odd_limit, int_limit, min_cents, max_cents)
--- - Tenney height is used for further filtering of ratios, and is considered
+-- - For prime-limit search, prime-limit is the first arg, int limit defaults to
---   optional. If omitted, tenney height defaults to infinity.
+--   twice the largest prime, and equave and min/max cents default to 2/1, 0c,
+--   and 1200c respectively.
-local DEFAULT_FINE_SEARCH_ARGS = {
+--   (prime_limit, int_limit, equave)
-	["Int Limit"]        = 50,
+--   (prime_limit, int_limit, min_cents, max_cents)
-	["Tenney Height"]    = 1/0,
+-- - For subgroup search, subgroup is the first arg, there's no default value
-	["Complements Only"] = false
+--   for int limit (due to complexity of subgroups), and equave and min/max
-}
+--   cents default to 2/1, 0c, and 1200c respectively.
+--   (subgroup, int_limit, equave)
+--   (subgroup, int_limit, min_cents, max_cents)
+-- - Filter ratios function is split into two:
+--   - Filter ratios by complement removes ratios from a table if its complement
+--     is missing. Complements are octave-complements by default.
+--   - Filter ratios by tenney height removes ratios from a table if its tenney
+--     height exceeds a passed-in value.
---------------------------------------------------------------------------------
+-- TODO: write filter function for cent range
------------------------------- HELPER FUNCTIONS --------------------------------
---------------------------------------------------------------------------------
--- Does not return anything; entries in source are added to destination.
+-- Module searches for ratios that are, at the minimum, up to an equave and are
-function p.merge_ratio_tables_without_duplicates(dest_table, source_table)
+-- up to some integer limit. Search hierarchy is as follows:
-	for i = 1, #source_table do
+-- - Search by subgroup (subgroup elements may be nonprime or rational)
-		if not p.find_ratio_in_table(dest_table, source_table[i]) then
+-- - Then search by prime limit
-			table.insert(dest_table, source_table[i])
+-- - Then search by odd limit
-		end
+-- - Then search by int limit
-	end
-end
--- Checks whether a ratio was already in a table
+-- Optional args omit ratios that don't meet certain conditions, and are used
-function p.find_ratio_in_table(table_, ratio)
+-- to further limit the number of ratios found. Current options include:
-	local found = false
+-- - Tenney Height: omits ratios that exceed some max Tenney height. Has no
-	for i = 1, #table_ do
+--   effect if no Tenney height is passed in.
-		if rat.as_float(table_[i]) == rat.as_float(ratio) then
+-- - Complements Only: omits ratios and their equave complements if either would
-			found = true
+--   be omitted by Tenney height, or if no Tenney height is entered, omits
-			break
+--   ratios whose complements are missing.
-		end
-	end
-	return found
-end
--- Preprocess fine-search args
+local DEFAULT_EQUAVE = rat.new(2)
-function p.preprocess_fine_search_args(fine_search_args)
+local DEFAULT_INT_LIMIT = 30
-	local fine_search_args = fine_search_args or DEFAULT_FINE_SEARCH_ARGS
-	local tenney_height = fine_search_args["Tenney Height"] or 1/0
-	local comps_only    = fine_search_args["Complements Only"] or false
-	local int_limit     = fine_search_args["Int Limit"] or DEFAULT_INT_LIMIT
-	return {
-		["Tenney Height"]    = tenney_height,
-		["Complements Only"] = comps_only,
-		["Int Limit"]        = int_limit
-	}
-end
 --------------------------------------------------------------------------------
@@ Line 76: / Line 63: @@
 --------------------------------------------------------------------------------
--- Remove ratios whose complements exceed the int limit and Tenney height.
+-- Filter function removes certain ratios that don't meet some requirement.
--- If filtering based on Tenney height is not needed, then Tenney height is set
+-- Filters currently include:
--- to infinity instead, which should be done by the calling function.
+-- - Removing ratios that exceed a max Tenney height.
-function p.filter_ratios_by_complements(ratios, equave, fine_search_args)
+-- - Removing ratios whose complement would exceed a max Tenney height or int limit
-	if fine_search_args["Complements Only"] then
+function p.filter_ratios(ratios, equave, int_limit, tenney_height, complements_only)
-		local filtered_ratios = {}
-		for i = 1, #ratios do
+	local filtered_ratios = {}
-			local complement = rat.mul(rat.inv(ratios[i]), equave)
+	for i = 1, #ratios do
-			if rat.int_limit(complement) <= fine_search_args["Int Limit"] and rat.tenney_height(complement) <= fine_search_args["Tenney Height"] then
+		local complement = rat.mul(rat.inv(ratios[i]), equave)
+		local ratio_th   = rat.tenney_height(ratios[i])
+		local compl_th   = rat.tenney_height(complement)
+		-- Are the ratios within the Tenney height?
+		-- Has no effect (defaults to TRUE) if Tenney height is infinity.
+		local ratio_within_th = ratio_th <= tenney_height
+		local compl_within_th = compl_th <= tenney_height
+		-- Is the ratio's complement within the int limit?
+		local compl_within_int_limit = rat.is_within_int_limit(complement, int_limit)
+		if complements_only then
+			if ratio_within_th and compl_within_th and compl_within_int_limit then
+				table.insert(filtered_ratios, ratios[i])
+			end
+		else
+			if ratio_within_th then
 				table.insert(filtered_ratios, ratios[i])
 			end
 		end
-		return filtered_ratios
-	else
-		return ratios
 	end
+	return filtered_ratios
 end
--- Remove ratios that exceed the Tenney height. This does nothing if the Tenney
+-- Filters ratios from a table of ratios, returning an array of ratios within
--- height is infinity.
+-- the cent range and preserving the original table. Meant for searching for
-function p.filter_ratios_by_tenney_height(ratios, equave, fine_search_args)
+-- multiple ranges. TODO: write
-	local filtered_ratios = {}
+function p.filter_ratios_within_cent_range(ratios, min_cents, max_cents)
-	for i = 1, #ratios do
-		if rat.tenney_height(ratios[i]) <= fine_search_args["Tenney Height"] then
-			table.insert(filtered_ratios, ratios[i])
-		end
-	end
-	return filtered_ratios
 end
 --------------------------------------------------------------------------------
------------------------ INT-LIMIT-BASED SEARCH FUNCTION ------------------------
+-------------------------- INT-LIMIT SEARCH FUNCTION ---------------------------
 --------------------------------------------------------------------------------
--- Int-limit-based search; finds ratios between 1/1 and an equave, within an int
+-- Int limit search finds ratios from 1/1 to an equave, where each ratio's
--- limit.
+-- numerator or denominator don't exceed the int limit.
-function p.search_within_equave(equave, fine_search_args)
+function p.search_by_int_limit(equave, int_limit)
-	local equave = equave or rat.new(2,1)			-- Defualt equave is 2/1.
+	return p.search_by_int_limit_within_cents(0, rat.cents(equave), int_limit)
-	local fine_search_args = p.preprocess_fine_search_args(fine_search_args)
+end
+-- Cent range search finds ratios within a cent range. Meant for searching for
+-- ratios within a single interval range. If searching for ratios within many
+-- interval ranges, then try a broad search first.
+function p.search_by_int_limit_within_cents(min_cents, max_cents, int_limit)
 	local init_ratios = {{1,1}, {1,0}}
-	local ratios = med.find_only_mediants_by_int_limit(init_ratios, fine_search_args["Int Limit"])
+	local ratios = med.find_only_mediants(init_ratios, 2)
+	for i = 3, int_limit do
+		ratios = med.find_mediants_by_int_limit(ratios, i)
+		-- Purge ratios from the beginning.
+		-- If the first and second ratio are smaller than min_cents, and smaller
+		-- than max_cents, then remove the first ratio. Keeping the first ratio
+		-- would add mediants outside the cent range.
+		local cents_1 = utils.log2(ratios[1][1] / ratios[1][2]) * 1200
+		local cents_2 = utils.log2(ratios[2][1] / ratios[2][2]) * 1200
+		if cents_1 < min_cents and cents_2 <= min_cents and cents_1 < max_cents and cents_2 < max_cents then
+			table.remove(ratios, 1)
+		end
+		-- Purge ratios from the end.
+		-- If the 2nd-last ratio and last ratio are greater than max_cents, and
+		-- larger than min_cents, then remove the last ratio. Keeping the last
+		-- ratio would add mediants outside the cent range.
+		local cents_3 = utils.log2(ratios[#ratios-1][1] / ratios[#ratios-1][2]) * 1200
+		local cents_4 = utils.log2(ratios[#ratios  ][1] / ratios[#ratios  ][2]) * 1200
+		if cents_3 > max_cents and cents_4 >= max_cents and cents_3 > min_cents and cents_4 > min_cents then
+			table.remove(ratios, #ratios)
+		end
+	end
 	-- Convert to ratios that Module:Rational can work with
@@ Line 124: / Line 150: @@
 	end
-	-- Remove ratios that exceed the equave.
+	-- Remove any remaining ratios that fall outside the cent range.
-	-- Note that mediant search returns sorted ratios, so remove them from the
+	while rat.cents(ratios[1]) < min_cents do
-	-- end until there's no more to remove.
+		table.remove(ratios, 1)
-	while rat.gt(ratios[#ratios], equave) do
+	end
+	while rat.cents(ratios[#ratios]) > max_cents do
 		table.remove(ratios, #ratios)
 	end
-	-- Filter out ratios that exceed the int limit.
-	-- Then filter out ratios if their equave complement would be filtered out.
-	ratios = p.filter_ratios_by_tenney_height(ratios, equave, fine_search_args)
-	ratios = p.filter_ratios_by_complements(ratios, equave, fine_search_args)
 	return ratios
@@ Line 140: / Line 162: @@
 --------------------------------------------------------------------------------
------------------------- SUBGROUP-BASED SEARCH FUNCTION ------------------------
+-------------------------- ODD-LIMIT SEARCH FUNCTION ---------------------------
 --------------------------------------------------------------------------------
-function p.search_by_prime_limit(prime_limit, equave, fine_search_args)
+-- Convert odd limit into equivalent subgroup.
-	local prime_limit = prime_limit or 5
+-- EG, 11-odd-limit becomes 2.3.5.7.9.11
-	local equave = equave or rat.new(2,1)
+-- 2 is part of the subgroup by definition.
-	local fine_search_args = p.preprocess_fine_search_args(fine_search_args)
+function p.odd_limit_to_subgroup(odd_limit)
+	local subgroup = { rat.new(2) }
+	for i = 3, odd_limit, 2 do
+		table.insert(subgroup, rat.new(i))
+	end
+	return subgroup
+end
-	-- Find all primes up to the prime limit.
+function p.search_by_odd_limit(equave, int_limit, odd_limit)
-	local primes = {}
+	local subgroup = p.odd_limit_to_subgroup(odd_limit)
-	for i = 2, prime_limit do
+	return p.search_by_subgroup_within_cents(0, rat.cents(equave), int_limit, subgroup)
+end
+function p.search_by_odd_limit_within_cents(min_cents, max_cents, odd_limit)
+	local subgroup = p.odd_limit_to_subgroup(odd_limit)
+	return p.search_by_subgroup_within_cents(min_cents, max_cents, int_limit, subgroup)
+end
+--------------------------------------------------------------------------------
+------------------------- PRIME-LIMIT SEARCH FUNCTION --------------------------
+--------------------------------------------------------------------------------
+-- Convert prime limit into equivalent subgroup.
+-- EG, 11-prime-limit becomes 2.3.5.7.11
+function p.prime_limit_to_subgroup(prime_limit)
+	local subgroup = {}
+	for i = 3, prime_limit do
 		local is_prime = true
 		for j = 2, math.floor(math.sqrt(i)) do
@@ Line 159: / Line 203: @@
 		end
 		if is_prime then
-			table.insert(primes, rat.new(i))
+			table.insert(subgroup, rat.new(i))
 		end
 	end
+	return subgroup
-	-- Perform subgroup search on the primes found, as subgroup-search code can
+end
-	-- be reused for prime-limit search.
-	return p.search_by_subgroup(primes, equave, fine_search_args)
+-- Prime limit search finds ratios with prime factors that don't exceed some
+-- prime limit.
+-- Upper bounds for searching is the equave and int limit.
+function p.search_by_prime_limit(equave, int_limit, prime_limit)
+	local subgroup = p.prime_limit_to_subgroup(prime_limit)
+	return p.search_by_subgroup_within_cents(0, rat.cents(equave), int_limit, subgroup)
+end
+-- Prime limit search finds ratios with prime factors that don't exceed some
+-- prime limit. Searches within a cent range.
+function p.search_by_prime_limit_within_cents(min_cents, max_cents, int_limit, prime_limit)
+	local subgroup = p.prime_limit_to_subgroup(prime_limit)
+	local ratios = p.search_by_subgroup_within_cents(min_cents, max_cents, int_limit, subgroup)
+	while rat.cents(ratios[1]) < min_cents do
+		table.remove(ratios, 1)
+	end
+	return ratios
+end
+--------------------------------------------------------------------------------
+---------------------------- SUBGROUP SEARCH FUNCTION --------------------------
+--------------------------------------------------------------------------------
+-- Subgroup search find ratios that are products of at least two non-unique
+-- elements from the subgroup.
+function p.search_by_subgroup(equave, int_limit, subgroup)
+	local ratios = p.search_by_subgroup_within_cents(0, rat.cents(equave), int_limit, subgroup)
+	return ratios
 end
--- WORK-IN-PROGRESS!!
+function p.search_by_subgroup_within_cents(min_cents, max_cents, int_limit, subgroup)
-function p.search_by_subgroup(subgroup, equave, fine_search_args)
+	--local equave    = equave or rat.new(2,1)	-- Defualt equave is 2/1.
-	local subgroup = subgroup or {rat.new(2), rat.new(3), rat.new(7)}
+	--local int_limit = int_limit or 50			-- Default is 50
-	local equave = equave or rat.new(2,1)
+	--local subgroup  = subgroup or {rat.new(2), rat.new(3), rat.new(7)}		-- Default is 2.3.7 subgroup
-	local fine_search_args = p.preprocess_fine_search_args(fine_search_args)
-	-- Fine search params for ease of access
+	-- Find all possible ways to multiply subgroup elements with one another
-	local tenney_height = fine_search_args["Tenney Height"]
+	-- using breadth-first-search. Products found this way should not exceed the
-	local comps_only = fine_search_args["Complements Only"]
+	-- int limit, and if a subgroup element is rational, neither its numerator
-	local int_limit = fine_search_args["Int Limit"]
+	-- nor denominator should exceed the int limit.
+	local products = { rat.new(1) }
+	local i = 1
+	while i <= #products do
+		-- Multiply each subgroup element by the current ratio. The table of
+		-- product ratios created this way is merged with the running table of
+		-- ratios. This is the Cartesian product of the single ratio as a set,
+		-- with the subgroup elements as a set, or {p/q} X subgroup.
+		local new_products = {}
+		for j = 1, #subgroup do
+			local new_ratio = rat.mul(products[i], subgroup[j])
+			if rat.is_within_int_limit(new_ratio, int_limit) and not p.find_ratio_in_table(new_products, new_ratio) then
+				table.insert(new_products, new_ratio)
+			end
+		end
+		-- Merge new products with the table of products, omitting duplicates.
+		p.merge_tables(products, new_products)
+		i = i + 1
+	end
-	-- Search for ratios within int limit within subgroup by multiplication.
+	-- Sort for next step
-	local products = p.multiply_ratios_using_bfs(rat.new(1), subgroup, int_limit)
+	table.sort(products, rat.lt)
 	-- Use the products found to find all ratios between 1 and the equave.
-	-- For each ratio found, have it be the denominator and have the numerator
+	-- For each ratio in the table of products, create a set of new ratios by
-	-- be all successive ratios after it. For each new ratio found this way, add
+	-- having that ratio be the numerator and all successive ratios be possible
-	-- it to the table of ratios, excluding ratios that exceed the equave or int
+	-- denominators. Store these new ratios in a table, and repeat with all
-	-- limit, and excluding duplicates. This is way faster than performing BFS
+	-- successive products, omitting duplicats. From earlier testing, this is
-	-- on each ratio and yields the same results.
+	-- faster than performing BFS on each ratio, and yields the same results.
 	local ratios = {}
 	for i = 1, #products do
 		local new_ratios = {}
 		for j = i, #products do
-			local ratio = rat.div(products[j], products[i])
+			local new_ratio = rat.div(products[j], products[i])
-			if rat.as_float(ratio) > rat.as_float(equave) then break end
+			if rat.cents(new_ratio) > max_cents then break end
-			if not p.find_ratio_in_table(new_ratios, ratio) and rat.int_limit(ratio) <= int_limit then
+			if not p.find_ratio_in_table(new_ratios, new_ratio) and rat.is_within_int_limit(new_ratio, int_limit) then
-				table.insert(new_ratios, ratio)
+				table.insert(new_ratios, new_ratio)
 			end
 		end
-		p.merge_ratio_tables_without_duplicates(ratios, new_ratios)
+		-- Merge new ratios with the table of ratios, omitting duplicates.
+		p.merge_tables(ratios, new_ratios)
 	end
-	-- Sort, then filter out ratios that exceed the int limit.
+	-- Sort
-	-- Then filter out ratios if their equave complement would be filtered out.
 	table.sort(ratios, rat.lt)
-	ratios = p.filter_ratios_by_tenney_height(ratios, equave, fine_search_args)
-	ratios = p.filter_ratios_by_complements(ratios, equave, fine_search_args)
+	-- Remove ratios less than minimum
+	while rat.cents(ratios[1]) < min_cents do
+		table.remove(ratios, 1)
+	end
 	return ratios
 end
--- Helper function for subgroup search; implementation of BFS
+--------------------------------------------------------------------------------
-function p.multiply_ratios_using_bfs(init_ratio, subgroup, int_limit)
+------------------------------- HELPER FUNCTIONS -------------------------------
-	local ratios = { init_ratio }
+--------------------------------------------------------------------------------
-	local i = 1
-	while i <= #ratios do
+-- Heleper function; merges elements from source table with destination table
-		local new_ratios = p.multiply_ratio_by_subgroup_elements(ratios[i], subgroup, int_limit)
+-- while disallowing duplicates.
-		p.merge_ratio_tables_without_duplicates(ratios, new_ratios)
+function p.merge_tables(dest_table, source_table)
-		i = i + 1
+	for i = 1, #source_table do
+		if not p.find_ratio_in_table(dest_table, source_table[i]) then
+			table.insert(dest_table, source_table[i])
+		end
 	end
-	table.sort(ratios, rat.lt)
-	return ratios
 end
--- Helper function for BFS search; returns { ratio } X subgroup
+-- Helper function for merge function.
-function p.multiply_ratio_by_subgroup_elements(ratio, subgroup, int_limit)
+function p.find_ratio_in_table(table_, ratio)
-	local ratios = {}
+	local found = false
-	for i = 1, #subgroup do
+	for i = 1, #table_ do
-		local new_ratio = rat.mul(ratio, subgroup[i])
+		if rat.as_float(table_[i]) == rat.as_float(ratio) then
-		if rat.int_limit(new_ratio) <= int_limit and not p.find_ratio_in_table(ratios, new_ratio) then
+			found = true
-			table.insert(ratios, new_ratio)
+			break
 		end
 	end
-	return ratios
+	return found
 end
 --------------------------------------------------------------------------------
---------------------------- REVERSE-SEARCH FUNCTIONS ---------------------------
+---------------------------- RATIO STRING FUNCTIONS ----------------------------
 --------------------------------------------------------------------------------
-function p.int_limit_of_ratios(ratios)
+-- Convert a table of ratios into a string, with options for links and delimiter
+function p.ratios_as_string(ratios, add_links, delimiter)
+	local add_links = add_links == true
+	local delimiter = delimiter or ", "
+	local text = ""
+	if #ratios ~= 0 then
+		text = add_links and string.format("[[%s]]", rat.as_ratio(ratios[1])) or rat.as_ratio(ratios[1])
+		for i = 2, #ratios do
+			text = text .. (add_links and string.format("%s[[%s]]", delimiter, rat.as_ratio(ratios[i])) or string.format("%s%s", delimiter, rat.as_ratio(ratios[i])))
+		end
+	end
+	return text
 end
-function p.prime_limit_of_ratios(ratios)
+-- Convert a jagged array of ratios into an array of strings
+function p.ratios_as_strings(ratios, add_links, delimiter)
+	local add_links = add_links == true
-end
+	local delimiter = delimiter or ", "
-function p.subgroup_of_ratios(ratios, is_nonprime)
+	local texts = {}
+	for i = 1, #ratios do
+		local text = p.ratios_as_string(ratios[i], add_links, delimiter)
+		table.insert(texts, text)
+	end
+	return texts
 end
 --------------------------------------------------------------------------------
--------------------------- ARG-BASED SEARCH FUNCTIONS --------------------------
+---------------------------- ARG-PARSING FUNCTION ------------------------------
 --------------------------------------------------------------------------------
--- Search for ratios based on an array of args passed in. Certain params have
+-- Parse search args if entered as one string. Use is to be determined.
--- their own function calls.
+function p.parse_args(search_args)
-function p.search_by_args_within_equave(equave, search_args)
+	local parsed = tip.parse_kv_pairs(search_args)
-	local equave = equave or rat.new(2,1)
-	-- For each search method, check whether the corresponding search arg and
+	if parsed["Equave"] ~= nil then
-	-- int limit are both present and pass it and the equave to that function.
+		parsed["Equave"] = rat.parse(parsed["Equave"])
-	-- All other search args are used as finer search args.
-	-- Note that search by int limit alone just has the equave and search args
-	-- passed in.
-	local ratios = {}
-	if search_args["Prime Limit"] ~= nil and search_args["Int Limit"] ~= nil then
-		ratios = p.search_by_prime_limit(search_args["Prime Limit"], equave, search_args)
-	elseif search_args["Subgroup"] ~= nil and search_args["Int Limit"] ~= nil then
-		ratios = p.search_by_subgroup(search_args["Subgroup"], equave, search_args)
-	elseif search_args["Int Limit"] ~= nil then
-		ratios = p.search_within_equave(equave, search_args)
 	end
-	return ratios
-end
--- Parse search args.
-function p.parse_search_args(search_args)
-	local parsed = tip.parse_kv_pairs(search_args)
 	if parsed["Int Limit"] ~= nil then
@@ Line 311: / Line 401: @@
 end
-function p.search_footnotes(search_args)
+--------------------------------------------------------------------------------
-	local result = "Other interpretations are possible."
+----------------------------- INVOKABLE FUNCTIONS ------------------------------
-	local autosearch_text = "Automatic search may be inexact."
+--------------------------------------------------------------------------------
-	local search_text = ""
+-- Function callable by other modules
+-- Ratios are returned as a table, for use with other modules.
+function p._ji_ratios(args)
+	-- Args for ease of access
+	equave      = args["Equave"     ]	or DEFAULT_EQUAVE
+	int_limit   = args["Int Limit"  ]	or DEFAULT_INT_LIMIT
+	odd_limit   = args["Odd Limit"  ]
+	prime_limit = args["Prime Limit"]
+	subgroup    = args["Subgroup"   ]
+	-- Filtering args
+	tenney_height    = args["Tenney Height"   ] or 1/0		-- Default Tenney height is infinity
+	complements_only = args["Complements Only"] or false	-- Default is to include all ratios
+	local ratios = {}
+	if subgroup ~= nil then
+		ratios = p.search_by_subgroup(equave, int_limit, subgroup)
+	elseif prime_limit ~= nil then
+		ratios = p.search_by_prime_limit(equave, int_limit, prime_limit)
+	elseif int_limit ~= nil then
+		ratios = p.search_by_int_limit(equave, int_limit)
+	end
+	-- Filter ratios
+	ratios = p.filter_ratios(ratios, equave, int_limit, tenney_height, complements_only)
+	return ratios
+end
+-- Invokable function; for templates
+-- Ratios are returned as a comma-delimited list. For finer control, it's
+-- necessary to call the "main" function, then further process the results.
+function p.ji_ratios(frame)
+	args = getArgs(frame)
+	-- Preprocess equave
+	-- Ratios are searched from 1/1 to some equave (default 2/1), so an equave
+	-- must be passed in.
+	args["Equave"] = args["Equave"] ~= nil and rat.parse(args["Equave"])
-	if search_args["Prime Limit"] ~= nil then
+	-- Preprocess int limit
-		search_text = string.format("Ratios shown are within the %s-prime limit.", search_args["Prime Limit"])
+	-- Ratios are searched up to some int limit (default 50), so an int limit
-			.. " " .. autosearch_text
+	-- must be passed in.
-	elseif search_args["Subgroup"] ~= nil then
+	args["Int Limit"] = args["Int Limit"] ~= nil and tonumber(args["Int Limit"])
-		local subgroup_members = {}
-		for i = 1, #search_args["Subgroup"] do
+	-- Preprocess Tenney height
-			local a, b = rat.as_pair(search_args["Subgroup"][i])
+	if args["Tenney Height"] ~= nil then
-			table.insert(subgroup_members, (b == 1 and string.format("%s", a) or string.format("%s/%s", a, b)))
+		args["Tenney Height"] = tonumber(args["Tenney Height"])
+	end
+	-- Preprocess prime limit
+	if args["Prime Limit"] ~= nil then
+		args["Prime Limit"] = tonumber(args["Prime Limit"])
+	end
+	-- Preprocess subgroup
+	if args["Subgroup"] ~= nil then
+		local subgroup_elements = tip.parse_numeric_pairs(args["Subgroup"], ".", "/", true)
+		for i = 1, #subgroup_elements do
+			subgroup_elements[i] = rat.new(subgroup_elements[i][1], subgroup_elements[i][2])
 		end
-		search_text = string.format("Ratios shown are within the %s subgroup.", table.concat(subgroup_members, "."))
+		args["Subgroup"] = subgroup_elements
-			.. " " .. autosearch_text
+	end
-	elseif search_args["Int Limit"] ~= nil then
-		search_text = string.format("Ratios shown are within the %s-integer limit.", search_args["Int Limit"])
+	if args["Complements Only"] ~= nil then
-			.. " " .. autosearch_text
+		args["Complements Only"] = yesno(args["Complements Only"], false)
+	end
+	-- Find and return ratios
+	local result = p.ratios_as_string(p._ji_ratios(args))
+	local debugg = yesno(frame.args["debug"])
+	if debugg == true then
+		result = "<syntaxhighlight lang=\"wikitext\">" .. result .. "</syntaxhighlight>"
 	end
-	result = search_text .. " " .. result
+	return frame:preprocess(result)
-	return result
+end
+function p.tester()
+	--return p.ratios_as_string(p._ji_ratios(p.parse_args("Int Limit: 16; Equave: 3/1; Complements Only: 0")))
+	--return p.ratios_as_string(p.search_by_prime_limit_within_cents(372, 440, 17, 30))
+	return p.ratios_as_string(p.search_by_odd_limit(rat.new(2), 15, 15*2))
 end
 --------------------------------------------------------------------------------
---------------------------- RATIO SORTING FUNCTIONS ----------------------------
+---------------------------- FUNCTIONS TO BE MOVED -----------------------------
 --------------------------------------------------------------------------------
--- Sorts ratios by closeness to cent values.
+-- Parse a list of ratios from a string. String is formatted as follows:
+-- "a/b; c/d; e/f; g/h"
+function p.parse_ratios(unparsed)
+	local parsed = tip.parse_numeric_pairs(unparsed)
+	for i = 1, #parsed do
+		parsed[i] = rat.new(parsed[i][1], parsed[i][2])
+	end
+	return parsed
+end
+-- Sorts ratios by closeness to cent values. Move to new module?
 function p.sort_by_closeness_to_cent_values(ratios, cent_values, tolerance)
 	local tolerance = tolerance or 30
@@ Line 368: / Line 533: @@
 	return sorted_ratios
-end
---------------------------------------------------------------------------------
------------------------- RATIO PARSING/INPUT FUNCTIONS -------------------------
---------------------------------------------------------------------------------
--- Parse a list of ratios from a string. String is formatted as follows:
--- "a/b; c/d; e/f; g/h"
-function p.parse_ratios(unparsed)
-	local parsed = tip.parse_numeric_pairs(unparsed)
-	for i = 1, #parsed do
-		parsed[i] = rat.new(parsed[i][1], parsed[i][2])
-	end
-	return parsed
-end
---------------------------------------------------------------------------------
----------------------------- RATIO STRING FUNCTIONS ----------------------------
---------------------------------------------------------------------------------
--- Convert a table of ratios into a string, with options for links and delimiter
-function p.ratios_as_string(ratios, add_links, delimiter)
-	local add_links = add_links == true
-	local delimiter = delimiter or ", "
-	local text = ""
-	if #ratios ~= 0 then
-		text = add_links and string.format("[[%s]]", rat.as_ratio(ratios[1])) or rat.as_ratio(ratios[1])
-		for i = 2, #ratios do
-			text = text .. (add_links and string.format("%s[[%s]]", delimiter, rat.as_ratio(ratios[i])) or string.format("%s%s", delimiter, rat.as_ratio(ratios[i])))
-		end
-	end
-	return text
-end
--- Convert a jagged array of ratios into an array of strings
-function p.ratios_as_strings(ratios, add_links, delimiter)
-	local add_links = add_links == true
-	local delimiter = delimiter or ", "
-	local texts = {}
-	for i = 1, #ratios do
-		local text = p.ratios_as_string(ratios[i], add_links, delimiter)
-		table.insert(texts, text)
-	end
-	return texts
-end
-function p.tester()
-	local equave = rat.new(2,1)
-	local fine_search_args = p.parse_search_args("Subgroup: 2.5.9/7.21; Int Limit: 50; Complements Only: 0; Tenney Height: 10")
-	local subgroup = {rat.new(2), rat.new(3), rat.new(5), rat.new(7)}
-	return p.ratios_as_string(p.search_by_args_within_equave(equave, fine_search_args))
-end
---------------------------------------------------------------------------------
------------------------------ INVOKABLE FUNCTIONS ------------------------------
---------------------------------------------------------------------------------
--- Function callable by other modules
-function p._ji_ratios(args)
-end
--- Invokable function; for templates
-function p.ji_ratios(frame)
-	args = getArgs(frame)
-	args["Equave"] = rat.parse(args["Equave"])
-	if args["Int Limit"] ~= nil then
-		args["Int Limit"] = tonumber(args["Int Limit"])
-	end
-	if args["Tenney Height"] ~= nil then
-		args["Tenney Height"] = tonumber(args["Tenney Height"])
-	end
-	if args["Prime Limit"] ~= nil then
-		args["Prime Limit"] = tonumber(args["Prime Limit"])
-	end
-	if args["Subgroup"] ~= nil then
-		local subgroup_elements = tip.parse_numeric_pairs(args["Subgroup"], ".", "/", true)
-		for i = 1, #subgroup_elements do
-			subgroup_elements[i] = rat.new(subgroup_elements[i][1], subgroup_elements[i][2])
-		end
-		args["Subgroup"] = subgroup_elements
-	end
-	if args["Complements Only"] ~= nil then
-		args["Complements Only"] = yesno(args["Complements Only"])
-	end
-	ratios = p.search_by_args_within_equave(args["Equave"], args)
-	return p.ratios_as_string(ratios)
 end
 return p