neovim/test/unit/marktree_spec.lua

649 lines
19 KiB
Lua

local helpers = require('test.unit.helpers')(after_each)
local itp = helpers.gen_itp(it)
local ffi = helpers.ffi
local eq = helpers.eq
local ok = helpers.ok
local lib = helpers.cimport('./src/nvim/marktree.h')
local function tablelength(t)
local count = 0
for _ in pairs(t) do
count = count + 1
end
return count
end
local function pos_leq(a, b)
return a[1] < b[1] or (a[1] == b[1] and a[2] <= b[2])
end
-- Checks that shadow and tree is consistent, and optionally
-- return the order
local function shadoworder(tree, shadow, iter, giveorder)
ok(iter ~= nil)
local status = lib.marktree_itr_first(tree, iter)
local count = 0
local pos2id, id2pos = {}, {}
local last
if not status and next(shadow) == nil then
return pos2id, id2pos
end
repeat
local mark = lib.marktree_itr_current(iter)
local id = tonumber(mark.id)
local spos = shadow[id]
eq(mark.pos.row, spos[1], mark.id)
eq(mark.pos.col, spos[2], mark.id)
if lib.mt_right_test(mark) ~= spos[3] then
error('invalid gravity for ' .. id .. ':(' .. mark.pos.row .. ', ' .. mark.pos.col .. ')')
end
if count > 0 then
if not pos_leq(last, spos) then
error('DISORDER')
end
end
count = count + 1
last = spos
if giveorder then
pos2id[count] = id
id2pos[id] = count
end
until not lib.marktree_itr_next(tree, iter)
local shadowlen = tablelength(shadow)
if shadowlen ~= count then
error('missed some keys? (shadow ' .. shadowlen .. ', tree ' .. count .. ')')
end
return id2pos, pos2id
end
local function shadowsplice(shadow, start, old_extent, new_extent)
local old_end = {
start[1] + old_extent[1],
(old_extent[1] == 0 and start[2] or 0) + old_extent[2],
}
local new_end = {
start[1] + new_extent[1],
(new_extent[1] == 0 and start[2] or 0) + new_extent[2],
}
local delta = { new_end[1] - old_end[1], new_end[2] - old_end[2] }
for _, pos in pairs(shadow) do
if pos_leq(start, pos) then
if pos_leq(pos, old_end) then
-- delete region
if pos[3] then -- right gravity
pos[1], pos[2] = new_end[1], new_end[2]
else
pos[1], pos[2] = start[1], start[2]
end
else
if pos[1] == old_end[1] then
pos[2] = pos[2] + delta[2]
end
pos[1] = pos[1] + delta[1]
end
end
end
end
local function dosplice(tree, shadow, start, old, new)
lib.marktree_splice(tree, start[1], start[2], old[1], old[2], new[1], new[2])
shadowsplice(shadow, start, old, new)
end
local ns = 10
local last_id = nil
local function put(tree, row, col, gravity, end_row, end_col, end_gravity)
last_id = last_id + 1
local my_id = last_id
end_row = end_row or -1
end_col = end_col or -1
end_gravity = end_gravity or false
lib.marktree_put_test(tree, ns, my_id, row, col, gravity, end_row, end_col, end_gravity, false)
return my_id
end
local function put_meta(tree, row, col, gravitate, meta)
last_id = last_id + 1
local my_id = last_id
lib.marktree_put_test(tree, ns, my_id, row, col, gravitate, -1, -1, false, meta)
return my_id
end
describe('marktree', function()
before_each(function()
last_id = 0
end)
itp('works', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
local shadow = {}
local iter = ffi.new('MarkTreeIter[1]')
local iter2 = ffi.new('MarkTreeIter[1]')
for i = 1, 100 do
for j = 1, 100 do
local gravitate = (i % 2) > 0
local id = put(tree, j, i, gravitate)
ok(id > 0)
eq(nil, shadow[id])
shadow[id] = { j, i, gravitate }
end
-- checking every insert is too slow, but this is ok
lib.marktree_check(tree)
end
-- ss = lib.mt_inspect_rec(tree)
-- io.stdout:write(ffi.string(ss))
-- io.stdout:flush()
local id2pos, pos2id = shadoworder(tree, shadow, iter)
eq({}, pos2id) -- not set if not requested
eq({}, id2pos)
for i, ipos in pairs(shadow) do
local p = lib.marktree_lookup_ns(tree, ns, i, false, iter)
eq(ipos[1], p.pos.row)
eq(ipos[2], p.pos.col)
local k = lib.marktree_itr_current(iter)
eq(ipos[1], k.pos.row)
eq(ipos[2], k.pos.col, ipos[1])
lib.marktree_itr_next(tree, iter)
-- TODO(bfredl): use id2pos to check neighbour?
-- local k2 = lib.marktree_itr_current(iter)
end
for i, ipos in pairs(shadow) do
lib.marktree_itr_get(tree, ipos[1], ipos[2], iter)
local k = lib.marktree_itr_current(iter)
eq(i, tonumber(k.id))
eq(ipos[1], k.pos.row)
eq(ipos[2], k.pos.col)
end
ok(lib.marktree_itr_first(tree, iter))
local del = lib.marktree_itr_current(iter)
lib.marktree_del_itr(tree, iter, false)
shadow[tonumber(del.id)] = nil
shadoworder(tree, shadow, iter)
for _, ci in ipairs({ 0, -1, 1, -2, 2, -10, 10 }) do
for i = 1, 100 do
lib.marktree_itr_get(tree, i, 50 + ci, iter)
local k = lib.marktree_itr_current(iter)
local id = tonumber(k.id)
eq(shadow[id][1], k.pos.row)
eq(shadow[id][2], k.pos.col)
lib.marktree_del_itr(tree, iter, false)
shadow[id] = nil
end
lib.marktree_check(tree)
shadoworder(tree, shadow, iter)
end
-- NB: this is quite rudimentary. We rely on
-- functional tests exercising splicing quite a bit
lib.marktree_check(tree)
dosplice(tree, shadow, { 2, 2 }, { 0, 5 }, { 1, 2 })
lib.marktree_check(tree)
shadoworder(tree, shadow, iter)
dosplice(tree, shadow, { 30, 2 }, { 30, 5 }, { 1, 2 })
lib.marktree_check(tree)
shadoworder(tree, shadow, iter)
dosplice(tree, shadow, { 5, 3 }, { 0, 2 }, { 0, 5 })
shadoworder(tree, shadow, iter)
lib.marktree_check(tree)
-- build then burn (HOORAY! HOORAY!)
while next(shadow) do
lib.marktree_itr_first(tree, iter)
-- delete every other key for fun and profit
while true do
local k = lib.marktree_itr_current(iter)
lib.marktree_del_itr(tree, iter, false)
ok(shadow[tonumber(k.id)] ~= nil)
shadow[tonumber(k.id)] = nil
local stat = lib.marktree_itr_next(tree, iter)
if not stat then
break
end
end
lib.marktree_check(tree)
shadoworder(tree, shadow, iter2)
end
-- Check iterator validity for 2 specific edge cases:
-- https://github.com/neovim/neovim/pull/14719
lib.marktree_clear(tree)
for i = 1, 20 do
put(tree, i, i, false)
end
lib.marktree_itr_get(tree, 10, 10, iter)
lib.marktree_del_itr(tree, iter, false)
eq(11, iter[0].x.key[iter[0].i].pos.col)
lib.marktree_itr_get(tree, 11, 11, iter)
lib.marktree_del_itr(tree, iter, false)
eq(12, iter[0].x.key[iter[0].i].pos.col)
end)
itp("'intersect_mov' function works correctly", function()
local function mov(x, y, w)
local xa = ffi.new('uint64_t[?]', #x)
for i, xi in ipairs(x) do
xa[i - 1] = xi
end
local ya = ffi.new('uint64_t[?]', #y)
for i, yi in ipairs(y) do
ya[i - 1] = yi
end
local wa = ffi.new('uint64_t[?]', #w)
for i, wi in ipairs(w) do
wa[i - 1] = wi
end
local dummy_size = #x + #y + #w
local wouta = ffi.new('uint64_t[?]', dummy_size)
local douta = ffi.new('uint64_t[?]', dummy_size)
local wsize = ffi.new('size_t[1]')
wsize[0] = dummy_size
local dsize = ffi.new('size_t[1]')
dsize[0] = dummy_size
local status = lib.intersect_mov_test(xa, #x, ya, #y, wa, #w, wouta, wsize, douta, dsize)
if status == 0 then
error 'wowza'
end
local wout, dout = {}, {}
for i = 0, tonumber(wsize[0]) - 1 do
table.insert(wout, tonumber(wouta[i]))
end
for i = 0, tonumber(dsize[0]) - 1 do
table.insert(dout, tonumber(douta[i]))
end
return { wout, dout }
end
eq({ {}, {} }, mov({}, { 2, 3 }, { 2, 3 }))
eq({ { 2, 3 }, {} }, mov({}, {}, { 2, 3 }))
eq({ { 2, 3 }, {} }, mov({ 2, 3 }, {}, {}))
eq({ {}, { 2, 3 } }, mov({}, { 2, 3 }, {}))
eq({ { 1, 5 }, {} }, mov({ 1, 2, 5 }, { 2, 3 }, { 3 }))
eq({ { 1, 2 }, {} }, mov({ 1, 2, 5 }, { 5, 10 }, { 10 }))
eq({ { 1, 2 }, { 5 } }, mov({ 1, 2 }, { 5, 10 }, { 10 }))
eq({ { 1, 3, 5, 7, 9 }, { 2, 4, 6, 8, 10 } }, mov({ 1, 3, 5, 7, 9 }, { 2, 4, 6, 8, 10 }, {}))
eq({ { 1, 3, 5, 7, 9 }, { 2, 6, 10 } }, mov({ 1, 3, 5, 7, 9 }, { 2, 4, 6, 8, 10 }, { 4, 8 }))
eq({ { 1, 4, 7 }, { 2, 5, 8 } }, mov({ 1, 3, 4, 6, 7, 9 }, { 2, 3, 5, 6, 8, 9 }, {}))
eq({ { 1, 4, 7 }, {} }, mov({ 1, 3, 4, 6, 7, 9 }, { 2, 3, 5, 6, 8, 9 }, { 2, 5, 8 }))
eq(
{ { 0, 1, 4, 7, 10 }, {} },
mov({ 1, 3, 4, 6, 7, 9 }, { 2, 3, 5, 6, 8, 9 }, { 0, 2, 5, 8, 10 })
)
end)
local function check_intersections(tree)
lib.marktree_check(tree)
-- to debug stuff disable this branch
if true == true then
ok(lib.marktree_check_intersections(tree))
return
end
local str1 = lib.mt_inspect(tree, true, true)
local dot1 = ffi.string(str1.data, str1.size)
local val = lib.marktree_check_intersections(tree)
if not val then
local str2 = lib.mt_inspect(tree, true, true)
local dot2 = ffi.string(str2.data, str2.size)
print('actual:\n\n' .. 'Xafile.dot' .. '\n\nexpected:\n\n' .. 'Xefile.dot' .. '\n')
print('nivå', tree[0].root.level)
io.stdout:flush()
local afil = io.open('Xafile.dot', 'wb')
afil:write(dot1)
afil:close()
local efil = io.open('Xefile.dot', 'wb')
efil:write(dot2)
efil:close()
ok(false)
else
ffi.C.xfree(str1.data)
end
end
itp('works with intersections', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
local ids = {}
for i = 1, 80 do
table.insert(ids, put(tree, 1, i, false, 2, 100 - i, false))
check_intersections(tree)
end
for i = 1, 80 do
lib.marktree_del_pair_test(tree, ns, ids[i])
check_intersections(tree)
end
ids = {}
for i = 1, 80 do
table.insert(ids, put(tree, 1, i, false, 2, 100 - i, false))
check_intersections(tree)
end
for i = 1, 10 do
for j = 1, 8 do
local ival = (j - 1) * 10 + i
lib.marktree_del_pair_test(tree, ns, ids[ival])
check_intersections(tree)
end
end
end)
itp('works with intersections with a big tree', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
local ids = {}
for i = 1, 1000 do
table.insert(ids, put(tree, 1, i, false, 2, 1000 - i, false))
if i % 10 == 1 then
check_intersections(tree)
end
end
check_intersections(tree)
eq(2000, tree[0].n_keys)
ok(tree[0].root.level >= 2)
local iter = ffi.new('MarkTreeIter[1]')
local k = 0
for i = 1, 20 do
for j = 1, 50 do
k = k + 1
local ival = (j - 1) * 20 + i
if false == true then -- if there actually is a failure, this branch will fail out at the actual spot of the error
lib.marktree_lookup_ns(tree, ns, ids[ival], false, iter)
lib.marktree_del_itr(tree, iter, false)
check_intersections(tree)
lib.marktree_lookup_ns(tree, ns, ids[ival], true, iter)
lib.marktree_del_itr(tree, iter, false)
check_intersections(tree)
else
lib.marktree_del_pair_test(tree, ns, ids[ival])
if k % 5 == 1 then
check_intersections(tree)
end
end
end
end
eq(0, tree[0].n_keys)
end)
itp('works with intersections and marktree_splice', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
for i = 1, 1000 do
put(tree, 1, i, false, 2, 1000 - i, false)
if i % 10 == 1 then
check_intersections(tree)
end
end
check_intersections(tree)
eq(2000, tree[0].n_keys)
ok(tree[0].root.level >= 2)
for _ = 1, 10 do
lib.marktree_splice(tree, 0, 0, 0, 100, 0, 0)
check_intersections(tree)
end
end)
itp('marktree_move should preserve key order', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
local iter = ffi.new('MarkTreeIter[1]')
local ids = {}
-- new index and old index look the same, but still have to move because
-- pos will get updated
table.insert(ids, put(tree, 1, 1, false, 1, 3, false))
table.insert(ids, put(tree, 1, 3, false, 1, 3, false))
table.insert(ids, put(tree, 1, 3, false, 1, 3, false))
table.insert(ids, put(tree, 1, 3, false, 1, 3, false))
lib.marktree_lookup_ns(tree, ns, ids[3], false, iter)
lib.marktree_move(tree, iter, 1, 2)
check_intersections(tree)
end)
itp('works with intersections and marktree_move', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
local ids = {}
for i = 1, 1000 do
table.insert(ids, put(tree, 1, i, false, 2, 1000 - i, false))
if i % 10 == 1 then
check_intersections(tree)
end
end
local iter = ffi.new('MarkTreeIter[1]')
for i = 1, 1000 do
local which = i % 2
lib.marktree_lookup_ns(tree, ns, ids[i], which, iter)
lib.marktree_move(tree, iter, 1 + which, 500 + i)
if i % 10 == 1 then
check_intersections(tree)
end
end
end)
itp('works with intersections with a even bigger tree', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
local ids = {}
-- too much overhead on ASAN
local size_factor = helpers.is_asan() and 3 or 10
local at_row = {}
for i = 1, 10 do
at_row[i] = {}
end
local size = 1000 * size_factor
local k = 1
while k <= size do
for row1 = 1, 9 do
for row2 = row1, 10 do -- note row2 can be == row1, leads to empty ranges being tested when k > size/2
if k > size then
break
end
local id = put(tree, row1, k, false, row2, size - k, false)
table.insert(ids, id)
for i = row1 + 1, row2 do
table.insert(at_row[i], id)
end
--if tree[0].root.level == 4 then error("kk"..k) end
if k % 100 * size_factor == 1 or (k < 2000 and k % 100 == 1) then
check_intersections(tree)
end
k = k + 1
end
end
end
eq(2 * size, tree[0].n_keys)
ok(tree[0].root.level >= 3)
check_intersections(tree)
local iter = ffi.new('MarkTreeIter[1]')
local pair = ffi.new('MTPair[1]')
for i = 1, 10 do
-- use array as set and not {[id]=true} map, to detect duplicates
local set = {}
eq(true, ffi.C.marktree_itr_get_overlap(tree, i, 0, iter))
while ffi.C.marktree_itr_step_overlap(tree, iter, pair) do
local id = tonumber(pair[0].start.id)
table.insert(set, id)
end
table.sort(set)
eq(at_row[i], set)
end
k = 0
for i = 1, 100 do
for j = 1, (10 * size_factor) do
k = k + 1
local ival = (j - 1) * 100 + i
lib.marktree_del_pair_test(tree, ns, ids[ival])
-- just a few stickprov, if there is trouble we need to check
-- everyone using the code in the "big tree" case above
if k % 100 * size_factor == 0 or (k > 3000 and k % 200 == 0) then
check_intersections(tree)
end
end
end
eq(0, tree[0].n_keys)
end)
itp('works with intersections with a even bigger tree and splice', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
-- too much overhead on ASAN
local size_factor = helpers.is_asan() and 3 or 10
local at_row = {}
for i = 1, 10 do
at_row[i] = {}
end
local size = 1000 * size_factor
local k = 1
while k <= size do
for row1 = 1, 9 do
for row2 = row1, 10 do -- note row2 can be == row1, leads to empty ranges being tested when k > size/2
if k > size then
break
end
local id = put(tree, row1, k, false, row2, size - k, false)
for i = row1 + 1, row2 do
table.insert(at_row[i], id)
end
--if tree[0].root.level == 4 then error("kk"..k) end
if k % 100 * size_factor == 1 or (k < 2000 and k % 100 == 1) then
check_intersections(tree)
end
k = k + 1
end
end
end
eq(2 * size, tree[0].n_keys)
ok(tree[0].root.level >= 3)
check_intersections(tree)
for _ = 1, 10 do
for j = 3, 8 do
lib.marktree_splice(tree, j, 0, 0, 200, 0, 0)
check_intersections(tree)
end
end
end)
itp('works with meta counts', function()
local tree = ffi.new('MarkTree[1]') -- zero initialized by luajit
-- add
local shadow = {}
for i = 1, 100 do
for j = 1, 100 do
local gravitate = (i % 2) > 0
local inline = (j == 3 or j == 50 or j == 51 or j == 55) and i % 11 == 1
inline = inline or ((j >= 80 and j < 85) and i % 3 == 1)
local id = put_meta(tree, j, i, gravitate, inline)
if inline then
shadow[id] = { j, i, gravitate }
end
end
-- checking every insert is too slow, but this is ok
lib.marktree_check(tree)
end
lib.marktree_check(tree)
local iter = ffi.new('MarkTreeIter[1]')
local filter = ffi.new('uint32_t[4]')
filter[0] = -1
ok(lib.marktree_itr_get_filter(tree, 0, 0, 101, 0, filter, iter))
local seen = {}
repeat
local mark = lib.marktree_itr_current(iter)
eq(nil, seen[mark.id])
seen[mark.id] = true
eq(mark.pos.row, shadow[mark.id][1])
eq(mark.pos.col, shadow[mark.id][2])
until not lib.marktree_itr_next_filter(tree, iter, 101, 0, filter)
eq(tablelength(seen), tablelength(shadow))
-- test skipping subtrees to find the filtered mark at line 50
for i = 4, 50 do
ok(lib.marktree_itr_get_filter(tree, i, 0, 60, 0, filter, iter))
local mark = lib.marktree_itr_current(iter)
eq({ 50, 50, 1 }, { mark.id, mark.pos.row, mark.pos.col })
end
-- delete
for id = 1, 10000, 2 do
lib.marktree_lookup_ns(tree, ns, id, false, iter)
if shadow[id] then
local mark = lib.marktree_itr_current(iter)
eq(mark.pos.row, shadow[id][1])
eq(mark.pos.col, shadow[id][2])
shadow[id] = nil
end
lib.marktree_del_itr(tree, iter, false)
if id % 100 == 1 then
lib.marktree_check(tree)
end
end
-- Splice!
dosplice(tree, shadow, { 82, 0 }, { 0, 50 }, { 0, 0 })
lib.marktree_check(tree)
dosplice(tree, shadow, { 81, 50 }, { 2, 50 }, { 1, 0 })
lib.marktree_check(tree)
dosplice(tree, shadow, { 2, 50 }, { 1, 50 }, { 0, 10 })
lib.marktree_check(tree)
ok(lib.marktree_itr_get_filter(tree, 0, 0, 101, 0, filter, iter))
seen = {}
repeat
local mark = lib.marktree_itr_current(iter)
eq(nil, seen[mark.id])
seen[mark.id] = true
eq(mark.pos.row, shadow[mark.id][1])
eq(mark.pos.col, shadow[mark.id][2])
until not lib.marktree_itr_next_filter(tree, iter, 101, 0, filter)
eq(tablelength(seen), tablelength(shadow))
end)
end)