447 lines
14 KiB
PL/PgSQL
447 lines
14 KiB
PL/PgSQL
\set ON_ERROR_STOP on
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SET plpgsql.extra_errors TO 'all';
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-- detect_bends detects bends using the inflection angles. No corrections.
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drop function if exists detect_bends;
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create function detect_bends(line geometry, dbgname text default null, OUT bends geometry[]) as $$
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declare
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pi constant real default radians(180);
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p geometry;
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p1 geometry;
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p2 geometry;
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p3 geometry;
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bend geometry;
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prev_sign int4;
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cur_sign int4;
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l_type text;
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begin
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l_type = st_geometrytype(line);
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if l_type != 'ST_LineString' then
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raise 'This function works with ST_LineString, got %', l_type;
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end if;
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-- The last vertex is iterated over twice, because the algorithm uses 3
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-- vertices to calculate the angle between them.
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--
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-- Given 3 vertices p1, p2, p3:
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--
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-- p1___ ...
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-- /
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-- ... _____/
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-- p3 p2
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--
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-- When looping over the line, p1 will be head (lead) vertex, p2 will be the
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-- measured angle, and p3 will be trailing. The line that will be added to
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-- the bend will always be [p3,p2].
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-- So once the p1 becomes the last vertex, the loop terminates, and the
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-- [p2,p1] line will not have a chance to be added. So the loop adds the last
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-- vertex twice, so it has a chance to become p2, and be added to the bend.
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for p in (
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(select geom from st_dumppoints(line) order by path[1] asc)
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union all
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(select geom from st_dumppoints(line) order by path[1] desc limit 1)
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) loop
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p3 = p2;
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p2 = p1;
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p1 = p;
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continue when p3 is null;
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cur_sign = sign(pi - st_angle(p1, p2, p2, p3));
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if bend is null then
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bend = st_makeline(p3, p2);
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else
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bend = st_linemerge(st_union(bend, st_makeline(p3, p2)));
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end if;
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if prev_sign + cur_sign = 0 then
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if bend is not null then
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bends = bends || bend;
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end if;
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bend = st_makeline(p3, p2);
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end if;
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prev_sign = cur_sign;
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end loop;
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-- the last line may be lost if there is no "final" inflection angle. Add it.
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if (select count(1) >= 2 from st_dumppoints(bend)) then
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bends = bends || bend;
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end if;
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end
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$$ language plpgsql;
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-- fix_gentle_inflections moves bend endpoints following "Gentle Inflection at
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-- End of a Bend" section.
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--
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-- The text does not specify how many vertices can be "adjusted"; it can
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-- equally be one or many. This function is adjusting many, as long as the
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-- commulative inflection angle small (see variable below).
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--
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-- The implementation could be significantly optimized to avoid `st_reverse`
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-- and array reversals, trading for complexity in fix_gentle_inflections1.
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create or replace function fix_gentle_inflections(INOUT bends geometry[]) as $$
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declare
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len int4;
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bends1 geometry[];
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begin
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len = array_length(bends, 1);
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bends = fix_gentle_inflections1(bends);
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for i in 1..len loop
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bends1[i] = st_reverse(bends[len-i+1]);
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end loop;
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bends1 = fix_gentle_inflections1(bends1);
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for i in 1..len loop
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bends[i] = st_reverse(bends1[len-i+1]);
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end loop;
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end
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$$ language plpgsql;
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-- fix_gentle_inflections1 fixes gentle inflections of an array of lines in
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-- one direction. This is an implementation detail of fix_gentle_inflections.
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drop function if exists fix_gentle_inflections1;
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create function fix_gentle_inflections1(INOUT bends geometry[]) as $$
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declare
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pi constant real default radians(180);
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-- the threshold when the angle is still "small", so gentle inflections can
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-- be joined
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small_angle constant real default radians(45);
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ptail geometry; -- tail point of tail bend
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phead geometry[]; -- 3 tail points of head bend
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i int4; -- bends[i] is the current head
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begin
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for i in 2..array_length(bends, 1) loop
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-- Predicate: two bends will always share an edge. Assuming (A,B,C,D,E,F)
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-- is a bend:
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-- C________D
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-- / \
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-- \________/ \_______/
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-- A B E F
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--
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-- Then edges (A,B) and (E,F) are shared with the neighboring bends.
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--
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--
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-- Assume this curve (figure `inflection-1`), going clockwise from A:
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--
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-- \______B
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-- A `-------. C
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-- |
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-- G___ F |
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-- / `-----.____+ D
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-- E
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--
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-- After processing the curve following the definition of a bend, the bend
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-- [A-E] would be detected. Assuming inflection point E and F are "small",
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-- the bend needs to be extended by two edges to [A,G].
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select geom from st_dumppoints(bends[i-1])
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order by path[1] asc limit 1 into ptail;
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while true loop
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-- copy last 3 points of bends[i-1] (tail) to ptail
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select array(
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select geom from st_dumppoints(bends[i]) order by path[1] asc limit 3
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) into phead;
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-- if the bend got too short, stop processing it
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exit when array_length(phead, 1) < 3;
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-- inflection angle between ptail[1:3] is "large", stop processing
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exit when abs(st_angle(phead[1], phead[2], phead[3]) - pi) > small_angle;
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-- distance from head's 1st vertex should be larger than from 2nd vertex
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exit when st_distance(ptail, phead[2]) < st_distance(ptail, phead[3]);
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-- Detected a gentle inflection.
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-- Move head of the tail to the tail of head
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bends[i] = st_removepoint(bends[i], 0);
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bends[i-1] = st_addpoint(bends[i-1], phead[3]);
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end loop;
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end loop;
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end
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$$ language plpgsql;
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-- self_crossing eliminates self-crossing from the bends, following the
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-- article's section "Self-line Crossing When Cutting a Bend".
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drop function if exists self_crossing;
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create function self_crossing(
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INOUT bends geometry[],
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OUT mutated boolean
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) as $$
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declare
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pi constant real default radians(180);
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i int4;
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j int4;
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prev_length int4;
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a geometry;
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b geometry;
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multi geometry;
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begin
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mutated = false;
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-- go through the bends and find one where sum of inflection angle is >180
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for i in 1..array_length(bends, 1) loop
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continue when abs(inflection_angle(bends[i])) <= pi;
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-- sum of inflection angles for this bend is >180, so it may be
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-- self-crossing. now try to find another bend in this line that
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-- crosses an imaginary line of end-vertices
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-- go through each bend in the given line, and see if has a potential to
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-- cross bends[i]. optimization: we care only about bends which beginning
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-- and end start at different sides of the plane, separated by endpoints
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-- of the vertex.
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j = 0;
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while j < array_length(bends, 1) loop
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j = j + 1;
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continue when i = j;
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-- do end vertices of bend[i] cross bend[j]?
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a = st_pointn(bends[i], 1);
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b = st_pointn(bends[i], -1);
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multi = st_split(bends[j], st_makeline(a, b));
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continue when st_numgeometries(multi) = 1;
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continue when st_numgeometries(multi) = 2 and
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(st_contains(bends[j], a) or st_contains(bends[j], b));
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-- stars are aligned, we are changing the bend
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mutated = true;
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-- Sincere apologies to someone who will need to debug the block below.
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-- To understand it, I suggest you take a pencil and paper, draw a
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-- self-crossing bend (fig6 from the article works well), and figure out
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-- what happens here, by hand.
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prev_length = array_length(bends, 1);
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if j < i then
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-- remove first vertex of the following bend, because the last
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-- segment is always duplicated with the i-th bend.
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bends[i+1] = st_removepoint(bends[i+1], 0);
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bends[j] = st_geometryn(multi, 1);
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bends[j] = st_setpoint(
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bends[j],
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st_npoints(bends[j])-1,
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st_pointn(bends[i], st_npoints(bends[i]))
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);
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bends = bends[1:j] || bends[i+1:prev_length];
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j = i;
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else
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-- remove last vertex of the previous bend, because the last
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-- segment is duplicated with the i'th bend.
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bends[i-1] = st_removepoint(bends[i-1], st_npoints(bends[i-1])-1);
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bends[i] = st_makeline(
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st_pointn(bends[i], 1),
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st_removepoint(st_geometryn(multi, st_numgeometries(multi)), 0)
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);
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bends = bends[1:i] || bends[j+1:prev_length];
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end if;
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j = j - prev_length + array_length(bends, 1);
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end loop;
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end loop;
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end
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$$ language plpgsql;
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drop function if exists inflection_angle;
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create function inflection_angle (IN bend geometry, OUT angle real) as $$
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declare
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pi constant real default radians(180);
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p0 geometry;
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p1 geometry;
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p2 geometry;
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p3 geometry;
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begin
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angle = 0;
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for p0 in (select geom from st_dumppoints(bend) order by path[1] asc) loop
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p3 = p2;
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p2 = p1;
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p1 = p0;
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continue when p3 is null;
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angle = angle + abs(pi - st_angle(p1, p2, p3));
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end loop;
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end
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$$ language plpgsql;
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drop function if exists bend_attrs;
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drop function if exists isolated_bends;
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drop type if exists t_bend_attrs;
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create type t_bend_attrs as (
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bend geometry,
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area real,
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cmp real,
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adjsize real,
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baselinelength real,
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curvature real,
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isolated boolean
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);
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create function bend_attrs(bends geometry[], dbgname text default null) returns setof t_bend_attrs as $$
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declare
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fourpi constant real default 4*radians(180);
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i int4;
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polygon geometry;
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bend geometry;
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res t_bend_attrs;
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begin
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for i in 1..array_length(bends, 1) loop
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bend = bends[i];
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res = null;
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res.bend = bend;
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res.area = 0;
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res.cmp = 0;
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res.adjsize = 0;
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res.baselinelength = st_distance(st_startpoint(bend), st_endpoint(bend));
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res.curvature = inflection_angle(bend) / st_length(bend);
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res.isolated = false;
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if st_numpoints(bend) >= 3 then
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polygon = st_makepolygon(st_addpoint(bend, st_startpoint(bend)));
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-- Compactness Index (cmp) is defined as "the ratio of the area of the
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-- polygon over the circle whose circumference length is the same as the
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-- length of the circumference of the polygon". I assume they meant the
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-- area of the circle. So here goes:
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-- 1. get polygon area P.
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-- 2. get polygon perimeter = u. Pretend it's our circle's circumference.
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-- 3. get A (area) of the circle from u: A = (u^2)/(4*pi)
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-- 4. divide P by A: cmp = P/A = P/((u^2)*4*pi) = 4*pi*P/u^2
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res.area = st_area(polygon);
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res.cmp = fourpi*res.area/(st_perimeter(polygon)^2);
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if res.cmp > 0 then
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res.adjsize = (res.area*(0.75/res.cmp));
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end if;
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end if;
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if dbgname is not null then
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insert into wm_debug (stage, name, nbend, way, props) values(
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'ebendattrs',
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dbgname,
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i,
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bend,
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json_build_object(
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'area', res.area,
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'cmp', res.cmp,
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'adjsize', res.adjsize,
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'baselinelength', res.baselinelength,
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'curvature', res.curvature
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)
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);
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end if;
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return next res;
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end loop;
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end;
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$$ language plpgsql;
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create function isolated_bends(INOUT bendattrs t_bend_attrs[], dbgname text default null) as $$
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declare
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isolation_threshold constant real default 0.2; -- if neighbor's curvatures are within, it's isolated
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this real;
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res t_bend_attrs;
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i int4;
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begin
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i = 2;
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while i < array_length(bendattrs, 1)-1 loop
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this = bendattrs[i].curvature * isolation_threshold;
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if bendattrs[i-1].curvature < this and bendattrs[i+1].curvature < this then
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res = bendattrs[i];
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res.isolated = true;
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bendattrs[i] = res;
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i = i + 2;
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else
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i = i + 1;
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end if;
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end loop;
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end
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$$ language plpgsql;
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-- ST_SimplifyWM simplifies a given geometry using Wang & Müller's
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-- "Line Generalization Based on Analysis of Shape Characteristics" algorithm,
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-- 1998.
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drop function if exists ST_SimplifyWM;
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create function ST_SimplifyWM(geom geometry, dbgname text default null) returns geometry as $$
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declare
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stagenum integer;
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i integer;
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line geometry;
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lines geometry[];
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bends geometry[];
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bend_attrs t_bend_attrs[];
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mutated boolean;
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l_type text;
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begin
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l_type = st_geometrytype(geom);
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if l_type = 'ST_LineString' then
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lines = array[geom];
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elseif l_type = 'ST_MultiLineString' then
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lines = array((select a.geom from st_dump(geom) a order by path[1] asc));
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else
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raise 'Unknown geometry type %', l_type;
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end if;
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for i in 1..array_length(lines, 1) loop
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mutated = true;
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stagenum = 1;
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while mutated loop
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if dbgname is not null then
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insert into wm_debug (stage, name, gen, nbend, way) values(
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'afigures',
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dbgname,
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stagenum,
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i,
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lines[i]
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);
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end if;
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bends = detect_bends(lines[i]);
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if dbgname is not null then
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insert into wm_debug(stage, name, gen, nbend, way) values(
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'bbends',
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dbgname,
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stagenum,
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generate_subscripts(bends, 1),
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unnest(bends)
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);
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end if;
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bends = fix_gentle_inflections(bends);
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if dbgname is not null then
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insert into wm_debug(stage, name, gen, nbend, way) values(
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'cinflections',
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dbgname,
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stagenum,
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generate_subscripts(bends, 1),
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unnest(bends)
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);
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end if;
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select * from self_crossing(bends) into bends, mutated;
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if dbgname is not null then
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insert into wm_debug(stage, name, gen, nbend, way) values(
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'dcrossings',
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dbgname,
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stagenum,
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generate_subscripts(bends, 1),
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unnest(bends)
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);
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end if;
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if mutated then
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lines[i] = st_linemerge(st_union(bends));
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stagenum = stagenum + 1;
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continue;
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end if;
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-- self-crossing mutations are done, calculate bend properties
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bend_attrs = array((select bend_attrs(bends, dbgname)));
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end loop;
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end loop;
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if l_type = 'ST_LineString' then
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return st_linemerge(st_union(lines));
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elseif l_type = 'ST_MultiLineString' then
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return st_union(lines);
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end if;
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end
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$$ language plpgsql;
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