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-rw-r--r--lib/percept/src/egd_render.erl664
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diff --git a/lib/percept/src/egd_render.erl b/lib/percept/src/egd_render.erl
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-%%
-%% %CopyrightBegin%
-%%
-%% Copyright Ericsson AB 2008-2016. All Rights Reserved.
-%%
-%% Licensed under the Apache License, Version 2.0 (the "License");
-%% you may not use this file except in compliance with the License.
-%% You may obtain a copy of the License at
-%%
-%% http://www.apache.org/licenses/LICENSE-2.0
-%%
-%% Unless required by applicable law or agreed to in writing, software
-%% distributed under the License is distributed on an "AS IS" BASIS,
-%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
-%% See the License for the specific language governing permissions and
-%% limitations under the License.
-%%
-%% %CopyrightEnd%
-
-%%
-%% @doc egd_render
-%%
-
--module(egd_render).
-
--export([binary/1, binary/2]).
--export([eps/1]).
--compile(inline).
-
--export([line_to_linespans/3]).
-
--include("egd.hrl").
--define('DummyC',0).
-
-binary(Image) ->
- binary(Image, opaque).
-
-binary(Image, Type) ->
- parallel_binary(precompile(Image),Type).
-
-parallel_binary(Image = #image{ height = Height },Type) ->
- case erlang:min(erlang:system_info(schedulers), Height) of
- 1 ->
- % if the height or the number of schedulers is 1
- % do the scanlines in this process.
- W = Image#image.width,
- Bg = Image#image.background,
- Os = Image#image.objects,
- erlang:list_to_binary([scanline(Y, Os, {0,0,W - 1, Bg}, Type)
- || Y <- lists:seq(1, Height)]);
- Np ->
- Pids = start_workers(Np, Type),
- Handler = handle_workers(Height, Pids),
- init_workers(Image, Handler, Pids),
- Res = receive_binaries(Height),
- finish_workers(Pids),
- Res
- end.
-
-start_workers(Np, Type) ->
- start_workers(Np, Type, []).
-
-start_workers( 0, _, Pids) -> Pids;
-start_workers(Np, Type, Pids) when Np > 0 ->
- start_workers(Np - 1, Type, [spawn_link(fun() -> worker(Type) end)|Pids]).
-
-worker(Type) ->
- receive
- {Pid, data, #image{ objects = Os, width = W, background = Bg }} ->
- worker(Os, W, Bg, Type, Pid)
- end.
-
-worker(Objects, Width, Bg, Type, Collector) ->
- receive
- {Pid, scan, {Ys, Ye}} ->
- lists:foreach(fun
- (Y) ->
- Bin = erlang:list_to_binary(scanline(Y, Objects, {0,0,Width - 1, Bg}, Type)),
- Collector ! {scan, Y, Bin}
- end, lists:seq(Ys,Ye)),
- Pid ! {self(), scan_complete},
- worker(Objects, Width, Bg, Type, Collector);
- {Pid, scan, Y} ->
- Bin = erlang:list_to_binary(scanline(Y, Objects, {0,0,Width - 1, Bg}, Type)),
- Collector ! {scan, Y, Bin},
- Pid ! {self(), scan_complete},
- worker(Objects, Width, Bg, Type, Collector);
- {_, done} ->
- ok
- end.
-
-init_workers(_Image, _Handler, []) -> ok;
-init_workers(Image, Handler, [Pid|Pids]) ->
- Pid ! {self(), data, Image},
- Handler ! {Pid, scan_complete},
- init_workers(Image, Handler, Pids).
-
-handle_workers(H, Pids) ->
- spawn_link(fun() -> handle_workers(H, H, length(Pids)) end).
-
-handle_workers(_, 0, _) -> ok;
-handle_workers(H, Hi, Np) when H > 0 ->
- N = trunc(Hi/(2*Np)),
- receive
- {Pid, scan_complete} ->
- if N < 2 ->
- Pid ! {self(), scan, Hi},
- handle_workers(H, Hi - 1, Np);
- true ->
- Pid ! {self(), scan, {Hi - N, Hi}},
- handle_workers(H, Hi - 1 - N, Np)
- end
- end.
-
-finish_workers([]) -> ok;
-finish_workers([Pid|Pids]) ->
- Pid ! {self(), done},
- finish_workers(Pids).
-
-receive_binaries(H) ->
- receive_binaries(H, []).
-
-receive_binaries(0, Bins) -> erlang:list_to_binary(Bins);
-receive_binaries(H, Bins) when H > 0 ->
- receive
- {scan, H, Bin} ->
- receive_binaries(H - 1, [Bin|Bins])
- end.
-
-scanline(Y, Os, {_,_,Width,_}=LSB, Type) ->
- OLSs = parse_objects_on_line(Y-1, Width, Os),
- RLSs = resulting_line_spans([LSB|OLSs],Type),
- [ lists:duplicate(Xr - Xl + 1, <<(trunc(R*255)):8,(trunc(G*255)):8,(trunc(B*255)):8>>) || {_,Xl, Xr, {R,G,B,_}} <- RLSs ].
-
-resulting_line_spans(LSs,Type) ->
- %% Build a list of "transitions" from left to right.
- Trans = line_spans_to_trans(LSs),
- %% Convert list of "transitions" to linespans.
- trans_to_line_spans(Trans,Type).
-
-line_spans_to_trans(LSs) ->
- line_spans_to_trans(LSs,[],0).
-
-line_spans_to_trans([],Db,_) ->
- lists:sort(Db);
-line_spans_to_trans([{_,L,R,C}|LSs],Db,Z) ->
- line_spans_to_trans(LSs,[{{L,Z,start},C},{{R+1,Z,stop},C}|Db],Z+1).
-
-trans_to_line_spans(Trans,Type) ->
- trans_to_line_spans(simplify_trans(Trans,Type,[],{0.0,0.0,0.0,0.0},[])).
-
-trans_to_line_spans(SimpleTrans) ->
- trans_to_line_spans1(SimpleTrans,[]).
-
-trans_to_line_spans1([],Spans) ->
- Spans;
-trans_to_line_spans1([_],Spans) ->
- Spans;
-trans_to_line_spans1([{L1,_},{L2,C2}|SimpleTrans],Spans) ->
- %% We are going backwards now...
- trans_to_line_spans1([{L2,C2}|SimpleTrans],[{?DummyC,L2,L1-1,C2}|Spans]).
-
-simplify_trans([],_,_,_,Acc) ->
- Acc;
-simplify_trans([{{L,_,_},_}|_] = Trans,Type,Layers,OldC,Acc) ->
- {NextTrans,RestTrans} =
- lists:splitwith(fun({{L1,_,_},_}) when L1 == L ->
- true;
- (_) ->
- false
- end, Trans),
- {C,NewLayers} = color(NextTrans,Layers,Type,OldC),
- case OldC of
- C -> %% No change in color, so transition unnecessary.
- simplify_trans(RestTrans,Type,NewLayers,OldC,Acc);
- _ ->
- simplify_trans(RestTrans,Type,NewLayers,C,[{L,C}|Acc])
- end.
-
-color(Trans,Layers,Type,OldC) ->
- case modify_layers(Layers,Trans) of
- Layers ->
- {OldC,Layers};
- NewLayers ->
- {color(NewLayers,Type),NewLayers}
- end.
-
-color([],_) -> {0.0,0.0,0.0,0.0};
-color([{_,C}|_],opaque) -> C;
-color(Layers,alpha) -> color1({0.0,0.0,0.0,0.0},Layers).
-
-color1(Color,[]) -> Color;
-color1(Color,[{_,C}|Layers]) -> color1(alpha_blend(Color,C),Layers).
-
-modify_layers(Layers,[]) -> Layers;
-modify_layers(Layers,[{{_,Z,start},C}|Trans]) ->
- modify_layers(add_layer(Layers, Z, C), Trans);
-modify_layers(Layers,[{{_,Z,stop },C}|Trans]) ->
- modify_layers(remove_layer(Layers, Z, C), Trans).
-
-add_layer([{Z1,_}=H|Layers],Z,C) when Z1 > Z ->
- [H|add_layer(Layers,Z,C)];
-add_layer(Layers,Z,C) ->
- [{Z,C}|Layers].
-
-remove_layer(Layers,Z,C) ->
- Layers -- [{Z,C}].
-
-alpha_blend({R1,G1,B1,A1}, {R2,G2,B2,A2}) when is_float(A1), is_float(A2)->
- Beta = A2*(1.0 - A1),
- A = A1 + Beta,
- R = R1*A1 + R2*Beta,
- G = G1*A1 + G2*Beta,
- B = B1*A1 + B2*Beta,
- {R,G,B,A}.
-
-parse_objects_on_line(Y, Width, Objects) ->
- parse_objects_on_line(Y, 1, Width, Objects, []).
-parse_objects_on_line(_Y, _Z, _, [], Out) -> lists:flatten(Out);
-parse_objects_on_line(Y, Z, Width, [O|Os], Out) ->
- case is_object_on_line(O, Y) of
- false ->
- parse_objects_on_line(Y, Z + 1, Width, Os, Out);
- true ->
- OLs = object_line_data(O,Y,Z),
- TOLs = trim_object_line_data(OLs, Width),
- parse_objects_on_line(Y, Z + 1, Width, Os, [TOLs|Out])
- end.
-
-trim_object_line_data(OLs, Width) ->
- trim_object_line_data(OLs, Width, []).
-trim_object_line_data([], _, Out) -> Out;
-
-trim_object_line_data([{_, Xl, _, _}|OLs], Width, Out) when Xl > Width ->
- trim_object_line_data(OLs, Width, Out);
-trim_object_line_data([{_, _, Xr, _}|OLs], Width, Out) when Xr < 0 ->
- trim_object_line_data(OLs, Width, Out);
-trim_object_line_data([{Z, Xl, Xr, C}|OLs], Width, Out) ->
- trim_object_line_data(OLs, Width, [{Z, erlang:max(0,Xl), erlang:min(Xr,Width), C}|Out]).
-
-% object_line_data
-% In:
-% Object :: image_object()
-% Y :: index of height
-% Z :: index of depth
-% Out:
-% OLs = [{Z, Xl, Xr, Color}]
-% Z = index of height
-% Xl = left X index
-% Xr = right X index
-% Purpose:
-% Calculate the length (start and finish index) of an objects horizontal
-% line given the height index.
-
-object_line_data(#image_object{type=rectangle,
- span={X0,Y0,X1,Y1}, color=C}, Y, Z) ->
- if
- Y0 =:= Y ; Y1 =:= Y ->
- [{Z, X0, X1, C}];
- true ->
- [{Z, X0, X0, C},
- {Z, X1, X1, C}]
- end;
-
-object_line_data(#image_object{type=filled_rectangle,
- span={X0, _, X1, _}, color=C}, _Y, Z) ->
- [{Z, X0, X1, C}];
-
-object_line_data(#image_object{type=filled_ellipse,
- internals={Xr,Yr,Yr2}, span={X0,Y0,X1,Y1}, color=C}, Y, Z) ->
- if
- X1 - X0 =:= 0; Y1 - Y0 =:= 0 ->
- [{Z, X0, X1, C}];
- true ->
- Yo = trunc(Y - Y0 - Yr),
- Yo2 = Yo*Yo,
- Xo = math:sqrt((1 - Yo2/Yr2))*Xr,
- [{Z, round(X0 - Xo + Xr), round(X0 + Xo + Xr), C}]
- end;
-
-object_line_data(#image_object{type=filled_triangle,
- intervals=Is, color=C}, Y, Z) ->
- case lists:keyfind(Y, 1, Is) of
- {Y, Xl, Xr} -> [{Z, Xl, Xr, C}];
- false -> []
- end;
-
-object_line_data(#image_object{type=line,
- intervals=M, color={R,G,B,_}}, Y, Z) ->
- case M of
- #{Y := Ls} -> [{Z, Xl, Xr, {R,G,B,1.0-C/255}}||{Xl,Xr,C} <- Ls];
- _ -> []
- end;
-
-object_line_data(#image_object{type=polygon,
- color=C, intervals=Is}, Y, Z) ->
- [{Z, Xl, Xr, C} || {Yp, Xl, Xr} <- Is, Yp =:= Y];
-
-object_line_data(#image_object{type=text_horizontal,
- color=C, intervals=Is}, Y, Z) ->
- [{Z, Xl, Xr, C} || {Yg, Xl, Xr} <- Is, Yg =:= Y];
-
-object_line_data(#image_object{type=pixel,
- span={X0,_,X1,_}, color=C}, _, Z) ->
- [{Z, X0, X1, C}].
-
-is_object_on_line(#image_object{span={_,Y0,_,Y1}}, Y) ->
- if Y < Y0; Y > Y1 -> false;
- true -> true
- end.
-
-%%% primitives to line_spans
-
-%% compile objects to linespans
-
-precompile(#image{objects = Os}=I) ->
- I#image{objects = precompile_objects(Os)}.
-
-precompile_objects([]) -> [];
-precompile_objects([#image_object{type=line, internals=W, points=[P0,P1]}=O|Os]) ->
- [O#image_object{intervals = linespans_to_map(line_to_linespans(P0,P1,W))}|precompile_objects(Os)];
-precompile_objects([#image_object{type=filled_triangle, points=[P0,P1,P2]}=O|Os]) ->
- [O#image_object{intervals = triangle_ls(P0,P1,P2)}|precompile_objects(Os)];
-precompile_objects([#image_object{type=polygon, points=Pts}=O|Os]) ->
- [O#image_object{intervals = polygon_ls(Pts)}|precompile_objects(Os)];
-precompile_objects([#image_object{type=filled_ellipse, span={X0,Y0,X1,Y1}}=O|Os]) ->
- Xr = (X1 - X0)/2,
- Yr = (Y1 - Y0)/2,
- Yr2 = Yr*Yr,
- [O#image_object{internals={Xr,Yr,Yr2}}|precompile_objects(Os)];
-precompile_objects([#image_object{type=arc, points=[P0,P1], internals=D}=O|Os]) ->
- Es = egd_primitives:arc_to_edges(P0, P1, D),
- Ls = lists:foldl(fun ({Ep0,Ep1},M) ->
- linespans_to_map(line_to_linespans(Ep0,Ep1,1),M)
- end, #{}, Es),
- [O#image_object{type=line, intervals=Ls}|precompile_objects(Os)];
-precompile_objects([#image_object{type=text_horizontal,
- points=[P0], internals={Font,Text}}=O|Os]) ->
- [O#image_object{intervals=text_horizontal_ls(P0,Font,Text)}|precompile_objects(Os)];
-precompile_objects([O|Os]) ->
- [O|precompile_objects(Os)].
-
-% triangle
-
-triangle_ls(P1,P2,P3) ->
- % Find top point (or left most top point),
- % From that point, two lines will be drawn to the
- % other points.
- % For each Y step,
- % bresenham_line_interval for each of the two lines
- % Find the left most and the right most for those lines
- % At an end point, a new line to the point already being drawn
- % repeat same procedure as above
- [Sp1, Sp2, Sp3] = tri_pt_ysort([P1,P2,P3]),
- triangle_ls_lp(tri_ls_ysort(line_to_linespans(Sp1,Sp2,1)), Sp2,
- tri_ls_ysort(line_to_linespans(Sp1,Sp3,1)), Sp3, []).
-
-% There will be Y mismatches between the two lists since bresenham is not perfect.
-% I can be remedied with checking intervals this could however be costly and
-% it may not be necessary, depending on how exact we need the points to be.
-% It should at most differ by one and endpoints should be fine.
-
-triangle_ls_lp([],_,[],_,Out) -> Out;
-triangle_ls_lp(LSs1, P1, [], P2, Out) ->
- SLSs = tri_ls_ysort(line_to_linespans(P2,P1,1)),
- N2 = length(SLSs),
- N1 = length(LSs1),
- if
- N1 > N2 ->
- [_|ILSs] = LSs1,
- triangle_ls_lp(ILSs, SLSs, Out);
- N2 > N1 ->
- [_|ILSs] = SLSs,
- triangle_ls_lp(LSs1, ILSs, Out);
- true ->
- triangle_ls_lp(LSs1, SLSs, Out)
- end;
-triangle_ls_lp([], P1, LSs2, P2, Out) ->
- SLSs = tri_ls_ysort(line_to_linespans(P1,P2,1)),
- N1 = length(SLSs),
- N2 = length(LSs2),
- if
- N1 > N2 ->
- [_|ILSs] = SLSs,
- triangle_ls_lp(ILSs, LSs2, Out);
- N2 > N1 ->
- [_|ILSs] = LSs2,
- triangle_ls_lp(SLSs, ILSs, Out);
- true ->
- triangle_ls_lp(SLSs, LSs2, Out)
- end;
-triangle_ls_lp([LS1|LSs1],P1,[LS2|LSs2],P2, Out) ->
- {Y, Xl1, Xr1,_Ca1} = LS1,
- {_, Xl2, Xr2,_Ca2} = LS2,
- Xr = lists:max([Xl1,Xr1,Xl2,Xr2]),
- Xl = lists:min([Xl1,Xr1,Xl2,Xr2]),
- triangle_ls_lp(LSs1,P1,LSs2,P2,[{Y,Xl,Xr}|Out]).
-
-triangle_ls_lp([],[],Out) -> Out;
-triangle_ls_lp([],_,Out) -> Out;
-triangle_ls_lp(_,[],Out) -> Out;
-triangle_ls_lp([LS1|LSs1], [LS2|LSs2], Out) ->
- {Y, Xl1, Xr1, _Ca1} = LS1,
- {_, Xl2, Xr2, _Ca2} = LS2,
- Xr = lists:max([Xl1,Xr1,Xl2,Xr2]),
- Xl = lists:min([Xl1,Xr1,Xl2,Xr2]),
- triangle_ls_lp(LSs1,LSs2,[{Y,Xl,Xr}|Out]).
-
-tri_pt_ysort(Pts) ->
- % {X,Y}
- lists:sort(
- fun ({_,Y1},{_,Y2}) ->
- if Y1 > Y2 -> false; true -> true end
- end, Pts).
-
-tri_ls_ysort(LSs) ->
- % {Y, Xl, Xr, Ca}
- lists:sort(
- fun ({Y1,_,_,_},{Y2,_,_,_}) ->
- if Y1 > Y2 -> false; true -> true end
- end, LSs).
-
-% polygon_ls
-% In:
-% Pts :: [{X,Y}]
-% Out:
-% LSs :: [{Y,Xl,Xr}]
-% Purpose:
-% Make polygon line spans
-% Algorithm:
-% 1. Find the left most (lm) point
-% 2. Find the two points adjacent to that point
-% The tripplet will make a triangle
-% 3. Ensure no points lies within the triangle
-% 4a.No points within triangle,
-% make triangle,
-% remove lm point
-% 1.
-% 4b.point(s) within triangle,
-%
-
-
-polygon_ls(Pts) ->
- % Make triangles
- Tris = polygon_tri(Pts),
- % interval triangles
- lists:flatten(polygon_tri_ls(Tris, [])).
-
-polygon_tri_ls([], Out) -> Out;
-polygon_tri_ls([{P1,P2,P3}|Tris], Out) ->
- polygon_tri_ls(Tris, [triangle_ls(P1,P2,P3)|Out]).
-
-polygon_tri(Pts) ->
- polygon_tri(polygon_lm_pt(Pts), []).
-
-
-polygon_tri([P1,P2,P3],Tris) -> [{P1,P2,P3}|Tris];
-polygon_tri([P2,P1,P3|Pts], Tris) ->
- case polygon_tri_test(P1,P2,P3,Pts) of
- false -> polygon_tri(polygon_lm_pt([P2,P3|Pts]), [{P1,P2,P3}|Tris]);
- [LmPt|Ptsn] -> polygon_tri([P2,P1,LmPt,P3|Ptsn], Tris)
- end.
-
-polygon_tri_test(P1,P2,P3, Pts) ->
- polygon_tri_test(P1,P2,P3, Pts, []).
-
-polygon_tri_test(_,_,_, [], _) -> false;
-polygon_tri_test(P1,P2,P3,[Pt|Pts], Ptsr) ->
- case point_inside_triangle(Pt, P1,P2,P3) of
- false -> polygon_tri_test(P1,P2,P3, Pts, [Pt|Ptsr]);
- true -> [Pt|Pts] ++ lists:reverse(Ptsr)
- end.
-
-% polygon_lm_pt
-% In:
-% Pts :: [{X,Y}]
-% Out
-% LmPts = [{X0,Y0},{Xmin,Y0},{X1,Y1},...]
-% Purpose:
-% The order of the list is important
-% rotate the elements until Xmin is first
-% This is not extremly fast.
-
-polygon_lm_pt(Pts) ->
- Xs = [X||{X,_}<-Pts],
- polygon_lm_pt(Pts, lists:min(Xs), []).
-
-polygon_lm_pt([Pt0,{X,_}=Ptm | Pts], Xmin, Ptsr) when X > Xmin ->
- polygon_lm_pt([Ptm|Pts], Xmin, [Pt0|Ptsr]);
-polygon_lm_pt(Pts, _, Ptsr) ->
- Pts ++ lists:reverse(Ptsr).
-
-
-% return true if P is inside triangle (p1,p2,p3),
-% otherwise false.
-
-points_same_side({P1x,P1y}, {P2x,P2y}, {L1x,L1y}, {L2x,L2y}) ->
- ((P1x - L1x)*(L2y - L1y) - (L2x - L1x)*(P1y - L1y) *
- (P2x - L1x)*(L2y - L1y) - (L2x - L1x)*(P2y - L1y)) >= 0.
-
-point_inside_triangle(P, P1, P2, P3) ->
- points_same_side(P, P1, P2, P3) and
- points_same_side(P, P2, P1, P3) and
- points_same_side(P, P3, P1, P2).
-
-%% [{Y, Xl, Xr}] -> #{Y := [{Xl,Xr}]}
-%% Reorganize linspans to a map with Y as key.
-
-linespans_to_map(Ls) ->
- linespans_to_map(Ls,#{}).
-linespans_to_map([{Y,Xl,Xr,C}|Ls], M) ->
- case M of
- #{Y := Spans} -> linespans_to_map(Ls, M#{Y := [{Xl,Xr,C}|Spans]});
- _ -> linespans_to_map(Ls, M#{Y => [{Xl,Xr,C}]})
- end;
-linespans_to_map([], M) ->
- M.
-
-
-%% line_to_linespans
-%% Anti-aliased thick line
-%% Do it CPS style
-%% In:
-%% P1 :: point()
-%% P2 :: point()
-%% Out:
-%% [{Y,Xl,Xr}]
-%%
-line_to_linespans({X0,Y0},{X1,Y1},Wd) ->
- Dx = abs(X1-X0),
- Dy = abs(Y1-Y0),
- Sx = if X0 < X1 -> 1; true -> -1 end,
- Sy = if Y0 < Y1 -> 1; true -> -1 end,
- E0 = Dx - Dy,
- Ed = if Dx + Dy =:= 0 -> 1; true -> math:sqrt(Dx*Dx + Dy*Dy) end,
- line_to_ls(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E0,Ed,(Wd+1)/2,[]).
-
-line_to_ls(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0) ->
- C = max(0, 255*(abs(E - Dx+Dy)/Ed - Wd + 1)),
- Ls1 = [{Y0,X0,X0,C}|Ls0],
- line_to_ls_sx(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls1,E).
-
-line_to_ls_sx(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls,E2) when 2*E2 > -Dx ->
- line_to_ls_sx_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls,E2+Dy,Y0);
-line_to_ls_sx(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls,E2) ->
- line_to_ls_sy(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls,E2,X0).
-
-line_to_ls_sx_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0,E2,Y) when E2 < Ed*Wd andalso
- (Y1 =/= Y orelse Dx > Dy) ->
- Y2 = Y + Sy,
- C = max(0,255*(abs(E2)/Ed-Wd+1)),
- Ls = [{Y2,X0,X0,C}|Ls0],
- line_to_ls_sx_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls,E2+Dx,Y2);
-line_to_ls_sx_do(X0,_Y0,X1,_Y1,_Dx,_Dy,_Sx,_Sy,_E,_Ed,_Wd,Ls,_E2,_Y) when X0 =:= X1 ->
- Ls;
-line_to_ls_sx_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls,_E2,_Y) ->
- line_to_ls_sy(X0+Sx,Y0,X1,Y1,Dx,Dy,Sx,Sy,E-Dy,Ed,Wd,Ls,E,X0).
-
-line_to_ls_sy(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0,E2,X) when 2*E2 =< Dy ->
- line_to_ls_sy_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0,Dx-E2,X);
-line_to_ls_sy(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0,_E2,_X) ->
- line_to_ls(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0).
-
-line_to_ls_sy_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0,E2,X) when E2 < Ed*Wd andalso
- (X1 =/= X orelse Dx < Dy) ->
- X2 = X + Sx,
- C = max(0,255*(abs(E2)/Ed-Wd+1)),
- Ls = [{Y0,X2,X2,C}|Ls0],
- line_to_ls_sy_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls,E2+Dy,X2);
-line_to_ls_sy_do(_X0,Y0,_X1,Y1,_Dx,_Dy,_Sx,_Sy,_E,_Ed,_Wd,Ls,_E2,_X) when Y0 =:= Y1 ->
- Ls;
-line_to_ls_sy_do(X0,Y0,X1,Y1,Dx,Dy,Sx,Sy,E,Ed,Wd,Ls0,_E2,_X) ->
- line_to_ls(X0,Y0+Sy,X1,Y1,Dx,Dy,Sx,Sy,E+Dx,Ed,Wd,Ls0).
-
-% Text
-
-text_horizontal_ls(Point, Font, Chars) ->
- {_Fw,Fh} = egd_font:size(Font),
- text_intervals(Point, Fh, Font, Chars, []).
-
-% This is stupid. The starting point is the top left (Ptl) but the font
-% offsets is relative to the bottom right origin,
-% {Xtl,Ytl} -------------------------
-% | |
-% | Glyph BoundingBox |
-% | -------- |
-% | |Bitmap| Gh |
-% FH |-Gx0-|Data | |
-% | -------- |
-% | | |
-% | Gy0 |
-% | | |
-% Glyph (0,0)------------------------- Gxm (Glyph X move)
-% FW
-% Therefore, we need Yo, which is Yo = FH - Gy0 - Gh,
-% Font height minus Glyph Y offset minus Glyph bitmap data boundingbox
-% height.
-
-text_intervals( _, _, _, [], Out) -> lists:flatten(Out);
-text_intervals({Xtl,Ytl}, Fh, Font, [Code|Chars], Out) ->
- {{_Gw, Gh, Gx0, Gy0, Gxm}, LSs} = egd_font:glyph(Font, Code),
- % Set offset points from translation matrix to point in TeInVe.
- Yo = Fh - Gh + Gy0,
- GLSs = text_intervals_vertical({Xtl+Gx0,Ytl+Yo},LSs, []),
- text_intervals({Xtl+Gxm,Ytl}, Fh, Font, Chars, [GLSs|Out]).
-
-text_intervals_vertical( _, [], Out) -> Out;
-text_intervals_vertical({Xtl, Ytl}, [LS|LSs], Out) ->
- H = lists:foldl(
- fun ({Xl,Xr}, RLSs) ->
- [{Ytl, Xl + Xtl, Xr + Xtl}|RLSs]
- end, [], LS),
- text_intervals_vertical({Xtl, Ytl+1}, LSs, [H|Out]).
-
-
-%%% E. PostScript implementation
-
-eps(#image{ objects = Os, width = W, height = H}) ->
- list_to_binary([eps_header(W,H),eps_objects(H,Os),eps_footer()]).
-
-eps_objects(H,Os) -> eps_objects(H,Os, []).
-eps_objects(_,[], Out) -> lists:flatten(Out);
-eps_objects(H,[O|Os], Out) -> eps_objects(H,Os, [eps_object(H,O)|Out]).
-
-eps_object(H,#image_object{ type = text_horizontal, internals = {_Font,Text}, points = [{X,Y}], color={R,G,B,_}}) ->
- s("/Times-Roman findfont\n14 scalefont\nsetfont\n~.4f ~.4f ~.4f setrgbcolor\nnewpath\n~p ~p moveto\n(~s) show~n",
- [R,G,B,X,H-(Y + 10), Text]);
-eps_object(H,#image_object{ type = filled_ellipse, points = [{X1,Y1p},{X2,Y2p}], color={R,G,B,_}}) ->
- Y1 = H - Y1p,
- Y2 = H - Y2p,
- Xr = trunc((X2-X1)/2),
- Yr = trunc((Y2-Y1)/2),
- Cx = X1 + Xr,
- Cy = Y1 + Yr,
- s("~.4f ~.4f ~.4f setrgbcolor\nnewpath\n~p ~p ~p ~p 0 360 ellipse fill\n",
- [R,G,B,Cx,Cy,Xr,Yr]);
-eps_object(H,#image_object{ type = arc, points = [P0, P1], internals = D, color={R,G,B,_}}) ->
- Es = egd_primitives:arc_to_edges(P0, P1, D),
- [s("~.4f ~.4f ~.4f setrgbcolor\n", [R,G,B])|lists:foldl(fun
- ({{X1,Y1},{X2,Y2}}, Eps) ->
- [s("newpath\n~p ~p moveto\n~p ~p lineto\n1 setlinewidth\nstroke\n", [X1,H-Y1,X2,H-Y2])|Eps]
- end, [], Es)];
-
-eps_object(H,#image_object{ type = line, points = [{X1,Y1}, {X2,Y2}], color={R,G,B,_}}) ->
- s("~.4f ~.4f ~.4f setrgbcolor\nnewpath\n~p ~p moveto\n~p ~p lineto\n1 setlinewidth\nstroke\n",
- [R,G,B,X1,H-Y1,X2,H-Y2]);
-eps_object(H,#image_object{ type = rectangle, points = [{X1,Y1}, {X2,Y2}], color={R,G,B,_}}) ->
- s("~.4f ~.4f ~.4f setrgbcolor\nnewpath\n~p ~p moveto\n~p ~p lineto\n~p ~p lineto\n~p ~p lineto\n~p ~p lineto\n1 setlinewidth\nstroke\n",
- [R,G,B,X1,H-Y1,X2,H-Y1,X2,H-Y2,X1,H-Y2,X1,H-Y1]);
-eps_object(H,#image_object{ type = filled_rectangle, points = [{X1,Y1}, {X2,Y2}], color={R,G,B,_}}) ->
- s("~.4f ~.4f ~.4f setrgbcolor\nnewpath\n~p ~p moveto\n~p ~p lineto\n~p ~p lineto\n~p ~p lineto\n~p ~p lineto\nclosepath\nfill\n",
- [R,G,B,X1,H-Y1,X2,H-Y1,X2,H-Y2,X1,H-Y2,X1,H-Y1]);
-eps_object(_,_) -> "".
-
-s(Format, Terms) -> lists:flatten(io_lib:format(Format, Terms)).
-
-eps_header(W,H) ->
- s("%!PS-Adobe-3.0 EPSF-3.0\n%%Creator: Created by egd\n%%BoundingBox: 0 0 ~p ~p\n%%LanguageLevel: 2\n%%Pages: 1\n%%DocumentData: Clean7Bit\n",[W,H]) ++
- "%%BeginProlog\n/ellipse {7 dict begin\n/endangle exch def\n/startangle exch def\n/yradius exch def\n/xradius exch def\n/yC exch def\n/xC exch def\n"
- "/savematrix matrix currentmatrix def\nxC yC translate\nxradius yradius scale\n0 0 1 startangle endangle arc\nsavematrix setmatrix\nend\n} def\n"
- "%%EndProlog\n".
-
-eps_footer() ->
- "%%EOF\n".