Looks like chained read/write isn't working

author: jbzdarkid <jbzdarkid@gmail.com> 2019-11-08 22:06:07 -0800
committer: jbzdarkid <jbzdarkid@gmail.com> 2019-11-08 22:06:07 -0800
commit: 4d55d7d9aad8d3c2bedec371c165bbb848c3786b (patch)
tree: 6d9c17bcc538a95c8edb28045e1f92d1a9a6177b /Source/Panel.cpp
parent: 0e6b61f87b676028fcfd75bbf576f48a0ef91632 (diff)
download: witness-tutorializer-4d55d7d9aad8d3c2bedec371c165bbb848c3786b.tar.gz
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1 files changed, 193 insertions, 144 deletions
diff --git a/Source/Panel.cpp b/Source/Panel.cpp
index 43e9763..b6f0403 100644
--- a/Source/Panel.cpp
+++ b/Source/Panel.cpp

@@ -1,108 +1,36 @@
 #include "Panel.h"
-#include "Random.h"
 #include "Memory.h"
-#include "Randomizer.h"
-#include <sstream>
 #pragma warning (disable:26451)
+#pragma warning (disable:26812)
-template <class T>
+PuzzleSerializer::PuzzleSerializer(const std::shared_ptr<Memory>& memory) : _memory(memory) {}
-int find(const std::vector<T> &data, T search, size_t startIndex = 0) {
-        for (size_t i=startIndex ; i<data.size(); i++) {
-                if (data[i] == search) return static_cast<int>(i);
-        }
-        return -1;
-}
-Panel::Panel(const std::shared_ptr<Memory>& memory, int id) : _memory(memory) {
-        _width = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_X, 1)[0] - 1;
-        _height = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_Y, 1)[0] - 1;
-        _grid.resize(_width);
-        for (auto& row : _grid) row.resize(_height);
-        ReadIntersections(id);
-        ReadDecorations(id);
-}
-void Panel::Write(int id) {
-        WriteIntersections(id);
-        WriteDecorations(id);
-        
-        _memory->WritePanelData<int>(id, GRID_SIZE_X, {(_width + 1)/2});
-        _memory->WritePanelData<int>(id, GRID_SIZE_Y, {(_height + 1)/2});
-}
-nlohmann::json Panel::Serialize() {
-        nlohmann::json puzzle = {
-                {"pillar", false},
-                {"dots", nlohmann::json::array()},
-                {"gaps", nlohmann::json::array()},
-                {"name", "Imported from The Witness :O"},
-                {"regionCache", nlohmann::json::object()},
-        };
-        if (_grid.empty()) return {};
-        puzzle["grid"] = nlohmann::json::array();
-        
-        for (int x=0; x<_width; x++) {
-                for (int y=0; y<_height; y++) {
-                        if (x%2 == 1 && y%2 == 1) {
-                                puzzle["grid"][x][y] = Decoration_to_json(_grid[x][y]);
-                        } else {
-                                if (_grid[x][y] & IntersectionFlags::HAS_DOT) {
-                                        puzzle["dots"].emplace_back(nlohmann::json({{"x", x}, {"y", y}}));
-                                }
-                                puzzle["grid"][x][y] = false;
-                        }
-                }
-        }
-        puzzle["startPoints"] = nlohmann::json::array();
-        for (auto [x, y] : _startpoints) {
-                nlohmann::json startPoint = {{"x", x}, {"y", y}};
-                puzzle["startPoints"].emplace_back(startPoint);
-        }
-        puzzle["endPoints"] = nlohmann::json::array();
-        for (Endpoint endpoint : _endpoints) {
-                puzzle["endPoints"].emplace_back(endpoint.to_json());
-        }
-        std::string out = puzzle.dump();
-        return puzzle;
-}
-void Panel::ReadDecorations(int id) {
+Puzzle PuzzleSerializer::ReadPuzzle(int id) {
-        int numDecorations = _memory->ReadPanelData<int>(id, NUM_DECORATIONS, 1)[0];
+    Puzzle p;
-        std::vector<int> decorations = _memory->ReadArray<int>(id, DECORATIONS, numDecorations);
+    p.width = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_X, 1)[0] - 1;
+    p.height = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_Y, 1)[0] - 1;
+    p.grid.resize(p.width);
+        for (auto& row : p.grid) row.resize(p.height);
-        for (int i=0; i<numDecorations; i++) {
+        ReadIntersections(p, id);
-                auto [x, y] = dloc_to_xy(i);
+        ReadDecorations(p, id);
-                _grid[x][y] = decorations[i];
-        }
-}
-void Panel::WriteDecorations(int id) {
-        std::vector<int> decorations;
-        for (int y=_height-2; y>0; y-=2) {
-                for (int x=1; x<_width - 1; x+=2) {
-                        decorations.push_back(_grid[x][y]);
-                }
-        }
-        _memory->WritePanelData<int>(id, NUM_DECORATIONS, {static_cast<int>(decorations.size())});
+    return p;
-        _memory->WriteArray<int>(id, DECORATIONS, decorations);
 }
-void Panel::ReadIntersections(int id) {
+void PuzzleSerializer::ReadIntersections(Puzzle& p, int id) {
        int numIntersections = _memory->ReadPanelData<int>(id, NUM_DOTS, 1)[0];
        std::vector<int> intersectionFlags = _memory->ReadArray<int>(id, DOT_FLAGS, numIntersections);
        int i = 0;
        for (;; i++) {
-                auto [x, y] = loc_to_xy(i);
+                auto [x, y] = loc_to_xy(p, i);
                if (y < 0) break;
-                if (intersectionFlags[i] & IntersectionFlags::IS_STARTPOINT) {
+                if (intersectionFlags[i] & Flags::IS_STARTPOINT) {
-                        _startpoints.push_back({x, y});
+            p.grid[x][y].start = true;
                }
+        p.grid[x][y].dot = FlagsToDot(intersectionFlags[i]);
        }
        int numConnections = _memory->ReadPanelData<int>(id, NUM_CONNECTIONS, 1)[0];
@@ -112,34 +40,32 @@ void Panel::ReadIntersections(int id) {
        // Iterate the remaining intersections (endpoints, dots, gaps)
        for (; i < numIntersections; i++) {
-                if (intersectionFlags[i] & IntersectionFlags::IS_ENDPOINT) {
+                if (intersectionFlags[i] & Flags::IS_ENDPOINT) {
                        for (int j=0; j<numConnections; j++) {
                                int location = 0;
                                if (connections_a[j] == i) location = connections_b[j];
                                if (connections_b[j] == i) location = connections_a[j];
                                if (location != 0) {
-                                        Endpoint::Direction dir;
+                                        auto [x, y] = loc_to_xy(p, location);
                                        if (intersections[2*i] < intersections[2*location]) { // Our (i) x coordinate is less than the target's (location)
-                                                dir = Endpoint::Direction::LEFT;
+                        p.grid[x][y].end = Cell::Dir::LEFT;
                                        } else if (intersections[2*i] > intersections[2*location]) {
-                                                dir = Endpoint::Direction::RIGHT;
+                        p.grid[x][y].end = Cell::Dir::RIGHT;
                                        } else if (intersections[2*i + 1] > intersections[2*location + 1]) { // y coordinate is 0 (bottom) 1 (top), so this check is reversed.
-                                                dir = Endpoint::Direction::UP;
+                        p.grid[x][y].end = Cell::Dir::UP;
                                        } else {
-                                                dir = Endpoint::Direction::DOWN;
+                        p.grid[x][y].end = Cell::Dir::DOWN;
                                        }
-                                        auto [x, y] = loc_to_xy(location);
-                                        _endpoints.push_back(Endpoint(x, y, dir));
                                        break;
                                }
                        }
-                } else if (intersectionFlags[i] & IntersectionFlags::HAS_DOT) {
+                } else if (intersectionFlags[i] & Flags::HAS_DOT) {
                        for (int j=0; j<numConnections; j++) {
                                int location = 0;
                                if (connections_a[j] == i) location = connections_b[j];
                                if (connections_b[j] == i) location = connections_a[j];
                                if (location != 0) {
-                                        auto [x, y] = loc_to_xy(location);
+                                        auto [x, y] = loc_to_xy(p, location);
                                        float x1 = intersections[2*i];
                                        float y1 = intersections[2*i+1];
                                        float x2 = intersections[2*location];
@@ -156,7 +82,7 @@ void Panel::ReadIntersections(int id) {
                                                y++;
                                        }
-                                        _grid[x][y] |= IntersectionFlags::HAS_DOT;
+                    p.grid[x][y].dot = FlagsToDot(intersectionFlags[i]);
                                        break;
                                }
                        }
@@ -164,72 +90,134 @@ void Panel::ReadIntersections(int id) {
        }       
 }
-void Panel::WriteIntersections(int id) {
+void PuzzleSerializer::ReadDecorations(Puzzle& p, int id) {
+        int numDecorations = _memory->ReadPanelData<int>(id, NUM_DECORATIONS, 1)[0];
+        std::vector<int> decorations = _memory->ReadArray<int>(id, DECORATIONS, numDecorations);
+    if (numDecorations != decorations.size()) return; // @Error!
+        for (int i=0; i<numDecorations; i++) {
+                auto [x, y] = dloc_to_xy(p, i);
+        auto d = std::make_shared<Decoration>();
+        p.grid[x][y].decoration = d;
+        d->type = static_cast<Shape>(decorations[i] & 0xFF00);
+        switch(d->type) {
+            case Shape::Poly:
+            case Shape::RPoly:
+            case Shape::Ylop:
+                d->polyshape = decorations[i] & 0xFFFF0000;
+                break;
+            case Shape::Triangle:
+                d->count = decorations[i] & 0x000F0000;
+                break;
+        }
+        d->color = static_cast<Color>(decorations[i] & 0xF);
+        }
+}
+void PuzzleSerializer::WritePuzzle(const Puzzle& p, int id) {
+        _memory->WritePanelData<int>(id, GRID_SIZE_X, {(p.width + 1)/2});
+        _memory->WritePanelData<int>(id, GRID_SIZE_Y, {(p.height + 1)/2});
+        WriteIntersections(p, id);
+        WriteDecorations(p, id);
+        _memory->WritePanelData<int>(id, NEEDS_REDRAW, {1});
+}
+void PuzzleSerializer::WriteIntersections(const Puzzle& p, int id) {
        std::vector<float> intersections;
        std::vector<int> intersectionFlags;
        std::vector<int> connections_a;
        std::vector<int> connections_b;
-        double min = 0.1;
+        float min = 0.1f;
-        double max = 0.9;
+        float max = 0.9f;
-        double width_interval = (max - min) / (_width/2);
+        float width_interval = (max - min) / (p.width/2);
-        double height_interval = (max - min) / (_height/2);
+        float height_interval = (max - min) / (p.height/2);
-        // TODO(future): Stop using push_back and set these into explicit locations, unrequires loop iteration order
+        // @Cleanup: If I write directly to locations, then I can remove this gross loop iterator.
-        for (int y=_height-1; y>=0; y-=2) {
+        for (int y=p.height-1; y>=0; y-=2) {
-                for (int x=0; x<_width; x+=2) {
+                for (int x=0; x<p.width; x+=2) {
                        intersections.push_back(static_cast<float>(min + (x/2) * width_interval));
                        intersections.push_back(static_cast<float>(max - (y/2) * height_interval));
                        int flags = 0;
-                        if (find(_startpoints, {x, y}) != -1) flags |= IntersectionFlags::IS_STARTPOINT;
+            if (p.grid[x][y].start) {
+                flags |= Flags::IS_STARTPOINT;
+            }
                        intersectionFlags.push_back(flags);
                        // Create connections for this intersection -- always write low -> high
                        if (y > 0) {
-                                connections_a.push_back(xy_to_loc(x, y-2));
+                                connections_a.push_back(xy_to_loc(p, x, y-2));
-                                connections_b.push_back(xy_to_loc(x, y));
+                                connections_b.push_back(xy_to_loc(p, x, y));
                        }
                        if (x > 0) {
-                                connections_a.push_back(xy_to_loc(x-2, y));
+                                connections_a.push_back(xy_to_loc(p, x-2, y));
-                                connections_b.push_back(xy_to_loc(x, y));
+                                connections_b.push_back(xy_to_loc(p, x, y));
                        }
                }
        }
-        for (Endpoint endpoint : _endpoints) {
+    for (int x=0; x<p.width; x++) {
-                connections_a.push_back(xy_to_loc(endpoint.GetX(), endpoint.GetY())); // Target to connect to
+        for (int y=0; y<p.height; y++) {
-                connections_b.push_back(static_cast<int>(intersectionFlags.size())); // This endpoint
+            if (p.grid[x][y].end == Cell::Dir::NONE) continue;
+            connections_a.push_back(xy_to_loc(p, x, y)); // Target to connect to
-                double xPos = min + (endpoint.GetX()/2) * width_interval;
+                    connections_b.push_back(static_cast<int>(intersectionFlags.size())); // This endpoint
-                double yPos = max - (endpoint.GetY()/2) * height_interval;
-                if (endpoint.GetDir()== Endpoint::Direction::LEFT) {
+                    float xPos = min + (x/2) * width_interval;
-                        xPos -= .05;
+                    float yPos = max - (y/2) * height_interval;
-                } else if (endpoint.GetDir() == Endpoint::Direction::RIGHT) {
+            switch (p.grid[x][y].end) {
-                        xPos += .05;
+                case Cell::Dir::LEFT:
-                } else if (endpoint.GetDir() == Endpoint::Direction::UP) {
+                                xPos -= .05f;
-                        yPos += .05; // Y position goes from 0 (bottom) to 1 (top), so this is reversed.
+                    break;
-                } else if (endpoint.GetDir() == Endpoint::Direction::DOWN) {
+                case Cell::Dir::RIGHT:
-                        yPos -= .05;
+                                xPos += .05f;
-                }
+                    break;
-                intersections.push_back(static_cast<float>(xPos));
+                case Cell::Dir::UP:
-                intersections.push_back(static_cast<float>(yPos));
+                                yPos += .05f; // Y position goes from 0 (bottom) to 1 (top), so this is reversed.
-                intersectionFlags.push_back(IntersectionFlags::IS_ENDPOINT);
+                    break;
-        }
+                case Cell::Dir::DOWN:
+                                yPos -= .05f;
+                    break;
+            }
+                    intersections.push_back(xPos);
+                    intersections.push_back(yPos);
+                    intersectionFlags.push_back(Flags::IS_ENDPOINT);
+        }
+    }
        // Dots
-        for (int y=0; y<_height; y++) {
+    for (int x=0; x<p.width; x++) {
-                for (int x=0; x<_width; x++) {
+        for (int y=0; y<p.height; y++) {
-                        if (!(_grid[x][y] & IntersectionFlags::HAS_DOT)) continue;
+                        if (p.grid[x][y].dot == Cell::Dot::NONE) continue;
                        if (x%2 == 1 && y%2 == 1) continue;
+            int flags = Flags::HAS_DOT;
+            switch (p.grid[x][y].dot) {
+                case Cell::Dot::BLACK:
+                    break;
+                case Cell::Dot::BLUE:
+                    flags |= DOT_IS_BLUE;
+                    break;
+                case Cell::Dot::YELLOW:
+                    flags |= DOT_IS_ORANGE;
+                    break;
+                case Cell::Dot::INVISIBLE:
+                    flags |= DOT_IS_INVISIBLE;
+                    break;
+            }
+            // Dot is already a point the grid, just overwrite the flags
                        if (x%2 == 0 && y%2 == 0) {
-                                intersectionFlags[xy_to_loc(x, y)] |= _grid[x][y];
+                                intersectionFlags[xy_to_loc(p, x, y)] |= flags;
                                continue;
                        }
+            // Else, we need to introduce a new segment
                        // Locate the segment we're breaking
                        for (int i=0; i<connections_a.size(); i++) {
-                                auto [x1, y1] = loc_to_xy(connections_a[i]);
+                                auto [x1, y1] = loc_to_xy(p, connections_a[i]);
-                                auto [x2, y2] = loc_to_xy(connections_b[i]);
+                                auto [x2, y2] = loc_to_xy(p, connections_b[i]);
                                if ((x1+1 == x && x2-1 == x && y1 == y && y2 == y) ||
                                        (y1+1 == y && y2-1 == y && x1 == x && x2 == x)) {
                                        int other_connection = connections_b[i];
@@ -241,21 +229,82 @@ void Panel::WriteIntersections(int id) {
                                }
                        }
                        // Add this dot to the end
-                        double xPos = min + (x/2.0) * width_interval;
+                        float xPos = min + (x/2.0f) * width_interval;
-                        double yPos = max - (y/2.0) * height_interval;
+                        float yPos = max - (y/2.0f) * height_interval;
-                        intersections.push_back(static_cast<float>(xPos));
+                        intersections.push_back(xPos);
-                        intersections.push_back(static_cast<float>(yPos));
+                        intersections.push_back(yPos);
-                        intersectionFlags.push_back(_grid[x][y]);
+            intersectionFlags.push_back(flags);
                }
        }
        _memory->WritePanelData<int>(id, NUM_DOTS, {static_cast<int>(intersectionFlags.size())});
        _memory->WriteArray<float>(id, DOT_POSITIONS, intersections);
        _memory->WriteArray<int>(id, DOT_FLAGS, intersectionFlags);
        _memory->WritePanelData<int>(id, NUM_CONNECTIONS, {static_cast<int>(connections_a.size())});
        _memory->WriteArray<int>(id, DOT_CONNECTION_A, connections_a);
        _memory->WriteArray<int>(id, DOT_CONNECTION_B, connections_b);
-        _memory->WritePanelData<int>(id, NEEDS_REDRAW, {1});
 }
+void PuzzleSerializer::WriteDecorations(const Puzzle& p, int id) {
+        std::vector<int> decorations;
+        for (int y=p.height-2; y>0; y-=2) {
+                for (int x=1; x<p.width-1; x+=2) {
+            auto d = p.grid[x][y].decoration;
+            if (d) {
+                decorations.push_back(d->color | d->type | d->count | d->polyshape);
+            } else {
+                decorations.push_back(0);
+            }
+                }
+        }
+        _memory->WritePanelData<int>(id, NUM_DECORATIONS, {static_cast<int>(decorations.size())});
+        _memory->WriteArray<int>(id, DECORATIONS, decorations);
+}
+std::tuple<int, int> PuzzleSerializer::loc_to_xy(const Puzzle& p, int location) {
+    int height2 = (p.height - 1) / 2;
+    int width2 = (p.width + 1) / 2;
+    int x = 2 * (location % width2);
+    int y = 2 * (height2 - location / width2);
+    return {x, y};
+}
+int PuzzleSerializer::xy_to_loc(const Puzzle& p, int x, int y) {
+    int height2 = (p.height - 1) / 2;
+    int width2 = (p.width + 1) / 2;
+    int rowsFromBottom = height2 - y/2;
+    return rowsFromBottom * width2 + x/2;
+}
+std::tuple<int, int> PuzzleSerializer::dloc_to_xy(const Puzzle& p, int location) {
+    int height2 = (p.height - 3) / 2;
+    int width2 = (p.width - 1) / 2;
+    int x = 2 * (location % width2) + 1;
+    int y = 2 * (height2 - location / width2) + 1;
+    return {x, y};
+}
+int PuzzleSerializer::xy_to_dloc(const Puzzle& p, int x, int y) {
+    int height2 = (p.height - 3) / 2;
+    int width2 = (p.width - 1) / 2;
+    int rowsFromBottom = height2 - (y - 1)/2;
+    return rowsFromBottom * width2 + (x - 1)/2;
+}
+Cell::Dot PuzzleSerializer::FlagsToDot(int flags) {
+    if (!(flags & Flags::HAS_DOT)) return Cell::Dot::NONE;
+    if (flags & Flags::DOT_IS_BLUE) {
+        return Cell::Dot::BLUE;
+    } else if (flags & Flags::DOT_IS_ORANGE) {
+        return Cell::Dot::YELLOW;
+    } else if (flags & Flags::DOT_IS_INVISIBLE) {
+        return Cell::Dot::INVISIBLE;
+    } else {
+        return Cell::Dot::BLACK;
+    }
+}
author	jbzdarkid <jbzdarkid@gmail.com>	2019-11-08 22:06:07 -0800
committer	jbzdarkid <jbzdarkid@gmail.com>	2019-11-08 22:06:07 -0800
commit	4d55d7d9aad8d3c2bedec371c165bbb848c3786b (patch)
tree	6d9c17bcc538a95c8edb28045e1f92d1a9a6177b /Source/Panel.cpp
parent	0e6b61f87b676028fcfd75bbf576f48a0ef91632 (diff)
download	witness-tutorializer-4d55d7d9aad8d3c2bedec371c165bbb848c3786b.tar.gz witness-tutorializer-4d55d7d9aad8d3c2bedec371c165bbb848c3786b.tar.bz2 witness-tutorializer-4d55d7d9aad8d3c2bedec371c165bbb848c3786b.zip

diff --git a/Source/Panel.cpp b/Source/Panel.cpp index 43e9763..b6f0403 100644 --- a/Source/Panel.cpp +++ b/Source/Panel.cpp
@@ -1,108 +1,36 @@
1	#include "Panel.h"	1	#include "Panel.h"
2	#include "Random.h"
3	#include "Memory.h"	2	#include "Memory.h"
4	#include "Randomizer.h"
5	#include <sstream>
6		3
7	#pragma warning (disable:26451)	4	#pragma warning (disable:26451)
		5	#pragma warning (disable:26812)
8		6
9	template <class T>	7	PuzzleSerializer::PuzzleSerializer(const std::shared_ptr<Memory>& memory) : _memory(memory) {}
10	int find(const std::vector<T> &data, T search, size_t startIndex = 0) {
11	for (size_t i=startIndex ; i<data.size(); i++) {
12	if (data[i] == search) return static_cast<int>(i);
13	}
14	return -1;
15	}
16
17	Panel::Panel(const std::shared_ptr<Memory>& memory, int id) : _memory(memory) {
18	_width = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_X, 1)[0] - 1;
19	_height = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_Y, 1)[0] - 1;
20	_grid.resize(_width);
21	for (auto& row : _grid) row.resize(_height);
22
23	ReadIntersections(id);
24	ReadDecorations(id);
25	}
26
27	void Panel::Write(int id) {
28	WriteIntersections(id);
29	WriteDecorations(id);
30
31	_memory->WritePanelData<int>(id, GRID_SIZE_X, {(_width + 1)/2});
32	_memory->WritePanelData<int>(id, GRID_SIZE_Y, {(_height + 1)/2});
33	}
34
35	nlohmann::json Panel::Serialize() {
36	nlohmann::json puzzle = {
37	{"pillar", false},
38	{"dots", nlohmann::json::array()},
39	{"gaps", nlohmann::json::array()},
40	{"name", "Imported from The Witness :O"},
41	{"regionCache", nlohmann::json::object()},
42	};
43	if (_grid.empty()) return {};
44	puzzle["grid"] = nlohmann::json::array();
45
46	for (int x=0; x<_width; x++) {
47	for (int y=0; y<_height; y++) {
48	if (x%2 == 1 && y%2 == 1) {
49	puzzle["grid"][x][y] = Decoration_to_json(_grid[x][y]);
50	} else {
51	if (_grid[x][y] & IntersectionFlags::HAS_DOT) {
52	puzzle["dots"].emplace_back(nlohmann::json({{"x", x}, {"y", y}}));
53	}
54	puzzle["grid"][x][y] = false;
55	}
56	}
57	}
58
59	puzzle["startPoints"] = nlohmann::json::array();
60	for (auto [x, y] : _startpoints) {
61	nlohmann::json startPoint = {{"x", x}, {"y", y}};
62	puzzle["startPoints"].emplace_back(startPoint);
63	}
64	puzzle["endPoints"] = nlohmann::json::array();
65	for (Endpoint endpoint : _endpoints) {
66	puzzle["endPoints"].emplace_back(endpoint.to_json());
67	}
68
69	std::string out = puzzle.dump();
70	return puzzle;
71	}
72		8
73	void Panel::ReadDecorations(int id) {	9	Puzzle PuzzleSerializer::ReadPuzzle(int id) {
74	int numDecorations = _memory->ReadPanelData<int>(id, NUM_DECORATIONS, 1)[0];	10	Puzzle p;
75	std::vector<int> decorations = _memory->ReadArray<int>(id, DECORATIONS, numDecorations);	11	p.width = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_X, 1)[0] - 1;
		12	p.height = 2 * _memory->ReadPanelData<int>(id, GRID_SIZE_Y, 1)[0] - 1;
		13	p.grid.resize(p.width);
		14	for (auto& row : p.grid) row.resize(p.height);
76		15
77	for (int i=0; i<numDecorations; i++) {	16	ReadIntersections(p, id);
78	auto [x, y] = dloc_to_xy(i);	17	ReadDecorations(p, id);
79	_grid[x][y] = decorations[i];
80	}
81	}
82
83	void Panel::WriteDecorations(int id) {
84	std::vector<int> decorations;
85	for (int y=_height-2; y>0; y-=2) {
86	for (int x=1; x<_width - 1; x+=2) {
87	decorations.push_back(_grid[x][y]);
88	}
89	}
90		18
91	_memory->WritePanelData<int>(id, NUM_DECORATIONS, {static_cast<int>(decorations.size())});	19	return p;
92	_memory->WriteArray<int>(id, DECORATIONS, decorations);
93	}	20	}
94		21
95	void Panel::ReadIntersections(int id) {	22	void PuzzleSerializer::ReadIntersections(Puzzle& p, int id) {
96	int numIntersections = _memory->ReadPanelData<int>(id, NUM_DOTS, 1)[0];	23	int numIntersections = _memory->ReadPanelData<int>(id, NUM_DOTS, 1)[0];
97	std::vector<int> intersectionFlags = _memory->ReadArray<int>(id, DOT_FLAGS, numIntersections);	24	std::vector<int> intersectionFlags = _memory->ReadArray<int>(id, DOT_FLAGS, numIntersections);
98		25
99	int i = 0;	26	int i = 0;
100	for (;; i++) {	27	for (;; i++) {
101	auto [x, y] = loc_to_xy(i);	28	auto [x, y] = loc_to_xy(p, i);
102	if (y < 0) break;	29	if (y < 0) break;
103	if (intersectionFlags[i] & IntersectionFlags::IS_STARTPOINT) {	30	if (intersectionFlags[i] & Flags::IS_STARTPOINT) {
104	_startpoints.push_back({x, y});	31	p.grid[x][y].start = true;
105	}	32	}
		33	p.grid[x][y].dot = FlagsToDot(intersectionFlags[i]);
106	}	34	}
107		35
108	int numConnections = _memory->ReadPanelData<int>(id, NUM_CONNECTIONS, 1)[0];	36	int numConnections = _memory->ReadPanelData<int>(id, NUM_CONNECTIONS, 1)[0];
@@ -112,34 +40,32 @@ void Panel::ReadIntersections(int id) {
112		40
113	// Iterate the remaining intersections (endpoints, dots, gaps)	41	// Iterate the remaining intersections (endpoints, dots, gaps)
114	for (; i < numIntersections; i++) {	42	for (; i < numIntersections; i++) {
115	if (intersectionFlags[i] & IntersectionFlags::IS_ENDPOINT) {	43	if (intersectionFlags[i] & Flags::IS_ENDPOINT) {
116	for (int j=0; j<numConnections; j++) {	44	for (int j=0; j<numConnections; j++) {
117	int location = 0;	45	int location = 0;
118	if (connections_a[j] == i) location = connections_b[j];	46	if (connections_a[j] == i) location = connections_b[j];
119	if (connections_b[j] == i) location = connections_a[j];	47	if (connections_b[j] == i) location = connections_a[j];
120	if (location != 0) {	48	if (location != 0) {
121	Endpoint::Direction dir;	49	auto [x, y] = loc_to_xy(p, location);
122	if (intersections[2i] < intersections[2location]) { // Our (i) x coordinate is less than the target's (location)	50	if (intersections[2i] < intersections[2location]) { // Our (i) x coordinate is less than the target's (location)
123	dir = Endpoint::Direction::LEFT;	51	p.grid[x][y].end = Cell::Dir::LEFT;
124	} else if (intersections[2i] > intersections[2location]) {	52	} else if (intersections[2i] > intersections[2location]) {
125	dir = Endpoint::Direction::RIGHT;	53	p.grid[x][y].end = Cell::Dir::RIGHT;
126	} else if (intersections[2i + 1] > intersections[2location + 1]) { // y coordinate is 0 (bottom) 1 (top), so this check is reversed.	54	} else if (intersections[2i + 1] > intersections[2location + 1]) { // y coordinate is 0 (bottom) 1 (top), so this check is reversed.
127	dir = Endpoint::Direction::UP;	55	p.grid[x][y].end = Cell::Dir::UP;
128	} else {	56	} else {
129	dir = Endpoint::Direction::DOWN;	57	p.grid[x][y].end = Cell::Dir::DOWN;
130	}	58	}
131	auto [x, y] = loc_to_xy(location);
132	_endpoints.push_back(Endpoint(x, y, dir));
133	break;	59	break;
134	}	60	}
135	}	61	}
136	} else if (intersectionFlags[i] & IntersectionFlags::HAS_DOT) {	62	} else if (intersectionFlags[i] & Flags::HAS_DOT) {
137	for (int j=0; j<numConnections; j++) {	63	for (int j=0; j<numConnections; j++) {
138	int location = 0;	64	int location = 0;
139	if (connections_a[j] == i) location = connections_b[j];	65	if (connections_a[j] == i) location = connections_b[j];
140	if (connections_b[j] == i) location = connections_a[j];	66	if (connections_b[j] == i) location = connections_a[j];
141	if (location != 0) {	67	if (location != 0) {
142	auto [x, y] = loc_to_xy(location);	68	auto [x, y] = loc_to_xy(p, location);
143	float x1 = intersections[2*i];	69	float x1 = intersections[2*i];
144	float y1 = intersections[2*i+1];	70	float y1 = intersections[2*i+1];
145	float x2 = intersections[2*location];	71	float x2 = intersections[2*location];
@@ -156,7 +82,7 @@ void Panel::ReadIntersections(int id) {
156	y++;	82	y++;
157	}	83	}
158		84
159	_grid[x][y] \|= IntersectionFlags::HAS_DOT;	85	p.grid[x][y].dot = FlagsToDot(intersectionFlags[i]);
160	break;	86	break;
161	}	87	}
162	}	88	}
@@ -164,72 +90,134 @@ void Panel::ReadIntersections(int id) {
164	}	90	}
165	}	91	}
166		92
167	void Panel::WriteIntersections(int id) {	93	void PuzzleSerializer::ReadDecorations(Puzzle& p, int id) {
		94	int numDecorations = _memory->ReadPanelData<int>(id, NUM_DECORATIONS, 1)[0];
		95	std::vector<int> decorations = _memory->ReadArray<int>(id, DECORATIONS, numDecorations);
		96	if (numDecorations != decorations.size()) return; // @Error!
		97
		98	for (int i=0; i<numDecorations; i++) {
		99	auto [x, y] = dloc_to_xy(p, i);
		100	auto d = std::make_shared<Decoration>();
		101	p.grid[x][y].decoration = d;
		102	d->type = static_cast<Shape>(decorations[i] & 0xFF00);
		103	switch(d->type) {
		104	case Shape::Poly:
		105	case Shape::RPoly:
		106	case Shape::Ylop:
		107	d->polyshape = decorations[i] & 0xFFFF0000;
		108	break;
		109	case Shape::Triangle:
		110	d->count = decorations[i] & 0x000F0000;
		111	break;
		112	}
		113	d->color = static_cast<Color>(decorations[i] & 0xF);
		114	}
		115	}
		116
		117	void PuzzleSerializer::WritePuzzle(const Puzzle& p, int id) {
		118	_memory->WritePanelData<int>(id, GRID_SIZE_X, {(p.width + 1)/2});
		119	_memory->WritePanelData<int>(id, GRID_SIZE_Y, {(p.height + 1)/2});
		120
		121	WriteIntersections(p, id);
		122	WriteDecorations(p, id);
		123
		124	_memory->WritePanelData<int>(id, NEEDS_REDRAW, {1});
		125	}
		126
		127	void PuzzleSerializer::WriteIntersections(const Puzzle& p, int id) {
168	std::vector<float> intersections;	128	std::vector<float> intersections;
169	std::vector<int> intersectionFlags;	129	std::vector<int> intersectionFlags;
170	std::vector<int> connections_a;	130	std::vector<int> connections_a;
171	std::vector<int> connections_b;	131	std::vector<int> connections_b;
172		132
173	double min = 0.1;	133	float min = 0.1f;
174	double max = 0.9;	134	float max = 0.9f;
175	double width_interval = (max - min) / (_width/2);	135	float width_interval = (max - min) / (p.width/2);
176	double height_interval = (max - min) / (_height/2);	136	float height_interval = (max - min) / (p.height/2);
177		137
178	// TODO(future): Stop using push_back and set these into explicit locations, unrequires loop iteration order	138	// @Cleanup: If I write directly to locations, then I can remove this gross loop iterator.
179	for (int y=_height-1; y>=0; y-=2) {	139	for (int y=p.height-1; y>=0; y-=2) {
180	for (int x=0; x<_width; x+=2) {	140	for (int x=0; x<p.width; x+=2) {
181	intersections.push_back(static_cast<float>(min + (x/2) * width_interval));	141	intersections.push_back(static_cast<float>(min + (x/2) * width_interval));
182	intersections.push_back(static_cast<float>(max - (y/2) * height_interval));	142	intersections.push_back(static_cast<float>(max - (y/2) * height_interval));
183	int flags = 0;	143	int flags = 0;
184	if (find(_startpoints, {x, y}) != -1) flags \|= IntersectionFlags::IS_STARTPOINT;	144	if (p.grid[x][y].start) {
		145	flags \|= Flags::IS_STARTPOINT;
		146	}
185	intersectionFlags.push_back(flags);	147	intersectionFlags.push_back(flags);
186		148
187	// Create connections for this intersection -- always write low -> high	149	// Create connections for this intersection -- always write low -> high
188	if (y > 0) {	150	if (y > 0) {
189	connections_a.push_back(xy_to_loc(x, y-2));	151	connections_a.push_back(xy_to_loc(p, x, y-2));
190	connections_b.push_back(xy_to_loc(x, y));	152	connections_b.push_back(xy_to_loc(p, x, y));
191	}	153	}
192	if (x > 0) {	154	if (x > 0) {
193	connections_a.push_back(xy_to_loc(x-2, y));	155	connections_a.push_back(xy_to_loc(p, x-2, y));
194	connections_b.push_back(xy_to_loc(x, y));	156	connections_b.push_back(xy_to_loc(p, x, y));
195	}	157	}
196	}	158	}
197	}	159	}
198		160
199	for (Endpoint endpoint : _endpoints) {	161	for (int x=0; x<p.width; x++) {
200	connections_a.push_back(xy_to_loc(endpoint.GetX(), endpoint.GetY())); // Target to connect to	162	for (int y=0; y<p.height; y++) {
201	connections_b.push_back(static_cast<int>(intersectionFlags.size())); // This endpoint	163	if (p.grid[x][y].end == Cell::Dir::NONE) continue;
202		164	connections_a.push_back(xy_to_loc(p, x, y)); // Target to connect to
203	double xPos = min + (endpoint.GetX()/2) * width_interval;	165	connections_b.push_back(static_cast<int>(intersectionFlags.size())); // This endpoint
204	double yPos = max - (endpoint.GetY()/2) * height_interval;	166
205	if (endpoint.GetDir()== Endpoint::Direction::LEFT) {	167	float xPos = min + (x/2) * width_interval;
206	xPos -= .05;	168	float yPos = max - (y/2) * height_interval;
207	} else if (endpoint.GetDir() == Endpoint::Direction::RIGHT) {	169	switch (p.grid[x][y].end) {
208	xPos += .05;	170	case Cell::Dir::LEFT:
209	} else if (endpoint.GetDir() == Endpoint::Direction::UP) {	171	xPos -= .05f;
210	yPos += .05; // Y position goes from 0 (bottom) to 1 (top), so this is reversed.	172	break;
211	} else if (endpoint.GetDir() == Endpoint::Direction::DOWN) {	173	case Cell::Dir::RIGHT:
212	yPos -= .05;	174	xPos += .05f;
213	}	175	break;
214	intersections.push_back(static_cast<float>(xPos));	176	case Cell::Dir::UP:
215	intersections.push_back(static_cast<float>(yPos));	177	yPos += .05f; // Y position goes from 0 (bottom) to 1 (top), so this is reversed.
216	intersectionFlags.push_back(IntersectionFlags::IS_ENDPOINT);	178	break;
217	}	179	case Cell::Dir::DOWN:
		180	yPos -= .05f;
		181	break;
		182	}
		183	intersections.push_back(xPos);
		184	intersections.push_back(yPos);
		185	intersectionFlags.push_back(Flags::IS_ENDPOINT);
		186	}
		187	}
218		188
219	// Dots	189	// Dots
220	for (int y=0; y<_height; y++) {	190	for (int x=0; x<p.width; x++) {
221	for (int x=0; x<_width; x++) {	191	for (int y=0; y<p.height; y++) {
222	if (!(_grid[x][y] & IntersectionFlags::HAS_DOT)) continue;	192	if (p.grid[x][y].dot == Cell::Dot::NONE) continue;
223	if (x%2 == 1 && y%2 == 1) continue;	193	if (x%2 == 1 && y%2 == 1) continue;
		194
		195	int flags = Flags::HAS_DOT;
		196	switch (p.grid[x][y].dot) {
		197	case Cell::Dot::BLACK:
		198	break;
		199	case Cell::Dot::BLUE:
		200	flags \|= DOT_IS_BLUE;
		201	break;
		202	case Cell::Dot::YELLOW:
		203	flags \|= DOT_IS_ORANGE;
		204	break;
		205	case Cell::Dot::INVISIBLE:
		206	flags \|= DOT_IS_INVISIBLE;
		207	break;
		208	}
		209
		210	// Dot is already a point the grid, just overwrite the flags
224	if (x%2 == 0 && y%2 == 0) {	211	if (x%2 == 0 && y%2 == 0) {
225	intersectionFlags[xy_to_loc(x, y)] \|= _grid[x][y];	212	intersectionFlags[xy_to_loc(p, x, y)] \|= flags;
226	continue;	213	continue;
227	}	214	}
228		215
		216	// Else, we need to introduce a new segment
229	// Locate the segment we're breaking	217	// Locate the segment we're breaking
230	for (int i=0; i<connections_a.size(); i++) {	218	for (int i=0; i<connections_a.size(); i++) {
231	auto [x1, y1] = loc_to_xy(connections_a[i]);	219	auto [x1, y1] = loc_to_xy(p, connections_a[i]);
232	auto [x2, y2] = loc_to_xy(connections_b[i]);	220	auto [x2, y2] = loc_to_xy(p, connections_b[i]);
233	if ((x1+1 == x && x2-1 == x && y1 == y && y2 == y) \|\|	221	if ((x1+1 == x && x2-1 == x && y1 == y && y2 == y) \|\|
234	(y1+1 == y && y2-1 == y && x1 == x && x2 == x)) {	222	(y1+1 == y && y2-1 == y && x1 == x && x2 == x)) {
235	int other_connection = connections_b[i];	223	int other_connection = connections_b[i];
@@ -241,21 +229,82 @@ void Panel::WriteIntersections(int id) {
241	}	229	}
242	}	230	}
243	// Add this dot to the end	231	// Add this dot to the end
244	double xPos = min + (x/2.0) * width_interval;	232	float xPos = min + (x/2.0f) * width_interval;
245	double yPos = max - (y/2.0) * height_interval;	233	float yPos = max - (y/2.0f) * height_interval;
246	intersections.push_back(static_cast<float>(xPos));	234	intersections.push_back(xPos);
247	intersections.push_back(static_cast<float>(yPos));	235	intersections.push_back(yPos);
248	intersectionFlags.push_back(_grid[x][y]);	236	intersectionFlags.push_back(flags);
249	}	237	}
250	}	238	}
251		239
252
253	_memory->WritePanelData<int>(id, NUM_DOTS, {static_cast<int>(intersectionFlags.size())});	240	_memory->WritePanelData<int>(id, NUM_DOTS, {static_cast<int>(intersectionFlags.size())});
254	_memory->WriteArray<float>(id, DOT_POSITIONS, intersections);	241	_memory->WriteArray<float>(id, DOT_POSITIONS, intersections);
255	_memory->WriteArray<int>(id, DOT_FLAGS, intersectionFlags);	242	_memory->WriteArray<int>(id, DOT_FLAGS, intersectionFlags);
256	_memory->WritePanelData<int>(id, NUM_CONNECTIONS, {static_cast<int>(connections_a.size())});	243	_memory->WritePanelData<int>(id, NUM_CONNECTIONS, {static_cast<int>(connections_a.size())});
257	_memory->WriteArray<int>(id, DOT_CONNECTION_A, connections_a);	244	_memory->WriteArray<int>(id, DOT_CONNECTION_A, connections_a);
258	_memory->WriteArray<int>(id, DOT_CONNECTION_B, connections_b);	245	_memory->WriteArray<int>(id, DOT_CONNECTION_B, connections_b);
259	_memory->WritePanelData<int>(id, NEEDS_REDRAW, {1});
260	}	246	}
261		247
		248	void PuzzleSerializer::WriteDecorations(const Puzzle& p, int id) {
		249	std::vector<int> decorations;
		250	for (int y=p.height-2; y>0; y-=2) {
		251	for (int x=1; x<p.width-1; x+=2) {
		252	auto d = p.grid[x][y].decoration;
		253	if (d) {
		254	decorations.push_back(d->color \| d->type \| d->count \| d->polyshape);
		255	} else {
		256	decorations.push_back(0);
		257	}
		258	}
		259	}
		260
		261	_memory->WritePanelData<int>(id, NUM_DECORATIONS, {static_cast<int>(decorations.size())});
		262	_memory->WriteArray<int>(id, DECORATIONS, decorations);
		263	}
		264
		265	std::tuple<int, int> PuzzleSerializer::loc_to_xy(const Puzzle& p, int location) {
		266	int height2 = (p.height - 1) / 2;
		267	int width2 = (p.width + 1) / 2;
		268
		269	int x = 2 * (location % width2);
		270	int y = 2 * (height2 - location / width2);
		271	return {x, y};
		272	}
		273
		274	int PuzzleSerializer::xy_to_loc(const Puzzle& p, int x, int y) {
		275	int height2 = (p.height - 1) / 2;
		276	int width2 = (p.width + 1) / 2;
		277
		278	int rowsFromBottom = height2 - y/2;
		279	return rowsFromBottom * width2 + x/2;
		280	}
		281
		282	std::tuple<int, int> PuzzleSerializer::dloc_to_xy(const Puzzle& p, int location) {
		283	int height2 = (p.height - 3) / 2;
		284	int width2 = (p.width - 1) / 2;
		285
		286	int x = 2 * (location % width2) + 1;
		287	int y = 2 * (height2 - location / width2) + 1;
		288	return {x, y};
		289	}
		290
		291	int PuzzleSerializer::xy_to_dloc(const Puzzle& p, int x, int y) {
		292	int height2 = (p.height - 3) / 2;
		293	int width2 = (p.width - 1) / 2;
		294
		295	int rowsFromBottom = height2 - (y - 1)/2;
		296	return rowsFromBottom * width2 + (x - 1)/2;
		297	}
		298
		299	Cell::Dot PuzzleSerializer::FlagsToDot(int flags) {
		300	if (!(flags & Flags::HAS_DOT)) return Cell::Dot::NONE;
		301	if (flags & Flags::DOT_IS_BLUE) {
		302	return Cell::Dot::BLUE;
		303	} else if (flags & Flags::DOT_IS_ORANGE) {
		304	return Cell::Dot::YELLOW;
		305	} else if (flags & Flags::DOT_IS_INVISIBLE) {
		306	return Cell::Dot::INVISIBLE;
		307	} else {
		308	return Cell::Dot::BLACK;
		309	}
		310	}