Try/catch, and select seed

author: jbzdarkid <jbzdarkid@gmail.com> 2019-11-24 12:28:53 -0800
committer: jbzdarkid <jbzdarkid@gmail.com> 2019-11-24 12:28:53 -0800
commit: 92084d06a5c87338cc988b5bc5868e617213e6b9 (patch)
tree: 314cbf8ee06821b9569a7b279bc39e2bf04abc87 /Source/PuzzleSerializer.cpp
parent: 6059a1d1b99186a28bcd3c60822bc8310724bfd4 (diff)
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1 files changed, 64 insertions, 56 deletions
diff --git a/Source/PuzzleSerializer.cpp b/Source/PuzzleSerializer.cpp
index fb4166b..3dffde1 100644
--- a/Source/PuzzleSerializer.cpp
+++ b/Source/PuzzleSerializer.cpp

@@ -8,73 +8,81 @@
 PuzzleSerializer::PuzzleSerializer(const std::shared_ptr<Memory>& memory) : _memory(memory) {}
 Puzzle PuzzleSerializer::ReadPuzzle(int id) {
-    int width = _memory->ReadEntityData<int>(id, GRID_SIZE_X, 1)[0];
-    int height = _memory->ReadEntityData<int>(id, GRID_SIZE_Y, 1)[0];
-    if (width == 0) width = height;
-    if (height == 0) height = width;
-    if (width < 0 || height < 0) return Puzzle(); // @Error: Grid size should be always positive? Looks like the starting panels break this rule, though.
-    _numGridLocations = width * height; // Highest location which represents a gridded intersection
-    _numIntersections = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];
-    _intersectionFlags = _memory->ReadArray<int>(id, DOT_FLAGS, _numIntersections);
-    int numConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];
-    _connectionsA = _memory->ReadArray<int>(id, DOT_CONNECTION_A, numConnections);
-    _connectionsB = _memory->ReadArray<int>(id, DOT_CONNECTION_B, numConnections);
-    _intersectionLocations = _memory->ReadArray<float>(id, DOT_POSITIONS, _numIntersections*2);
    Puzzle p;
-    p.NewGrid(width - 1, height - 1);
+    try {
-    ReadIntersections(p);
+        int width = _memory->ReadEntityData<int>(id, GRID_SIZE_X, 1)[0];
-    ReadExtras(p);
+        int height = _memory->ReadEntityData<int>(id, GRID_SIZE_Y, 1)[0];
-    ReadDecorations(p, id);
+        if (width == 0) width = height;
-    ReadSequence(p, id);
+        if (height == 0) height = width;
-    ReadSymmetry(p, id);
+        if (width < 0 || height < 0) return Puzzle(); // @Error: Grid size should be always positive? Looks like the starting panels break this rule, though.
+        _numGridLocations = width * height; // Highest location which represents a gridded intersection
+        _numIntersections = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];
+        _intersectionFlags = _memory->ReadArray<int>(id, DOT_FLAGS, _numIntersections);
+        int numConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];
+        _connectionsA = _memory->ReadArray<int>(id, DOT_CONNECTION_A, numConnections);
+        _connectionsB = _memory->ReadArray<int>(id, DOT_CONNECTION_B, numConnections);
+        _intersectionLocations = _memory->ReadArray<float>(id, DOT_POSITIONS, _numIntersections*2);
+        p.NewGrid(width - 1, height - 1);
+        ReadIntersections(p);
+        ReadExtras(p);
+        ReadDecorations(p, id);
+        ReadSequence(p, id);
+        ReadSymmetry(p, id);
+    } catch (MemoryException exc) {
+        MemoryException::HandleException(exc);
+    }
    return p;
 }
 void PuzzleSerializer::WritePuzzle(const Puzzle& p, int id) {
-    _intersectionFlags.clear();
+    try {
-    _connectionsA.clear();
+        _intersectionFlags.clear();
-    _connectionsB.clear();
+        _connectionsA.clear();
-    _intersectionLocations.clear();
+        _connectionsB.clear();
-    _extraLocations.clear();
+        _intersectionLocations.clear();
+        _extraLocations.clear();
-    MIN = 0.1f;
-    MAX = 0.9f;
+        MIN = 0.1f;
-    WIDTH_INTERVAL = (MAX - MIN) / (p.width/2);
+        MAX = 0.9f;
-    HEIGHT_INTERVAL = (MAX - MIN) / (p.height/2);
+        WIDTH_INTERVAL = (MAX - MIN) / (p.width/2);
-    GAP_SIZE = min(WIDTH_INTERVAL, HEIGHT_INTERVAL) / 2;
+        HEIGHT_INTERVAL = (MAX - MIN) / (p.height/2);
-    // @Improvement: This will make grid cells square... but how do I keep the puzzle centered? Maybe save extra metadata?
+        GAP_SIZE = min(WIDTH_INTERVAL, HEIGHT_INTERVAL) / 2;
-    // INTERVAL = (MAX - MIN) / (max(p.width, p.height) / 2);
+        // @Improvement: This will make grid cells square... but how do I keep the puzzle centered? Maybe save extra metadata?
-    // GAP_SIZE = INTERVAL / 2;
+        // INTERVAL = (MAX - MIN) / (max(p.width, p.height) / 2);
+        // GAP_SIZE = INTERVAL / 2;
    
-    WriteIntersections(p);
+        WriteIntersections(p);
-    WriteEndpoints(p);
+        WriteEndpoints(p);
-    WriteDots(p);
+        WriteDots(p);
-    WriteGaps(p);
+        WriteGaps(p);
-    WriteDecorations(p, id);
+        WriteDecorations(p, id);
-    WriteSequence(p, id);
+        WriteSequence(p, id);
-    WriteSymmetry(p, id);
+        WriteSymmetry(p, id);
 #ifndef NDEBUG
-    int maxDots = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];
+        int maxDots = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];
-    assert(_intersectionFlags.size() <= maxDots);
+        assert(_intersectionFlags.size() <= maxDots);
-    assert(_intersectionLocations.size() <= maxDots*2);
+        assert(_intersectionLocations.size() <= maxDots*2);
-    int maxConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];
+        int maxConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];
-    assert(_connectionsA.size() <= maxConnections);
+        assert(_connectionsA.size() <= maxConnections);
-    assert(_connectionsB.size() <= maxConnections);
+        assert(_connectionsB.size() <= maxConnections);
 #endif
-    _memory->WriteEntityData<int>(id, GRID_SIZE_X, {(p.width + 1)/2});
+        _memory->WriteEntityData<int>(id, GRID_SIZE_X, {(p.width + 1)/2});
-    _memory->WriteEntityData<int>(id, GRID_SIZE_Y, {(p.height + 1)/2});
+        _memory->WriteEntityData<int>(id, GRID_SIZE_Y, {(p.height + 1)/2});
-    _memory->WriteEntityData<int>(id, NUM_DOTS, {static_cast<int>(_intersectionFlags.size())});
+        _memory->WriteEntityData<int>(id, NUM_DOTS, {static_cast<int>(_intersectionFlags.size())});
-    _memory->WriteArray<float>(id, DOT_POSITIONS, _intersectionLocations);
+        _memory->WriteArray<float>(id, DOT_POSITIONS, _intersectionLocations);
-    _memory->WriteArray<int>(id, DOT_FLAGS, _intersectionFlags);
+        _memory->WriteArray<int>(id, DOT_FLAGS, _intersectionFlags);
-    _memory->WriteEntityData<int>(id, NUM_CONNECTIONS, {static_cast<int>(_connectionsA.size())});
+        _memory->WriteEntityData<int>(id, NUM_CONNECTIONS, {static_cast<int>(_connectionsA.size())});
-    _memory->WriteArray<int>(id, DOT_CONNECTION_A, _connectionsA);
+        _memory->WriteArray<int>(id, DOT_CONNECTION_A, _connectionsA);
-    _memory->WriteArray<int>(id, DOT_CONNECTION_B, _connectionsB);
+        _memory->WriteArray<int>(id, DOT_CONNECTION_B, _connectionsB);
-    _memory->WriteEntityData<int>(id, NEEDS_REDRAW, {1});
+        _memory->WriteEntityData<int>(id, NEEDS_REDRAW, {1});
+    } catch (MemoryException exc) {
+        MemoryException::HandleException(exc);
+    }
 }
 void PuzzleSerializer::ReadIntersections(Puzzle& p) {
author	jbzdarkid <jbzdarkid@gmail.com>	2019-11-24 12:28:53 -0800
committer	jbzdarkid <jbzdarkid@gmail.com>	2019-11-24 12:28:53 -0800
commit	92084d06a5c87338cc988b5bc5868e617213e6b9 (patch)
tree	314cbf8ee06821b9569a7b279bc39e2bf04abc87 /Source/PuzzleSerializer.cpp
parent	6059a1d1b99186a28bcd3c60822bc8310724bfd4 (diff)
download	witness-tutorializer-92084d06a5c87338cc988b5bc5868e617213e6b9.tar.gz witness-tutorializer-92084d06a5c87338cc988b5bc5868e617213e6b9.tar.bz2 witness-tutorializer-92084d06a5c87338cc988b5bc5868e617213e6b9.zip

diff --git a/Source/PuzzleSerializer.cpp b/Source/PuzzleSerializer.cpp index fb4166b..3dffde1 100644 --- a/Source/PuzzleSerializer.cpp +++ b/Source/PuzzleSerializer.cpp
@@ -8,73 +8,81 @@
8	PuzzleSerializer::PuzzleSerializer(const std::shared_ptr<Memory>& memory) : _memory(memory) {}	8	PuzzleSerializer::PuzzleSerializer(const std::shared_ptr<Memory>& memory) : _memory(memory) {}
9		9
10	Puzzle PuzzleSerializer::ReadPuzzle(int id) {	10	Puzzle PuzzleSerializer::ReadPuzzle(int id) {
11	int width = _memory->ReadEntityData<int>(id, GRID_SIZE_X, 1)[0];
12	int height = _memory->ReadEntityData<int>(id, GRID_SIZE_Y, 1)[0];
13	if (width == 0) width = height;
14	if (height == 0) height = width;
15	if (width < 0 \|\| height < 0) return Puzzle(); // @Error: Grid size should be always positive? Looks like the starting panels break this rule, though.
16
17	_numGridLocations = width * height; // Highest location which represents a gridded intersection
18	_numIntersections = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];
19	_intersectionFlags = _memory->ReadArray<int>(id, DOT_FLAGS, _numIntersections);
20	int numConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];
21	_connectionsA = _memory->ReadArray<int>(id, DOT_CONNECTION_A, numConnections);
22	_connectionsB = _memory->ReadArray<int>(id, DOT_CONNECTION_B, numConnections);
23	_intersectionLocations = _memory->ReadArray<float>(id, DOT_POSITIONS, _numIntersections*2);
24
25	Puzzle p;	11	Puzzle p;
26	p.NewGrid(width - 1, height - 1);	12	try {
27	ReadIntersections(p);	13	int width = _memory->ReadEntityData<int>(id, GRID_SIZE_X, 1)[0];
28	ReadExtras(p);	14	int height = _memory->ReadEntityData<int>(id, GRID_SIZE_Y, 1)[0];
29	ReadDecorations(p, id);	15	if (width == 0) width = height;
30	ReadSequence(p, id);	16	if (height == 0) height = width;
31	ReadSymmetry(p, id);	17	if (width < 0 \|\| height < 0) return Puzzle(); // @Error: Grid size should be always positive? Looks like the starting panels break this rule, though.
		18
		19	_numGridLocations = width * height; // Highest location which represents a gridded intersection
		20	_numIntersections = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];
		21	_intersectionFlags = _memory->ReadArray<int>(id, DOT_FLAGS, _numIntersections);
		22	int numConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];
		23	_connectionsA = _memory->ReadArray<int>(id, DOT_CONNECTION_A, numConnections);
		24	_connectionsB = _memory->ReadArray<int>(id, DOT_CONNECTION_B, numConnections);
		25	_intersectionLocations = _memory->ReadArray<float>(id, DOT_POSITIONS, _numIntersections*2);
		26
		27	p.NewGrid(width - 1, height - 1);
		28	ReadIntersections(p);
		29	ReadExtras(p);
		30	ReadDecorations(p, id);
		31	ReadSequence(p, id);
		32	ReadSymmetry(p, id);
		33	} catch (MemoryException exc) {
		34	MemoryException::HandleException(exc);
		35	}
32	return p;	36	return p;
33	}	37	}
34		38
35	void PuzzleSerializer::WritePuzzle(const Puzzle& p, int id) {	39	void PuzzleSerializer::WritePuzzle(const Puzzle& p, int id) {
36	_intersectionFlags.clear();	40	try {
37	_connectionsA.clear();	41	_intersectionFlags.clear();
38	_connectionsB.clear();	42	_connectionsA.clear();
39	_intersectionLocations.clear();	43	_connectionsB.clear();
40	_extraLocations.clear();	44	_intersectionLocations.clear();
41		45	_extraLocations.clear();
42	MIN = 0.1f;	46
43	MAX = 0.9f;	47	MIN = 0.1f;
44	WIDTH_INTERVAL = (MAX - MIN) / (p.width/2);	48	MAX = 0.9f;
45	HEIGHT_INTERVAL = (MAX - MIN) / (p.height/2);	49	WIDTH_INTERVAL = (MAX - MIN) / (p.width/2);
46	GAP_SIZE = min(WIDTH_INTERVAL, HEIGHT_INTERVAL) / 2;	50	HEIGHT_INTERVAL = (MAX - MIN) / (p.height/2);
47	// @Improvement: This will make grid cells square... but how do I keep the puzzle centered? Maybe save extra metadata?	51	GAP_SIZE = min(WIDTH_INTERVAL, HEIGHT_INTERVAL) / 2;
48	// INTERVAL = (MAX - MIN) / (max(p.width, p.height) / 2);	52	// @Improvement: This will make grid cells square... but how do I keep the puzzle centered? Maybe save extra metadata?
49	// GAP_SIZE = INTERVAL / 2;	53	// INTERVAL = (MAX - MIN) / (max(p.width, p.height) / 2);
		54	// GAP_SIZE = INTERVAL / 2;
50		55
51	WriteIntersections(p);	56	WriteIntersections(p);
52	WriteEndpoints(p);	57	WriteEndpoints(p);
53	WriteDots(p);	58	WriteDots(p);
54	WriteGaps(p);	59	WriteGaps(p);
55	WriteDecorations(p, id);	60	WriteDecorations(p, id);
56	WriteSequence(p, id);	61	WriteSequence(p, id);
57	WriteSymmetry(p, id);	62	WriteSymmetry(p, id);
58		63
59	#ifndef NDEBUG	64	#ifndef NDEBUG
60	int maxDots = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];	65	int maxDots = _memory->ReadEntityData<int>(id, NUM_DOTS, 1)[0];
61	assert(_intersectionFlags.size() <= maxDots);	66	assert(_intersectionFlags.size() <= maxDots);
62	assert(_intersectionLocations.size() <= maxDots*2);	67	assert(_intersectionLocations.size() <= maxDots*2);
63		68
64	int maxConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];	69	int maxConnections = _memory->ReadEntityData<int>(id, NUM_CONNECTIONS, 1)[0];
65	assert(_connectionsA.size() <= maxConnections);	70	assert(_connectionsA.size() <= maxConnections);
66	assert(_connectionsB.size() <= maxConnections);	71	assert(_connectionsB.size() <= maxConnections);
67	#endif	72	#endif
68		73
69	_memory->WriteEntityData<int>(id, GRID_SIZE_X, {(p.width + 1)/2});	74	_memory->WriteEntityData<int>(id, GRID_SIZE_X, {(p.width + 1)/2});
70	_memory->WriteEntityData<int>(id, GRID_SIZE_Y, {(p.height + 1)/2});	75	_memory->WriteEntityData<int>(id, GRID_SIZE_Y, {(p.height + 1)/2});
71	_memory->WriteEntityData<int>(id, NUM_DOTS, {static_cast<int>(_intersectionFlags.size())});	76	_memory->WriteEntityData<int>(id, NUM_DOTS, {static_cast<int>(_intersectionFlags.size())});
72	_memory->WriteArray<float>(id, DOT_POSITIONS, _intersectionLocations);	77	_memory->WriteArray<float>(id, DOT_POSITIONS, _intersectionLocations);
73	_memory->WriteArray<int>(id, DOT_FLAGS, _intersectionFlags);	78	_memory->WriteArray<int>(id, DOT_FLAGS, _intersectionFlags);
74	_memory->WriteEntityData<int>(id, NUM_CONNECTIONS, {static_cast<int>(_connectionsA.size())});	79	_memory->WriteEntityData<int>(id, NUM_CONNECTIONS, {static_cast<int>(_connectionsA.size())});
75	_memory->WriteArray<int>(id, DOT_CONNECTION_A, _connectionsA);	80	_memory->WriteArray<int>(id, DOT_CONNECTION_A, _connectionsA);
76	_memory->WriteArray<int>(id, DOT_CONNECTION_B, _connectionsB);	81	_memory->WriteArray<int>(id, DOT_CONNECTION_B, _connectionsB);
77	_memory->WriteEntityData<int>(id, NEEDS_REDRAW, {1});	82	_memory->WriteEntityData<int>(id, NEEDS_REDRAW, {1});
		83	} catch (MemoryException exc) {
		84	MemoryException::HandleException(exc);
		85	}
78	}	86	}
79		87
80	void PuzzleSerializer::ReadIntersections(Puzzle& p) {	88	void PuzzleSerializer::ReadIntersections(Puzzle& p) {