1 files changed, 8 insertions, 243 deletions
diff --git a/Source/Randomizer.cpp b/Source/Randomizer.cpp
index 74166af..5239cd6 100644
--- a/Source/Randomizer.cpp
+++ b/Source/Randomizer.cpp

@@ -93,7 +93,6 @@ Things to do for V2:
 */
 #include "pch.h"
 #include "Randomizer.h"
-#include "ChallengeRandomizer.h"
 #include "Panels.h"
 #include "Random.h"
@@ -124,14 +123,6 @@ void Randomizer::Randomize() {
        }
        _memory->WriteData<byte>({index}, {0xEB}); // jz -> jmp
    });
-    // Sig scans will be run during challenge randomization.
-    // Seed challenge first for future-proofing
-    MEMORY_CATCH(RandomizeChallenge());
-    // Content swaps -- must happen before squarePanels
-    //MEMORY_CATCH(Randomize(upDownPanels, SWAP::LINES | SWAP::COLORS));
-    //MEMORY_CATCH(Randomize(leftForwardRightPanels, SWAP::LINES | SWAP::COLORS));
    // Tutorial Bend
    for (int panel : utmPerspective) {
@@ -141,220 +132,23 @@ void Randomizer::Randomize() {
    for (int panel : squarePanels) {
        Tutorialise(panel, 0x00064);
    }
-    //Randomize(squarePanels, SWAP::LINES | SWAP::COLORS);
-    // Individual area modifications
-    MEMORY_CATCH(RandomizeTutorial());
-    MEMORY_CATCH(RandomizeDesert());
-    MEMORY_CATCH(RandomizeQuarry());
-    MEMORY_CATCH(RandomizeTreehouse());
-    MEMORY_CATCH(RandomizeKeep());
-    MEMORY_CATCH(RandomizeShadows());
-    MEMORY_CATCH(RandomizeMonastery());
-    MEMORY_CATCH(RandomizeBunker());
-    MEMORY_CATCH(RandomizeJungle());
-    MEMORY_CATCH(RandomizeSwamp());
-    MEMORY_CATCH(RandomizeMountain());
-    MEMORY_CATCH(RandomizeTown());
-    MEMORY_CATCH(RandomizeSymmetry());
-    // RandomizeAudioLogs();
-}
-void Randomizer::AdjustSpeed() {
-    // Desert Surface Final Control
-    _memory->WriteEntityData<float>(0x09F95, OPEN_RATE, {0.04f}); // 4x
-    // Swamp Sliding Bridge
-    _memory->WriteEntityData<float>(0x0061A, OPEN_RATE, {0.1f}); // 4x
-    // Mountain 2 Elevator
-    _memory->WriteEntityData<float>(0x09EEC, OPEN_RATE, {0.075f}); // 3x
-}
-void Randomizer::RandomizeLasers() {
-    Randomize(lasers, SWAP::TARGETS);
-    // Read the target of keep front laser, and write it to keep back laser.
-    std::vector<int> keepFrontLaserTarget = _memory->ReadEntityData<int>(0x0360E, TARGET, 1);
-    _memory->WriteEntityData<int>(0x03317, TARGET, keepFrontLaserTarget);
-}
-void Randomizer::PreventSnipes()
-{
-    // Distance-gate swamp snipe 1 to prevent RNG swamp snipe
-    //_memory->WriteEntityData<float>(0x17C05, MAX_BROADCAST_DISTANCE, {15.0});
-    // Distance-gate shadows laser to prevent sniping through the bars
-    //_memory->WriteEntityData<float>(0x19650, MAX_BROADCAST_DISTANCE, {2.5});
-}
-// Private methods
-void Randomizer::RandomizeTutorial() {
    // Disable tutorial cursor speed modifications (not working?)
-    _memory->WriteEntityData<float>(0x00295, CURSOR_SPEED_SCALE, {1.0});
+    _memory->WriteEntityData<float>(0x00295, CURSOR_SPEED_SCALE, { 1.0 });
-    _memory->WriteEntityData<float>(0x0C373, CURSOR_SPEED_SCALE, {1.0});
+    _memory->WriteEntityData<float>(0x0C373, CURSOR_SPEED_SCALE, { 1.0 });
-    _memory->WriteEntityData<float>(0x00293, CURSOR_SPEED_SCALE, {1.0});
+    _memory->WriteEntityData<float>(0x00293, CURSOR_SPEED_SCALE, { 1.0 });
-    _memory->WriteEntityData<float>(0x002C2, CURSOR_SPEED_SCALE, {1.0});
+    _memory->WriteEntityData<float>(0x002C2, CURSOR_SPEED_SCALE, { 1.0 });
-}
-void Randomizer::RandomizeSymmetry() {
-    /*std::vector<int> randomOrder(transparent.size(), 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    RandomizeRange(randomOrder, SWAP::NONE, 1, 5);
-    ReassignTargets(transparent, randomOrder);*/
-}
-void Randomizer::RandomizeDesert() {
-    //Randomize(desertPanels, SWAP::LINES);
-    // Turn off desert surface 8
-    /*_memory->WriteEntityData<float>(0x09F94, POWER, {0.0, 0.0});
-    // Turn off desert flood final
-    _memory->WriteEntityData<float>(0x18076, POWER, {0.0, 0.0});
-    // Change desert floating target to desert flood final
-    _memory->WriteEntityData<int>(0x17ECA, TARGET, {0x18077});*/
-}
-void Randomizer::RandomizeQuarry() {
-}
-void Randomizer::RandomizeTreehouse() {
    // Ensure that whatever pivot panels we have are flagged as "pivotable"
    // @Bug: Can return {}, be careful!
    int panelFlags = _memory->ReadEntityData<int>(0x17DD1, STYLE_FLAGS, 1)[0];
-    _memory->WriteEntityData<int>(0x17DD1, STYLE_FLAGS, {panelFlags | 0x8000});
+    _memory->WriteEntityData<int>(0x17DD1, STYLE_FLAGS, { panelFlags | 0x8000 });
    panelFlags = _memory->ReadEntityData<int>(0x17CE3, STYLE_FLAGS, 1)[0];
-    _memory->WriteEntityData<int>(0x17CE3, STYLE_FLAGS, {panelFlags | 0x8000});
+    _memory->WriteEntityData<int>(0x17CE3, STYLE_FLAGS, { panelFlags | 0x8000 });
    panelFlags = _memory->ReadEntityData<int>(0x17DB7, STYLE_FLAGS, 1)[0];
-    _memory->WriteEntityData<int>(0x17DB7, STYLE_FLAGS, {panelFlags | 0x8000});
+    _memory->WriteEntityData<int>(0x17DB7, STYLE_FLAGS, { panelFlags | 0x8000 });
    panelFlags = _memory->ReadEntityData<int>(0x17E52, STYLE_FLAGS, 1)[0];
-    _memory->WriteEntityData<int>(0x17E52, STYLE_FLAGS, {panelFlags | 0x8000});
+    _memory->WriteEntityData<int>(0x17E52, STYLE_FLAGS, { panelFlags | 0x8000 });
-}
-void Randomizer::RandomizeKeep() {
-}
-void Randomizer::RandomizeShadows() {
-    // Change the shadows tutorial cable to only activate avoid
-    _memory->WriteEntityData<int>(0x319A8, CABLE_TARGET_2, {0});
-    // Change shadows avoid 8 to power shadows follow
-    _memory->WriteEntityData<int>(0x1972F, TARGET, {0x1C34C});
-    /*std::vector<int> randomOrder(shadowsPanels.size(), 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    RandomizeRange(randomOrder, SWAP::NONE, 0, 8); // Tutorial
-    RandomizeRange(randomOrder, SWAP::NONE, 8, 16); // Avoid
-    RandomizeRange(randomOrder, SWAP::NONE, 16, 21); // Follow
-    ReassignTargets(shadowsPanels, randomOrder);
-    // Turn off original starting panel
-    _memory->WriteEntityData<float>(shadowsPanels[0], POWER, {0.0f, 0.0f});
-    // Turn on new starting panel
-    _memory->WriteEntityData<float>(shadowsPanels[randomOrder[0]], POWER, {1.0f, 1.0f});*/
-}
-void Randomizer::RandomizeTown() {
-    // @Hack...? To open the gate at the end
-    /*std::vector<int> randomOrder(orchard.size() + 1, 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    RandomizeRange(randomOrder, SWAP::NONE, 1, 5);
-    // Ensure that we open the gate before the final puzzle (by swapping)
-    int panel3Index = find(randomOrder, 3);
-    int panel4Index = find(randomOrder, 4);
-    randomOrder[std::min(panel3Index, panel4Index)] = 3;
-    randomOrder[std::max(panel3Index, panel4Index)] = 4;
-    ReassignTargets(orchard, randomOrder);*/
-}
-void Randomizer::RandomizeMonastery() {
-    /*std::vector<int> randomOrder(monasteryPanels.size(), 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    RandomizeRange(randomOrder, SWAP::NONE, 3, 9); // Outer 2 & 3, Inner 1-4
-    ReassignTargets(monasteryPanels, randomOrder);*/
-}
-void Randomizer::RandomizeBunker() {
-    /*std::vector<int> randomOrder(bunkerPanels.size(), 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    // Randomize Tutorial 2-Advanced Tutorial 4 + Glass 1
-    // Tutorial 1 cannot be randomized, since no other panel can start on
-    // Glass 1 will become door + glass 1, due to the targetting system
-    RandomizeRange(randomOrder, SWAP::NONE, 1, 10);
-    // Randomize Glass 1-3 into everything after the door/glass 1
-    const size_t glass1Index = find(randomOrder, 9);
-    RandomizeRange(randomOrder, SWAP::NONE, glass1Index + 1, 12);
-    ReassignTargets(bunkerPanels, randomOrder);*/
-}
-void Randomizer::RandomizeJungle() {
-    /*std::vector<int> randomOrder(junglePanels.size(), 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    // Waves 1 cannot be randomized, since no other panel can start on
-    RandomizeRange(randomOrder, SWAP::NONE, 1, 7); // Waves 2-7
-    RandomizeRange(randomOrder, SWAP::NONE, 8, 13); // Pitches 1-6
-    ReassignTargets(junglePanels, randomOrder);*/
-    // Fix the wall's target to point back to the cable, and the cable to point to the pitches panel.
-    // auto wallTarget = _memory->ReadPanelData<int>(junglePanels[7], TARGET, 1);
-    // _memory->WritePanelData<int>(junglePanels[7], TARGET, {0x3C113});
-    // _memory->WritePanelData<int>(0x3C112, CABLE_TARGET_1, wallTarget);
-}
-void Randomizer::RandomizeSwamp() {
-}
-void Randomizer::RandomizeMountain() {
-    // Randomize multipanel
-    //Randomize(mountainMultipanel, SWAP::LINES | SWAP::COLORS);
-    // Randomize final pillars order
-    /*std::vector<int> targets = {pillars[0] + 1};
-    for (const int pillar : pillars) {
-        int target = _memory->ReadEntityData<int>(pillar, TARGET, 1)[0];
-        targets.push_back(target);
-    }
-    targets[5] = pillars[5] + 1;
-    std::vector<int> randomOrder(pillars.size(), 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    RandomizeRange(randomOrder, SWAP::NONE, 0, 4); // Left Pillars 1-4
-    RandomizeRange(randomOrder, SWAP::NONE, 5, 9); // Right Pillars 1-4
-    ReassignTargets(pillars, randomOrder, targets);
-    // Turn off original starting panels
-    _memory->WriteEntityData<float>(pillars[0], POWER, {0.0f, 0.0f});
-    _memory->WriteEntityData<float>(pillars[5], POWER, {0.0f, 0.0f});
-    // Turn on new starting panels
-    _memory->WriteEntityData<float>(pillars[randomOrder[0]], POWER, {1.0f, 1.0f});
-    _memory->WriteEntityData<float>(pillars[randomOrder[5]], POWER, {1.0f, 1.0f});*/
-}
-void Randomizer::RandomizeChallenge() {
-    /*ChallengeRandomizer cr(_memory, Random::RandInt(1, 0x7FFFFFFF)); // 0 will trigger an "RNG not initialized" block
-    for (int panel : challengePanels) {
-        _memory->WriteEntityData<int>(panel, POWER_OFF_ON_FAIL, {0});
-    }*/
-}
-void Randomizer::RandomizeAudioLogs() {
-    std::vector<int> randomOrder(audiologs.size(), 0);
-    std::iota(randomOrder.begin(), randomOrder.end(), 0);
-    Randomize(randomOrder, SWAP::NONE);
-    ReassignNames(audiologs, randomOrder);
-}
-void Randomizer::Randomize(std::vector<int>& panels, int flags) {
-    return RandomizeRange(panels, flags, 0, panels.size());
-}
-// Range is [start, end)
-void Randomizer::RandomizeRange(std::vector<int> &panels, int flags, size_t startIndex, size_t endIndex) {
-    if (panels.size() == 0) return;
-    if (startIndex >= endIndex) return;
-    if (endIndex >= panels.size()) endIndex = static_cast<int>(panels.size());
-    for (size_t i = 0; i < panels.size(); i++) {
-        /*const int target = Random::RandInt(static_cast<int>(startIndex), static_cast<int>(i));
-        if (i != target) {
-            // std::cout << "Swapping panels " << std::hex << panels[i] << " and " << std::hex << panels[target] << std::endl;
-            SwapPanels(panels[i], panels[target], flags);
-            //std::swap(panels[i], panels[target]); // Panel indices in the array
-        }*/
-        
-    }
 }
 void Randomizer::Tutorialise(int panel1, int tutorialStraight) {
@@ -421,32 +215,3 @@ void Randomizer::Tutorialise(int panel1, int tutorialStraight) {
        //arrays.push_back(SPECULAR_TEXTURE);
 }
-void Randomizer::ReassignTargets(const std::vector<int>& panels, const std::vector<int>& order, std::vector<int> targets) {
-    if (targets.empty()) {
-        // This list is offset by 1, so the target of the Nth panel is in position N (aka the N+1th element)
-        // The first panel may not have a wire to power it, so we use the panel ID itself.
-        targets = {panels[0] + 1};
-        for (const int panel : panels) {
-            int target = _memory->ReadEntityData<int>(panel, TARGET, 1)[0];
-            targets.push_back(target);
-        }
-    }
-    for (size_t i=0; i<order.size() - 1; i++) {
-        // Set the target of order[i] to order[i+1], using the "real" target as determined above.
-        const int panelTarget = targets[order[i+1]];
-        _memory->WriteEntityData<int>(panels[order[i]], TARGET, {panelTarget});
-    }
-}
-void Randomizer::ReassignNames(const std::vector<int>& panels, const std::vector<int>& order) {
-    std::vector<int64_t> names;
-    for (const int panel : panels) {
-        names.push_back(_memory->ReadEntityData<int64_t>(panel, AUDIO_LOG_NAME, 1)[0]);
-    }
-    for (int i=0; i<panels.size(); i++) {
-        _memory->WriteEntityData<int64_t>(panels[i], AUDIO_LOG_NAME, {names[order[i]]});
-    }
-}

diff --git a/Source/Randomizer.cpp b/Source/Randomizer.cpp index 74166af..5239cd6 100644 --- a/Source/Randomizer.cpp +++ b/Source/Randomizer.cpp
@@ -93,7 +93,6 @@ Things to do for V2:
93	*/	93	*/
94	#include "pch.h"	94	#include "pch.h"
95	#include "Randomizer.h"	95	#include "Randomizer.h"
96	#include "ChallengeRandomizer.h"
97	#include "Panels.h"	96	#include "Panels.h"
98	#include "Random.h"	97	#include "Random.h"
99		98
@@ -124,14 +123,6 @@ void Randomizer::Randomize() {
124	}	123	}
125	_memory->WriteData<byte>({index}, {0xEB}); // jz -> jmp	124	_memory->WriteData<byte>({index}, {0xEB}); // jz -> jmp
126	});	125	});
127	// Sig scans will be run during challenge randomization.
128
129	// Seed challenge first for future-proofing
130	MEMORY_CATCH(RandomizeChallenge());
131
132	// Content swaps -- must happen before squarePanels
133	//MEMORY_CATCH(Randomize(upDownPanels, SWAP::LINES \| SWAP::COLORS));
134	//MEMORY_CATCH(Randomize(leftForwardRightPanels, SWAP::LINES \| SWAP::COLORS));
135		126
136	// Tutorial Bend	127	// Tutorial Bend
137	for (int panel : utmPerspective) {	128	for (int panel : utmPerspective) {
@@ -141,220 +132,23 @@ void Randomizer::Randomize() {
141	for (int panel : squarePanels) {	132	for (int panel : squarePanels) {
142	Tutorialise(panel, 0x00064);	133	Tutorialise(panel, 0x00064);
143	}	134	}
144	//Randomize(squarePanels, SWAP::LINES \| SWAP::COLORS);
145
146	// Individual area modifications
147	MEMORY_CATCH(RandomizeTutorial());
148	MEMORY_CATCH(RandomizeDesert());
149	MEMORY_CATCH(RandomizeQuarry());
150	MEMORY_CATCH(RandomizeTreehouse());
151	MEMORY_CATCH(RandomizeKeep());
152	MEMORY_CATCH(RandomizeShadows());
153	MEMORY_CATCH(RandomizeMonastery());
154	MEMORY_CATCH(RandomizeBunker());
155	MEMORY_CATCH(RandomizeJungle());
156	MEMORY_CATCH(RandomizeSwamp());
157	MEMORY_CATCH(RandomizeMountain());
158	MEMORY_CATCH(RandomizeTown());
159	MEMORY_CATCH(RandomizeSymmetry());
160	// RandomizeAudioLogs();
161	}
162
163	void Randomizer::AdjustSpeed() {
164	// Desert Surface Final Control
165	_memory->WriteEntityData<float>(0x09F95, OPEN_RATE, {0.04f}); // 4x
166	// Swamp Sliding Bridge
167	_memory->WriteEntityData<float>(0x0061A, OPEN_RATE, {0.1f}); // 4x
168	// Mountain 2 Elevator
169	_memory->WriteEntityData<float>(0x09EEC, OPEN_RATE, {0.075f}); // 3x
170	}
171
172	void Randomizer::RandomizeLasers() {
173	Randomize(lasers, SWAP::TARGETS);
174	// Read the target of keep front laser, and write it to keep back laser.
175	std::vector<int> keepFrontLaserTarget = _memory->ReadEntityData<int>(0x0360E, TARGET, 1);
176	_memory->WriteEntityData<int>(0x03317, TARGET, keepFrontLaserTarget);
177	}
178		135
179	void Randomizer::PreventSnipes()
180	{
181	// Distance-gate swamp snipe 1 to prevent RNG swamp snipe
182	//_memory->WriteEntityData<float>(0x17C05, MAX_BROADCAST_DISTANCE, {15.0});
183	// Distance-gate shadows laser to prevent sniping through the bars
184	//_memory->WriteEntityData<float>(0x19650, MAX_BROADCAST_DISTANCE, {2.5});
185	}
186
187	// Private methods
188	void Randomizer::RandomizeTutorial() {
189	// Disable tutorial cursor speed modifications (not working?)	136	// Disable tutorial cursor speed modifications (not working?)
190	_memory->WriteEntityData<float>(0x00295, CURSOR_SPEED_SCALE, {1.0});	137	_memory->WriteEntityData<float>(0x00295, CURSOR_SPEED_SCALE, { 1.0 });
191	_memory->WriteEntityData<float>(0x0C373, CURSOR_SPEED_SCALE, {1.0});	138	_memory->WriteEntityData<float>(0x0C373, CURSOR_SPEED_SCALE, { 1.0 });
192	_memory->WriteEntityData<float>(0x00293, CURSOR_SPEED_SCALE, {1.0});	139	_memory->WriteEntityData<float>(0x00293, CURSOR_SPEED_SCALE, { 1.0 });
193	_memory->WriteEntityData<float>(0x002C2, CURSOR_SPEED_SCALE, {1.0});	140	_memory->WriteEntityData<float>(0x002C2, CURSOR_SPEED_SCALE, { 1.0 });
194	}
195
196	void Randomizer::RandomizeSymmetry() {
197	/*std::vector<int> randomOrder(transparent.size(), 0);
198	std::iota(randomOrder.begin(), randomOrder.end(), 0);
199	RandomizeRange(randomOrder, SWAP::NONE, 1, 5);
200	ReassignTargets(transparent, randomOrder);*/
201	}
202
203	void Randomizer::RandomizeDesert() {
204	//Randomize(desertPanels, SWAP::LINES);
205
206	// Turn off desert surface 8
207	/*_memory->WriteEntityData<float>(0x09F94, POWER, {0.0, 0.0});
208	// Turn off desert flood final
209	_memory->WriteEntityData<float>(0x18076, POWER, {0.0, 0.0});
210	// Change desert floating target to desert flood final
211	_memory->WriteEntityData<int>(0x17ECA, TARGET, {0x18077});*/
212	}
213
214	void Randomizer::RandomizeQuarry() {
215	}
216		141
217	void Randomizer::RandomizeTreehouse() {
218	// Ensure that whatever pivot panels we have are flagged as "pivotable"	142	// Ensure that whatever pivot panels we have are flagged as "pivotable"
219	// @Bug: Can return {}, be careful!	143	// @Bug: Can return {}, be careful!
220	int panelFlags = _memory->ReadEntityData<int>(0x17DD1, STYLE_FLAGS, 1)[0];	144	int panelFlags = _memory->ReadEntityData<int>(0x17DD1, STYLE_FLAGS, 1)[0];
221	_memory->WriteEntityData<int>(0x17DD1, STYLE_FLAGS, {panelFlags \| 0x8000});	145	_memory->WriteEntityData<int>(0x17DD1, STYLE_FLAGS, { panelFlags \| 0x8000 });
222	panelFlags = _memory->ReadEntityData<int>(0x17CE3, STYLE_FLAGS, 1)[0];	146	panelFlags = _memory->ReadEntityData<int>(0x17CE3, STYLE_FLAGS, 1)[0];
223	_memory->WriteEntityData<int>(0x17CE3, STYLE_FLAGS, {panelFlags \| 0x8000});	147	_memory->WriteEntityData<int>(0x17CE3, STYLE_FLAGS, { panelFlags \| 0x8000 });
224	panelFlags = _memory->ReadEntityData<int>(0x17DB7, STYLE_FLAGS, 1)[0];	148	panelFlags = _memory->ReadEntityData<int>(0x17DB7, STYLE_FLAGS, 1)[0];
225	_memory->WriteEntityData<int>(0x17DB7, STYLE_FLAGS, {panelFlags \| 0x8000});	149	_memory->WriteEntityData<int>(0x17DB7, STYLE_FLAGS, { panelFlags \| 0x8000 });
226	panelFlags = _memory->ReadEntityData<int>(0x17E52, STYLE_FLAGS, 1)[0];	150	panelFlags = _memory->ReadEntityData<int>(0x17E52, STYLE_FLAGS, 1)[0];
227	_memory->WriteEntityData<int>(0x17E52, STYLE_FLAGS, {panelFlags \| 0x8000});	151	_memory->WriteEntityData<int>(0x17E52, STYLE_FLAGS, { panelFlags \| 0x8000 });
228	}
229
230	void Randomizer::RandomizeKeep() {
231	}
232
233	void Randomizer::RandomizeShadows() {
234	// Change the shadows tutorial cable to only activate avoid
235	_memory->WriteEntityData<int>(0x319A8, CABLE_TARGET_2, {0});
236	// Change shadows avoid 8 to power shadows follow
237	_memory->WriteEntityData<int>(0x1972F, TARGET, {0x1C34C});
238
239	/*std::vector<int> randomOrder(shadowsPanels.size(), 0);
240	std::iota(randomOrder.begin(), randomOrder.end(), 0);
241	RandomizeRange(randomOrder, SWAP::NONE, 0, 8); // Tutorial
242	RandomizeRange(randomOrder, SWAP::NONE, 8, 16); // Avoid
243	RandomizeRange(randomOrder, SWAP::NONE, 16, 21); // Follow
244	ReassignTargets(shadowsPanels, randomOrder);
245	// Turn off original starting panel
246	_memory->WriteEntityData<float>(shadowsPanels[0], POWER, {0.0f, 0.0f});
247	// Turn on new starting panel
248	_memory->WriteEntityData<float>(shadowsPanels[randomOrder[0]], POWER, {1.0f, 1.0f});*/
249	}
250
251	void Randomizer::RandomizeTown() {
252	// @Hack...? To open the gate at the end
253	/*std::vector<int> randomOrder(orchard.size() + 1, 0);
254	std::iota(randomOrder.begin(), randomOrder.end(), 0);
255	RandomizeRange(randomOrder, SWAP::NONE, 1, 5);
256	// Ensure that we open the gate before the final puzzle (by swapping)
257	int panel3Index = find(randomOrder, 3);
258	int panel4Index = find(randomOrder, 4);
259	randomOrder[std::min(panel3Index, panel4Index)] = 3;
260	randomOrder[std::max(panel3Index, panel4Index)] = 4;
261	ReassignTargets(orchard, randomOrder);*/
262	}
263
264	void Randomizer::RandomizeMonastery() {
265	/*std::vector<int> randomOrder(monasteryPanels.size(), 0);
266	std::iota(randomOrder.begin(), randomOrder.end(), 0);
267	RandomizeRange(randomOrder, SWAP::NONE, 3, 9); // Outer 2 & 3, Inner 1-4
268	ReassignTargets(monasteryPanels, randomOrder);*/
269	}
270
271	void Randomizer::RandomizeBunker() {
272	/*std::vector<int> randomOrder(bunkerPanels.size(), 0);
273	std::iota(randomOrder.begin(), randomOrder.end(), 0);
274	// Randomize Tutorial 2-Advanced Tutorial 4 + Glass 1
275	// Tutorial 1 cannot be randomized, since no other panel can start on
276	// Glass 1 will become door + glass 1, due to the targetting system
277	RandomizeRange(randomOrder, SWAP::NONE, 1, 10);
278	// Randomize Glass 1-3 into everything after the door/glass 1
279	const size_t glass1Index = find(randomOrder, 9);
280	RandomizeRange(randomOrder, SWAP::NONE, glass1Index + 1, 12);
281	ReassignTargets(bunkerPanels, randomOrder);*/
282	}
283
284	void Randomizer::RandomizeJungle() {
285	/*std::vector<int> randomOrder(junglePanels.size(), 0);
286	std::iota(randomOrder.begin(), randomOrder.end(), 0);
287	// Waves 1 cannot be randomized, since no other panel can start on
288	RandomizeRange(randomOrder, SWAP::NONE, 1, 7); // Waves 2-7
289	RandomizeRange(randomOrder, SWAP::NONE, 8, 13); // Pitches 1-6
290	ReassignTargets(junglePanels, randomOrder);*/
291
292	// Fix the wall's target to point back to the cable, and the cable to point to the pitches panel.
293	// auto wallTarget = _memory->ReadPanelData<int>(junglePanels[7], TARGET, 1);
294	// _memory->WritePanelData<int>(junglePanels[7], TARGET, {0x3C113});
295	// _memory->WritePanelData<int>(0x3C112, CABLE_TARGET_1, wallTarget);
296	}
297
298	void Randomizer::RandomizeSwamp() {
299	}
300
301	void Randomizer::RandomizeMountain() {
302	// Randomize multipanel
303	//Randomize(mountainMultipanel, SWAP::LINES \| SWAP::COLORS);
304
305	// Randomize final pillars order
306	/*std::vector<int> targets = {pillars[0] + 1};
307	for (const int pillar : pillars) {
308	int target = _memory->ReadEntityData<int>(pillar, TARGET, 1)[0];
309	targets.push_back(target);
310	}
311	targets[5] = pillars[5] + 1;
312
313	std::vector<int> randomOrder(pillars.size(), 0);
314	std::iota(randomOrder.begin(), randomOrder.end(), 0);
315	RandomizeRange(randomOrder, SWAP::NONE, 0, 4); // Left Pillars 1-4
316	RandomizeRange(randomOrder, SWAP::NONE, 5, 9); // Right Pillars 1-4
317	ReassignTargets(pillars, randomOrder, targets);
318	// Turn off original starting panels
319	_memory->WriteEntityData<float>(pillars[0], POWER, {0.0f, 0.0f});
320	_memory->WriteEntityData<float>(pillars[5], POWER, {0.0f, 0.0f});
321	// Turn on new starting panels
322	_memory->WriteEntityData<float>(pillars[randomOrder[0]], POWER, {1.0f, 1.0f});
323	_memory->WriteEntityData<float>(pillars[randomOrder[5]], POWER, {1.0f, 1.0f});*/
324	}
325
326	void Randomizer::RandomizeChallenge() {
327	/*ChallengeRandomizer cr(_memory, Random::RandInt(1, 0x7FFFFFFF)); // 0 will trigger an "RNG not initialized" block
328	for (int panel : challengePanels) {
329	_memory->WriteEntityData<int>(panel, POWER_OFF_ON_FAIL, {0});
330	}*/
331	}
332
333	void Randomizer::RandomizeAudioLogs() {
334	std::vector<int> randomOrder(audiologs.size(), 0);
335	std::iota(randomOrder.begin(), randomOrder.end(), 0);
336	Randomize(randomOrder, SWAP::NONE);
337	ReassignNames(audiologs, randomOrder);
338	}
339
340	void Randomizer::Randomize(std::vector<int>& panels, int flags) {
341	return RandomizeRange(panels, flags, 0, panels.size());
342	}
343
344	// Range is [start, end)
345	void Randomizer::RandomizeRange(std::vector<int> &panels, int flags, size_t startIndex, size_t endIndex) {
346	if (panels.size() == 0) return;
347	if (startIndex >= endIndex) return;
348	if (endIndex >= panels.size()) endIndex = static_cast<int>(panels.size());
349	for (size_t i = 0; i < panels.size(); i++) {
350	/*const int target = Random::RandInt(static_cast<int>(startIndex), static_cast<int>(i));
351	if (i != target) {
352	// std::cout << "Swapping panels " << std::hex << panels[i] << " and " << std::hex << panels[target] << std::endl;
353	SwapPanels(panels[i], panels[target], flags);
354	//std::swap(panels[i], panels[target]); // Panel indices in the array
355	}*/
356
357	}
358	}	152	}
359		153
360	void Randomizer::Tutorialise(int panel1, int tutorialStraight) {	154	void Randomizer::Tutorialise(int panel1, int tutorialStraight) {
@@ -421,32 +215,3 @@ void Randomizer::Tutorialise(int panel1, int tutorialStraight) {
421	//arrays.push_back(SPECULAR_TEXTURE);	215	//arrays.push_back(SPECULAR_TEXTURE);
422		216
423	}	217	}
424
425	void Randomizer::ReassignTargets(const std::vector<int>& panels, const std::vector<int>& order, std::vector<int> targets) {
426	if (targets.empty()) {
427	// This list is offset by 1, so the target of the Nth panel is in position N (aka the N+1th element)
428	// The first panel may not have a wire to power it, so we use the panel ID itself.
429	targets = {panels[0] + 1};
430	for (const int panel : panels) {
431	int target = _memory->ReadEntityData<int>(panel, TARGET, 1)[0];
432	targets.push_back(target);
433	}
434	}
435
436	for (size_t i=0; i<order.size() - 1; i++) {
437	// Set the target of order[i] to order[i+1], using the "real" target as determined above.
438	const int panelTarget = targets[order[i+1]];
439	_memory->WriteEntityData<int>(panels[order[i]], TARGET, {panelTarget});
440	}
441	}
442
443	void Randomizer::ReassignNames(const std::vector<int>& panels, const std::vector<int>& order) {
444	std::vector<int64_t> names;
445	for (const int panel : panels) {
446	names.push_back(_memory->ReadEntityData<int64_t>(panel, AUDIO_LOG_NAME, 1)[0]);
447	}
448
449	for (int i=0; i<panels.size(); i++) {
450	_memory->WriteEntityData<int64_t>(panels[i], AUDIO_LOG_NAME, {names[order[i]]});
451	}
452	}