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#include "RandomizerCore.h"
#include "Memory.h"
#include <sstream>
void RandomizerCore::Randomize(std::vector<int>& panels, int flags) {
return RandomizeRange(panels, flags, 0, panels.size());
}
// Range is [start, end)
void RandomizerCore::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 = panels.size();
for (size_t i = endIndex-1; i > startIndex; i--) {
const size_t target = rand() % (i - startIndex) + startIndex;
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 RandomizerCore::SwapPanels(int panel1, int panel2, int flags) {
std::map<int, int> offsets;
if (flags & SWAP_TARGETS) {
offsets[TARGET] = sizeof(int);
}
if (flags & SWAP_LINES) {
offsets[PATH_COLOR] = 16;
offsets[REFLECTION_PATH_COLOR] = 16;
offsets[DOT_COLOR] = 16;
offsets[ACTIVE_COLOR] = 16;
offsets[BACKGROUND_REGION_COLOR] = 16;
offsets[SUCCESS_COLOR_A] = 16;
offsets[SUCCESS_COLOR_B] = 16;
offsets[STROBE_COLOR_A] = 16;
offsets[STROBE_COLOR_B] = 16;
offsets[ERROR_COLOR] = 16;
offsets[PATTERN_POINT_COLOR] = 16;
offsets[PATTERN_POINT_COLOR_A] = 16;
offsets[PATTERN_POINT_COLOR_B] = 16;
offsets[SYMBOL_A] = 16;
offsets[SYMBOL_B] = 16;
offsets[SYMBOL_C] = 16;
offsets[SYMBOL_D] = 16;
offsets[SYMBOL_E] = 16;
offsets[PUSH_SYMBOL_COLORS] = sizeof(int);
offsets[OUTER_BACKGROUND] = 16;
offsets[OUTER_BACKGROUND_MODE] = sizeof(int);
offsets[TRACED_EDGES] = 16;
offsets[AUDIO_PREFIX] = sizeof(void*);
// offsets[IS_CYLINDER] = sizeof(int);
// offsets[CYLINDER_Z0] = sizeof(float);
// offsets[CYLINDER_Z1] = sizeof(float);
// offsets[CYLINDER_RADIUS] = sizeof(float);
offsets[SPECULAR_ADD] = sizeof(float);
offsets[SPECULAR_POWER] = sizeof(int);
offsets[PATH_WIDTH_SCALE] = sizeof(float);
offsets[STARTPOINT_SCALE] = sizeof(float);
offsets[NUM_DOTS] = sizeof(int);
offsets[NUM_CONNECTIONS] = sizeof(int);
offsets[DOT_POSITIONS] = sizeof(void*);
offsets[DOT_FLAGS] = sizeof(void*);
offsets[DOT_CONNECTION_A] = sizeof(void*);
offsets[DOT_CONNECTION_B] = sizeof(void*);
offsets[DECORATIONS] = sizeof(void*);
offsets[DECORATION_FLAGS] = sizeof(void*);
offsets[DECORATION_COLORS] = sizeof(void*);
offsets[NUM_DECORATIONS] = sizeof(int);
offsets[REFLECTION_DATA] = sizeof(void*);
offsets[GRID_SIZE_X] = sizeof(int);
offsets[GRID_SIZE_Y] = sizeof(int);
offsets[STYLE_FLAGS] = sizeof(int);
offsets[SEQUENCE_LEN] = sizeof(int);
offsets[SEQUENCE] = sizeof(void*);
offsets[DOT_SEQUENCE_LEN] = sizeof(int);
offsets[DOT_SEQUENCE] = sizeof(void*);
offsets[DOT_SEQUENCE_LEN_REFLECTION] = sizeof(int);
offsets[DOT_SEQUENCE_REFLECTION] = sizeof(void*);
offsets[NUM_COLORED_REGIONS] = sizeof(int);
offsets[COLORED_REGIONS] = sizeof(void*);
offsets[PANEL_TARGET] = sizeof(void*);
offsets[SPECULAR_TEXTURE] = sizeof(void*);
}
for (auto const& [offset, size] : offsets) {
std::vector<byte> panel1data = ReadPanelData<byte>(panel1, offset, size);
std::vector<byte> panel2data = ReadPanelData<byte>(panel2, offset, size);
WritePanelData<byte>(panel2, offset, panel1data);
WritePanelData<byte>(panel1, offset, panel2data);
}
}
void RandomizerCore::ReassignTargets(const std::vector<int>& panels, const std::vector<int>& order) {
// 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.
std::vector<int> targetToActivatePanel = {panels[0] + 1};
for (const int panel : panels) {
int target = ReadPanelData<int>(panel, TARGET, 1)[0];
targetToActivatePanel.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 = targetToActivatePanel[order[i+1]];
WritePanelData<int>(panels[order[i]], TARGET, {panelTarget});
}
}
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