#include "Tileset.h" #include "SimpleIStringStream.h" #include "Base.h" #include "ttvfs_stdio.h" #include "TextureMgr.h" #include "Core.h" Tileset::Tileset() { } Tileset::~Tileset() { clear(); } bool Tileset::loadFile(const char *fn, const unsigned char *usedIdx, size_t usedIdxLen) { clear(); InStream in(fn); if(!in) return false; bool warn = false; std::string line, gfx; while (std::getline(in, line)) { gfx.clear(); int idx=-1, w=0, h=0; SimpleIStringStream is(line.c_str(), SimpleIStringStream::REUSE); is >> idx >> gfx >> w >> h; if(idx >= 0 && !gfx.empty()) { if(idx < 1024) { ElementTemplate *et = new ElementTemplate; et->idx = idx; et->gfx = gfx; et->w = w; et->h = h; elementTemplates.push_back(et); } else warn = true; } } in.close(); if(warn) errorLog("Tileset indices of 1024 and above are reserved; ignored during load"); std::sort(elementTemplates.begin(), elementTemplates.end()); // begin preloading textures std::vector usedTex; usedTex.reserve(elementTemplates.size()); // optimistically assume all textures in the tileset are used for (size_t i = 0; i < elementTemplates.size(); i++) { size_t idx = elementTemplates[i]->idx; if (!usedIdx || (idx < usedIdxLen && usedIdx[idx])) usedTex.push_back(elementTemplates[i]->gfx); } std::sort(usedTex.begin(), usedTex.end()); // drop duplicates usedTex.resize(std::distance(usedTex.begin(), std::unique(usedTex.begin(), usedTex.end()))); { std::ostringstream os; os << "Loading " << usedTex.size() << " used textures out of the " << elementTemplates.size() << " tileset entries"; debugLog(os.str()); } // preload all used textures size_t loaded = 0; if(usedTex.size()) loaded = core->texmgr.loadBatch(NULL, &usedTex[0], usedTex.size()); { std::ostringstream os; os << "Loaded " << loaded << " textures successfully"; debugLog(os.str()); } // finalize size_t nfailed = 0; std::ostringstream failed; for (size_t i = 0; i < elementTemplates.size(); i++) { ElementTemplate *et = elementTemplates[i]; // only check those that are actualy loaded; otherwise this would load in textures // that we didn't bother to batch-load above if(!usedIdx || (et->idx < usedIdxLen && usedIdx[et->idx])) { et->finalize(); // assigns width/height and caches texture pointer if(!et->tex) { ++nfailed; failed << et->gfx << " "; } } } if(nfailed) { std::ostringstream os; os << "The following " << nfailed << " textures failed to load and would be used by tiles:"; debugLog(os.str()); debugLog(failed.str()); } return true; } void Tileset::clear() { for(size_t i = 0; i < dummies.size(); ++i) delete dummies[i]; dummies.clear(); for(size_t i = 0; i < elementTemplates.size(); ++i) delete elementTemplates[i]; elementTemplates.clear(); } const ElementTemplate *Tileset::getByIdx(size_t idx) { for (size_t i = 0; i < elementTemplates.size(); i++) { ElementTemplate *et = elementTemplates[i]; if (et->idx == idx) { et->finalize(); // HACK: make sure the texture is loaded before this gets used return et; } } // a tile that gets an ET attached must remember its tileset id even if the entry is not present // in the tileset. since the tile does not store the idx as an integer, we need to return a dummy element. for (size_t i = 0; i < dummies.size(); i++) { ElementTemplate *et = dummies[i]; if (et->idx == idx) return et; } { std::ostringstream os; os << "Tileset idx " << idx << " not found, creating dummy"; debugLog(os.str()); } ElementTemplate *dummy = new ElementTemplate; dummy->idx = idx; dummy->finalize(); dummies.push_back(dummy); return dummy; } const ElementTemplate* Tileset::getAdjacent(size_t idx, int direction, bool wraparound) { ElementTemplate *et = _getAdjacent(idx, direction, wraparound); if(et) et->finalize(); // load just in case return et; } ElementTemplate::~ElementTemplate() { delete grid; } void ElementTemplate::finalize() { if(!gfx.empty()) tex = core->getTexture(gfx); // may end up NULL if(tex) { if(!w) w = tex->width; if(!h) h = tex->height; } else { if(!w) w = 64; if(!h) h = 64; } if(tc.isStandard()) { delete grid; grid = NULL; } else { if(!grid) grid = new RenderGrid; grid->init(2, 2, tc); } } ElementTemplate * Tileset::_getAdjacent(size_t idx, int direction, bool wraparound) { assert(direction == 1 || direction == -1); const size_t maxn = elementTemplates.size(); size_t closest = 0; int mindiff = 0; for (size_t i = 0; i < maxn; i++) { if (elementTemplates[i]->idx == idx) { if(wraparound) { if(!i && direction < 0) return elementTemplates.back(); if(i + direction >= maxn) return elementTemplates[0]; } else i += direction; // may underflow return i < maxn ? elementTemplates[i] : NULL; } int diff = labs((int)elementTemplates[i]->idx - (int)idx); if(diff < mindiff || !mindiff) { mindiff = diff; closest = i; } } // not found? pick whatever was closest to the non-existing idx, and go back/forward from there // avoid going "twice" in the given direction if(closest < idx && direction < 0) direction = 0; // this is already a step back, don't step again else if(closest > idx && direction > 0) direction = 0; // this is already a step forward, don't step again else if(wraparound) { if(!closest && direction < 0) return elementTemplates.back(); if(closest + direction >= maxn) return elementTemplates[0]; } size_t i = closest + direction; return i < maxn ? elementTemplates[i] : NULL; }