#include "wled.h" /* * Utility for SPIFFS filesystem */ #ifndef WLED_DISABLE_FILESYSTEM #ifdef ARDUINO_ARCH_ESP32 #include "esp_spiffs.h" //FS info bare IDF function until FS wrapper is available for ESP32 #endif #define FS_BUFSIZE 256 //allow presets to be added until this percentage of FS space is used #define FS_QUOTA 75 /* * Structural requirements for files managed by writeObjectToFile() and readObjectFromFile() utilities: * 1. File must be a string representation of a valid JSON object * 2. File must have '{' as first character * 3. There must not be any additional characters between a root-level key and its value object (e.g. space, tab, newline) * 4. There must not be any characters between an root object-separating ',' and the next object key string * 5. There may be any number of spaces, tabs, and/or newlines before such object-separating ',' * 6. There must not be more than 5 consecutive spaces at any point except for those permitted in condition 5 * 7. If it is desired to delete the first usable object (e.g. preset file), a dummy object '"0":{}' is inserted at the beginning. * It shall be disregarded by receiving software. * The reason for it is that deleting the first preset would require special code to handle commas between it and the 2nd preset */ // There are no consecutive spaces longer than this in the file, so if more space is required, findSpace() can return false immediately // Actual space may be lower uint16_t knownLargestSpace = UINT16_MAX; File f; //wrapper to find out how long closing takes void closeFile() { DEBUGFS_PRINT(F("Close -> ")); uint32_t s = millis(); f.close(); DEBUGFS_PRINTF("took %d ms\n", millis() - s); doCloseFile = false; } //find() that reads and buffers data from file stream in 256-byte blocks. //Significantly faster, f.find(key) can take SECONDS for multi-kB files bool bufferedFind(const char *target, bool fromStart = true) { #ifdef WLED_DEBUG_FS DEBUGFS_PRINT("Find "); DEBUGFS_PRINTLN(target); uint32_t s = millis(); #endif if (!f || !f.size()) return false; size_t targetLen = strlen(target); size_t index = 0; byte c; uint16_t bufsize = 0, count = 0; byte buf[FS_BUFSIZE]; if (fromStart) f.seek(0); while (f.position() < f.size() -1) { bufsize = f.read(buf, FS_BUFSIZE); count = 0; while (count < bufsize) { if(buf[count] != target[index]) index = 0; // reset index if any char does not match if(buf[count] == target[index]) { if(++index >= targetLen) { // return true if all chars in the target match f.seek((f.position() - bufsize) + count +1); DEBUGFS_PRINTF("Found at pos %d, took %d ms", f.position(), millis() - s); return true; } } count++; } } DEBUGFS_PRINTF("No match, took %d ms\n", millis() - s); return false; } //find empty spots in file stream in 256-byte blocks. bool bufferedFindSpace(uint16_t targetLen, bool fromStart = true) { #ifdef WLED_DEBUG_FS DEBUGFS_PRINTF("Find %d spaces\n", targetLen); uint32_t s = millis(); #endif if (knownLargestSpace < targetLen) { DEBUGFS_PRINT(F("No match, KLS ")); DEBUGFS_PRINTLN(knownLargestSpace); return false; } if (!f || !f.size()) return false; uint16_t index = 0; uint16_t bufsize = 0, count = 0; byte buf[FS_BUFSIZE]; if (fromStart) f.seek(0); while (f.position() < f.size() -1) { bufsize = f.read(buf, FS_BUFSIZE); count = 0; while (count < bufsize) { if(buf[count] == ' ') { if(++index >= targetLen) { // return true if space long enough if (fromStart) { f.seek((f.position() - bufsize) + count +1 - targetLen); knownLargestSpace = UINT16_MAX; //there may be larger spaces after, so we don't know } DEBUGFS_PRINTF("Found at pos %d, took %d ms", f.position(), millis() - s); return true; } } else { if (!fromStart) return false; if (index) { if (knownLargestSpace < index || knownLargestSpace == UINT16_MAX) knownLargestSpace = index; index = 0; // reset index if not space } } count++; } } DEBUGFS_PRINTF("No match, took %d ms\n", millis() - s); return false; } //find the closing bracket corresponding to the opening bracket at the file pos when calling this function bool bufferedFindObjectEnd() { #ifdef WLED_DEBUG_FS DEBUGFS_PRINTLN(F("Find obj end")); uint32_t s = millis(); #endif if (!f || !f.size()) return false; uint16_t objDepth = 0; //num of '{' minus num of '}'. return once 0 uint16_t bufsize = 0, count = 0; //size_t start = f.position(); byte buf[FS_BUFSIZE]; while (f.position() < f.size() -1) { bufsize = f.read(buf, FS_BUFSIZE); count = 0; while (count < bufsize) { if (buf[count] == '{') objDepth++; if (buf[count] == '}') objDepth--; if (objDepth == 0) { f.seek((f.position() - bufsize) + count +1); DEBUGFS_PRINTF("} at pos %d, took %d ms", f.position(), millis() - s); return true; } count++; } } DEBUGFS_PRINTF("No match, took %d ms\n", millis() - s); return false; } //fills n bytes from current file pos with ' ' characters void writeSpace(uint16_t l) { byte buf[FS_BUFSIZE]; memset(buf, ' ', FS_BUFSIZE); while (l > 0) { uint16_t block = (l>FS_BUFSIZE) ? FS_BUFSIZE : l; f.write(buf, block); l -= block; } if (knownLargestSpace < l) knownLargestSpace = l; } bool appendObjectToFile(const char* key, JsonDocument* content, uint32_t s, uint32_t contentLen = 0) { #ifdef WLED_DEBUG_FS DEBUGFS_PRINTLN(F("Append")); uint32_t s1 = millis(); #endif uint32_t pos = 0; if (!f) return false; if (f.size() < 3) { char init[10]; strcpy_P(init, PSTR("{\"0\":{}}")); f.print(init); } if (content->isNull()) { doCloseFile = true; return true; //nothing to append } //if there is enough empty space in file, insert there instead of appending if (!contentLen) contentLen = measureJson(*content); DEBUGFS_PRINTF("CLen %d\n", contentLen); if (bufferedFindSpace(contentLen + strlen(key) + 1)) { if (f.position() > 2) f.write(','); //add comma if not first object f.print(key); serializeJson(*content, f); DEBUGFS_PRINTF("Inserted, took %d ms (total %d)", millis() - s1, millis() - s); doCloseFile = true; return true; } //not enough space, append at end if ((fsBytesUsed*100)/fsBytesTotal > FS_QUOTA) { //permitted space for presets exceeded errorFlag = ERR_FS_QUOTA; doCloseFile = true; return false; } //check if last character in file is '}' (typical) f.seek(1, SeekEnd); if (f.read() == '}') pos = f.size() -1; if (pos == 0) //not found { DEBUGFS_PRINTLN("not }"); while (bufferedFind("}", false)) //find last closing bracket in JSON if not last char { pos = f.position(); } } DEBUGFS_PRINT("pos "); DEBUGFS_PRINTLN(pos); if (pos > 2) { f.seek(pos, SeekSet); f.write(','); } else { //file content is not valid JSON object f.seek(0, SeekSet); f.write('{'); //start JSON } f.print(key); //Append object serializeJson(*content, f); f.write('}'); doCloseFile = true; DEBUGFS_PRINTF("Appended, took %d ms (total %d)", millis() - s1, millis() - s); return true; } bool writeObjectToFileUsingId(const char* file, uint16_t id, JsonDocument* content) { char objKey[10]; sprintf(objKey, "\"%d\":", id); return writeObjectToFile(file, objKey, content); } bool writeObjectToFile(const char* file, const char* key, JsonDocument* content) { uint32_t s = 0; //timing #ifdef WLED_DEBUG_FS DEBUGFS_PRINTF("Write to %s with key %s >>>\n", file, key); serializeJson(*content, Serial); DEBUGFS_PRINTLN(); s = millis(); #endif uint32_t pos = 0; f = WLED_FS.open(file, "r+"); if (!f && !WLED_FS.exists(file)) f = WLED_FS.open(file, "w+"); if (!f) { DEBUGFS_PRINTLN(F("Failed to open!")); return false; } if (!bufferedFind(key)) //key does not exist in file { return appendObjectToFile(key, content, s); } //an object with this key already exists, replace or delete it pos = f.position(); //measure out end of old object bufferedFindObjectEnd(); uint32_t pos2 = f.position(); uint32_t oldLen = pos2 - pos; DEBUGFS_PRINTF("Old obj len %d\n", oldLen); //Three cases: //1. The new content is null, overwrite old obj with spaces //2. The new content is smaller than the old, overwrite and fill diff with spaces //3. The new content is larger than the old, but smaller than old + trailing spaces, overwrite with new //4. The new content is larger than old + trailing spaces, delete old and append uint32_t contentLen = 0; if (!content->isNull()) contentLen = measureJson(*content); if (contentLen && contentLen <= oldLen) { //replace and fill diff with spaces DEBUGFS_PRINTLN(F("replace")); f.seek(pos); serializeJson(*content, f); writeSpace(pos2 - f.position()); } else if (contentLen && bufferedFindSpace(contentLen - oldLen, false)) { //enough leading spaces to replace DEBUGFS_PRINTLN(F("replace (trailing)")); f.seek(pos); serializeJson(*content, f); } else { DEBUGFS_PRINTLN(F("delete")); pos -= strlen(key); if (pos > 3) pos--; //also delete leading comma if not first object f.seek(pos); writeSpace(pos2 - pos); if (contentLen) return appendObjectToFile(key, content, s, contentLen); } doCloseFile = true; DEBUGFS_PRINTF("Replaced/deleted, took %d ms\n", millis() - s); return true; } bool readObjectFromFileUsingId(const char* file, uint16_t id, JsonDocument* dest) { char objKey[10]; sprintf(objKey, "\"%d\":", id); return readObjectFromFile(file, objKey, dest); } bool readObjectFromFile(const char* file, const char* key, JsonDocument* dest) { if (doCloseFile) closeFile(); #ifdef WLED_DEBUG_FS DEBUGFS_PRINTF("Read from %s with key %s >>>\n", file, key); uint32_t s = millis(); #endif f = WLED_FS.open(file, "r"); if (!f) return false; if (!bufferedFind(key)) //key does not exist in file { f.close(); dest->clear(); DEBUGFS_PRINTLN(F("Obj not found.")); return false; } deserializeJson(*dest, f); f.close(); DEBUGFS_PRINTF("Read, took %d ms\n", millis() - s); return true; } void updateFSInfo() { #ifdef ARDUINO_ARCH_ESP32 esp_spiffs_info(nullptr, &fsBytesTotal, &fsBytesUsed); #else FSInfo fsi; WLED_FS.info(fsi); fsBytesUsed = fsi.usedBytes; fsBytesTotal = fsi.totalBytes; #endif } #endif #if !defined WLED_DISABLE_FILESYSTEM && defined WLED_ENABLE_FS_SERVING //Un-comment any file types you need String getContentType(AsyncWebServerRequest* request, String filename){ if(request->hasArg("download")) return "application/octet-stream"; else if(filename.endsWith(".htm")) return "text/html"; else if(filename.endsWith(".html")) return "text/html"; // else if(filename.endsWith(".css")) return "text/css"; // else if(filename.endsWith(".js")) return "application/javascript"; else if(filename.endsWith(".json")) return "application/json"; else if(filename.endsWith(".png")) return "image/png"; // else if(filename.endsWith(".gif")) return "image/gif"; else if(filename.endsWith(".jpg")) return "image/jpeg"; else if(filename.endsWith(".ico")) return "image/x-icon"; // else if(filename.endsWith(".xml")) return "text/xml"; // else if(filename.endsWith(".pdf")) return "application/x-pdf"; // else if(filename.endsWith(".zip")) return "application/x-zip"; // else if(filename.endsWith(".gz")) return "application/x-gzip"; return "text/plain"; } bool handleFileRead(AsyncWebServerRequest* request, String path){ DEBUG_PRINTLN("FileRead: " + path); if(path.endsWith("/")) path += "index.htm"; if(path.indexOf("sec") > -1) return false; String contentType = getContentType(request, path); /*String pathWithGz = path + ".gz"; if(WLED_FS.exists(pathWithGz)){ request->send(WLED_FS, pathWithGz, contentType); return true; }*/ if(WLED_FS.exists(path)) { request->send(WLED_FS, path, contentType); return true; } return false; } #else bool handleFileRead(AsyncWebServerRequest*, String path){return false;} #endif