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Added a modified version of the SDFS lib : implemented the setTimeCallback() method :) it is working now

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anschrammh 2020-12-12 15:07:01 +01:00
parent 9db06f5be6
commit 4cf3b36f8d
4 changed files with 1106 additions and 0 deletions
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10
src/libs/SDFS/library.properties Normal file
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name=SDFS
version=0.1.0
author=Earle F. Philhower, III <earlephilhower@yahoo.com>
maintainer=Earle F. Philhower, III <earlephilhower@yahoo.com>
sentence=ESP8266 FS filesystem for use on SD cards using Bill Greiman's amazing FAT16/FAT32 Arduino library.
paragraph=ESP8266 FS filesystem for use on SD cards using Bill Greiman's amazing FAT16/FAT32 Arduino library.
category=Data Storage
url=https://github.com/esp8266/Arduino
architectures=esp8266
dot_a_linkage=true

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src/libs/SDFS/src/SDFS.cpp Normal file
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/*
SDFS.cpp - file system wrapper for SdFat
Copyright (c) 2019 Earle F. Philhower, III. All rights reserved.
Based on spiffs_api.cpp which is:
| Copyright (c) 2015 Ivan Grokhotkov. All rights reserved.
This code was influenced by NodeMCU and Sming libraries, and first version of
Arduino wrapper written by Hristo Gochkov.
This file is part of the esp8266 core for Arduino environment.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include "SDFS.h"
#include "SDFSFormatter.h"
#include <FS.h>
using namespace fs;
#if !defined(NO_GLOBAL_INSTANCES) && !defined(NO_GLOBAL_SDFS)
FS SDFS = FS(FSImplPtr(new sdfs::SDFSImpl()));
#endif
namespace sdfs {
FileImplPtr SDFSImpl::open(const char* path, OpenMode openMode, AccessMode accessMode)
{
if (!_mounted) {
DEBUGV("SDFSImpl::open() called on unmounted FS\n");
return FileImplPtr();
}
if (!path || !path[0]) {
DEBUGV("SDFSImpl::open() called with invalid filename\n");
return FileImplPtr();
}
int flags = _getFlags(openMode, accessMode);
if ((openMode && OM_CREATE) && strchr(path, '/')) {
// For file creation, silently make subdirs as needed. If any fail,
// it will be caught by the real file open later on
char *pathStr = strdup(path);
if (pathStr) {
// Make dirs up to the final fnamepart
char *ptr = strrchr(pathStr, '/');
if (ptr && ptr != pathStr) { // Don't try to make root dir!
*ptr = 0;
_fs.mkdir(pathStr, true);
}
}
free(pathStr);
}
sdfat::File fd = _fs.open(path, flags);
if (!fd) {
DEBUGV("SDFSImpl::openFile: fd=%p path=`%s` openMode=%d accessMode=%d",
&fd, path, openMode, accessMode);
return FileImplPtr();
}
auto sharedFd = std::make_shared<sdfat::File>(fd);
return std::make_shared<SDFSFileImpl>(this, sharedFd, path);
}
DirImplPtr SDFSImpl::openDir(const char* path)
{
if (!_mounted) {
return DirImplPtr();
}
char *pathStr = strdup(path); // Allow edits on our scratch copy
if (!pathStr) {
// OOM
return DirImplPtr();
}
// Get rid of any trailing slashes
while (strlen(pathStr) && (pathStr[strlen(pathStr)-1]=='/')) {
pathStr[strlen(pathStr)-1] = 0;
}
// At this point we have a name of "/blah/blah/blah" or "blah" or ""
// If that references a directory, just open it and we're done.
sdfat::File dirFile;
const char *filter = "";
if (!pathStr[0]) {
// openDir("") === openDir("/")
dirFile = _fs.open("/", sdfat::O_RDONLY);
filter = "";
} else if (_fs.exists(pathStr)) {
dirFile = _fs.open(pathStr, sdfat::O_RDONLY);
if (dirFile.isDir()) {
// Easy peasy, path specifies an existing dir!
filter = "";
} else {
dirFile.close();
// This is a file, so open the containing dir
char *ptr = strrchr(pathStr, '/');
if (!ptr) {
// No slashes, open the root dir
dirFile = _fs.open("/", sdfat::O_RDONLY);
filter = pathStr;
} else {
// We've got slashes, open the dir one up
*ptr = 0; // Remove slash, truncare string
dirFile = _fs.open(pathStr, sdfat::O_RDONLY);
filter = ptr + 1;
}
}
} else {
// Name doesn't exist, so use the parent dir of whatever was sent in
// This is a file, so open the containing dir
char *ptr = strrchr(pathStr, '/');
if (!ptr) {
// No slashes, open the root dir
dirFile = _fs.open("/", sdfat::O_RDONLY);
filter = pathStr;
} else {
// We've got slashes, open the dir one up
*ptr = 0; // Remove slash, truncare string
dirFile = _fs.open(pathStr, sdfat::O_RDONLY);
filter = ptr + 1;
}
}
if (!dirFile) {
DEBUGV("SDFSImpl::openDir: path=`%s`\n", path);
return DirImplPtr();
}
auto sharedDir = std::make_shared<sdfat::File>(dirFile);
auto ret = std::make_shared<SDFSDirImpl>(filter, this, sharedDir, pathStr);
free(pathStr);
return ret;
}
bool SDFSImpl::format() {
if (_mounted) {
return false;
}
SDFSFormatter formatter;
bool ret = formatter.format(&_fs, _cfg._csPin, _cfg._spiSettings);
return ret;
}
time_t (*SDFSImpl::timeCallback)(void) = nullptr;
}; // namespace sdfs

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src/libs/SDFS/src/SDFS.h Normal file
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#ifndef SDFS_H
#define SDFS_H
/*
SDFS.h - file system wrapper for SdLib
Copyright (c) 2019 Earle F. Philhower, III. All rights reserved.
Based on spiffs_api.h, which is:
| Copyright (c) 2015 Ivan Grokhotkov. All rights reserved.
This code was influenced by NodeMCU and Sming libraries, and first version of
Arduino wrapper written by Hristo Gochkov.
This file is part of the esp8266 core for Arduino environment.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <limits>
#include <assert.h>
#include "FS.h"
#include "FSImpl.h"
#include "debug.h"
#include <SPI.h>
#include <SdFat.h>
#include <FS.h>
using namespace fs;
namespace sdfs {
class SDFSFileImpl;
class SDFSDirImpl;
class SDFSConfig : public FSConfig
{
public:
static constexpr uint32_t FSId = 0x53444653;
SDFSConfig(uint8_t csPin = 4, SPISettings spi = SD_SCK_MHZ(10)) : FSConfig(FSId, false), _csPin(csPin), _part(0), _spiSettings(spi) { }
SDFSConfig setAutoFormat(bool val = true) {
_autoFormat = val;
return *this;
}
SDFSConfig setCSPin(uint8_t pin) {
_csPin = pin;
return *this;
}
SDFSConfig setSPI(SPISettings spi) {
_spiSettings = spi;
return *this;
}
SDFSConfig setPart(uint8_t part) {
_part = part;
return *this;
}
// Inherit _type and _autoFormat
uint8_t _csPin;
uint8_t _part;
SPISettings _spiSettings;
};
class SDFSImpl : public FSImpl
{
public:
SDFSImpl() : _mounted(false)
{
}
FileImplPtr open(const char* path, OpenMode openMode, AccessMode accessMode) override;
bool exists(const char* path) override {
return _mounted ? _fs.exists(path) : false;
}
DirImplPtr openDir(const char* path) override;
bool rename(const char* pathFrom, const char* pathTo) override {
return _mounted ? _fs.rename(pathFrom, pathTo) : false;
}
bool info64(FSInfo64& info) override {
if (!_mounted) {
DEBUGV("SDFS::info: FS not mounted\n");
return false;
}
info.maxOpenFiles = 999; // TODO - not valid
info.blockSize = _fs.vol()->blocksPerCluster() * 512;
info.pageSize = 0; // TODO ?
info.maxPathLength = 255; // TODO ?
info.totalBytes =_fs.vol()->volumeBlockCount() * 512LL;
info.usedBytes = info.totalBytes - (_fs.vol()->freeClusterCount() * _fs.vol()->blocksPerCluster() * 512LL);
return true;
}
bool info(FSInfo& info) override {
FSInfo64 i;
if (!info64(i)) {
return false;
}
info.blockSize = i.blockSize;
info.pageSize = i.pageSize;
info.maxOpenFiles = i.maxOpenFiles;
info.maxPathLength = i.maxPathLength;
#ifdef DEBUG_ESP_PORT
if (i.totalBytes > (uint64_t)SIZE_MAX) {
// This catches both total and used cases, since used must always be < total.
DEBUG_ESP_PORT.printf_P(PSTR("WARNING: SD card size overflow (%lld>= 4GB). Please update source to use info64().\n"), i.totalBytes);
}
#endif
info.totalBytes = (size_t)i.totalBytes;
info.usedBytes = (size_t)i.usedBytes;
return true;
}
bool remove(const char* path) override {
return _mounted ? _fs.remove(path) : false;
}
bool mkdir(const char* path) override {
return _mounted ? _fs.mkdir(path) : false;
}
bool rmdir(const char* path) override {
return _mounted ?_fs.rmdir(path) : false;
}
bool setConfig(const FSConfig &cfg) override
{
if ((cfg._type != SDFSConfig::FSId) || _mounted) {
DEBUGV("SDFS::setConfig: invalid config or already mounted\n");
return false;
}
_cfg = *static_cast<const SDFSConfig *>(&cfg);
return true;
}
bool begin() override {
if (_mounted) {
end();
}
_mounted = _fs.begin(_cfg._csPin, _cfg._spiSettings);
if (!_mounted && _cfg._autoFormat) {
format();
_mounted = _fs.begin(_cfg._csPin, _cfg._spiSettings);
}
sdfat::SdFile::dateTimeCallback(dateTimeCB);
return _mounted;
}
void end() override {
_mounted = false;
// TODO
}
bool format() override;
// The following are not common FS interfaces, but are needed only to
// support the older SD.h exports
uint8_t type() {
return _fs.card()->type();
}
uint8_t fatType() {
return _fs.vol()->fatType();
}
size_t blocksPerCluster() {
return _fs.vol()->blocksPerCluster();
}
size_t totalClusters() {
return _fs.vol()->clusterCount();
}
size_t totalBlocks() {
return (totalClusters() / blocksPerCluster());
}
size_t clusterSize() {
return blocksPerCluster() * 512; // 512b block size
}
size_t size() {
return (clusterSize() * totalClusters());
}
// Helper function, takes FAT and makes standard time_t
static time_t FatToTimeT(uint16_t d, uint16_t t) {
struct tm tiempo;
memset(&tiempo, 0, sizeof(tiempo));
tiempo.tm_sec = (((int)t) << 1) & 0x3e;
tiempo.tm_min = (((int)t) >> 5) & 0x3f;
tiempo.tm_hour = (((int)t) >> 11) & 0x1f;
tiempo.tm_mday = (int)(d & 0x1f);
tiempo.tm_mon = ((int)(d >> 5) & 0x0f) - 1;
tiempo.tm_year = ((int)(d >> 9) & 0x7f) + 80;
tiempo.tm_isdst = -1;
return mktime(&tiempo);
}
// Because SdFat has a single, global setting for this we can only use a
// static member of our class to return the time/date. However, since
// this is static, we can't see the time callback variable. Punt for now,
// using time(NULL) as the best we can do.
static void dateTimeCB(uint16_t *dosYear, uint16_t *dosTime) {
time_t now = (timeCallback == nullptr) ? time(nullptr) : (*timeCallback)();
//time_t now = time(nullptr);
struct tm *tiempo = localtime(&now);
*dosYear = ((tiempo->tm_year - 80) << 9) | ((tiempo->tm_mon + 1) << 5) | tiempo->tm_mday;
*dosTime = (tiempo->tm_hour << 11) | (tiempo->tm_min << 5) | tiempo->tm_sec;
}
virtual void setTimeCallback(time_t (*cb)(void))
{
timeCallback = cb;
}
protected:
friend class SDFileImpl;
friend class SDFSDirImpl;
sdfat::SdFat* getFs()
{
return &_fs;
}
static uint8_t _getFlags(OpenMode openMode, AccessMode accessMode) {
uint8_t mode = 0;
if (openMode & OM_CREATE) {
mode |= sdfat::O_CREAT;
}
if (openMode & OM_APPEND) {
mode |= sdfat::O_AT_END;
}
if (openMode & OM_TRUNCATE) {
mode |= sdfat::O_TRUNC;
}
if (accessMode & AM_READ) {
mode |= sdfat::O_READ;
}
if (accessMode & AM_WRITE) {
mode |= sdfat::O_WRITE;
}
return mode;
}
sdfat::SdFat _fs;
SDFSConfig _cfg;
bool _mounted;
private:
static time_t (*timeCallback)(void);
};
class SDFSFileImpl : public FileImpl
{
public:
SDFSFileImpl(SDFSImpl *fs, std::shared_ptr<sdfat::File> fd, const char *name)
: _fs(fs), _fd(fd), _opened(true)
{
_name = std::shared_ptr<char>(new char[strlen(name) + 1], std::default_delete<char[]>());
strcpy(_name.get(), name);
}
~SDFSFileImpl() override
{
flush();
close();
}
size_t write(const uint8_t *buf, size_t size) override
{
return _opened ? _fd->write(buf, size) : -1;
}
size_t read(uint8_t* buf, size_t size) override
{
return _opened ? _fd->read(buf, size) : -1;
}
void flush() override
{
if (_opened) {
_fd->flush();
_fd->sync();
}
}
bool seek(uint32_t pos, SeekMode mode) override
{
if (!_opened) {
return false;
}
switch (mode) {
case SeekSet:
return _fd->seekSet(pos);
case SeekEnd:
return _fd->seekEnd(-pos); // TODO again, odd from POSIX
case SeekCur:
return _fd->seekCur(pos);
default:
// Should not be hit, we've got an invalid seek mode
DEBUGV("SDFSFileImpl::seek: invalid seek mode %d\n", mode);
assert((mode==SeekSet) || (mode==SeekEnd) || (mode==SeekCur)); // Will fail and give meaningful assert message
return false;
}
}
size_t position() const override
{
return _opened ? _fd->curPosition() : 0;
}
size_t size() const override
{
return _opened ? _fd->fileSize() : 0;
}
bool truncate(uint32_t size) override
{
if (!_opened) {
DEBUGV("SDFSFileImpl::truncate: file not opened\n");
return false;
}
return _fd->truncate(size);
}
void close() override
{
if (_opened) {
_fd->close();
_opened = false;
}
}
const char* name() const override
{
if (!_opened) {
DEBUGV("SDFSFileImpl::name: file not opened\n");
return nullptr;
} else {
const char *p = _name.get();
const char *slash = strrchr(p, '/');
// For names w/o any path elements, return directly
// If there are slashes, return name after the last slash
// (note that strrchr will return the address of the slash,
// so need to increment to ckip it)
return (slash && slash[1]) ? slash + 1 : p;
}
}
const char* fullName() const override
{
return _opened ? _name.get() : nullptr;
}
bool isFile() const override
{
return _opened ? _fd->isFile() : false;;
}
bool isDirectory() const override
{
return _opened ? _fd->isDirectory() : false;
}
time_t getLastWrite() override {
time_t ftime = 0;
if (_opened && _fd) {
sdfat::dir_t tmp;
if (_fd.get()->dirEntry(&tmp)) {
ftime = SDFSImpl::FatToTimeT(tmp.lastWriteDate, tmp.lastWriteTime);
}
}
return ftime;
}
time_t getCreationTime() override {
time_t ftime = 0;
if (_opened && _fd) {
sdfat::dir_t tmp;
if (_fd.get()->dirEntry(&tmp)) {
ftime = SDFSImpl::FatToTimeT(tmp.creationDate, tmp.creationTime);
}
}
return ftime;
}
protected:
SDFSImpl* _fs;
std::shared_ptr<sdfat::File> _fd;
std::shared_ptr<char> _name;
bool _opened;
};
class SDFSDirImpl : public DirImpl
{
public:
SDFSDirImpl(const String& pattern, SDFSImpl* fs, std::shared_ptr<sdfat::File> dir, const char *dirPath = nullptr)
: _pattern(pattern), _fs(fs), _dir(dir), _valid(false), _dirPath(nullptr)
{
if (dirPath) {
_dirPath = std::shared_ptr<char>(new char[strlen(dirPath) + 1], std::default_delete<char[]>());
strcpy(_dirPath.get(), dirPath);
}
}
~SDFSDirImpl() override
{
_dir->close();
}
FileImplPtr openFile(OpenMode openMode, AccessMode accessMode) override
{
if (!_valid) {
return FileImplPtr();
}
// MAX_PATH on FAT32 is potentially 260 bytes per most implementations
char tmpName[260];
snprintf(tmpName, sizeof(tmpName), "%s%s%s", _dirPath.get() ? _dirPath.get() : "", _dirPath.get()&&_dirPath.get()[0]?"/":"", _lfn);
return _fs->open((const char *)tmpName, openMode, accessMode);
}
const char* fileName() override
{
if (!_valid) {
DEBUGV("SDFSDirImpl::fileName: directory not valid\n");
return nullptr;
}
return (const char*) _lfn; //_dirent.name;
}
size_t fileSize() override
{
if (!_valid) {
return 0;
}
return _size;
}
time_t fileTime() override
{
if (!_valid) {
return 0;
}
return _time;
}
time_t fileCreationTime() override
{
if (!_valid) {
return 0;
}
return _creation;
}
bool isFile() const override
{
return _valid ? _isFile : false;
}
bool isDirectory() const override
{
return _valid ? _isDirectory : false;
}
bool next() override
{
const int n = _pattern.length();
do {
sdfat::File file;
file.openNext(_dir.get(), sdfat::O_READ);
if (file) {
_valid = 1;
_size = file.fileSize();
_isFile = file.isFile();
_isDirectory = file.isDirectory();
sdfat::dir_t tmp;
if (file.dirEntry(&tmp)) {
_time = SDFSImpl::FatToTimeT(tmp.lastWriteDate, tmp.lastWriteTime);
_creation = SDFSImpl::FatToTimeT(tmp.creationDate, tmp.creationTime);
} else {
_time = 0;
_creation = 0;
}
file.getName(_lfn, sizeof(_lfn));
file.close();
} else {
_valid = 0;
}
} while(_valid && strncmp((const char*) _lfn, _pattern.c_str(), n) != 0);
return _valid;
}
bool rewind() override
{
_valid = false;
_dir->rewind();
return true;
}
protected:
String _pattern;
SDFSImpl* _fs;
std::shared_ptr<sdfat::File> _dir;
bool _valid;
char _lfn[64];
time_t _time;
time_t _creation;
std::shared_ptr<char> _dirPath;
uint32_t _size;
bool _isFile;
bool _isDirectory;
};
}; // namespace sdfs
#if !defined(NO_GLOBAL_INSTANCES) && !defined(NO_GLOBAL_SDFS)
extern FS SDFS;
using sdfs::SDFSConfig;
#endif
#endif // SDFS.h

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src/libs/SDFS/src/SDFSFormatter.h Normal file
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/*
SDFSFormatter.cpp - Formatter for SdFat SD cards
Copyright (c) 2019 Earle F. Philhower, III. All rights reserved.
A C++ implementation of the SdFat/examples/SdFormatter sketch:
| Copyright (c) 2011-2018 Bill Greiman
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
#ifndef _SDFSFORMATTER_H
#define _SDFSFORMATTER_H
#include "SDFS.h"
#include <FS.h>
#include <PolledTimeout.h>
namespace sdfs {
class SDFSFormatter {
private:
// Taken from main FS object
sdfat::Sd2Card *card;
sdfat::cache_t *cache;
uint32_t cardSizeBlocks;
uint32_t cardCapacityMB;
// MBR information
uint8_t partType;
uint32_t relSector;
uint32_t partSize;
// Fake disk geometry
uint8_t numberOfHeads;
uint8_t sectorsPerTrack;
// FAT parameters
uint16_t reservedSectors;
uint8_t sectorsPerCluster;
uint32_t fatStart;
uint32_t fatSize;
uint32_t dataStart;
uint8_t writeCache(uint32_t lbn) {
return card->writeBlock(lbn, cache->data);
}
void clearCache(uint8_t addSig) {
memset(cache, 0, sizeof(*cache));
if (addSig) {
cache->mbr.mbrSig0 = sdfat::BOOTSIG0;
cache->mbr.mbrSig1 = sdfat::BOOTSIG1;
}
}
bool clearFatDir(uint32_t bgn, uint32_t count) {
clearCache(false);
if (!card->writeStart(bgn, count)) {
DEBUGV("SDFS: Clear FAT/DIR writeStart failed");
return false;
}
esp8266::polledTimeout::periodicFastMs timeToYield(5); // Yield every 5ms of runtime
for (uint32_t i = 0; i < count; i++) {
if (timeToYield) {
delay(0); // WDT feed
}
if (!card->writeData(cache->data)) {
DEBUGV("SDFS: Clear FAT/DIR writeData failed");
return false;
}
}
if (!card->writeStop()) {
DEBUGV("SDFS: Clear FAT/DIR writeStop failed");
return false;
}
return true;
}
uint16_t lbnToCylinder(uint32_t lbn) {
return lbn / (numberOfHeads * sectorsPerTrack);
}
uint8_t lbnToHead(uint32_t lbn) {
return (lbn % (numberOfHeads * sectorsPerTrack)) / sectorsPerTrack;
}
uint8_t lbnToSector(uint32_t lbn) {
return (lbn % sectorsPerTrack) + 1;
}
bool writeMbr() {
clearCache(true);
sdfat::part_t* p = cache->mbr.part;
p->boot = 0;
uint16_t c = lbnToCylinder(relSector);
if (c > 1023) {
DEBUGV("SDFS: MBR CHS");
return false;
}
p->beginCylinderHigh = c >> 8;
p->beginCylinderLow = c & 0XFF;
p->beginHead = lbnToHead(relSector);
p->beginSector = lbnToSector(relSector);
p->type = partType;
uint32_t endLbn = relSector + partSize - 1;
c = lbnToCylinder(endLbn);
if (c <= 1023) {
p->endCylinderHigh = c >> 8;
p->endCylinderLow = c & 0XFF;
p->endHead = lbnToHead(endLbn);
p->endSector = lbnToSector(endLbn);
} else {
// Too big flag, c = 1023, h = 254, s = 63
p->endCylinderHigh = 3;
p->endCylinderLow = 255;
p->endHead = 254;
p->endSector = 63;
}
p->firstSector = relSector;
p->totalSectors = partSize;
if (!writeCache(0)) {
DEBUGV("SDFS: write MBR");
return false;
}
return true;
}
uint32_t volSerialNumber() {
return (cardSizeBlocks << 8) + micros();
}
bool makeFat16() {
uint16_t const BU16 = 128;
uint32_t nc;
for (dataStart = 2 * BU16;; dataStart += BU16) {
nc = (cardSizeBlocks - dataStart)/sectorsPerCluster;
fatSize = (nc + 2 + 255)/256;
uint32_t r = BU16 + 1 + 2 * fatSize + 32;
if (dataStart < r) {
continue;
}
relSector = dataStart - r + BU16;
break;
}
// check valid cluster count for FAT16 volume
if (nc < 4085 || nc >= 65525) {
DEBUGV("SDFS: Bad cluster count");
}
reservedSectors = 1;
fatStart = relSector + reservedSectors;
partSize = nc * sectorsPerCluster + 2 * fatSize + reservedSectors + 32;
if (partSize < 32680) {
partType = 0X01;
} else if (partSize < 65536) {
partType = 0X04;
} else {
partType = 0X06;
}
// write MBR
if (!writeMbr()) {
DEBUGV("SDFS: writembr failed");
return false;
}
clearCache(true);
sdfat::fat_boot_t* pb = &cache->fbs;
pb->jump[0] = 0XEB;
pb->jump[1] = 0X00;
pb->jump[2] = 0X90;
for (uint8_t i = 0; i < sizeof(pb->oemId); i++) {
pb->oemId[i] = ' ';
}
pb->bytesPerSector = 512;
pb->sectorsPerCluster = sectorsPerCluster;
pb->reservedSectorCount = reservedSectors;
pb->fatCount = 2;
pb->rootDirEntryCount = 512;
pb->mediaType = 0XF8;
pb->sectorsPerFat16 = fatSize;
pb->sectorsPerTrack = sectorsPerTrack;
pb->headCount = numberOfHeads;
pb->hidddenSectors = relSector;
pb->totalSectors32 = partSize;
pb->driveNumber = 0X80;
pb->bootSignature = sdfat::EXTENDED_BOOT_SIG;
pb->volumeSerialNumber = volSerialNumber();
memcpy_P(pb->volumeLabel, PSTR("NO NAME "), sizeof(pb->volumeLabel));
memcpy_P(pb->fileSystemType, PSTR("FAT16 "), sizeof(pb->fileSystemType));
// write partition boot sector
if (!writeCache(relSector)) {
DEBUGV("SDFS: FAT16 write PBS failed");
return false;
}
// clear FAT and root directory
if (!clearFatDir(fatStart, dataStart - fatStart)) {
DEBUGV("SDFS: FAT16 clear root failed\n");
return false;
}
clearCache(false);
cache->fat16[0] = 0XFFF8;
cache->fat16[1] = 0XFFFF;
// write first block of FAT and backup for reserved clusters
if (!writeCache(fatStart) || !writeCache(fatStart + fatSize)) {
DEBUGV("FAT16 reserve failed");
return false;
}
return true;
}
bool makeFat32() {
uint16_t const BU32 = 8192;
uint32_t nc;
relSector = BU32;
for (dataStart = 2 * BU32;; dataStart += BU32) {
nc = (cardSizeBlocks - dataStart)/sectorsPerCluster;
fatSize = (nc + 2 + 127)/128;
uint32_t r = relSector + 9 + 2 * fatSize;
if (dataStart >= r) {
break;
}
}
// error if too few clusters in FAT32 volume
if (nc < 65525) {
DEBUGV("SDFS: Bad cluster count");
return false;
}
reservedSectors = dataStart - relSector - 2 * fatSize;
fatStart = relSector + reservedSectors;
partSize = nc * sectorsPerCluster + dataStart - relSector;
// type depends on address of end sector
// max CHS has lbn = 16450560 = 1024*255*63
if ((relSector + partSize) <= 16450560) {
// FAT32
partType = 0X0B;
} else {
// FAT32 with INT 13
partType = 0X0C;
}
if (!writeMbr()) {
DEBUGV("SDFS: writembr failed");
return false;
}
clearCache(true);
sdfat::fat32_boot_t* pb = &cache->fbs32;
pb->jump[0] = 0XEB;
pb->jump[1] = 0X00;
pb->jump[2] = 0X90;
for (uint8_t i = 0; i < sizeof(pb->oemId); i++) {
pb->oemId[i] = ' ';
}
pb->bytesPerSector = 512;
pb->sectorsPerCluster = sectorsPerCluster;
pb->reservedSectorCount = reservedSectors;
pb->fatCount = 2;
pb->mediaType = 0XF8;
pb->sectorsPerTrack = sectorsPerTrack;
pb->headCount = numberOfHeads;
pb->hidddenSectors = relSector;
pb->totalSectors32 = partSize;
pb->sectorsPerFat32 = fatSize;
pb->fat32RootCluster = 2;
pb->fat32FSInfo = 1;
pb->fat32BackBootBlock = 6;
pb->driveNumber = 0X80;
pb->bootSignature = sdfat::EXTENDED_BOOT_SIG;
pb->volumeSerialNumber = volSerialNumber();
memcpy_P(pb->volumeLabel, PSTR("NO NAME "), sizeof(pb->volumeLabel));
memcpy_P(pb->fileSystemType, PSTR("FAT32 "), sizeof(pb->fileSystemType));
// write partition boot sector and backup
if (!writeCache(relSector) || !writeCache(relSector + 6)) {
DEBUGV("SDFS: FAT32 write PBS failed");
return false;
}
clearCache(true);
// write extra boot area and backup
if (!writeCache(relSector + 2) || !writeCache(relSector + 8)) {
DEBUGV("SDFS: FAT32 PBS ext failed");
return false;
}
sdfat::fat32_fsinfo_t* pf = &cache->fsinfo;
pf->leadSignature = sdfat::FSINFO_LEAD_SIG;
pf->structSignature = sdfat::FSINFO_STRUCT_SIG;
pf->freeCount = 0XFFFFFFFF;
pf->nextFree = 0XFFFFFFFF;
// write FSINFO sector and backup
if (!writeCache(relSector + 1) || !writeCache(relSector + 7)) {
DEBUGV("SDFS: FAT32 FSINFO failed");
return false;
}
clearFatDir(fatStart, 2 * fatSize + sectorsPerCluster);
clearCache(false);
cache->fat32[0] = 0x0FFFFFF8;
cache->fat32[1] = 0x0FFFFFFF;
cache->fat32[2] = 0x0FFFFFFF;
// write first block of FAT and backup for reserved clusters
if (!writeCache(fatStart) || !writeCache(fatStart + fatSize)) {
DEBUGV("SDFS: FAT32 reserve failed");
return false;
}
return true;
}
public:
bool format(sdfat::SdFat *_fs, int8_t _csPin, SPISettings _spiSettings) {
card = static_cast<sdfat::Sd2Card*>(_fs->card());
cache = _fs->cacheClear();
if (!card->begin(_csPin, _spiSettings)) {
return false;
}
cardSizeBlocks = card->cardSize();
if (cardSizeBlocks == 0) {
return false;
}
cardCapacityMB = (cardSizeBlocks + 2047)/2048;
if (cardCapacityMB <= 6) {
return false; // Card is too small
} else if (cardCapacityMB <= 16) {
sectorsPerCluster = 2;
} else if (cardCapacityMB <= 32) {
sectorsPerCluster = 4;
} else if (cardCapacityMB <= 64) {
sectorsPerCluster = 8;
} else if (cardCapacityMB <= 128) {
sectorsPerCluster = 16;
} else if (cardCapacityMB <= 1024) {
sectorsPerCluster = 32;
} else if (cardCapacityMB <= 32768) {
sectorsPerCluster = 64;
} else {
// SDXC cards
sectorsPerCluster = 128;
}
// set fake disk geometry
sectorsPerTrack = cardCapacityMB <= 256 ? 32 : 63;
if (cardCapacityMB <= 16) {
numberOfHeads = 2;
} else if (cardCapacityMB <= 32) {
numberOfHeads = 4;
} else if (cardCapacityMB <= 128) {
numberOfHeads = 8;
} else if (cardCapacityMB <= 504) {
numberOfHeads = 16;
} else if (cardCapacityMB <= 1008) {
numberOfHeads = 32;
} else if (cardCapacityMB <= 2016) {
numberOfHeads = 64;
} else if (cardCapacityMB <= 4032) {
numberOfHeads = 128;
} else {
numberOfHeads = 255;
}
// Erase all data on card (TRIM)
uint32_t const ERASE_SIZE = 262144L;
uint32_t firstBlock = 0;
uint32_t lastBlock;
do {
lastBlock = firstBlock + ERASE_SIZE - 1;
if (lastBlock >= cardSizeBlocks) {
lastBlock = cardSizeBlocks - 1;
}
if (!card->erase(firstBlock, lastBlock)) {
return false; // Erase fail
}
delay(0); // yield to the OS to avoid WDT
firstBlock += ERASE_SIZE;
} while (firstBlock < cardSizeBlocks);
if (!card->readBlock(0, cache->data)) {
return false;
}
if (card->type() != sdfat::SD_CARD_TYPE_SDHC) {
return makeFat16();
} else {
return makeFat32();
}
}
}; // class SDFSFormatter
}; // namespace sdfs
#endif // _SDFSFORMATTER_H