diff options
Diffstat (limited to 'fatfs/documents')
54 files changed, 1414 insertions, 596 deletions
diff --git a/fatfs/documents/00index_e.html b/fatfs/documents/00index_e.html index 3646a38..b3b8adb 100644 --- a/fatfs/documents/00index_e.html +++ b/fatfs/documents/00index_e.html @@ -5,6 +5,8 @@ <meta http-equiv="Content-Style-Type" content="text/css">
<meta http-equiv="cache-control" content="no-cache">
<meta name="description" content="Open source FAT filesystem for embedded projects">
+<link rel="start" title="Site Top" href="../../">
+<link rel="up" title="Freewares" href="../../fsw_e.html">
<link rel="stylesheet" href="css_e.css" type="text/css" media="screen" title="ELM Default">
<title>FatFs - Generic FAT Filesystem Module</title>
</head>
@@ -19,18 +21,18 @@ <h4>Features</h4>
<ul>
- <li>DOS/Windows compatible FAT/exFAT filesystem.</li>
- <li>Platform independent. Easy to port.</li>
- <li>Very small footprint for program code and work area.</li>
- <li>Various <a href="doc/config.html">configuration options</a> to support for:
+ <li>DOS/Windows Compatible FAT/exFAT Filesystem.</li>
+ <li>Platform Independent. <a href="doc/appnote.html#port">Easy to port</a>.</li>
+ <li>Very Small <a href="doc/appnote.html#memory">Footprint</a> for Program Code and Work Area.</li>
+ <li>Various <a href="doc/config.html">Configuration Options</a> to Support for:
<ul>
- <li>Long file name in ANSI/OEM or Unicode.</li>
- <li>exFAT filesystem.</li>
- <li>Thread safe for RTOS.</li>
- <li>Multiple volumes (physical drives and partitions).</li>
- <li>Variable sector size.</li>
- <li>Multiple code pages including DBCS.</li>
- <li>Read-only, optional API, I/O buffer and etc...</li>
+ <li>Long File Name in ANSI/OEM or Unicode.</li>
+ <li>exFAT Filesystem, 64-bit LBA and GPT for Huge Storages.</li>
+ <li>Thread Safe for RTOS.</li>
+ <li>Multiple Volumes. (Physical Drives and Partitions)</li>
+ <li>Variable Sector Size.</li>
+ <li>Multiple Code Pages Including DBCS.</li>
+ <li>Read-only, Optional APIs, I/O Buffer and etc...</li>
</ul>
</li>
</ul>
@@ -67,7 +69,7 @@ <ul>
<li><a href="doc/opendir.html">f_opendir</a> - Open a directory</li>
<li><a href="doc/closedir.html">f_closedir</a> - Close an open directory</li>
- <li><a href="doc/readdir.html">f_readdir</a> - Read an directory item</li>
+ <li><a href="doc/readdir.html">f_readdir</a> - Read a directory item</li>
<li><a href="doc/findfirst.html">f_findfirst</a> - Open a directory and read the first item matched</li>
<li><a href="doc/findnext.html">f_findnext</a> - Read a next item matched</li>
</ul>
@@ -89,8 +91,8 @@ <ul>
<li><a href="doc/mount.html">f_mount</a> - Register/Unregister the work area of the volume</li>
<li><a href="doc/mkfs.html">f_mkfs</a> - Create an FAT volume on the logical drive</li>
- <li><a href="doc/fdisk.html">f_fdisk</a> - Create logical drives on the physical drive</li>
- <li><a href="doc/getfree.html">f_getfree</a> - Get total size and free size on the volume</li>
+ <li><a href="doc/fdisk.html">f_fdisk</a> - Create partitions on the physical drive</li>
+ <li><a href="doc/getfree.html">f_getfree</a> - Get free space on the volume</li>
<li><a href="doc/getlabel.html">f_getlabel</a> - Get volume label</li>
<li><a href="doc/setlabel.html">f_setlabel</a> - Set volume label</li>
<li><a href="doc/setcp.html">f_setcp</a> - Set active code page</li>
@@ -103,39 +105,45 @@ <div class="para">
<h3>Media Access Interface</h3>
<img src="res/layers2.png" class="rset" width="245" height="220" alt="layer">
-<p>Since the FatFs module is the <em>filesystem layer</em> independent of platforms and storage media, it is completely separated from the physical devices, such as memory card, harddisk and any type of storage device. The low level device control module is <em>not a part of FatFs module</em> and it needs to be provided by implementer. FatFs accesses the storage devices via a simple media access interface shown below. Also sample implementations for some platforms are available in the downloads. A function checker for low level disk I/O module is available <a href="res/app4.c">here</a>.</p>
+<p>Since FatFs module is the <em>Filesystem Layer</em> independent of platforms and storage media, it is completely separated from the physical devices, such as memory card, harddisk and any type of storage device. The storage device control module is <em>not any part of FatFs module</em> and it needs to be provided by implementer. FatFs controls the storage devices via a simple media access interface shown below. Also sample implementations for some platforms are available in the downloads. A function checker for storage device control module is available <a href="res/app4.c">here</a>.</p>
<ul>
- <li><a href="doc/dstat.html">disk_status</a> - Get device status</li>
- <li><a href="doc/dinit.html">disk_initialize</a> - Initialize device</li>
- <li><a href="doc/dread.html">disk_read</a> - Read sector(s)</li>
- <li><a href="doc/dwrite.html">disk_write</a> - Write sector(s)</li>
- <li><a href="doc/dioctl.html">disk_ioctl</a> - Control device dependent functions</li>
- <li><a href="doc/fattime.html">get_fattime</a> - Get current time</li>
+ <li>Storage Device Controls
+ <ul>
+ <li><a href="doc/dstat.html">disk_status</a> - Get device status</li>
+ <li><a href="doc/dinit.html">disk_initialize</a> - Initialize device</li>
+ <li><a href="doc/dread.html">disk_read</a> - Read data</li>
+ <li><a href="doc/dwrite.html">disk_write</a> - Write data</li>
+ <li><a href="doc/dioctl.html">disk_ioctl</a> - Control device dependent functions</li>
+ </ul>
+ </li>
+ <li>Real Time Clock
+ <ul>
+ <li><a href="doc/fattime.html">get_fattime</a> - Get current time</li>
+ </ul>
+ </li>
</ul>
</div>
<div class="para">
<h3>Resources</h3>
-<p>The FatFs module is a free software opened for education, research and development. You can use, modify and/or redistribute it for personal projects or commercial products without any restriction under your responsibility. For further information, refer to the application note.</p>
+<p>The FatFs module is a free software opened for education, research and development. You can use, modify and/or redistribute it for any purpose without any restriction under your responsibility. For further information, refer to the application note.</p>
<ul>
- <li>Read first: <a href="doc/appnote.html">FatFs module application note</a></li>
- <li>Download: <a href="http://elm-chan.org/fsw/ff/archives.html">Archives of FatFs and Petit-FatFs</a></li>
+ <li><em>Getting Started: <a href="doc/appnote.html">FatFs Application Note</a></em></li>
<li>Community: <a href="http://elm-chan.org/fsw/ff/bd/">FatFs User Forum</a></li>
<li><a href="https://msdn.microsoft.com/en-us/windows/hardware/gg463080.aspx">FAT32 Specification by Microsoft</a>↗ (The authorized document on FAT filesystem)</li>
- <li><a href="http://elm-chan.org/docs/fat_e.html">The basics of FAT filesystem</a></li>
- <li><a href="http://elm-chan.org/docs/exfat_e.html">The basics of exFAT filesystem</a></li>
+ <li><a href="http://elm-chan.org/docs/fat_e.html">The basics of FAT filesystem</a> (FatFs is written based on this documentation)</li>
+ <li><a href="http://elm-chan.org/docs/exfat_e.html">The basics of exFAT filesystem</a> (FatFs is written based on this documentation)</li>
<li><a href="http://elm-chan.org/docs/mmc/mmc_e.html">How to use MMC/SDC</a></li>
<li><a href="http://elm-chan.org/junk/fa/faff.html">Playing with FlashAir and FatFs</a></li>
<li><a href="http://nemuisan.blog.bai.ne.jp/">Nemuisan's Blog</a>↗ (Well written implementations for STM32F/SPI & SDIO and LPC4088/SDMMC)</li>
<li><a href="http://stm32f4-discovery.net/2014/07/library-21-read-sd-card-fatfs-stm32f4xx-devices/">Read SD card with FatFs on STM32F4xx devices by Tilen Majerle</a>↗ (Quick and easy implementation for STM32F4-Discovery)</li>
<li><a href="res/rwtest1.png">Benchmark 1</a> (ATmega1284/20MHz with MMC via USART in SPI, CFC via GPIO)</li>
<li><a href="res/rwtest2.png">Benchmark 2</a> (LPC2368/72MHz with MMC via MCI)</li>
- <li><a href="res/fd.mp4">Demo movie of an application</a> (this project is in ffsample.zip/lpc23xx)</li></ul>
</div>
<hr>
-<p class="foot"><a href="http://elm-chan.org/fsw/ff/00index_e.html">FatFs Home Page</a></p>
+<p class="foot"><a href="../../fsw_e.html">Return</a></p>
</body>
</html>
diff --git a/fatfs/documents/css_e.css b/fatfs/documents/css_e.css index 8274af3..1181a09 100644 --- a/fatfs/documents/css_e.css +++ b/fatfs/documents/css_e.css @@ -14,6 +14,7 @@ strong {} pre {border: 1px dashed gray; margin: 0.5em 1em; padding: 0.5em; line-height: 1.2em; font-size: 85%; font-family: "Consolas", "Courier New", monospace; background-color: white;}
pre span.c {color: green;}
pre span.k {color: blue;}
+pre span.e {color: red;}
pre span.b {font-weight: bold;}
pre span.arg {font-style: italic;}
tt {margin: 0 0.2em; font-size: 0.85em; font-family: "Consolas", "Courier New", monospace; }
@@ -57,13 +58,16 @@ small {font-size: 80%;} .indent {margin-left: 2em;}
/* Tables */
-table {margin: 0.5em 1em; border-collapse: collapse; border: 2px solid black; }
-th {background-color: white; border-style: solid; border-width: 1px 1px 2px; border-color: black; padding: 0 3px; vertical-align: top; white-space: nowrap;}
-td {background-color: white; border: 1px solid black; padding: 0 3px; vertical-align: top; line-height: 1.3em;}
+table {margin: 0.5em 1em; border-collapse: collapse; border: 2px solid gray; }
+table caption {font-family: sans-serif; font-weight: bold;}
+table th {background-color: white; border-style: solid; border-width: 1px 1px 2px; border-color: gray; padding: 0 3px; vertical-align: top; white-space: nowrap;}
+table td {background-color: white; border: 1px solid gray; padding: 0 3px; vertical-align: top; line-height: 1.3em;}
table.lst td:first-child {font-size: 0.85em; font-family: "Consolas", "Courier New", monospace; white-space: nowrap;}
table.lst2 td {font-size: 0.85em; font-family: "Consolas", "Courier New", monospace; white-space: nowrap;}
table.lst3 td {font-family: "Consolas", "Courier New", monospace; white-space: nowrap;}
-table caption {font-family: sans-serif; font-weight: bold;}
-tr.lst3 td { border-width: 2px 1px 1px; }
+tr.lst3 td {border-width: 2px 1px 1px; }
+table.lst4 td {padding: 0.3em;}
+table.lst4 td:nth-child(2) {width: 45%;}
+table.lst4 td:nth-child(3) {width: 45%;}
p.foot {clear: both; text-indent: 0; margin: 1em 0.5em 1em;}
diff --git a/fatfs/documents/doc/appnote.html b/fatfs/documents/doc/appnote.html index ee88b42..5a7a2df 100644 --- a/fatfs/documents/doc/appnote.html +++ b/fatfs/documents/doc/appnote.html @@ -19,12 +19,13 @@ <li><a href="#lfn">Long File Name</a></li>
<li><a href="#unicode">Unicode API</a></li>
<li><a href="#exfat">exFAT Filesystem</a></li>
+<li><a href="#lba64">64-bit LBA</a></li>
<li><a href="#reentrant">Re-entrancy</a></li>
<li><a href="#dup">Duplicated File Access</a></li>
<li><a href="#fs1">Performance Effective File Access</a></li>
<li><a href="#fs2">Considerations on Flash Memory Media</a></li>
<li><a href="#critical">Critical Section</a></li>
-<li><a href="#fs3">Extended Use of FatFs API</a></li>
+<li><a href="#fs3">Various Usable Functions for FatFs Projects</a></li>
<li><a href="#license">About FatFs License</a></li>
</ol>
@@ -32,33 +33,58 @@ <h3>How to Port</h3>
<h4>Basic Considerations</h4>
-<p>The FatFs module is assuming following conditions on portability.</p>
+<p>The FatFs module assumes following conditions on portability.</p>
<ul>
<li>ANSI C<br>
-The FatFs module is a middleware written in ANSI C (C89). There is no platform dependence, so long as the compiler is in compliance with ANSI C.</li>
+The FatFs module is a middleware written in ANSI C (C89). There is no platform dependence, so long as the compiler is in compliance with C89 or later. Only exFAT feature requires C99.</li>
<li>Size of integer types<br>
-The FatFs module assumes that size of <tt>char</tt>/<tt>short</tt>/<tt>long</tt> are 8/16/32 bit and <tt>int</tt> is 16 or 32 bit. These correspondence are defined in <tt>integer.h</tt>. This will not be a problem on most compilers. When a conflict with existing definitions is occured, you must resolve it with care.</li>
+<ul>
+<li>Size of <tt>char</tt> must be 8-bit.</li>
+<li>Size of <tt>int</tt>, as well as integer promotion, must be 16-bit or 32-bit.</li>
+<li>Size of <tt>short</tt> and <tt>long</tt> must be 16-bit and 32-bit respectively. (in C89 only)</li>
+</ul>
+<li>Dependency<br>
+<ul>
+<li>C89: <tt>string.h</tt>.</li>
+<li>C99: <tt>string.h</tt> and <tt>stdint.h</tt>.</li>
+<li>Optional: <tt>stdarg.h</tt> and <tt>math.h</tt>.</li>
</ul>
+</ul>
+
+<h4>Integer Types in FatFs API</h4>
+<p>Integer types used in FatFs are defined in <tt>ff.h</tt> as described below. It is based on Win32 API (<tt>windef.h</tt>). This will not be a problem on most platform. When a conflict with existing definitions occured, you must resolve it with care.</p>
+<dl>
+<dt><tt>BYTE</tt></dt><dd>8-bit unsigned integer in range of 0 to 2<sup>8</sup> - 1.</dd>
+<dt><tt>WORD</tt></dt><dd>16-bit unsigned integer in range of 0 to 2<sup>16</sup> - 1.</dd>
+<dt><tt>DWORD</tt></dt><dd>32-bit unsigned integer in range of 0 to 2<sup>32</sup> - 1.</dd>
+<dt><tt>QWORD</tt></dt><dd>64-bit unsigned integer in range of 0 to 2<sup>64</sup> - 1.</dd>
+<dt><tt>UINT</tt></dt><dd>Alias of <tt>unsigned int</tt> used to specify any number.</dd>
+<dt><tt>WCHAR</tt></dt><dd>Alias of <tt>WORD</tt> used to specify a UTF-16 code unit.</dd>
+<dt><tt>TCHAR</tt></dt><dd>Alias of <tt>char</tt>, <tt>WCHAR</tt> or <tt>DWORD</tt> used to specify a character encoding unit.</dd>
+<dt><tt>FSIZE_t</tt></dt><dd>Alias of <tt>DWORD</tt> or <tt>QWORD</tt> used to address file offset and to specify file size.</dd>
+<dt><tt>LBA_t</tt></dt><dd>Alias of <tt>DWORD</tt> or <tt>QWORD</tt> used to address sectors in LBA and to specify number of sectors.</dd>
+</dl>
<h4>System Organizations</h4>
-<p>The dependency diagram shown below is a typical but not specific configuration of the embedded system with FatFs module.</p>
+<p>The dependency diagram shown below is a typical, but not specific, configuration of the embedded system with FatFs module.</p>
<p><img src="../res/modules.png" width="580" height="280" alt="dependency diagram"></p>
-<p>(a) If a working disk module with FatFs disk interface is provided, nothing else will be needed. (b) To attach existing disk drivers with different interface, glue functions are needed to translate the interfaces between FatFs and the drivers.</p>
+<p>(a) If a working disk module for FatFs is provided, nothing else will be needed. (b) To attach existing disk drivers with different interface, some glue functions are needed to translate the interfaces between FatFs and the driver.</p>
<p><img src="../res/funcs.png" width="750" height="420" alt="functional diagram"></p>
<h4>Required Functions</h4>
-<p>You need to provide only low level disk I/O functions required by FatFs module and nothing else. If a working disk module for the target system is already provided, you need to write only glue functions to attach it to the FatFs module. If not, you need to port another disk I/O module or write it from scratch. Most of defined functions are not that always required. For example, any write function is not required at read-only configuration. Following table shows which function is required depends on the configuration options.</p>
+<p>You need to provide only MAI functions required by FatFs module and nothing else. If a working device control module for the target system is available, you need to write only glue functions to attach it to the FatFs module. If not, you need to port another device control module or write it from scratch. Most of MAI functions are not that always required. For instance, the write function is not required in read-only configuration. Following table shows which function is required depends on the configuration options.</p>
<table class="lst2">
-<tr><th>Function</th><th>Required when</th><th>Note</th></tr>
+<tr><th>Function</th><th>Required when:</th><th>Note</th></tr>
<tr><td>disk_status<br>disk_initialize<br>disk_read</td><td>Always</td><td rowspan="5">Disk I/O functions.<br>Samples available in ffsample.zip.<br>There are many implementations on the web.</td></tr>
-<tr><td>disk_write<br>get_fattime<br>disk_ioctl (CTRL_SYNC)</td><td>FF_FS_READONLY == 0</td></tr>
-<tr><td>disk_ioctl (GET_SECTOR_COUNT)<br>disk_ioctl (GET_BLOCK_SIZE)</td><td>FF_USE_MKFS == 1</td></tr>
-<tr><td>disk_ioctl (GET_SECTOR_SIZE)</td><td>FF_MAX_SS != FF_MIN_SS</td></tr>
-<tr><td>disk_ioctl (CTRL_TRIM)</td><td>FF_USE_TRIM == 1</td></tr>
-<tr><td>ff_uni2oem<br>ff_oem2uni<br>ff_wtoupper</td><td>FF_USE_LFN != 0</td><td>Unicode support functions.<br>Just add ffunicode.c to the project.</td></tr>
-<tr><td>ff_cre_syncobj<br>ff_del_syncobj<br>ff_req_grant<br>ff_rel_grant</td><td>FF_FS_REENTRANT == 1</td><td rowspan="2">O/S dependent functions.<br>Samples available in ffsystem.c.</td></tr>
+<tr><td>disk_write<br>get_fattime<br>disk_ioctl (CTRL_SYNC)</td><td><a href="config.html#fs_readonly">FF_FS_READONLY == 0</a></td></tr>
+<tr><td>disk_ioctl (GET_SECTOR_COUNT)<br>disk_ioctl (GET_BLOCK_SIZE)</td><td><a href="config.html#use_mkfs">FF_USE_MKFS == 1</a></td></tr>
+<tr><td>disk_ioctl (GET_SECTOR_SIZE)</td><td><a href="config.html#max_ss">FF_MAX_SS != FF_MIN_SS</a></td></tr>
+<tr><td>disk_ioctl (CTRL_TRIM)</td><td><a href="config.html#use_trim">FF_USE_TRIM == 1</a></td></tr>
+<tr><td>ff_uni2oem<br>ff_oem2uni<br>ff_wtoupper</td><td><a href="config.html#use_lfn">FF_USE_LFN != 0</a></td><td>Unicode support functions.<br>Add optional module ffunicode.c to the project.</td></tr>
+<tr><td>ff_mutex_create<br>ff_mutex_delete<br>ff_mutex_take<br>ff_mutex_give</td><td><a href="config.html#fs_reentrant">FF_FS_REENTRANT == 1</a></td><td rowspan="2">O/S dependent functions.<br>Sample code is available in ffsystem.c.</td></tr>
<tr><td>ff_mem_alloc<br>ff_mem_free</td><td>FF_USE_LFN == 3</td></tr>
</table>
+<p>FatFs cares about neither what kind of storage device is used nor how it is implemented. Only a requirement is that it is a block device read/written in fixed-size blocks that accessible via the disk I/O functions defined above.</p>
</div>
<div class="para doc" id="limits">
@@ -66,11 +92,12 @@ The FatFs module assumes that size of <tt>char</tt>/<tt>short</tt>/<tt>long</tt> <ul>
<li>Filesystem type: FAT, FAT32(rev0.0) and exFAT(rev1.0).</li>
<li>Number of open files: Unlimited. (depends on available memory)</li>
-<li>Number of volumes: Upto 10.</li>
-<li>Volume size: Upto 2 TB at 512 bytes/sector.</li>
-<li>File size: Upto 4 GB - 1 on FAT volume and virtually unlimited on exFAT volume.</li>
-<li>Cluster size: Upto 128 sectors on FAT volume and upto 16 MB on exFAT volume.</li>
+<li>Number of volumes: Up to 10.</li>
<li>Sector size: 512, 1024, 2048 and 4096 bytes.</li>
+<li>Minimum volume size: 128 sectors.</li>
+<li>Maximum volume size: 2<sup>32</sup> - 1 sectors in 32-bit LBA, virtually unlimited in 64-bit LBA with exFAT.</li>
+<li>Maximum file size: 2<sup>32</sup> - 1 bytes on FAT volume, virtually unlimited on exFAT volume.</li>
+<li>Cluster size: Upto 128 sectors on FAT volume and up to 16 MB on exFAT volume.</li>
</ul>
</div>
@@ -81,29 +108,29 @@ The FatFs module assumes that size of <tt>char</tt>/<tt>short</tt>/<tt>long</tt> <tr><th></th><th>ARM7<small><br>32bit</small></th><th>ARM7<small><br>Thumb</small></th><th>CM3<small><br>Thumb-2</small></th><th>AVR</th><th>H8/300H</th><th>PIC24</th><th>RL78</th><th>V850ES</th><th>SH-2A</th><th>RX600</th><th>IA-32</th></tr>
<tr class="cal"> <td>Compiler</td><td>GCC</td><td>GCC</td><td>GCC</td><td>GCC</td><td>CH38</td><td>C30</td><td>CC78K0R</td><td>CA850</td><td>SHC</td><td>RXC</td><td>MSC</td></tr>
<!-- ARM Thumb CM3 AVR H8 PIC24 RL78 V850ES SH-2A RX600 IA-32 -->
-<tr class="ral"><td class="cal">text (Full, R/W)</td><td>10.4k</td><td>6.7k</td><td>6.3k</td><td>12.4k</td> <td>9.9k</td><td>11.2k</td><td>13.0k</td><td>8.7k</td><td>9.0k</td><td>6.5k</td><td>8.9k</td></tr>
-<tr class="ral"><td class="cal">text (Min, R/W)</td> <td>7.0k</td><td>4.7k</td><td>4.4k</td> <td>8.4k</td> <td>6.9k</td> <td>7.8k</td> <td>9.4k</td><td>6.0k</td><td>6.2k</td><td>4.6k</td><td>6.3k</td></tr>
-<tr class="ral"><td class="cal">text (Full, R/O)</td> <td>4.8k</td><td>3.1k</td><td>2.8k</td> <td>5.7k</td> <td>4.7k</td> <td>5.3k</td> <td>6.4k</td><td>4.2k</td><td>4.0k</td><td>3.1k</td><td>4.2k</td></tr>
-<tr class="ral"><td class="cal">text (Min, R/O)</td> <td>3.6k</td><td>2.4k</td><td>2.2k</td> <td>4.4k</td> <td>3.6k</td> <td>4.1k</td> <td>5.0k</td><td>3.3k</td><td>3.1k</td><td>2.4k</td><td>3.3k</td></tr>
-<tr class="ral"><td class="cal">bss</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*2 + 2</td><td>V*4 + 2</td><td>V*2 + 2</td><td>V*2 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td></tr>
+<tr class="ral"><td class="cal">.text (Def, R/W)</td><td>10.4k</td><td>6.7k</td><td>6.1k</td><td>12.5k</td><td>11.0k</td><td>11.4k</td><td>13.0k</td><td>8.9k</td><td>9.2k</td><td>6.5k</td><td>8.9k</td></tr>
+<tr class="ral"><td class="cal">.text (Min, R/W)</td> <td>7.0k</td><td>4.7k</td><td>4.2k</td> <td>8.5k</td> <td>7.6k</td> <td>7.9k</td> <td>9.5k</td><td>6.3k</td><td>6.4k</td><td>4.7k</td><td>6.4k</td></tr>
+<tr class="ral"><td class="cal">.text (Def, R/O)</td> <td>4.9k</td><td>3.2k</td><td>2.7k</td> <td>6.1k</td> <td>5.2k</td> <td>5.4k</td> <td>6.5k</td><td>4.3k</td><td>4.2k</td><td>3.2k</td><td>4.3k</td></tr>
+<tr class="ral"><td class="cal">.text (Min, R/O)</td> <td>3.7k</td><td>2.5k</td><td>2.1k</td> <td>4.4k</td> <td>4.0k</td> <td>4.2k</td> <td>5.1k</td><td>3.4k</td><td>3.3k</td><td>2.5k</td><td>3.5k</td></tr>
+<tr class="ral"><td class="cal">.bss</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*2 + 2</td><td>V*4 + 2</td><td>V*2 + 2</td><td>V*2 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td><td>V*4 + 2</td></tr>
<tr class="ral"><td class="cal">Work area<br><small>(FF_FS_TINY == 0)</small></td><td>V*564<br>+ F*552</td><td>V*564<br>+ F*552</td><td>V*564<br>+ F*552</td><td>V*560<br>+ F*546</td><td>V*560<br>+ F*546</td><td>V*560<br>+ F*546</td><td>V*560<br>+ F*546</td><td>V*564<br>+ F*552</td><td>V*564<br>+ F*552</td><td>V*564<br>+ F*552</td><td>V*564<br>+ F*552</td></tr>
<tr class="ral"><td class="cal">Work area<br><small>(FF_FS_TINY == 1)</small></td><td>V*564<br>+ F*40</td><td>V*564<br>+ F*40</td><td>V*564<br>+ F*40</td><td>V*560<br>+ F*34</td><td>V*560<br>+ F*34</td><td>V*560<br>+ F*34</td><td>V*560<br>+ F*34</td><td>V*564<br>+ F*40</td><td>V*564<br>+ F*40</td><td>V*564<br>+ F*40</td><td>V*564<br>+ F*40</td></tr>
</table>
-<p>These are the memory usage on some target systems with following condition. The memory sizes are in unit of byte, <em>V</em> denotes number of mounted volumes and <em>F</em> denotes number of open files. All samples here are optimezed in code size.</p>
+<p>These are the memory usage of FatFs module without lower layer on some target systems in following condition. <em>V</em> denotes number of mounted volumes and <em>F</em> denotes number of open files. Every samples here are optimezed in code size.</p>
<pre>
-FatFs R0.13a options:
-FF_FS_READONLY 0 (Read/Write) or 1 (Read only)
-FF_FS_MINIMIZE 0 (Full, with all basic functions) or 3 (Min, with fully minimized)
+FatFs R0.15 options:
+FF_FS_READONLY 0 (R/W, read/write) or 1 (R/O, read only)
+FF_FS_MINIMIZE 0 (Def, with all basic functions) or 3 (Min, with fully minimized)
FF_FS_TINY 0 (Default) or 1 (Tiny file object)
-And other options are left unchanged from original setting.
+And any other options are left unchanged from original setting.
</pre>
</div>
<div class="para doc" id="reduce">
-<h3>Reducing Modle Size</h3>
-<p>Follwing table shows which API function is removed by configuration options for the module size reduction. To use any API function, the row of the function must be clear.</p>
+<h3>Reducing Module Size</h3>
+<p>Follwing table shows which API function is removed by configuration options to reduce the module size. To use an API function, the row of the function must be clear.</p>
<table class="lst2">
-<tr><td rowspan="2">Function</td><td colspan="4">FF_FS_<br>MINIMIZE</td><td colspan="2">FF_FS_<br>READONLY</td><td colspan="2">FF_USE_<br>STRFUNC</td><td colspan="3">FF_FS_<br>RPATH</td><td colspan="2">FF_USE_<br>FIND</td><td colspan="2">FF_USE_<br>CHMOD</td><td colspan="2">FF_USE_<br>EXPAND</td><td colspan="2">FF_USE_<br>LABEL</td><td colspan="2">FF_USE_<br>MKFS</td><td colspan="2">FF_USE_<br>FORWARD</td><td colspan="2">FF_MULTI_<br>PARTITION</td></tr>
+<tr><td rowspan="2">Function</td><td colspan="4"><a href="config.html#fs_minimize">FF_FS_<br>MINIMIZE</a></td><td colspan="2"><a href="config.html#fs_readonly">FF_FS_<br>READONLY</a></td><td colspan="2"><a href="config.html#use_strfunc">FF_USE_<br>STRFUNC</a></td><td colspan="3"><a href="config.html#fs_rpath">FF_FS_<br>RPATH</a></td><td colspan="2"><a href="config.html#use_find">FF_USE_<br>FIND</a></td><td colspan="2"><a href="config.html#use_chmod">FF_USE_<br>CHMOD</a></td><td colspan="2"><a href="config.html#use_expand">FF_USE_<br>EXPAND</a></td><td colspan="2"><a href="config.html#use_label">FF_USE_<br>LABEL</a></td><td colspan="2"><a href="config.html#use_mkfs">FF_USE_<br>MKFS</a></td><td colspan="2"><a href="config.html#use_forward">FF_USE_<br>FORWARD</a></td><td colspan="2"><a href="config.html#multi_partition">FF_MULTI_<br>PARTITION</a></td></tr>
<tr> <td>0</td><td>1</td><td>2</td><td>3</td><td>0</td><td>1</td><td>0</td><td>1</td><td>0</td><td>1</td><td>2</td><td>0</td><td>1</td><td>0</td><td>1</td><td>0</td><td>1</td><td>0</td><td>1</td><td>0</td><td>1</td><td>0</td><td>1</td><td>0</td><td>1</td></tr>
<tr class="lst3">
<td>f_mount</td> <td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td><td> </td></tr>
@@ -144,141 +171,169 @@ And other options are left unchanged from original setting. <div class="para doc" id="lfn">
<h3>Long File Name</h3>
-<p>FatFs module supports long file name (LFN). The two different file names, short file name (SFN) and LFN, of a file is transparent on the API except for <tt>f_readdir</tt> function. The support for LFN is disabled by default. To enable the LFN, set <tt><a href="config.html#use_lfn">FF_USE_LFN</a></tt> to 1, 2 or 3, and add <tt>ffunicode.c</tt> to the project. The LFN requiers a certain working buffer in addition. The buffer size can be configured by <tt><a href="config.html#max_lfn">FF_MAX_LFN</a></tt> according to the available memory. The length of an LFN will be up to 255 characters, so that the <tt>FF_MAX_LFN</tt> should be set to 255 for all file names. If the size of working buffer is insufficient for the input file name, the file function fails with <tt>FR_INVALID_NAME</tt>. When use any re-entry to the API with LFN is enabled, <tt>FF_USE_LFN</tt> must be set to 2 or 3. In this case, the file function allocates the working buffer on the stack or heap. The working buffer occupies <tt>(FF_MAX_LFN + 1) * 2</tt> bytes and additional <tt>(FF_MAX_LFN + 44) / 15 * 32</tt> bytes when exFAT is enabled.</p>
-<table class="lst2 rset">
-<caption>With LFN at CM3+gcc</caption>
-<tr><th><tt>FF_CODE_PAGE</tt></th><th>Increment</th></tr>
-<tr><td>437-869 (SBCS)</td><td>+3.3k</td></tr>
-<tr><td>932 (Japanese)</td><td>+62k</td></tr>
-<tr><td>936 (Simplified Chinese)</td><td>+177k</td></tr>
-<tr><td>949 (Korean)</td><td>+140k</td></tr>
-<tr><td>950 (Traditional Chinese)</td><td>+111k</td></tr>
-<tr><td>0 (All code pages)</td><td>+486k</td></tr>
-</table>
-<p>When the LFN is enabled, the module size will be increased depends on the configured code page. Right table shows increment of code size by LFN function at different code pages. Especially, in the CJK region, tens of thousands of characters are being used. Unfortunately, it requires a huge OEM-Unicode bidirectional conversion table and the module size will be drastically increased as shown in the table. As the result, the FatFs with LFN enebled with those code pages will not able to be ported on the most 8-bit MCU systems.</p>
-<p>If you can discard ANSI/OEM code API and backward compatibility with non-ASCII SFN, you will able to configure FatFs for Unicode API with any SBCS.</p>
-<p>There ware some restrictions on using LFN for open source project because the support for LFN on the FAT volume was a patent of Microsoft Corporation. The related patents have expired and using the LFN function have got free for any projects.</p>
-</div>
-
-<div class="para doc" id="unicode">
-<h3>Unicode API</h3>
-<p>By default, FatFs uses ANSI/OEM code set on the API even at LFN configuration. FatFs can also switch the character encoding on the API to Unicode by configuration option <tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a></tt>. This means that FatFs supports the full featured LFN specification. The data type <tt>TCHAR</tt> specifies path name strings on the API is an alias of either <tt>char</tt>(ANSI/OEM or UTF-8), <tt>WCHAR</tt>(UTF-16) or <tt>DWORD</tt>(UTF-32) depends on that option. For more information, refer to the description in the <a href="filename.html#uni">file name</a>.</p>
-<p>Note that code page setting, <tt><a href="config.html#code_page">FF_CODE_PAGE</a></tt>, has actually no meaning for the path names at the Unicode API. However it still affects code conversion of string I/O functions at <tt><a href="config.html#strf_encode">FF_STRF_ENCODE</a> != 0</tt> and backward compatibility with legacy systems, so that code page needs to be configured properly when it is considered a problem.</p>
-</div>
-
-<div class="para doc" id="exfat">
-<h3>exFAT Filesystem</h3>
-<p>The exFAT (Microsoft's Extended File Allocation Table) filesystem is a succession of the FAT/FAT32 filesystem which has been widely used in embedded systems, consumer devices and portable storage media. It is adopted by SDA (SD Association) as a recommended filesystem for high capacity SD cards larger than 32 GB and they are being shipped with this format, so that the exFAT became one of the standard filesystems for removable media as well as FAT. The exFAT filesystem allows the file size beyond the 4 GB limit what FAT filesystem allows upto and some filesystem overhead, especially cluster allocation delay, are reduced as well. This feature improves the write throughput to the file.</p>
-<p>Note that the exFAT is a patent of Microsoft Corporation. The exFAT function of FatFs is an implementation based on <cite>US. Pat. App. Pub. No. 2009/0164440 A1</cite>. FatFs module can switch the support for exFAT on/off by configuration option, <tt><a href="config.html#fs_exfat">FF_FS_EXFAT</a></tt>. When enable the exFAT on the commercial products, a license by Microsoft will be needed depends on the final destination of the products.</p>
-<p><em>Remark: Enabling exFAT discards ANSI C (C89) compatibility because of need for 64-bit integer type.</em></p>
-</div>
-
-<div class="para doc" id="reentrant">
-<h3>Re-entrancy</h3>
-<p>The file operations to the <em>different volumes</em> each other is always re-entrant regardless of configurations except when LFN is enabled with static working buffer. It can work concurrently without any mutual exclusion.</p>
-<p>The file operations to the <em>same volume</em> is not re-entrant. It can also be configured for thread-safe by option <tt><a href="config.html#fs_reentrant">FF_FS_REENTRANT</a></tt>. In this case, also the OS dependent synchronization control functions, <tt>ff_cre_syncobj/ff_del_syncobj/ff_req_grant/ff_rel_grant</tt>, need to be added to the project. There are some examples in the <tt>ffsystem.c</tt>. When a file function is called while the volume is being accessed by another task, the file function to the volume will be suspended until that task leaves the file function. If the wait time exceeded a period defined by <tt>FF_TIMEOUT</tt>, the file function will abort with <tt>FR_TIMEOUT</tt>. The timeout function might not be supported on the some RTOSs.</p>
-<p>There is an exception on the re-entrancy for <tt>f_mount/f_mkfs</tt> function. These volume management functions are not re-entrant to the same volume. When use these functions, other tasks need to avoid to access the volume.</p>
-<p>Remarks: This section describes on the re-entrancy of the FatFs module itself. The <tt>FF_FS_REENTRANT</tt> option enables only exclusive use of each filesystem objects and FatFs never prevents to re-enter <tt>disk_*()</tt> functions. Thus the low level disk I/O layer must be always thread-safe when FatFs API is re-entered for different volumes.</p>
-</div>
-
-<div class="para doc" id="dup">
-<h3>Duplicated File Open</h3>
-<p>FatFs module does not support the read/write collision control of duplicated open to a file. The duplicated open is permitted only when each of open method to a file is read mode. The duplicated open with one or more write mode to a file is always prohibited, and also open file must not be renamed or deleted. A violation of these rules can cause data collaption.</p>
-<p>The file lock control can be enabled by <tt><a href="config.html#fs_lock">FF_FS_LOCK</a></tt> option. The value of option defines the number of open objects to manage simultaneously. In this case, if any opening, renaming or removing against the file shareing rule that described above is attempted, the file function will be rejected with <tt>FR_LOCKED</tt>. If number of open objects, files and sub-directories, is equal to <tt>FF_FS_LOCK</tt>, an extra <tt>f_open/f_opendir</tt> function will fail with <tt>FR_TOO_MANY_OPEN_FILES</tt>.</p>
-</div>
-
-<div class="para doc" id="fs1">
-<h3>Performance Effective File Access</h3>
-<p>For good read/write throughput on the small embedded systems with limited size of memory, application programmer should consider what process is done in the FatFs module. The file data on the volume is transferred in following sequence by <tt>f_read</tt> function.</p>
-<p>Figure 1. Sector unaligned read (short)<br>
-<img src="../res/f1.png" width="490" height="110" alt="">
-</p>
-<p>Figure 2. Sector unaligned read (long)<br>
-<img src="../res/f2.png" width="490" height="140" alt="">
-</p>
-<p>Figure 3. Fully sector aligned read<br>
-<img src="../res/f3.png" width="490" height="119" alt="">
-</p>
-<p>The file I/O buffer is a sector buffer to read/write a part of data on the sector. The sector buffer is either file private sector buffer on each file object or shared sector buffer in the filesystem object. The buffer configuration option <tt><a href="config.html#fs_tiny">FF_FS_TINY</a></tt> determins which sector buffer is used for the file data transfer. When tiny buffer configuration (1) is selected, data memory consumption is reduced <tt>FF_MAX_SS</tt> bytes each file object. In this case, FatFs module uses only a sector buffer in the filesystem object for file data transfer and FAT/directory access. The disadvantage of the tiny buffer configuration is: the FAT data cached in the sector buffer will be lost by file data transfer and it must be reloaded at every cluster boundary. However it will be suitable for most application from view point of the decent performance and low memory comsumption.</p>
-<p>Figure 1 shows that a partial sector, sector unaligned part of the file, is transferred via the file I/O buffer. At long data transfer shown in Figure 2, middle of transfer data that covers one or more sector is transferred to the application buffer directly. Figure 3 shows that the case of entier transfer data is aligned to the sector boundary. In this case, file I/O buffer is not used. On the direct transfer, the maximum extent of sectors are read with <tt>disk_read</tt> function at a time but the multiple sector transfer is divided at cluster boundary even if it is contiguous.</p>
-<p>Therefore taking effort to sector aligned read/write accesss eliminates buffered data transfer and the read/write performance will be improved. Besides the effect, cached FAT data will not be flushed by file data transfer at the tiny configuration, so that it can achieve same performance as non-tiny configuration with small memory footprint.</p>
-</div>
-
-<div class="para doc" id="fs2">
-<h3>Considerations on Flash Memory Media</h3>
-<p>To maximize the write performance of flash memory media, such as SDC, CFC and U Disk, it must be controlled in consideration of its characteristitcs.</p>
-<h4>Using Mutiple-Sector Write</h4>
-<div class="rset">
-Figure 6. Comparison between Multiple/Single Sector Write<br>
-<img src="../res/f6.png" width="630" height="148" alt="fig.6">
-</div>
-<p>The write throughput of the flash memory media becomes the worst at single sector write transaction. The write throughput increases as the number of sectors per a write transaction as shown in Figure 6. This effect more appers at faster interface speed and the performance ratio often becomes grater than ten. <a href="../res/rwtest2.png">This result</a> is clearly explaining how fast is multiple block write (W:16K, 32 sectors) than single block write (W:100, 1 sector), and also larger card tends to be slow at single block write. Number of write transactions also affects life time of the flash memory media. When compared at same amount of write data, the single sector write in Figure 6 above wears flash memory media 16 times more than multiple sector write in Figure 6 below. Single sector write is pretty pain for the flash memory media.</p>
-<p>Therefore the application program should write the data in large block as possible. The ideal write chunk size and alighment is size of sector, and size of cluster is the best. Of course all layers between the application and the storage device must have consideration on multiple sector write, however most of open-source memory card drivers lack it. Do not split a multiple sector write request into single sector write transactions or the write throughput gets poor. Note that FatFs module and its sample disk drivers supprt multiple sector read/write operation. </p>
-<h4>Forcing Memory Erase</h4>
-<p>When remove a file with <tt>f_unlink</tt> function, the data clusters occupied by the file are marked 'free' on the FAT. But the data sectors containing the file data are not that applied any process, so that the file data left occupies a part of the flash memory array as 'live block'. If the file data can be erased on removing the file, those data blocks will be turned into the free block pool. This may skip internal block erase operation to the data block on next write operation. As the result the write performance might be improved. FatFs can manage this function by setting <tt><a href="config.html#use_trim">FF_USE_TRIM</a></tt> to 1. Note that this is an expectation of internal process of the storage device and not that always effective. Most applications will not need this function. Also <tt>f_unlink</tt> function can take a time when remove a large file.</p>
-</div>
-
-<div class="para doc" id="critical">
-<h3>Critical Section</h3>
-<p>If a write operation to the FAT volume is interrupted due to an accidental failure, such as sudden blackout, incorrect media removal and unrecoverable disk error, the FAT structure on the volume can be broken. Following images shows the critical section of the FatFs module.</p>
-<div class="lset">
-Figure 4. Long critical section<br>
-<img src="../res/f4.png" width="320" height="436" alt="fig.4">
-</div>
-<div class="lset">
-Figure 5. Minimized critical section<br>
-<img src="../res/f5.png" width="320" height="436" alt="fig.5">
-</div>
-<br class="clr">
-<p>An interruption in the red section can cause a cross link; as a result, the object being changed can be lost. If an interruption in the yellow section is occured, there is one or more possibility listed below.</p>
-<ul>
-<li>The file data being rewrited is collapsed.</li>
-<li>The file being appended returns initial state.</li>
-<li>The file created as new is gone.</li>
-<li>The file created as new or overwritten remains but no content.</li>
-<li>Efficiency of disk use gets worse due to lost clusters.</li>
-</ul>
-<p>Each case does not affect any file not opened in write mode. To minimize risk of data loss, the critical section can be minimized by minimizing the time that file is opened in write mode or using <tt>f_sync</tt> function as shown in Figure 5.</p>
-</div>
-
-<div class="para doc" id="fs3">
-<h3>Extended Use of FatFs API</h3>
-<p>These are examples of extended use of FatFs APIs. New item will be added whenever a useful code is found.</p>
-<ol>
-<li><a href="http://elm-chan.org/fsw/ff/res/app1.c">Open or create a file for append</a> (for only R0.12 and earlier)</li>
-<li><a href="http://elm-chan.org/fsw/ff/res/app2.c">Empty a directory</a></li>
-<li><a href="http://elm-chan.org/fsw/ff/res/app3.c">Allocate contiguous area to the file</a> (for only R0.11a and earlier)</li>
-<li><a href="http://elm-chan.org/fsw/ff/res/app4.c">Compatibility checker for low level disk I/O module</a></li>
-<li><a href="http://elm-chan.org/fsw/ff/res/mkfatimg.zip">FAT volume image creator</a></li>
-</ol>
-</div>
-
-<div class="para doc" id="license">
-<h3>About FatFs License</h3>
-<p>FatFs has being developped as a personal project of the author, ChaN. It is free from the code anyone else wrote at current release. Following code block shows a copy of the FatFs license document that included in the source files.</p>
-<pre>
-/*----------------------------------------------------------------------------/
-/ FatFs - Generic FAT Filesystem Module Rx.xx /
-/-----------------------------------------------------------------------------/
-/
-/ Copyright (C) 20xx, ChaN, all right reserved.
-/
-/ FatFs module is an open source software. Redistribution and use of FatFs in
-/ source and binary forms, with or without modification, are permitted provided
-/ that the following condition is met:
-/
-/ 1. Redistributions of source code must retain the above copyright notice,
-/ this condition and the following disclaimer.
-/
-/ This software is provided by the copyright holder and contributors "AS IS"
-/ and any warranties related to this software are DISCLAIMED.
-/ The copyright owner or contributors be NOT LIABLE for any damages caused
-/ by use of this software.
-/----------------------------------------------------------------------------*/
-</pre>
-<p>Therefore FatFs license is one of the BSD-style licenses but there is a significant feature. FatFs is mainly intended for embedded systems. In order to extend the usability for commercial products, the redistributions of FatFs in binary form, such as embedded code, binary library and any forms without source code, does not need to include about FatFs in the documentations. This is equivalent to the 1-clause BSD license. Of course FatFs is compatible with the most of open source software licenses including GNU GPL. When you redistribute the FatFs source code with any changes or create a fork, the license can also be changed to GNU GPL, BSD-style license or any open source software license that not conflict with FatFs license.</p>
-</div>
-
-<p class="foot"><a href="../00index_e.html">Return Home</a></p>
-</body>
-</html>
+<p>FatFs module supports the long file name (LFN) extension of the FAT filesystem. The two different file names, short file name (SFN) and LFN, of a file is transparent on the API. The support for LFN feature is disabled by default. To enable the LFN, set <tt><a href="config.html#use_lfn">FF_USE_LFN</a></tt> to 1, 2 or 3, and add <tt>ffunicode.c</tt> to the project. The LFN feature requiers a certain working buffer. The buffer size can be configured by <tt><a href="config.html#max_lfn">FF_MAX_LFN</a></tt> according to the available memory. The length of LFN can be up to 255 characters, so that the <tt>FF_MAX_LFN</tt> should be set to 255 for any existing file names. If the size of working buffer is insufficient for the input file name, the file function fails with <tt>FR_INVALID_NAME</tt>. When use any re-entry to the API with LFN feature in RTOS environment, <tt>FF_USE_LFN</tt> must be set to 2 or 3. In this case, the file function allocates the working buffer on the stack or heap. The LFN working buffer occupies <tt>(FF_MAX_LFN + 1) * 2</tt> bytes and additional <tt>(FF_MAX_LFN + 44) / 15 * 32</tt> bytes when exFAT is enabled.</p> +<h4>Impact upon Module Size</h4> +<table class="lst2 rset"> +<caption>With LFN at CM3 + gcc</caption> +<tr><th><tt>FF_CODE_PAGE</tt></th><th>Code size</th></tr> +<tr><td>437-869 (SBCS)</td><td>+3.3k</td></tr> +<tr><td>932 (Japanese)</td><td>+62k</td></tr> +<tr><td>936 (Simplified Chinese)</td><td>+177k</td></tr> +<tr><td>949 (Korean)</td><td>+140k</td></tr> +<tr><td>950 (Traditional Chinese)</td><td>+111k</td></tr> +<tr><td>0 (All code pages)</td><td>+486k</td></tr> +</table> +<p>When the LFN is enabled, the module size will be increased depends on the configured code page. Right table shows the increment of code size in some code pages. Especially, in the CJK region, tens of thousands of characters are being used. Unfortunately, it requires a huge OEM-Unicode bidirectional conversion table and the module size will be drastically increased as shown in the table.</p> +<p>As the result, the FatFs with LFN enabled with DBCS code pages will not able to be ported on the most 8-bit MCU systems. If the target system is in legacy-free, in only Unicode and any ANSI/OEM code is not used at all, the code page setting gets meaningless. You will able to reduce the code size by configureing FatFs for Unicode API with any SBCS code page.</p> +<p>There ware some restrictions on using LFN for open source project, because the LFN extension on the FAT filesystem was a patent of Microsoft Corporation. However the related patents all have expired and using the LFN feature is free for any projects.</p> +</div> + +<div class="para doc" id="unicode"> +<h3>Unicode API</h3> +<p>By default, FatFs uses ANSI/OEM code set on the API even in LFN configuration. FatFs can also switch the character encoding on the API to Unicode by configuration option <tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a></tt>. This means that FatFs is compliant with the full featured LFN specification. The data type <tt>TCHAR</tt> specifies path name strings on the API is an alias of either <tt>char</tt>(ANSI/OEM or UTF-8), <tt>WCHAR</tt>(UTF-16) or <tt>DWORD</tt>(UTF-32) depends on that option. For more information, refer to the description in the <a href="filename.html#uni">file name</a>.</p> +<p>Note that setting of code page, <tt><a href="config.html#code_page">FF_CODE_PAGE</a></tt>, has actually no meaning when FatFs is configured for the Unicode API. It should be set 437 to reduce the module size. However it still affects code conversion of string I/O functions when <tt><a href="config.html#strf_encode">FF_STRF_ENCODE</a> == 0</tt>, and also backward compatibility with legacy systems. In this case, the code page may need to be configured properly if it is considered a problem.</p> +</div> + +<div class="para doc" id="exfat"> +<h3>exFAT Filesystem</h3> +<p>The exFAT (Microsoft's Extended File Allocation Table) filesystem is a succession of the FAT/FAT32 filesystem which has been widely used in embedded systems, consumer devices and portable storage media. It is adopted by SDA (SD Association) as the filesystem for SDXC card, 64 GB and larger, and they are being shipped with this format. Therefore the exFAT is one of the standard filesystems for removable media as well as FAT. The exFAT filesystem allows the file size beyond the 4 GB limit what FAT filesystem allows up to and some filesystem overhead, especially cluster allocation delay, are reduced as well. These features allow to record the large data without dividing into some files and improve the write throughput to the file.</p> +<p>Note that the exFAT filesystem is a patent of Microsoft Corporation. The exFAT feature of FatFs is an implementation based on <cite>US. Pat. App. Pub. No. 2009/0164440 A1</cite>. FatFs module can switch the exFAT on or off by a configuration option, <tt><a href="config.html#fs_exfat">FF_FS_EXFAT</a></tt>. When enable the exFAT for the commercial products, a license by Microsoft will be needed depends on the final destination of the products.</p> +<p><em>Remarks: Enabling exFAT discards C89 compatibility and it wants C99 because of need for 64-bit integer type.</em></p> +</div> + +<div class="para doc" id="lba64"> +<h3>64-bit LBA</h3> +<p>LBA (Logical Block Addressing) is an addressing method to specify the location of data block, called <em>sector</em>, on the storage media. It is a simple linear address beginning from 0 as the first sector, 1 as the second sector and so on. The host system does not need to consider how the data block is located and managed in the storage device. FatFs supports only LBA for the media access. 32-bit LBA is a common size in the most LBA scheme. It can address up to 2<sup>32</sup> sectors, 2 TB in 512 bytes/sector. When a storage device larger than 2 TB is used, larger sector size or 64-bit LBA will be needed to address the entire sectors of the storage device.</p> +<p>By default, FatFs works in 32-bit LBA for media access. FatFs can also switch it to 64-bit LBA by a configuration option <tt><a href="config.html#fs_lba64">FF_LBA64</a></tt>. It also enables GPT (GUID Partition Table) for partiotion management on the storage device. For further information about GPT, refer to <tt><a href="mkfs.html">f_mkfs</a></tt> and <tt><a href="fdisk.html">f_fdisk</a></tt> function.</p> +</div> + +<div class="para doc" id="reentrant"> +<h3>Re-entrancy</h3> +<p>The file operations of two tasks to the <em>different volumes</em> each other is always re-entrant and it can work concurrently without any mutual exclusion regardless of the configurations except when LFN is enabled with static working buffer (<tt>FF_USE_LFN = 1</tt>).</p> +<p>The file operations of two tasks to the <em>same volume</em> is not thread-safe by default. FatFs can also be configured to make it thread-safe by an option <tt><a href="config.html#fs_reentrant">FF_FS_REENTRANT</a></tt>. When a file function is called while the volume is being accessed by another task, the file function to the volume will be suspended until that task leaves the file function. If the wait time exceeded a period defined by <tt>FF_TIMEOUT</tt>, the file function will abort with <tt>FR_TIMEOUT</tt>. The timeout feature might not be supported on the some OSs. To enable this feature, OS dependent synchronization control functions, <tt>ff_mutex_create/ff_mutex_delete/ff_mutex_take/ff_mutex_give</tt>, need to be added to the project. There is an example code in the <tt>ffsystem.c</tt> for some OSs.</p> +<p>Note that there is an exception on the re-entrancy for <tt>f_mount</tt> and <tt>f_mkfs</tt> function. You will know why it is. These volume management functions are always not thread-safe to the volume being processed. When use these functions, other tasks need to avoid to access the corresponding volume.</p> +<div class="rset"> +<table class="lst2"> +<tr><th><tt>Function</tt></th><th>Case 1</th><th>Case 2</th><th>Case 3</th></tr> +<tr><td>disk_status</td><td>Yes</td><td>Yes</td><td>Yes(*)</td></tr> +<tr><td>disk_initialize</td><td>No</td><td>Yes</td><td>Yes(*)</td></tr> +<tr><td>disk_read</td><td>No</td><td>Yes</td><td>Yes(*)</td></tr> +<tr><td>disk_write</td><td>No</td><td>Yes</td><td>Yes(*)</td></tr> +<tr><td>disk_ioctl</td><td>No</td><td>Yes</td><td>Yes(*)</td></tr> +<tr><td>get_fattime</td><td>No</td><td>Yes</td><td>Yes</td></tr> +</table> +<small> +Case 1: Same volume.<br> +Case 2: Different volume on the same drive.<br> +Case 3: Different volume on the different drive.<br> +(*) In only different drive number. +</small> +</div> +<p>Remarks: This section describes on the re-entrancy of the FatFs module itself. The <tt>FF_FS_REENTRANT</tt> option enables only exclusive use of each filesystem objects and FatFs does not that prevent to re-enter the storage device control functions. Thus the device control layer needs to be always thread-safe when FatFs API is re-entered for different volumes. Right table shows which control function can be re-entered when FatFs API is re-entered on some conditions.</p> +</div> + +<div class="para doc" id="dup"> +<h3>Duplicated File Open</h3> +<p>FatFs module does not support the read/write collision control of duplicated open to a file. The duplicated open is permitted only when each of open method to a file is read mode. The duplicated open with one or more write mode to a file is always prohibited, and also open file must not be renamed or deleted. A violation of these rules can cause data collaption.</p> +<p>The file lock control can be enabled by <tt><a href="config.html#fs_lock">FF_FS_LOCK</a></tt> option. The value of option defines the number of open objects to manage simultaneously. In this case, if any opening, renaming or removing against the file shareing rule that described above is attempted, the file function will be rejected with <tt>FR_LOCKED</tt>. If number of open objects, files and sub-directories, is equal to <tt>FF_FS_LOCK</tt>, an extra <tt>f_open/f_opendir</tt> function will fail with <tt>FR_TOO_MANY_OPEN_FILES</tt>.</p> +</div> + +<div class="para doc" id="fs1"> +<h3>Performance Effective File Access</h3> +<p>For good read/write throughput on the small embedded systems with limited size of memory, application programmer should consider what process is done in the FatFs module. The file data on the volume is transferred in following sequence by <tt>f_read</tt> function.</p> +<p>Figure 1. Sector unaligned read (short)<br> +<img src="../res/f1.png" width="490" height="110" alt=""> +</p> +<p>Figure 2. Sector unaligned read (long)<br> +<img src="../res/f2.png" width="490" height="140" alt=""> +</p> +<p>Figure 3. Fully sector aligned read<br> +<img src="../res/f3.png" width="490" height="119" alt=""> +</p> +<p>The file I/O buffer is a sector buffer to read/write a part of data on the sector. The sector buffer is either file private sector buffer on each file object or shared sector buffer in the filesystem object. The buffer configuration option <tt><a href="config.html#fs_tiny">FF_FS_TINY</a></tt> determins which sector buffer is used for the file data transfer. When tiny buffer configuration (1) is selected, data memory consumption is reduced <tt>FF_MAX_SS</tt> bytes each file object. In this case, FatFs module uses only a sector buffer in the filesystem object for file data transfer and FAT/directory access. The disadvantage of the tiny buffer configuration is: the FAT data cached in the sector buffer will be lost by file data transfer and it must be reloaded at every cluster boundary. However it will be suitable for most application from view point of the decent performance and low memory comsumption.</p> +<p>Figure 1 shows that a partial sector, sector unaligned part of the file, is transferred via the file I/O buffer. At long data transfer shown in Figure 2, middle of transfer data that covers one or more sector is transferred to the application buffer directly. Figure 3 shows that the case of entier transfer data is aligned to the sector boundary. In this case, file I/O buffer is not used. On the direct transfer, the maximum extent of sectors are read with <tt>disk_read</tt> function at a time but the multiple sector transfer is divided at cluster boundary even if it is contiguous.</p> +<p>Therefore taking effort to sector aligned read/write accesss eliminates buffered data transfer and the read/write performance will be improved. Besides the effect, cached FAT data will not be flushed by file data transfer at the tiny configuration, so that it can achieve same performance as non-tiny configuration with small memory footprint.</p> +</div> + +<div class="para doc" id="fs2"> +<h3>Considerations on Flash Memory Media</h3> +<p>To maximize the write performance of flash memory media, such as SDC, CFC and U Disk, it must be controlled in consideration of its characteristitcs.</p> +<h4>Using Mutiple-Sector Write</h4> +<div class="rset"> +Figure 6. Comparison between Multiple/Single Sector Write<br> +<img src="../res/f6.png" width="630" height="148" alt="fig.6"> +</div> +<p>The write throughput of the flash memory media becomes the worst at single sector write transaction. The write throughput increases as the number of sectors per a write transaction as shown in Figure 6. This effect more appers at faster interface speed and the performance ratio often becomes grater than ten. <a href="../res/rwtest2.png">This result</a> is clearly explaining how fast is multiple block write (W:16K, 32 sectors) than single block write (W:100, 1 sector), and also larger card tends to be slow at single block write. Number of write transactions also affects life time of the flash memory media. When compared at same amount of write data, the single sector write in Figure 6 above wears flash memory media 16 times more than multiple sector write in Figure 6 below. Single sector write is pretty pain for the flash memory media.</p> +<p>Therefore the application program should write the data in large block as possible. The ideal write chunk size and alighment is size of sector, and size of cluster is the best. Of course all layers between the application and the storage device must have consideration on multiple sector write, however most of open-source memory card drivers lack it. Do not split a multiple sector write request into single sector write transactions or the write throughput gets poor. Note that FatFs module and its sample disk drivers supprt multiple sector read/write operation. </p> +<h4>Forcing Memory Erase</h4> +<p>When remove a file with <tt>f_unlink</tt> function, the data clusters occupied by the file are marked 'free' on the FAT. But the data sectors containing the file data are not that applied any process, so that the file data left occupies a part of the flash memory array as 'live block'. If the file data can be erased on removing the file, those data blocks will be turned into the free block pool. This may skip internal block erase operation to the data block on next write operation. As the result the write performance might be improved. FatFs can manage this function by setting <tt><a href="config.html#use_trim">FF_USE_TRIM</a></tt> to 1. Note that because this effect is from an expectation of internal process of the storage device, it is not that always effective. Most applications will not need this function. Also <tt>f_unlink</tt> function can take a time when remove a large file.</p> +</div> + +<div class="para doc" id="critical"> +<h3>Critical Section</h3> +<p>If a write operation to the FAT volume is interrupted due to an accidental failure, such as sudden blackout, wrong media removal and unrecoverable disk error, the FAT structure on the volume can be broken. Following images shows the critical section of the FatFs module.</p> +<div class="lset"> +Figure 4. Long critical section<br> +<img src="../res/f4.png" width="320" height="436" alt="fig.4"> +</div> +<div class="lset"> +Figure 5. Minimized critical section<br> +<img src="../res/f5.png" width="320" height="436" alt="fig.5"> +</div> +<br class="clr"> +<p>An interruption in the red section can cause a cross link; as a result, the object being changed can be lost. If an interruption in the yellow section is occured, there is one or more possibility listed below.</p> +<ul> +<li>The file data being rewrited is collapsed.</li> +<li>The file being appended returns initial state.</li> +<li>The file created as new is gone.</li> +<li>The file created as new or overwritten remains but no content.</li> +<li>Efficiency of disk use gets worse due to lost clusters.</li> +</ul> +<p>Each case does not affect any file not opened in write mode. To minimize risk of data loss, the critical section can be minimized by minimizing the time that file is opened in write mode or using <tt>f_sync</tt> function as shown in Figure 5.</p> +</div> + +<div class="para doc" id="fs3"> +<h3>Various Usable Functions for FatFs Projects</h3> +<p>These are examples of extended use of FatFs APIs. New item will be added when useful code example is found.</p> +<ol> +<li><a href="http://elm-chan.org/fsw/ff/res/app1.c">Open or Create File for Append</a> (superseded by FA_OPEN_APPEND flag added at R0.12)</li> +<li><a href="http://elm-chan.org/fsw/ff/res/app2.c">Delete Non-empty Sub-directory</a> (for R0.12 and later)</li> +<li><a href="http://elm-chan.org/fsw/ff/res/app3.c">Create Contiguous File</a> (superseded by f_expand function added at R0.12)</li> +<li><a href="http://elm-chan.org/fsw/ff/res/app5.c">Test if the File is Contiguous or Not</a></li> +<li><a href="http://elm-chan.org/fsw/ff/res/app4.c">Compatibility Checker for Storage Device Control Module</a></li> +<li><a href="http://elm-chan.org/fsw/ff/res/app6.c">Performance Checker for Storage Device Control Module</a></li> +<li><a href="http://elm-chan.org/fsw/ff/res/mkfatimg.zip">FAT Volume Image Creator</a> (Pre-creating built-in FAT volume)</li> +<li>Virtual Drive Feature (refer to lpc176x/ in <a href="../ffsample.zip">ffsample.zip</a>)</li> +<li><a href="http://elm-chan.org/fsw/ff/res/uniconv.zip">Embedded Unicode String Utilities</a> (OEMxxx→Unicode, Unicode→OEMxxx, Unicode→Unicode)</li> +</ol> +</div> + +<div class="para doc" id="license"> +<h3>About FatFs License</h3> +<p>FatFs has being developped as a personal project of the author, ChaN. It is free from the code anyone else wrote at current release. Following code block shows a copy of the FatFs license document that included in the source files.</p> +<pre> +/*----------------------------------------------------------------------------/ +/ FatFs - Generic FAT Filesystem Module Rx.xx / +/-----------------------------------------------------------------------------/ +/ +/ Copyright (C) 20xx, ChaN, all right reserved. +/ +/ FatFs module is an open source software. Redistribution and use of FatFs in +/ source and binary forms, with or without modification, are permitted provided +/ that the following condition is met: +/ +/ 1. Redistributions of source code must retain the above copyright notice, +/ this condition and the following disclaimer. +/ +/ This software is provided by the copyright holder and contributors "AS IS" +/ and any warranties related to this software are DISCLAIMED. +/ The copyright owner or contributors be NOT LIABLE for any damages caused +/ by use of this software. +/----------------------------------------------------------------------------*/ +</pre> +<p>Therefore FatFs license is one of the BSD-style licenses but there is a significant feature. FatFs is mainly intended for embedded systems. In order to extend the usability for commercial products, the redistributions of FatFs in binary form, such as embedded code, binary library and any forms without source code, does not need to include about FatFs in the documentations. This is equivalent to the 1-clause BSD license. Of course FatFs is compatible with the most of open source software licenses includes GNU GPL. When you redistribute the FatFs source code with any changes or create a fork, the license can also be changed to GNU GPL, BSD-style license or any open source software license that compatible with FatFs license.</p> +</div> + +<p class="foot"><a href="../00index_e.html">Return Home</a></p> +</body> +</html> diff --git a/fatfs/documents/doc/chdir.html b/fatfs/documents/doc/chdir.html index 072b9e9..93e116c 100644 --- a/fatfs/documents/doc/chdir.html +++ b/fatfs/documents/doc/chdir.html @@ -25,7 +25,7 @@ FRESULT f_chdir ( <h4>Parameters</h4>
<dl class="par">
<dt>path</dt>
-<dd>Pointer to the null-terminated string that specifies the <a href="filename.html">directory</a> to go.</dd>
+<dd>Pointer to the null-terminated string that specifies the <a href="filename.html">directory</a> to be set as current directory.</dd>
</dl>
</div>
@@ -50,7 +50,7 @@ FRESULT f_chdir ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_chdir</tt> function changes the current directory of the logical drive. Also the current drive is changed at Unix style volume ID, <tt><a href="config.html#str_volume_id">FF_STR_VOLUME_ID</a> == 2</tt>. The current directory of each logical drive is initialized to the root directory on mount.</p>
+<p>The <tt>f_chdir</tt> function changes the current directory of the logical drive. Also the current drive will be changed when in Unix style drive prefix, <tt><a href="config.html#str_volume_id">FF_STR_VOLUME_ID</a> == 2</tt>. The current directory of each logical drive is initialized to the root directory on mount.</p>
<p>Note that the current directory is retained in the each file system object and the current drive is retained in a static variable, so that it also affects other tasks that use the file functions.</p>
</div>
diff --git a/fatfs/documents/doc/chdrive.html b/fatfs/documents/doc/chdrive.html index fb1c32f..4dfc7d8 100644 --- a/fatfs/documents/doc/chdrive.html +++ b/fatfs/documents/doc/chdrive.html @@ -41,7 +41,7 @@ FRESULT f_chdrive ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_chdrive</tt> function changes only the current drive. The initial value of the current drive number is 0. Note that the current drive is retained in a static variable, so that it also affects other tasks that using the file functions.</p>
+<p>The <tt>f_chdrive</tt> function changes only the current drive. The initial value of the current drive number is 0. In Unix style drive prefix configuration, this function will not be needed because <tt>f_chdir</tt> function changes also the current drive. Note that the current drive is retained in a static variable, so that it also affects other tasks that using the file functions.</p>
</div>
<div class="para comp">
@@ -56,8 +56,6 @@ FRESULT f_chdrive ( <em>f_chdrive</em>("2:"); <span class="c">/* Set drive 2 as current drive */</span>
<em>f_chdrive</em>(""); <span class="c">/* No effect (set current drive as current drive) */</span>
-
- <em>f_chdrive</em>("/flash"); <span class="c">/* Set drive "flash" as current drive (at Unix style volume ID) */</span>
</pre>
</div>
diff --git a/fatfs/documents/doc/config.html b/fatfs/documents/doc/config.html index aeea190..788e075 100644 --- a/fatfs/documents/doc/config.html +++ b/fatfs/documents/doc/config.html @@ -11,13 +11,12 @@ <body>
<h1>Configuration Options</h1>
-<p>There are many options to configure the functions of FatFs for requirement of each project. The configuration options are defined in the <em><tt>ffconf.h</tt></em>.</p>
+<p>There are many options to configure the features of FatFs for various requirements of each project. The configuration options are defined in <em><tt>ffconf.h</tt></em>.</p>
<ul>
<li>Function Configurations
<ul>
<li><a href="#fs_readonly">FF_FS_READONLY</a></li>
<li><a href="#fs_minimize">FF_FS_MINIMIZE</a></li>
- <li><a href="#use_strfunc">FF_USE_STRFUNC</a></li>
<li><a href="#use_find">FF_USE_FIND</a></li>
<li><a href="#use_mkfs">FF_USE_MKFS</a></li>
<li><a href="#use_fastseek">FF_USE_FASTSEEK</a></li>
@@ -25,6 +24,10 @@ <li><a href="#use_chmod">FF_USE_CHMOD</a></li>
<li><a href="#use_label">FF_USE_LABEL</a></li>
<li><a href="#use_forward">FF_USE_FORWARD</a></li>
+ <li><a href="#use_strfunc">FF_USE_STRFUNC</a></li>
+ <li><a href="#print_lli">FF_PRINT_LLI</a></li>
+ <li><a href="#print_fp">FF_PRINT_FLOAT</a></li>
+ <li><a href="#strf_encode">FF_STRF_ENCODE</a></li>
</ul>
</li>
<li>Namespace and Locale Configurations
@@ -34,7 +37,6 @@ <li><a href="#max_lfn">FF_MAX_LFN</a></li>
<li><a href="#lfn_unicode">FF_LFN_UNICODE</a></li>
<li><a href="#lfn_buf">FF_LFN_BUF, FF_SFN_BUF</a></li>
- <li><a href="#strf_encode">FF_STRF_ENCODE</a></li>
<li><a href="#fs_rpath">FF_FS_RPATH</a></li>
</ul>
</li>
@@ -45,8 +47,9 @@ <li><a href="#volume_strs">FF_VOLUME_STRS</a></li>
<li><a href="#multi_partition">FF_MULTI_PARTITION</a></li>
<li><a href="#max_ss">FF_MIN_SS, FF_MAX_SS</a></li>
+ <li><a href="#fs_lba64">FF_LBA64</a></li>
+ <li><a href="#fs_gptmin">FF_GPT_MIN</a></li>
<li><a href="#use_trim">FF_USE_TRIM</a></li>
- <li><a href="#fs_nofsinfo">FF_FS_NOFSINFO</a></li>
</ul>
</li>
<li>System Configurations
@@ -55,6 +58,7 @@ <li><a href="#fs_exfat">FF_FS_EXFAT</a></li>
<li><a href="#fs_nortc">FF_FS_NORTC</a></li>
<li><a href="#nortc_time">FF_NORTC_MON, FF_NORTC_MDAY, FF_NORTC_YEAR</a></li>
+ <li><a href="#fs_nofsinfo">FF_FS_NOFSINFO</a></li>
<li><a href="#fs_lock">FF_FS_LOCK</a></li>
<li><a href="#fs_reentrant">FF_FS_REENTRANT</a></li>
<li><a href="#fs_timeout">FF_FS_TIMEOUT</a></li>
@@ -79,15 +83,6 @@ <tr><td>3</td><td><tt>f_lseek</tt> function is removed in addition to 2.</td></tr>
</table>
-<h4 id="use_strfunc">FF_USE_STRFUNC</h4>
-<p>This option switches string functions, <tt>f_gets</tt>, <tt>f_putc</tt>, <tt>f_puts</tt> and <tt>f_printf</tt>.</p>
-<table class="lst1">
-<tr><th>Value</th><th>Description</th></tr>
-<tr><td>0</td><td>Disable string functions.</td></tr>
-<tr><td>1</td><td>Enable string functions without LF-CRLF conversion.</td></tr>
-<tr><td>2</td><td>Enable string functions with LF-CRLF conversion.</td></tr>
-</table>
-
<h4 id="use_find">FF_USE_FIND</h4>
<p>Disable (0) or Enable (1) filtered directory read functions, <tt>f_findfirst</tt> and <tt>f_findnext</tt>. Also <tt>FF_FS_MINIMIZE</tt> needs to be 0 or 1.</p>
@@ -109,6 +104,38 @@ <h4 id="use_forward">FF_USE_FORWARD</h4>
<p>Disable (0) or Enable (1) <tt>f_forward</tt> function.</p>
+<h4 id="use_strfunc">FF_USE_STRFUNC</h4>
+<p>This option switches string functions, <tt>f_gets</tt>, <tt>f_putc</tt>, <tt>f_puts</tt> and <tt>f_printf</tt>. These functions are equivalents of regular string stream I/O functions in POSIX. If <tt>sprintf</tt> is available and code conversion is not needed, <tt>f_write</tt> with <tt>sprintf</tt> will be efficient in code size and performance rather than <tt>f_printf</tt>. When enable this feature, <tt>stdarg.h</tt> is included in <tt>ff.c</tt>.</p>
+<table class="lst1">
+<tr><th>Value</th><th>Description</th></tr>
+<tr><td>0</td><td>Disable string functions.</td></tr>
+<tr><td>1</td><td>Enable string functions without LF-CRLF conversion.</td></tr>
+<tr><td>2</td><td>Enable string functions with LF-CRLF conversion.</td></tr>
+</table>
+
+<h4 id="print_lli">FF_PRINT_LLI</h4>
+<p>This option switches support for long long integer argument in <tt>f_printf</tt>.</p>
+<p>Disable (0) or Enable (1). When enable this feature, C standard needs to be C99 or later.</p>
+
+<h4 id="print_fp">FF_PRINT_FLOAT</h4>
+<p>This option switches support for floating point argument in <tt>f_printf</tt>. When enable this feature, C standard needs to be C99 or later and <tt>math.h</tt> is included in <tt>ff.c</tt>.</p>
+<table class="lst1">
+<tr><th>Value</th><th>Description</th></tr>
+<tr><td>0</td><td>Disable floating point argument.</td></tr>
+<tr><td>1</td><td>Enable floating point argument in type <tt>'f'</tt>, <tt>'e'</tt> and <tt>'E'</tt>.</td></tr>
+<tr><td>2</td><td>Enable it with decimal separator <tt>','</tt> instead of <tt>'.'</tt>.</td></tr>
+</table>
+
+<h4 id="strf_encode">FF_STRF_ENCODE</h4>
+<p>When character encoding on the API is Unicode (<tt>FF_LFN_UNICODE >= 1</tt>), string I/O functions enabled by <tt>FF_USE_STRFUNC</tt> convert the character encoding in it. This option defines the assumption of character encoding <em>on the file</em> to be read/written via those functions. When LFN is not enabled or <tt>FF_LFN_UNICODE == 0</tt>, the string functions work without any code conversion and this option has no effect.</p>
+<table class="lst2">
+<tr><th>Value</th><th>Character encoding on the file</th></tr>
+<tr><td>0</td><td>ANSI/OEM in current code page</td></tr>
+<tr><td>1</td><td>Unicode in UTF-16LE</td></tr>
+<tr><td>2</td><td>Unicode in UTF-16BE</td></tr>
+<tr><td>3</td><td>Unicode in UTF-8</td></tr>
+</table>
+
</div>
@@ -116,10 +143,10 @@ <h3>Namespace and Locale Configurations</h3>
<h4 id="code_page">FF_CODE_PAGE</h4>
-<p>This option specifies the OEM code page to be used on the target system. Incorrect setting of the code page can cause a file open failure. If any non-ASCII character is not used at all, there is no difference between any code page settings.</p>
+<p>This option specifies the OEM code page used on the target system. Incorrect setting of the code page can cause a file open failure. If any non-ASCII character is not used for the path name or <tt>FF_LFN_UNICODE != 0</tt>, there is no difference between any code page settings. Set it 437 anyway.</p>
<table class="lst1">
<tr><th>Value</th><th>Code page</th></tr>
-<tr><td>0</td><td>Include all code pages below and set by <tt>f_setcp()</tt></td></tr>
+<tr><td>0</td><td>Includes all code pages below and set by <tt>f_setcp()</tt></td></tr>
<tr><td>437</td><td>U.S.</td></tr>
<tr><td>720</td><td>Arabic</td></tr>
<tr><td>737</td><td>Greek</td></tr>
@@ -154,10 +181,10 @@ </table>
<h4 id="max_lfn">FF_MAX_LFN</h4>
-<p>LFN function requiers certain internal working buffer for the file name. This option defines size of the buffer and the value can be in range of 12 to 255 in UTF-16 encoding unit of the LFN. The buffer occupies <tt>(FF_MAX_LFN + 1) * 2</tt> bytes and additional <tt>(FF_MAX_LFN + 44) / 15 * 32</tt> bytes when exFAT is enabled. It is recommended to be set 255 to fully support the LFN specification. This option has no effect when LFN is not enabled.</p>
+<p>LFN function requiers certain internal working buffer for the file name. This option defines size of the buffer and the value can be in range of 12 to 255 characters (actually in UTF-16 code units) of the LFN. The buffer occupies <tt>(FF_MAX_LFN + 1) * 2</tt> bytes and additional <tt>(FF_MAX_LFN + 44) / 15 * 32</tt> bytes when exFAT is enabled. It is recommended to be set 255 to fully support the LFN specification. This option has no effect when LFN is not enabled.</p>
<h4 id="lfn_unicode">FF_LFN_UNICODE</h4>
-<p>This option switches character encoding for the file name on the API. When Unicode is selected, <tt>FF_CODE_PAGE</tt> has actually no meaning except for compatibility with legacy systems. FatFs supports the code point upto U+10FFFF.</p>
+<p>This option switches character encoding for the file name on the API. FatFs supports the code point up to U+10FFFF. This option also affects behavior of string I/O functions (see <tt>FF_STRF_ENCODE</tt>).</p>
<table class="lst2">
<tr><th>Value</th><th>Character Encoding</th><th><tt>TCHAR</tt></th></tr>
<tr><td>0</td><td>ANSI/OEM in current CP</td><td>char</td></tr>
@@ -165,35 +192,26 @@ <tr><td>2</td><td>Unicode in UTF-8</td><td>char</td></tr>
<tr><td>3</td><td>Unicode in UTF-32</td><td>DWORD</td></tr>
</table>
-<p>This option also affects behavior of string I/O functions (see <tt>FF_STRF_ENCODE</tt>). When LFN is not enabled, this option has no effect and FatFs works at ANSI/OEM code on the API. For more information, read <a href="filename.html#uni">here</a>.</p>
+<p>When Unicode is selected, <tt>FF_CODE_PAGE</tt> has actually no meaning except for compatibility with legacy systems, such as MS-DOS and any system without support for LFN.</p>
+<p>When LFN is not enabled, this option has no effect and FatFs works in ANSI/OEM code on the API. For more information, read <a href="filename.html#uni">here</a>.</p>
<h4 id="lfn_buf">FF_LFN_BUF, FF_SFN_BUF</h4>
-<p>This set of options defines size of file name members, <tt>fname[]</tt> and <tt>altname[]</tt>, in the <tt><a href="sfileinfo.html">FILINFO</a></tt> structure which is used to read out the directory items. These values should be suffcient for the file names to read. How long is the read file name length maximum depends on the character encoding on the API as follows:</p>
+<p>This set of options defines size of file name members, <tt>fname[]</tt> and <tt>altname[]</tt>, in the <tt><a href="sfileinfo.html">FILINFO</a></tt> structure which is used to read out the directory items. These values should be suffcient for the file names to read. The maximum possible length of read file name depends on the character encoding scheme on the API as follows:</p>
<table class="lst2">
<tr><th>Encoding</th><th>LFN length</th><th>SFN length</th></tr>
-<tr><td>ANSI/OEM at SBCS</td><td>255 items</td><td>12 items</td></tr>
-<tr><td>ANSI/OEM at DBCS</td><td>510 items</td><td>12 items</td></tr>
+<tr><td>ANSI/OEM in SBCS</td><td>255 items</td><td>12 items</td></tr>
+<tr><td>ANSI/OEM in DBCS</td><td>510 items</td><td>12 items</td></tr>
<tr><td>Unicode in UTF-16/32</td><td>255 items</td><td>12 items</td></tr>
<tr><td>Unicode in UTF-8</td><td>765 items</td><td>34 items</td></tr>
</table>
<p>If the size of name member is insufficient for the LFN, the item is treated as without LFN. When LFN is not enabled, these options have no effect.</p>
-<h4 id="strf_encode">FF_STRF_ENCODE</h4>
-<p>When character encoding on the API is Unicode (<tt>FF_LFN_UNICODE >= 1</tt>), string I/O functions, <tt>f_gets</tt>, <tt>f_putc</tt>, <tt>f_puts</tt> and <tt>f_printf</tt>, convert the character encodins in it. This option defines the assumption of character encoding <em>on the file</em> to be read/written via those functions. When LFN is not enabled or <tt>FF_LFN_UNICODE == 0</tt>, the string functions work without any encoding conversion and this option has no effect.</p>
-<table class="lst2">
-<tr><th>Value</th><th>Character encoding on the file</th></tr>
-<tr><td>0</td><td>ANSI/OEM in current code page</td></tr>
-<tr><td>1</td><td>Unicode in UTF-16LE</td></tr>
-<tr><td>2</td><td>Unicode in UTF-16BE</td></tr>
-<tr><td>3</td><td>Unicode in UTF-8</td></tr>
-</table>
-
<h4 id="fs_rpath">FF_FS_RPATH</h4>
<p>This option configures relative path function. For more information, read <a href="filename.html#nam">here</a>.</p>
<table class="lst1">
<tr><th>Value</th><th>Description</th></tr>
-<tr><td>0</td><td>Disable relative path function and remove related functions.</td></tr>
-<tr><td>1</td><td>Enable relative path function. <tt>f_chdir</tt> and <tt>f_chdrive</tt> function is available.</td></tr>
+<tr><td>0</td><td>Disable relative path and remove related functions.</td></tr>
+<tr><td>1</td><td>Enable relative path. <tt>f_chdir</tt> and <tt>f_chdrive</tt> function is available.</td></tr>
<tr><td>2</td><td><tt>f_getcwd</tt> function is available in addition to 1</td></tr>
</table>
@@ -204,43 +222,39 @@ <h3>Volume/Drive Configurations</h3>
<h4 id="volumes">FF_VOLUMES</h4>
-<p>This option configures number of volumes (logical drives upto 10) to be used.</p>
+<p>This option configures number of volumes (logical drives up to 10) to be used.</p>
<h4 id="str_volume_id">FF_STR_VOLUME_ID</h4>
<p>This option switches the support for string volume ID. When arbitrary string for the volume ID is enabled for the drive prefix, also pre-defined strings by <tt>FF_VOLUME_STRS</tt> or user defined strings can be used as drive prefix in the path name. Numeric drive number is always valid regardless of this option, and also either format of drive prefix can be enabled by this option.</p>
<table class="lst2">
<tr><th>Value</th><th>Description</th><th>Example</th></tr>
-<tr><td>0</td><td>Only DOS/Windows style drive prefix in numeric ID can be used.</td><td>0:/filename</td></tr>
+<tr><td>0</td><td>Only DOS/Windows style drive prefix in numeric ID can be used.</td><td>1:/filename</td></tr>
<tr><td>1</td><td>Also DOS/Windows style drive prefix in string ID can be used.</td><td>flash:/filename</td></tr>
<tr><td>2</td><td>Also Unix style drive prefix in string ID can be used.</td><td>/flash/filename</td></tr>
</table>
<h4 id="volume_strs">FF_VOLUME_STRS</h4>
-<p>This option defines the volume ID strings for each logical drives. Number of items must not be less than <tt>FF_VOLUMES</tt>. Valid characters for the volume ID string are A-Z, a-z and 0-9, however, they are compared in case-insensitive. If <tt>FF_STR_VOLUME_ID == 0</tt>, this option has no effect. If <tt>FF_STR_VOLUME_ID >= 1</tt> and this option is not defined, a user defined volume string table needs to be defined as shown below.</p>
+<p>This option defines the volume ID strings for each logical drives. Number of items must not be less than <tt>FF_VOLUMES</tt>. Valid characters for the volume ID string are A-Z, a-z and 0-9, however, they are compared in case-insensitive. If <tt>FF_STR_VOLUME_ID == 0</tt>, this option has no effect. If <tt>FF_STR_VOLUME_ID >= 1</tt> and this option is not defined, a user defined volume string table needs to be defined as shown below. The table should not be modified on the fly.</p>
<pre>
-<span class="c">/* User defined volume ID strings for 0: 1: 2: 3: ... */</span>
-const char* VolumeStr[FF_VOLUMES] = {"ram","flash","sdc","usb"};
+<span class="c">/* User defined volume ID strings for 0: to 3: */</span>
+const char* VolumeStr[FF_VOLUMES] = {"ram","flash","sd","usb"};
</pre>
<h4 id="multi_partition">FF_MULTI_PARTITION</h4>
<p>Disable (0) or Enable (1). This option switches multi-partition function. By default (0), each logical drive number is bound to the same physical drive number and only a volume in the physical drive is mounted. When enabled, each logical drive is bound to the partition on the physical drive listed in the user defined partition resolution table <tt>VolToPart[]</tt>. Also <tt>f_fdisk</tt> funciton will be available. For more information, read <a href="filename.html#vol">here</a>.</p>
<h4 id="max_ss">FF_MIN_SS, FF_MAX_SS</h4>
-<p>This set of options defines the extent of sector size used on the low level disk I/O interface, <tt>disk_read</tt> and <tt>disk_write</tt> function. Valid values are 512, 1024, 2048 and 4096. <tt>FF_MIN_SS</tt> defines minimum sector size and <tt>FF_MAX_SS</tt> defines the maximum sector size. Always set both 512 for memory card and harddisk. But a larger value may be required for on-board flash memory and some type of optical media. When <tt>FF_MAX_SS > FF_MIN_SS</tt>, support of variable sector size is enabled and <tt>GET_SECTOR_SIZE</tt> command needs to be implemented to the <tt>disk_ioctl</tt> function.</p>
+<p>This set of options defines the extent of sector size used for the low level disk I/O interface, <tt>disk_read</tt> and <tt>disk_write</tt> function. Valid values are 512, 1024, 2048 and 4096. <tt>FF_MIN_SS</tt> defines minimum sector size and <tt>FF_MAX_SS</tt> defines the maximum sector size. Always set both 512 for memory card and harddisk. But a larger value may be required for on-board flash memory and some type of optical media. When <tt>FF_MAX_SS > FF_MIN_SS</tt>, support of variable sector size is enabled and <tt>GET_SECTOR_SIZE</tt> command needs to be implemented to the <tt>disk_ioctl</tt> function.</p>
+
+<h4 id="fs_lba64">FF_LBA64</h4>
+<p>This option switches media access interface to 64-bit LBA and enables GUID Partition Table (GPT) for partition management, Enabled (1) or Disabled (0). exFAT filesystem needs to be enabled to enable this feature.</p>
+
+<h4 id="fs_gptmin">FF_MIN_GPT</h4>
+<p>This option specifies the threshold of determination of partitioning format when create patitions on the drive in <tt>f_mkfs</tt> and <tt>f_fdisk</tt> function. When number of available sectors is equal or larger than this value, the drive will be partitioned in GPT. This option has no effect when <tt>FF_LBA64 == 0</tt>.</p>
<h4 id="use_trim">FF_USE_TRIM</h4>
<p>Disable (0) or Enable (1). This option switches ATA-TRIM function. To enable Trim function, also <tt>CTRL_TRIM</tt> command should be implemented to the <tt>disk_ioctl</tt> function.</p>
-<h4 id="fs_nofsinfo">FF_FS_NOFSINFO</h4>
-<p>0 to 3. If you need to know correct free space on the FAT32 volume, set bit 0 of this option, and <tt>f_getfree</tt> function at first time after volume mount will force a full FAT scan. Bit 1 controls the use of last allocated cluster number.</p>
-<table class="lst1">
-<tr><th>Value</th><th>Description</th></tr>
-<tr><td>bit0=0</td><td>Use free cluster count in the FSINFO if available.</td></tr>
-<tr><td>bit0=1</td><td>Do not trust free cluster count in the FSINFO.</td></tr>
-<tr><td>bit1=0</td><td>Use last allocated cluster number in the FSINFO to find a free cluster if available.</td></tr>
-<tr><td>bit1=1</td><td>Do not trust last allocated cluster number in the FSINFO.</td></tr>
-</table>
-
</div>
@@ -248,33 +262,40 @@ const char* VolumeStr[FF_VOLUMES] = {"ram","flash","sdc","usb"}; <h3>System Configurations</h3>
<h4 id="fs_tiny">FF_FS_TINY</h4>
-<p>Normal (0) or Tiny (1). At the tiny configuration, size of the file object <tt>FIL</tt> is reduced <tt>FF_MAX_SS</tt> bytes. Instead of private data buffer eliminated from the file object, common sector buffer in the filesystem object <tt>FATFS</tt> is used for the file data transfer.</p>
+<p>Normal (0) or Tiny (1). The tiny configuration reduces size of the <tt>FIL</tt> structure, file object, <tt>FF_MAX_SS</tt> bytes each. Instead of private sector buffer eliminated from the file object, common sector buffer in the <tt>FATFS</tt> structure, filesystem object, is used for the file data transfer.</p>
<h4 id="fs_exfat">FF_FS_EXFAT</h4>
-<p>This option switches support for the exFAT filesystem in addition to the FAT/FAT32 filesystem, Enabled (1) or Disabled (0). To enable exFAT, also LFN must be enabled and configureing <tt>FF_LFN_UNICODE >= 1</tt> and <tt>FF_MAX_LFN == 255</tt> is recommended for full-featured exFAT function. Note that enabling exFAT discards ANSI C (C89) compatibility because of need for 64-bit integer type.</p>
+<p>This option switches support for exFAT filesystem in addition to the FAT/FAT32 filesystem, Enabled (1) or Disabled (0). To enable exFAT, also LFN must be enabled and configureing <tt>FF_LFN_UNICODE >= 1</tt> and <tt>FF_MAX_LFN == 255</tt> is recommended for full-featured exFAT function. Note that enabling exFAT discards ANSI C (C89) compatibility and wants C99 because of need for 64-bit integer type.</p>
<h4 id="fs_nortc">FF_FS_NORTC</h4>
-<p>Use RTC (0) or Do not use RTC (1). This option controls timestamp function. If the system does not have any RTC function or valid timestamp is not needed, set <tt>FF_FS_NORTC</tt> to 1 to disable the timestamp function. Every objects modified by FatFs will have a fixed timestamp defined by <tt>FF_NORTC_MON</tt>, <tt>FF_NORTC_MDAY</tt> and <tt>FF_NORTC_YEAR</tt>. To use the timestamp function, set <tt>FF_FS_NORTC == 0</tt> and add <tt>get_fattime</tt> function to the project to get current time form the RTC. This option has no effect at read-only configuration.</p>
+<p>Use RTC (0) or Do not use RTC (1). This option controls timestamp featuer. If the system does not have an RTC or valid timestamp is not needed, set <tt>FF_FS_NORTC</tt> to 1 to disable the timestamp function. Every objects modified by FatFs will have a constant timestamp defined by <tt>FF_NORTC_MON</tt>, <tt>FF_NORTC_MDAY</tt> and <tt>FF_NORTC_YEAR</tt>. To use the timestamp featuer, set <tt>FF_FS_NORTC == 0</tt> and add <tt>get_fattime</tt> function to the project to get current time form the RTC. This option has no effect in read-only configuration.</p>
<h4 id="nortc_time">FF_NORTC_MON, FF_NORTC_MDAY, FF_NORTC_YEAR</h4>
-<p>This set of options defines the time to be used at no RTC systems. This option has no effect at read-only configuration or <tt>FF_FS_NORTC == 0</tt>.</p>
+<p>This set of options defines the time to be used in no RTC systems. This option has no effect in read-only configuration or <tt>FF_FS_NORTC == 0</tt>.</p>
+
+<h4 id="fs_nofsinfo">FF_FS_NOFSINFO</h4>
+<p>0 to 3. If you need to know correct free space on the FAT32 volume, set bit 0 of this option, and <tt>f_getfree</tt> function at first time after the volume mounted will force a full FAT scan. Bit 1 controls the use of last allocated cluster number for new allocation.</p>
+<table class="lst1">
+<tr><th>Value</th><th>Description</th></tr>
+<tr><td>bit0=0</td><td>Use free cluster count in the FSINFO if available.</td></tr>
+<tr><td>bit0=1</td><td>Do not trust free cluster count in the FSINFO.</td></tr>
+<tr><td>bit1=0</td><td>Use last allocated cluster number in the FSINFO to find a free cluster if available.</td></tr>
+<tr><td>bit1=1</td><td>Do not trust last allocated cluster number in the FSINFO.</td></tr>
+</table>
<h4 id="fs_lock">FF_FS_LOCK</h4>
-<p>This option switches file lock function to control duplicated file open and illegal operations to open objects. Note that the file lock function is independent of re-entrancy. This option must be 0 at read-only configuration.</p>
+<p>This option switches file lock feature to control duplicated file open and illegal operations to the open objects. Note that this feature is independent of re-entrancy. This option must be 0 in read-only configuration.</p>
<table class="lst1">
<tr><th>Value</th><th>Description</th></tr>
-<tr><td>0</td><td>Disable file lock function. To avoid collapsing file by wrong file operation, application program needs to avoid illegal open, remove and rename to the open objects.</td></tr>
-<tr><td>>0</td><td>Enable file lock function. The value defines how many files/sub-directories can be opened simultaneously under the file lock control. Illigal operations to the open object will be rejected with <tt>FR_LOCKED</tt>.</td></tr>
+<tr><td>0</td><td>Disable file lock feature. To avoid to collapse files due to wrong file operations, application program needs to avoid illegal open, remove and rename to the open objects.</td></tr>
+<tr><td>>0</td><td>Enable file lock feature. The value defines how many files/sub-directories can be opened simultaneously under the file lock feature. Illigal operations to the open object will be rejected with <tt>FR_LOCKED</tt>.</td></tr>
</table>
<h4 id="fs_reentrant">FF_FS_REENTRANT</h4>
-<p>Disable (0) or Enable (1). This option switches the re-entrancy (thread safe) of the FatFs module itself. Note that file/directory access to the different volume is always re-entrant and it can work simultaneously regardless of this option but volume control functions. <tt>f_mount</tt>, <tt>f_mkfs</tt> and <tt>f_fdisk</tt>, are always not re-entrant. Only file/directory access to the same volume, in other words, exclusive use of each filesystem object, is under control of this function. To enable this feature, also user provided synchronization handlers, <tt>ff_req_grant</tt>, <tt>ff_rel_grant</tt>, <tt>ff_del_syncobj</tt> and <tt>ff_cre_syncobj</tt>, need to be added to the project. Sample code is available in <tt>ffsystem.c</tt>.</p>
+<p>Disable (0) or Enable (1). This option switches the re-entrancy (thread safe) of the FatFs module itself. Note that file/directory access to the different volume is always re-entrant and it can work simultaneously regardless of this option, however, volume management functions, <tt>f_mount</tt>, <tt>f_mkfs</tt> and <tt>f_fdisk</tt>, are <em>always not re-entrant</em>. Only file/directory access to the same volume, in other words, exclusive use of each filesystem object, is under control in this feature. To enable this feature, also user provided synchronization handlers, <tt>ff_mutex_take</tt>, <tt>ff_mutex_give</tt>, <tt>ff_mutex_create</tt> and <tt>ff_mutex_delete</tt>, need to be added to the project. Sample code is available in <tt>ffsystem.c</tt>.</p>
<h4 id="fs_timeout">FF_FS_TIMEOUT</h4>
-<p>Number of time ticks to abort the file function with <tt>FR_TIMEOUT</tt> when wait time is too long. This option has no effect when <tt>FF_FS_REENTRANT == 0</tt>.</p>
-
-<h4 id="sync_t">FF_SYNC_t</h4>
-<p>This option defines O/S dependent sync object type. e.g. <tt>HANDLE</tt>, <tt>ID</tt>, <tt>OS_EVENT*</tt>, <tt>SemaphoreHandle_t</tt> and etc. A header file for O/S definitions needs to be included somewhere in the scope of <tt>ff.c</tt>. This option has no effect when <tt>FF_FS_REENTRANT == 0</tt>.</p>
+<p>Number of O/S time ticks to abort the file function with <tt>FR_TIMEOUT</tt> when the wait time exceeds this period. This option has no effect when <tt>FF_FS_REENTRANT == 0</tt>.</p>
</div>
diff --git a/fatfs/documents/doc/dinit.html b/fatfs/documents/doc/dinit.html index a7718bc..c668c66 100644 --- a/fatfs/documents/doc/dinit.html +++ b/fatfs/documents/doc/dinit.html @@ -38,7 +38,7 @@ DSTATUS disk_initialize ( <div class="para desc">
<h4>Description</h4>
<p>This function initializes the storage device and put it ready to generic read/write. When the function succeeded, <tt>STA_NOINIT</tt> flag in the return value is cleared.</p>
-<p><em>Remarks: This function needs to be under control of FatFs module. Application program MUST NOT call this function, or FAT structure on the volume can be broken. To re-initialize the filesystem, use <tt>f_mount</tt> function instead.</em></p>
+<p><em>Remarks: This function needs to be under control of FatFs module. Application program MUST NOT call this function while FatFs is in use, or FAT structure on the volume can be broken. To re-initialize the filesystem, use <tt>f_mount</tt> function instead.</em></p>
</div>
<p class="foot"><a href="../00index_e.html">Return</a></p>
diff --git a/fatfs/documents/doc/dioctl.html b/fatfs/documents/doc/dioctl.html index 15b9c8a..b7ad0aa 100644 --- a/fatfs/documents/doc/dioctl.html +++ b/fatfs/documents/doc/dioctl.html @@ -57,35 +57,35 @@ DRESULT disk_ioctl ( <table class="lst">
<caption>Standard ioctl command used by FatFs</caption>
<tr><th>Command</th><th>Description</th></tr>
-<tr><td>CTRL_SYNC</td><td>Make sure that the device has finished pending write process. If the disk I/O module has a write back cache, the dirty buffers must be written back to the media immediately. Nothing to do for this command if each write operation to the media is completed within the <tt>disk_write</tt> function.</td></tr>
-<tr><td>GET_SECTOR_COUNT</td><td>Returns number of available sectors on the drive into the <tt>DWORD</tt> variable pointed by <tt class="arg">buff</tt>. This command is used by <tt>f_mkfs</tt> and <tt>f_fdisk</tt> function to determine the volume/partition size to be created. Required at <tt>FF_USE_MKFS == 1</tt>.</td></tr>
-<tr><td>GET_SECTOR_SIZE</td><td>Returns sector size of the device into the <tt>WORD</tt> variable pointed by <tt class="arg">buff</tt>. Valid return values for this command are 512, 1024, 2048 and 4096. This command is required only if <tt>FF_MAX_SS > FF_MIN_SS</tt>. When <tt>FF_MAX_SS == FF_MIN_SS</tt>, this command is never used and the device must work at that sector size.</td></tr>
-<tr><td>GET_BLOCK_SIZE</td><td>Returns erase block size of the flash memory media in unit of sector into the <tt>DWORD</tt> variable pointed by <tt class="arg">buff</tt>. The allowable value is 1 to 32768 in power of 2. Return 1 if the erase block size is unknown or non flash memory media. This command is used by only <tt>f_mkfs</tt> function and it attempts to align data area on the erase block boundary. Required at <tt>FF_USE_MKFS == 1</tt>.</td></tr>
-<tr><td>CTRL_TRIM</td><td>Informs the device the data on the block of sectors is no longer needed and it can be erased. The sector block is specified by a <tt>DWORD</tt> array {<start sector>, <end sector>} pointed by <tt class="arg">buff</tt>. This is an identical command to Trim of ATA device. Nothing to do for this command if this funcion is not supported or not a flash memory device. FatFs does not check the result code and the file function is not affected even if the sector block was not erased well. This command is called on remove a cluster chain and in the <tt>f_mkfs</tt> function. Required at <tt>FF_USE_TRIM == 1</tt>.</td></tr>
+<tr><td>CTRL_SYNC</td><td>Makes sure that the device has finished pending write process. If the disk I/O layer or storage device has a write-back cache, the dirty cache data must be committed to the medium immediately. Nothing to do for this command if each write operation to the medium is completed in the <tt>disk_write</tt> function.</td></tr>
+<tr><td>GET_SECTOR_COUNT</td><td>Retrieves number of available sectors, the largest allowable LBA + 1, on the drive into the <tt>LBA_t</tt> variable that pointed by <tt class="arg">buff</tt>. This command is used by <tt>f_mkfs</tt> and <tt>f_fdisk</tt> function to determine the size of volume/partition to be created.</td></tr>
+<tr><td>GET_SECTOR_SIZE</td><td>Retrieves sector size, minimum data unit for generic read/write, into the <tt>WORD</tt> variable that pointed by <tt class="arg">buff</tt>. Valid sector sizes are 512, 1024, 2048 and 4096. This command is required only if <tt>FF_MAX_SS > FF_MIN_SS</tt>. When <tt>FF_MAX_SS == FF_MIN_SS</tt>, this command will never be used and the <tt>disk_read</tt> and <tt>disk_write</tt> function must work in <tt>FF_MAX_SS</tt> bytes/sector.</td></tr>
+<tr><td>GET_BLOCK_SIZE</td><td>Retrieves <em>erase block size in unit of sector</em> of the flash memory media into the <tt>DWORD</tt> variable that pointed by <tt class="arg">buff</tt>. The allowable value is 1 to 32768 in power of 2. Return 1 if it is unknown or in non flash memory media. This command is used by <tt>f_mkfs</tt> function with block size not specified and it attempts to align the data area on the suggested block boundary. Note that FatFs does not have FTL (flash translation layer), so that either disk I/O layter or storage device must have an FTL in it.</td></tr>
+<tr><td>CTRL_TRIM</td><td>Informs the disk I/O layter or the storage device that the data on the block of sectors is no longer needed and it can be erased. The sector block is specified in an <tt>LBA_t</tt> array <tt>{<Start LBA>, <End LBA>}</tt> that pointed by <tt class="arg">buff</tt>. This is an identical command to Trim of ATA device. Nothing to do for this command if this funcion is not supported or not a flash memory device. FatFs does not check the result code and the file function is not affected even if the sector block was not erased well. This command is called on remove a cluster chain and in the <tt>f_mkfs</tt> function. It is required when <tt>FF_USE_TRIM == 1</tt>.</td></tr>
</table>
-<p>FatFs never uses any device dependent command nor user defined command. Following table shows an example of non-standard commands which may be useful for some applications.</p>
+<p>FatFs will never use any device dependent command nor user defined command. Following table shows an example of non-standard commands which may be useful for some applications.</p>
<table class="lst">
<caption>Example of optional ioctl command</caption>
<tr><th>Command</th><th>Description</th></tr>
-<tr><td>CTRL_FORMAT</td><td>Create a physical format on the media. If <tt class="arg">buff</tt> is not null, it is pointer to the call-back function for progress notification.</td></tr>
-<tr><td>CTRL_POWER_IDLE</td><td>Put the device idle state. <tt>STA_NOINIT</tt> in the current status flags may not be set if the device goes active state by generic read/write function.</td></tr>
-<tr><td>CTRL_POWER_OFF</td><td>Put the device off state. Shut-down the power to the device and deinitialize the device interface if needed. <tt>STA_NOINIT</tt> in the current status flags must be set. The device goes active state by <tt>disk_initialize</tt> function.</td></tr>
-<tr><td>CTRL_LOCK</td><td>Lock media eject mechanism.</td></tr>
-<tr><td>CTRL_UNLOCK</td><td>Unlock media eject mechanism.</td></tr>
-<tr><td>CTRL_EJECT</td><td>Eject media cartridge. <tt>STA_NOINIT</tt> and <tt>STA_NODISK</tt> in status flag are set after the function succeeded.</td></tr>
-<tr><td>CTRL_GET_SMART</td><td>Read SMART information.</td></tr>
-<tr><td>MMC_GET_TYPE</td><td>Get card type. The type flags, bit0:MMCv3, bit1:SDv1, bit2:SDv2+ and bit3:LBA, is stored to a BYTE variable pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
-<tr><td>MMC_GET_CSD</td><td>Read CSD register into a 16-byte buffer pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
-<tr><td>MMC_GET_CID</td><td>Read CID register into a 16-byte buffer pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
-<tr><td>MMC_GET_OCR</td><td>Read OCR register into a 4-byte buffer pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
-<tr><td>MMC_GET_SDSTAT</td><td>Read SDSTATUS register into a 64-byte buffer pointed by <tt class="arg">buff</tt>. (SDC specific command)</td></tr>
-<tr><td>ATA_GET_REV</td><td>Get the revision string into a 16-byte buffer pointed by <tt class="arg">buff</tt>. (ATA/CFC specific command)</td></tr>
-<tr><td>ATA_GET_MODEL</td><td>Get the model string into a 40-byte buffer pointed by <tt class="arg">buff</tt>. (ATA/CFC specific command)</td></tr>
-<tr><td>ATA_GET_SN</td><td>Get the serial number string into a 20-byte buffer pointed by <tt class="arg">buff</tt>. (ATA/CFC specific command)</td></tr>
-<tr><td>ISDIO_READ</td><td>Read a block of iSDIO registers specified by command structure pointed by <tt class="arg">buff</tt>. (FlashAir specific command)</td></tr>
-<tr><td>ISDIO_WRITE</td><td>Write a block of data to iSDIO registers specified by command structure pointed by <tt class="arg">buff</tt>. (FlashAir specific command)</td></tr>
-<tr><td>ISDIO_MRITE</td><td>Change bits in an iSDIO register specified by command structure pointed by <tt class="arg">buff</tt>. (FlashAir specific command)</td></tr>
+<tr><td>CTRL_FORMAT</td><td>Creates a physical format on the media. If <tt class="arg">buff</tt> is not null, it is pointer to the call-back function for progress notification.</td></tr>
+<tr><td>CTRL_POWER_IDLE</td><td>Puts the device idle state. <tt>STA_NOINIT</tt> in the current status flags may not be set if the device goes active state by generic read/write function.</td></tr>
+<tr><td>CTRL_POWER_OFF</td><td>Puts the device off state. Shut-down the power to the device and deinitialize the device interface if needed. <tt>STA_NOINIT</tt> in the current status flags must be set. The device goes active state by <tt>disk_initialize</tt> function.</td></tr>
+<tr><td>CTRL_LOCK</td><td>Locks media eject mechanism.</td></tr>
+<tr><td>CTRL_UNLOCK</td><td>Unlocks media eject mechanism.</td></tr>
+<tr><td>CTRL_EJECT</td><td>Ejects media cartridge. <tt>STA_NOINIT</tt> and <tt>STA_NODISK</tt> in status flag are set after the function succeeds.</td></tr>
+<tr><td>CTRL_GET_SMART</td><td>Reads SMART information.</td></tr>
+<tr><td>MMC_GET_TYPE</td><td>Gets card type. The type flags, bit0:MMCv3, bit1:SDv1, bit2:SDv2+ and bit3:LBA, is stored to a <tt>BYTE</tt> variable pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
+<tr><td>MMC_GET_CSD</td><td>Reads CSD register and sets it into a 16-byte buffer pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
+<tr><td>MMC_GET_CID</td><td>Reads CID register and sets it into a 16-byte buffer pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
+<tr><td>MMC_GET_OCR</td><td>Reads OCR register and sets it into a 4-byte buffer pointed by <tt class="arg">buff</tt>. (MMC/SDC specific command)</td></tr>
+<tr><td>MMC_GET_SDSTAT</td><td>Reads SDSTATUS register and sets it into a 64-byte buffer pointed by <tt class="arg">buff</tt>. (SDC specific command)</td></tr>
+<tr><td>ATA_GET_REV</td><td>Reads the revision string and sets it into a 16-byte buffer pointed by <tt class="arg">buff</tt>. (ATA/CFC specific command)</td></tr>
+<tr><td>ATA_GET_MODEL</td><td>Reads the model string and sets it into a 40-byte buffer pointed by <tt class="arg">buff</tt>. (ATA/CFC specific command)</td></tr>
+<tr><td>ATA_GET_SN</td><td>Reads the serial number string and sets it into a 20-byte buffer pointed by <tt class="arg">buff</tt>. (ATA/CFC specific command)</td></tr>
+<tr><td>ISDIO_READ</td><td>Reads a block of iSDIO registers specified by command structure pointed by <tt class="arg">buff</tt>. (FlashAir specific command)</td></tr>
+<tr><td>ISDIO_WRITE</td><td>Writes a block of data to iSDIO registers specified by command structure pointed by <tt class="arg">buff</tt>. (FlashAir specific command)</td></tr>
+<tr><td>ISDIO_MRITE</td><td>Changes bits in an iSDIO register specified by command structure pointed by <tt class="arg">buff</tt>. (FlashAir specific command)</td></tr>
</table>
</div>
diff --git a/fatfs/documents/doc/dread.html b/fatfs/documents/doc/dread.html index 75b52c0..1be191b 100644 --- a/fatfs/documents/doc/dread.html +++ b/fatfs/documents/doc/dread.html @@ -13,12 +13,12 @@ <div class="para func">
<h2>disk_read</h2>
-<p>The disk_read function is called to read data from the sector(s) of storage device.</p>
+<p>The disk_read function is called to read data from the storage device.</p>
<pre>
DRESULT disk_read (
BYTE <span class="arg">pdrv</span>, <span class="c">/* [IN] Physical drive number */</span>
BYTE* <span class="arg">buff</span>, <span class="c">/* [OUT] Pointer to the read data buffer */</span>
- DWORD <span class="arg">sector</span>, <span class="c">/* [IN] Start sector number */</span>
+ LBA_t <span class="arg">sector</span>, <span class="c">/* [IN] Start sector number */</span>
UINT <span class="arg">count</span> <span class="c">/* [IN] Number of sectros to read */</span>
);
</pre>
@@ -32,7 +32,7 @@ DRESULT disk_read ( <dt>buff</dt>
<dd>Pointer to the first item of the <em>byte array</em> to store read data. Size of read data will be the sector size * <tt class="arg">count</tt> bytes.</dd>
<dt>sector</dt>
-<dd>Start sector number in 32-bit LBA.</dd>
+<dd>Start sector number in LBA. The data type <tt>LBA_t</tt> is an alias of <tt>DWORD</tt> or <tt>QWORD</tt> depends on the configuration option.</dd>
<dt>count</dt>
<dd>Number of sectors to read.</dd>
</dl>
@@ -56,13 +56,14 @@ DRESULT disk_read ( <div class="para desc">
<h4>Description</h4>
-<p>Read/write operation to the generic storage devices, such as memory card, hadddisk and optical disk, is done in unit of block of data bytes called <em>sector</em>. FatFs supports the sector size in range of 512 to 4096 bytes. When FatFs is configured for fixed sector size (<tt>FF_MIN_SS == FF_MAX_SS</tt>, this is the most case), the read/write function must work at that sector size. When FatFs is configured for variable sector size (<tt>FF_MIN_SS < FF_MAX_SS</tt>), the sector size of medium is inquired with <tt>disk_ioctl</tt> function immediately following <tt>disk_initialize</tt> function succeeded.</p>
-<p>The memory address specified by <tt class="arg">buff</tt> is not that always aligned to word boundary because the argument is defined as <tt>BYTE*</tt>. The unaligned read/write request can occure at <a href="appnote.html#fs1">direct transfer</a>. If the bus architecture, especially DMA controller, does not allow unaligned memory access, it should be solved in this function. There are some workarounds described below to avoid this issue.</p>
+<p>Read/write operation to the generic storage devices, such as memory card, hadddisk and optical disk, is done in unit of block of data bytes called <em>sector</em>. FatFs supports the sector size in range of 512 to 4096 bytes. When FatFs is configured for fixed sector size (<tt>FF_MIN_SS == FF_MAX_SS</tt>, this is the most case), the generic read/write function must work at this sector size only. When FatFs is configured for variable sector size (<tt>FF_MIN_SS < FF_MAX_SS</tt>), the sector size of medium is inquired with <tt>disk_ioctl</tt> function after <tt>disk_initialize</tt> function succeeds.</p>
+<p>There are some considerations about the memory addres passed via <tt class="arg">buff</tt>. It is not that always aligned with the word boundary, because the argument is defined as <tt>BYTE*</tt>. The unaligned transfer request can occure at <a href="appnote.html#fs1">direct transfer</a>. If the bus architecture, especially DMA controller, does not allow unaligned memory access, it should be solved in this function. If it is the case, there are some workarounds described below to avoid this issue.</p>
<ul>
-<li>Convert word transfer to byte transfer in this function if needed. - Recommended.</li>
+<li>Convert word transfer to byte transfer with some trick in this function. - Recommended.</li>
<li>On the <tt>f_read()</tt> calls, avoid long read request that includes a whole of sector. - Any direct transfer never occures.</li>
-<li>On the <tt>f_read(fp, dat, btw, bw)</tt> calls, make sure that <tt>(((UINT)dat & 3) == (f_tell(fp) & 3))</tt> is true. - Word alignment of <tt class="arg">buff</tt> is guaranteed no matter dat is not word aligned.</li>
+<li>On the <tt>f_read(fp, data, btw, bw)</tt> calls, make sure that <tt>(((UINT)data & 3) == (f_tell(fp) & 3))</tt> is true. - Word alignment of <tt class="arg">buff</tt> is guaranteed.</li>
</ul>
+<p>Also the memory area may be out of reach in DMA. This is the case if it is located on the tightly coupled memory which is usually used for stack. Use double buffered transfer, or avoid to define file I/O buffer, <tt>FATFS</tt> and <tt>FIL</tt> structure as local variables where on the stack.</p>
<p>Generally, a multiple sector read request must not be split into single sector transactions to the storage device, or read throughput gets worse.</p>
</div>
diff --git a/fatfs/documents/doc/dstat.html b/fatfs/documents/doc/dstat.html index e9926bb..a891489 100644 --- a/fatfs/documents/doc/dstat.html +++ b/fatfs/documents/doc/dstat.html @@ -25,7 +25,7 @@ DSTATUS disk_status ( <h4>Parameter</h4>
<dl class="par">
<dt>pdrv</dt>
-<dd>Physical drive number to identify the target device. Always zero at single drive system.</dd>
+<dd>Physical drive number to identify the target device. Always zero in single drive system.</dd>
</dl>
</div>
@@ -37,9 +37,9 @@ DSTATUS disk_status ( <dt>STA_NOINIT</dt>
<dd>Indicates that the device has not been initialized and not ready to work. This flag is set on system reset, media removal or failure of <a href="dinit.html"><tt>disk_initialize</tt></a> function. It is cleared on <tt>disk_initialize</tt> function succeeded. Any media change that occurs asynchronously must be captured and reflect it to the status flags, or auto-mount function will not work correctly. If the system does not support media change detection, application program needs to explicitly re-mount the volume with <tt>f_mount</tt> function after each media change.</dd>
<dt>STA_NODISK</dt>
-<dd>Indicates that no medium in the drive. This is always cleared at fixed disk drive. Note that FatFs does not refer this flag.</dd>
+<dd>Indicates that no medium in the drive. This is always cleared when the drive is non-removable class. Note that FatFs does not refer this flag.</dd>
<dt>STA_PROTECT</dt>
-<dd>Indicates that the medium is write protected. This is always cleared at the drives without write protect function. Not valid if <tt>STA_NODISK</tt> is set.</dd>
+<dd>Indicates that the medium is write protected. This is always cleared when the drive has no write protect function. Not valid if <tt>STA_NODISK</tt> is set.</dd>
</dl>
</div>
diff --git a/fatfs/documents/doc/dwrite.html b/fatfs/documents/doc/dwrite.html index 51174f9..fef5106 100644 --- a/fatfs/documents/doc/dwrite.html +++ b/fatfs/documents/doc/dwrite.html @@ -13,12 +13,12 @@ <div class="para func">
<h2>disk_write</h2>
-<p>The disk_write function is called to write data to the sector(s) of storage device.</p>
+<p>The disk_write function is called to write data to the storage device.</p>
<pre>
DRESULT disk_write (
BYTE <span class="arg">pdrv</span>, <span class="c">/* [IN] Physical drive number */</span>
const BYTE* <span class="arg">buff</span>, <span class="c">/* [IN] Pointer to the data to be written */</span>
- DWORD <span class="arg">sector</span>, <span class="c">/* [IN] Sector number to write from */</span>
+ LBA_t <span class="arg">sector</span>, <span class="c">/* [IN] Sector number to write from */</span>
UINT <span class="arg">count</span> <span class="c">/* [IN] Number of sectors to write */</span>
);
</pre>
@@ -32,7 +32,7 @@ DRESULT disk_write ( <dt>buff</dt>
<dd>Pointer to the first item of the <em>byte array</em> to be written. The size of data to be written is sector size * <tt class="arg">count</tt> bytes.</dd>
<dt>sector</dt>
-<dd>Start sector number in 32-bit LBA.</dd>
+<dd>Start sector number in LBA. The data type <tt>LBA_t</tt> is an alias of <tt>DWORD</tt> or <tt>QWORD</tt> depends on the configuration option.</dd>
<dt>count</dt>
<dd>Number of sectors to write.</dd>
</dl>
@@ -60,7 +60,7 @@ DRESULT disk_write ( <h4>Description</h4>
<p>The specified memory address is not that always aligned to word boundary because the argument is defined as <tt>BYTE*</tt>. For more information, refer to the description of <a href="dread.html"><tt>disk_read</tt></a> function.</p>
<p>Generally, a multiple sector write request (<tt class="arg">count</tt><tt> > 1</tt>) must not be split into single sector transactions to the storage device, or the file write throughput will be drastically decreased.</p>
-<p>FatFs expects delayed write function of the disk control layer. The write operation to the media does not need to be completed at return from this function by what write operation is in progress or data is only stored into the write-back cache. But write data on the <tt class="arg">buff</tt> is invalid after return from this function. The write completion request is done by <tt>CTRL_SYNC</tt> command of <tt><a href="dioctl.html">disk_ioctl</a></tt> function. Therefore, if a delayed write function is implemented, the write throughput of the filesystem will be improved.</p>
+<p>FatFs expects delayed write function of the disk control layer. The write operation to the media does not need to be completed when return from this function by what write operation is in progress or data is only stored into the write-back cache. But write data on the <tt class="arg">buff</tt> is invalid after return from this function. The write completion request is done by <tt>CTRL_SYNC</tt> command of <tt><a href="dioctl.html">disk_ioctl</a></tt> function. Therefore, if a delayed write function is implemented, the write throughput of the filesystem will be improved.</p>
<p><em>Remarks: Application program MUST NOT call this function, or FAT structure on the volume can be collapsed.</em></p>
</div>
diff --git a/fatfs/documents/doc/expand.html b/fatfs/documents/doc/expand.html index d64f483..7620ba9 100644 --- a/fatfs/documents/doc/expand.html +++ b/fatfs/documents/doc/expand.html @@ -19,7 +19,7 @@ FRESULT f_expand (
FIL* <span class="arg">fp</span>, <span class="c">/* [IN] File object */</span>
FSIZE_t <span class="arg">fsz</span>, <span class="c">/* [IN] File size expanded to */</span>
- BYTE <span class="arg">opt</span> <span class="c">/* [IN] Operation mode */</span>
+ BYTE <span class="arg">opt</span> <span class="c">/* [IN] Allocation mode */</span>
);
</pre>
</div>
@@ -32,7 +32,7 @@ FRESULT f_expand ( <dt>fsz</dt>
<dd>Number of bytes in size to prepare or allocate for the file. The data type <tt>FSIZE_t</tt> is an alias of either <tt>DWORD</tt>(32-bit) or <tt>QWORD</tt>(64-bit) depends on the configuration option <tt>FF_FS_EXFAT</tt>.</dd>
<dt>opt</dt>
-<dd>Operation mode. Prepare only (0) or Allocate now (1).</dd>
+<dd>Allocation mode. Prepare to allocate (0) or Allocate now (1).</dd>
</dl>
</div>
@@ -52,16 +52,16 @@ FRESULT f_expand ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_expand</tt> function prepares or allocates a contiguous data area to the file. When <tt class="arg">opt</tt> is 1, the function allocates a contiguous data area to the file. Unlike expansion of file by <tt>f_lseek</tt> function, the file must be truncated prior to use this function and read/write pointer of the file stays at top of the file after the function. The file content allocated with this function is <em>undefined</em> because no data is written to the file in this process. The function can fail with <tt>FR_DENIED</tt> due to some reasons below.</p>
+<p>The <tt>f_expand</tt> function prepares or allocates a contiguous data area to the file. When <tt class="arg">opt</tt> is 1, the data area is allocated to the file in this function. Unlike expansion of file size by <tt>f_lseek</tt> function, the file must be truncated prior to use this function and read/write pointer of the file stays at offset 0 after the function call. The file content allocated with this function is <em>undefined</em>, because no data is written to the file in this process. The function can fail with <tt>FR_DENIED</tt> due to some reasons below.</p>
<ul>
<li>No free contiguous space was found.</li>
<li>Size of the file was not zero.</li>
<li>The file has been opened in read-only mode.</li>
<li>Not allowable file size. (>= 4 GB on FAT volume)</li>
</ul>
-<p>When <tt class="arg">opt</tt> is 0, the function finds a contiguous data area and set it as suggested point for next allocation instead of allocating it to the file. The next cluster allocation is started at top of the contiguous area found by this function. Thus the write file is guaranteed be contiguous and no allocation delay until the size reaches that size at least unless any other changes to the volume is performed.</p>
-<p>The contiguous file would have an advantage at time-critical read/write operations. It eliminates some overheads in the filesystem and the storage media caused by random access due to fragmented file data. Especially FAT access for the contiguous file on the exFAT volume is completely eliminated and storage media will be accessed sequentially.</p>
-<p>Also the contiguous file can be easily accessed directly via low-level disk functions. But this is not recommended in consideration for future compatibility.</p>
+<p>When <tt class="arg">opt</tt> is 0, the function finds a contiguous data area and set it as suggested point for next allocation. The subsequent cluster allocation begins at top of the contiguous area found by this function. Thus the file allocation is guaranteed be contiguous and without allocation delay until the file size reaches this size unless any other changes to the volume is performed.</p>
+<p>The contiguous file has an advantage for time-critical read/write operations. It eliminates some overheads in the filesystem and the storage device caused by random access for fragmented file.</p>
+<p>Also the contiguous file can be easily accessed directly via low-level disk functions. However, this is not recommended in consideration of portability and future compatibility. If the file has not been confirmed be contiguous, use <a href="../res/app5.c">this function</a> to examine if the file is contiguous or not.</p>
</div>
<div class="para comp">
diff --git a/fatfs/documents/doc/fattime.html b/fatfs/documents/doc/fattime.html index dfc4937..002733a 100644 --- a/fatfs/documents/doc/fattime.html +++ b/fatfs/documents/doc/fattime.html @@ -48,7 +48,30 @@ DWORD get_fattime (void); <div class="para comp">
<h4>QuickInfo</h4>
-<p>This function is not needed when <tt>FF_FS_READONLY == 1</tt> or <tt>FF_FS_NORTC == 1</tt>.</p>
+<p>This function is not needed when <tt><a href="config.html#fs_readonly">FF_FS_READONLY</a> == 1</tt> or <tt><a href="config.html#fs_nortc">FF_FS_NORTC</a> == 1</tt>.</p>
+</div>
+
+
+<div class="para use">
+<h4>Example</h4>
+<pre>
+DWORD get_fattime (void)
+{
+ time_t t;
+ struct tm *stm;
+
+
+ t = time(0);
+ stm = localtime(&t);
+
+ return (DWORD)(stm->tm_year - 80) << 25 |
+ (DWORD)(stm->tm_mon + 1) << 21 |
+ (DWORD)stm->tm_mday << 16 |
+ (DWORD)stm->tm_hour << 11 |
+ (DWORD)stm->tm_min << 5 |
+ (DWORD)stm->tm_sec >> 1;
+}
+</pre>
</div>
diff --git a/fatfs/documents/doc/fdisk.html b/fatfs/documents/doc/fdisk.html index 1c0c1e1..d8c40bd 100644 --- a/fatfs/documents/doc/fdisk.html +++ b/fatfs/documents/doc/fdisk.html @@ -16,9 +16,9 @@ <p>The f_fdisk fucntion divides a physical drive.</p>
<pre>
FRESULT f_fdisk (
- BYTE <span class="arg">pdrv</span>, <span class="c">/* [IN] Physical drive number */</span>
- const DWORD* <span class="arg">szt</span>, <span class="c">/* [IN] Partition map table */</span>
- void* <span class="arg">work</span> <span class="c">/* [IN] Work area */</span>
+ BYTE <span class="arg">pdrv</span>, <span class="c">/* [IN] Physical drive number */</span>
+ const LBA_t <span class="arg">ptbl[]</span>, <span class="c">/* [IN] Partition map table */</span>
+ void* <span class="arg">work</span> <span class="c">/* [IN] Work area */</span>
);
</pre>
</div>
@@ -28,10 +28,10 @@ FRESULT f_fdisk ( <dl class="par">
<dt>pdrv</dt>
<dd>Specifies the <em>physical drive</em> to be divided. This is not the logical drive number but the drive identifier passed to the low level disk functions.</dd>
-<dt>szt</dt>
-<dd>Pointer to the first item of the partition map table.</dd>
+<dt>ptbl</dt>
+<dd>List of partition size to create on the drive. The data type <tt>LBA_t</tt> is an alias of <tt>DWORD</tt> or <tt>QWORD</tt> depends on the configuration option <tt><a href="config.html#fs_lba64">FF_LBA64</a></tt>.</dd>
<dt>work</dt>
-<dd>Pointer to the function work area. The size must be at least <tt><a href="config.html#max_ss">FF_MAX_SS</a></tt> bytes. When a null pointer is given, the function allocates a memory block for the working buffer (at only <tt><a href="config.html#use_lfn">FF_USE_LFN</a> == 3</tt>).</dd>
+<dd>Pointer to the function work area. The size must be at least <tt><a href="config.html#max_ss">FF_MAX_SS</a></tt> bytes. When a null pointer is given with <tt><a href="config.html#use_lfn">FF_USE_LFN</a> = 3</tt>, a memory block is obtained in this function for the working buffer.</dd>
</dl>
</div>
@@ -49,7 +49,8 @@ FRESULT f_fdisk ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_fdisk</tt> function creates partitions on the physical drive. The partitioning format is in generic FDISK format, so that it can create upto four primary partitions. Logical volumes in the extended partition is not supported. The partition map table with four items specifies how to divide the physical drive. The first item specifies the size of first primary partition and fourth item specifies the fourth primary partition. If the value is less than or equal to 100, it specifies the partition size in percentage of the entire drive space. If it is larger than 100, it specifies the partition size in unit of sector. The partitions are located on the drive in order of from first item.</p>
+<p>The <tt>f_fdisk</tt> function creates partitions on the physical drive. The partitioning format can be in generic MBR or GPT. The partition map table specifies how to divide the physical drive. The first item specifies the size of the first partition and the partitions are located on the drive in order of from the first item. When the value of item is less than or equal to 100, it specifies the partition size in percentage of the entire drive space. When it is larger than 100, it specifies number of sectors. The partition map table is terminated by a zero, no space is remaining for next allocation or 4th partition is created in MBR format. If the specified size is larger than remaining space on the drive, the partition is truncated at end of the drive.</p>
+<p>By default, partitions are created in MBR format. It can create upto four primary partitions on a drive. GPT format is used to create the partitions when 64-bit LBA is enabled (<tt>FF_LBA64 = 1</tt>) and the drive size is equal to or larger than <tt><a href="config.html#fs_gptmin">FF_MIN_GPT</a></tt> sectors. It can create over ten partitions on a drive.</p>
</div>
<div class="para comp">
@@ -60,24 +61,26 @@ FRESULT f_fdisk ( <div class="para use">
<h4>Example</h4>
<pre>
- <span class="c">/* Volume management table defined by user (required when FF_MULTI_PARTITION == 1) */</span>
+ <span class="c">/* Volume mapping table defined by user (required when FF_MULTI_PARTITION == 1) */</span>
- PARTITION VolToPart[] = {
- {0, 1}, <span class="c">/* "0:" ==> Physical drive 0, 1st partition */</span>
- {0, 2}, <span class="c">/* "1:" ==> Physical drive 0, 2nd partition */</span>
- {1, 0} <span class="c">/* "2:" ==> Physical drive 1, auto detection */</span>
+ PARTITION VolToPart[FF_VOLUMES] = {
+ {0, 1}, <span class="c">/* "0:" ==> 1st partition in PD#0 */</span>
+ {0, 2}, <span class="c">/* "1:" ==> 2nd partition in PD#0 */</span>
+ {1, 0} <span class="c">/* "2:" ==> PD#1 as removable drive */</span>
};
</pre>
<pre>
<span class="c">/* Initialize a brand-new disk drive mapped to physical drive 0 */</span>
- DWORD plist[] = {50, 50, 0, 0}; <span class="c">/* Divide drive into two partitions */</span>
- BYTE work[FF_MAX_SS];
+ BYTE work[FF_MAX_SS]; <span class="c">/* Working buffer */</span>
+ LBA_t plist[] = {50, 50, 0}; <span class="c">/* Divide the drive into two partitions */</span>
+ <span class="c">/* {0x10000000, 100}; 256M sectors for 1st partition and left all for 2nd partition */</span>
+ <span class="c">/* {20, 20, 20, 0}; 20% for 3 partitions each and remaing space is left not allocated */</span>
<em>f_fdisk</em>(0, plist, work); <span class="c">/* Divide physical drive 0 */</span>
- f_mkfs("0:", FM_ANY, work, sizeof work); <span class="c">/* Create FAT volume on the logical drive 0 */</span>
- f_mkfs("1:", FM_ANY, work, sizeof work); <span class="c">/* Create FAT volume on the logical drive 1 */</span>
+ f_mkfs("0:", 0, work, sizeof work); <span class="c">/* Create FAT volume on the logical drive 0 */</span>
+ f_mkfs("1:", 0, work, sizeof work); <span class="c">/* Create FAT volume on the logical drive 1 */</span>
</pre>
</div>
diff --git a/fatfs/documents/doc/filename.html b/fatfs/documents/doc/filename.html index dfc285e..8ff028d 100644 --- a/fatfs/documents/doc/filename.html +++ b/fatfs/documents/doc/filename.html @@ -10,16 +10,16 @@ </head>
<body>
-<h1>Path Names on the FatFs</h1>
+<h1>Path Names on the FatFs API</h1>
<div class="para doc" id="nam">
<h3>Format of the Path Names</h3>
<p>The format of path name on the FatFs module is similer to the filename specs of DOS/Windos as follows:</p>
<pre>[<em>drive#</em>:][/]<em>directory</em>/<em>file</em></pre>
-<p>The FatFs module supports long file name (LFN) and 8.3 format file name (SFN). The LFN can be used when <tt><a href="config.html#use_lfn">FF_USE_LFN</a> >= 1</tt>. The sub directories are separated with a <tt>\</tt> or <tt>/</tt> in the same way as DOS/Windows API. Duplicated separators are skipped and ignored. Only a difference is that the heading drive prefix to specify logical drive is in a numeral + colon. When drive prefix is omitted, the drive number is assumed as <em>default drive</em> (drive 0 or current drive).</p>
-<p>Control characters (<tt>\0</tt> to <tt>\x1F</tt>) are recognized as end of the path name. Leading/embedded white spaces in the path name are valid as a part of the name at LFN configuration but the white space is recognized as end of the path name at non-LFN configuration. Trailing white spaces and dots are ignored at both configurations.</p>
-<p>In default configuration (<tt><a href="config.html#fs_rpath">FF_FS_RPATH</a> == 0</tt>), it does not have a concept of current directory like OS oriented filesystem. Every object on the volume is always specified in full path name that followed from the root directory. Dot directory names (<tt>".", ".."</tt>) are not allowed. Heading separator is ignored and it can be exist or omitted. The default drive is fixed to drive 0.</p>
-<p>When relative path is enabled (<tt>FF_FS_RPATH >= 1</tt>), specified path is followed from the root directory if a heading separator is exist. If not, it is followed from the current directory of the drive set by <a href="chdir.html"><tt>f_chdir</tt></a> function. Dot names are also allowed for the path names. The default drive is the current drive set by <a href="chdrive.html"><tt>f_chdrive</tt></a> function.</p>
+<p>The FatFs module supports long file name (LFN) and 8.3 format file name (SFN). The LFN can be used when <tt><a href="config.html#use_lfn">FF_USE_LFN</a> >= 1</tt>. The sub-directories are separated with a <tt>\</tt> or <tt>/</tt> as the same way as DOS/Windows API. Duplicated separator and terminating separator, such as <tt>"/<em>/</em>animal/<em>//</em>cat<em>/</em>"</tt>, are ignored. Only a difference is that the heading drive prefix to specify the <a href="#vol">logical drive</a>, an FAT volume, is in a digit (0-9) + a colon, while it is in an alphabet (A-Z) + a colon in DOS/Windows. The logical drive number is the identifier to specify the volume to be accessed. When drive prefix is omitted, the logical drive number is assumed as <em>default drive</em>.</p>
+<p>Control characters (<tt>\0</tt> to <tt>\x1F</tt>) are recognized as end of the path name. In LFN configuration, leading or embedded white spaces in the file name are valid as part of the file name, but the treminating white space and dot of the file name are ignored and truncated. In non-LFN configuration, white space is recognized as end of the path name.</p>
+<p>In default configuration (<tt><a href="config.html#fs_rpath">FF_FS_RPATH</a> == 0</tt>), it does not have a concept of current directory like OS oriented filesystem. Every object on the volume is always specified in full path name followed from the root directory. Dot directory names (<tt>".", ".."</tt>) are not allowed. Heading separator is ignored and it can be exist or omitted. The default drive is fixed to drive 0.</p>
+<p>When relative path feature is enabled (<tt>FF_FS_RPATH >= 1</tt>), specified path is followed from the root directory if a heading separator is exist. If not, it is followed from the current directory of the default drive. Dot directory name is also allowed for the path name. The current directory is set by <a href="chdir.html"><tt>f_chdir</tt></a> function and the default drive is the current drive set by <a href="chdrive.html"><tt>f_chdrive</tt></a> function.</p>
<table class="lst2">
<tr><td>Path name</td><td>FF_FS_RPATH == 0</td><td>FF_FS_RPATH >= 1</td></tr>
<tr class="lst3"><td>file.txt</td><td>A file in the root directory of the drive 0</td><td>A file in the current directory of the current drive</td></tr>
@@ -35,51 +35,57 @@ <tr><td>dir1/..</td><td>Invalid name</td><td>The current directory</td></tr>
<tr><td>/..</td><td>Invalid name</td><td>The root directory (sticks the top level)</td></tr>
</table>
-<p>Also the drive prefix can be in pre-defined arbitrary string. When the option <tt><a href="config.html#str_volume_id">FF_STR_VOLUME_ID</a> == 1</tt>, also arbitrary string volume ID can be used as drive prefix. e.g. <tt>"flash:file1.txt"</tt>, <tt>"ram:temp.dat"</tt> or <tt>"usb:"</tt>. When <tt>FF_STR_VOLUME_ID == 2</tt>, Unix style drive prefix can be used. e.g. <tt>"/flash/file1.txt"</tt>, <tt>"/ram/temp.dat"</tt> or <tt>"/usb"</tt>. However, it cannot traverse the drives such as <tt>"/flash/../ram/temp.dat"</tt>. The Unix style drive prefix may lead a confusion in identification between volume ID and file name. For instance, which does <tt>"/flash"</tt> mean, a file <tt>"flash"</tt> on the root directory without drive prefix or a drive prefix of <tt>"flash"</tt>? If the string following a heading slash matches with any volume ID, it is treated as a drive prefix and skipped over.</p>
-
+<p>Also the drive prefix can be in pre-defined arbitrary string. When the option <tt><a href="config.html#str_volume_id">FF_STR_VOLUME_ID</a> == 1</tt>, also arbitrary string volume ID can be used as drive prefix. e.g. <tt>"<em>flash:</em>file1.txt"</tt>, <tt>"<em>ram:</em>temp.dat"</tt> or <tt>"<em>sd:</em>"</tt>. If the srting does not match any volume ID, the function fails with <tt>FR_INVALID_DRIVE</tt>.</p>
+<p>When <tt>FF_STR_VOLUME_ID == 2</tt>, Unix style drive prefix can be used. e.g. <tt>"<em>/flash</em>/file1.txt"</tt>, <tt>"<em>/ram</em>/temp.dat"</tt> or <tt>"<em>/sd</em>"</tt>. If a heading separator is exist, it is treated as start of drive prefix and in absolute path. Any form as "root directory in current drive" and "current directory in specified drive" cannot be used. Double dot name cannot traverse the drives such as <tt>"<em>/flash</em>/..<em>/ram</em>/foo.dat"</tt>.</p>
<p><em>Remark: In this revision, double dot name <tt>".."</tt> cannot follow the parent directory on the exFAT volume. It will work as <tt>"."</tt> and stay there.</em></p>
</div>
<div class="para doc" id="case">
<h3>Legal Characters and Case Sensitivity</h3>
-<p>On the FAT filesystem, legal characters for object name (file/directory name) are, <tt>0-9 A-Z ! # $ % & ' ( ) - @ ^ _ ` { } ~</tt> and extended characters (<tt>\x80</tt>-<tt>\xFF</tt>). Under LFN supported system, also <tt>+ , ; = [ ]</tt> and white space are legal for the object name and the white spaces and dots can be placed anywhere in the path name except for end of the object name.</p>
-<p>FAT filesystem is case-insensitive to the object names on the volume. Object name on the FAT volume is compared in case-insensitive. For instance, these three names, <tt>file.txt</tt>, <tt>File.Txt</tt> and <tt>FILE.TXT</tt>, are identical. This is applied to extended charactres as well. When an object is created on the FAT volume, up converted name is recorded to the SFN entry, and the raw name is recorded to the LFN entry when LFN function is enabled.</p>
-<p>As for the MS-DOS and PC DOS for CJK, it was case-sensitive to the DBCS extended characters. To follow this specification, FatFs works with case-sensitive to the extended characters at only non-LFN with DBCS configuration (DOS/DBCS specs). But at LFN configuration, FatFs works with case-insensitive to the extended character (WindowsNT specs). This can cause a problem on compatibility with Windows system when an object with extended characters is created on the volume at non-LFN and DBCS configuration; therfore the object names with DBCS extended characters should not be used on the FAT volume shared by those systems.</p>
+<p>In the generic FAT filesystems, the legal characters for object name (file/directory name) are, <tt>0-9 A-Z ! # $ % & ' ( ) - @ ^ _ ` { } ~</tt> in ASCII and extended characters <tt>\x80</tt> to <tt>\xFF</tt>. In the FAT filesystems with LFN extention, also <tt>+ , ; = [ ]</tt>, white space and extended characters <tt>U+000080</tt> to <tt>U+10FFFF</tt> are legal for the object name. White spaces and dots can be placed anywhere in the path name except end of the name. Trailing white spaces and dots are ignored.</p>
+<p>FAT filesystem is case-insensitive to the object names on the volume. Object name on the FAT volume is compared in case-insensitive. For instance, these three names, <tt>file.txt</tt>, <tt>File.Txt</tt> and <tt>FILE.TXT</tt>, are identical on the FAT filesystem. This is applied to extended charactres as well. When an object is created on the FAT volume, up converted name is recorded to the SFN entry, and the raw name is recorded to the LFN entry when LFN extension is exist.</p>
+<p>As for the MS-DOS and PC DOS for CJK (DOS/DBCS), extended characters ware recorded to the SFN entry without up-case conversion and compared in case-sensitive. This causes a problem on compatibility with Windows system when the object with extended characters is created on the volume by DOS/DBCS system; therfore the object names with DBCS extended characters should not be used on the FAT volume shared by those systems. FatFs works with case-sensitive to the extended characters in only non-LFN with DBCS configuration (DOS/DBCS specs). However, FatFs works with case-insensitive to the extended character (WindowsNT specs) in LFN configuration.</p>
</div>
<div class="para doc" id="uni">
<h3>Unicode API</h3>
-<p>The path names are input/output in either ANSI/OEM code or Unicode depends on the configuration options. The type of arguments which specifies the path names is defined as <tt>TCHAR</tt>. It is an alias of <tt>char</tt> by default and the code set used for the path name string is ANSI/OEM specifid by <tt><a href="config.html#code_page">FF_CODE_PAGE</a></tt>. When <tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a></tt> is set to 1, the type of the <tt>TCHAR</tt> is switched to <tt>WCHAR</tt> to support UTF-16 encoded Unicode string. When UTF-16 or UTF-8 is specified by this option, the full-featured LFN specification is supported and the Unicode specific characters, such as ✝☪✡☸☭, can also be used for the path name. It also affects data types and encoding of the string I/O functions. To define literal strings, <tt>_T(s)</tt> and <tt>_TEXT(s)</tt> macro are available to select either ANSI/OEM or Unicode automatically. The code shown below is an example to define the literal strings.</p>
+<p>The path names are input/output in either ANSI/OEM code or Unicode depends on the configuration options. The type of arguments which specifies the path names is defined as <tt>TCHAR</tt>. It is an alias of <tt>char</tt> by default and the code set used for the path name string is ANSI/OEM specifid by <tt><a href="config.html#code_page">FF_CODE_PAGE</a></tt>. When <tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a></tt> is set to 1 or larger, the type of the <tt>TCHAR</tt> is switched to proper type to support the Unicode string. When Unicode API is specified by this option, the full-featured LFN specification is supported and the Unicode specific characters, such as ✝☪✡☸☭ and any character not in BMP, can also be used for the path name. It also affects data types and encoding of the string I/O functions. To define literal strings, <tt>_T(s)</tt> and <tt>_TEXT(s)</tt> macro are available to specify the string in proper type. The code shown below is an example to define the literal strings.</p>
<pre>
- f_open(fp, "filename.txt", FA_READ); <span class="c">/* ANSI/OEM string (char) */</span>
- f_open(fp, L"filename.txt", FA_READ); <span class="c">/* UTF-16 string (WCHAR) */</span>
- f_open(fp, u8"filename.txt", FA_READ); <span class="c">/* UTF-8 string (char) */</span>
- f_open(fp, U"filename.txt", FA_READ); <span class="c">/* UTF-32 string (DWORD) */</span>
- f_open(fp, _T("filename.txt"), FA_READ); <span class="c">/* Changed by configuration (TCHAR) */</span>
+ f_open(fp, <span class="e">"filename.txt"</span>, FA_READ); <span class="c">/* ANSI/OEM string (char) */</span>
+ f_open(fp, <span class="e">L"filename.txt"</span>, FA_READ); <span class="c">/* UTF-16 string (WCHAR) */</span>
+ f_open(fp, <span class="e">u8"filename.txt"</span>, FA_READ); <span class="c">/* UTF-8 string (char) */</span>
+ f_open(fp, <span class="e">U"filename.txt"</span>, FA_READ); <span class="c">/* UTF-32 string (DWORD) */</span>
+ f_open(fp, <span class="e">_T("filename.txt")</span>, FA_READ); <span class="c">/* Changed by configuration (TCHAR) */</span>
</pre>
</div>
<div class="para doc" id="vol">
<h3>Volume Management</h3>
-<p>FatFs module requires dynamic work area, <em>filesystem object</em>, for each volume (logical drive). It is registered/unregistered to the FatFs module by <tt>f_mount</tt> function. By default, each logical drive is bound to the physical drive with the same drive number and an FAT volume on the drive is serched by the volume mount process. It reads boot sectors and checks it if it is an FAT boot sector in order of sector 0 as SFD format, 1st partition, 2nd partition, 3rd partition and 4th partition as FDISK format.</p>
-<p>When <tt><a href="config.html#multi_partition">FF_MULTI_PARTITION = 1</a></tt> is specified by configuration option, each individual logical drive is bound to the partition on the physical drive specified by volume management table. The volume management table needs to be defined by user to resolve the mappings of logical drives and partitions. Following code is an example of a volume management table.</p>
+<p>By default, each logical drive is associated with the physical drive in same drive number. An FAT volume on the physical drive is serched in the volume mount process. It reads boot sectors and checks it if it is an FAT VBR in order of LBA 0 as SFD format, 1st partition, 2nd partition, 3rd partition, ..., as MBR or GPT format.</p>
+<p>When multiple partition feature is enabled, <tt><a href="config.html#multi_partition">FF_MULTI_PARTITION = 1</a></tt>, each individual logical drive is associated with arbitrary partition or physical drive specified by volume management table, <tt>VolToPart[]</tt>. The table needs to be defined by user to resolve mappings of the logical drive numbers and the associated partitions or drives. Following code is an example of the volume management table.</p>
<pre>
-Example: "0:", "1:" and "2:" are tied to three pri-partitions on the physical drive 0 (fixed drive)
- "3:" is tied to an FAT volume on the physical drive 1 (removable drive)
+Example: "0:", "1:" and "2:" are associated with three partitions on the physical drive 0 (a non-removable drive)
+ "3:" is associated with physical drive 1 (a removable drive)
PARTITION VolToPart[FF_VOLUMES] = {
- {0, 1}, <span class="c">/* "0:" ==> Physical drive 0, 1st partition */</span>
- {0, 2}, <span class="c">/* "1:" ==> Physical drive 0, 2nd partition */</span>
- {0, 3}, <span class="c">/* "2:" ==> Physical drive 0, 3rd partition */</span>
- {1, 0} <span class="c">/* "3:" ==> Physical drive 1, auto detection */</span>
+ {0, 1}, <span class="c">/* "0:" ==> 1st partition on the pd#0 */</span>
+ {0, 2}, <span class="c">/* "1:" ==> 2nd partition on the pd#0 */</span>
+ {0, 3}, <span class="c">/* "2:" ==> 3rd partition on the pd#0 */</span>
+ {1, 0} <span class="c">/* "3:" ==> pd#1 as removable drive (auto-search) */</span>
};
+
+
+<img src="../res/f7.png" width="900" height="288" alt="relationship between logical drive and physical drive">
</pre>
-<div><img src="../res/f7.png" width="900" height="288" alt="relationship between logical drive and physical drive"></div>
-<p>There are some considerations on using multi-partition configuration.</p>
+<p>There are some considerations when enable the multi-partition configuration.</p>
<ul>
-<li>The physical drive that has two or more mounted partitions must be non-removable. Media change while a system operation is prohibited.</li>
-<li>Only four primary partitions can be specified. Extended partition is not supported.</li>
-<li>Windows does not support multiple volumes on the removable storage. Only first parition will be recognized.</li>
+<li>The physical drive that hosts two or more mounted partitions should be non-removable, or all volumes on the drive must be unmounted when remove the medium.</li>
+<li>When make any change to the <tt>VolToPart[]</tt>, corresponding volume should be unmounted prior to make change the item.</li>
+<li>On the MBR format drive, up to four primary partitions (1-4) can be specified. The partition number 1 specifies the first item in the partition table and the partition number 2 specifies the second one, and so on. The logical patitions (5-) in the extended partition is not supported.</li>
+<li>On the GPT format drive, the partition number 1 specifies the first Microsoft BDP found in the partition table and the partition number 2 specifies the second one found, and so on.</li>
+<li>Windows 10 earlier than 1703 does not support multiple volumes on the physical drive with removable class. Only the first parition found on the drive will be mounted. Windows OS does not support SFD format on the physical drive with non-removable class.</li>
+<li>Some systems manage the on-board storage in non-standard partition format and each partition is mapped as physical drive in <tt>disk_*</tt> functions. For such system, <tt>FF_MULTI_PARTITION</tt> should be always 0.</li>
+<li>For further information about the volume management, refer to the description in <tt><a href="fdisk.html">f_fdisk</a></tt> and <tt><a href="mkfs.html">f_mkfs</a></tt>.</li>
</ul>
</div>
diff --git a/fatfs/documents/doc/findfirst.html b/fatfs/documents/doc/findfirst.html index daa6de6..5f1e344 100644 --- a/fatfs/documents/doc/findfirst.html +++ b/fatfs/documents/doc/findfirst.html @@ -61,12 +61,19 @@ FRESULT f_findfirst ( <div class="para desc">
<h4>Description</h4>
-<p>After the directory specified by <tt class="arg">path</tt> could be opened, it starts to search the directory for items with the name specified by <tt class="arg">pattern</tt>. If the first item is found, the information about the object is stored into the file information structure <tt class="arg">fno</tt>.</p>
-<p>The matching pattern can contain wildcard characters (<tt>?</tt> and <tt>*</tt>). A <tt>?</tt> matches an any character and an <tt>*</tt> matches an any string in length of zero or longer. When support of long file name is enabled, only <tt>fname[]</tt> is tested at <tt>FF_USE_FIND == 1</tt> and also <tt>altname[]</tt> is tested at <tt>FF_USE_FIND == 2</tt>. In this revision, there are some differences listed below between FatFs and standard systems in matching condition.</p>
+<p>After the directory specified by <tt class="arg">path</tt> could be opened, it starts to search the directory for items with the matching pattern specified by <tt class="arg">pattern</tt>. If the first item is found, the information about the item is stored into the file information structure <tt class="arg">fno</tt>. If not found, <tt>fno->fname[]</tt> has a null string.</p>
+<p>The matching pattern string can contain wildcards. For example:</p>
<ul>
-<li><tt>"*.*"</tt> never matches any name without extension while it matches any name with or without extension at the standard systems.</li>
-<li>Any pattern terminated with a period never matches any name while it matches any name without extensiton at the standard systems.</li>
-<li><a href="filename.html#case">DBCS extended characters</a> are compared in case-sensitive at LFN with ANSI/OEM API.</li>
+<li><tt>?</tt> - An any character.</li>
+<li><tt>???</tt> - An any string in length of three characters.</li>
+<li><tt>*</tt> - An any string in length of zero or longer.</li>
+<li><tt>????*</tt> - An any string in length of four characters or longer.</li>
+</ul>
+<p>Since the matching algorithm uses recursion, number of wildcards in the matching pattern is limited to four to limit the stack usage. Any pattern with too many wildcards does not match any name. In LFN configuration, only <tt>fname[]</tt> is tested when <tt>FF_USE_FIND == 1</tt> and also <tt>altname[]</tt> is tested when <tt>FF_USE_FIND == 2</tt>. There are some differences listed below between FatFs and standard systems in matching condition.</p>
+<ul>
+<li><tt>"*.*"</tt> does not match any name without extension while it matches any name with or without extension in standard systems.</li>
+<li>Any pattern terminated with a dot does not match any name while it matches the name without extensiton in standard systems.</li>
+<li><a href="filename.html#case">DBCS extended characters</a> are compared in case-sensitive when LFN is enabled with <tt>!FF_LFN_UNICODE</tt>.</li>
</ul>
</div>
@@ -85,13 +92,13 @@ FRESULT f_findfirst ( void find_image_file (void)
{
FRESULT fr; <span class="c">/* Return value */</span>
- DIR dj; <span class="c">/* Directory search object */</span>
+ DIR dj; <span class="c">/* Directory object */</span>
FILINFO fno; <span class="c">/* File information */</span>
- fr = <em>f_findfirst</em>(&dj, &fno, "", "dsc*.jpg"); <span class="c">/* Start to search for photo files */</span>
+ fr = <em>f_findfirst</em>(&dj, &fno, "", "????????.JPG"); <span class="c">/* Start to search for photo files */</span>
while (fr == FR_OK && fno.fname[0]) { <span class="c">/* Repeat while an item is found */</span>
- printf("%s\n", fno.fname); <span class="c">/* Display the object name */</span>
+ printf("%s\n", fno.fname); <span class="c">/* Print the object name */</span>
fr = f_findnext(&dj, &fno); <span class="c">/* Search for next item */</span>
}
diff --git a/fatfs/documents/doc/forward.html b/fatfs/documents/doc/forward.html index ada0a05..fdb5f49 100644 --- a/fatfs/documents/doc/forward.html +++ b/fatfs/documents/doc/forward.html @@ -54,7 +54,7 @@ FRESULT f_forward ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_forward</tt> function reads the data from the file and forward it to the outgoing stream without data buffer. This is suitable for small memory system because it does not require any data buffer at application module. The file pointer of the file object increases in number of bytes forwarded. In case of <tt class="arg">*bf</tt> is less than <tt class="arg">btf</tt> without error, it means the requested bytes could not be transferred due to end of file or stream goes busy during data transfer.</p>
+<p>The <tt>f_forward</tt> function reads the data from the file and forward it to the outgoing stream. This function is suitable for small memory system, because it does not require any data buffer in the application module. The file pointer of the file object advances in number of bytes forwarded. In case of <tt class="arg">*bf</tt> is less than <tt class="arg">btf</tt> without error, it means the requested size of data could not be transferred due to end of file or stream goes busy during data transfer.</p>
</div>
@@ -65,7 +65,7 @@ FRESULT f_forward ( <div class="para use">
-<h4>Example (Audio playback)</h4>
+<h4>Example</h4>
<pre>
<span class="c">/*------------------------------------------------------------------------*/</span>
<span class="c">/* Sample code of data transfer function to be called back from f_forward */</span>
diff --git a/fatfs/documents/doc/getcwd.html b/fatfs/documents/doc/getcwd.html index d5eab61..6eb9a58 100644 --- a/fatfs/documents/doc/getcwd.html +++ b/fatfs/documents/doc/getcwd.html @@ -50,7 +50,7 @@ FRESULT f_getcwd ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_getcwd</tt> function retrieves full path name of the current directory of the current drive. When <tt><a href="config.html#volumes">FF_VOLUMES</a> >= 2</tt>, a heading drive prefix is added to the path name. The style of drive prefix is depends on <tt><a href="config.html#str_volume_id">FF_STR_VOLUME_ID</a></tt>.</p>
+<p>The <tt>f_getcwd</tt> function retrieves full path name of the current directory of the current drive. When <tt><a href="config.html#volumes">FF_VOLUMES</a> >= 2</tt>, a heading drive prefix is added to the path name. The style of drive prefix depends on <tt><a href="config.html#str_volume_id">FF_STR_VOLUME_ID</a></tt>.</p>
<p><em>Note: In this revision, this function cannot retrieve the current directory path on the exFAT volume. It always returns the root directory path.</em></p>
</div>
diff --git a/fatfs/documents/doc/getfree.html b/fatfs/documents/doc/getfree.html index cdc730b..5e4f419 100644 --- a/fatfs/documents/doc/getfree.html +++ b/fatfs/documents/doc/getfree.html @@ -53,7 +53,7 @@ FRESULT f_getfree ( <div class="para desc">
<h4>Descriptions</h4>
-<p>The <tt>f_getfree</tt> function gets number of free clusters on the volume. The member <tt>csize</tt> in the filesystem object indicates number of sectors per cluster, so that the free space in unit of sector can be calcurated with this information. When FSINFO structure on the FAT32 volume is not in sync, this function can return an incorrect free cluster count. To avoid this problem, FatFs can be forced full FAT scan by <tt><a href="config.html#fs_nofsinfo">FF_FS_NOFSINFO</a></tt> option.</p>
+<p>The <tt>f_getfree</tt> function gets number of free clusters on the volume. The member <tt>csize</tt> in the filesystem object indicates number of sectors per cluster, so that the free space in unit of sector can be calcurated with this information. In case of FSINFO structure on the FAT32 volume is not in sync, this function can return an incorrect free cluster count. To avoid this problem, FatFs can be forced full FAT scan by <tt><a href="config.html#fs_nofsinfo">FF_FS_NOFSINFO</a></tt> option.</p>
</div>
diff --git a/fatfs/documents/doc/getlabel.html b/fatfs/documents/doc/getlabel.html index dfe067d..0ec6d0d 100644 --- a/fatfs/documents/doc/getlabel.html +++ b/fatfs/documents/doc/getlabel.html @@ -34,7 +34,7 @@ FRESULT f_getlabel ( <tr><td>Configuration</td><td>FF_FS_EXFAT == 0</td><td>FF_FS_EXFAT == 1</td></tr>
<tr><td>FF_USE_LFN == 0</td><td>12 items</td><td>-</td></tr>
<tr><td>FF_LFN_UNICODE == 0</td><td>12 items</td><td>23 items</td></tr>
-<tr><td>FF_LFN_UNICODE == 1/3</td><td>12 items</td><td>12 items</td></tr>
+<tr><td>FF_LFN_UNICODE == 1,3</td><td>12 items</td><td>12 items</td></tr>
<tr><td>FF_LFN_UNICODE == 2</td><td>34 items</td><td>34 items</td></tr>
</table>
</dd>
diff --git a/fatfs/documents/doc/gets.html b/fatfs/documents/doc/gets.html index 8ab46f4..89d9560 100644 --- a/fatfs/documents/doc/gets.html +++ b/fatfs/documents/doc/gets.html @@ -45,7 +45,7 @@ TCHAR* f_gets ( <div class="para desc">
<h4>Description</h4>
<p>The read operation continues until a <tt>'\n'</tt> is stored, reached end of the file or the buffer is filled with <tt>len - 1</tt> characters. The read string is terminated with a <tt>'\0'</tt>. When no character to read or any error occured during read operation, it returns a null pointer. The status of EOF and error can be examined with <tt>f_eof</tt> and <tt>f_error</tt> function.</p>
-<p>When FatFs is configured to Unicode API (<tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a> >= 1</tt>), data types on the srting fuctions, <tt>f_putc</tt>, <tt>f_puts</tt>, <tt>f_printf</tt> and <tt>f_gets</tt>, is also switched to Unicode. The character encoding <em>on the file</em> to be read via this function is assumed as <a href="config.html#strf_encode"><tt>FF_STRF_ENCODE</tt></a>. If the character encoding on the file differs from that on the API, it is converted in this function. In this case, input characters with wrong encoding will be lost.<p>
+<p>When FatFs is configured to Unicode API (<tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a> >= 1</tt>), data types on the srting fuctions, <tt>f_putc</tt>, <tt>f_puts</tt>, <tt>f_printf</tt> and <tt>f_gets</tt>, is also switched to Unicode. The character encoding <em>on the file</em> to be read via this function is assumed as <a href="config.html#strf_encode"><tt>FF_STRF_ENCODE</tt></a>. If the character encoding on the file differs from that on the API, it is converted in this function. In this case, input characters with wrong encoding will be lost.</p>
</div>
diff --git a/fatfs/documents/doc/lseek.html b/fatfs/documents/doc/lseek.html index 7173b0e..ffd1f62 100644 --- a/fatfs/documents/doc/lseek.html +++ b/fatfs/documents/doc/lseek.html @@ -18,7 +18,12 @@ <pre>
FRESULT f_lseek (
FIL* <span class="arg">fp</span>, <span class="c">/* [IN] File object */</span>
- FSIZE_t <span class="arg">ofs</span> <span class="c">/* [IN] File read/write pointer */</span>
+ FSIZE_t <span class="arg">ofs</span> <span class="c">/* [IN] Offset of file read/write pointer to be set */</span>
+);
+</pre>
+<pre>
+FRESULT f_rewind (
+ FIL* <span class="arg">fp</span> <span class="c">/* [IN] File object */</span>
);
</pre>
</div>
@@ -48,14 +53,17 @@ FRESULT f_lseek ( <div class="para desc">
<h4>Description</h4>
-<p>File read/write ponter in the open file object points the data byte to be read/written at next read/write operation. It advances as the number of bytes read/written. The <tt>f_lseek</tt> function moves the file read/write pointer without any read/write operation to the file.</p>
-<p>When an offset beyond the file size is specified at write mode, the file size is expanded to the specified offset. The file data in the expanded area is <em>undefined</em> because no data is written to the file in this process. This is suitable to pre-allocate a data area to the file quickly for fast write operation. When a contiguous data area needs to be allocated to the file, use <tt>f_expand</tt> function instead. After the <tt>f_lseek</tt> function succeeded, the current read/write pointer should be checked in order to make sure the read/write pointer has been moved correctry. In case of the read/write pointer is not the expected value, either of followings has been occured.</p>
+<p>File read/write ponter in the open file object points the data byte to be read/written at next read/write operation. It advances as the number of bytes read/written. The <tt>f_lseek</tt> function moves the file read/write pointer without any read/write operation to the file. The <tt>f_rewind</tt> function is impremented as a macro.</p>
+<pre>
+#define <em>f_rewind</em>(fp) f_lseek((fp), 0)
+</pre>
+<p>If an offset beyond the file size is specified in write mode, the file size is expanded to the specified offset. The file data in the expanded part is <em>undefined</em>, because no data is written to the file in this process. This is suitable to pre-allocate a data area to the file quickly for fast write operation. When a contiguous data area needs to be allocated to the file, use <tt>f_expand</tt> function instead. After the <tt>f_lseek</tt> function succeeded, the current read/write pointer should be checked in order to make sure the read/write pointer has been moved correctry. In case of the read/write pointer is not pointing expected offset, either of followings has been occured.</p>
<ul>
-<li>End of file. The specified <tt class="arg">ofs</tt> was clipped at end of the file because the file has been opened in read-only mode.</li>
+<li>End of file. The specified <tt class="arg">ofs</tt> was clipped at end of the file in read-only mode.</li>
<li>Disk full. There is no free space on the volume to expand the file.</li>
</ul>
-<p>The fast seek function enables fast backward/long seek operations without FAT access by using an on-memory CLMT (cluster link map table). It is applied to <tt>f_read</tt> and <tt>f_write</tt> function as well, however, the file size cannot be expanded by <tt>f_write</tt>, <tt>f_lseek</tt> function while the file is at fast seek mode.</p>
-<p>The fast seek mode is enabled when the member <tt>cltbl</tt> in the file object is not NULL. The CLMT must be created into the <tt>DWORD</tt> array prior to use the fast seek function. To create the CLMT, set address of the <tt>DWORD</tt> array to the member <tt>cltbl</tt> in the open file object, set the size of array in unit of items to the first item and call the <tt>f_lseek</tt> function with <tt class="arg">ofs</tt><tt> = CREATE_LINKMAP</tt>. After the function succeeded and CLMT is created, no FAT access is occured in subsequent <tt>f_read</tt>, <tt>f_write</tt>, <tt>f_lseek</tt> function to the file. The number of items used or required is returned into the first item of the array. The number of items to be used is (number of the file fragments + 1) * 2. For example, when the file is fragmented in 5, 12 items in the array will be used. If the function failed with <tt>FR_NOT_ENOUGH_CORE</tt>, the given array size is insufficient for the file.</p>
+<p>The fast seek feature enables fast backward/long seek operations without FAT access by using an on-memory CLMT (cluster link map table). It is applied to <tt>f_read</tt> and <tt>f_write</tt> function as well, however, the file size cannot be expanded by <tt>f_write</tt>, <tt>f_lseek</tt> function while the file is at fast seek mode.</p>
+<p>The fast seek mode is available when <tt>FF_USE_FASTSEEK = 1</tt>. The CLMT must be created into the <tt>DWORD</tt> array prior to use the fast seek mode. To create the CLMT, set address of the <tt>DWORD</tt> array to the member <tt>cltbl</tt> in the open file object, set the size of array in unit of items to the <tt>cltbl[0]</tt> and then call <tt>f_lseek</tt> function with <tt class="arg">ofs</tt><tt> = CREATE_LINKMAP</tt>. After the function succeeded, no FAT access is occured in subsequent <tt>f_read</tt>, <tt>f_write</tt>, <tt>f_lseek</tt> function to the file. The number of items used or required is returned into the <tt>cltbl[0]</tt>. The number of items needed is (number of the file fragments + 1) * 2. For example, 12 items in the array will be used for the file fragmented in 5 portions. If the function failed with <tt>FR_NOT_ENOUGH_CORE</tt>, the size of given array is insufficient for the file.</p>
</div>
@@ -73,16 +81,16 @@ FRESULT f_lseek ( res = f_open(fp, "file.dat", FA_READ|FA_WRITE);
if (res) ...
- <span class="c">/* Move to offset of 5000 from top of the file */</span>
+ <span class="c">/* Set read/write pointer to 5000 */</span>
res = <em>f_lseek</em>(fp, 5000);
- <span class="c">/* Move to end of the file to append data */</span>
+ <span class="c">/* Set read/write pointer to end of the file to append data */</span>
res = <em>f_lseek</em>(fp, f_size(fp));
- <span class="c">/* Forward 3000 bytes */</span>
+ <span class="c">/* Advance read/write pointer 3000 bytes */</span>
res = <em>f_lseek</em>(fp, f_tell(fp) + 3000);
- <span class="c">/* Rewind 2000 bytes (take care on wraparound) */</span>
+ <span class="c">/* Rewind read/write pointer 2000 bytes (take care on wraparound) */</span>
res = <em>f_lseek</em>(fp, f_tell(fp) - 2000);
</pre>
<pre>
@@ -93,17 +101,17 @@ FRESULT f_lseek ( res = <em>f_lseek</em>(fp, PRE_SIZE); <span class="c">/* Expand file size (cluster pre-allocation) */</span>
if (res || f_tell(fp) != PRE_SIZE) ... <span class="c">/* Check if the file has been expanded successfly */</span>
- res = <em>f_lseek</em>(fp, DATA_START); <span class="c">/* Record data stream WITHOUT cluster allocation delay */</span>
+ res = <em>f_lseek</em>(fp, OFS_DATA); <span class="c">/* Record data stream with free from cluster allocation delay */</span>
... <span class="c">/* Write operation should be aligned to sector boundary to optimize the write throughput */</span>
res = f_truncate(fp); <span class="c">/* Truncate unused area */</span>
- res = <em>f_lseek</em>(fp, 0); <span class="c">/* Set file header */</span>
+ res = <em>f_lseek</em>(fp, OFS_HEADER); <span class="c">/* Set file header */</span>
...
res = f_close(fp);
</pre>
<pre>
-<span class="c">/* Using fast seek function */</span>
+<span class="c">/* Using fast seek mode */</span>
DWORD clmt[SZ_TBL]; <span class="c">/* Cluster link map table buffer */</span>
@@ -111,7 +119,7 @@ FRESULT f_lseek ( res = <em>f_lseek</em>(fp, ofs1); <span class="c">/* This is normal seek (cltbl is nulled on file open) */</span>
- fp->cltbl = clmt; <span class="c">/* Enable fast seek function (cltbl != NULL) */</span>
+ fp->cltbl = clmt; <span class="c">/* Enable fast seek mode (cltbl != NULL) */</span>
clmt[0] = SZ_TBL; <span class="c">/* Set table size */</span>
res = <em>f_lseek</em>(fp, CREATE_LINKMAP); <span class="c">/* Create CLMT */</span>
...
diff --git a/fatfs/documents/doc/mkfs.html b/fatfs/documents/doc/mkfs.html index 8e2bd1c..f40ebb0 100644 --- a/fatfs/documents/doc/mkfs.html +++ b/fatfs/documents/doc/mkfs.html @@ -13,14 +13,13 @@ <div class="para func">
<h2>f_mkfs</h2>
-<p>The f_mkfs fucntion creates an FAT/exFAT volume on the logical drive.</p>
+<p>The f_mkfs function creates an FAT/exFAT volume on the logical drive.</p>
<pre>
FRESULT f_mkfs (
- const TCHAR* <span class="arg">path</span>, <span class="c">/* [IN] Logical drive number */</span>
- BYTE <span class="arg">opt</span>, <span class="c">/* [IN] Format options */</span>
- DWORD <span class="arg">au</span>, <span class="c">/* [IN] Size of the allocation unit */</span>
- void* <span class="arg">work</span>, <span class="c">/* [-] Working buffer */</span>
- UINT <span class="arg">len</span> <span class="c">/* [IN] Size of working buffer */</span>
+ const TCHAR* <span class="arg">path</span>, <span class="c">/* [IN] Logical drive number */</span>
+ const MKFS_PARM* <span class="arg">opt</span>,<span class="c">/* [IN] Format options */</span>
+ void* <span class="arg">work</span>, <span class="c">/* [-] Working buffer */</span>
+ UINT <span class="arg">len</span> <span class="c">/* [IN] Size of working buffer */</span>
);
</pre>
</div>
@@ -29,15 +28,25 @@ FRESULT f_mkfs ( <h4>Parameters</h4>
<dl class="par">
<dt>path</dt>
-<dd>Pointer to the null-terminated string specifies the <a href="filename.html">logical drive</a> to be formatted. If it has no drive number in it, it means the default drive. The logical drive may or may not be mounted for the format process.</dd>
+<dd>Pointer to the null-terminated string specifies the <a href="filename.html">logical drive</a> to be formatted. If it does not have a drive number in it, it means to specify the default drive. The logical drive may or may not have been mounted for the format process.</dd>
<dt>opt</dt>
-<dd>Specifies the format option in combination of <tt>FM_FAT</tt>, <tt>FM_FAT32</tt>, <tt>FM_EXFAT</tt> and bitwise-or of these three, <tt>FM_ANY</tt>. <tt>FM_EXFAT</tt> is ignored when exFAT is not enabled. These flags specify which FAT type to be created on the volume. If two or more types are specified, one out of them will be selected depends on the volume size and <tt class="arg">au</tt>. The flag <tt>FM_SFD</tt> specifies to create the volume on the drive in SFD format.</dd>
-<dt>au</dt>
-<dd>Specifies size of the allocation unit (cluter) in unit of byte. The valid value is <em>n</em> times the sector size. The <em>n</em> is power of 2 from 1 to 128 for FAT volume and upto 16MiB for exFAT volume. If zero is given, the default allocation unit size is selected depends on the volume size.</dd>
+<dd>Specifies the format option structure <tt>MKFS_PARM</tt> holding format options. If a null pointer is given, it gives the function every option in default value. The structure has five members in order of described below:<br>
+<dl class="par">
+<dt>BYTE fmt</dt>
+<dd>Specifies a combination of FAT type flags, <tt>FM_FAT</tt>, <tt>FM_FAT32</tt>, <tt>FM_EXFAT</tt> and bitwise-or of these three, <tt>FM_ANY</tt>. <tt>FM_EXFAT</tt> is ignored when exFAT is not enabled. These flags specify which type of FAT volume to be created. If two or more types are specified, one out of them will be selected depends on the volume size and <tt class="arg">au_size</tt>. The flag <tt>FM_SFD</tt> specifies to create the volume on the drive in SFD format. The default value is <tt>FM_ANY</tt>.</dd>
+<dt>BYTE n_fat</dt>
+<dd>Specifies number of FAT copies on the FAT/FAT32 volume. Valid value for this member is 1 or 2. The default value (0) and any invaid value gives 1. If the FAT type is exFAT, this member has no effect.</dd>
+<dt>UINT n_align</dt>
+<dd>Specifies alignment of the volume data area (file allocation pool, usually erase block boundary of flash memory media) in unit of sector. The valid value for this member is between 1 and 32768 inclusive in power of 2. If a zero (the default value) or any invalid value is given, the function obtains the block size from lower layer with <tt>disk_ioctl</tt> function.</dd>
+<dt>DWORD au_size</dt>
+<dd>Specifies size of the allocation unit (cluter) in unit of byte. The valid value is power of 2 between sector size and 128 * sector size inclusive for FAT/FAT32 volume, or up to 16 MB for exFAT volume. If a zero (default value) or any invalid value is given, the function uses default allocation unit size depends on the volume size.</dd>
+<dt>UINT n_root</dt>
+<dd>Specifies number of root directory entries on the FAT volume. Valid value for this member is up to 32768 and aligned to sector size / 32. The default value (0) and any invaid value gives 512. If the FAT type is FAT32 or exFAT, this member has no effect.</dd>
+</dl>
<dt>work</dt>
-<dd>Pointer to the working buffer used for the format process. When a null pointer is given, the function allocates a memory block for the working buffer and <tt class="arg">len</tt> has no effect (at only <tt><a href="config.html#use_lfn">FF_USE_LFN</a> == 3</tt>).</dd>
+<dd>Pointer to the working buffer used for the format process. If a null pointer is given with <tt><a href="config.html#use_lfn">FF_USE_LFN</a> == 3</tt>, the function uses a <tt>len</tt> bytes of heap memory in this function.</dd>
<dt>len</dt>
-<dd>Size of the working buffer in unit of byte. It needs to be the sector size of the corresponding physical drive at least. Plenty of working buffer reduces number of write transactions to the drive and the format process will finish quickly.</dd>
+<dd>Size of the working buffer in unit of byte. It needs to be <tt>FF_MAX_SS</tt> at least. Plenty of working buffer reduces number of write transactions to the drive, thus the format process will finish quickly.</dd>
</dl>
</div>
@@ -57,11 +66,12 @@ FRESULT f_mkfs ( <div class="para desc">
<h4>Description</h4>
-<p>The FAT sub-type, FAT12/FAT16/FAT32, of FAT volume except exFAT is determined by only number of clusters on the volume and nothing else, according to the FAT specification issued by Microsoft. Thus the FAT sub-type of created volume depends on the volume size and the cluster size. In case of the combination of FAT type and cluter size specified by argument cannot be valid on the volume, the function will fail with <tt>FR_MKFS_ABORTED</tt>. The minimum drive size is 128 sectors with <tt>FM_SFD</tt> option.</p>
-<p>The allocation unit, also called <em>cluster</em>, is a unit of disk space allocation for files. When the size of allocation unit is 32768 bytes, a file with 100 bytes in size occupies 32768 bytes of disk space. The space efficiency of disk usage gets worse as increasing size of allocation unit, but, on the other hand, the read/write performance increases as the size of allocation unit. Therefore the size of allocation unit is a trade-off between space efficiency and performance. For the large storages in GB order, 32768 bytes or larger (this is automatically selected by default) is recommended for most case unless extremely many small files are created on a volume.</p>
-<p>There are three disk partitioning formats, FDISK, SFD and GPT. The FDISK format is usually used for harddisk, memory card and U disk. It can divide a physical drive into one or more partitions with a partition table on the MBR (maser boot record, the first sector of the physical drive). The SFD (super-floppy disk) is non-partitioned disk format. The FAT volume starts at the first sector of the physical drive without any disk partitioning. It is usually used for floppy disk, optical disk and most super-floppy media. Some systems support only either one of the two disk formats and the other is not supported. The GPT (GUID Partition Table) is a newly defined format for large storage devices. FatFs does not support the storages with GPT.</p>
-<p>When the logical drive to be formatted is bound to a physical drive and <tt>FM_SFD</tt> is not specified, a primary partition occupies whole drive space is created in FDISK format, and then the FAT volume is created in the partition. When <tt>FM_SFD</tt> is specified, the FAT volume occupies from the first sector of the physical drive is created in SFD format.</p>
-<p>When the logical drive to be formatted is bound to a specific partition (1-4) by support of multiple partition (<tt><a href="config.html#multi_partition">FF_MULTI_PARTITION</a> == 1</tt>), the FAT volume is created on the partition and <tt>FM_SFD</tt> flag is ignored. The physical drive needs to be partitioned with <tt>f_fdisk</tt> function or any other partitioning tools prior to create the FAT volume with this function.</p>
+<p>The FAT sub-type, FAT12/FAT16/FAT32, of FAT volume except exFAT is determined by only number of clusters on the volume and nothing else, according to the FAT specification issued by Microsoft. Thus the FAT sub-type of created volume depends on the volume size and the cluster size. In case of the combination of FAT type and cluter size specified by argument is not valid for the volume size, the function will fail with <tt>FR_MKFS_ABORTED</tt>.</p>
+<p>The allocation unit, also known as <em>cluster</em>, is a unit of disk space allocation for files. When the size of allocation unit is 32768 bytes, a file with 100 bytes in size occupies 32768 bytes of disk space. The space efficiency of disk usage gets worse as increasing size of allocation unit, but, on the other hand, the read/write performance increases. Therefore the size of allocation unit is a trade-off between space efficiency and performance. For the large volumes in GB order, 32768 bytes or larger, automatically selected by default, is recommended for most case unless extremely many small files are created in the volume.</p>
+<p>When the logical drive to be formatted is associated with a physical drive (<tt><a href="config.html#multi_partition">FF_MULTI_PARTITION</a> == 0</tt> or <tt>VolToPart[].pt == 0</tt>) and <tt>FM_SFD</tt> flag is not specified, a partition occupies entire drive space is created and then the FAT volume is created in the partition. When <tt>FM_SFD</tt> flag is specified, the FAT volume is created without any disk partitioning.</p>
+<p>When the logical drive to be formatted is associated with a specific partition by multiple partition feature (<tt>FF_MULTI_PARTITION == 1</tt> and <tt>VolToPart[].pt > 0</tt>), the FAT volume is created in the partition of the physical drive specified by <a href="filename.html#vol">volume mapping table</a> and <tt>FM_SFD</tt> flag is ignored. The hosting physical drive needs to be partitioned with <tt>f_fdisk</tt> function or any partitioning tool prior to create the FAT volume with this function. If the partition is not exist, the function aborts with <tt>FR_MKFS_ABORTED</tt>.</p>
+<p>There are three standard disk partitioning formats, MBR, GPT and SFD. The MBR format, also known as FDISK format, is usually used for harddisk, memory card and U disk. It can divide a physical drive into one or more partitions with a partition table. The GPT, GUID Partition Table, is a newly defined patitioning format for large storage devices. FatFs suppors the GPT only when 64-bit LBA is enabled. The SFD, Super-Floppy Disk, is non-partitioned disk format. The FAT volume is located at LBA 0 and occupies the entire physical drive without any disk partitioning. It is usually used for floppy disk, optical disk and most super-floppy media. Some combination of systems and media support only either partitioned format or non-partitioned format and the other is not supported.</p>
+<p>Some systems manage the partitions in the on-board storage in non-standard format. The partitions are mapped as physical drives identified by <tt class="arg">pdrv</tt> in <tt>disk_*</tt> functions. For such systems, SFD format is suitable to create the FAT volume in the partition.</p>
</div>
<div class="para comp">
@@ -82,11 +92,11 @@ int main (void) BYTE work[FF_MAX_SS]; <span class="c">/* Work area (larger is better for processing time) */</span>
- <span class="c">/* Create FAT volume */</span>
- res = <em>f_mkfs</em>("", FM_ANY, 0, work, sizeof work);
+ <span class="c">/* Format the default drive with default parameters */</span>
+ res = <em>f_mkfs</em>("", 0, work, sizeof work);
if (res) ...
- <span class="c">/* Register work area */</span>
+ <span class="c">/* Give a work area to the default drive */</span>
f_mount(&fs, "", 0);
<span class="c">/* Create a file as new */</span>
@@ -109,7 +119,7 @@ int main (void) <div class="para ref">
<h4>See Also</h4>
-<p><a href="../res/mkfs.xls">Example of volume size and format parameters</a>, <a href="filename.html#vol">Volume management</a>, <tt><a href="fdisk.html">f_fdisk</a></tt></p>
+<p><a href="../res/mkfs.xlsx">Example of volume size and format parameters</a>, <a href="filename.html#vol">Volume management</a>, <tt><a href="fdisk.html">f_fdisk</a></tt></p>
</div>
<p class="foot"><a href="../00index_e.html">Return</a></p>
diff --git a/fatfs/documents/doc/mount.html b/fatfs/documents/doc/mount.html index 901ffc0..57f40be 100644 --- a/fatfs/documents/doc/mount.html +++ b/fatfs/documents/doc/mount.html @@ -13,7 +13,7 @@ <div class="para func">
<h2>f_mount</h2>
-<p>The f_mount fucntion registers/unregisters filesystem object to the FatFs module.</p>
+<p>The f_mount fucntion gives work area to the FatFs module.</p>
<pre>
FRESULT f_mount (
FATFS* <span class="arg">fs</span>, <span class="c">/* [IN] Filesystem object */</span>
@@ -21,6 +21,11 @@ FRESULT f_mount ( BYTE <span class="arg">opt</span> <span class="c">/* [IN] Initialization option */</span>
);
</pre>
+<pre>
+FRESULT f_unmount (
+ const TCHAR* <span class="arg">path</span> <span class="c">/* [IN] Logical drive number */</span>
+);
+</pre>
</div>
<div class="para arg">
@@ -50,7 +55,7 @@ FRESULT f_mount ( <div class="para desc">
<h4>Description</h4>
-<p>FatFs requires work area (<em>filesystem object</em>) for each logical drives (FAT volumes). Prior to perform file/directory operations, a filesystem object needs to be registered with <tt>f_mount</tt> function to the logical drive. The file/directory API functions get ready to work after this procedure. If there is any open object of file or directory on the logical drive, the object will be invalidated by this function.</p>
+<p>FatFs requires work area (<em>filesystem object</em>) for each logical drives (FAT volumes). Prior to perform any file/directory operations, a filesystem object needs to be registered with <tt>f_mount</tt> function for the logical drive. The file/directory API functions get ready to work after this procedure. Some volume management functions, <tt>f_mkfs</tt>, <tt>f_fdisk</tt> and <tt>f_setcp</tt>, do not want a filesystem object.</p>
<p>The <tt>f_mount</tt> function registers/unregisters a filesystem object to the FatFs module as follows:</p>
<ol>
<li>Determines the logical drive which specified by <tt class="arg">path</tt>.</li>
@@ -58,6 +63,7 @@ FRESULT f_mount ( <li>Clears and registers the new work area to the volume if <tt class="arg">fs</tt> is not NULL.</li>
<li>Performs volume mount process to the volume if forced mounting is specified.</li>
</ol>
+<p>If there is any open object of file or directory on the logical drive, the object will be invalidated by this function.</p>
<p>If forced mounting is not specified (<tt>opt = 0</tt>), this function always succeeds regardless of the physical drive status. It only clears (de-initializes) the given work area and registers its address to the internal table and no activity of the physical drive in this function. The volume mount process will be attempted on subsequent file/directroy function if the filesystem object is not initialized. (delayed mounting) The volume mount processes, initialize the corresponding physical drive, find the FAT volume in it and then initialize the work area, is performed in the subsequent file/directory functions when either of following conditions is true.</p>
<ul>
<li>Filesystem object has not been initialized. It is de-initialized by <tt>f_mount</tt> function.</li>
@@ -65,7 +71,10 @@ FRESULT f_mount ( </ul>
<p>If the function with forced mounting (<tt>opt = 1</tt>) failed with <tt>FR_NOT_READY</tt>, it means that the filesystem object has been registered successfully but the volume is currently not ready to work. The volume mount process will be attempted on subsequent file/directroy function.</p>
<p>If implementation of the disk I/O layer lacks asynchronous media change detection, application program needs to perform <tt>f_mount</tt> function after each media change to force cleared the filesystem object.</p>
-<p>To unregister the work area, specify a NULL to the <tt class="arg">fs</tt>, and then the work area can be discarded.</p>
+<p>To unregister the work area, specify a NULL to the <tt class="arg">fs</tt>, and then the work area can be discarded. <tt>f_unmount</tt> function is implemented as a macro.</p>
+<pre>
+#define <em>f_unmount</em>(path) f_mount(0, path, 0)
+</pre>
</div>
diff --git a/fatfs/documents/doc/open.html b/fatfs/documents/doc/open.html index c00c5e4..cc8b87a 100644 --- a/fatfs/documents/doc/open.html +++ b/fatfs/documents/doc/open.html @@ -34,15 +34,15 @@ FRESULT f_open ( <dd>Mode flags that specifies the type of access and open method for the file. It is specified by a combination of following flags.<br>
<table class="lst">
<tr><th>Flags</th><th>Meaning</th></tr>
-<tr><td>FA_READ</td><td>Specifies read access to the object. Data can be read from the file.</tr>
-<tr><td>FA_WRITE</td><td>Specifies write access to the object. Data can be written to the file. Combine with <tt>FA_READ</tt> for read-write access.</td></tr>
-<tr><td>FA_OPEN_EXISTING</td><td>Opens the file. The function fails if the file is not existing. (Default)</td></tr>
+<tr><td>FA_READ</td><td>Specifies read access to the file. Data can be read from the file.</tr>
+<tr><td>FA_WRITE</td><td>Specifies write access to the file. Data can be written to the file. Combine with <tt>FA_READ</tt> for read-write access.</td></tr>
+<tr><td>FA_OPEN_EXISTING</td><td>Opens a file. The function fails if the file is not existing. (Default)</td></tr>
<tr><td>FA_CREATE_NEW</td><td>Creates a new file. The function fails with <tt>FR_EXIST</tt> if the file is existing.</td></tr>
<tr><td>FA_CREATE_ALWAYS</td><td>Creates a new file. If the file is existing, it will be truncated and overwritten.</td></tr>
<tr><td>FA_OPEN_ALWAYS</td><td>Opens the file if it is existing. If not, a new file will be created.</td></tr>
<tr><td>FA_OPEN_APPEND</td><td>Same as <tt>FA_OPEN_ALWAYS</tt> except the read/write pointer is set end of the file.</td></tr>
</table>
-Mode flags of POSIX fopen() corresponds to FatFs mode flags as follows:<br>
+Mode flags in POSIX fopen() function corresponds to FatFs mode flags as follows:<br>
<table class="lst2">
<tr><th>POSIX</th><th>FatFs</th></tr>
<tr><td>"r"</td><td>FA_READ</td></tr>
@@ -86,7 +86,7 @@ Mode flags of POSIX fopen() corresponds to FatFs mode flags as follows:<br> <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_open</tt> function opens a file and creates a <em>file object</em>. The file object is used for subsequent read/write operations to the file to identify the file. Open file should be closed with <a href="close.html"><tt>f_close</tt></a> function after the session of the file access. If any change to the file is made and not closed prior to power down, media removal or re-mount, or the file can be collapsed.</p>
+<p>The <tt>f_open</tt> function opens a file and creates a <em>file object</em>. The file object is an identifier for subsequent operations to the file. Open file should be closed with <a href="close.html"><tt>f_close</tt></a> function after the session of the file access. If any change to the file has been made and not closed prior to power off, media removal or re-mount, or the file can be collapsed.</p>
<p>If duplicated file open is needed, read <a href="appnote.html#dup">here</a> carefully. However duplicated open of a file with any write mode flag is always prohibited.</p>
</div>
@@ -111,14 +111,14 @@ int main (void) FRESULT fr; <span class="c">/* FatFs return code */</span>
- <span class="c">/* Register work area to the default drive */</span>
+ <span class="c">/* Give a work area to the default drive */</span>
f_mount(&FatFs, "", 0);
<span class="c">/* Open a text file */</span>
fr = <em>f_open</em>(&fil, "message.txt", FA_READ);
if (fr) return (int)fr;
- <span class="c">/* Read all lines and display it */</span>
+ <span class="c">/* Read every line and display it */</span>
while (f_gets(line, sizeof line, &fil)) {
printf(line);
}
@@ -134,16 +134,16 @@ int main (void) int main (void)
{
- FATFS fs[2]; <span class="c">/* Work area (filesystem object) for logical drives */</span>
+ FATFS fs0, fs1; <span class="c">/* Work area (filesystem object) for logical drives */</span>
FIL fsrc, fdst; <span class="c">/* File objects */</span>
BYTE buffer[4096]; <span class="c">/* File copy buffer */</span>
FRESULT fr; <span class="c">/* FatFs function common result code */</span>
UINT br, bw; <span class="c">/* File read/write count */</span>
- <span class="c">/* Register work area for each logical drive */</span>
- f_mount(&fs[0], "0:", 0);
- f_mount(&fs[1], "1:", 0);
+ <span class="c">/* Give work areas to each logical drive */</span>
+ f_mount(&fs0, "0:", 0);
+ f_mount(&fs1, "1:", 0);
<span class="c">/* Open source file on the drive 1 */</span>
fr = <em>f_open</em>(&fsrc, "1:file.bin", FA_READ);
@@ -155,10 +155,10 @@ int main (void) <span class="c">/* Copy source to destination */</span>
for (;;) {
- fr = f_read(&fsrc, buffer, sizeof buffer, &br); <span class="c">/* Read a chunk of source file */</span>
- if (fr || br == 0) break; <span class="c">/* error or eof */</span>
- fr = f_write(&fdst, buffer, br, &bw); <span class="c">/* Write it to the destination file */</span>
- if (fr || bw < br) break; <span class="c">/* error or disk full */</span>
+ fr = f_read(&fsrc, buffer, sizeof buffer, &br); <span class="c">/* Read a chunk of data from the source file */</span>
+ if (br == 0) break; <span class="c">/* error or eof */</span>
+ fr = f_write(&fdst, buffer, br, &bw); <span class="c">/* Write it to the destination file */</span>
+ if (bw < br) break; <span class="c">/* error or disk full */</span>
}
<span class="c">/* Close open files */</span>
@@ -166,8 +166,8 @@ int main (void) f_close(&fdst);
<span class="c">/* Unregister work area prior to discard it */</span>
- f_mount(NULL, "0:", 0);
- f_mount(NULL, "1:", 0);
+ f_unmount("0:");
+ f_unmount("1:");
return (int)fr;
}
diff --git a/fatfs/documents/doc/printf.html b/fatfs/documents/doc/printf.html index 82be70c..eb64e8d 100644 --- a/fatfs/documents/doc/printf.html +++ b/fatfs/documents/doc/printf.html @@ -39,7 +39,7 @@ int f_printf ( <div class="para ret"> <h4>Return Values</h4> -<p>When the string was written successfuly, it returns number of character encoding units written to the file. When the function failed due to disk full or any error, an <tt>EOF (-1)</tt> will be returned.</p> +<p>When the string was written successfuly, it returns number of character encoding units written to the file. When the function failed due to disk full or an error, a negative value will be returned.</p> </div> @@ -47,14 +47,30 @@ int f_printf ( <h4>Description</h4> <p>The format control directive is a sub-set of standard library shown as follows:</p> <pre> - %[flag][width][type] + %[flag][width][precision][size]type </pre> <dl> -<dt>flag</dt><dd>Padding options. A <tt>-</tt> specifies left justified. A <tt>0</tt> specifies zero padded.</dd> -<dt>width</dt><dd>Minimum width of the field, <tt>1-99</tt> or <tt>*</tt>. If the width of generated string is less than the specified value, rest field is padded with white spaces or zeros. An <tt>*</tt> specifies the value comes from an argument in int type.</dd> -<dt>type</dt><dd><tt>c s d u o x b</tt> and prefix <tt>l</tt> specify type of the argument, character, string, signed integer in decimal, unsigned integer in decimal, unsigned integer in octal, unsigned integer in hexdecimal and unsigned integer in binary respectively. If <tt>sizeof (long)</tt> is greater than <tt>sizeof (int)</tt> (this is typical of 8/16-bit systems), a prefix <tt>l</tt> needs to be explicitly specified for long integer argument. These characters except for <tt>x</tt> are case insensitive.</dd> +<dt>flag</dt><dd>Padding option. A <tt>-</tt> specifies left-aligned. A <tt>0</tt> specifies zero padded. The default setting is in right-aligned and space padded.</dd> +<dt>width</dt><dd>Minimum width of the field, <tt>1-99</tt> or <tt>*</tt>. If the width of generated string is less than the minimum width, rest field is padded with spaces or zeros. An <tt>*</tt> specifies the value comes from an argument in int type. The default setting is zero.</dd> +<dt>precision</dt><dd>Specifies number of fractional digits or maximum width of string, <tt>.0-.99</tt> or <tt>.*</tt>. If the number is omitted, it is same as <tt>.0</tt>. Default setting is 6 for number and no limit for string.</dd> +<dt>size</dt><dd>Specifies size of integer argument, <tt>l</tt>(long) and <tt>ll</tt>(long long). If <tt>sizeof (long) == sizeof (int)</tt> is true (this is typical of 32-bit systems), prefix <tt>l</tt> can be omitted for long integer argument. The default size is int for integer argument and floating point argument is always assumed double as the default argument promotion.</dd> +<dt>type</dt><dd>Specifies type of the output format and the argument as shown below. The length of generated string is in assumtion of int is 32-bit. +<table class="lst1"> +<tr><th>Type</th><th>Format</th><th>Argument</th><th>Length</th></tr> +<tr><td><tt>c</tt></td><td>Character</td><td rowspan="6"><tt>int</tt>,<br><tt>long</tt>,<br><tt>long long</tt></td><td>1 character.</td></tr> +<tr><td><tt>d</tt></td><td>Signed decimal</td><td>1 to 11 (20 for ll) characters.</td></tr> +<tr><td><tt>u</tt></td><td>Unsigned decimal</td><td>1 to 10 (20 for ll) characters.</td></tr> +<tr><td><tt>o</tt></td><td>Unsigned octal</td><td>1 to 11 (22 for ll) characters.</td></tr> +<tr><td><tt>x X</tt></td><td>Unsigned hexdecimal</td><td>1 to 8 (16 for ll) characters.</td></tr> +<tr><td><tt>b</tt></td><td>Unsigned binary</td><td>1 to 32 characters. Limited to lower 32 digits when ll is specified.</td></tr> +<tr><td><tt>s</tt></td><td>String</td><td><tt>TCHAR*</tt></td><td>As input string. Null pointer generates a null string.</td></tr> +<tr><td><tt>f</tt></td><td>Floating point<br>(decimal)</td><td rowspan="2"><tt>double</tt></td><td>1 to 31 characters. If the number of characters exceeds 31, it writes <tt>"±OV"</tt>. Not a number and infinite write <tt>"NaN"</tt> and <tt>"±INF"</tt>.</td></tr> +<tr><td><tt>e E</tt></td><td>Floating point<br>(e notation)</td><td>4 to 31 characters. If the number of characters exceeds 31 or exponent exceeds +99, it writes <tt>"±OV"</tt>.</td></tr> +</table> +</dd> </dl> <p>When FatFs is configured for Unicode API (<tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a> >= 1</tt>), character encoding on the string fuctions, <tt>f_putc</tt>, <tt>f_puts</tt>, <tt>f_printf</tt> and <tt>f_gets</tt> function, is also switched to Unicode. The Unicode characters in multiple encoding unit, such as surrogate pair and multi-byte sequence, should not be divided into two function calls, or the character will be lost. The character encoding <em>on the file</em> to be written via this function is selected by <tt><a href="config.html#strf_encode">FF_STRF_ENCODE</a></tt>. The characters with wrong encoding or invalid for the output encoding will be lost.</p> +<p>If <tt>sprintf</tt> is used in the project and code conversion is not needed, <tt>f_write</tt> with <tt>sprintf</tt> will be efficient in code size and performance rather than <tt>f_printf</tt>.</p> </div> @@ -67,23 +83,24 @@ int f_printf ( <div class="para use"> <h4>Example</h4> <pre> - <em>f_printf</em>(&fil, "%d", 1234); <span class="c">/* "1234" */</span> - <em>f_printf</em>(&fil, "%6d,%3d%%", -200, 5); <span class="c">/* " -200, 5%" */</span> - <em>f_printf</em>(&fil, "%ld", 12345L); <span class="c">/* "12345" */</span> - <em>f_printf</em>(&fil, "%06d", 25); <span class="c">/* "000025" */</span> - <em>f_printf</em>(&fil, "%06d", -25); <span class="c">/* "000-25" */</span> - <em>f_printf</em>(&fil, "%*d", 5, 100); <span class="c">/* " 100" */</span> - <em>f_printf</em>(&fil, "%-6d", 25); <span class="c">/* "25 " */</span> - <em>f_printf</em>(&fil, "%u", -1); <span class="c">/* "65535" or "4294967295" */</span> - <em>f_printf</em>(&fil, "%04x", 0xAB3); <span class="c">/* "0ab3" */</span> - <em>f_printf</em>(&fil, "%08lX", 0x123ABCL); <span class="c">/* "00123ABC" */</span> - <em>f_printf</em>(&fil, "%04o", 255); <span class="c">/* "0377" */</span> - <em>f_printf</em>(&fil, "%016b", 0x550F); <span class="c">/* "0101010100001111" */</span> - <em>f_printf</em>(&fil, "%s", "String"); <span class="c">/* "String" */</span> - <em>f_printf</em>(&fil, "%8s", "abc"); <span class="c">/* " abc" */</span> - <em>f_printf</em>(&fil, "%-8s", "abc"); <span class="c">/* "abc " */</span> - <em>f_printf</em>(&fil, "%c", 'a'); <span class="c">/* "a" */</span> - <em>f_printf</em>(&fil, "%f", 10.0); <span class="c">/* f_printf lacks floating point support */</span> + <em>f_printf</em>(fp, "%d", 1234); <span class="c">/* "1234" */</span> + <em>f_printf</em>(fp, "%6d,%3d%%", -200, 5); <span class="c">/* " -200, 5%" */</span> + <em>f_printf</em>(fp, "%-6u", 100); <span class="c">/* "100 " */</span> + <em>f_printf</em>(fp, "%ld", 12345678); <span class="c">/* "12345678" */</span> + <em>f_printf</em>(fp, "%llu", 0x100000000); <span class="c">/* "4294967296" (<a href="config.html#print_lli">FF_PRINT_LLI</a>) */</span> + <em>f_printf</em>(fp, "%lld", -1LL); <span class="c">/* "-1" (FF_PRINT_LLI) */</span> + <em>f_printf</em>(fp, "%04x", 0xA3); <span class="c">/* "00a3" */</span> + <em>f_printf</em>(fp, "%08lX", 0x123ABC); <span class="c">/* "00123ABC" */</span> + <em>f_printf</em>(fp, "%016b", 0x550F); <span class="c">/* "0101010100001111" */</span> + <em>f_printf</em>(fp, "%*d", 6, 100); <span class="c">/* " 100" */</span> + <em>f_printf</em>(fp, "%s", "abcdefg"); <span class="c">/* "abcdefg" */</span> + <em>f_printf</em>(fp, "%5s", "abc"); <span class="c">/* " abc" */</span> + <em>f_printf</em>(fp, "%-5s", "abc"); <span class="c">/* "abc " */</span> + <em>f_printf</em>(fp, "%.5s", "abcdefg"); <span class="c">/* "abcde" */</span> + <em>f_printf</em>(fp, "%-5.2s", "abcdefg"); <span class="c">/* "ab " */</span> + <em>f_printf</em>(fp, "%c", 'a'); <span class="c">/* "a" */</span> + <em>f_printf</em>(fp, "%12f", 10.0); <span class="c">/* " 10.000000" (<a href="config.html#print_fp">FF_PRINT_FLOAT</a>) */</span> + <em>f_printf</em>(fp, "%.4E", 123.45678); <span class="c">/* "1.2346E+02" (FF_PRINT_FLOAT) */</span> </pre> </div> diff --git a/fatfs/documents/doc/putc.html b/fatfs/documents/doc/putc.html index 4d93bf5..747b5fd 100644 --- a/fatfs/documents/doc/putc.html +++ b/fatfs/documents/doc/putc.html @@ -35,7 +35,7 @@ int f_putc ( <div class="para ret">
<h4>Return Values</h4>
-<p>When the character was written successfuly, it returns number of character encoding units written to the file. When the function failed due to disk full or any error, an <tt>EOF (-1)</tt> will be returned.</p>
+<p>When the character was written successfuly, it returns number of character encoding units written to the file. When the function failed due to disk full or any error, a negative value will be returned.</p>
</div>
diff --git a/fatfs/documents/doc/puts.html b/fatfs/documents/doc/puts.html index 92c7e74..3695942 100644 --- a/fatfs/documents/doc/puts.html +++ b/fatfs/documents/doc/puts.html @@ -35,7 +35,7 @@ int f_puts ( <div class="para ret">
<h4>Return Value</h4>
-<p>When the string was written successfuly, it returns number of character encoding units written to the file. When the function failed due to disk full or any error, an EOF (-1) will be returned.</p>
+<p>When the string was written successfuly, it returns number of character encoding units written to the file. When the function failed due to disk full or any error, a negative value will be returned.</p>
</div>
diff --git a/fatfs/documents/doc/rc.html b/fatfs/documents/doc/rc.html index 05bcf9e..8f7fffa 100644 --- a/fatfs/documents/doc/rc.html +++ b/fatfs/documents/doc/rc.html @@ -11,7 +11,7 @@ <body>
<h1>Return Code of API Functions</h1>
-<p>Most of API functions return common result code as enum type <tt>FRESULT</tt>. When an API function succeeded, it returns zero (<tt>FR_OK</tt>), otherwise it returns non-zero value indicates type of error.</p>
+<p>Most of API functions return common result code in enum type <tt>FRESULT</tt>. When an API function succeeded, it returns zero (<tt>FR_OK</tt>), otherwise it returns non-zero value indicates type of error.</p>
<dl class="ret">
@@ -22,14 +22,14 @@ <dd>The lower layer, <tt>disk_read</tt>, <tt>disk_write</tt> or <tt>disk_ioctl</tt> function, reported that an unrecoverable hard error occured.<br>Note that if once this error occured at any operation to an open file, the file object is aborted and any operations to the file except for close will be rejected.</dd>
<dt id="ie">FR_INT_ERR</dt>
-<dd>Assertion failed. An insanity is detected in the internal process. One of the following possibilities is suspected.
+<dd>Assertion failed and an insanity is detected in the internal process. One of the following possibilities is suspected.
<ul>
-<li>Work area (file system object, file object or etc...) has been broken by stack overflow or any other tasks. This is the reason in most case.</li>
+<li>Work area (file system object, file object or etc...) has been broken by stack overflow or something. This is the reason in most case.</li>
<li>There is an error of the FAT structure on the volume.</li>
<li>There is a bug in the FatFs module itself.</li>
<li>Wrong lower layer implementation.</li>
</ul>
-Note that if once this error occured at any operation to an open file, the file object is aborted and all operations to the file except for close will be rejected.
+Note that if once this error occured in the operation to an open file, the file object is aborted and any operation to the file except for close will be rejected.
</dd>
<dt id="nr">FR_NOT_READY</dt>
@@ -38,46 +38,46 @@ Note that if once this error occured at any operation to an open file, the file <li>No medium in the drive.</li>
<li>Wrong lower layer implementation.</li>
<li>Wrong hardware configuration.</li>
-<li>The storage device has been broken.</li>
+<li>The storage device has broken.</li>
</ul>
</dd>
<dt id="nf">FR_NO_FILE</dt>
-<dd>Could not find the file.</dd>
+<dd>Could not find the file in the directory.</dd>
<dt id="np">FR_NO_PATH</dt>
-<dd>Could not find the path.</dd>
+<dd>Could not find the path. A directory in the path name could not be found.</dd>
<dt id="in">FR_INVALID_NAME</dt>
-<dd>The given string is invalid as the <a href="filename.html">path name</a>. One of the following possibilities is suspected.
+<dd>The given string is invalid as a <a href="filename.html">path name</a>. One of the following possibilities is suspected.
<ul>
-<li>There is any character not allowed for the file name.</li>
-<li>The string is out of 8.3 format. (at non-LFN cfg.)</li>
+<li>There is a character not allowed for the file name.</li>
+<li>The file name is out of 8.3 format. (at non-LFN cfg.)</li>
<li><tt>FF_MAX_LFN</tt> is insufficient for the file name. (at LFN cfg.)</li>
-<li>There is any character encoding error in the string.</li>
+<li>There is a character encoding error in the string.</li>
</ul>
</dd>
<dt id="dn">FR_DENIED</dt>
<dd>The required access was denied due to one of the following reasons:
<ul>
-<li>Write mode open against the read-only file.</li>
-<li>Deleting the read-only file or directory.</li>
-<li>Deleting the non-empty directory or current directory.</li>
-<li>Reading the file opened without <tt>FA_READ</tt> flag.</li>
-<li>Any modification to the file opened without <tt>FA_WRITE</tt> flag.</li>
-<li>Could not create the object due to root directory full or disk full.</li>
-<li>Could not allocate a contiguous area to the file.</li>
+<li>Write mode open against the read-only file. (f_open)</li>
+<li>Deleting the read-only file or directory. (f_unlink)</li>
+<li>Deleting the non-empty directory or current directory. (f_unlink)</li>
+<li>Reading the file opened without <tt>FA_READ</tt> flag. (f_read)</li>
+<li>Any modification to the file opened without <tt>FA_WRITE</tt> flag. (f_write, f_truncate, f_expand)</li>
+<li>Could not create the object due to root directory full or disk full. (f_open, f_mkdir)</li>
+<li>Could not find a contiguous area for the file. (f_expand)</li>
</ul>
</dd>
<dt id="ex">FR_EXIST</dt>
-<dd>Name collision. An object with the same name is already existing.</dd>
+<dd>Name collision. An object with the same name is already existing in the directory.</dd>
<dt id="io">FR_INVALID_OBJECT</dt>
<dd>The file/directory object is invalid or a null pointer is given. There are some reasons as follows:
<ul>
-<li>It has been closed, or collapsed.</li>
+<li>It has been closed, or the structure has been collapsed.</li>
<li>It has been invalidated. Open objects on the volume are invalidated by voulme mount process.</li>
<li>Physical drive is not ready to work due to a media removal.</li>
</ul>
@@ -87,20 +87,25 @@ Note that if once this error occured at any operation to an open file, the file <dd>A write mode operation against the write-protected media.</dd>
<dt id="id">FR_INVALID_DRIVE</dt>
-<dd>Invalid drive number is specified in the path name. A null pointer is given as the path name. (Related option: <tt><a href="config.html#volumes">FF_VOLUMES</a></tt>)</dd>
+<dd>Invalid drive number is specified in the path name or a null pointer is given as the path name. (Related option: <tt><a href="config.html#volumes">FF_VOLUMES</a></tt>)</dd>
<dt id="ne">FR_NOT_ENABLED</dt>
<dd>Work area for the logical drive has not been registered by <tt>f_mount</tt> function.</dd>
<dt id="ns">FR_NO_FILESYSTEM</dt>
-<dd>There is no valid FAT volume on the drive or wrong lower layer implementation.</dd>
+<dd>Valid FAT volume could not be found in the drive. One of the following possibilities is suspected.
+<ul>
+<li>The FAT volume on the drive is collapsed.</li>
+<li>Wrong lower layer implementation.</li>
+<li>Wrong <tt>VolToPart[]</tt> settings. (<tt>FF_MULTI_PARTITION = 1</tt>)</li>
+</ul></dd>
<dt id="ma">FR_MKFS_ABORTED</dt>
<dd>The <tt>f_mkfs</tt> function aborted before start in format due to a reason as follows:
<ul>
-<li>It is impossible to format with the given parameters.</li>
-<li>The size of volume is too small. 128 sectors minimum with <tt>FM_SFD</tt>.</li>
-<li>The partition bound to the logical drive coulud not be found. (Related option: <tt><a href="config.html#multi_partition">FF_MULTI_PARTITION</a></tt>)</li>
+<li>It is impossible to create the volume with the given conditions.</li>
+<li>The size of the volume is too small. 128 sectors minimum with <tt>FM_SFD</tt> option.</li>
+<li>The partition associated with the logical drive is not exist. (Related option: <tt><a href="config.html#multi_partition">FF_MULTI_PARTITION</a></tt>)</li>
</ul>
</dd>
diff --git a/fatfs/documents/doc/read.html b/fatfs/documents/doc/read.html index 3f0d23b..9dff623 100644 --- a/fatfs/documents/doc/read.html +++ b/fatfs/documents/doc/read.html @@ -30,11 +30,11 @@ FRESULT f_read ( <dt>fp</dt>
<dd>Pointer to the open file object.</dd>
<dt>buff</dt>
-<dd>Pointer to the buffer to store read data.</dd>
+<dd>Pointer to the buffer to store the read data.</dd>
<dt>btr</dt>
-<dd>Number of bytes to read in range of <tt>UINT</tt> type.</dd>
+<dd>Number of bytes to read in range of <tt>UINT</tt> type. If the file needs to be read fast, it should be read in large chunk as possible.</dd>
<dt>br</dt>
-<dd>Pointer to the <tt>UINT</tt> variable to return number of bytes read. This value is always valid after the function call regardless of the function return code.</dd>
+<dd>Pointer to the <tt>UINT</tt> variable that receives number of bytes read. This value is always valid after the function call regardless of the function return code. If the return value is equal to <tt class="arg">btr</tt>, the function return code should be <tt>FR_OK</tt>.</dd>
</dl>
</div>
@@ -54,7 +54,7 @@ FRESULT f_read ( <div class="para desc">
<h4>Description</h4>
-<p>The function starts to read data from the file at the position pointed by the read/write pointer. The read/write pointer advances as number of bytes read. After the function succeeded, <tt class="arg">*br</tt> should be checked to detect end of the file. In case of <tt class="arg">*br</tt> < <tt class="arg">btr</tt>, it means the read/write pointer reached end of the file during read operation.</p>
+<p>The function starts to read data from the file at the file offset pointed by read/write pointer. The read/write pointer advances as number of bytes read. After the function succeeded, <tt class="arg">*br</tt> should be checked to detect end of the file. In case of <tt class="arg">*br</tt> < <tt class="arg">btr</tt>, it means the read/write pointer hit end of the file during read operation.</p>
</div>
@@ -64,6 +64,12 @@ FRESULT f_read ( </div>
+<div class="para use">
+<h4>Example</h4>
+<p>Refer to the example in <tt>f_open</tt>.</p>
+</div>
+
+
<div class="para ref">
<h4>See Also</h4>
<p><tt><a href="open.html">f_open</a>, <a href="gets.html">fgets</a>, <a href="write.html">f_write</a>, <a href="close.html">f_close</a>, <a href="sfile.html">FIL</a></tt></p>
diff --git a/fatfs/documents/doc/readdir.html b/fatfs/documents/doc/readdir.html index 878cb02..52a96b9 100644 --- a/fatfs/documents/doc/readdir.html +++ b/fatfs/documents/doc/readdir.html @@ -20,6 +20,11 @@ FRESULT f_readdir ( FILINFO* <span class="arg">fno</span> <span class="c">/* [OUT] File information structure */</span>
);
</pre>
+<pre>
+FRESULT f_rewinddir (
+ DIR* <span class="arg">dp</span> <span class="c">/* [IN] Directory object */</span>
+);
+</pre>
</div>
<div class="para arg">
@@ -48,15 +53,19 @@ FRESULT f_readdir ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_readdir</tt> function reads a directory item, informations about the object. All items in the directory can be read in sequence by <tt>f_readdir</tt> function calls. Dot entries (<tt>"."</tt> and <tt>".."</tt>) in the sub-directory are filtered out and they will never appear in the read items. When all directory items have been read and no item to read, a nul string is stored into the <tt>fno->fname[]</tt> without any error. When a null pointer is given to the <tt class="arg">fno</tt>, the read index of the directory object is rewinded.</p>
-<p>When support of long file name (LFN) is enabled, a member <tt>altname[]</tt> is defined in the file information structure to store the short file name of the object. If the long file name is not accessible due to some reason listed below, short file name is stored to the <tt>fname[]</tt> and <tt>altname[]</tt> has a null string.</p>
+<p>The <tt>f_readdir</tt> function reads a directory item, informations about the object, from the open directory. Items in the directory can be read in sequence by <tt>f_readdir</tt> function calls. When all items in the directory have been read and no item to read, a null string is stored into the <tt>fno->fname[]</tt> without any error. When a null pointer is given to the <tt class="arg">fno</tt>, the read index of the directory object is rewinded. The <tt>f_rewinddir</tt> function is implemented as a macro.</p>
+<pre>
+#define <em>f_rewinddir</em>(dp) f_readdir((dp), 0)
+</pre>
+<p>When LFN is enabled, a member <tt>altname[]</tt> is defined in the file information structure to store the short file name of the object. If the long file name is not accessible due to a reason listed below, short file name is stored to the <tt>fname[]</tt> and the <tt>altname[]</tt> has a null string.</p>
<ul>
-<li>The item has no LFN. (Not the case at exFAT volume)</li>
-<li>Setting of <a href="config.html#max_lfn"><tt>FF_MAX_LFN</tt></a> is insufficient to handle the LFN. (Not the case at <tt>FF_MAX_LFN == 255</tt>)</li>
-<li>Setting of <a href="config.html#lfn_buf"><tt>FF_LFN_BUF</tt></a> is insufficient to store the LFN.</li>
-<li>The LFN contains any character not defined in current code page. (Not the case at <tt>FF_LFN_UNICODE >= 1</tt>)</li>
+<li>The item has no LFN. (Not the case in exFAT volume)</li>
+<li><a href="config.html#max_lfn"><tt>FF_MAX_LFN</tt></a> is insufficient to handle the LFN. (Not the case in <tt>FF_MAX_LFN == 255</tt>)</li>
+<li><a href="config.html#lfn_buf"><tt>FF_LFN_BUF</tt></a> is insufficient to store the LFN.</li>
+<li>The LFN contains some character not defined in current CP. (Not the case in <tt>FF_LFN_UNICODE != 0</tt>)</li>
</ul>
-<p>There is a problem on reading a directory of exFAT volume. The exFAT does not support short file name. This means no name can be returned on the condition above. If it is the case, "?" is returned into the <tt>fname[]</tt> to indicate that the object is not accessible. To avoid this problem, configure FatFs <tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a> >= 1</tt> and <tt>FF_MAX_LFN == 255</tt> to support the full feature of LFN specification.</p>
+<p>There is an issue on read directories in exFAT volume. The exFAT does not support short file name. This means no name can be returned on the condition above. If it is the case, "?" is returned as the file name to indicate that the object is not accessible. To avoid this problem, configure FatFs <tt><a href="config.html#lfn_unicode">FF_LFN_UNICODE</a> != 0</tt> and <tt>FF_MAX_LFN == 255</tt> to support the full feature of LFN specification.</p>
+<p>Dot entries (<tt>"."</tt> and <tt>".."</tt>) in the sub-directory of FAT volume are filtered out and they will never appear in the read items because exFAT lacks dot entries in the sub-directory.</p>
</div>
@@ -94,7 +103,7 @@ FRESULT scan_files ( printf("%s/%s\n", path, fno.fname);
}
}
- f_closedir(&dir)
+ f_closedir(&dir);
}
return res;
diff --git a/fatfs/documents/doc/sdir.html b/fatfs/documents/doc/sdir.html index 53a460d..eb18cc3 100644 --- a/fatfs/documents/doc/sdir.html +++ b/fatfs/documents/doc/sdir.html @@ -19,7 +19,7 @@ FFOBJID obj; <span class="c">/* Object identifier */</span>
DWORD dptr; <span class="c">/* Current read/write offset */</span>
DWORD clust; <span class="c">/* Current cluster */</span>
- DWORD sect; <span class="c">/* Current sector */</span>
+ LBA_t sect; <span class="c">/* Current sector */</span>
BYTE* dir; <span class="c">/* Pointer to the current SFN entry in the win[] */</span>
BYTE* fn; <span class="c">/* Pointer to the SFN buffer (in/out) {file[8],ext[3],status[1]} */</span>
<span class="k">#if</span> FF_USE_LFN
diff --git a/fatfs/documents/doc/setlabel.html b/fatfs/documents/doc/setlabel.html index c50db18..9eb5e78 100644 --- a/fatfs/documents/doc/setlabel.html +++ b/fatfs/documents/doc/setlabel.html @@ -53,9 +53,9 @@ FRESULT f_setlabel ( <ul>
<li>Up to 11 bytes long as conversion of OEM code page at FAT volume.</li>
<li>Up to 11 characters long at exFAT volume.</li>
-<li>Allowable characters for FAT volume are: <tt>! # $ % & ' ( ) - ^ _ ` ~ { } 0-9 A-Z a-z</tt> and extended characters. Low-case characters are up converted.</li>
-<li>Allowable characters for exFAT volume are: characters allowed for FAT volume and <tt>" + , . ; = [ ]</tt>. Low-case characters are preserved.</li>
-<li>Spaces can be contained anywhere in the volume label. Trailing spaces are truncated off at FAT volume.</li>
+<li>Allowable characters for FAT volume are: characters allowed for SFN excludes dot. Low-case characters are up converted.</li>
+<li>Allowable characters for exFAT volume are: characters allowed for LFN includes dot. Low-case characters are preserved.</li>
+<li>Spaces can be embedded anywhere in the volume label. Trailing spaces are truncated off at FAT volume.</li>
</ul>
<p>Remark: The standard system (Windows) has a problem at the volume label with a heading <tt>\xE5</tt> on the FAT volume. To avoid this problem, this function rejects such volume label as invalid name.</p>
</div>
diff --git a/fatfs/documents/doc/sfatfs.html b/fatfs/documents/doc/sfatfs.html index e5207cb..6ecd6e5 100644 --- a/fatfs/documents/doc/sfatfs.html +++ b/fatfs/documents/doc/sfatfs.html @@ -31,7 +31,7 @@ BYTE* dirbuf; <span class="c">/* Directory entry block scratchpad buffer */</span>
<span class="k">#endif</span>
<span class="k">#if</span> FF_FS_REENTRANT
- FF_SYNC_t sobj; <span class="c">/* Identifier of sync object */</span>
+ FF_SYNC_t sobj; <span class="c">/* Identifier of sync object */</span>
<span class="k">#endif</span>
<span class="k">#if</span> !FF_FS_READONLY
DWORD last_clust; <span class="c">/* FSINFO: Last allocated cluster (0xFFFFFFFF if invalid) */</span>
@@ -47,11 +47,11 @@ <span class="k">#endif</span>
DWORD n_fatent; <span class="c">/* Number of FAT entries (Number of clusters + 2) */</span>
DWORD fsize; <span class="c">/* Sectors per FAT */</span>
- DWORD volbase; <span class="c">/* Volume base LBA */</span>
- DWORD fatbase; <span class="c">/* FAT base LBA */</span>
- DWORD dirbase; <span class="c">/* Root directory base (LBA|Cluster) */</span>
- DWORD database; <span class="c">/* Data base LBA */</span>
- DWORD winsect; <span class="c">/* Sector LBA appearing in the win[] */</span>
+ LBA_t volbase; <span class="c">/* Volume base LBA */</span>
+ LBA_t fatbase; <span class="c">/* FAT base LBA */</span>
+ LBA_t dirbase; <span class="c">/* Root directory base (LBA|Cluster) */</span>
+ LBA_t database; <span class="c">/* Data base LBA */</span>
+ LBA_t winsect; <span class="c">/* Sector LBA appearing in the win[] */</span>
BYTE win[FF_MAX_SS]; <span class="c">/* Disk access window for directory, FAT (and file data at tiny cfg) */</span>
} FATFS;
</pre>
diff --git a/fatfs/documents/doc/sfile.html b/fatfs/documents/doc/sfile.html index e8a677f..9234d32 100644 --- a/fatfs/documents/doc/sfile.html +++ b/fatfs/documents/doc/sfile.html @@ -22,9 +22,9 @@ BYTE err; <span class="c">/* Abort flag (error code) */</span>
FSIZE_t fptr; <span class="c">/* File read/write pointer (Byte offset origin from top of the file) */</span>
DWORD clust; <span class="c">/* Current cluster of fptr (One cluster behind if fptr is on the cluster boundary. Invalid if fptr == 0.) */</span>
- DWORD sect; <span class="c">/* Current data sector (Can be invalid if fptr is on the cluster boundary.)*/</span>
+ LBA_t sect; <span class="c">/* Current data sector (Can be invalid if fptr is on the cluster boundary.)*/</span>
<span class="k">#if</span> !FF_FS_READONLY
- DWORD dir_sect; <span class="c">/* Sector number containing the directory entry */</span>
+ LBA_t dir_sect; <span class="c">/* Sector number containing the directory entry */</span>
BYTE* dir_ptr; <span class="c">/* Ponter to the directory entry in the window */</span>
<span class="k">#endif</span>
<span class="k">#if</span> FF_USE_FASTSEEK
diff --git a/fatfs/documents/doc/sfileinfo.html b/fatfs/documents/doc/sfileinfo.html index b4c9063..db0f45e 100644 --- a/fatfs/documents/doc/sfileinfo.html +++ b/fatfs/documents/doc/sfileinfo.html @@ -13,7 +13,7 @@ <div class="para">
<h2>FILINFO</h2>
-<p>The <tt>FILINFO</tt> structure holds information about the object returned by <tt>f_readdir</tt>, <tt>f_findfirst</tt>, <tt>f_findnext</tt> and <tt>f_stat</tt> function. Be careful in the size of structure when LFN is enabled.</p>
+<p>The <tt>FILINFO</tt> structure holds information about the object retrieved by <tt>f_readdir</tt>, <tt>f_findfirst</tt>, <tt>f_findnext</tt> and <tt>f_stat</tt> function. Be careful in the size of structure when LFN is enabled.</p>
<pre>
<span class="k">typedef struct</span> {
FSIZE_t fsize; <span class="c">/* File size */</span>
@@ -33,9 +33,9 @@ <h4>Members</h4>
<dl>
<dt>fsize</dt>
-<dd>Indicates size of the file in unit of byte. <tt>FSIZE_t</tt> is an alias of integer type either <tt>DWORD</tt>(32-bit) or <tt>QWORD</tt>(64-bit) depends on the configuration option <tt>FF_FS_EXFAT</tt>. Do not care when the item is a directory.</dd>
+<dd>Size of the file in unit of byte. <tt>FSIZE_t</tt> is an alias of integer type either <tt>DWORD</tt>(32-bit) or <tt>QWORD</tt>(64-bit) depends on the configuration option <tt>FF_FS_EXFAT</tt>. Do not care if the item is a sub-directory.</dd>
<dt>fdate</dt>
-<dd>Indicates the date when the file was modified or the directory was created.<br>
+<dd>The date when the file was modified or the directory was created.<br>
<dl>
<dt>bit15:9</dt>
<dd>Year origin from 1980 (0..127)</dd>
@@ -46,7 +46,7 @@ </dl>
</dd>
<dt>ftime</dt>
-<dd>Indicates the time when the file was modified or the directory was created.<br>
+<dd>The time when the file was modified or the directory was created.<br>
<dl>
<dt>bit15:11</dt>
<dd>Hour (0..23)</dd>
@@ -57,7 +57,7 @@ </dl>
</dd>
<dt>fattrib</dt>
-<dd>Indicates the attribute flags in combination of:<br>
+<dd>The attribute flags in combination of:<br>
<table class="lst">
<tr><th>Flag</th><th>Meaning</th></tr>
<tr><td>AM_RDO</td><td>Read-only. Write mode open and deleting is rejected.</td></tr>
@@ -68,9 +68,9 @@ </table>
</dd>
<dt>fname[]</dt>
-<dd>The null-terminated object name is stored. A null string is stored when no item to read and it indicates this structure is invalid. The size of <tt>fname[]</tt> and <tt>altname[]</tt> each can be configured at LFN configuration.</dd>
+<dd>Null-terminated object name. A null string is stored when no item to read and it indicates this structure is invalid. The size of <tt>fname[]</tt> and <tt>altname[]</tt> each can be configured in LFN configuration.</dd>
<dt>altname[]</dt>
-<dd>Alternative object name is stored if available. This member is not available at non-LFN configuration.</dd>
+<dd>Alternative object name is stored if available. This member is not available in non-LFN configuration.</dd>
</dl>
<p class="foot"><a href="../00index_e.html">Return</a></p>
diff --git a/fatfs/documents/doc/stat.html b/fatfs/documents/doc/stat.html index db63667..a4e4fc8 100644 --- a/fatfs/documents/doc/stat.html +++ b/fatfs/documents/doc/stat.html @@ -28,7 +28,7 @@ FRESULT f_stat ( <dt>path</dt>
<dd>Pointer to the null-terminated string that specifies the <a href="filename.html">object</a> to get its information. The object must not be the root direcotry.</dd>
<dt>fno</dt>
-<dd>Pointer to the blank <tt>FILINFO</tt> structure to store the information of the object. Set null pointer if it is not needed.</dd>
+<dd>Pointer to the blank <tt>FILINFO</tt> structure to store the information of the object. Set null pointer if this information is not needed.</dd>
</dl>
</div>
@@ -54,7 +54,8 @@ FRESULT f_stat ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_stat</tt> function checks the existence of a file or sub-directory. If not exist, the function returns with <tt>FR_NO_FILE</tt>. If exist, the function returns with <tt>FR_OK</tt> and the informations of the object, file size, timestamp and attribute, are stored to the file information structure. For details of the file information, refer to the <tt>FILINFO</tt> structure and <a href="readdir.html"><tt>f_readdir</tt></a> function.</p>
+<p>The <tt>f_stat</tt> function checks the existence of a file or sub-directory in the directory. If it is not exist, the function returns with <tt>FR_NO_FILE</tt>. If it is exist, the function returns with <tt>FR_OK</tt> and the informations about the object, size, timestamp and attribute, is stored to the file information structure. For details of the file information, refer to the <tt>FILINFO</tt> structure and <a href="readdir.html"><tt>f_readdir</tt></a> function.</p>
+<p>Note that the file information comes from the meta data in the directory. If the file has been opend and modified, the file will need to be synched or closed in order to obtain the latest file information.</p>
</div>
@@ -69,16 +70,17 @@ FRESULT f_stat ( <pre>
FRESULT fr;
FILINFO fno;
+ const char *fname = "file.txt";
- printf("Test for 'file.txt'...\n");
+ printf("Test for \"%s\"...\n", fname);
- fr = f_stat("file.txt", &fno);
+ fr = <em>f_stat</em>(fname, &fno);
switch (fr) {
case FR_OK:
printf("Size: %lu\n", fno.fsize);
- printf("Timestamp: %u/%02u/%02u, %02u:%02u\n",
+ printf("Timestamp: %u-%02u-%02u, %02u:%02u\n",
(fno.fdate >> 9) + 1980, fno.fdate >> 5 & 15, fno.fdate & 31,
fno.ftime >> 11, fno.ftime >> 5 & 63);
printf("Attributes: %c%c%c%c%c\n",
@@ -90,7 +92,7 @@ FRESULT f_stat ( break;
case FR_NO_FILE:
- printf("It is not exist.\n");
+ printf("\"%s\" is not exist.\n", fname);
break;
default:
diff --git a/fatfs/documents/doc/sync.html b/fatfs/documents/doc/sync.html index a0317d6..9fb42a0 100644 --- a/fatfs/documents/doc/sync.html +++ b/fatfs/documents/doc/sync.html @@ -44,7 +44,30 @@ FRESULT f_sync ( <div class="para desc">
<h4>Description</h4>
-<p>The <tt>f_sync</tt> function performs the same process as <tt>f_close</tt> function but the file is left opened and can continue read/write/seek operations to the file. This is suitable for the applications that open files for a long time in write mode, such as data logger. Performing <tt>f_sync</tt> function of periodic or immediataly after <tt>f_write</tt> function can minimize the risk of data loss due to a sudden blackout or an unintentional media removal. For more information, refer to <a href="appnote.html#critical">application note</a>.</p>
+<p>The <tt>f_sync</tt> function performs the same process as <tt>f_close</tt> function but the file is left opened and can continue read/write/seek operations to the file. This is suitable for the applications that open files for a long time in write mode, such as data logger. Performing <tt>f_sync</tt> function in certain interval can minimize the risk of data loss due to a sudden blackout, wrong media removal or unrecoverable disk error. For more information, refer to <a href="appnote.html#critical">application note</a>.</p>
+<pre>
+Case 1. Normal write sequence
+
+ Time --> ↓Normal shutdown
+OwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwC <Power off>
+
+
+Case 2. Without using f_sync()
+
+ Time --> ↓System crush
+O<span class="e">wwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwwww</span>
+ |<--------------- All data written will be lost ------------------>|
+
+
+Case 3. Using f_sync()
+ Time --> ↓System crush
+OwwwwwwwwSwwwwwwwwSwwwwwwwwSwwwwwwwwSwwwwwwwwSwwwwwwwwSwwwwwwwwS<span class="e">wwwww</span>
+ Data after last f_sync will be lost |<->|
+O - f_open()
+C - f_close()
+w - f_write()
+S - f_sync()
+</pre>
<p>However there is no sense in <tt>f_sync</tt> function immediataly before <tt>f_close</tt> function because it performs <tt>f_sync</tt> function in it. In other words, the differnce between those functions is that the file object is invalidated or not.</p>
</div>
diff --git a/fatfs/documents/doc/unlink.html b/fatfs/documents/doc/unlink.html index 26f3cb9..7809648 100644 --- a/fatfs/documents/doc/unlink.html +++ b/fatfs/documents/doc/unlink.html @@ -13,7 +13,7 @@ <div class="para func">
<h2>f_unlink</h2>
-<p>The f_unlink function removes a file or sub-directory.</p>
+<p>The f_unlink function removes a file or sub-directory from the volume.</p>
<pre>
FRESULT f_unlink (
const TCHAR* <span class="arg">path</span> <span class="c">/* [IN] Object name */</span>
diff --git a/fatfs/documents/doc/write.html b/fatfs/documents/doc/write.html index d451255..3d16674 100644 --- a/fatfs/documents/doc/write.html +++ b/fatfs/documents/doc/write.html @@ -32,9 +32,9 @@ FRESULT f_write ( <dt>buff</dt>
<dd>Pointer to the data to be written.</dd>
<dt>btw</dt>
-<dd>Specifies number of bytes to write in range of <tt>UINT</tt> type.</dd>
+<dd>Specifies number of bytes to write in range of <tt>UINT</tt> type. If the data needs to be written fast, it should be written in large chunk as possible.</dd>
<dt>bw</dt>
-<dd>Pointer to the <tt>UINT</tt> variable to return the number of bytes written. This value is always valid after the function call regardless of the function return code.</dd>
+<dd>Pointer to the <tt>UINT</tt> variable that receives the number of bytes written. This value is always valid after the function call regardless of the function return code. If the return value is equal to <tt class="arg">btw</tt>, the function return code should be <tt>FR_OK</tt>.</dd>
</dl>
</div>
@@ -54,7 +54,7 @@ FRESULT f_write ( <div class="para desc">
<h4>Description</h4>
-<p>The function starts to write data to the file at the position pointed by the read/write pointer. The read/write pointer advances as number of bytes written. After the function succeeded, <tt class="arg">*bw</tt> should be checked to detect the disk full. In case of <tt class="arg">*bw</tt> < <tt class="arg">btw</tt>, it means the volume got full during the write operation. The function can take a time when the volume is full or close to full.</p>
+<p>The function starts to write data to the file at the file offset pointed by read/write pointer. The read/write pointer advances as number of bytes written. After the function succeeded, <tt class="arg">*bw</tt> should be checked to detect the disk full. In case of <tt class="arg">*bw</tt> < <tt class="arg">btw</tt>, it means the volume got full during the write operation. The function can take a time when the volume is full or close to full.</p>
</div>
@@ -64,6 +64,12 @@ FRESULT f_write ( </div>
+<div class="para use">
+<h4>Example</h4>
+<p>Refer to the example in <tt>f_open</tt>.</p>
+</div>
+
+
<div class="para ref">
<h4>See Also</h4>
<p><tt><a href="open.html">f_open</a>, <a href="read.html">f_read</a>, <a href="putc.html">fputc</a>, <a href="puts.html">fputs</a>, <a href="printf.html">fprintf</a>, <a href="close.html">f_close</a>, <a href="sfile.html">FIL</a></tt></p>
diff --git a/fatfs/documents/res/app2.c b/fatfs/documents/res/app2.c index 3de3eee..415c4bc 100644 --- a/fatfs/documents/res/app2.c +++ b/fatfs/documents/res/app2.c @@ -1,65 +1,78 @@ /*------------------------------------------------------------/
-/ Remove all contents of a directory
-/ This function works regardless of FF_FS_RPATH.
-/------------------------------------------------------------*/
+/ Delete a sub-directory even if it contains any file
+/-------------------------------------------------------------/
+/ The delete_node() function is for R0.12+.
+/ It works regardless of FF_FS_RPATH.
+*/
-FILINFO fno;
-
-FRESULT empty_directory (
- char* path /* Working buffer filled with start directory */
+FRESULT delete_node (
+ TCHAR* path, /* Path name buffer with the sub-directory to delete */
+ UINT sz_buff, /* Size of path name buffer (items) */
+ FILINFO* fno /* Name read buffer */
)
{
UINT i, j;
FRESULT fr;
DIR dir;
- fr = f_opendir(&dir, path);
- if (fr == FR_OK) {
- for (i = 0; path[i]; i++) ;
- path[i++] = '/';
- for (;;) {
- fr = f_readdir(&dir, &fno);
- if (fr != FR_OK || !fno.fname[0]) break;
- if (_FS_RPATH && fno.fname[0] == '.') continue;
- j = 0;
- do
- path[i+j] = fno.fname[j];
- while (fno.fname[j++]);
- if (fno.fattrib & AM_DIR) {
- fr = empty_directory(path);
- if (fr != FR_OK) break;
+
+ fr = f_opendir(&dir, path); /* Open the sub-directory to make it empty */
+ if (fr != FR_OK) return fr;
+
+ for (i = 0; path[i]; i++) ; /* Get current path length */
+ path[i++] = _T('/');
+
+ for (;;) {
+ fr = f_readdir(&dir, fno); /* Get a directory item */
+ if (fr != FR_OK || !fno->fname[0]) break; /* End of directory? */
+ j = 0;
+ do { /* Make a path name */
+ if (i + j >= sz_buff) { /* Buffer over flow? */
+ fr = 100; break; /* Fails with 100 when buffer overflow */
}
+ path[i + j] = fno->fname[j];
+ } while (fno->fname[j++]);
+ if (fno->fattrib & AM_DIR) { /* Item is a sub-directory */
+ fr = delete_node(path, sz_buff, fno);
+ } else { /* Item is a file */
fr = f_unlink(path);
- if (fr != FR_OK) break;
}
- path[--i] = '\0';
- closedir(&dir);
+ if (fr != FR_OK) break;
}
+ path[--i] = 0; /* Restore the path name */
+ f_closedir(&dir);
+
+ if (fr == FR_OK) fr = f_unlink(path); /* Delete the empty sub-directory */
return fr;
}
-int main (void)
+
+int main (void) /* How to use */
{
FRESULT fr;
FATFS fs;
- char buff[256]; /* Working buffer */
+ TCHAR buff[256];
+ FILINFO fno;
+ f_mount(&fs, _T("5:"), 0);
- f_mount(&fs, "", 0);
+ /* Directory to be deleted */
+ _tcscpy(buff, _T("5:dir"));
- strcpy(buff, "/"); /* Directory to be emptied */
- fr = empty_directory(buff);
+ /* Delete the directory */
+ fr = delete_node(buff, sizeof buff / sizeof buff[0], &fno);
+ /* Check the result */
if (fr) {
- printf("Function failed. (%u)\n", fr);
+ _tprintf(_T("Failed to delete the directory. (%u)\n"), fr);
return fr;
} else {
- printf("All contents in the %s are successfully removed.\n", buff);
+ _tprintf(_T("The directory and the contents have successfully been deleted.\n"), buff);
return 0;
}
}
diff --git a/fatfs/documents/res/app4.c b/fatfs/documents/res/app4.c index 4209f39..c46d1a0 100644 --- a/fatfs/documents/res/app4.c +++ b/fatfs/documents/res/app4.c @@ -10,9 +10,9 @@ #include "diskio.h" /* Declarations of disk functions */
-static
-DWORD pn ( /* Pseudo random number generator */
- DWORD pns /* 0:Initialize, !0:Read */
+
+static DWORD pn ( /* Pseudo random number generator */
+ DWORD pns /* 0:Initialize, !0:Read */
)
{
static DWORD lfsr;
@@ -50,8 +50,8 @@ int test_diskio ( printf("test_diskio(%u, %u, 0x%08X, 0x%08X)\n", pdrv, ncyc, (UINT)buff, sz_buff);
- if (sz_buff < _MAX_SS + 4) {
- printf("Insufficient work area to run program.\n");
+ if (sz_buff < FF_MAX_SS + 8) {
+ printf("Insufficient work area to run the program.\n");
return 1;
}
@@ -115,7 +115,7 @@ int test_diskio ( }
/* Single sector write test */
- printf("**** Single sector write test 1 ****\n");
+ printf("**** Single sector write test ****\n");
lba = 0;
for (n = 0, pn(pns); n < sz_sect; n++) pbuff[n] = (BYTE)pn(0);
printf(" disk_write(%u, 0x%X, %lu, 1)", pdrv, (UINT)pbuff, lba);
@@ -145,52 +145,56 @@ int test_diskio ( }
for (n = 0, pn(pns); n < sz_sect && pbuff[n] == (BYTE)pn(0); n++) ;
if (n == sz_sect) {
- printf(" Data matched.\n");
+ printf(" Read data matched.\n");
} else {
- printf("Failed: Read data differs from the data written.\n");
+ printf(" Read data differs from the data written.\n");
return 10;
}
pns++;
printf("**** Multiple sector write test ****\n");
- lba = 1; ns = sz_buff / sz_sect;
+ lba = 5; ns = sz_buff / sz_sect;
if (ns > 4) ns = 4;
- for (n = 0, pn(pns); n < (UINT)(sz_sect * ns); n++) pbuff[n] = (BYTE)pn(0);
- printf(" disk_write(%u, 0x%X, %lu, %u)", pdrv, (UINT)pbuff, lba, ns);
- dr = disk_write(pdrv, pbuff, lba, ns);
- if (dr == RES_OK) {
- printf(" - ok.\n");
- } else {
- printf(" - failed.\n");
- return 11;
- }
- printf(" disk_ioctl(%u, CTRL_SYNC, NULL)", pdrv);
- dr = disk_ioctl(pdrv, CTRL_SYNC, 0);
- if (dr == RES_OK) {
- printf(" - ok.\n");
- } else {
- printf(" - failed.\n");
- return 12;
- }
- memset(pbuff, 0, sz_sect * ns);
- printf(" disk_read(%u, 0x%X, %lu, %u)", pdrv, (UINT)pbuff, lba, ns);
- dr = disk_read(pdrv, pbuff, lba, ns);
- if (dr == RES_OK) {
- printf(" - ok.\n");
- } else {
- printf(" - failed.\n");
- return 13;
- }
- for (n = 0, pn(pns); n < (UINT)(sz_sect * ns) && pbuff[n] == (BYTE)pn(0); n++) ;
- if (n == (UINT)(sz_sect * ns)) {
- printf(" Data matched.\n");
+ if (ns > 1) {
+ for (n = 0, pn(pns); n < (UINT)(sz_sect * ns); n++) pbuff[n] = (BYTE)pn(0);
+ printf(" disk_write(%u, 0x%X, %lu, %u)", pdrv, (UINT)pbuff, lba, ns);
+ dr = disk_write(pdrv, pbuff, lba, ns);
+ if (dr == RES_OK) {
+ printf(" - ok.\n");
+ } else {
+ printf(" - failed.\n");
+ return 11;
+ }
+ printf(" disk_ioctl(%u, CTRL_SYNC, NULL)", pdrv);
+ dr = disk_ioctl(pdrv, CTRL_SYNC, 0);
+ if (dr == RES_OK) {
+ printf(" - ok.\n");
+ } else {
+ printf(" - failed.\n");
+ return 12;
+ }
+ memset(pbuff, 0, sz_sect * ns);
+ printf(" disk_read(%u, 0x%X, %lu, %u)", pdrv, (UINT)pbuff, lba, ns);
+ dr = disk_read(pdrv, pbuff, lba, ns);
+ if (dr == RES_OK) {
+ printf(" - ok.\n");
+ } else {
+ printf(" - failed.\n");
+ return 13;
+ }
+ for (n = 0, pn(pns); n < (UINT)(sz_sect * ns) && pbuff[n] == (BYTE)pn(0); n++) ;
+ if (n == (UINT)(sz_sect * ns)) {
+ printf(" Read data matched.\n");
+ } else {
+ printf(" Read data differs from the data written.\n");
+ return 14;
+ }
} else {
- printf("Failed: Read data differs from the data written.\n");
- return 14;
+ printf(" Test skipped.\n");
}
pns++;
- printf("**** Single sector write test (misaligned address) ****\n");
+ printf("**** Single sector write test (unaligned buffer address) ****\n");
lba = 5;
for (n = 0, pn(pns); n < sz_sect; n++) pbuff[n+3] = (BYTE)pn(0);
printf(" disk_write(%u, 0x%X, %lu, 1)", pdrv, (UINT)(pbuff+3), lba);
@@ -220,9 +224,9 @@ int test_diskio ( }
for (n = 0, pn(pns); n < sz_sect && pbuff[n+5] == (BYTE)pn(0); n++) ;
if (n == sz_sect) {
- printf(" Data matched.\n");
+ printf(" Read data matched.\n");
} else {
- printf("Failed: Read data differs from the data written.\n");
+ printf(" Read data differs from the data written.\n");
return 18;
}
pns++;
@@ -274,9 +278,9 @@ int test_diskio ( }
for (n = 0, pn(pns); pbuff[n] == (BYTE)pn(0) && n < (UINT)(sz_sect * 2); n++) ;
if (n == (UINT)(sz_sect * 2)) {
- printf(" Data matched.\n");
+ printf(" Read data matched.\n");
} else {
- printf("Failed: Read data differs from the data written.\n");
+ printf(" Read data differs from the data written.\n");
return 24;
}
} else {
diff --git a/fatfs/documents/res/app5.c b/fatfs/documents/res/app5.c new file mode 100644 index 0000000..2739019 --- /dev/null +++ b/fatfs/documents/res/app5.c @@ -0,0 +1,38 @@ +/*----------------------------------------------------------------------/
+/ Test if the file is contiguous /
+/----------------------------------------------------------------------*/
+
+FRESULT test_contiguous_file (
+ FIL* fp, /* [IN] Open file object to be checked */
+ int* cont /* [OUT] 1:Contiguous, 0:Fragmented or zero-length */
+)
+{
+ DWORD clst, clsz, step;
+ FSIZE_t fsz;
+ FRESULT fr;
+
+
+ *cont = 0;
+ fr = f_rewind(fp); /* Validates and prepares the file */
+ if (fr != FR_OK) return fr;
+
+#if FF_MAX_SS == FF_MIN_SS
+ clsz = (DWORD)fp->obj.fs->csize * FF_MAX_SS; /* Cluster size */
+#else
+ clsz = (DWORD)fp->obj.fs->csize * fp->obj.fs->ssize;
+#endif
+ fsz = f_size(fp);
+ if (fsz > 0) {
+ clst = fp->obj.sclust - 1; /* A cluster leading the first cluster for first test */
+ while (fsz) {
+ step = (fsz >= clsz) ? clsz : (DWORD)fsz;
+ fr = f_lseek(fp, f_tell(fp) + step); /* Advances file pointer a cluster */
+ if (fr != FR_OK) return fr;
+ if (clst + 1 != fp->clust) break; /* Is not the cluster next to previous one? */
+ clst = fp->clust; fsz -= step; /* Get current cluster for next test */
+ }
+ if (fsz == 0) *cont = 1; /* All done without fail? */
+ }
+
+ return FR_OK;
+}
diff --git a/fatfs/documents/res/app6.c b/fatfs/documents/res/app6.c new file mode 100644 index 0000000..4a3565e --- /dev/null +++ b/fatfs/documents/res/app6.c @@ -0,0 +1,61 @@ +/*---------------------------------------------------------------------*/
+/* Raw Read/Write Throughput Checker */
+/*---------------------------------------------------------------------*/
+
+#include <stdio.h>
+#include <systimer.h>
+#include "diskio.h"
+#include "ff.h"
+
+
+int test_raw_speed (
+ BYTE pdrv, /* Physical drive number */
+ DWORD lba, /* Start LBA for read/write test */
+ DWORD len, /* Number of bytes to read/write (must be multiple of sz_buff) */
+ void* buff, /* Read/write buffer */
+ UINT sz_buff /* Size of read/write buffer (must be multiple of FF_MAX_SS) */
+)
+{
+ WORD ss;
+ DWORD ofs, tmr;
+
+
+#if FF_MIN_SS != FF_MAX_SS
+ if (disk_ioctl(pdrv, GET_SECTOR_SIZE, &ss) != RES_OK) {
+ printf("\ndisk_ioctl() failed.\n");
+ return 0;
+ }
+#else
+ ss = FF_MAX_SS;
+#endif
+
+ printf("Starting raw write test at sector %lu in %u bytes of data chunks...", lba, sz_buff);
+ tmr = systimer();
+ for (ofs = 0; ofs < len / ss; ofs += sz_buff / ss) {
+ if (disk_write(pdrv, buff, lba + ofs, sz_buff / ss) != RES_OK) {
+ printf("\ndisk_write() failed.\n");
+ return 0;
+ }
+ }
+ if (disk_ioctl(pdrv, CTRL_SYNC, 0) != RES_OK) {
+ printf("\ndisk_ioctl() failed.\n");
+ return 0;
+ }
+ tmr = systimer() - tmr;
+ printf("\n%lu bytes written and it took %lu timer ticks.\n", len, tmr);
+
+ printf("Starting raw read test at sector %lu in %u bytes of data chunks...", lba, sz_buff);
+ tmr = systimer();
+ for (ofs = 0; ofs < len / ss; ofs += sz_buff / ss) {
+ if (disk_read(pdrv, buff, lba + ofs, sz_buff / ss) != RES_OK) {
+ printf("\ndisk_read() failed.\n");
+ return 0;
+ }
+ }
+ tmr = systimer() - tmr;
+ printf("\n%lu bytes read and it took %lu timer ticks.\n", len, tmr);
+
+ printf("Test completed.\n");
+ return 1;
+}
+
diff --git a/fatfs/documents/res/f4.png b/fatfs/documents/res/f4.png Binary files differindex f9a6b46..2c00ddc 100644 --- a/fatfs/documents/res/f4.png +++ b/fatfs/documents/res/f4.png diff --git a/fatfs/documents/res/f5.png b/fatfs/documents/res/f5.png Binary files differindex b110b29..bc0171a 100644 --- a/fatfs/documents/res/f5.png +++ b/fatfs/documents/res/f5.png diff --git a/fatfs/documents/res/funcs.png b/fatfs/documents/res/funcs.png Binary files differindex 022cd74..f381ec5 100644 --- a/fatfs/documents/res/funcs.png +++ b/fatfs/documents/res/funcs.png diff --git a/fatfs/documents/res/layers2.png b/fatfs/documents/res/layers2.png Binary files differindex 406c453..c7dbef4 100644 --- a/fatfs/documents/res/layers2.png +++ b/fatfs/documents/res/layers2.png diff --git a/fatfs/documents/res/mkfatimg.zip b/fatfs/documents/res/mkfatimg.zip Binary files differindex 67d423b..63e6ad7 100644 --- a/fatfs/documents/res/mkfatimg.zip +++ b/fatfs/documents/res/mkfatimg.zip diff --git a/fatfs/documents/res/mkfs.xls b/fatfs/documents/res/mkfs.xls Binary files differdeleted file mode 100644 index ee6b2bf..0000000 --- a/fatfs/documents/res/mkfs.xls +++ /dev/null diff --git a/fatfs/documents/res/mkfs.xlsx b/fatfs/documents/res/mkfs.xlsx Binary files differnew file mode 100644 index 0000000..6024888 --- /dev/null +++ b/fatfs/documents/res/mkfs.xlsx diff --git a/fatfs/documents/res/modules.png b/fatfs/documents/res/modules.png Binary files differindex b1ab987..d7e69a3 100644 --- a/fatfs/documents/res/modules.png +++ b/fatfs/documents/res/modules.png diff --git a/fatfs/documents/res/uniconv.zip b/fatfs/documents/res/uniconv.zip Binary files differnew file mode 100644 index 0000000..be7d84f --- /dev/null +++ b/fatfs/documents/res/uniconv.zip diff --git a/fatfs/documents/updates.html b/fatfs/documents/updates.html new file mode 100644 index 0000000..24b8fd4 --- /dev/null +++ b/fatfs/documents/updates.html @@ -0,0 +1,481 @@ +<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.01//EN" "http://www.w3.org/TR/html4/strict.dtd">
+<html lang="en">
+<head>
+<meta http-equiv="Content-Type" content="text/html; charset=utf-8">
+<meta http-equiv="Content-Style-Type" content="text/css">
+<meta http-equiv="cache-control" content="no-cache">
+<link rel="start" title="Site Top" href="../../">
+<link rel="stylesheet" href="css_e.css" type="text/css" media="screen" title="ELM Default">
+<title>FatFs - Updates and Migration Notes</title>
+</head>
+<body style="max-width: none;">
+<h2>Updates and Migration Notes</h2>
+<table class="lst4">
+<tr><th>Revision</th><th>Updates</th><th>Migration Notes</th></tr>
+<tr>
+<td>R0.15<br>Nov 6, 2022</td>
+<td>
+Changed user provided synchronization functions in order to completely eliminate the platform dependency from FatFs code.<br>
+Fixed a potential error in <tt>f_mount</tt> when <tt>FF_FS_REENTRANT</tt>.<br>
+Fixed file lock control <tt>FF_FS_LOCK</tt> is not mutal excluded when <tt>FF_FS_REENTRANT && FF_VOLUMES > 1</tt> is true.<br>
+Fixed <tt>f_mkfs</tt> creates broken exFAT volume when the size of volume is <tt>>= 2^32</tt> sectors.<br>
+Fixed string functions cannot write the unicode characters not in BMP when <tt>FF_LFN_UNICODE == 2</tt> (UTF-8).<br>
+Fixed a compatibility issue in identification of GPT header.<br>
+</td>
+<td>
+User provided synchronization functions, <tt>ff_cre_syncobj</tt>, <tt>ff_del_syncobj</tt>, <tt>ff_req_grant</tt> and <tt>ff_rel_grant</tt>, needed when <tt>FF_FS_REENTRANT</tt> are replaced with <tt>ff_mutex_create</tt>, <tt>ff_mutex_delete</tt>, <tt>ff_mutex_take</tt> and <tt>ff_mutex_give</tt> respectively. For example, see <tt>ffsystem.c</tt>.<br>
+<tt>FF_SYNC_t</tt> is removed from the configuration options.<br>
+</td>
+</tr>
+<tr>
+<td>R0.14b<br>Apr 17, 2021</td>
+<td>
+Made FatFs uses standard library <tt>string.h</tt> for copy, compare and search instead of built-in string functions.<br>
+Added support for long long integer and floating point to <tt>f_printf</tt>. (<tt>FF_STRF_LLI</tt> and <tt>FF_STRF_FP</tt>)<br>
+Made path name parser ignores the terminating separator to allow <tt>"dir/"</tt>.<br>
+Improved the compatibility in Unix style path name feature.<br>
+Fixed the file gets dead-locked when <tt>f_open</tt> failed with certain conditions. (appeared at R0.12a)<br>
+Fixed <tt>f_mkfs</tt> can create wrong exFAT volume due to a timing dependent error. (appeared at R0.12)<br>
+Fixed code page 855 cannot be set by <tt>f_setcp</tt>. (appeared at R0.13)<br>
+Fixed some compiler warnings.<br>
+</td>
+<td>
+From this revision, FatFs depends on <tt>string.h</tt>.<br>
+</td>
+</tr>
+<tr>
+<td>R0.14a<br>Dec 05, 2020</td>
+<td>
+Limited number of recursive calls in <tt>f_findnext</tt> to prevent stack overflow.<br>
+Fixed old floppy disks formatted with MS-DOS 2.x and 3.x cannot be mounted.<br>
+Fixed some compiler warnings.<br>
+</td>
+<td>
+Number of wildcards in the matching pattern in <tt>f_findfirst</tt> is limited to 4.<br>
+</td>
+</tr>
+<tr>
+<td>R0.14<br>Oct 14, 2019</td>
+<td>
+Added support for 64-bit LBA and GUID partition table (<tt>FF_LBA64</tt>)<br>
+Changed some API functions, <tt>f_mkfs</tt> and <tt>f_fdisk</tt>.<br>
+Fixed <tt>f_open</tt> cannot find the file with file name in length of <tt>FF_MAX_LFN</tt> characters.<br>
+Fixed <tt>f_readdir</tt> cannot retrieve long file names in length of <tt>FF_MAX_LFN - 1</tt> characters.<br>
+Fixed <tt>f_readdir</tt> returns file names with wrong case conversion. (appeared at R0.12)<br>
+Fixed <tt>f_mkfs</tt> can fail to create exFAT volume in the second partition. (appeared at R0.12)<br>
+</td>
+<td>
+Usage of <tt>f_mkfs</tt> and <tt>f_fdisk</tt> is changed and some features are added to these functions.<br>
+</td>
+</tr>
+<tr>
+<td>R0.13c<br>Oct 14, 2018</td>
+<td>
+Supported <tt>stdint.h</tt> for C99 and later. (<tt>integer.h</tt> was included in <tt>ff.h</tt>)<br>
+Fixed reading a directory gets infinite loop when the last directory entry is not empty. (appeared at R0.12)<br>
+Fixed creating a sub-directory in the fragmented sub-directory on the exFAT volume collapses FAT chain of the parent directory. (appeared at R0.12)<br>
+Fixed <tt>f_getcwd</tt> cause output buffer overrun when the buffer has a valid drive number. (appeared at R0.13b)<br>
+</td>
+<td>
+From this revision, FatFs depends on <tt>stdint.h</tt> in C99 or later.<br>
+<tt>integer.h</tt> is removed.<br>
+</td>
+</tr>
+<tr>
+<td>R0.13b<br>Apr 07, 2018</td>
+<td>
+Added support for UTF-32 encoding on the API. (<tt>FF_LFN_UNICODE = 3</tt>)<br>
+Added support for Unix style volume prefix. (<tt>FF_STR_VOLUME_ID = 2</tt>)<br>
+Fixed accesing objects in the exFAT root directory beyond the cluster boundary can fail. (appeared at R0.12c)<br>
+Fixed <tt>f_setlabel</tt> does not reject some invalid characters. (appeared at R0.09b)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.13a<br>Oct 14, 2017</td>
+<td>
+Added support for UTF-8 encoding on the API. (<tt>FF_LFN_UNICODE = 2</tt>)<br>
+Added options for file name output buffer. (<tt>FF_LFN_BUF, FF_SFN_BUF</tt>)<br>
+Added dynamic memory allocation option for working buffer of <tt>f_mkfs</tt> and <tt>f_fdisk</tt>.<br>
+Fixed <tt>f_fdisk</tt> and <tt>f_mkfs</tt> create the partition table with wrong CHS parameters. (appeared at R0.09)<br>
+Fixed <tt>f_unlink</tt> can cause lost clusters at fragmented file on the exFAT volume. (appeared at R0.12c)<br>
+Fixed <tt>f_setlabel</tt> rejects some valid characters for exFAT volume. (appeared at R0.12)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.13<br>May 21, 2017</td>
+<td>
+Prefix of configuration item names are changed from <tt>"_"</tt> to <tt>"FF_"</tt>.<br>
+Added <tt>f_setcp</tt>, run-time code page configuration. (<tt>FF_CODE_PAGE = 0</tt>)<br>
+Improved cluster allocation time on stretch a deep buried cluster chain.<br>
+Improved processing time of <tt>f_mkdir</tt> with large cluster size by using <tt>FF_USE_LFN = 3</tt>.<br>
+Improved exFAT <tt>NoFatChain</tt> flag of the fragmented file to be set after it is truncated and got contiguous.<br>
+Fixed archive attribute is left not set when a file on the exFAT volume is renamed. (appeared at R0.12)<br>
+Fixed exFAT FAT entry can be collapsed when write or lseek operation to the existing file is done. (appeared at R0.12c)<br>
+Fixed creating a file can fail when a new cluster allocation to the exFAT directory occures. (appeared at R0.12c)<br>
+</td>
+<td>
+ASCII only configuration, <tt>FF_CODE_PAGE = 1</tt>, is removed. Use <tt>FF_CODE_PAGE = 437</tt> instead.<br>
+</td>
+</tr>
+<tr>
+<td>R0.12c<br>Mar 04, 2017</td>
+<td>
+Improved write throughput at the fragmented file on the exFAT volume.<br>
+Made memory usage for exFAT be able to be reduced as decreasing <tt>_MAX_LFN</tt>.<br>
+Fixed successive <tt>f_getfree</tt> can return wrong count on the FAT12/16 volume. (appeared at R0.12)<br>
+Fixed configuration option <tt>_VOLUMES</tt> cannot be set 10. (appeared at R0.10c)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.12b<br>Sep 4, 2016</td>
+<td>
+Made <tt>f_rename</tt> be able to rename objects with the same name but case.<br>
+Fixed an error in the case conversion teble of code page 866. (<tt>ff.c</tt>)<br>
+Fixed writing data is truncated at the file offset 4GiB on the exFAT volume. (appeared at R0.12)<br>
+Fixed creating a file in the root directory of exFAT volume can fail. (appeared at R0.12)<br>
+Fixed <tt>f_mkfs</tt> creating exFAT volume with too small cluster size can collapse unallocated memory. (appeared at R0.12a)<br>
+Fixed wrong object name can be returned when read directory at Unicode cfg. (appeared at R0.12)<br>
+Fixed large file allocation/removing on the exFAT volume collapses allocation bitmap. (appeared at R0.12)<br>
+Fixed some internal errors in <tt>f_expand</tt> and <tt>f_lseek.</tt> (appeared at R0.12)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.12a<br>Jul 10, 2016</td>
+<td>
+Added support for creating exFAT volume with some changes of <tt>f_mkfs</tt>.<br>
+Added a file open method <tt>FA_OPEN_APPEND</tt>.<br>
+<tt>f_forward</tt> is available regardless of <tt>_FS_TINY</tt>.<br>
+Fixed <tt>f_mkfs</tt> creates broken volume. (appeared at R0.12)<br>
+Fixed wrong memory read in <tt>create_name</tt>. (appeared at R0.12)<br>
+Fixed compilation fails at some configurations, <tt>_USE_FASTSEEK</tt> and <tt>_USE_FORWARD</tt>.<br>
+</td>
+<td>
+Usage of <tt>f_mkfs</tt> is changed.<br>
+</td>
+</tr>
+<tr>
+<td>R0.12<br>Apr 12, 2016</td>
+<td>
+Added support for exFAT file system. (<tt>_FS_EXFAT</tt>)<br>
+Added <tt>f_expand</tt>. (<tt>_USE_EXPAND</tt>)<br>
+Changed some members in <tt>FINFO</tt> and behavior of <tt>f_readdir</tt>.<br>
+Added a configuration option <tt>_USE_CHMOD</tt>.<br>
+Fixed errors in the case conversion teble of Unicode (<tt>cc*.c</tt>).<br>
+</td>
+<td>
+Usage and members of <tt>FINFO</tt> sructure used in <tt>f_readdir</tt> is changed.<br>
+Dot entries in the sub-directory are never appear in <tt>f_readdir</tt>.<br>
+<tt>".."</tt> does not work as path name in exFAT volume.<br>
+<tt>f_getcwd</tt> does not work in exFAT volume.</br>
+Many members in <tt>FIL</tt> and <tt>DIR</tt> structure are changed.<br>
+To use <tt>f_chmod</tt>, <tt>_USE_CHMOD</tt> needs to be set.<br>
+<tt>_WORD_ACCESS</tt> is removed from the configuration options.<br>
+</td>
+</tr>
+<tr>
+<td>R0.11a<br>Sep 5, 2015</td>
+<td>
+Fixed wrong media change can lead a deadlock at thread-safe configuration.<br>
+Added code page 771, 860, 861, 863, 864, 865 and 869. (<tt>_CODE_PAGE</tt>)<br>
+Fixed errors in the case conversion teble of code page 437 and 850 (<tt>ff.c</tt>).<br>
+Fixed errors in the case conversion teble of Unicode (<tt>cc*.c</tt>).<br>
+</td>
+<td>
+Removed some code pages actually not exist on the standard systems. (<tt>_CODE_PAGE</tt>)<br>
+</td>
+</tr>
+<tr>
+<td>R0.11<br>Feb 9, 2015</td>
+<td>
+Added <tt>f_findfirst</tt> and <tt>f_findnext.</tt> (<tt>_USE_FIND</tt>)<br>
+Fixed <tt>f_unlink</tt> does not remove cluster chain of the file. (appeared at R0.10c)<br>
+Fixed <tt>_FS_NORTC</tt> option does not work properly. (appeared at R0.10c)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.10c<br>Nov 9, 2014</td>
+<td>
+Added a configuration option for the platforms without RTC. (<tt>_FS_NORTC</tt>)<br>
+Fixed volume label created by Mac OS X cannot be retrieved with <tt>f_getlabel</tt>. (appeared at R0.09b)<br>
+Fixed a potential problem of FAT access that can appear on disk error.<br>
+Fixed null pointer dereference on attempting to delete the root direcotry. (appeared at R0.08)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.10b<br>May 19, 2014</td>
+<td>
+Fixed a hard error in the disk I/O layer can collapse the directory entry.<br>
+Fixed LFN entry is not deleted on delete/rename an object with its lossy converted SFN. (appeared at R0.07)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.10a<br>Jan 15, 2014</td>
+<td>
+Added arbitrary strings as drive number in the path name. (<tt>_STR_VOLUME_ID</tt>)<br>
+Added an option for minimum sector size. (<tt>_MIN_SS</tt>)<br>
+2nd argument of <tt>f_rename</tt> can have a drive number and it will be ignored.<br>
+Fixed <tt>f_mount</tt> with forced mount fails when drive number is larger than 0. (appeared at R0.10)<br>
+Fixed <tt>f_close</tt> invalidates the file object without volume lock.<br>
+Fixed volume lock is left acquired after return from <tt>f_closedir</tt>. (appeared at R0.10)<br>
+Fixed creation of a directory entry with LFN fails on too many SFN collisions. (appeared at R0.07)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.10<br>Oct 2, 2013</td>
+<td>
+Added an option for character encoding on the file. (<tt>_STRF_ENCODE</tt>)<br>
+Added f_closedir.<br>
+Added forced full FAT scan option for <tt>f_getfree</tt>. (<tt>_FS_NOFSINFO</tt>)<br>
+Added forced mount option with changes of <tt>f_mount</tt>.<br>
+Improved behavior of volume auto detection.<br>
+Improved write throughput of <tt>f_puts</tt> and <tt>f_printf</tt>.<br>
+Changed argument of <tt>f_chdrive,</tt> <tt>f_mkfs</tt>, <tt>disk_read</tt> and <tt>disk_write</tt>.<br>
+Fixed <tt>f_write</tt> can be truncated when the file size is close to 4 GB.<br>
+Fixed <tt>f_open</tt>, <tt>f_mkdir</tt> and <tt>f_setlabel</tt> can return incorrect result code on error.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.09b<br>Jan 24, 2013</td>
+<td>
+Added <tt>f_getlabel</tt> and <tt>f_setlabel</tt>. (<tt>_USE_LABEL</tt>)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.09a<br>Aug 27, 2012</td>
+<td>
+Fixed assertion failure due to OS/2 EA on FAT12/16 volume.<br>
+Changed file functions reject null object pointer to avoid crash.<br>
+Changed option name <tt>_FS_SHARE</tt> to <tt>_FS_LOCK</tt>.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.09<br>Sep 6, 2011</td>
+<td>
+<tt>f_mkfs</tt> supports multiple partition on a physical drive.<br>
+Added <tt>f_fdisk</tt>. (<tt>_MULTI_PARTITION = 2</tt>)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.08b<br>Jan 15, 2011</td>
+<td>
+Fast seek function is also applied to <tt>f_read</tt> and <tt>f_write</tt>.<br>
+<tt>f_lseek</tt> reports required table size on creating CLMP.<br>
+Extended format syntax of <tt>f_printf</tt>.<br>
+Ignores duplicated directory separators in given path names.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.08a<br>Aug 16, 2010</td>
+<td>
+Added <tt>f_getcwd</tt>. (<tt>_FS_RPATH = 2</tt>)<br>
+Added sector erase function. (<tt>_USE_ERASE</tt>)<br>
+Moved file lock semaphore table from fs object to the bss.<br>
+Fixed <tt>f_mkdir</tt> creates wrong directory on non-LFN cfg when the given name contains <tt>';'</tt>.<br>
+Fixed <tt>f_mkfs</tt> creates wrong FAT32 volume.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.08<br>May 15, 2010</td>
+<td>
+Added an option to <tt>_USE_LFN</tt><br>
+Added support of file lock. (<tt>_FS_SHARE</tt>)<br>
+Added fast seek function. (<tt>_USE_FASTSEEK</tt>)<br>
+Changed a type name on the API, <tt>XCHAR</tt> to <tt>TCHAR</tt>.<br>
+Changed member, <tt>fname</tt>, in the <tt>FILINFO</tt> on Unicode cfg.<br>
+String functions support UTF-8 encoding files on Unicode cfg.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.07e<br>Nov 3, 2009</td>
+<td>
+Separated out configuration options from <tt>ff.h</tt> to <tt>ffconf.h</tt>.<br>
+Added a configuration option, <tt>_LFN_UNICODE</tt>.<br>
+Fixed <tt>f_unlink</tt> fails to remove a sub-dir on <tt>_FS_RPATH</tt>.<br>
+Fixed name matching error on the 13 char boundary.<br>
+Changed <tt>f_readdir</tt> to return the SFN with always upper case on non-LFN cfg.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.07c<br>Jan 21, 2009</td>
+<td>
+Fixed <tt>f_unlink</tt> may return FR_OK on error.<br>
+Fixed wrong cache control in <tt>f_lseek</tt>.<br>
+Added support of relative path.<br>
+Added <tt>f_chdir</tt>.<br>
+Added <tt>f_chdrive</tt>.<br>
+Added proper case conversion to extended characters.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.07a<br>Apr 14, 2009</td>
+<td>
+Separated out OS dependent code on re-entrant configuration.<br>
+Added multiple sector size support.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.07<br>Apr 1, 2009</td>
+<td>
+Merged Tiny-FatFs into FatFs as a buffer configuration option.<br>
+Added support for long file extension.<br>
+Added multiple code page support.<br>
+Added re-entrancy for multitask operation.<br>
+Added auto cluster size selection to <tt>f_mkfs</tt>.<br>
+Added rewind option to <tt>f_readdir</tt>.<br>
+Changed result code of critical errors.<br>
+Renamed string functions to avoid name collision.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.06<br>Apr 1, 2008</td>
+<td>
+Added <tt>f_forward</tt>. (Tiny-FatFs)<br>
+Added string functions: <tt>f_gets</tt>, <tt>f_putc</tt>, <tt>f_puts</tt> and <tt>f_printf</tt>.<br>
+Improved performance of <tt>f_lseek</tt> on moving to the same or following cluster.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.05a<br>Feb 3, 2008</td>
+<td>
+Added <tt>f_truncate</tt>.<br>
+Added <tt>f_utime</tt>.<br>
+Fixed off by one error at FAT sub-type determination.<br>
+Fixed btr in <tt>f_read</tt> can be mistruncated.<br>
+Fixed cached sector is left not flushed when create and close without write.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.05<br>Aug 26, 2007</td>
+<td>
+Changed arguments of <tt>f_read</tt>, <tt>f_write</tt>.<br>
+Changed arguments of <tt>f_mkfs</tt>. (FatFs)<br>
+Fixed <tt>f_mkfs</tt> on FAT32 creates incorrect FSInfo. (FatFs)<br>
+Fixed <tt>f_mkdir</tt> on FAT32 creates broken directory. (FatFs)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.04b<br>May 5, 2007</td>
+<td>
+Added <tt>_USE_NTFLAG</tt> option.<br>
+Added support for FSInfo in FAT32 volume.<br>
+Fixed some problems corresponds to FAT32. (Tiny-FatFs)<br>
+Fixed DBCS name can result <tt>FR_INVALID_NAME</tt>.<br>
+Fixed short seek (<tt><= csize</tt>) collapses the file object.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.04a<br>Apr 1, 2007</td>
+<td>
+Supported multiple partitions on a plysical drive. (FatFs)<br>
+Added minimization level 3.<br>
+Added a capability of extending file size to <tt>f_lseek</tt>.<br>
+Fixed an endian sensitive code in <tt>f_mkfs</tt>. (FatFs)<br>
+Fixed a problem corresponds to FAT32 support. (Tiny-FatFs)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.04<br>Feb 4, 2007</td>
+<td>
+Supported multiple drive system. (FatFs)<br>
+Changed some APIs for multiple drive system.<br>
+Added <tt>f_mkfs</tt>. (FatFs)<br>
+Added <tt>_USE_FAT32</tt> option. (Tiny-FatFs)<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.03a<br>Dec 11, 2006</td>
+<td>
+Improved cluster scan algolithm to write files fast.<br>
+Fixed <tt>f_mkdir</tt> creates broken directory on FAT32.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.03<br>Sep 22, 2006</td>
+<td>
+Added <tt>f_rename</tt>.
+Changed option <tt>_FS_MINIMUM</tt> to <tt>_FS_MINIMIZE</tt>.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.02a<br>Jun 10, 2006</td>
+<td>
+Added a configuration option <tt>_FS_MINIMUM</tt>.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.02<br>Jun 01, 2006</td>
+<td>
+Added FAT12.<br>
+Removed unbuffered mode.<br>
+Fixed a problem on small (<tt><32M</tt>) patition.<br>
+</td>
+<td>
+</td>
+</tr>
+<tr>
+<td>R0.01<br>Apr 29, 2006</td>
+<td>
+First release.<br>
+</td>
+<td>
+</td>
+</tr>
+</table>
+</body>
+</html>
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