734 lines
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734 lines
25 KiB
HTML
<HTML>
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<HEAD>
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<TITLE>
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Using The TIFF Library
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</TITLE>
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</HEAD>
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<BODY BGCOLOR=WHITE>
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<FONT FACE="Arial, Helvetica, Sans">
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<H1>
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<IMG SRC=images/cat.gif WIDTH=113 HEIGHT=146 BORDER=2 ALIGN=left HSPACE=6>
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Using The TIFF Library
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</H1>
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<P>
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<TT>libtiff</TT> is a set of C functions (a library) that support
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the manipulation of TIFF image files.
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The library requires an ANSI C compilation environment for building
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and presumes an ANSI C environment for use.
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<P>
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<TT>libtiff</TT>
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provides interfaces to image data at several layers of abstraction (and cost).
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At the highest level image data can be read into an 8-bit/sample,
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ABGR pixel raster format without regard for the underlying data organization,
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colorspace, or compression scheme. Below this high-level interface
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the library provides scanline-, strip-, and tile-oriented interfaces that
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return data decompressed but otherwise untransformed. These interfaces
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require that the application first identify the organization of stored
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data and select either a strip-based or tile-based API for manipulating
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data. At the lowest level the library
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provides access to the raw uncompressed strips or tiles,
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returning the data exactly as it appears in the file.
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<P>
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The material presented in this chapter is a basic introduction
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to the capabilities of the library; it is not an attempt to describe
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everything a developer needs to know about the library or about TIFF.
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Detailed information on the interfaces to the library are given in
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the <A HREF="http://www.libtiff.org/man/index.html">
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UNIX manual pages</A> that accompany this software.
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<P>Michael Still has also written a useful introduction to libtiff for the
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IBM DeveloperWorks site available at
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<a href="http://www.ibm.com/developerworks/linux/library/l-libtiff">
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http://www.ibm.com/developerworks/linux/library/l-libtiff</a>.
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<P>
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The following sections are found in this chapter:
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<UL>
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<LI><A HREF=#Version>How to tell which version you have</A>
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<LI><A HREF=#Typedefs>Library Datatypes</A>
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<LI><A HREF=#Mman>Memory Management</A>
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<LI><A HREF=#Errors>Error Handling</A>
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<LI><A HREF=#FIO>Basic File Handling</A>
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<LI><A HREF=#Dirs>TIFF Directories</A>
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<LI><A HREF=#Tags>TIFF Tags</A>
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<LI><A HREF=#Compression>TIFF Compression Schemes</A>
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<LI><A HREF=#ByteOrder>Byte Order</A>
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<LI><A HREF=#DataPlacement>Data Placement</A>
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<LI><A HREF=#TIFFRGBAImage>TIFFRGBAImage Support</A>
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<LI><A HREF=#Scanlines>Scanline-based Image I/O</A>
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<LI><A HREF=#Strips>Strip-oriented Image I/O</A>
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<LI><A HREF=#Tiles>Tile-oriented Image I/O</A>
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<LI><A HREF=#Other>Other Stuff</A>
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</UL>
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<A NAME="Version"><P><HR WIDTH=65% ALIGN=right><H3>How to tell which version you have</H3></A>
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The software version can be found by looking at the file named
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<TT>VERSION</TT>
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that is located at the top of the source tree; the precise alpha number
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is given in the file <TT>dist/tiff.alpha</TT>.
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If you have need to refer to this
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specific software, you should identify it as:
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<PRE>
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TIFF <<I>version</I>> <<I>alpha</I>>
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</PRE>
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where <<I>version</I>> is whatever you get from
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<KBD>"cat VERSION"</KBD> and <<I>alpha</I>> is
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what you get from <KBD>"cat dist/tiff.alpha"</KBD>.
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<P>
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Within an application that uses <TT>libtiff</TT> the <TT>TIFFGetVersion</TT>
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routine will return a pointer to a string that contains software version
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information.
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The library include file <TT><tiffio.h></TT> contains a C pre-processor
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define <TT>TIFFLIB_VERSION</TT> that can be used to check library
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version compatiblity at compile time.
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<A NAME="Typedefs"><P><HR WIDTH=65% ALIGN=right><H3>Library Datatypes</H3></A>
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<TT>libtiff</TT> defines a portable programming interface through the
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use of a set of C type definitions.
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These definitions, defined in in the files <B>tiff.h</B> and
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<B>tiffio.h</B>,
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isolate the <TT>libtiff</TT> API from the characteristics
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of the underlying machine.
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To insure portable code and correct operation, applications that use
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<TT>libtiff</TT> should use the typedefs and follow the function
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prototypes for the library API.
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<A NAME="Mman"><P><HR WIDTH=65% ALIGN=right><H3>Memory Management</H3></A>
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<TT>libtiff</TT> uses a machine-specific set of routines for managing
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dynamically allocated memory.
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<TT>_TIFFmalloc</TT>, <TT>_TIFFrealloc</TT>, and <TT>_TIFFfree</TT>
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mimic the normal ANSI C routines.
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Any dynamically allocated memory that is to be passed into the library
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should be allocated using these interfaces in order to insure pointer
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compatibility on machines with a segmented architecture.
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(On 32-bit UNIX systems these routines just call the normal <TT>malloc</TT>,
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<TT>realloc</TT>, and <TT>free</TT> routines in the C library.)
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<P>
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To deal with segmented pointer issues <TT>libtiff</TT> also provides
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<TT>_TIFFmemcpy</TT>, <TT>_TIFFmemset</TT>, and <TT>_TIFFmemmove</TT>
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routines that mimic the equivalent ANSI C routines, but that are
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intended for use with memory allocated through <TT>_TIFFmalloc</TT>
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and <TT>_TIFFrealloc</TT>.
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<A NAME="Errors"><P><HR WIDTH=65% ALIGN=right><H3>Error Handling</H3></A>
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<TT>libtiff</TT> handles most errors by returning an invalid/erroneous
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value when returning from a function call.
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Various diagnostic messages may also be generated by the library.
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All error messages are directed to a single global error handler
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routine that can be specified with a call to <TT>TIFFSetErrorHandler</TT>.
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Likewise warning messages are directed to a single handler routine
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that can be specified with a call to <TT>TIFFSetWarningHandler</TT>
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<A NAME="FIO"><P><HR WIDTH=65% ALIGN=right><H3>Basic File Handling</H3></A>
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The library is modeled after the normal UNIX stdio library.
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For example, to read from an existing TIFF image the
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file must first be opened:
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<UL><PRE>
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#include "tiffio.h"
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main()
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{
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TIFF* tif = TIFFOpen("foo.tif", "r");
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... do stuff ...
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TIFFClose(tif);
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}
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</PRE></UL>
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The handle returned by <TT>TIFFOpen</TT> is <I>opaque</I>, that is
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the application is not permitted to know about its contents.
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All subsequent library calls for this file must pass the handle
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as an argument.
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<P>
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To create or overwrite a TIFF image the file is also opened, but with
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a <TT>"w"</TT> argument:
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<UL><PRE>
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#include "tiffio.h"
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main()
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{
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TIFF* tif = TIFFOpen("foo.tif", "w");
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... do stuff ...
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TIFFClose(tif);
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}
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</PRE></UL>
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If the file already exists it is first truncated to zero length.
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<P>
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<IMG SRC=images/warning.gif ALIGN=left HSPACE=6>
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<EM>Note that unlike the stdio library TIFF image files may not be
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opened for both reading and writing;
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there is no support for altering the contents of a TIFF file.
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</EM>
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<P>
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<TT>libtiff</TT> buffers much information associated with writing a
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valid TIFF image. Consequently, when writing a TIFF image it is necessary
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to always call <TT>TIFFClose</TT> or <TT>TIFFFlush</TT> to flush any
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buffered information to a file. Note that if you call <TT>TIFFClose</TT>
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you do not need to call <TT>TIFFFlush</TT>.
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<A NAME="Dirs"><P><HR WIDTH=65% ALIGN=right><H3>TIFF Directories</H3></A>
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TIFF supports the storage of multiple images in a single file.
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Each image has an associated data structure termed a <I>directory</I>
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that houses all the information about the format and content of the
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image data.
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Images in a file are usually related but they do not need to be; it
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is perfectly alright to store a color image together with a black and
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white image.
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Note however that while images may be related their directories are
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not.
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That is, each directory stands on its own; their is no need to read
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an unrelated directory in order to properly interpret the contents
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of an image.
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<P>
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<TT>libtiff</TT> provides several routines for reading and writing
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directories. In normal use there is no need to explicitly
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read or write a directory: the library automatically reads the first
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directory in a file when opened for reading, and directory information
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to be written is automatically accumulated and written when writing
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(assuming <TT>TIFFClose</TT> or <TT>TIFFFlush</TT> are called).
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<P>
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For a file open for reading the <TT>TIFFSetDirectory</TT> routine can
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be used to select an arbitrary directory; directories are referenced by
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number with the numbering starting at 0. Otherwise the
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<TT>TIFFReadDirectory</TT> and <TT>TIFFWriteDirectory</TT> routines can
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be used for sequential access to directories.
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For example, to count the number of directories in a file the following
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code might be used:
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<UL><PRE>
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#include "tiffio.h"
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main(int argc, char* argv[])
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{
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TIFF* tif = TIFFOpen(argv[1], "r");
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if (tif) {
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int dircount = 0;
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do {
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dircount++;
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} while (TIFFReadDirectory(tif));
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printf("%d directories in %s\n", dircount, argv[1]);
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TIFFClose(tif);
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}
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exit(0);
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}
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</PRE></UL>
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<P>
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Finally, note that there are several routines for querying the
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directory status of an open file:
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<TT>TIFFCurrentDirectory</TT> returns the index of the current
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directory and
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<TT>TIFFLastDirectory</TT> returns an indication of whether the
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current directory is the last directory in a file.
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There is also a routine, <TT>TIFFPrintDirectory</TT>, that can
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be called to print a formatted description of the contents of
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the current directory; consult the manual page for complete details.
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<A NAME="Tags"><P><HR WIDTH=65% ALIGN=right><H3>TIFF Tags</H3></A>
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Image-related information such as the image width and height, number
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of samples, orientation, colorimetric information, etc.
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are stored in each image
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directory in <I>fields</I> or <I>tags</I>.
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Tags are identified by a number that is usually a value registered
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with the Aldus (now Adobe) Corporation.
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Beware however that some vendors write
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TIFF images with tags that are unregistered; in this case interpreting
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their contents is usually a waste of time.
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<P>
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<TT>libtiff</TT> reads the contents of a directory all at once
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and converts the on-disk information to an appropriate in-memory
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form. While the TIFF specification permits an arbitrary set of
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tags to be defined and used in a file, the library only understands
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a limited set of tags.
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Any unknown tags that are encountered in a file are ignored.
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There is a mechanism to extend the set of tags the library handles
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without modifying the library itself;
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this is described <A HREF=../contrib/tags/README>elsewhere</A>.
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<P>
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<TT>libtiff</TT> provides two interfaces for getting and setting tag
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values: <TT>TIFFGetField</TT> and <TT>TIFFSetField</TT>.
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These routines use a variable argument list-style interface to pass
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parameters of different type through a single function interface.
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The <I>get interface</I> takes one or more pointers to memory locations
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where the tag values are to be returned and also returns one or
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zero according to whether the requested tag is defined in the directory.
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The <I>set interface</I> takes the tag values either by-reference or
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by-value.
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The TIFF specification defines
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<I>default values</I> for some tags.
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To get the value of a tag, or its default value if it is undefined,
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the <TT>TIFFGetFieldDefaulted</TT> interface may be used.
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<P>
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The manual pages for the tag get and set routines specifiy the exact data types
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and calling conventions required for each tag supported by the library.
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<A NAME="Compression"><P><HR WIDTH=65% ALIGN=right><H3>TIFF Compression Schemes</H3></A>
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<TT>libtiff</TT> includes support for a wide variety of
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data compression schemes.
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In normal operation a compression scheme is automatically used when
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the TIFF <TT>Compression</TT> tag is set, either by opening a file
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for reading, or by setting the tag when writing.
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<P>
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Compression schemes are implemented by software modules termed <I>codecs</I>
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that implement decoder and encoder routines that hook into the
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core library i/o support.
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Codecs other than those bundled with the library can be registered
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for use with the <TT>TIFFRegisterCODEC</TT> routine.
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This interface can also be used to override the core-library
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implementation for a compression scheme.
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<A NAME="ByteOrder"><P><HR WIDTH=65% ALIGN=right><H3>Byte Order</H3></A>
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The TIFF specification says, and has always said, that
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<EM>a correct TIFF
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reader must handle images in big-endian and little-endian byte order</EM>.
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<TT>libtiff</TT> conforms in this respect.
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Consequently there is no means to force a specific
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byte order for the data written to a TIFF image file (data is
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written in the native order of the host CPU unless appending to
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an existing file, in which case it is written in the byte order
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specified in the file).
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<A NAME="DataPlacement"><P><HR WIDTH=65% ALIGN=right><H3>Data Placement</H3></A>
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The TIFF specification requires that all information except an
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8-byte header can be placed anywhere in a file.
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In particular, it is perfectly legitimate for directory information
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to be written after the image data itself.
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Consequently TIFF is inherently not suitable for passing through a
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stream-oriented mechanism such as UNIX pipes.
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Software that require that data be organized in a file in a particular
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order (e.g. directory information before image data) does not
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correctly support TIFF.
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<TT>libtiff</TT> provides no mechanism for controlling the placement
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of data in a file; image data is typically written before directory
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information.
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<A NAME="TIFFRGBAImage"><P><HR WIDTH=65% ALIGN=right><H3>TIFFRGBAImage Support</H3></A>
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<TT>libtiff</TT> provides a high-level interface for reading image
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data from a TIFF file. This interface handles the details of
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data organization and format for a wide variety of TIFF files;
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at least the large majority of those files that one would normally
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encounter. Image data is, by default, returned as ABGR
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pixels packed into 32-bit words (8 bits per sample). Rectangular
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rasters can be read or data can be intercepted at an intermediate
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level and packed into memory in a format more suitable to the
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application.
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The library handles all the details of the format of data stored on
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disk and, in most cases, if any colorspace conversions are required:
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bilevel to RGB, greyscale to RGB, CMYK to RGB, YCbCr to RGB, 16-bit
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samples to 8-bit samples, associated/unassociated alpha, etc.
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<P>
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There are two ways to read image data using this interface. If
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all the data is to be stored in memory and manipulated at once,
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then the routine <TT>TIFFReadRGBAImage</TT> can be used:
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<UL><PRE>
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#include "tiffio.h"
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main(int argc, char* argv[])
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{
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TIFF* tif = TIFFOpen(argv[1], "r");
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if (tif) {
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uint32 w, h;
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size_t npixels;
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uint32* raster;
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TIFFGetField(tif, TIFFTAG_IMAGEWIDTH, &w);
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TIFFGetField(tif, TIFFTAG_IMAGELENGTH, &h);
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npixels = w * h;
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raster = (uint32*) _TIFFmalloc(npixels * sizeof (uint32));
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if (raster != NULL) {
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if (TIFFReadRGBAImage(tif, w, h, raster, 0)) {
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...process raster data...
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}
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_TIFFfree(raster);
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}
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TIFFClose(tif);
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}
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exit(0);
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}
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</PRE></UL>
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Note above that <TT>_TIFFmalloc</TT> is used to allocate memory for
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the raster passed to <TT>TIFFReadRGBAImage</TT>; this is important
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to insure the ``appropriate type of memory'' is passed on machines
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with segmented architectures.
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<P>
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Alternatively, <TT>TIFFReadRGBAImage</TT> can be replaced with a
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more low-level interface that permits an application to have more
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control over this reading procedure. The equivalent to the above
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is:
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<UL><PRE>
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#include "tiffio.h"
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main(int argc, char* argv[])
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{
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TIFF* tif = TIFFOpen(argv[1], "r");
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if (tif) {
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TIFFRGBAImage img;
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char emsg[1024];
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if (TIFFRGBAImageBegin(&img, tif, 0, emsg)) {
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size_t npixels;
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uint32* raster;
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npixels = img.width * img.height;
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raster = (uint32*) _TIFFmalloc(npixels * sizeof (uint32));
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if (raster != NULL) {
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if (TIFFRGBAImageGet(&img, raster, img.width, img.height)) {
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...process raster data...
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}
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_TIFFfree(raster);
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}
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TIFFRGBAImageEnd(&img);
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} else
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TIFFError(argv[1], emsg);
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TIFFClose(tif);
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}
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exit(0);
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}
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</PRE></UL>
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However this usage does not take advantage of the more fine-grained
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control that's possible. That is, by using this interface it is
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possible to:
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<UL>
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<LI>repeatedly fetch (and manipulate) an image without opening
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and closing the file
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<LI>interpose a method for packing raster pixel data according to
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application-specific needs (or write the data at all)
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<LI>interpose methods that handle TIFF formats that are not already
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handled by the core library
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</UL>
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The first item means that, for example, image viewers that want to
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handle multiple files can cache decoding information in order to
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speedup the work required to display a TIFF image.
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<P>
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The second item is the main reason for this interface. By interposing
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a ``put method'' (the routine that is called to pack pixel data in
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the raster) it is possible share the core logic that understands how
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to deal with TIFF while packing the resultant pixels in a format that
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is optimized for the application. This alternate format might be very
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different than the 8-bit per sample ABGR format the library writes by
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default. For example, if the application is going to display the image
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on an 8-bit colormap display the put routine might take the data and
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convert it on-the-fly to the best colormap indices for display.
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<P>
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The last item permits an application to extend the library
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without modifying the core code.
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By overriding the code provided an application might add support
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for some esoteric flavor of TIFF that it needs, or it might
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substitute a packing routine that is able to do optimizations
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using application/environment-specific information.
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<P>
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The TIFF image viewer found in <B>tools/sgigt.c</B> is an example
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of an application that makes use of the <TT>TIFFRGBAImage</TT>
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support.
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<A NAME="Scanlines"><P><HR WIDTH=65% ALIGN=right><H3>Scanline-based Image I/O</H3></A>
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The simplest interface provided by <TT>libtiff</TT> is a
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scanline-oriented interface that can be used to read TIFF
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images that have their image data organized in strips
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(trying to use this interface to read data written in tiles
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will produce errors.)
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A scanline is a one pixel high row of image data whose width
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is the width of the image.
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Data is returned packed if the image data is stored with samples
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packed together, or as arrays of separate samples if the data
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is stored with samples separated.
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The major limitation of the scanline-oriented interface, other
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than the need to first identify an existing file as having a
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suitable organization, is that random access to individual
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scanlines can only be provided when data is not stored in a
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compressed format, or when the number of rows in a strip
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of image data is set to one (<TT>RowsPerStrip</TT> is one).
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<P>
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Two routines are provided for scanline-based i/o:
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<TT>TIFFReadScanline</TT>
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and
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<TT>TIFFWriteScanline</TT>.
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For example, to read the contents of a file that
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is assumed to be organized in strips, the following might be used:
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<UL><PRE>
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#include "tiffio.h"
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main()
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{
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TIFF* tif = TIFFOpen("myfile.tif", "r");
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if (tif) {
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uint32 imagelength;
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tdata_t buf;
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uint32 row;
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TIFFGetField(tif, TIFFTAG_IMAGELENGTH, &imagelength);
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buf = _TIFFmalloc(TIFFScanlineSize(tif));
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for (row = 0; row < imagelength; row++)
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TIFFReadScanline(tif, buf, row);
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_TIFFfree(buf);
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TIFFClose(tif);
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}
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}
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</PRE></UL>
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<TT>TIFFScanlineSize</TT> returns the number of bytes in
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a decoded scanline, as returned by <TT>TIFFReadScanline</TT>.
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Note however that if the file had been create with samples
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written in separate planes, then the above code would only
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read data that contained the first sample of each pixel;
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to handle either case one might use the following instead:
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<UL><PRE>
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#include "tiffio.h"
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main()
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{
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TIFF* tif = TIFFOpen("myfile.tif", "r");
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if (tif) {
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uint32 imagelength;
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tdata_t buf;
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uint32 row;
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TIFFGetField(tif, TIFFTAG_IMAGELENGTH, &imagelength);
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TIFFGetField(tif, TIFFTAG_PLANARCONFIG, &config);
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buf = _TIFFmalloc(TIFFScanlineSize(tif));
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if (config == PLANARCONFIG_CONTIG) {
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for (row = 0; row < imagelength; row++)
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TIFFReadScanline(tif, buf, row);
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} else if (config == PLANARCONFIG_SEPARATE) {
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uint16 s, nsamples;
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TIFFGetField(tif, TIFFTAG_SAMPLESPERPIXEL, &nsamples);
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for (s = 0; s < nsamples; s++)
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for (row = 0; row < imagelength; row++)
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TIFFReadScanline(tif, buf, row, s);
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}
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_TIFFfree(buf);
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TIFFClose(tif);
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}
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}
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</PRE></UL>
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Beware however that if the following code were used instead to
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read data in the case <TT>PLANARCONFIG_SEPARATE</TT>,
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<UL><PRE>
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for (row = 0; row < imagelength; row++)
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for (s = 0; s < nsamples; s++)
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TIFFReadScanline(tif, buf, row, s);
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</PRE></UL>
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then problems would arise if <TT>RowsPerStrip</TT> was not one
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because the order in which scanlines are requested would require
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random access to data within strips (something that is not supported
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by the library when strips are compressed).
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<A NAME="Strips"><P><HR WIDTH=65% ALIGN=right><H3>Strip-oriented Image I/O</H3></A>
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The strip-oriented interfaces provided by the library provide
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access to entire strips of data. Unlike the scanline-oriented
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calls, data can be read or written compressed or uncompressed.
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Accessing data at a strip (or tile) level is often desirable
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because there are no complications with regard to random access
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to data within strips.
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<P>
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A simple example of reading an image by strips is:
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<UL><PRE>
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#include "tiffio.h"
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main()
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{
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TIFF* tif = TIFFOpen("myfile.tif", "r");
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if (tif) {
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tdata_t buf;
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tstrip_t strip;
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buf = _TIFFmalloc(TIFFStripSize(tif));
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for (strip = 0; strip < TIFFNumberOfStrips(tif); strip++)
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TIFFReadEncodedStrip(tif, strip, buf, (tsize_t) -1);
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_TIFFfree(buf);
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TIFFClose(tif);
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}
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}
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</PRE></UL>
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Notice how a strip size of <TT>-1</TT> is used; <TT>TIFFReadEncodedStrip</TT>
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will calculate the appropriate size in this case.
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<P>
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The above code reads strips in the order in which the
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data is physically stored in the file. If multiple samples
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are present and data is stored with <TT>PLANARCONFIG_SEPARATE</TT>
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then all the strips of data holding the first sample will be
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read, followed by strips for the second sample, etc.
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<P>
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Finally, note that the last strip of data in an image may have fewer
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rows in it than specified by the <TT>RowsPerStrip</TT> tag. A
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reader should not assume that each decoded strip contains a full
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set of rows in it.
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<P>
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The following is an example of how to read raw strips of data from
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a file:
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<UL><PRE>
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#include "tiffio.h"
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main()
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{
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TIFF* tif = TIFFOpen("myfile.tif", "r");
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if (tif) {
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tdata_t buf;
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tstrip_t strip;
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uint32* bc;
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uint32 stripsize;
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TIFFGetField(tif, TIFFTAG_STRIPBYTECOUNTS, &bc);
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stripsize = bc[0];
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buf = _TIFFmalloc(stripsize);
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for (strip = 0; strip < TIFFNumberOfStrips(tif); strip++) {
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if (bc[strip] > stripsize) {
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buf = _TIFFrealloc(buf, bc[strip]);
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stripsize = bc[strip];
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}
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TIFFReadRawStrip(tif, strip, buf, bc[strip]);
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}
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_TIFFfree(buf);
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TIFFClose(tif);
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}
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}
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</PRE></UL>
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As above the strips are read in the order in which they are
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physically stored in the file; this may be different from the
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logical ordering expected by an application.
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<A NAME="Tiles"><P><HR WIDTH=65% ALIGN=right><H3>Tile-oriented Image I/O</H3></A>
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Tiles of data may be read and written in a manner similar to strips.
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With this interface, an image is
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broken up into a set of rectangular areas that may have dimensions
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less than the image width and height. All the tiles
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in an image have the same size, and the tile width and length must each
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be a multiple of 16 pixels. Tiles are ordered left-to-right and
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top-to-bottom in an image. As for scanlines, samples can be packed
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contiguously or separately. When separated, all the tiles for a sample
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are colocated in the file. That is, all the tiles for sample 0 appear
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before the tiles for sample 1, etc.
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<P>
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Tiles and strips may also be extended in a z dimension to form
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volumes. Data volumes are organized as "slices". That is, all the
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data for a slice is colocated. Volumes whose data is organized in
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tiles can also have a tile depth so that data can be organized in
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cubes.
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<P>
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There are actually two interfaces for tiles.
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One interface is similar to scanlines, to read a tiled image,
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code of the following sort might be used:
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<UL><PRE>
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main()
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{
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TIFF* tif = TIFFOpen("myfile.tif", "r");
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if (tif) {
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uint32 imageWidth, imageLength;
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uint32 tileWidth, tileLength;
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uint32 x, y;
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tdata_t buf;
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TIFFGetField(tif, TIFFTAG_IMAGEWIDTH, &imageWidth);
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TIFFGetField(tif, TIFFTAG_IMAGELENGTH, &imageLength);
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TIFFGetField(tif, TIFFTAG_TILEWIDTH, &tileWidth);
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TIFFGetField(tif, TIFFTAG_TILELENGTH, &tileLength);
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buf = _TIFFmalloc(TIFFTileSize(tif));
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for (y = 0; y < imageLength; y += tileLength)
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for (x = 0; x < imageWidth; x += tileWidth)
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TIFFReadTile(tif, buf, x, y, 0);
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_TIFFfree(buf);
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TIFFClose(tif);
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}
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}
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</PRE></UL>
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(once again, we assume samples are packed contiguously.)
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<P>
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Alternatively a direct interface to the low-level data is provided
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a la strips. Tiles can be read with
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<TT>TIFFReadEncodedTile</TT> or
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<TT>TIFFReadRawTile</TT>,
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and written with
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<TT>TIFFWriteEncodedTile</TT> or
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<TT>TIFFWriteRawTile</TT>.
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For example, to read all the tiles in an image:
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<UL><PRE>
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#include "tiffio.h"
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main()
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{
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TIFF* tif = TIFFOpen("myfile.tif", "r");
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if (tif) {
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tdata_t buf;
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ttile_t tile;
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buf = _TIFFmalloc(TIFFTileSize(tif));
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for (tile = 0; tile < TIFFNumberOfTiles(tif); tile++)
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TIFFReadEncodedTile(tif, tile, buf, (tsize_t) -1);
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_TIFFfree(buf);
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TIFFClose(tif);
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}
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}
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</PRE></UL>
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<A NAME="Other"><P><HR WIDTH=65% ALIGN=right><H3>Other Stuff</H3></A>
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<P>
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<I>Some other stuff will almost certainly go here...</I>
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<P>
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<HR>
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Last updated: $Date: 2004-02-19 07:47:59 $
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