61 lines
3.1 KiB
Plaintext
61 lines
3.1 KiB
Plaintext
/*! \page dtr DTR Format
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\section dtrPres Presentation
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The <b>Design Technology Rules (DTR)</b> format was developped as a part of the Chams Project (http://www-soc.lip6.fr/recherche/cian/chams/). It aims at offering a generic description of layout design rules for CMOS technologies.\n
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\subsection dtrAutrhos Author
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Damien Dupuis: damien.dupuis(at)lip6(.)fr
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\subsection dtrLimits Limitations
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Only simple rules are supported at the moment. For example the minimum width of a metal layer has only one value, although it should depends on the length of the wire drawned.
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\section dtrDB Stand alone database structure
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The database contains four object :
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- DTR::Techno contains generic informations such as the name of the technology and the unit used, and the list of all technologic rules.
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- DTR::Rule & DTR::ARule respectively describe a symmetrical and an asymmetrical rule.
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- DTR::Name provides an automatic management of shared name.
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The library also use the DTR::DTRException class to throw excptions.
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\subsection dtrParser Using the parser
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Simply load a technology with static function DTR::Techno::readFromFile() and then get rules (DTR::Techno::getRule()) or directly values (DTR::Techno::getValue()).
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\subsection dtrDriver Using the driver
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Using the driver is very simple, user has to create a DTR::Techno object and simply add DTR::Rule or DTR::ARule to it.
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The adding methods return the newly created Rule so user can set the rule type (DTR::Rule::setType()) if necessary. Finally use the DTR::Techno::writeToFile() method to dump the database to file.
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\section dtrExamples Examples
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As said is the global presentation, VLSI SAPD project provides C++ libraries and Python modules for each supported format. In this section we present simple code examples to parse and drive a DTR file using C++ or Python. The DTR file considered is the same for all examples: \c example.dtr.xml
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\include example.dtr.xml
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All source codes are available in the \c examples directory.
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\subsection dtrC C++
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\subsubsection dtrParseC Parser
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The following code (\c parseDtr.cpp) is an example of how to parse a DTR file using C++ library.
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\include parseDtr.cpp
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\subsubsection dtrDriveC Driver
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This C++ code (\c driveDtr.cpp) generates a out.dtr.xml file equivalent to the previous example.dtr.xml.
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\include driveDtr.cpp
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\note In order to compile these codes, a CMakeLists.txt file is provided. User must set the $VLSISAPD_TOP variable before running these commands in the directory containing the CMakeLists.txt file:
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\code
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%> mkdir build; cd build
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%> cmake ..
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%> make
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\endcode
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\subsection dtrPython Python
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\subsubsection dtrParsePython Parser
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The following python script (\c parseDtr.py) is an example of how to parse a DTR file using python module.
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\include parseDtr.py
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\subsubsection dtrDrivePython Driver
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This python script (\c driveDtr.py) generates a out.dtr.xml file equivalent to the previous example.dtr.xml.
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\include driveDtr.py
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\note In order to run these two scripts (\c parseDtr.py & driveDtr.py), user must ensure that $PYTHONPATH variable points to the directory containing DTR.so module.
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*/
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