mirror of https://github.com/YosysHQ/yosys.git
103 lines
5.1 KiB
TeX
103 lines
5.1 KiB
TeX
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\chapter{Technology Mapping}
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\label{chapter:techmap}
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Previous chapters outlined how HDL code is transformed into an RTL netlist. The
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RTL netlist is still based on abstract coarse-grain cell types like arbitrary
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width adders and even multipliers. This chapter covers how an RTL netlist is
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transformed into a functionally equivialent netlist utililizing the cell types
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available in the target architecture.
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Technology mapping is often performed in two phases. In the first phase RTL cells
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are mapped to an internal library of single-bit cells (see Sec.~\ref{sec:celllib_gates}).
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In the second phase this netlist of internal gate types is transformed to a netlist
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of gates from the target technology library.
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When the target architecture provides coarse-grain cells (such as block ram
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or ALUs), these must be mapped to directly form the RTL netlist, as information
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on the coarse-grain structure of the design is lost when it is mapped to
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bit-width gate types.
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\section{Cell Substitution}
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The simplest form of technology mapping is cell substitution, as performed by
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the {\tt techmap} pass. This pass, when provided with a Verilog file that
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implements the RTL cell types using simpler cells, simply replaces the RTL
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cells with the provided implementation.
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When no map file is provided, {\tt techmap} uses a built-in map file that
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maps the Yosys RTL cell types to the internal gate library used by Yosys.
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The curious reader may find this map file as {\tt techlibs/stdcells.v} in
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the Yosys source tree.
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Additional features have been added to {\tt techmap} to allow for conditional
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mapping of cells (see {\tt help techmap} or Sec.~\ref{cmd:techmap}). This can
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for example be usefull if the target architecture supports hardware multipliers for
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certain bit-widths but not for others.
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A usual synthesis flow would first use the {\tt techmap} pass to directly map
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some RTL cells to coarse-grain cells provided by the target architecture (if
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any) and then use techmap with the built-in default file to map the remaining
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RTL cells to gate logic.
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\section{Subcircuit Substitution}
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Sometimes the target architecture provides cells that are more powerful than
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the RTL cells used by Yosys. For example a cell in the target architecture that can
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calculate the absolute-difference of two numbers does not match any single
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RTL cell type but only combinations of cells.
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For these cases Yosys provides the {\tt extract} pass that can match a given set
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of modules against a design and identify the portions of the design that are
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identical (i.e.~isomorphic subcircuits) to any of the given modules. These
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matched subcircuits are then replaced by instances of the given modules.
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The {\tt extract} pass also finds basic variations of the given modules,
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such as swapped inputs on commutative cell types.
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In addition to this the {\tt extract} pass also has limited support for
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frequent subcircuit mining, i.e.~the process of finding recurring subcircuits
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in the design. This has a few applications, including the design of new
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coarse-grain architectures \cite{intersynthFdlBookChapter}.
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The hard algorithmic work done by the {\tt extract} pass (solving the
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isomorphic subcircuit problem and frequent subcircuit mining) is performed
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using the SubCircuit library that can also be used stand-alone without Yosys
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(see Sec.~\ref{sec:SubCircuit}).
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\section{Gate-Level Technology Mapping}
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\label{sec:techmap_extern}
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On the gate-level the target architecture is usually described by a ``Liberty
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file''. The Liberty file format is an industry standard format that can be
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used to describe the behaviour and other properties of standard library cells
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\citeweblink{LibertyFormat}.
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Mapping a design utilizing the Yosys internal gate library (e.g.~as a result
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of mapping it to this representation using the {\tt techmap} pass) is
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performed in two phases.
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First the register cells must be mapped to the registers that are available
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on the target architectures. The target architecture might not provide all
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variations of d-type flip-flops with positive and negative clock edge,
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high-active and low-active asynchronous set and/or reset, etc. Therefore the
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process of mapping the registers might add additional inverters to the design
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and thus it is important to map the register cells first.
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Mapping of the register cells may be performed by using the {\tt dfflibmap}
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pass. This pass expects a Liberty file as argument (using the {\tt -liberty}
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option) and only uses the register cells from the Liberty file.
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Secondly the combinational logic must be mapped to the target architecture.
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This is done using the external program ABC \citeweblink{ABC} via the
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{\tt abc} pass by using the {\tt -liberty} option to the pass. Note that
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in this case only the combinatorial cells are used from the cell library.
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Occasionally Liberty files contain trade secrets (such as sensitive timing
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information) that cannot be shared freely. This complicates processes such as
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reporting bugs in the tools involved. When the information in the Liberty file
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used by Yosys and ABC are not part of the sensitive information, the additional
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tool {\tt yosys-filterlib} (see Sec.~\ref{sec:filterlib}) can be used to strip
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the sensitive information from the Liberty file.
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