1071 lines
45 KiB
TeX
1071 lines
45 KiB
TeX
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% IEEEtran howto:
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% http://ftp.univie.ac.at/packages/tex/macros/latex/contrib/IEEEtran/IEEEtran_HOWTO.pdf
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\documentclass[9pt,technote,a4paper]{IEEEtran}
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\usepackage[T1]{fontenc} % required for luximono!
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\usepackage[scaled=0.8]{luximono} % typewriter font with bold face
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% getnonfreefonts-sys --all or
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% getnonfreefonts-sys luximono
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\usepackage[unicode,bookmarks=false]{hyperref}
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\usepackage[english]{babel}
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\usepackage[utf8]{inputenc}
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\usepackage{amssymb}
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\usepackage{amsmath}
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\usepackage{amsfonts}
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\usepackage{units}
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\usepackage{nicefrac}
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\usepackage{eurosym}
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\usepackage{graphicx}
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\usepackage{verbatim}
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\usepackage{algpseudocode}
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\usepackage{scalefnt}
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\usepackage{xspace}
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\usepackage{color}
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\usepackage{colortbl}
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\usepackage{multirow}
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\usepackage{hhline}
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\usepackage{listings}
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\usepackage{float}
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\usepackage{tikz}
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\usetikzlibrary{calc}
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\usetikzlibrary{arrows}
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\usetikzlibrary{scopes}
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\usetikzlibrary{through}
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\usetikzlibrary{shapes.geometric}
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\def\FIXME{{\color{red}\bf FIXME}}
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\lstset{basicstyle=\ttfamily,frame=trBL,xleftmargin=0.7cm,xrightmargin=0.2cm,numbers=left}
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\begin{document}
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\title{Yosys Application Note 011: \\ Interactive Design Investigation}
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\author{Clifford Wolf \\ Original Version December 2013}
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\maketitle
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\begin{abstract}
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Yosys \cite{yosys} can be a great environment for building custom synthesis
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flows. It can also be an excellent tool for teaching and learning Verilog based
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RTL synthesis. In both applications it is of great importance to be able to
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analyze the designs it produces easily.
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This Yosys application note covers the generation of circuit diagrams with the
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Yosys {\tt show} command, the selection of interesting parts of the circuit
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using the {\tt select} command, and briefly discusses advanced investigation
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commands for evaluating circuits and solving SAT problems.
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\end{abstract}
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\section{Installation and Prerequisites}
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This Application Note is based on the Yosys \cite{yosys} GIT Rev. {\tt 2b90ba1} from
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2013-12-08. The {\tt README} file covers how to install Yosys. The
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{\tt show} command requires a working installation of GraphViz \cite{graphviz}
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and \cite{xdot} for generating the actual circuit diagrams.
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\section{Overview}
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This application note is structured as follows:
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Sec.~\ref{intro_show} introduces the {\tt show} command and explains the
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symbols used in the circuit diagrams generated by it.
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Sec.~\ref{navigate} introduces additional commands used to navigate in the
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design, select portions of the design, and print additional information on
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the elements in the design that are not contained in the circuit diagrams.
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Sec.~\ref{poke} introduces commands to evaluate the design and solve SAT
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problems within the design.
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Sec.~\ref{conclusion} concludes the document and summarizes the key points.
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\section{Introduction to the {\tt show} command}
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\label{intro_show}
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\begin{figure}[b]
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\begin{lstlisting}
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$ cat example.ys
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read_verilog example.v
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show -pause
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proc
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show -pause
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opt
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show -pause
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$ cat example.v
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module example(input clk, a, b, c,
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output reg [1:0] y);
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always @(posedge clk)
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if (c)
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y <= c ? a + b : 2'd0;
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endmodule
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\end{lstlisting}
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\caption{Yosys script with {\tt show} commands and example design}
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\label{example_src}
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\end{figure}
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\begin{figure}[b!]
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\includegraphics[width=\linewidth]{APPNOTE_011_Design_Investigation/example_00.pdf}
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\includegraphics[width=\linewidth]{APPNOTE_011_Design_Investigation/example_01.pdf}
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\includegraphics[width=\linewidth]{APPNOTE_011_Design_Investigation/example_02.pdf}
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\caption{Output of the three {\tt show} commands from Fig.~\ref{example_src}}
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\label{example_out}
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\end{figure}
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The {\tt show} command generates a circuit diagram for the design in its
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current state. Various options can be used to change the appearance of the
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circuit diagram, set the name and format for the output file, and so forth.
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When called without any special options, it saves the circuit diagram in
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a temporary file and launches {\tt xdot} to display the diagram.
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Subsequent calls to {\tt show} re-use the {\tt xdot} instance
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(if still running).
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\subsection{A simple circuit}
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Fig.~\ref{example_src} shows a simple synthesis script and a Verilog file that
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demonstrate the usage of {\tt show} in a simple setting. Note that {\tt show}
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is called with the {\tt -pause} option, that halts execution of the Yosys
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script until the user presses the Enter key. The {\tt show -pause} command
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also allows the user to enter an interactive shell to further investigate the
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circuit before continuing synthesis.
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So this script, when executed, will show the design after each of the three
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synthesis commands. The generated circuit diagrams are shown in Fig.~\ref{example_out}.
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The first diagram (from top to bottom) shows the design directly after being
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read by the Verilog front-end. Input and output ports are displayed as
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octagonal shapes. Cells are displayed as rectangles with inputs on the left
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and outputs on the right side. The cell labels are two lines long: The first line
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contains a unique identifier for the cell and the second line contains the cell
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type. Internal cell types are prefixed with a dollar sign. The Yosys manual
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contains a chapter on the internal cell library used in Yosys.
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Constants are shown as ellipses with the constant value as label. The syntax
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{\tt <bit\_width>'<bits>} is used for for constants that are not 32-bit wide
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and/or contain bits that are not 0 or 1 (i.e. {\tt x} or {\tt z}). Ordinary
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32-bit constants are written using decimal numbers.
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Single-bit signals are shown as thin arrows pointing from the driver to the
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load. Signals that are multiple bits wide are shown as think arrows.
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Finally {\it processes\/} are shown in boxes with round corners. Processes
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are Yosys' internal representation of the decision-trees and synchronization
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events modelled in a Verilog {\tt always}-block. The label reads {\tt PROC}
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followed by a unique identifier in the first line and contains the source code
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location of the original {\tt always}-block in the 2nd line. Note how the
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multiplexer from the {\tt ?:}-expression is represented as a {\tt \$mux} cell
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but the multiplexer from the {\tt if}-statement is yet still hidden within the
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process.
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\medskip
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The {\tt proc} command transforms the process from the first diagram into a
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multiplexer and a d-type flip-flip, which brings us to the 2nd diagram.
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The Rhombus shape to the right is a dangling wire. (Wire nodes are only shown
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if they are dangling or have ``public'' names, for example names assigned from
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the Verilog input.) Also note that the design now contains two instances of a
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{\tt BUF}-node. This are artefacts left behind by the {\tt proc}-command. It is
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quite usual to see such artefacts after calling commands that perform changes
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in the design, as most commands only care about doing the transformation in the
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least complicated way, not about cleaning up after them. The next call to {\tt
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clean} (or {\tt opt}, which includes {\tt clean} as one of its operations) will
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clean up this artefacts. This operation is so common in Yosys scripts that it
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can simply be abbreviated with the {\tt ;;} token, which doubles as
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separator for commands. Unless one wants to specifically analyze this artefacts
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left behind some operations, it is therefore recommended to always call {\tt clean}
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before calling {\tt show}.
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\medskip
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In this script we directly call {\tt opt} as next step, which finally leads us to
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the 3rd diagram in Fig.~\ref{example_out}. Here we see that the {\tt opt} command
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not only has removed the artifacts left behind by {\tt proc}, but also determined
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correctly that it can remove the first {\tt \$mux} cell without changing the behavior
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of the circuit.
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\begin{figure}[b!]
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\includegraphics[width=\linewidth,trim=0 2cm 0 0]{APPNOTE_011_Design_Investigation/splice.pdf}
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\caption{Output of {\tt yosys -p 'proc; opt; show' splice.v}}
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\label{splice_dia}
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\end{figure}
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\begin{figure}[b!]
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\lstinputlisting{APPNOTE_011_Design_Investigation/splice.v}
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\caption{\tt splice.v}
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\label{splice_src}
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\end{figure}
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\begin{figure}[t!]
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\includegraphics[height=\linewidth]{APPNOTE_011_Design_Investigation/cmos_00.pdf}
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\includegraphics[width=\linewidth]{APPNOTE_011_Design_Investigation/cmos_01.pdf}
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\caption{Effects of {\tt splitnets} command and of providing a cell library. (The
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circuit is a half-adder built from simple CMOS gates.)}
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\label{splitnets_libfile}
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\end{figure}
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\subsection{Break-out boxes for signal vectors}
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As has been indicated by the last example, Yosys is can manage signal vectors (aka.
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multi-bit wires or buses) as native objects. This provides great advantages
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when analyzing circuits that operate on wide integers. But it also introduces
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some additional complexity when the individual bits of of a signal vector
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are accessed. The example show in Fig.~\ref{splice_dia} and \ref{splice_src}
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demonstrates how such circuits are visualized by the {\tt show} command.
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The key elements in understanding this circuit diagram are of course the boxes
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with round corners and rows labeled {\tt <MSB\_LEFT>:<LSB\_LEFT> -- <MSB\_RIGHT>:<LSB\_RIGHT>}.
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Each of this boxes has one signal per row on one side and a common signal for all rows on the
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other side. The {\tt <MSB>:<LSB>} tuples specify which bits of the signals are broken out
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and connected. So the top row of the box connecting the signals {\tt a} and {\tt x} indicates
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that the bit 0 (i.e. the range 0:0) from signal {\tt a} is connected to bit 1 (i.e. the range
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1:1) of signal {\tt x}.
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Lines connecting such boxes together and lines connecting such boxes to cell
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ports have a slightly different look to emphasise that they are not actual signal
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wires but a necessity of the graphical representation. This distinction seems
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like a technicality, until one wants to debug a problem related to the way
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Yosys internally represents signal vectors, for example when writing custom
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Yosys commands.
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\subsection{Gate level netlists}
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Finally Fig.~\ref{splitnets_libfile} shows two common pitfalls when working
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with designs mapped to a cell library. The top figure has two problems: First
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Yosys did not have access to the cell library when this diagram was generated,
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resulting in all cell ports defaulting to being inputs. This is why all ports
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are drawn on the left side the cells are awkwardly arranged in a large column.
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Secondly the two-bit vector {\tt y} requires breakout-boxes for its individual
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bits, resulting in an unnecessary complex diagram.
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For the 2nd diagram Yosys has been given a description of the cell library as
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Verilog file containing blackbox modules. There are two ways to load cell
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descriptions into Yosys: First the Verilog file for the cell library can be
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passed directly to the {\tt show} command using the {\tt -lib <filename>}
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option. Secondly it is possible to load cell libraries into the design with
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the {\tt read\_verilog -lib <filename>} command. The 2nd method has the great
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advantage that the library only needs to be loaded once and can then be used
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in all subsequent calls to the {\tt show} command.
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In addition to that, the 2nd diagram was generated after {\tt splitnet -ports}
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was run on the design. This command splits all signal vectors into individual
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signal bits, which is often desirable when looking at gate-level circuits. The
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{\tt -ports} option is required to also split module ports. Per default the
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command only operates on interior signals.
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\subsection{Miscellaneous notes}
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Per default the {\tt show} command outputs a temporary {\tt dot} file and launches
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{\tt xdot} to display it. The options {\tt -format}, {\tt -viewer}
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and {\tt -prefix} can be used to change format, viewer and filename prefix.
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Note that the {\tt pdf} and {\tt ps} format are the only formats that support
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plotting multiple modules in one run.
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In densely connected circuits it is sometimes hard to keep track of the
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individual signal wires. For this cases it can be useful to call {\tt show}
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with the {\tt -colors <integer>} argument, which randomly assigns colors to the
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nets. The integer (> 0) is used as seed value for the random color
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assignments. Sometimes it is necessary it try some values to find an assignment
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of colors that looks good.
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The command {\tt help show} prints a complete listing of all options supported
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by the {\tt show} command.
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\section{Navigating the design}
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\label{navigate}
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Plotting circuit diagrams for entire modules in the design brings us only helps
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in simple cases. For complex modules the generated circuit diagrams are just stupidly big
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and are no help at all. In such cases one first has to select the relevant
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portions of the circuit.
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In addition to {\it what\/} to display one also needs to carefully decide
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{\it when\/} to display it, with respect to the synthesis flow. In general
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it is a good idea to troubleshoot a circuit in the earliest state in which
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a problem can be reproduced. So if, for example, the internal state before calling
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the {\tt techmap} command already fails to verify, it is better to troubleshoot
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the coarse-grain version of the circuit before {\tt techmap} than the gate-level
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circuit after {\tt techmap}.
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\medskip
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Note: It is generally recommended to verify the internal state of a design by
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writing it to a Verilog file using {\tt write\_verilog -noexpr} and using the
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simulation models from {\tt simlib.v} and {\tt simcells.v} from the Yosys data
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directory (as printed by {\tt yosys-config -{}-datdir}).
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\subsection{Interactive Navigation}
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\begin{figure}
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\begin{lstlisting}
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yosys> ls
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1 modules:
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example
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yosys> cd example
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yosys [example]> ls
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7 wires:
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$0\y[1:0]
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$add$example.v:5$2_Y
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a
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b
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c
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clk
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y
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3 cells:
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$add$example.v:5$2
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$procdff$7
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$procmux$5
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\end{lstlisting}
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\caption{Demonstration of {\tt ls} and {\tt cd} using {\tt example.v} from Fig.~\ref{example_src}}
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\label{lscd}
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\end{figure}
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\begin{figure}[b]
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\begin{lstlisting}
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attribute \src "example.v:5"
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cell $add $add$example.v:5$2
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parameter \A_SIGNED 0
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parameter \A_WIDTH 1
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parameter \B_SIGNED 0
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parameter \B_WIDTH 1
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parameter \Y_WIDTH 2
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connect \A \a
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connect \B \b
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connect \Y $add$example.v:5$2_Y
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end
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\end{lstlisting}
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\caption{Output of {\tt dump \$2} using the design from Fig.~\ref{example_src} and Fig.~\ref{example_out}}
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\label{dump2}
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\end{figure}
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Once the right state within the synthesis flow for debugging the circuit has
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been identified, it is recommended to simply add the {\tt shell} command
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to the matching place in the synthesis script. This command will stop the
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synthesis at the specified moment and go to shell mode, where the user can
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interactively enter commands.
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For most cases, the shell will start with the whole design selected (i.e. when
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the synthesis script does not already narrow the selection). The command {\tt
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ls} can now be used to create a list of all modules. The command {\tt cd} can
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be used to switch to one of the modules (type {\tt cd ..} to switch back). Now
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the {\tt ls} command lists the objects within that module. Fig.~\ref{lscd}
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demonstrates this using the design from Fig.~\ref{example_src}.
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There is a thing to note in Fig.~\ref{lscd}: We can see that the cell names
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from Fig.~\ref{example_out} are just abbreviations of the actual cell names,
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namely the part after the last dollar-sign. Most auto-generated names (the ones
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starting with a dollar sign) are rather long and contains some additional
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information on the origin of the named object. But in most cases those names
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can simply be abbreviated using the last part.
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Usually all interactive work is done with one module selected using the {\tt cd}
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command. But it is also possible to work from the design-context ({\tt cd ..}). In
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this case all object names must be prefixed with {\tt <module\_name>/}. For
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example {\tt a*/b*} would refer to all objects whose names start with {\tt b} from
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all modules whose names start with {\tt a}.
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The {\tt dump} command can be used to print all information about an object.
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For example {\tt dump \$2} will print Fig.~\ref{dump2}. This can for example
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be useful to determine the names of nets connected to cells, as the net-names
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are usually suppressed in the circuit diagram if they are auto-generated.
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For the remainder of this document we will assume that the commands are run from
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module-context and not design-context.
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\subsection{Working with selections}
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\begin{figure}[t]
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\includegraphics[width=\linewidth]{APPNOTE_011_Design_Investigation/example_03.pdf}
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\caption{Output of {\tt show} after {\tt select \$2} or {\tt select t:\$add}
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(see also Fig.~\ref{example_out})}
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\label{seladd}
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\end{figure}
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When a module is selected using the {\tt cd} command, all commands (with a few
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exceptions, such as the {\tt read\_*} and {\tt write\_*} commands) operate
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only on the selected module. This can also be useful for synthesis scripts
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where different synthesis strategies should be applied to different modules
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in the design.
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But for most interactive work we want to further narrow the set of selected
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objects. This can be done using the {\tt select} command.
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For example, if the command {\tt select \$2} is executed, a subsequent {\tt show}
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command will yield the diagram shown in Fig.~\ref{seladd}. Note that the nets are
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now displayed in ellipses. This indicates that they are not selected, but only
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shown because the diagram contains a cell that is connected to the net. This
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of course makes no difference for the circuit that is shown, but it can be a useful
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information when manipulating selections.
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Objects can not only be selected by their name but also by other properties.
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For example {\tt select t:\$add} will select all cells of type {\tt \$add}. In
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this case this is also yields the diagram shown in Fig.~\ref{seladd}.
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\begin{figure}[b]
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\lstinputlisting{APPNOTE_011_Design_Investigation/foobaraddsub.v}
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\caption{Test module for operations on selections}
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\label{foobaraddsub}
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\end{figure}
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The output of {\tt help select} contains a complete syntax reference for
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matching different properties.
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Many commands can operate on explicit selections. For example the command {\tt
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dump t:\$add} will print information on all {\tt \$add} cells in the active
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module. Whenever a command has {\tt [selection]} as last argument in its usage
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help, this means that it will use the engine behind the {\tt select} command
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to evaluate additional arguments and use the resulting selection instead of
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the selection created by the last {\tt select} command.
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Normally the {\tt select} command overwrites a previous selection. The
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commands {\tt select -add} and {\tt select -del} can be used to add
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or remove objects from the current selection.
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The command {\tt select -clear} can be used to reset the selection to the
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default, which is a complete selection of everything in the current module.
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\subsection{Operations on selections}
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\begin{figure}[t]
|
|
\lstinputlisting{APPNOTE_011_Design_Investigation/sumprod.v}
|
|
\caption{Another test module for operations on selections}
|
|
\label{sumprod}
|
|
\end{figure}
|
|
|
|
\begin{figure}[b]
|
|
\includegraphics[width=\linewidth]{APPNOTE_011_Design_Investigation/sumprod_00.pdf}
|
|
\caption{Output of {\tt show a:sumstuff} on Fig.~\ref{sumprod}}
|
|
\label{sumprod_00}
|
|
\end{figure}
|
|
|
|
The {\tt select} command is actually much more powerful than it might seem on
|
|
the first glimpse. When it is called with multiple arguments, each argument is
|
|
evaluated and pushed separately on a stack. After all arguments have been
|
|
processed it simply creates the union of all elements on the stack. So the
|
|
following command will select all {\tt \$add} cells and all objects with
|
|
the {\tt foo} attribute set:
|
|
|
|
\begin{verbatim}
|
|
select t:$add a:foo
|
|
\end{verbatim}
|
|
|
|
(Try this with the design shown in Fig.~\ref{foobaraddsub}. Use the {\tt
|
|
select -list} command to list the current selection.)
|
|
|
|
In many cases simply adding more and more stuff to the selection is an
|
|
ineffective way of selecting the interesting part of the design. Special
|
|
arguments can be used to combine the elements on the stack.
|
|
For example the {\tt \%i} arguments pops the last two elements from
|
|
the stack, intersects them, and pushes the result back on the stack. So the
|
|
following command will select all {\$add} cells that have the {\tt foo}
|
|
attribute set:
|
|
|
|
\begin{verbatim}
|
|
select t:$add a:foo %i
|
|
\end{verbatim}
|
|
|
|
The listing in Fig.~\ref{sumprod} uses the Yosys non-standard {\tt \{* ... *\}}
|
|
syntax to set the attribute {\tt sumstuff} on all cells generated by the first
|
|
assign statement. (This works on arbitrary large blocks of Verilog code an
|
|
can be used to mark portions of code for analysis.)
|
|
|
|
Selecting {\tt a:sumstuff} in this module will yield the circuit diagram shown
|
|
in Fig.~\ref{sumprod_00}. As only the cells themselves are selected, but not
|
|
the temporary wire {\tt \$1\_Y}, the two adders are shown as two disjunct
|
|
parts. This can be very useful for global signals like clock and reset signals: just
|
|
unselect them using a command such as {\tt select -del clk rst} and each cell
|
|
using them will get its own net label.
|
|
|
|
In this case however we would like to see the cells connected properly. This
|
|
can be achieved using the {\tt \%x} action, that broadens the selection, i.e.
|
|
for each selected wire it selects all cells connected to the wire and vice
|
|
versa. So {\tt show a:sumstuff \%x} yields the diagram shown in Fig.~\ref{sumprod_01}.
|
|
|
|
\begin{figure}[t]
|
|
\includegraphics[width=\linewidth]{APPNOTE_011_Design_Investigation/sumprod_01.pdf}
|
|
\caption{Output of {\tt show a:sumstuff \%x} on Fig.~\ref{sumprod}}
|
|
\label{sumprod_01}
|
|
\end{figure}
|
|
|
|
\subsection{Selecting logic cones}
|
|
|
|
Fig.~\ref{sumprod_01} shows what is called the {\it input cone\/} of {\tt sum}, i.e.
|
|
all cells and signals that are used to generate the signal {\tt sum}. The {\tt \%ci}
|
|
action can be used to select the input cones of all object in the top selection
|
|
in the stack maintained by the {\tt select} command.
|
|
|
|
As the {\tt \%x} action, this commands broadens the selection by one ``step''. But
|
|
this time the operation only works against the direction of data flow. That means,
|
|
wires only select cells via output ports and cells only select wires via input ports.
|
|
|
|
Fig.~\ref{select_prod} show the sequence of diagrams generated by the following
|
|
commands:
|
|
|
|
\begin{verbatim}
|
|
show prod
|
|
show prod %ci
|
|
show prod %ci %ci
|
|
show prod %ci %ci %ci
|
|
\end{verbatim}
|
|
|
|
When selecting many levels of logic, repeating {\tt \%ci} over and over again
|
|
can be a bit dull. So there is a shortcut for that: the number of iterations
|
|
can be appended to the action. So for example the action {\tt \%ci3} is
|
|
identical to performing the {\tt \%ci} action three times.
|
|
|
|
The action {\tt \%ci*} performs the {\tt \%ci} action over and over again until
|
|
it has no effect anymore.
|
|
|
|
\begin{figure}[t]
|
|
\hfill \includegraphics[width=4cm,trim=0 1cm 0 1cm]{APPNOTE_011_Design_Investigation/sumprod_02.pdf} \\
|
|
\includegraphics[width=\linewidth,trim=0 0cm 0 1cm]{APPNOTE_011_Design_Investigation/sumprod_03.pdf} \\
|
|
\includegraphics[width=\linewidth,trim=0 0cm 0 1cm]{APPNOTE_011_Design_Investigation/sumprod_04.pdf} \\
|
|
\includegraphics[width=\linewidth,trim=0 2cm 0 1cm]{APPNOTE_011_Design_Investigation/sumprod_05.pdf} \\
|
|
\caption{Objects selected by {\tt select prod \%ci...}}
|
|
\label{select_prod}
|
|
\end{figure}
|
|
|
|
\medskip
|
|
|
|
In most cases there are certain cell types and/or ports that should not be considered for the {\tt \%ci}
|
|
action, or we only want to follow certain cell types and/or ports. This can be achieved using additional
|
|
patterns that can be appended to the {\tt \%ci} action.
|
|
|
|
Lets consider the design from Fig.~\ref{memdemo_src}. It serves no purpose other than being a non-trivial
|
|
circuit for demonstrating some of the advanced Yosys features. We synthesize the circuit using {\tt proc;
|
|
opt; memory; opt} and change to the {\tt memdemo} module with {\tt cd memdemo}. If we type {\tt show}
|
|
now we see the diagram shown in Fig.~\ref{memdemo_00}.
|
|
|
|
\begin{figure}[b!]
|
|
\lstinputlisting{APPNOTE_011_Design_Investigation/memdemo.v}
|
|
\caption{Demo circuit for demonstrating some advanced Yosys features}
|
|
\label{memdemo_src}
|
|
\end{figure}
|
|
|
|
\begin{figure*}[t]
|
|
\includegraphics[width=\linewidth,trim=0 0cm 0 0cm]{APPNOTE_011_Design_Investigation/memdemo_00.pdf} \\
|
|
\caption{Complete circuit diagram for the design shown in Fig.~\ref{memdemo_src}}
|
|
\label{memdemo_00}
|
|
\end{figure*}
|
|
|
|
But maybe we are only interested in the tree of multiplexers that select the
|
|
output value. In order to get there, we would start by just showing the output signal
|
|
and its immediate predecessors:
|
|
|
|
\begin{verbatim}
|
|
show y %ci2
|
|
\end{verbatim}
|
|
|
|
From this we would learn that {\tt y} is driven by a {\tt \$dff cell}, that
|
|
{\tt y} is connected to the output port {\tt Q}, that the {\tt clk} signal goes
|
|
into the {\tt CLK} input port of the cell, and that the data comes from a
|
|
auto-generated wire into the input {\tt D} of the flip-flop cell.
|
|
|
|
As we are not interested in the clock signal we add an additional pattern to the {\tt \%ci}
|
|
action, that tells it to only follow ports {\tt Q} and {\tt D} of {\tt \$dff} cells:
|
|
|
|
\begin{verbatim}
|
|
show y %ci2:+$dff[Q,D]
|
|
\end{verbatim}
|
|
|
|
To add a pattern we add a colon followed by the pattern to the {\tt \%ci}
|
|
action. The pattern it self starts with {\tt -} or {\tt +}, indicating if it is
|
|
an include or exclude pattern, followed by an optional comma separated list
|
|
of cell types, followed by an optional comma separated list of port names in
|
|
square brackets.
|
|
|
|
Since we know that the only cell considered in this case is a {\tt \$dff} cell,
|
|
we could as well only specify the port names:
|
|
|
|
\begin{verbatim}
|
|
show y %ci2:+[Q,D]
|
|
\end{verbatim}
|
|
|
|
Or we could decide to tell the {\tt \%ci} action to not follow the {\tt CLK} input:
|
|
|
|
\begin{verbatim}
|
|
show y %ci2:-[CLK]
|
|
\end{verbatim}
|
|
|
|
\begin{figure}[b]
|
|
\includegraphics[width=\linewidth,trim=0 0cm 0 0cm]{APPNOTE_011_Design_Investigation/memdemo_01.pdf} \\
|
|
\caption{Output of {\tt show y \%ci2:+\$dff[Q,D] \%ci*:-\$mux[S]:-\$dff}}
|
|
\label{memdemo_01}
|
|
\end{figure}
|
|
|
|
Next we would investigate the next logic level by adding another {\tt \%ci2} to
|
|
the command:
|
|
|
|
\begin{verbatim}
|
|
show y %ci2:-[CLK] %ci2
|
|
\end{verbatim}
|
|
|
|
From this we would learn that the next cell is a {\tt \$mux} cell and we would add additional
|
|
pattern to narrow the selection on the path we are interested. In the end we would end up
|
|
with a command such as
|
|
|
|
\begin{verbatim}
|
|
show y %ci2:+$dff[Q,D] %ci*:-$mux[S]:-$dff
|
|
\end{verbatim}
|
|
|
|
in which the first {\tt \%ci} jumps over the initial d-type flip-flop and the
|
|
2nd action selects the entire input cone without going over multiplexer select
|
|
inputs and flip-flop cells. The diagram produces by this command is shown in
|
|
Fig.~\ref{memdemo_01}.
|
|
|
|
\medskip
|
|
|
|
Similar to {\tt \%ci} exists an action {\tt \%co} to select output cones that
|
|
accepts the same syntax for pattern and repetition. The {\tt \%x} action mentioned
|
|
previously also accepts this advanced syntax.
|
|
|
|
This actions for traversing the circuit graph, combined with the actions for
|
|
boolean operations such as intersection ({\tt \%i}) and difference ({\tt \%d})
|
|
are powerful tools for extracting the relevant portions of the circuit under
|
|
investigation.
|
|
|
|
See {\tt help select} for a complete list of actions available in selections.
|
|
|
|
\subsection{Storing and recalling selections}
|
|
|
|
The current selection can be stored in memory with the command {\tt select -set
|
|
<name>}. It can later be recalled using {\tt select @<name>}. In fact, the {\tt
|
|
@<name>} expression pushes the stored selection on the stack maintained by the
|
|
{\tt select} command. So for example
|
|
|
|
\begin{verbatim}
|
|
select @foo @bar %i
|
|
\end{verbatim}
|
|
|
|
will select the intersection between the stored selections {\tt foo} and {\tt bar}.
|
|
|
|
\medskip
|
|
|
|
In larger investigation efforts it is highly recommended to maintain a script that
|
|
sets up relevant selections, so they can easily be recalled, for example when
|
|
Yosys needs to be re-run after a design or source code change.
|
|
|
|
The {\tt history} command can be used to list all recent interactive commands.
|
|
This feature can be useful for creating such a script from the commands used in
|
|
an interactive session.
|
|
|
|
\section{Advanced investigation techniques}
|
|
\label{poke}
|
|
|
|
When working with very large modules, it is often not enough to just select the
|
|
interesting part of the module. Instead it can be useful to extract the
|
|
interesting part of the circuit into a separate module. This can for example be
|
|
useful if one wants to run a series of synthesis commands on the critical part
|
|
of the module and wants to carefully read all the debug output created by the
|
|
commands in order to spot a problem. This kind of troubleshooting is much easier
|
|
if the circuit under investigation is encapsulated in a separate module.
|
|
|
|
Fig.~\ref{submod} shows how the {\tt submod} command can be used to split the
|
|
circuit from Fig.~\ref{memdemo_src} and \ref{memdemo_00} into its components.
|
|
The {\tt -name} option is used to specify the name of the new module and
|
|
also the name of the new cell in the current module.
|
|
|
|
\begin{figure}[t]
|
|
\includegraphics[width=\linewidth,trim=0 1.3cm 0 0cm]{APPNOTE_011_Design_Investigation/submod_00.pdf} \\ \centerline{\tt memdemo} \vskip1em\par
|
|
\includegraphics[width=\linewidth,trim=0 1.3cm 0 0cm]{APPNOTE_011_Design_Investigation/submod_01.pdf} \\ \centerline{\tt scramble} \vskip1em\par
|
|
\includegraphics[width=\linewidth,trim=0 1.3cm 0 0cm]{APPNOTE_011_Design_Investigation/submod_02.pdf} \\ \centerline{\tt outstage} \vskip1em\par
|
|
\includegraphics[width=\linewidth,trim=0 1.3cm 0 0cm]{APPNOTE_011_Design_Investigation/submod_03.pdf} \\ \centerline{\tt selstage} \vskip1em\par
|
|
\begin{lstlisting}[basicstyle=\ttfamily\scriptsize]
|
|
select -set outstage y %ci2:+$dff[Q,D] %ci*:-$mux[S]:-$dff
|
|
select -set selstage y %ci2:+$dff[Q,D] %ci*:-$dff @outstage %d
|
|
select -set scramble mem* %ci2 %ci*:-$dff mem* %d @selstage %d
|
|
submod -name scramble @scramble
|
|
submod -name outstage @outstage
|
|
submod -name selstage @selstage
|
|
\end{lstlisting}
|
|
\caption{The circuit from Fig.~\ref{memdemo_src} and \ref{memdemo_00} broken up using {\tt submod}}
|
|
\label{submod}
|
|
\end{figure}
|
|
|
|
\subsection{Evaluation of combinatorial circuits}
|
|
|
|
The {\tt eval} command can be used to evaluate combinatorial circuits.
|
|
For example (see Fig.~\ref{submod} for the circuit diagram of {\tt selstage}):
|
|
|
|
{\scriptsize
|
|
\begin{verbatim}
|
|
yosys [selstage]> eval -set s2,s1 4'b1001 -set d 4'hc -show n2 -show n1
|
|
|
|
9. Executing EVAL pass (evaluate the circuit given an input).
|
|
Full command line: eval -set s2,s1 4'b1001 -set d 4'hc -show n2 -show n1
|
|
Eval result: \n2 = 2'10.
|
|
Eval result: \n1 = 2'10.
|
|
\end{verbatim}
|
|
\par}
|
|
|
|
So the {\tt -set} option is used to set input values and the {\tt -show} option
|
|
is used to specify the nets to evaluate. If no {\tt -show} option is specified,
|
|
all selected output ports are used per default.
|
|
|
|
If a necessary input value is not given, an error is produced. The option
|
|
{\tt -set-undef} can be used to instead set all unspecified input nets to
|
|
undef ({\tt x}).
|
|
|
|
The {\tt -table} option can be used to create a truth table. For example:
|
|
|
|
{\scriptsize
|
|
\begin{verbatim}
|
|
yosys [selstage]> eval -set-undef -set d[3:1] 0 -table s1,d[0]
|
|
|
|
10. Executing EVAL pass (evaluate the circuit given an input).
|
|
Full command line: eval -set-undef -set d[3:1] 0 -table s1,d[0]
|
|
|
|
\s1 \d [0] | \n1 \n2
|
|
---- ------ | ---- ----
|
|
2'00 1'0 | 2'00 2'00
|
|
2'00 1'1 | 2'xx 2'00
|
|
2'01 1'0 | 2'00 2'00
|
|
2'01 1'1 | 2'xx 2'01
|
|
2'10 1'0 | 2'00 2'00
|
|
2'10 1'1 | 2'xx 2'10
|
|
2'11 1'0 | 2'00 2'00
|
|
2'11 1'1 | 2'xx 2'11
|
|
|
|
Assumed undef (x) value for the following signals: \s2
|
|
\end{verbatim}
|
|
}
|
|
|
|
Note that the {\tt eval} command (as well as the {\tt sat} command discussed in
|
|
the next sections) does only operate on flattened modules. It can not analyze
|
|
signals that are passed through design hierarchy levels. So the {\tt flatten}
|
|
command must be used on modules that instantiate other modules before this
|
|
commands can be applied.
|
|
|
|
\subsection{Solving combinatorial SAT problems}
|
|
|
|
\begin{figure}[b]
|
|
\lstinputlisting{APPNOTE_011_Design_Investigation/primetest.v}
|
|
\caption{A simple miter circuit for testing if a number is prime. But it has a
|
|
problem (see main text and Fig.~\ref{primesat}).}
|
|
\label{primetest}
|
|
\end{figure}
|
|
|
|
\begin{figure*}[!t]
|
|
\begin{lstlisting}[basicstyle=\ttfamily\small]
|
|
yosys [primetest]> sat -prove ok 1 -set p 31
|
|
|
|
8. Executing SAT pass (solving SAT problems in the circuit).
|
|
Full command line: sat -prove ok 1 -set p 31
|
|
|
|
Setting up SAT problem:
|
|
Import set-constraint: \p = 16'0000000000011111
|
|
Final constraint equation: \p = 16'0000000000011111
|
|
Imported 6 cells to SAT database.
|
|
Import proof-constraint: \ok = 1'1
|
|
Final proof equation: \ok = 1'1
|
|
|
|
Solving problem with 2790 variables and 8241 clauses..
|
|
SAT proof finished - model found: FAIL!
|
|
|
|
______ ___ ___ _ _ _ _
|
|
(_____ \ / __) / __) (_) | | | |
|
|
_____) )___ ___ ___ _| |__ _| |__ _____ _| | _____ __| | |
|
|
| ____/ ___) _ \ / _ (_ __) (_ __|____ | | || ___ |/ _ |_|
|
|
| | | | | |_| | |_| || | | | / ___ | | || ____( (_| |_
|
|
|_| |_| \___/ \___/ |_| |_| \_____|_|\_)_____)\____|_|
|
|
|
|
|
|
Signal Name Dec Hex Bin
|
|
-------------------- ---------- ---------- ---------------------
|
|
\a 15029 3ab5 0011101010110101
|
|
\b 4099 1003 0001000000000011
|
|
\ok 0 0 0
|
|
\p 31 1f 0000000000011111
|
|
|
|
yosys [primetest]> sat -prove ok 1 -set p 31 -set a[15:8],b[15:8] 0
|
|
|
|
9. Executing SAT pass (solving SAT problems in the circuit).
|
|
Full command line: sat -prove ok 1 -set p 31 -set a[15:8],b[15:8] 0
|
|
|
|
Setting up SAT problem:
|
|
Import set-constraint: \p = 16'0000000000011111
|
|
Import set-constraint: { \a [15:8] \b [15:8] } = 16'0000000000000000
|
|
Final constraint equation: { \a [15:8] \b [15:8] \p } = { 16'0000000000000000 16'0000000000011111 }
|
|
Imported 6 cells to SAT database.
|
|
Import proof-constraint: \ok = 1'1
|
|
Final proof equation: \ok = 1'1
|
|
|
|
Solving problem with 2790 variables and 8257 clauses..
|
|
SAT proof finished - no model found: SUCCESS!
|
|
|
|
/$$$$$$ /$$$$$$$$ /$$$$$$$
|
|
/$$__ $$ | $$_____/ | $$__ $$
|
|
| $$ \ $$ | $$ | $$ \ $$
|
|
| $$ | $$ | $$$$$ | $$ | $$
|
|
| $$ | $$ | $$__/ | $$ | $$
|
|
| $$/$$ $$ | $$ | $$ | $$
|
|
| $$$$$$/ /$$| $$$$$$$$ /$$| $$$$$$$//$$
|
|
\____ $$$|__/|________/|__/|_______/|__/
|
|
\__/
|
|
\end{lstlisting}
|
|
\caption{Experiments with the miter circuit from Fig.~\ref{primetest}. The first attempt of proving that 31
|
|
is prime failed because the SAT solver found a creative way of factorizing 31 using integer overflow.}
|
|
\label{primesat}
|
|
\end{figure*}
|
|
|
|
Often the opposite of the {\tt eval} command is needed, i.e. the circuits
|
|
output is given and we want to find the matching input signals. For small
|
|
circuits with only a few input bits this can be accomplished by trying all
|
|
possible input combinations, as it is done by the {\tt eval -table} command.
|
|
For larger circuits however, Yosys provides the {\tt sat} command that uses
|
|
a SAT \cite{CircuitSAT} solver \cite{MiniSAT} to solve this kind of problems.
|
|
|
|
The {\tt sat} command works very similar to the {\tt eval} command. The main
|
|
difference is that it is now also possible to set output values and find the
|
|
corresponding input values. For Example:
|
|
|
|
{\scriptsize
|
|
\begin{verbatim}
|
|
yosys [selstage]> sat -show s1,s2,d -set s1 s2 -set n2,n1 4'b1001
|
|
|
|
11. Executing SAT pass (solving SAT problems in the circuit).
|
|
Full command line: sat -show s1,s2,d -set s1 s2 -set n2,n1 4'b1001
|
|
|
|
Setting up SAT problem:
|
|
Import set-constraint: \s1 = \s2
|
|
Import set-constraint: { \n2 \n1 } = 4'1001
|
|
Final constraint equation: { \n2 \n1 \s1 } = { 4'1001 \s2 }
|
|
Imported 3 cells to SAT database.
|
|
Import show expression: { \s1 \s2 \d }
|
|
|
|
Solving problem with 81 variables and 207 clauses..
|
|
SAT solving finished - model found:
|
|
|
|
Signal Name Dec Hex Bin
|
|
-------------------- ---------- ---------- ---------------
|
|
\d 9 9 1001
|
|
\s1 0 0 00
|
|
\s2 0 0 00
|
|
\end{verbatim}
|
|
}
|
|
|
|
Note that the {\tt sat} command supports signal names in both arguments
|
|
to the {\tt -set} option. In the above example we used {\tt -set s1 s2}
|
|
to constraint {\tt s1} and {\tt s2} to be equal. When more complex
|
|
constraints are needed, a wrapper circuit must be constructed that
|
|
checks the constraints and signals if the constraint was met using an
|
|
extra output port, which then can be forced to a value using the {\tt
|
|
-set} option. (Such a circuit that contains the circuit under test
|
|
plus additional constraint checking circuitry is called a {\it miter\/}
|
|
circuit.)
|
|
|
|
Fig.~\ref{primetest} shows a miter circuit that is supposed to be used as a
|
|
prime number test. If {\tt ok} is 1 for all input values {\tt a} and {\tt b}
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for a given {\tt p}, then {\tt p} is prime, or at least that is the idea.
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|
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The Yosys shell session shown in Fig.~\ref{primesat} demonstrates that SAT
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|
solvers can even find the unexpected solutions to a problem: Using integer
|
|
overflow there actually is a way of ``factorizing'' 31. The clean solution
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|
would of course be to perform the test in 32 bits, for example by replacing
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{\tt p != a*b} in the miter with {\tt p != \{16'd0,a\}*b}, or by using a
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|
temporary variable for the 32 bit product {\tt a*b}. But as 31 fits well into
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|
8 bits (and as the purpose of this document is to show off Yosys features)
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|
we can also simply force the upper 8 bits of {\tt a} and {\tt b} to zero for
|
|
the {\tt sat} call, as is done in the second command in Fig.~\ref{primesat}
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(line 31).
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|
|
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The {\tt -prove} option used in this example works similar to {\tt -set}, but
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|
tries to find a case in which the two arguments are not equal. If such a case is
|
|
not found, the property is proven to hold for all inputs that satisfy the other
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|
constraints.
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|
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|
It might be worth noting, that SAT solvers are not particularly efficient at
|
|
factorizing large numbers. But if a small factorization problem occurs as
|
|
part of a larger circuit problem, the Yosys SAT solver is perfectly capable
|
|
of solving it.
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|
|
|
\subsection{Solving sequential SAT problems}
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|
|
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\begin{figure}[t!]
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\begin{lstlisting}[basicstyle=\ttfamily\scriptsize]
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yosys [memdemo]> sat -seq 6 -show y -show d -set-init-undef \
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-max_undef -set-at 4 y 1 -set-at 5 y 2 -set-at 6 y 3
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|
|
|
6. Executing SAT pass (solving SAT problems in the circuit).
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Full command line: sat -seq 6 -show y -show d -set-init-undef
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|
-max_undef -set-at 4 y 1 -set-at 5 y 2 -set-at 6 y 3
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|
|
|
Setting up time step 1:
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|
Final constraint equation: { } = { }
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|
Imported 29 cells to SAT database.
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|
|
|
Setting up time step 2:
|
|
Final constraint equation: { } = { }
|
|
Imported 29 cells to SAT database.
|
|
|
|
Setting up time step 3:
|
|
Final constraint equation: { } = { }
|
|
Imported 29 cells to SAT database.
|
|
|
|
Setting up time step 4:
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|
Import set-constraint for timestep: \y = 4'0001
|
|
Final constraint equation: \y = 4'0001
|
|
Imported 29 cells to SAT database.
|
|
|
|
Setting up time step 5:
|
|
Import set-constraint for timestep: \y = 4'0010
|
|
Final constraint equation: \y = 4'0010
|
|
Imported 29 cells to SAT database.
|
|
|
|
Setting up time step 6:
|
|
Import set-constraint for timestep: \y = 4'0011
|
|
Final constraint equation: \y = 4'0011
|
|
Imported 29 cells to SAT database.
|
|
|
|
Setting up initial state:
|
|
Final constraint equation: { \y \s2 \s1 \mem[3] \mem[2] \mem[1]
|
|
\mem[0] } = 24'xxxxxxxxxxxxxxxxxxxxxxxx
|
|
|
|
Import show expression: \y
|
|
Import show expression: \d
|
|
|
|
Solving problem with 10322 variables and 27881 clauses..
|
|
SAT model found. maximizing number of undefs.
|
|
SAT solving finished - model found:
|
|
|
|
Time Signal Name Dec Hex Bin
|
|
---- -------------------- ---------- ---------- ---------------
|
|
init \mem[0] -- -- xxxx
|
|
init \mem[1] -- -- xxxx
|
|
init \mem[2] -- -- xxxx
|
|
init \mem[3] -- -- xxxx
|
|
init \s1 -- -- xx
|
|
init \s2 -- -- xx
|
|
init \y -- -- xxxx
|
|
---- -------------------- ---------- ---------- ---------------
|
|
1 \d 0 0 0000
|
|
1 \y -- -- xxxx
|
|
---- -------------------- ---------- ---------- ---------------
|
|
2 \d 1 1 0001
|
|
2 \y -- -- xxxx
|
|
---- -------------------- ---------- ---------- ---------------
|
|
3 \d 2 2 0010
|
|
3 \y 0 0 0000
|
|
---- -------------------- ---------- ---------- ---------------
|
|
4 \d 3 3 0011
|
|
4 \y 1 1 0001
|
|
---- -------------------- ---------- ---------- ---------------
|
|
5 \d -- -- 001x
|
|
5 \y 2 2 0010
|
|
---- -------------------- ---------- ---------- ---------------
|
|
6 \d -- -- xxxx
|
|
6 \y 3 3 0011
|
|
\end{lstlisting}
|
|
\caption{Solving a sequential SAT problem in the {\tt memdemo} module from Fig.~\ref{memdemo_src}.}
|
|
\label{memdemo_sat}
|
|
\end{figure}
|
|
|
|
The SAT solver functionality in Yosys can not only be used to solve
|
|
combinatorial problems, but can also solve sequential problems. Let's consider
|
|
the entire {\tt memdemo} module from Fig.~\ref{memdemo_src} and suppose we
|
|
want to know which sequence of input values for {\tt d} will cause the output
|
|
{\tt y} to produce the sequence 1, 2, 3 from any initial state.
|
|
Fig.~\ref{memdemo_sat} show the solution to this question, as produced by
|
|
the following command:
|
|
|
|
\begin{verbatim}
|
|
sat -seq 6 -show y -show d -set-init-undef \
|
|
-max_undef -set-at 4 y 1 -set-at 5 y 2 -set-at 6 y 3
|
|
\end{verbatim}
|
|
|
|
The {\tt -seq 6} option instructs the {\tt sat} command to solve a sequential
|
|
problem in 6 time steps. (Experiments with lower number of steps have show that
|
|
at least 3 cycles are necessary to bring the circuit in a state from which
|
|
the sequence 1, 2, 3 can be produced.)
|
|
|
|
The {\tt -set-init-undef} option tells the {\tt sat} command to initialize
|
|
all registers to the undef ({\tt x}) state. The way the {\tt x} state
|
|
is treated in Verilog will ensure that the solution will work for any
|
|
initial state.
|
|
|
|
The {\tt -max\_undef} option instructs the {\tt sat} command to find a solution
|
|
with a maximum number of undefs. This way we can see clearly which inputs bits
|
|
are relevant to the solution.
|
|
|
|
Finally the three {\tt -set-at} options add constraints for the {\tt y}
|
|
signal to play the 1, 2, 3 sequence, starting with time step 4.
|
|
|
|
It is not surprising that the solution sets {\tt d = 0} in the first step, as
|
|
this is the only way of setting the {\tt s1} and {\tt s2} registers to a known
|
|
value. The input values for the other steps are a bit harder to work out
|
|
manually, but the SAT solver finds the correct solution in an instant.
|
|
|
|
\medskip
|
|
|
|
There is much more to write about the {\tt sat} command. For example, there is
|
|
a set of options that can be used to performs sequential proofs using temporal
|
|
induction \cite{tip}. The command {\tt help sat} can be used to print a list
|
|
of all options with short descriptions of their functions.
|
|
|
|
\section{Conclusion}
|
|
\label{conclusion}
|
|
|
|
Yosys provides a wide range of functions to analyze and investigate designs. For
|
|
many cases it is sufficient to simply display circuit diagrams, maybe use some
|
|
additional commands to narrow the scope of the circuit diagrams to the interesting
|
|
parts of the circuit. But some cases require more than that. For this applications
|
|
Yosys provides commands that can be used to further inspect the behavior of the
|
|
circuit, either by evaluating which output values are generated from certain input values
|
|
({\tt eval}) or by evaluation which input values and initial conditions can result
|
|
in a certain behavior at the outputs ({\tt sat}). The SAT command can even be used
|
|
to prove (or disprove) theorems regarding the circuit, in more advanced cases
|
|
with the additional help of a miter circuit.
|
|
|
|
This features can be powerful tools for the circuit designer using Yosys as a
|
|
utility for building circuits and the software developer using Yosys as a
|
|
framework for new algorithms alike.
|
|
|
|
\begin{thebibliography}{9}
|
|
|
|
\bibitem{yosys}
|
|
Clifford Wolf. The Yosys Open SYnthesis Suite.
|
|
\url{http://www.clifford.at/yosys/}
|
|
|
|
\bibitem{graphviz}
|
|
Graphviz - Graph Visualization Software.
|
|
\url{http://www.graphviz.org/}
|
|
|
|
\bibitem{xdot}
|
|
xdot.py - an interactive viewer for graphs written in Graphviz's dot language.
|
|
\url{https://github.com/jrfonseca/xdot.py}
|
|
|
|
\bibitem{CircuitSAT}
|
|
{\it Circuit satisfiability problem} on Wikipedia
|
|
\url{http://en.wikipedia.org/wiki/Circuit_satisfiability}
|
|
|
|
\bibitem{MiniSAT}
|
|
MiniSat: a minimalistic open-source SAT solver.
|
|
\url{http://minisat.se/}
|
|
|
|
\bibitem{tip}
|
|
Niklas Een and Niklas S\"orensson (2003).
|
|
Temporal Induction by Incremental SAT Solving.
|
|
\url{http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.4.8161}
|
|
|
|
\end{thebibliography}
|
|
|
|
\end{document}
|