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Making prograss on Appnote 010
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@ -50,10 +50,14 @@ the BLIF format, for example it only uses synchronous resets.
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Converting {\tt softusb\_navre.v} to {\tt softusb\_navre.blif} could not be
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easier:
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\begin{figure}[H]
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left]
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yosys -o softusb_navre.blif \
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-S softusb_navre.v
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\end{lstlisting}
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\renewcommand{\figurename}{Listing}
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\caption{Calling Yosys without script file}
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\end{figure}
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Behind the scenes Yosys is controlled by synthesis scripts that execute
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commands that operate on Yosys' internal state. For example, the {\tt -o
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@ -76,12 +80,16 @@ to use an actual script file.
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With a script file we have better control over Yosys. The following script
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file replicates what the command from the last section did:
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left,caption={\tt softusb\_navre.ys}]
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\begin{figure}[H]
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left]
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read_verilog softusb_navre.v
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hierarchy
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proc; opt; memory; opt; techmap; opt
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write_blif softusb_navre.blif
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\end{lstlisting}
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\renewcommand{\figurename}{Listing}
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\caption{\tt softusb\_navre.ys}
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\end{figure}
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The first and last line obviously read the Verilog file and write the BLIF
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file.
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@ -124,9 +132,13 @@ source file, as we will see in the next section.
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Now Yosys can be run with the file of the synthesis script as argument:
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\begin{figure}[H]
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left]
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yosys softusb_navre.ys
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\end{lstlisting}
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\renewcommand{\figurename}{Listing}
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\caption{Calling Yosys with script file}
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\end{figure}
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\medskip
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@ -155,13 +167,17 @@ processed using custom commands. But in this case we don't need that.
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So now we have the final synthesis script for generating a BLIF file
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for the navre CPU:
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left,caption={\tt softusb\_navre.ys} (improved)]
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\begin{figure}[H]
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left]
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read_verilog softusb_navre.v
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hierarchy -check -top softusb_navre
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proc; opt; memory; opt;
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fsm; opt; techmap; opt
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write_blif softusb_navre.blif
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\end{lstlisting}
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\renewcommand{\figurename}{Listing}
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\caption{{\tt softusb\_navre.ys} (improved)}
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\end{figure}
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\section{Advanced Example: The Amber23 ARMv2a CPU}
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@ -169,7 +185,8 @@ Our 2nd example is the Amber23\footnote{\url{http://opencores.org/project,amber}
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ARMv2a CPU. Once again we base our example on the Verilog code that is included
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in {\it yosys-bigsim}.
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left,caption={\tt amber23.ys}]
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\begin{figure}[b!]
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left]
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read_verilog a23_alu.v
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read_verilog a23_barrel_shift_fpga.v
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read_verilog a23_barrel_shift.v
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@ -188,10 +205,77 @@ read_verilog generic_sram_line_en.v
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hierarchy -check -top a23_core
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add -global_input globrst 1
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proc -global_arst globrst
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opt; memory; opt; fsm; opt
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techmap -map adff2dff.v
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techmap
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opt; memory; opt; fsm; opt; techmap
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write_blif amber23.blif
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\end{lstlisting}
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\renewcommand{\figurename}{Listing}
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\caption{\tt amber23.ys}
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\label{aber23.ys}
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\end{figure}
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The problem with this core is that it contains no dedicated reset signals.
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Instead it is using the coding techiques shown in Listing~\ref{glob_arst} to
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set reset values to be used on the global asynchronous reset in an FPGA
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implementation. This design can not be expressed in BLIF as it is. Instead we
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need to use a synthesis script that transforms this to synchonous resets that
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can be expressed in BLIF.
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\medskip
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Listing~\ref{aber23.ys} shows the synthesis script for the Amber23 core. In
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line 17 the {\tt add} command is used to add a 1-bit wide global input signal
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with the name {\tt globrst}. That means that an input with that name is added
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to each module in the design hierarchy and then all module instanciations are
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altered so that this new signal is connected throughout the whole design
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hierarchy.
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\begin{figure}[t!]
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left]
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reg [7:0] a = 13, b;
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initial b = 37;
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\end{lstlisting}
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\renewcommand{\figurename}{Listing}
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\caption{Implicit coding of global asynchronous resets}
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\label{glob_arst}
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\end{figure}
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\begin{figure}[b!]
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\begin{lstlisting}[frame=trBL,xleftmargin=1.5em,numbers=left]
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module \$adff (CLK, ARST, D, Q);
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parameter WIDTH = 1;
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parameter CLK_POLARITY = 1'b1;
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parameter ARST_POLARITY = 1'b1;
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parameter ARST_VALUE = 0;
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input CLK, ARST;
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input [WIDTH-1:0] D;
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output reg [WIDTH-1:0] Q;
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wire _TECHMAP_FAIL_ =
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!CLK_POLARITY || !ARST_POLARITY;
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always @(posedge CLK)
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if (ARST)
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Q <= ARST_VALUE;
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else
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Q <= D;
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endmodule
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\end{lstlisting}
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\renewcommand{\figurename}{Listing}
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\caption{\tt adff2dff.v}
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\label{adff2dff.v}
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\end{figure}
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In line 18 the {\tt proc} command is called. But this time the newly created
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reset signal is passed to the core as a global reset line to use for resetting
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all registers to their initial values.
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Finally in line 19 the {\tt techmap} command is used to replace all instances
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of flip-flops with asynchronous resets to flip-flops with synchronous resets.
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The map file used fo this is shown in Lising~\ref{adff2dff.v}.
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{\color{red} FIXME}
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@ -22,6 +22,7 @@
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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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