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\chapter{PLB interface}
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\section{Structure}
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The Processor Local Bus interface for this core is structured as in Figure~\ref{PLBstructure}. The core acts as a slave
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to the PLB bus. The PLB v4.6 Slave\cite{XilinxPLB} logic translates the interface to a lower level IP Interconnect
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Interface (IPIC).
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This is then used to connect the core internal components to. The user logic contains the exponentiation core and the
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control register for the core its control inputs and outputs. An internal interrupt controller\cite{XilinxIntr} handles
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the outgoing interrupt requests and a software reset module is provided to be able to reset the IP core at runtime. This
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bus interface is created using the ``Create or Import Peripheral'' wizard from Xilinx Platform Studio.\\
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\begin{figure}[H]
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\centering
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\includegraphics[trim=1.2cm 1.2cm 1.2cm 1.2cm, width=7cm]{pictures/plb_interface.pdf}
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\caption{PLB IP core structure}
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\label{PLBstructure}
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\end{figure}
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\newpage
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\section{Parameters}
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This section describes the parameters used to configure the core, only the relevant parameters are discussed. PLB
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specific parameters are left to the user to configure. The IP core specific parameters and their respective use are
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listed in the table below.
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\begin{center}
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        \begin{tabular}{|l|p{6.5cm}|c|l|}
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                \hline
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                \rowcolor{Gray}
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                \textbf{Name} & \textbf{Description} & \textbf{VHDL Type} &\textbf{Default Value} \bigstrut\\
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                \hline
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                \multicolumn{4}{|l|}{\textit{\textbf{Memory configuration}}} \\
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                \hline
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                \verb|C_BASEADDR| & base address for the IP core's memory space & std\_logic\_vector & X"FFFFFFFF" \bigstrut\\
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                \hline
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                \verb|C_HIGHADDR| & high address for the IP core's memory space & std\_logic\_vector & X"00000000" \bigstrut\\
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                \hline
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                \verb|C_M_BASEADDR| & base address for the modulus memory space & std\_logic\_vector & X"FFFFFFFF" \bigstrut\\
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                \hline
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                \verb|C_M_HIGHADDR| & high address for the modulus memory space & std\_logic\_vector & X"00000000" \bigstrut\\
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                \hline
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                \verb|C_OP0_BASEADDR| & base address for the operand 0 memory space & std\_logic\_vector & X"FFFFFFFF" \bigstrut\\
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                \hline
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                \verb|C_OP0_HIGHADDR| & high address for the operand 0 memory space & std\_logic\_vector & X"00000000" \bigstrut\\
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                \hline
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                \verb|C_OP1_BASEADDR| & base address for the operand 1 memory space & std\_logic\_vector & X"FFFFFFFF" \bigstrut\\
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                \hline
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                \verb|C_OP1_HIGHADDR| & high address for the operand 1 memory space & std\_logic\_vector & X"00000000" \bigstrut\\
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                \hline
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                \verb|C_OP2_BASEADDR| & base address for the operand 2 memory space & std\_logic\_vector & X"FFFFFFFF" \bigstrut\\
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                \hline
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                \verb|C_OP2_HIGHADDR| & high address for the operand 2 memory space & std\_logic\_vector & X"00000000" \bigstrut\\
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                \hline
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                \verb|C_OP3_BASEADDR| & base address for the operand 3 memory space & std\_logic\_vector & X"FFFFFFFF" \bigstrut\\
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                \hline
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                \verb|C_OP3_HIGHADDR| & high address for the operand 3 memory space & std\_logic\_vector & X"00000000" \bigstrut\\
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                \hline
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                \verb|C_FIFO_BASEADDR| & base address for the FIFO memory space & std\_logic\_vector & X"FFFFFFFF" \bigstrut\\
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                \hline
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                \verb|C_FIFO_HIGHADDR| & high address for the FIFO memory space & std\_logic\_vector & X"00000000" \bigstrut\\
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                \hline
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                \multicolumn{4}{|l|}{\textit{\textbf{Multiplier configuration}}} \\
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                \hline
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                \verb|C_NR_BITS_TOTAL| & total width of the multiplier in bits & integer & 1536\bigstrut\\
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                \hline
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                \verb|C_NR_STAGES_TOTAL| & total number of stages in the pipeline & integer & 96\bigstrut\\
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                \hline
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                \verb|C_NR_STAGES_LOW| & number of lower stages in the pipeline, defines the bit-width of the lower pipeline part & integer & 32 \bigstrut\\
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                \hline
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                \verb|C_SPLIT_PIPELINE| & option to split the pipeline in 2 parts & boolean & true \bigstrut\\
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                \hline
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        \end{tabular}%
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\end{center}
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%\newline
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The complete IP core's memory space can be controlled. As can be seen, the operand, modulus and FIFO memory space can be
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chosen separately from the IP core's memory space which hold the registers for control, software reset and interrupt
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control. The core's memory space must have a minimum width of 1K byte for all registers to be accessible. For the FIFO
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memory space, a minimum width of 4 byte is needed, since the FIFO is only 32 bit wide. The memory space width for the
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operands and the modulus need a minimum width equal to the total multiplier width.\\
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There are 4 parameters to configure the multiplier. These values define the width of the multiplier operands and the
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number of pipeline stages. If \verb|C_SPLIT_PIPELINE| is false, only operands with a width of\\\verb|C_NR_BITS_TOTAL| are
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valid. Else if \verb|C_SPLIT_PIPELINE| is true, 3 operand widths can be supported:
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\begin{itemize}
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  \item the length of the full pipeline ($C\_NR\_BITS\_TOTAL$)
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  \item the length of the lower pipeline ($\frac{C\_NR\_BITS\_TOTAL}{C\_NR\_STAGES\_TOTAL} \cdot C\_NR\_STAGES\_LOW $)
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  \item the length of the higher pipeline ($\frac{C\_NR\_BITS\_TOTAL}{C\_NR\_STAGES\_TOTAL} \cdot (C\_NR\_STAGES\_TOTAL - C\_NR\_STAGES\_LOW$)
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\end{itemize}
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\section{IO ports}
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\begin{tabular}{|l|c|c|l|}
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        \hline
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        \rowcolor{Gray}
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        \textbf{Port} & \textbf{Width} & \textbf{Direction} & \textbf{Description} \\
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        \hline
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        \multicolumn{4}{|l|}{\textit{\textbf{PLB bus connections}}} \\
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        \hline
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        \verb|SPLB_Clk| & 1     & in & see note 1 \\
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        \hline
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        \verb|SPLB_Rst| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_ABus| & 32    & in & see note 1 \\
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        \hline
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        \verb|PLB_PAValid| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_masterID| & 3     & in & see note 1 \\
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        \hline
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        \verb|PLB_RNW| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_BE| & 4     & in & see note 1 \\
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        \hline
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        \verb|PLB_size| & 4     & in & see note 1 \\
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        \hline
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        \verb|PLB_type| & 3     & in & see note 1 \\
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        \hline
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        \verb|PLB_wrDBus| & 32    & in & see note 1 \\
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        \hline
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        \verb|Sl_addrAck| & 1     & out & see note 1 \\
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        \hline
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        \verb|Sl_SSize| & 2     & out & see note 1 \\
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        \hline
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        \verb|Sl_wait| & 1     & out & see note 1 \\
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        \hline
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        \verb|Sl_rearbitrate| & 1     & out & see note 1 \\
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        \hline
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        \verb|Sl_wrDack| & 1     & out & see note 1 \\
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        \hline
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        \verb|Sl_wrComp| & 1     & out & see note 1 \\
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        \hline
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        \verb|Sl_rdBus| & 32    & out & see note 1 \\
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        \hline
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        \verb|Sl_MBusy| & 8     & out & see note 1 \\
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        \hline
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        \verb|Sl_MWrErr| & 8     & out & see note 1 \\
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        \hline
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        \verb|Sl_MRdErr| & 8     & out & see note 1 \\
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        \hline
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        \multicolumn{4}{|l|}{\textit{\textbf{unused PLB signals}}} \\
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        \hline
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        \verb|PLB_UABus| & 32    & in & see note 1 \\
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        \hline
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        \verb|PLB_SAValid| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_rdPrim| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_wrPrim| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_abort| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_busLock| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_MSize| & 2     & in & see note 1 \\
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        \hline
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        \verb|PLB_TAttribute| & 16    & in & see note 1 \\
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        \hline
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        \verb|PLB_lockerr| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_wrBurst| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_rdBurst| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_wrPendReq| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_rdPendReq| & 1     & in & see note 1 \\
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        \hline
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        \verb|PLB_rdPendPri| & 2     & in & see note 1 \\
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        \hline
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        \verb|PLB_wrPendPri| & 2     & in & see note 1 \\
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        \hline
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        \verb|PLB_reqPri| & 2     & in & see note 1 \\
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        \hline
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        \verb|Sl_wrBTerm| & 1     & out & see note 1 \\
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        \hline
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        \verb|Sl_rdWdAddr| & 4     & out & see note 1 \\
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        \hline
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        \verb|Sl_rdBTerm| & 1     & out & see note 1 \\
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        \hline
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        \verb|Sl_MIRQ| & 8     & out & see note 1 \\
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        \hline
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        \multicolumn{4}{|l|}{\textit{\textbf{Core signals}}} \\
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        \hline
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        \verb|IP2INTC_Irpt| & 1     & out   & core interrupt signal \\
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        \hline
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        \verb|calc_time| & 1     & out   & is high when core is performing a multiplication, for monitoring \\
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        \hline
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\end{tabular}%
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\newline \newline
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\textbf{Note 1:} The function and timing of this signal is defined in the IBM\textsuperscript{\textregistered} 128-Bit Processor Local Bus Architecture Specification
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Version 4.6.
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188
\section{Registers}
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This section specifies the IP core internal registers as seen from the software. These registers allow to control and
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configure the modular exponentiation core and to read out its state. All addresses given in this table are relative to the
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IP core's base address.\\
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\newline
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% Table generated by Excel2LaTeX
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\begin{tabular}{|l|c|c|c|l|}
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\hline
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\rowcolor{Gray}
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\textbf{Name} & \textbf{Width} & \textbf{Address} & \textbf{Access} & \textbf{Description} \bigstrut\\
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\hline
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control register                & 32 & 0x0000 & RW      & multiplier core control signals and \bigstrut[t]\\
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                                                &       &               &               & interrupt flags register\bigstrut[b]\\
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\hline
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software reset                  & 32 & 0x0100 & W       & soft reset for the IP core  \bigstrut\\
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\hline
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\multicolumn{5}{|l|}{\textbf{\textit{Interrupt controller registers}}} \bigstrut\\
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\hline
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global interrupt enable register        & 32 & 0x021C & RW & global interrupt enable for the IP core \bigstrut[t]\\
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interrupt status register                       & 32 & 0x0220 & R  & register for interrupt status flags\\
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interrupt enable register                       & 32 & 0x0228 & RW & register to enable individual IP core interrupts \bigstrut[b]\\
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\hline
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\end{tabular}%
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\newpage
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\subsection{Control register (offset = 0x0000)}
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This registers holds the control inputs to the multiplier core and the interrupt flags.\\
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\begin{figure}[H]
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\centering
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\includegraphics[trim=1.2cm 1.2cm 1.2cm 1.2cm, width=15cm]{pictures/plb_control_reg.pdf}
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\caption{control register}
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\end{figure}
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\begin{tabular}{ll}
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bits 0-1        & P\_SEL : selects which pipeline part to be active\\
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                        & $\bullet$  "01" lower pipeline part\\
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                        & $\bullet$  "10" higher pipeline part\\
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                        & $\bullet$  "11" full pipeline\\
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                        & $\bullet$  "00" invalid selection\\
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                        &\\
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bits 2-3        & DEST\_OP : selects the operand (0-3) to store the result in for a single\\
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                        & Montgomery multiplication\footnotemark\\
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                        &\\
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bits 4-5        & X\_OP : selects the x operand (0-3) for a single Montgomery multiplication\footnotemark[\value{footnote}]\\
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                        &\\
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bits 6-7        & Y\_OP : selects the y operand (0-3) for a single Montgomery multiplication\footnotemark[\value{footnote}]\\
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                        &\\
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bit 8           & START : starts the multiplication/exponentiation\\
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                        &\\
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bit 9           & EXP/M : selects the operating mode\\
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                        & $\bullet$  "0" single Montgomery multiplications\\
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                        & $\bullet$  "1" simultaneous exponentiations\\
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                        &\\
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bits 10-15      & unimplemented\\
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                        &\\
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bit 16          & READY : ready flag, "1" when multiplication is done\\
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                        & must be cleared in software\\
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                        &\\
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bit 17          & MEM\_ERR : memory collision error flag, "1" when write error occurred\\
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                        & must be cleared in software\\
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                        &\\
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bit 18          & FIFO\_FULL : FIFO full error flag, "1" when FIFO is full\\
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                        & must be cleared in software\\
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                        &\\
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bit 19          & FIFO\_ERR : FIFO write/push error flag, "1" when push error occurred\\
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                        & must be cleared in software\\
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                        &\\
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bits 20-31      & unimplemented\\
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                        &\\
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\end{tabular}
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\newline
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\newline
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\footnotetext{when the core is running in exponentiation mode, the parameters DEST\_OP, X\_OP and Y\_OP have no effect.}
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263
\newpage
264
\subsection{Software reset register (offset = 0x0100)}
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This is a register with write only access, and provides the possibility to reset the IP core from software by writing
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0x0000000A to this address. The reset affects the full IP core, thus resetting the control register, interrupt controller,
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the multiplier pipeline, FIFO and control logic of the core.
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269
\subsection{Global interrupt enable register (offset = 0x021C)}
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This register contains a single defined bit in the high-order position. The GIE bit enables or disables all interrupts
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form the IP core.\\
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\begin{figure}[H]
273
\centering
274
\includegraphics[trim=1.2cm 1.2cm 1.2cm 1.2cm, width=15cm]{pictures/plb_gie_reg.pdf}
275
\caption{Global interrupt enable register}
276
\end{figure}
277
 
278
\begin{tabular}{ll}
279
bit 0           & GIE : Global interrupt enable\\
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                        & $\bullet$  "0" disables all core interrupts\\
281
                        & $\bullet$  "1" enables all core interrupts\\
282
                        &\\
283
bits 1-31       & unimplemented\\
284
                        &\\
285
\end{tabular}
286
 
287
\subsection{Interrupt status register (offset = 0x0220)}
288
Read-only register that contains the status of the core interrupts. Currently there is only one common interrupt from
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the core that is asserted when a multiplication/exponentiation is done, FIFO is full, on FIFO push error or memory write
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collision.\\
291
\begin{figure}[H]
292
\centering
293
\includegraphics[trim=1.2cm 1.2cm 1.2cm 1.2cm, width=15cm]{pictures/plb_is_reg.pdf}
294
\caption{Interrupt status register}
295
\end{figure}
296
 
297
\begin{tabular}{ll}
298
bits 0-30       & unimplemented\\
299
                        &\\
300
bit 31          & CIS : Core interrupt status\\
301
                        & is high when interrupt is requested from core\\
302
                        &\\
303
\end{tabular}
304
 
305
\subsection{interrupt enable register (offset = 0x0228)}
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This register contains the interrupt enable bits for the respective interrupt bits of the interrupt status register.\\
307
\begin{figure}[H]
308
\centering
309
\includegraphics[trim=1.2cm 1.2cm 1.2cm 1.2cm, width=15cm]{pictures/plb_ie_reg.pdf}
310
\caption{Interrupt enable register}
311
\end{figure}
312
\begin{tabular}{ll}
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bits 0-30       & unimplemented\\
314
                        &\\
315
bit 31          & CIE : Core interrupt enable\\
316
                        & $\bullet$  "0" disable core interrupt\\
317
                        & $\bullet$  "1" enable core interrupt\\
318
                        &\\
319
\end{tabular}
320
 
321
\section{Interfacing the core's RAM}
322
Special attention must be taken when writing data to the operands and modulus. The least significant bit of the data has be on the lowest
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address and the most significant bit on the highest address. A write to the RAM has to happen 1 word at a time, byte writes are not
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supported due to the structure of the RAM.
325
 
326
\section{Handling interrupts}
327
When the embedded processor receives an interrupt signal from this core, it is up to the controlling software to
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determine the source of the interrupt by reading out the interrupt flag of the control register.

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