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%% Filename:    spec.tex

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%% Project:     Wishbone scope

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%% Purpose:     This LaTeX file contains all of the documentation/description

%%              currently provided with this Wishbone scope core.  It's not

%%              nearly as interesting as the PDF file it creates, so I'd

%%              recommend reading that before diving into this file.  You

%%              should be able to find the PDF file in the SVN distribution

%%              together with this PDF file and a copy of the GPL-3.0 license

%%              this file is distributed under.  If not, just type 'make'

%%              in the doc directory and it (should) build without a problem.

%%

%%

%% Creator:     Dan Gisselquist

%%              Gisselquist Technology, LLC

%%

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%%

%% Copyright (C) 2015, Gisselquist Technology, LLC

%%

%% This program is free software (firmware): you can redistribute it and/or

%% modify it under the terms of  the GNU General Public License as published

%% by the Free Software Foundation, either version 3 of the License, or (at

%% your option) any later version.

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%% This program is distributed in the hope that it will be useful, but WITHOUT

%% ANY WARRANTY; without even the implied warranty of MERCHANTIBILITY or

%% FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License

%% for more details.

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%% You should have received a copy of the GNU General Public License along

%% with this program.  (It's in the $(ROOT)/doc directory, run make with no

%% target there if the PDF file isn't present.)  If not, see

%% <http://www.gnu.org/licenses/> for a copy.

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%% License:     GPL, v3, as defined and found on www.gnu.org,

%%              http://www.gnu.org/licenses/gpl.html

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\documentclass{gqtekspec}

\project{Wishbone Scope}

\title{Specification}

\author{Dan Gisselquist, Ph.D.}

\email{dgisselq (at) ieee.org}

\revision{Rev.~0.1}

\begin{document}

\pagestyle{gqtekspecplain}

\titlepage

\begin{license}

Copyright (C) \theyear\today, Gisselquist Technology, LLC

This project is free software (firmware): you can redistribute it and/or

modify it under the terms of  the GNU General Public License as published

by the Free Software Foundation, either version 3 of the License, or (at

your option) any later version.

This program is distributed in the hope that it will be useful, but WITHOUT

ANY WARRANTY; without even the implied warranty of MERCHANTIBILITY or

FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License

for more details.

You should have received a copy of the GNU General Public License along

with this program.  If not, see \texttt{http://www.gnu.org/licenses/} for a

copy.

\end{license}

\begin{revisionhistory}

0.3 & 6/22/2015 & Gisselquist & Minor updates to enhance readability \\\hline

0.2 & 6/22/2015 & Gisselquist & Finished Draft \\\hline

0.1 & 6/22/2015 & Gisselquist & First Draft \\\hline

\end{revisionhistory}

% Revision History

% Table of Contents, named Contents

\tableofcontents

% \listoffigures

\listoftables

\begin{preface}

This project began, years ago, for all the wrong reasons.  Rather than pay a

high price to purchase a Verilog simulator and then to learn how to use it,

I took working Verilog code, to include a working bus, added features and

used the FPGA system as my testing platform.  I arranged the FPGA to step

internal registers upon command, and to make many of those registers

available via the bus.

When I then needed to make the project run in real-time, as opposed to the

manually stepped approach, I generated a scope like this one.  I had already

bench tested the components on the hardware itself.  Thus, testing and

development continued on the hardware, and the scope helped me see what was

going right or wrong.  The great advantage of the approach was that, at the

end of the project, I didn't need to do any hardware in the loop testing.

All of the testing that had been accomplished prior to that date was already

hardware in the loop testing.

When I left that job, I took this concept with me and rebuilt this piece of

infrastructure using a Wishbone Bus.

\end{preface}

\chapter{Introduction}

\pagenumbering{arabic}

\setcounter{page}{1}

The Wishbone Scope is a debugging tool for reading results from the chip after

events have taken place.  In general, the scope records data until some

some (programmable) holdoff number of data samples after a trigger has taken

place.  Once the holdoff has been reached, the scope stops recording and

asserts an interrupt.  At this time, data may be read from the scope in order

from oldest to most recent.  That's the basics, now for two extra details.

First, the trigger and the data that the scope records are both implementation

dependent.  The scope itself is designed to be easily reconfigurable from one

build to the next so that the actual configuration may even be build dependent.

Second, the scope is built to be able to run off of a separate clock from the

bus that commands and controls it.  This is configurable, set the parameter

``SYNCHRONOUS'' to `1' to run off of a single clock.  When running off of two

clocks, it means that actions associated with commands issued to the scope,

such as manual triggering or being disabled or released, will not act

synchronously with the scope itself--but this is to be expected.

Third, the data clock associated with the scope has a clock enable line

associated with it.  Depending on how often the clock enable line is enabled

may determine how fast the scope is {\tt PRIMED}, {\tt TRIGGERED}, and eventually completes

its collection.

Finally, and in conclusion, this scope has been an invaluable tool for

testing, for figuring out what is going on internal to a chip, and for fixing

such things.  I have fixed interactions over a PS/2 connection, Internal

Configuration Access Port (ICAPE2) interfaces, mouse controller interactions,

bus errors, quad-SPI flash interactions, and more using this scope.

% \chapter{Architecture}

\chapter{Operation}

So how shall one use the scope?  The scope itself supports a series of

states:

\begin{enumerate}

\item {\tt RESET}

        Any write to the control register, without setting the high order bit,

        will automatically reset the scope.  Once reset, the scope will

        immediately start collecting.

\item {\tt PRIMED}

        Following a reset, once the scope has filled its memory, it enters the

        {\tt PRIMED} state.  Once it reaches this state, it will be sensitive

        to a trigger.

\item {\tt TRIGGERED}

    The scope may be {\tt TRIGGERED} either automatically, via an input port to

    the core, or manually, via a wishbone bus command.  Once a trigger

    has been received, the core will record a user configurable number of

    further samples before stopping.

\item {\tt STOPPED}

    Once the core has {\tt STOPPED}, the data within it may be read back off.

\end{enumerate}

Let's go through that list again.  First, before using the scope, the holdoff

needs to be set.  The scope is designed so that setting the scope control value

to the holdoff alone, with all other bits set to zero, will reset the scope

from whatever condition it was in,

freeing it to run.  Once running, then upon every clock enabled clock, one

sample of data is read into the scope and recorded.  Once every memory value

is filled, the scope has been {\tt PRIMED}.  Once the scope has been

{\tt PRIMED}, it will then be responsive to its trigger.  Should the trigger be

active on an input clock with the clock--enable line set, the scope will then

be {\tt TRIGGERED}.  It

will then count for the number of clocks in the holdoff before stopping

collection, placing it in the {\tt STOPPED} state.  \footnote{You can even

change the holdoff while the scope is running by writing a new holdoff value

together with setting the {\tt RESET\_n} bit of the control register.  However,

if you do this after the core has triggered it may stop at some other

non--holdoff value!}  If the holdoff is zero, the last sample in the buffer

will be the sample containing the trigger.  Likewise if the holdoff is one

less than the size of the memory, the first sample in the buffer will be the

one containing the trigger.

There are two further commands that will affect the operation of the scope.  The

first is the {\tt MANUAL} trigger command/bit.  This bit may be set by writing

the holdoff to the control register while setting this bit high.  This will

cause the scope to trigger as soon as it is primed.  If the {\tt RESET\_n}

bit is also set so as to prevent an internal reset, and if the scope was already

primed, then manual trigger command will cause it to trigger immediately.

The last command that can affect the operation of the scope is the {\tt DISABLE}

command/bit in the control register.  Setting this bit will prevent the scope

from triggering, or if {\tt TRIGGERED}, it will prevent the scope from

generating an interrupt.

Finally, be careful how you set the clock enable line.  If the clock enable

line leaves the clock too often disabled, the scope might never prime in any

reasonable amount of time.

So, in summary, to use this scope you first set the holdoff value in the

control register.  Second, you wait until the scope has been {\tt TRIGGERED}

and {\tt STOPPED}.  Finally, you read from the data register once for every

memory value in the buffer and you can then sit back, relax, and study what

took place within the FPGA.  Additional modes allow you to manually trigger

the scope, or to disable the automatic trigger entirely.

\chapter{Registers}

This scope core supports two registers, as listed in

Tbl.~\ref{tbl:reglist}: a control register and a data register.

\begin{table}[htbp]

\begin{center}

\begin{reglist}

CONTROL & 0 & 32 & R/W & Configuration, control, and status of the

        scope.\\\hline

DATA    & 1 & 32 & R(/W) & Read out register, to read out the data

        from the core.  Writes to this register reset the read address

        to the beginning of the buffer, but are otherwise ignored.

        \\\hline

\end{reglist}\caption{List of Registers}\label{tbl:reglist}

\end{center}\end{table}

Each register will be discussed in detail in this chapter.

\section{Control Register}

The bits in the control register are defined in Tbl.~\ref{tbl:control}.

\begin{table}[htbp]

\begin{center}

\begin{bitlist}

31 & R/W & {\tt RESET\_n}.  Write a `0' to this register to command a reset.

        Reading a `1' from this register means the reset has not finished

        crossing clock domains and is still pending.\\\hline

30 & R & {\tt STOPPED}, indicates that all collection has stopped.\\\hline

29 & R & {\tt TRIGGERED}, indicates that a trigger has been recognized, and that

        the scope is counting for holdoff samples before stopping.\\\hline

28 & R & {\tt PRIMED}, indicates that the memory has been filled, and that the

        scope is now waiting on a trigger.\\\hline

27 & R/W & {\tt MANUAL}, set to invoke a manual trigger.\\\hline

26 & R/W & {\tt DISABLE}, set to disable the internal trigger.  The scope may still

        be {\tt TRIGGERED} manually.\\\hline

25 & R & {\tt RZERO}, this will be true whenever the scope's internal address

        register is pointed at the beginning of the memory.\\\hline

20--24 & R & {\tt LGMEMLEN}, the base two logarithm of the memory length.  Thus,

        the memory internal to the scope is given by 1$<<$LGMEMLEN. \\\hline

0--19 & R/W & Unsigned holdoff\\\hline

\end{bitlist}

\caption{Control Register}\label{tbl:control}

\end{center}\end{table}

The register has been designed so that one need only write the holdoff value to

it, while leaving the other bits zero, to get the scope going.  On such a write,

the RESET\_n bit will be a zero, causing the scope to internally reset itself.

Further, during normal operation, the high order nibble will go from 4'h8

(a nearly instantaneous reset state) to 4'h0 (running), to 4'h1 ({\tt PRIMED}),

to 4'h3 ({\tt TRIGGERED}), and then stop at 4'h7 ({\tt PRIMED}, {\tt TRIGGERED},

and {\tt STOPPED}).

Finally, user's are cautioned not to adjust the holdoff between the time the

scope triggers and the time it stops--just to guarantee data coherency.

While this approach works, the scope has some other capabilities.  For example,

if you set the {\tt MANUAL} bit, the scope will trigger as soon as it is {\tt PRIMED}.

If you set the {\tt MANUAL} bit and the {\tt RESET\_n} bit, it will trigger

immediately if the scope was already {\tt PRIMED}.  However, if the

{\tt RESET\_n} bit was not also set, a reset will take place and the scope

will start over by first collecting enough data to be {\tt PRIMED}, and only

then will the {\tt MANUAL} trigger take effect.

A second optional capability is to disable the scope entirely.  This might be

useful if, for example, certain irrelevant things might trigger the scope.

By setting the {\tt DISABLE} bit, the scope will not automatically trigger.  It

will still record into its memory, and it will still prime itself, it will just

not trigger automatically.  The scope may still be manually {\tt TRIGGERED}

while the {\tt DISABLE} bit is set.  Likewise, if the {\tt DISABLE} bit is set

after the scope has been {\tt TRIGGERED}, the scope will continue to its

natural stopped state--it just won't generate an interrupt.

There are two other interesting bits in this control register.  The {\tt RZERO}

bit indicates that the next read from the data register will read from the first

value in the memory, while the {\tt LGMEMLEN} bits indicate how long the memory is.  Thus, if {\tt LGMEMLEN} is 10, the FIFO will be (1$<<$10) or 1024 words

long, whereas if {\tt LGMEMLEN} is 14, the FIFO will be (1$<<$14) or 16,384 words

long.

\section{Data Register}

This is perhaps the simplest register to explain.  Before the core stops

recording, reads from this register will produce reads of the bits going into

the core, save only that they have not been protected from any meta-stability

issues.  This is useful for reading what's going on when the various lines are

stuck.  After the core stops recording, reads from this register return values

from the stored memory, beginning at the oldest and ending with the value

holdoff clocks after the trigger.  Further, after recording has stopped, every

read increments an internal memory address, so that after (1$<<$LGMEMLEN)

reads (for however long the internal memory is), the entire memory has been

returned over the bus.

If you would like some assurance that you are reading from the beginning of the

memory, you may either check the control register's {\tt RZERO} flag which will

be `1' for the first value in the buffer, or you may write to the data register.

Such writes will be ignored, save that they will reset the read address back

to the beginning of the buffer.

\chapter{Clocks}

This scope supports two clocks: a wishbone bus clock, and a data clock.

If the internal parameter ``SYNCHRONOUS'' is set to zero, proper transfers

will take place between these two clocks.  Setting this parameter to a one

will save some flip flops and logic in implementation.  The speeds of the

respective clocks are based upon the speed of your device, and not specific

to this core.

\chapter{Wishbone Datasheet}\label{chap:wishbone}

Tbl.~\ref{tbl:wishbone}

\begin{table}[htbp]

\begin{center}

\begin{wishboneds}

Revision level of wishbone & WB B4 spec \\\hline

Type of interface & Slave, Read/Write, pipeline reads supported \\\hline

Port size & 32--bit \\\hline

Port granularity & 32--bit \\\hline

Maximum Operand Size & 32--bit \\\hline

Data transfer ordering & (Irrelevant) \\\hline

Clock constraints & None.\\\hline

Signal Names & \begin{tabular}{ll}

                Signal Name & Wishbone Equivalent \\\hline

                {\tt i\_wb\_clk} & {\tt CLK\_I} \\

                {\tt i\_wb\_cyc} & {\tt CYC\_I} \\

                {\tt i\_wb\_stb} & {\tt STB\_I} \\

                {\tt i\_wb\_we} & {\tt WE\_I} \\

                {\tt i\_wb\_addr} & {\tt ADR\_I} \\

                {\tt i\_wb\_data} & {\tt DAT\_I} \\

                {\tt o\_wb\_ack} & {\tt ACK\_O} \\

                {\tt o\_wb\_stall} & {\tt STALL\_O} \\

                {\tt o\_wb\_data} & {\tt DAT\_O}

                \end{tabular}\\\hline

\end{wishboneds}

\caption{Wishbone Datasheet}\label{tbl:wishbone}

\end{center}\end{table}

is required by the wishbone specification, and so

it is included here.  The big thing to notice is that this core

acts as a wishbone slave, and that all accesses to the wishbone scope

registers become 32--bit reads and writes to this interface.  You may also wish

to note that the scope supports pipeline reads from the data port, to speed

up reading the results out.

What this table doesn't show is that all accesses to the port take a single

clock.  That is, if the {\tt i\_wb\_stb} line is high on one clock, the

{\tt i\_wb\_ack} line will be high the next.  Further, the {\tt o\_wb\_stall}

line is tied to zero.

\chapter{I/O Ports}\label{ch:ioports}

The ports are listed in Table.~\ref{tbl:ioports}.

\begin{table}[htbp]

\begin{center}

\begin{portlist}

{\tt i\_clk} & 1 & Input & The clock the data lines, clock enable, and trigger

        are synchronous to. \\\hline

{\tt i\_ce} & 1 & Input & Clock Enable.  Set this high to clock data in and

        out.\\\hline

{\tt i\_trigger} & 1 & Input & An active high trigger line.  If this trigger is

        set to one on any clock enabled data clock cycle, once

        the scope has been {\tt PRIMED}, it will then enter into its

        {\tt TRIGGERED} state.

        \\\hline

{\tt i\_data} & 32 & Input & 32--wires of ... whatever you are interested in

        recording and later examining.  These can be anything, only

        they should be synchronous with the data clock.

        \\\hline

{\tt i\_wb\_clk} & 1 & Input & The clock that the wishbone interface runs on.

                \\\hline

{\tt i\_wb\_cyc} & 1 & Input & Indicates a wishbone bus cycle is active when

                high.  \\\hline

{\tt i\_wb\_stb} & 1 & Input & Indicates a wishbone bus cycle for this

        peripheral when high.  (See the wishbone spec for more details) \\\hline

{\tt i\_wb\_we} & 1 & Input & Write enable, allows indicates a write to one of

        the two registers when {\tt i\_wb\_stb} is also high.

        \\\hline

{\tt i\_wb\_addr} & 1 & Input & A single address line, set to zero to access the

                configuration and control register, to one to access the data

                register.  \\\hline

{\tt i\_wb\_data} & 32 & Input & Data used when writing to the control register,

                ignored otherwise.  \\\hline

{\tt o\_wb\_ack} & 1 & Output & Wishbone acknowledgement.  This line will go

                high on the clock after any wishbone access, as long as the

                wishbone {\tt i\_wb\_cyc} line remains high (i.e., no ack's if

                you terminate the cycle early).

                \\\hline

{\tt o\_wb\_stall} & 1 & Output & Required by the wishbone spec, but always

                set to zero in this implementation.

                \\\hline

{\tt o\_wb\_data} & 32 & Output & Values read, either control or data, headed

        back to the wishbone bus.  These values will be valid during any

        read cycle when the {\tt i\_wb\_ack} line is high.

        \\\hline

\end{portlist}

\caption{List of IO ports}\label{tbl:ioports}

\end{center}\end{table}

At this point, most of these ports should have been well defined and described

earlier in this document.  The only new things are the data clock, {\tt i\_clk},

the clock enable for the data, {\tt i\_ce}, the trigger, {\tt i\_trigger}, and

the data of interest itself, {\tt i\_data}.  Hopefully these are fairly self

explanatory by this point.  If not, just remember the data, {\tt i\_data},

are synchronous to the clock, {\tt i\_clk}.  On every clock where the clock

enable line is high, {\tt i\_ce}, the data will be recorded until the scope

has stopped.  Further, the scope will stop some programmable holdoff number

of clock enabled data clocks after {\tt i\_trigger} goes high.  Further,

{\tt i\_trigger} need only be high for one clock cycle to be noticed by the

scope.

% Appendices

% Index

\end{document}