Fix few typos

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Théophile Bastian 2017-08-28 20:10:06 +02:00
parent 1802f8caa8
commit 6e9cec0c32

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@ -86,7 +86,7 @@ To avoid such disasters, the industry nowadays uses a wide range of techniques
to catch bugs as early as possible --- which, hopefully, is before the
product's release date. These techniques include of course a lot of testing on
simulated hardware or FPGAs (since an actual processor is extremely expensive
to actually print). A lot of testing is run as a routine on the current version
to burn). A lot of testing is run as a routine on the current version
of the hardware, to catch and notify the designers, since it remains the
easiest way to test the behaviour of a circuit. Symbolic trajectory
evaluation~\cite{hazelhurst1997symbolic} has also its place in the domain,
@ -97,18 +97,19 @@ since its results are more precise; yet it is also too expensive to run on a
significantly long number of cycles, and therefore a lot of bugs are impossible
to catch this way.
The previous methods are a good cheap method to test a circuit, but give only
little confidence in its correction --- it only proves that among all the cases
that were tested, all yielded a correct behaviour. These reasons led to the
development of proved hardware in the industry. On circuits as complex as
processors, usually, only sub-components are proved correct with respect to a
given specification of its behaviour (usually source code that should behave as
the processor is expected to behave, itself with respect to the written
documentation draft of the circuit). These proofs are typically valid only
while the circuit is kept in a specified context, \ie{} a set of valid inputs
and outputs, etc. --- that should, but is not proved to, be respected by the
other parts of the circuit. Yet, this trade-off between proved correctness and
engineer's work time already gives a pretty good confidence in the circuit.
The previous methods are great cheap strategies to run the first tests on a
circuit, but give only little confidence in its correction --- it only proves
that among all the cases that were tested, all yielded a correct behaviour.
These reasons led to the development of proved hardware in the industry. On
circuits as complex as processors, usually, only sub-components are proved
correct with respect to a given specification of its behaviour (usually source
code that should behave as the processor is expected to behave, itself with
respect to the written documentation draft of the circuit). These proofs are
typically valid only while the circuit is kept in a specified context, \ie{} a
set of valid inputs, tensions, etc. --- that should, but is not proved to, be
respected by the other parts of the circuit. Yet, this trade-off between proved
correctness and engineer's work time already gives a pretty good confidence in
the circuit.
In this context, Carl Seger was one of the main developers of fl at
Intel~\cite{seger1993vos}~\cite{seger2005industrially}~\cite{seger2006design},