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IRSIM(1) IRSIM Users's Manual IRSIM(1)
NAME
irsim - An event-driven logic-level simulator for MOS circuits
SYNOPSIS
irsim [-s] prm_file sim_file ... [+hist_file] [-cmd_file ...]
DESCRIPTION
IRSIM is an event-driven logic-level simulator for MOS (both N and P)
transistor circuits. Two simulation models are available:
switch Each transistor is modeled as a voltage-controlled switch.
Useful for initializing or determining the functionality of the
network.
linear Each transistor is modeled as a resistor in series with a
voltage-controlled switch; each node has a capacitance. Node
values and transition times are computed from the resulting RC
network, using Chorng-Yeoung Chu's model. Chris Terman's
original model is not supported any more.
If the -s switch is specified, 2 or more transistors of the same type
connected in series, with no other connections to their common
source/drain will be stacked into a compound transistor with multiple
gates.
The prm_file is the electrical parameters file that configure the
devices to be simulated. It defines the capacitance of the various
layers, transistor resistances, threshold voltages, etc... (see
presim(1)).
If prm_file does not specify an absolute path then IRSIM will search
for the prm_file as follows (in that order):
1) ./<prm_file> (in the current directory).
2) ${CAD_ROOT}/irsim/<prm_file>
3) ${CAD_ROOT}/irsim/<prm_file>.prm
The default search directory (nominally /usr/local/lib) can be
overriden by setting the environment variable CAD_ROOT to the
appropriate directory prior to running IRSIM (i.e. setenv CAD_ROOT
/cad/lib).
IRSIM first processes the files named on the command line, then
(assuming the exit command has not been processed) accepts commands
from the user, executing each command before reading the next.
File names NOT beginning with a '-' are assumed to be sim files (see
sim(5)), note that this version does not require to run the sim files
through presim. These files are read and added to the network
database. There is only a single name space for nodes, so references
to node "A" in different network files all refer to the same node.
While this feature allows one to modularize a large circuit into
several network files, care must be taken to ensure that no unwanted
node merges happen due to an unfortunate clash in names.
File names prefaced with a '-' are assumed to be command files: text
files which contain command lines to be processed in the normal
fashion. These files are processed line by line; when an end-of-file
is encountered, processing continues with the next file. After all the
command files have been processed, and if an "exit" command has not
terminated the simulation run, IRSIM will accept further commands from
the user, prompting for each one like so:
irsim>
The hist_file is the name of a file created with the dumph command (see
below). If it is present, IRSIM will initilize the network to the
state saved in that file. This file is different from the ones created
with the ">" command since it saves the state of every node for all
times, including any pending events.
This version supports changes to the network through the update
command. Also, the capability to incrementally re-simulate the network
up to the current time is provided by the isim command.
COMMAND SUMMARY
@ filename take commands from command file
? wnode... print info about node's source/drain
connections
! wnode... print info about node's gate connections
< filename restore network state from file
> filename write current network state to file
<< filename same as "<" but restores inputs too
| comment... comment line
activity from [to] graph circuit activity in time interval
ana wnode... display nodes in analyzer window
analyzer wnode... display nodes in analyzer window
assert wnode [m] val assert that wnode equals value
assertWhen nodeT valT node val
assert when a condition is met
back [time] move back to time
c [n] simulate for n clock cycles (default:1)
changes from [to] print nodes that changed in time interval
clock [node [val]] define value sequence for clock node
clear clear analyzer window (remove signals)
d [wnode]... print display list or specified node(s)
debug [debug_level...]
set debug level (default: off)
decay [n] set charge decay time (0 => no decay)
display [arg]... control what gets displayed when
dumph filename... write net history to file
hist [on|off] turn history on or off
exit [status] return to system
flush [time] flush out history up to time (default: now)
h wnode... make node logic high (1) input
has_coords print YES if transistor coordinates are
available
inputs print current list of input nodes
ires [n] set incremental resolution to n ns
isim [filename] incrementally resimulate changes form filename
l wnode... make node logic low (0) input
logfile [filename] start/stop log file
model [name] set simulation model to name
p step clock one simulation step (phase)
path wnode... display critical path for last transition of a
node
powlogfile [filename] start/stop power logfile
powtrace -[node]... start/stop power tracing of specified
node(s)/vector(s)
powstep toggle the display of power estimate for each
timestep
print comment... print specified text
printp print a list of all pending events
printx print all undefined (X) nodes
q terminate input from current stream
R [n] simulate for n cycles (default:longest
sequence)
readh filename read history from filename
report[level] set/reset reporting of decay events
s [n] simulate for n ns. (default: stepsize)
stepsize [n] set simulation step size to n ns.
set vector value assign value to vector
setlog[file|off] log net changes to file (off -> no log)
setpath set search path for cmd files
stats print event statistics
sumcap print out the sum of the capacitance of all
nodes
t [-]wnode... start/stop tracing of specified nodes
tcap print list of shorted transistors
time [command] print resource utilization summary
until wnode [mask] value count
delayed assert based on the clock count.
u wnode... make node undefined (X) input
unitdelay [n] force transitions to take n ns. (0 disables)
update filename read net changes from file
V [node [value...]] define sequence of inputs for a node
vector label node... define bit vector
vsupply voltage set supply voltage for calculating power
(default 5V)
w [-]wnode... add/delete nodes from display list
wnet [filename] write network to file
x wnode... remove node from input lists
Xdisplay [host:n] set/show X display (for analyzer)
COMMAND DESCRIPTIONS
Commands have the following simple syntax:
cmd arg1 arg2 ... argn <newline>
where cmd specifies the command to be performed and the argi are
arguments to that command. The arguments are separated by spaces (or
tabs) and the command is terminated by a <newline>.
If cmd is not one of the built-in commands documented below, IRSIM
appends ".cmd" to the command name and tries to open that file as a
command file (see "@" command). Thus the command "foo" has the same
effect as "@ foo.cmd".
Notation:
... indicates zero or more repetitions
[ ] enclosed arguments are optional
node name of node or vector in network
wnode name of node or vector in network, can include '*' wildcard
which matches any sequence of zero or more characters. The pair
of characters '{' and '}' denote iteration over the limits
enclosed by it, for example: name{1:10} will expand into name1,
name2 ... name10. A 3rd optional argument sets the stride, for
example: name{1:10:2} will expand into name1, name3, ... name7,
name9.
| comment...
Lines beginning with vertical bar are treated as comments and
ignored -- useful for comments or temporarily disabling certain
commands in a command file.
Most commands take one or more node names as arguments. Whenever a
node name is acceptible in a command line, one can also use the name of
a bit vector. In this case, the command will be applied to each node
of the vector (the "t" and "d" treat vectors specially, see below).
vector label node...
Define a bit vector named "label" which includes the specified
nodes. If you redefine a bit vector, any special attributes of
the old vector (e.g., being on the display or trace list) are
lost. Wild cards are not accepted in the list of node names
since you would have no control over the order in which matching
nodes would appear in the vector.
The simulator performs most commands silently. To find out what's
happened you can use one of the following commands to examine the state
of the network and/or the simulator.
set vector value
Assign value to vector. For example, the following sequence of
commands:
vector BUS bit.1 bit.2 bit.3
set BUS 01x
The first command will define BUS to be a vector composed of
nodes bit.1, bit.2, and bit.3. The second command will assign
the following values:
bit.1 = 0
bit.2 = 1
bit.3 = X
Value can be any sequence of [0,1,h,H,l,L,x,X], and must be of
the same length as the bit vector itself.
d [wnode]...
Display. Without arguments displays the values all nodes and
bit vectors currently on the display list (see w command). With
arguments, only displays the nodes or bit vectors specified.
See also the "display" command if you wish to have the display
list printed out automatically at the end of certain simulation
commands.
w [-]wnode...
Watch/unwatch one or more nodes. Whenever a "d" command is
given, each watched node will displayed like so:
node1=0 node2=X ...
To remove a node from the watched list, preface its name with a
'-'. If wnode is the name of a bit vector, the values of the
nodes which make up the vector will be displayed as follows:
label=010100
where the first 0 is the value of first node in the list, the
first 1 the value of the second node, etc.
assert wnode [mask] value
Assert that the boolean value of the node or vector wnode is
value. If the comparison fails, an error message is printed.
If mask is given then only those bits corresponding to zero bits
in mask take part in the comparison, any character other than 0
will skip that bit. The format of the error message is the
following:
(tty, 3): assertion failed on 'name' 10X10 (1010X)
Where name is the name of the vector, followed by the actual
value and the expected value enclosed in parenthesis. If a mask
is specified, then bits that were not compared are printed as
'-'.
until wnode [mask] value count
Acts just like the assert command except it requires an
additional argument <count> which is the max number of clock
cycles to run. Instead of just testing the current state, like
assert, until tests for true and if false it runs clock cycles
until condition becomes true or count runs out.
ana wnode...
This is a shorthand for the analyzer command (described below).
analyzer wnode...
Add the specified node(s)/vector(s) to the analyzer display list
(see irsim-analyzer(3) for a detailed explanation). If the
analyzer window does not exist, it will be created. If no
arguments are given and the analyzer window already exists,
nothing happens.
Xdisplay [host:display]
You must be able to connect to an X-server to start the
analyzer. If you haven't set up the DISPLAY environment
variable properly, the analyzer command may fail. If this is the
case you can use the Xdisplay command to set it from within the
simulator. With no arguments, the name of the current X-server
will be printed.
clear Removes all nodes and vectors from the analyzer window. This
command is most useful in command scripts for switching between
different signals being displayed on the analyzer.
"?" and "!" allow the user to go both backwards and forwards through
the network. This is a useful debugging aid.
? wnode...
Prints a synopsis of the named nodes including their current
values and the state of all transistors that affect the value of
these nodes. This is the most common way of wandering through
the network in search of what went wrong.
The output from the command ? out looks like
out=0 (vl=0.3 vh=0.8) (0.100 pf) is computed from:
n-channel phi2=0 out=0 in=0 [1.0e+04, 1.3e+04, 8.7e+03]
pulled down by (a=1 b=1) [1.0e+04, 1.3e+04, 8.8e+03]
pulled up [4.0e+04, 7.4e+04, 4.0e+04]
The first line gives the node's name and current value, its low
and high logic thresholds, user-specifed low-to-high and high-
to-low propagation delays if present, and its capacitance if
nonzero. Succeeding lines list the transistor whose sources or
drains connect to this node: the transistor type ("pulled down"
is an n-channel transistor connected to gnd, "pulled up" is a
depletion pullup or p-channel transistor connected to vdd), the
values of the gate, source, and drain nodes, and the modeling
resistances. Simple chains of transistors with the same implant
type are collapsed by the -s option into a single transistor
with a "compound" gate; compound gates appear as a parenthesized
list of nodes (e.g., the pulldown shown above). The three
resistance values -- static, dynamic high, dynamic low -- are
given in Kilo-ohms.
Finally, any pending events for a node are listed after the
electrical information.
! wnode...
For each node in the argument list, print a list of transistors
controlled by that node.
tcap
Prints a list of all transistors with their source/drain shorted
together or whose source/drain are connected to the power
supplies. These transistors will have no effect on the
simulation other than their gate capacitance load. Although
transistors connected across the power supplies are real design
errors, the simulator does not complain about them.
Any node can be made an input -- the simulator will not change an input
node's value until it is released. Usually on specific nodes -- inputs
to the circuit -- are manipulated using the commands below, but you can
fool with a subcircuit by forcing values on internal nodes just as
easily.
h wnode...
Force each node on the argument list to be a high (1) input.
Overrides previous input commands if necessary.
l wnode...
Like "h" except forces nodes to be a low (0) input.
u wnode...
Like "h" except forces nodes to be a undefined (X) input.
x wnode...
Removes nodes from whatever input list they happen to be on.
The next simulation step will determine the correct node value
from the surrounding circuit. This is the default state of most
nodes. Note that this does not force nodes to have an "X" value
-- it simply removes them from the input lists.
inputs prints the high, low, and undefined input lists.
It is possible to define a sequence of values for a node, and then
cycle the circuit as many times as necessary to input each value and
simulate the network. A similar mechanism is used to define the
sequence of values each clock node goes through during a single cycle.
Each value is a list of characters (with no intervening blanks) chosen
from the following:
1, h, H logic high (1)
0, l, L logic low (0)
u, U undefined (X)
x, X remove node from input lists
Presumably the length of the character list is the same as the size of
the node/vector to which it will be assigned. Blanks (spaces and tabs)
are used to separate values in a sequence. The sequence is used one
value at a time, left to right. If more values are needed than
supplied by the sequence, IRSIM just restarts the sequence again.
V [node [value...]]
Define a vector of inputs for a node. After each cycle of an
"R" command, the node is set to the next value specified in the
sequence.
With no arguments, clears all input sequences (does not affect
clock sequences however). With one argument, "node", clears any
input sequences for that node/vector.
clock [node [value...]]
Define a phase of the clock. Each cycle, each node specified by
a clock command must run through its respective values. For
example,
clock phi1 1 0 0 0
clock phi2 0 0 1 0
defines a simple 4-phase clock using nodes phi1 and phi2.
Alternatively one could have issued the following commands:
vector clk phi1 phi2
clock clk 10 00 01 00
With no arguments, clears all clock sequences. With one
argument, "node", clears any clock sequences for that
node/vector.
After input values have been established, their effect can be
propagated through the network with the following commands. The basic
simulated time unit is 0.1ns; all event times are quantized into basic
time units. A simulation step continues until stepsize ns. have
elapsed, and any events scheduled for that interval are processed. It
is possible to build circuits which oscillate -- if the period of
oscillation is zero, the simulation command will not return. If this
seems to be the case, you can hit <ctrl-C> to return to the command
interpreter. Note that if you do this while input is being taken from
a file, the simulator will bring you to the top level interpreter,
aborting all pending input from any command files.
When using the linear model (see the "model" command) transition times
are estimated using an RC time constant calculated from the surrounding
circuit. When using the switch model, transitions are scheduled with
unit delay. These calculations can be overridden for a node by setting
its tplh and tphl parameters which will then be used to determine the
time for a transition.
s [n] Simulation step. Propogates new values for the inputs through
the network, returns when n (default: stepsize) ns. have passed.
If n is specified, it will temporarily override the stepsize
value. Unlike previous versions, this value is NOT remembered
as the default value for the stepsize parameter. If the display
mode is "automatic", the current display list is printed out on
the completion of this command (see "display" command).
c [n] Cycle n times (default: 1) through the clock, as defined by the
"clock" command. Each phase of the clock lasts stepsize ns. If
the display mode is "automatic", the current display list is
printed out on the completion of this command (see "display"
command).
p Step the clock through one phase (or simulation step). For
example, if the clock is defined as above
clock phi1 1 0 0 0
clock phi2 0 0 1 0
then "p" will set phi1 to 1 and phi2 to 0, and then propagate
the effects for one simulation step. The next time "p" is
issued, phi1 and phi2 will both be set to 0, and the effects
propagated, and so on. If the "c" command is issued after "p"
has been used, the effect will be to step through the next 4
phases from where the "p" command left off.
R [n] Run the simulator through n cycles (see the "c" command). If n
is not present make the run as long as the longest sequence. If
display mode is automatic (see "display" command) the display is
printed at the end of each cycle. Each "R" command starts over
at the beginning of the sequence defined for each node.
back time
Move back to the specified time. This command restores circuit
state as of time, effectively undoing any changes in between.
Note that you can not move past any previously flushed out
history (see flush command below) as the history mechanism is
used to restore the network state. This command can be useful
to undo a mistake in the input vectors or to re-simulate the
circuit with a different debug level.
path wnode...
display critical path(s) for last transition of the specified
node(s). The critical path transistions are reported using the
following format:
node -> value @ time (delta)
where node is the name of the node, value is the value to which
the node transitioned, time is the time at which the transistion
occurred, and delta is the delay through the node since the last
transition. For example:
critical path for last transition of Hit_v1:
phi1-> 1 @ 2900.0ns , node was an input
PC_driver-> 0 @ 2900.4ns (0.4ns)
PC_b_q1-> 1 @ 2904.0ns (3.6ns)
tagDone_b_v1-> 0 @ 2912.8ns (8.8ns)
tagDone1_v1-> 1 @ 2915.3ns (2.5ns)
tagDone1_b_v1-> 0 @ 2916.0ns (0.7ns)
tagDone_v1-> 1 @ 2918.4ns (2.4ns)
tagCmp_b_v1-> 0 @ 2922.1ns (3.7ns)
tagCmp_v1-> 1 @ 2923.0ns (0.9ns)
Vbit_b_v1-> 0 @ 2923.2ns (0.2ns)
Hit_v1-> 1 @ 2923.5ns (0.3ns)
activity from_time [to_time]
print histogram showing amount of circuit activity in the
specified time inteval. Actually only shows number of nodes
which had their most recent transition in the interval.
changes from_time [to_time]
print list of nodes which last changed value in the specified
time interval.
printp print list of all pending events sorted in time. The node
associated with each event and the scheduled time is printed.
printx print a list of all nodes with undefined (X) values.
Using the trace command, it is possible to get more detail about what's
happening to a particular node. Much of what is said below is
described in much more detail in "Logic-level Simulation for VLSI
Circuits" by Chris Terman, available from Kluwer Academic Press. When
a node is traced, the simulator reports each change in the node's
value:
[event #100] node out.1: 0 -> 1 @ 407.6ns
The event index is incremented for each event that is processed. The
transition is reported as
old value -> new value @ report time
Note that since the time the event is processed may differ from the
event's report time, the report time for successive events may not be
strictly increasing.
Depending on the debug level (see the "debug" command) each calculation
of a traced node's value is reported:
[event #99] node clk: 0 -> 1 @ 400.2ns
final_value( Load ) V=[0.00, 0.04] => 0
..compute_tau( Load )
{Rmin=2.2K Rdom=2.2K Rmax=2.2K} {Ca=0.06 Cd=0.17}
tauA=0.1 tauD=0.4 ns
[event #99: clk->1] transition for Load: 1 -> 0 (tau=0.5ns,
delay=0.6ns)
In this example, a calculation for node Load is reported. The
calculation was caused by event 99 in which node clk went to 1. When
using the linear model (as in this example) the report shows
current value -> final value
The second line displays information regarding the final value (or dc)
analysis for node "Load"; the minimun and maximum voltages as well as
the final logical value (0 in this case).
The next three lines display timing analysis information used to
estimate the delays. The meaning of the variables displayed can be
found Chu's thesis: "Improved Models for Switch-Level Simulation".
When the final value is reported as "D", the node is not connected to
an input and may be scheduled to decay from its current value to X at
some later time (see the "decay" command).
"tau" is the calculated transition time constant, "delta" is when any
consequences of the event will be computed; the difference in the two
times is how IRSIM accounts for the shape of the transition waveform on
subsequent stages (see reference given above for more details). The
middle lines of the report indicate the Thevenin and capacitance
parameters of the surrounding networks, i.e., the parameters on which
the transition calculations are based.
debug [ev dc tau taup tw spk][off][all]
Set debugging level. Useful for debugging simulator and/or
circuit at various levels of the computation. The meaning of
the various debug levels is as follows:
ev display event enqueueing and dequeueing.
dc display dc calculation information.
tau display time constant (timing) calculation.
taup display second time constant (timing) calculation.
tw display network parameters for each stage of the tree
walk, this applies to dc, tau, and taup. This level of
debugging detail is usually needed only when debugging
the simulator.
spk displays spike analysis information.
all This is a shorthand for specifying all of the above.
off This turns off all debugging information.
If a debug switch is on then during a simulation step, each time
a watched node is encounted in some event, that fact is
indicated to the user along with some event info. If a node
keeps appearing in this prinout, chances are that its value is
oscillating. Vice versa, if your circuit never settles (ie., it
oscillates) , you can use the "debug" and "t" commands to find
the node(s) that are causing the problem.
Without any arguments, the debug command prints the current
debug level.
t [-]wnode...
set trace flag for node. Enables the various printouts
described above. Prefacing the node name with '-' clear its
trace flag. If "wnode" is the name of a vector, whenever any
node of that vector changes value, the current time and the
values of all traced vectors is printed. This feature is useful
for watching the relative arrival times of values at nodes in an
output vector.
System interface commands:
> filename
Write current state of each node into specified file. Useful
for making a breakpoint in your simulation run. Only stores
values so isn't really useful to "dump" a run for later use,
i.e., the current input lists, pending events, etc. are NOT
saved in the state file.
< filename
Read from specified file, reinitializing the value of each node
as directed. Note that network must already exist and be
identical to the network used to create the dump file with the
">" command. These state saving commands are really provided so
that complicated initializing sequences need only be simulated
once.
<< filename
Same as "<" command, except that this command will restore the
input status of the nodes as well. It does not, however,
restore pending events.
dumph [filename]
Write the history of the simulation to the specified file, that
is; all transistions since time = 0. The resulting file is a
machine-independent binary file, and contains all the required
information to continue simulation at the time the dump takes
place. If the filename isn't specified, it will be constructed
by taking the name of the sim_file (from the command line) and
appending ".hist" to it.
readh filename
Read the specified history-dump file into the current network.
This command will restore the state of the circuit to that of
the dump file, overwriting the current state.
flush [time]
If memory consumption due to history maintanance becomes
prohibitive, this command can be used to free the memory
consumed by the history up to the time specified. With no
arguments, all history up to the current point in the simulation
is freed. Flushing out the history may invalidate an
incremental simulation and the portions flushed will no longer
appear in the analyzer window.
setpath [path...]
Set the search-path for command files. Path should be a
sequence of directories to be searched for ".cmd" files, "."
meaning the current directory. For eaxmple:
setpath . /usr/me/rsim/cmds /cad/lib/cmds
With no arguments, it will print the current search-path.
Initially this is just ".".
print text...
Simply prints the text on the user's console. Useful for
keeping user posted of progress through a long command file.
logfile [filename]
Create a logfile with the specified name, closing current log
file if any; if no argument, just close current logfile. All
output which appears on user's console will also be placed in
the logfile. Output to the logfile is cleverly formatted so
that logfiles themselves can serve as command files.
setlog [filename | off]
Record all net changes, as well as resulting error messages, to
the specified file (see "update" command). Net changes are
always appended to the log-file, preceding each sequence of
changes by the current date. If the argument is off then net-
changes will not be logged. With no arguments, the name of the
current log-file is printed.
The default is to always record net changes; if no filename is
specified (using the "setlog" command) the default filename
irsim_changes.log will be used. The log-files are formatted so
that log-files may themselves be used as net-change files.
wnet [filename]
Write the current network to the specified file. If the
filename isn't specified, it will be constructed by taking the
name of the sim_file (from the command line) and appending
".inet" to it. The resulting file can be used in a future
simulation run, as if it were a sim file. The file produced is
a machine independent binary file, which is typically about 1/3
the size of the sim file and about 8 times faster to load.
time [command]
With no argument, a summary of time used by the simulator is
printed. If arguments are given the specified command is timed
and a time summary is printed when the command completes. The
format of the time summary is Uu Ss E P% M, where:
U => User time in seconds
S => System time in seconds
E => Elapsed time, minutes:seconds
P => Percentage of CPU time (((U + S)/E) * 100)
M => Median text, data, and stack size use
q
Terminate current input stream. If this is typed at top level,
the simulator will exit back to the system; otherwise, input
reverts to the previous input stream.
exit [n]
Exit to system, n is the reported status (default: 0).
Simulator parameters are set with the following commands. With no
arguments, each of the commands simply prints the current value of the
parameter.
decay [n]
Set decay parameter to n ns. (default: 0). If non-zero, it
tells the number of ns. it takes for charge on a node to decay
to X. A value of 0 implies no decay at all. You cannot specify
this parameters separately for each node, but this turns out not
to be a problem. See "report" command.
display [-][cmdfile][automatic]
set/reset the display modes, which are
cmdfile commands executed from command files are displayed
to user before executing. The default is cmdfile =
OFF.
automatic print out current display list (see "d" command)
after completion of "s" or "c" command. The default
is automatic = ON.
Prefacing the previous commands with a "-" turns off that
display option.
model [name]
Set simulation model to one of the following:
switch Model transistors as voltage controlled switches. This
model uses interval logic levels, without accounting for
transistor resistances, so circuits with fighting
transistors may not be accuratelly modelled. Delays may
not reflect the true speed of the circuit as well.
linear Model transistors as a resistor in series with a voltage
controlled switch. This model uses a single-time-
constant computed from the resulting RC network and uses
a two-time-constant model to analyze charge sharing and
spikes.
The default is the linear model. You can change the simulation
model at any time -- even with events pending -- as only new
calculations are affected. Without arguments, this command
prints the current model name.
report [level]
When level is nonzero, report all nodes which are set to X
because of charge decay, regardless on whether they are being
traced. Setting level to zero disables reporting, but not the
decay itself (see "decay" command).
stepsize [n]
Specify duration of simulation step or clock phase. n is
specified in ns. (nanoseconds). Floating point numbers with up
to 1 digit past the decimal point are allowed. Further decimals
are trucated (i.e. 10.299 == 10.2).
unitdelay [n]
When nonzero, force all transitions to take n ns. Setting the
parameter to zero disables this feature. The resolution is the
same as for the "stepsize" command.
stats Print event statitistics, as follows:
changes = 26077
punts (cns) = 208 (34)
punts = 0.79%, cons_punted = 16.35%
nevents = 28012; evaluations = 27972
Where changes is the total number of transistions recorded,
punts is the number of punted events, (cns) is the number of
consecutive punted events (a punted event that punted another
event). The penultimate line shows the percentage of punted
events with respect to the total number of events, and the
percentage of consecutive punted events with respect to the
number of punted events. The last line shows the total number
of events (nevents) and the number of net evaluations.
Incremental simulation commands:
Irsim supports incremental changes to the network and resimulation of
the resulting network. This is done incrementally so that only the
nodes affected by the changes, either directly or indirectly, are re-
evaluated.
update filename
Read net-change tokens from the specified file. The following
net-change commands are available:
add type gate source drain length width [area]
delete type gate source drain length width [area]
move type gate source drain length width [area] g s d
cap node value
N node metal-area poly-area diff-area diff-perim
M node M2A M2P MA MP PA PP DA DP PDA PDP
thresh node low high
Delay node tplh tphl
For a detailed dscription of this file see netchange(5). Note
that this is an experimental interface and is likely to change
in the future.
Note that this command doesn't resimulate the circuit so that it
may leave the network in an inconsistent state. Usually this
command will be followed by an isim command (see below), if that
is not the case then it's up to the user to initilize the state
of the circuit. This command exists only for historical reasons
and will probably disappear in the future. It's use is
discouraged.
isim [filename]
Read net-change tokens from the specified file (see
netchange(5)) and incrementally resimulate the circuit up to the
current simulation time (not supported yet).
ires n The incremental algorithm keeps track of nodes deviating from
their past behavior as recorded in the network history. During
resimulation, a node is considered to deviate from its history
if it's new state is found to be different within n ns of its
previous state. This command allows for changing the
incremental resolution. With no arguments, it will print the
current resolution. The default resolution is 0 ns.
powlogfile [filename]
Opens filename for writting nodal transition reports. The format
of the report is the same you get when you trace a node normaly.
With no arguments powlogfile just closes the opened logfile and
prints out a power dissipation summary. Nodal transitions in
inputs are not included in the transition count.
powtrace [[-]node...]
The syntax of this command is the same as the normal t (trace)
command. If you want to trace and report power dissipation for
all the nodes just use powtrace *. Use powtrace -node if you
want to exclude some nodes.
powstep
Toggles whether dynamic power estimation is displayed after each
timestep. The ynamic power displayed will only be for the nodes
that have been selected using the powtrace command.
vsupply voltage
Sets the V variable for use in the P=CV^2/(2t) expression where
C is capacitance switched, and t is the timestep. The default
value for vsupply is 5.0 Volts.
sumcap Gives a sum of all nodal capcitances, not just those selected
with the powtrace command.
SEE ALSO
presim(1) (now obsolete)
rsim(1)
irsim-analyzer(3)
sim(5)
netchange(5)
3rd Berkeley Distribution IRSIM(1)