run free() on a memory location that was never allocated. This
error has no effect on anything, but correcting it prevents magic
from issuing a mysterious warning.
for BPEnum instead of putting it in the local frame. The structure
is half a megabyte and will severely limit the hierarchy depth
because it is used in the recursive cell search.
that are unattached (type = space) will cause magic to crash on
the command "lef write -hide"---The lowest level issue was in
SelectChunk(), so for good measure SelectChunk() now checks for
type == TT_SPACE, and "lef write" does also.
non-default rules and so can accurately capture wire widths other
than the technology LEF defaults (also corrected a bug with non-
default rules for "def read"). Corrected via handling in "def
write" to function as claimed (although the algorithm is still
naive and expects all contacts to be rectangular, which is usually
true but doesn't have to be).
record. Failure to use the right 8-byte real format can produce
bizarre results where a label's bounding box ends up in some random
place and messes up an entire top level circuit's bounding box.
with class, use, and shape information from the DEF file PINS record.
This is similar to what is done with LEF file annotation, but less
sophisticated (only erases an existing pin if it is an exact match
for pin name and location).
alternative separator "." instead of "/". This prevents other
routines that expect "/" to indicate a true hierarchy from treating
the label as hierarchical instead of flat, which should be the
correct handling for a flattened cell.
guarantee unique instance names during generation of each new
copy, but only afterward, in bulk. Otherwise the copy routine
has a runtime that is exponential with the number of cells being
copied. This and the last commit guarantee that the "flatten
-novendor" option works as advertised.
caused by other code that can move the plane of a device to match
the plane of a port. Solved by retaining the original plane of the
node in the extTransRec structure, and using that to determine the
device plane for purposes of calculating perimeters and not double-
counting contacts.
that queries a default layer width. Otherwise this can cause a
segfault, especially when a technology file has not been specified
and the minimum tech is in effect.
with slashes in the name (picks up the text after the last slash).
Also allowed the "gds library" command option to modify the
behavior of "gds read" (previously only affected "gds write") to
indicate that the GDS file is a library and that there are no top-
level contents, only subcell definitions. Also: Corrected a typo
from yesterday's commit that prevents magic from compiling (oops).
"Antenna checker should ignore vias in partial mode". I changed the
implementation by moving the correction into the antennaAccumFunc()
subroutine so that it skips the area calculations for the contacts,
avoiding unnecessary computation. Otherwise, it's the same (vias
do not contribute to the surface area of the antenna when calculating
antenna area in "partial" mode).
(OpenBSD/NetBSD/DragonFly support), and a change to the wrapper to allow
manual override of the number of icon columns (because sometimes some
window managers are clueless about the correct window dimensions).
make sure that the cell def's .ext is not marked "abstract".
Otherwise, "antennacheck" appears to run, but no output is
produced, and no reason is given.
prevents magic from crashing but does not do anything about the
fact that a non-existent node ended up in the .ext file, which
will have to be investigated.
Previous commits changed the port IDs to an integer rather than a
bitfield. However, the first and next commands were utilizing that
a -1 became a large positive integer when masked. This resulted in
the min port operations failing. Added a default comparison with -1
to fix the problem.
polygon cell has been created with the "gds polygon subcell"
option and the parent cell is read-only (vendor GDS), then the
polygon cell does not actually exist in the original GDS and
should not be output during a "gds write".
fringe capacitance halo where the default halo distance was set to
zero instead of one and caused divide-by-zero issues; (2) Found
extraction issues where labels picked up from cells flattened
during GDS reading cause the flattened/emptied cells to show up
in the extraction with extra pins that can mess up LVS. Solved
this by removing labels from flattened/emptied cells.
using the newer methods for nearest-edge searching and fringe area
of effect. Removed a same-net check in a routine that removes
capacitances that are redundant due to hierarchical overlaps; these
redundancies must be checked on shapes within the same net. Corrected
(again) an out-of-clip-bounds check.
reading GDS files, caused by an unneeded change to pass both
the "original" filename and the actual filename when handling
compressed files---The original filename is unneeded.
(2) Implemented several new methods for parasitic extraction. The
first is an option offset value to apply to sidewall calculations.
This handles issues where actual wire separation is different
from drawn wire separation, which can be significant for the
1/d calculation of sidewall coupling. The second method is to
use the recently-added fringe halo to compute the coupling of the
fringe capacitance to nearby wires. Prior to this change, all
fringe capacitance was applied to surfaces directly under a wire
edge as if the fringe capacitance did not extend outward from the
edge. Now the capacitance is properly pro-rated for the position
of any overlapped shape inside the fringing field. Finally, the
third method added is a new search algorithm for finding the
nearest shapes along the length of a boundary. This is used for
sidewall coupling and fringe shielding, where the nearest shape
dominates the coupling, and any shapes behind are shielded and
may (to first order) be ignored. Previously, the entire halo
was searched without regard to shapes shielding other shapes
behind, and a recent correction added an ad-hoc search for
blocking shapes that was inefficient and not always correct.
The new method is both efficient and accurate.
to the fringe shielding calculations, which uses very similar code and
suffered the same problem of not being able to recognize when another
shape was between the two edges under consideration. Fixing this
makes the fringe shielding calculations symmetric, as they should be.
computing coupling to shapes that are shielded by other
intervening shapes. This is not a perfect solution but will
properly handle all but a few pathological cases.
Compression levels of the output can be controlled with the "gds
compress [<value>]" command, where <value> 0 (default) is uncompressed
output, 6 is "normal" gzip compression, and 9 is maximum compression.
pointing GDS_FILE to a compressed filename when using "gds readonly
true" on a compressed file. The start and end pointers still point
to data bounds in the uncompressed file.
of systems calls to "gzip" and "gunzip". A compressed GDS file can
be made simply by doing "gds write <name>.gds.gz", and can be read
simply by doing "gds read <name>.gds.gz". Names of compressed files
can be put in the GDS_FILE property of a cell.
Tim Edwards
Brad Smith
Anton Blanchard
mrg