Python Interface for Hurricane / Coriolis

The (almost) complete interface of Hurricane is exported as a Python module and some part of the other components of Coriolis (each one in a separate module). The interface has been made to mirror as closely as possible the C++ one, so the C++ doxygen documentation could be used to write code with either languages.

Summary of the C++ Documentation

A script could be run directly in text mode from the command line or through the graphical interface (see Executing Python Scripts in Cgt).

Asides for this requirement, the python script can contain anything valid in Python, so don’t hesitate to use any package or extention.

Small example of Python/Stratus script:

from Hurricane import *
from Stratus   import *

def doSomething ():
    # ...
    return

def ScriptMain ( **kw ):
  editor = None
  if kw.has_key('editor') and kw['editor']:
    editor = kw['editor']
    stratus.setEditor( editor )

  doSomething()
  return

if __name__ == "__main__" :
  kw           = {}
  success      = ScriptMain( **kw )
  shellSuccess = 0
  if not success: shellSuccess = 1

  sys.exit( shellSuccess )
      ScriptMain ()

This typical script can be executed in two ways:

  1. Run directly as a Python script, thanks to the

    if __name__ == "__main__" :

    part (this is standart Python). It is a simple adapter that will calls ScriptMain().

  2. Through cgt, either in text or graphical mode. In that case, the ScriptMain() is directly called trough a sub-interpreter. The arguments of the script are passed through the **kw dictionnary.

    **kw Dictionnary
    Parameter Key/Name Contents type
    'cell' A Hurricane cell on which to work. Depending on the context, it may be None. For example, when run from cgt, it the cell currently loaded in the viewer, if any.
    'editor' The viewer from which the script is run, when lauched through cgt.

Plugins

Plugins are Python scripts specially crafted to integrate with cgt. Their entry point is a ScriptMain() method as described in Python Interface to Coriolis. They can be called by user scripts through this method.

Chip Placement

Automatically perform the placement of a complete chip. This plugin, as well as the other P&R tools expect a specific top-level hierarchy for the design. The top-level hierarchy must contains the instances of all the I/O pads and exactly one instance of the chip’s core model.

Chip Top Structure

The designer must provide a configuration file that define the rules for the placement of the top-level hierarchy (that is, the pads and the core). This file must be named after the chip’s name, by appending _chip.py (obviously, it is a Python file). For instance if the chip netlist file is called amd2901_crl.vst, then the configuration file must be named amd2901_crl_chip.vst.

Example of chip placement configuration file (for AM2901):

chip = \
  { 'pads.south'     : [ 'p_a3'     , 'p_a2'     , 'p_a1'     , 'p_r0'
                       , 'p_vddick0', 'p_vssick0', 'p_a0'     , 'p_i6'
                       , 'p_i8'     , 'p_i7'     , 'p_r3'     ]
  , 'pads.east'      : [ 'p_zero'   , 'p_i0'     , 'p_i1'     , 'p_i2'
                       , 'p_vddeck0', 'p_vsseck0', 'p_q3'     , 'p_b0'
                       , 'p_b1'     , 'p_b2'     , 'p_b3'     ]
  , 'pads.north'     : [ 'p_noe'    , 'p_y3'     , 'p_y2'     , 'p_y1'
                       , 'p_y0'     , 'p_vddeck1', 'p_vsseck1', 'p_np'
                       , 'p_ovr'    , 'p_cout'   , 'p_ng'     ]
  , 'pads.west'      : [ 'p_cin'    , 'p_i4'     , 'p_i5'     , 'p_i3'
                       , 'p_ck'     , 'p_d0'     , 'p_d1'     , 'p_d2'
                       , 'p_d3'     , 'p_q0'     , 'p_f3'     ]
  , 'core.size'      : ( 1500, 1500 )
  , 'chip.size'      : ( 3000, 3000 )
  , 'chip.clockTree' : True
  }

The file must contain one dictionnary named chip.

Chip Dictionnary
Parameter Key/Name Value/Contents type
'pad.south' Ordered list (left to right) of pad instances names to put on the south side of the chip
'pad.east' Ordered list (down to up) of pad instances names to put on the east side of the chip
'pad.north' Ordered list (left to right) of pad instances names to put on the north side of the chip
'pad.west' Ordered list (down to up) of pad instances names to put on the west side of the chip
'core.size' The size of the core (to be used by the placer)
'chip.size' The size of the whole chip. The sides must be great enough to accomodate all the pads
'chip.clockTree' Whether to generate a clock tree or not. This calls the ClockTree plugin

Configuration parameters, defaults are defined in etc/coriolis2/<STECHNO>/plugins.conf.

Parameter Identifier Type Default
Chip Plugin Parameters
chip.block.rails.count TypeInt 5
The minimum number of rails around the core block. Must be odd and suppérior to 5. One rail for the clock and at least two pairs of power/grounds
chip.block.rails.hWidth TypeInt 12
The horizontal with of the rails
chip.block.rails.vWidth TypeInt 12
The vertical with of the rails
chip.block.rails.hSpacing TypeInt 6
The spacing, edge to edge of two adjacent horizontal rails
chip.block.rails.vSpacing TypeInt 6
The spacing, edge to edge of two adjacent vertical rails
chip.pad.pck TypeString pck_px
The model name of the pad connected to the chip external clock
chip.pad.pvddeck TypeString pvddeck_px
The model name of the pad connected to the vdde (external power) and suppling it to the core
chip.pad.pvsseck TypeString pvsseck_px
The model name of the pad connected to the vsse (external ground) and suppling it to the core
chip.pad.pvddick TypeString pvddick_px
The model name of the pad connected to the vddi (internal power) and suppling it to the core
chip.pad.pvssick TypeString pvssick_px
The model name of the pad connected to the vssi (internal ground) and suppling it to the core

Note

If no clock tree is generated, then the clock rail is not created. So even if the requested number of rails chip.block.rails.count is, say 5, only four rails (2* power, 2* ground) will be generateds.

Clock Tree

Insert a clock tree into a block. The clock tree uses the H strategy. The clock net is splitted into sub-nets, one for each branch of the tree.

  • On chips design, the sub-nets are createds in the model of the core block (then trans-hierarchically flattened to be shown at chip level).

  • On blocks, the sub nets are created directly in the top block.

  • The sub-nets are named according to a simple geometrical scheme. A common prefix ck_htree, then one postfix by level telling on which quarter of plane the sub-clock is located:

    1. _bl: bottom left plane quarter.
    2. _br: bottom right plane quarter.
    3. _tl: top left plane quarter.
    4. _tr: top right plane quarter.

    We can have ck_htree_bl, ck_htree_bl_bl, ch_htree_bl_tl and so on.

The clock tree plugin works in four steps:

  1. Build the clock tree: creates the top-block abutment box, compute the levels of H tree neededs and place the clock buffers.
  2. Once the clock buffers are placed, calls the placer (Etesian) to place the ordinary standart cells, whithout disturbing clock H-tree buffers.
  3. At this point we know the exact positions of all the DFFs, so we can connect them to the nearest H-tree leaf clock signal.
  4. Leaf clock signals that are not connecteds to any DFFs are removed.

Netlist reorganisation:

  • Obviously the top block or chip core model netlist is modificated to contains all the clock sub-nets. The interface is not changed.
  • If the top block contains instances of other models and those models contains DFFs that get re-connecteds to the clock sub-nets (from the top level). Change both the model netlist and interface to propagate the relevant clock sub-nets to the instanciated model. The new model with the added clock signal is renamed with a _clocked suffix. For example, the sub-block model ram.vst will become ram_clocked.vst.

Note

If you are to re-run the clock tree plugin on a netlist, be careful to erase any previously generated _clocked file (both netlist and layout: rm *.clocked.{ap,vst}). And restart cgt to clear it’s memory cache.

Configuration parameters, defaults are defined in etc/coriolis2/<STECHNO>/plugins.conf.

Parameter Identifier Type Default
ClockTree Plugin Parameters
clockTree.minimumSide TypeInt 300
The minimum size below which the clock tree will stop to perform quadri-partitions
clockTree.buffer TypeString buf_x2
The buffer model to use to drive sub-nets
clockTree.placerEngine TypeString Etesian
The placer to use. Other value is Mauka the simulated annealing placer which will go into retirement very soon

Recursive-Save (RSave)

Perform a recursive top down save of all the models from the top cell loaded in cgt. Force a write of any non-terminal model. This plugin is used by the clock tree plugin after the netlist clock sub-nets creation.

A Simple Example: AM2901

To illustrate the capabilities of Coriolis tools and Python scripting, a small example, derived from the Alliance AM2901 is supplied.

This example contains only the synthetized netlists and the doChip.py script which perform the whole P&R of the design.

You can generate the chip using one of the following method:

  1. Command line mode: directly run the script:

    dummy@lepka:AM2901$ ./doChip -V --cell=amd2901
  2. Graphic mode: launch cgt, load chip netlist amd2901 (the top cell) then run the Python script doChip.py.

Note

Between two consecutive run, be sure to erase the netlist/layout generateds:

dummy@lepka:AM2901$ rm *_clocked*.vst *.ap