configs/topologies/CustomMesh.py - public/gem5 - Git at Google

 # Copyright (c) 2021 ARM Limited
 # All rights reserved.
 #
 # The license below extends only to copyright in the software and shall
 # not be construed as granting a license to any other intellectual
 # property including but not limited to intellectual property relating
 # to a hardware implementation of the functionality of the software
 # licensed hereunder.  You may use the software subject to the license
 # terms below provided that you ensure that this notice is replicated
 # unmodified and in its entirety in all distributions of the software,
 # modified or unmodified, in source code or in binary form.
 #
 # Redistribution and use in source and binary forms, with or without
 # modification, are permitted provided that the following conditions are
 # met: redistributions of source code must retain the above copyright
 # notice, this list of conditions and the following disclaimer;
 # redistributions in binary form must reproduce the above copyright
 # notice, this list of conditions and the following disclaimer in the
 # documentation and/or other materials provided with the distribution;
 # neither the name of the copyright holders nor the names of its
 # contributors may be used to endorse or promote products derived from
 # this software without specific prior written permission.
 #
 # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 # A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 # OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 # SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 #

 import math

 from m5.util import fatal
 from m5.params import *
 from m5.objects import *

 from m5.defines import buildEnv
 if buildEnv['PROTOCOL'] == 'CHI':
     import ruby.CHI_config as CHI

 from topologies.BaseTopology import SimpleTopology

 class CustomMesh(SimpleTopology):
     description = 'CustomMesh'

     def __init__(self, controllers):
         self.nodes = controllers

     #--------------------------------------------------------------------------
     # _makeMesh
     #--------------------------------------------------------------------------

     def _makeMesh(self, IntLink, link_latency, num_rows, num_columns,
                   cross_links, cross_link_latency):

         # East->West, West->East, North->South, South->North
         # XY routing weights
         link_weights = [1, 1, 2, 2]

         # East output to West input links
         for row in range(num_rows):
             for col in range(num_columns):
                 if (col + 1 < num_columns):
                     east_out = col + (row * num_columns)
                     west_in = (col + 1) + (row * num_columns)
                     llat = cross_link_latency \
                                 if (east_out, west_in) in cross_links \
                                 else link_latency
                     self._int_links.append(\
                                 IntLink(link_id=self._link_count,
                                         src_node=self._routers[east_out],
                                         dst_node=self._routers[west_in],
                                         dst_inport="West",
                                         latency = llat,
                                         weight=link_weights[0]))
                     self._link_count += 1

         # West output to East input links
         for row in range(num_rows):
             for col in range(num_columns):
                 if (col + 1 < num_columns):
                     east_in = col + (row * num_columns)
                     west_out = (col + 1) + (row * num_columns)
                     llat = cross_link_latency \
                                 if (west_out, east_in) in cross_links \
                                 else link_latency
                     self._int_links.append(\
                                 IntLink(link_id=self._link_count,
                                         src_node=self._routers[west_out],
                                         dst_node=self._routers[east_in],
                                         dst_inport="East",
                                         latency = llat,
                                         weight=link_weights[1]))
                     self._link_count += 1

         # North output to South input links
         for col in range(num_columns):
             for row in range(num_rows):
                 if (row + 1 < num_rows):
                     north_out = col + (row * num_columns)
                     south_in = col + ((row + 1) * num_columns)
                     llat = cross_link_latency \
                             if (north_out, south_in) in cross_links \
                             else link_latency
                     self._int_links.append(\
                                 IntLink(link_id=self._link_count,
                                         src_node=self._routers[north_out],
                                         dst_node=self._routers[south_in],
                                         dst_inport="South",
                                         latency = llat,
                                         weight=link_weights[2]))
                     self._link_count += 1

         # South output to North input links
         for col in range(num_columns):
             for row in range(num_rows):
                 if (row + 1 < num_rows):
                     north_in = col + (row * num_columns)
                     south_out = col + ((row + 1) * num_columns)
                     llat = cross_link_latency \
                             if (south_out, north_in) in cross_links \
                             else link_latency
                     self._int_links.append(\
                                 IntLink(link_id=self._link_count,
                                         src_node=self._routers[south_out],
                                         dst_node=self._routers[north_in],
                                         dst_inport="North",
                                         latency = llat,
                                         weight=link_weights[3]))
                     self._link_count += 1

     #--------------------------------------------------------------------------
     # distributeNodes
     #--------------------------------------------------------------------------

     def _createRNFRouter(self, mesh_router):
         # Create a zero-latency router bridging node controllers
         # and the mesh router
         node_router = self._Router(router_id = len(self._routers),
                                     latency = 0)
         self._routers.append(node_router)

         # connect node_router <-> mesh router
         self._int_links.append(self._IntLink( \
                                     link_id = self._link_count,
                                     src_node = node_router,
                                     dst_node = mesh_router,
                             latency = self._router_link_latency))
         self._link_count += 1

         self._int_links.append(self._IntLink( \
                                     link_id = self._link_count,
                                     src_node = mesh_router,
                                     dst_node = node_router,
                             latency = self._router_link_latency))
         self._link_count += 1

         return node_router

     def distributeNodes(self, node_placement_config, node_list):
         if len(node_list) == 0:
             return

         num_nodes_per_router = node_placement_config.num_nodes_per_router
         router_idx_list = node_placement_config.router_list

         if num_nodes_per_router:
             # evenly distribute nodes to all listed routers
             assert(len(router_idx_list)*num_nodes_per_router == len(node_list))

             for idx, node in enumerate(node_list):
                 mesh_router_idx = router_idx_list[idx // num_nodes_per_router]
                 router = self._routers[mesh_router_idx]

                 # Create another router bridging RNF node controllers
                 # and the mesh router
                 # for non-RNF nodes, node router is mesh router
                 if isinstance(node, CHI.CHI_RNF):
                     router = self._createRNFRouter(router)

                 # connect all ctrls in the node to node_router
                 ctrls = node.getNetworkSideControllers()
                 for c in ctrls:
                     self._ext_links.append(self._ExtLink(
                                     link_id = self._link_count,
                                     ext_node = c,
                                     int_node = router,
                                     latency = self._node_link_latency))
                     self._link_count += 1
         else:
             # try to circulate all nodes to all routers, some routers may be
             # connected to zero or more than one node.
             idx = 0
             for node in node_list:
                 ridx = router_idx_list[idx]
                 router = self._routers[ridx]

                 if isinstance(node, CHI.CHI_RNF):
                     router = self._createRNFRouter(router)
                 ctrls = node.getNetworkSideControllers()
                 for c in ctrls:
                     self._ext_links.append(self._ExtLink( \
                                                  link_id = self._link_count,
                                                  ext_node = c,
                                                  int_node = router,
                                             latency = self._node_link_latency))
                     self._link_count += 1
                 idx = (idx + 1) % len(router_idx_list)

     #--------------------------------------------------------------------------
     # makeTopology
     #--------------------------------------------------------------------------

     def makeTopology(self, options, network, IntLink, ExtLink, Router):
         assert(buildEnv['PROTOCOL'] == 'CHI')

         num_rows = options.num_rows
         num_cols = options.num_cols
         num_mesh_routers = num_rows * num_cols

         self._IntLink = IntLink
         self._ExtLink = ExtLink
         self._Router = Router

         if hasattr(options, 'router_link_latency'):
             self._router_link_latency = options.router_link_latency
             self._node_link_latency = options.node_link_latency
         else:
             print("WARNING: router/node link latencies not provided")
             self._router_link_latency = options.link_latency
             self._node_link_latency = options.link_latency

         # classify nodes into different types
         rnf_nodes = []
         hnf_nodes = []
         mem_nodes = []
         io_mem_nodes = []
         rni_dma_nodes = []
         rni_io_nodes = []

         # Notice below that all the type must be the same for all nodes with
         # the same base type.
         rnf_params = None
         hnf_params = None
         mem_params = None
         io_mem_params = None
         rni_dma_params = None
         rni_io_params = None

         def check_same(val, curr):
             assert(curr == None or curr == val)
             return val

         for n in self.nodes:
             if isinstance(n, CHI.CHI_RNF):
                 rnf_nodes.append(n)
                 rnf_params = check_same(type(n).NoC_Params, rnf_params)
             elif isinstance(n, CHI.CHI_HNF):
                 hnf_nodes.append(n)
                 hnf_params = check_same(type(n).NoC_Params, hnf_params)
             elif isinstance(n, CHI.CHI_SNF_MainMem):
                 mem_nodes.append(n)
                 mem_params = check_same(type(n).NoC_Params, mem_params)
             elif isinstance(n, CHI.CHI_SNF_BootMem):
                 io_mem_nodes.append(n)
                 io_mem_params = check_same(type(n).NoC_Params, io_mem_params)
             elif isinstance(n, CHI.CHI_RNI_DMA):
                 rni_dma_nodes.append(n)
                 rni_dma_params = check_same(type(n).NoC_Params, rni_dma_params)
             elif isinstance(n, CHI.CHI_RNI_IO):
                 rni_io_nodes.append(n)
                 rni_io_params = check_same(type(n).NoC_Params, rni_io_params)
             else:
                 fatal('topologies.CustomMesh: {} not supported'
                             .format(n.__class__.__name__))

         # Create all mesh routers
         self._routers = [Router(router_id=i, latency = options.router_latency)\
                                     for i in range(num_mesh_routers)]

         self._link_count = 0
         self._int_links = []
         self._ext_links = []

         # Create all the mesh internal links.
         self._makeMesh(IntLink, self._router_link_latency, num_rows, num_cols,
                        options.cross_links, options.cross_link_latency)

         # Place CHI_RNF on the mesh
         self.distributeNodes(rnf_params, rnf_nodes)

         # Place CHI_HNF on the mesh
         self.distributeNodes(hnf_params, hnf_nodes)

         # Place CHI_SNF_MainMem on the mesh
         self.distributeNodes(mem_params, mem_nodes)

         # Place all IO mem nodes on the mesh
         self.distributeNodes(io_mem_params, io_mem_nodes)

         # Place all IO request nodes on the mesh
         self.distributeNodes(rni_dma_params, rni_dma_nodes)
         self.distributeNodes(rni_io_params, rni_io_nodes)

         # Set up
         network.int_links = self._int_links
         network.ext_links = self._ext_links
         network.routers = self._routers

         pairing = getattr(options, 'pairing', None)
         if pairing != None:
             self._autoPairHNFandSNF(hnf_list, mem_ctrls, pairing)

     #--------------------------------------------------------------------------
     # _autoPair
     #--------------------------------------------------------------------------
     def _autoPairHNFandSNF(self, cache_ctrls, mem_ctrls, pairing):
         # Use the pairing defined by the configuration to reassign the
         # memory ranges
         pair_debug = False

         print("Pairing HNFs to SNFs")
         print(pairing)

         all_cache = []
         for c in cache_ctrls: all_cache.extend(c.getNetworkSideControllers())
         all_mem = []
         for c in mem_ctrls: all_mem.extend(c.getNetworkSideControllers())

         # checks and maps index from pairing map to component
         assert(len(pairing) == len(all_cache))

         def _tolist(val): return val if isinstance(val, list) else [val]

         for m in all_mem: m._pairing = []

         pairing_check = max(1, len(all_mem) / len(all_cache))
         for cidx,c in enumerate(all_cache):
             c._pairing = []
             for midx in _tolist(pairing[cidx]):
                 c._pairing.append(all_mem[midx])
                 if c not in all_mem[midx]._pairing:
                     all_mem[midx]._pairing.append(c)
             assert(len(c._pairing) == pairing_check)
             if pair_debug:
                 print(c.path())
                 for r in c.addr_ranges:
                     print("%s" % r)
                 for p in c._pairing:
                     print("\t"+p.path())
                     for r in p.addr_ranges:
                         print("\t%s" % r)

         # all must be paired
         for c in all_cache: assert(len(c._pairing) > 0)
         for m in all_mem: assert(len(m._pairing) > 0)

         # only support a single range for the main memory controllers
         tgt_range_start = all_mem[0].addr_ranges[0].start.value
         for mem in all_mem:
             for r in mem.addr_ranges:
                 if r.start.value != tgt_range_start:
                     fatal('topologies.CustomMesh: not supporting pairing of '\
                           'main memory with multiple ranges')

         # reassign ranges for a 1 -> N paring
         def _rerange(src_cntrls, tgt_cntrls, fix_tgt_peer):
             assert(len(tgt_cntrls) >= len(src_cntrls))

             def _rangeToBit(addr_ranges):
                 bit = None
                 for r in addr_ranges:
                     if bit == None:
                         bit = r.intlvMatch
                     else:
                         assert(bit == r.intlvMatch)
                 return bit

             def _getPeer(cntrl):
                 return cntrl.memory_out_port.peer.simobj

             sorted_src = list(src_cntrls)
             sorted_src.sort(key = lambda x: _rangeToBit(x.addr_ranges))

             # paired controllers need to have seq. interleaving match values
             intlvMatch = 0
             for src in sorted_src:
                 for tgt in src._pairing:
                     for r in tgt.addr_ranges:
                         r.intlvMatch = intlvMatch
                     if fix_tgt_peer:
                         _getPeer(tgt).range.intlvMatch = intlvMatch
                     intlvMatch = intlvMatch + 1

             # recreate masks
             for src in sorted_src:
                 for src_range in src.addr_ranges:
                     if src_range.start.value != tgt_range_start:
                         continue
                     new_src_mask = []
                     for m in src_range.masks:
                         # TODO should mask all the way to the max range size
                         new_src_mask.append(m | (m*2) | (m*4) |
                                                   (m*8) | (m*16))
                     for tgt in src._pairing:
                         paired = False
                         for tgt_range in tgt.addr_ranges:
                             if tgt_range.start.value == \
                                src_range.start.value:
                                 src_range.masks = new_src_mask
                                 new_tgt_mask = []
                                 lsbs = len(tgt_range.masks) - \
                                        len(new_src_mask)
                                 for i in range(lsbs):
                                     new_tgt_mask.append(tgt_range.masks[i])
                                 for m in new_src_mask:
                                     new_tgt_mask.append(m)
                                 tgt_range.masks = new_tgt_mask
                                 if fix_tgt_peer:
                                     _getPeer(tgt).range.masks = new_tgt_mask
                                 paired = True
                         if not paired:
                             fatal('topologies.CustomMesh: could not ' \
                                     'reassign ranges {} {}'.format(
                                     src.path(), tgt.path()))
         if len(all_mem) >= len(all_cache):
             _rerange(all_cache, all_mem, True)
         else:
             _rerange(all_mem, all_cache, False)

         if pair_debug:
             print("")
             for cidx,c in enumerate(all_cache):
                 assert(len(c._pairing) == pairing_check)
                 print(c.path())
                 for r in c.addr_ranges:
                     print("%s" % r)
                 for p in c._pairing:
                     print("\t"+p.path())
                     for r in p.addr_ranges:
                         print("\t%s" % r)
	# Copyright (c) 2021 ARM Limited
	# All rights reserved.
	#
	# The license below extends only to copyright in the software and shall
	# not be construed as granting a license to any other intellectual
	# property including but not limited to intellectual property relating
	# to a hardware implementation of the functionality of the software
	# licensed hereunder. You may use the software subject to the license
	# terms below provided that you ensure that this notice is replicated
	# unmodified and in its entirety in all distributions of the software,
	# modified or unmodified, in source code or in binary form.
	#
	# Redistribution and use in source and binary forms, with or without
	# modification, are permitted provided that the following conditions are
	# met: redistributions of source code must retain the above copyright
	# notice, this list of conditions and the following disclaimer;
	# redistributions in binary form must reproduce the above copyright
	# notice, this list of conditions and the following disclaimer in the
	# documentation and/or other materials provided with the distribution;
	# neither the name of the copyright holders nor the names of its
	# contributors may be used to endorse or promote products derived from
	# this software without specific prior written permission.
	#
	# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	# OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	#

	import math

	from m5.util import fatal
	from m5.params import *
	from m5.objects import *

	from m5.defines import buildEnv
	if buildEnv['PROTOCOL'] == 'CHI':
	import ruby.CHI_config as CHI

	from topologies.BaseTopology import SimpleTopology

	class CustomMesh(SimpleTopology):
	description = 'CustomMesh'

	def __init__(self, controllers):
	self.nodes = controllers

	#--------------------------------------------------------------------------
	# _makeMesh
	#--------------------------------------------------------------------------

	def _makeMesh(self, IntLink, link_latency, num_rows, num_columns,
	cross_links, cross_link_latency):

	# East->West, West->East, North->South, South->North
	# XY routing weights
	link_weights = [1, 1, 2, 2]

	# East output to West input links
	for row in range(num_rows):
	for col in range(num_columns):
	if (col + 1 < num_columns):
	east_out = col + (row * num_columns)
	west_in = (col + 1) + (row * num_columns)
	llat = cross_link_latency \
	if (east_out, west_in) in cross_links \
	else link_latency
	self._int_links.append(\
	IntLink(link_id=self._link_count,
	src_node=self._routers[east_out],
	dst_node=self._routers[west_in],
	dst_inport="West",
	latency = llat,
	weight=link_weights[0]))
	self._link_count += 1

	# West output to East input links
	for row in range(num_rows):
	for col in range(num_columns):
	if (col + 1 < num_columns):
	east_in = col + (row * num_columns)
	west_out = (col + 1) + (row * num_columns)
	llat = cross_link_latency \
	if (west_out, east_in) in cross_links \
	else link_latency
	self._int_links.append(\
	IntLink(link_id=self._link_count,
	src_node=self._routers[west_out],
	dst_node=self._routers[east_in],
	dst_inport="East",
	latency = llat,
	weight=link_weights[1]))
	self._link_count += 1

	# North output to South input links
	for col in range(num_columns):
	for row in range(num_rows):
	if (row + 1 < num_rows):
	north_out = col + (row * num_columns)
	south_in = col + ((row + 1) * num_columns)
	llat = cross_link_latency \
	if (north_out, south_in) in cross_links \
	else link_latency
	self._int_links.append(\
	IntLink(link_id=self._link_count,
	src_node=self._routers[north_out],
	dst_node=self._routers[south_in],
	dst_inport="South",
	latency = llat,
	weight=link_weights[2]))
	self._link_count += 1

	# South output to North input links
	for col in range(num_columns):
	for row in range(num_rows):
	if (row + 1 < num_rows):
	north_in = col + (row * num_columns)
	south_out = col + ((row + 1) * num_columns)
	llat = cross_link_latency \
	if (south_out, north_in) in cross_links \
	else link_latency
	self._int_links.append(\
	IntLink(link_id=self._link_count,
	src_node=self._routers[south_out],
	dst_node=self._routers[north_in],
	dst_inport="North",
	latency = llat,
	weight=link_weights[3]))
	self._link_count += 1

	#--------------------------------------------------------------------------
	# distributeNodes
	#--------------------------------------------------------------------------

	def _createRNFRouter(self, mesh_router):
	# Create a zero-latency router bridging node controllers
	# and the mesh router
	node_router = self._Router(router_id = len(self._routers),
	latency = 0)
	self._routers.append(node_router)

	# connect node_router <-> mesh router
	self._int_links.append(self._IntLink( \
	link_id = self._link_count,
	src_node = node_router,
	dst_node = mesh_router,
	latency = self._router_link_latency))
	self._link_count += 1

	self._int_links.append(self._IntLink( \
	link_id = self._link_count,
	src_node = mesh_router,
	dst_node = node_router,
	latency = self._router_link_latency))
	self._link_count += 1

	return node_router

	def distributeNodes(self, node_placement_config, node_list):
	if len(node_list) == 0:
	return

	num_nodes_per_router = node_placement_config.num_nodes_per_router
	router_idx_list = node_placement_config.router_list

	if num_nodes_per_router:
	# evenly distribute nodes to all listed routers
	assert(len(router_idx_list)*num_nodes_per_router == len(node_list))

	for idx, node in enumerate(node_list):
	mesh_router_idx = router_idx_list[idx // num_nodes_per_router]
	router = self._routers[mesh_router_idx]

	# Create another router bridging RNF node controllers
	# and the mesh router
	# for non-RNF nodes, node router is mesh router
	if isinstance(node, CHI.CHI_RNF):
	router = self._createRNFRouter(router)

	# connect all ctrls in the node to node_router
	ctrls = node.getNetworkSideControllers()
	for c in ctrls:
	self._ext_links.append(self._ExtLink(
	link_id = self._link_count,
	ext_node = c,
	int_node = router,
	latency = self._node_link_latency))
	self._link_count += 1
	else:
	# try to circulate all nodes to all routers, some routers may be
	# connected to zero or more than one node.
	idx = 0
	for node in node_list:
	ridx = router_idx_list[idx]
	router = self._routers[ridx]

	if isinstance(node, CHI.CHI_RNF):
	router = self._createRNFRouter(router)
	ctrls = node.getNetworkSideControllers()
	for c in ctrls:
	self._ext_links.append(self._ExtLink( \
	link_id = self._link_count,
	ext_node = c,
	int_node = router,
	latency = self._node_link_latency))
	self._link_count += 1
	idx = (idx + 1) % len(router_idx_list)

	#--------------------------------------------------------------------------
	# makeTopology
	#--------------------------------------------------------------------------

	def makeTopology(self, options, network, IntLink, ExtLink, Router):
	assert(buildEnv['PROTOCOL'] == 'CHI')

	num_rows = options.num_rows
	num_cols = options.num_cols
	num_mesh_routers = num_rows * num_cols

	self._IntLink = IntLink
	self._ExtLink = ExtLink
	self._Router = Router

	if hasattr(options, 'router_link_latency'):
	self._router_link_latency = options.router_link_latency
	self._node_link_latency = options.node_link_latency
	else:
	print("WARNING: router/node link latencies not provided")
	self._router_link_latency = options.link_latency
	self._node_link_latency = options.link_latency

	# classify nodes into different types
	rnf_nodes = []
	hnf_nodes = []
	mem_nodes = []
	io_mem_nodes = []
	rni_dma_nodes = []
	rni_io_nodes = []

	# Notice below that all the type must be the same for all nodes with
	# the same base type.
	rnf_params = None
	hnf_params = None
	mem_params = None
	io_mem_params = None
	rni_dma_params = None
	rni_io_params = None

	def check_same(val, curr):
	assert(curr == None or curr == val)
	return val

	for n in self.nodes:
	if isinstance(n, CHI.CHI_RNF):
	rnf_nodes.append(n)
	rnf_params = check_same(type(n).NoC_Params, rnf_params)
	elif isinstance(n, CHI.CHI_HNF):
	hnf_nodes.append(n)
	hnf_params = check_same(type(n).NoC_Params, hnf_params)
	elif isinstance(n, CHI.CHI_SNF_MainMem):
	mem_nodes.append(n)
	mem_params = check_same(type(n).NoC_Params, mem_params)
	elif isinstance(n, CHI.CHI_SNF_BootMem):
	io_mem_nodes.append(n)
	io_mem_params = check_same(type(n).NoC_Params, io_mem_params)
	elif isinstance(n, CHI.CHI_RNI_DMA):
	rni_dma_nodes.append(n)
	rni_dma_params = check_same(type(n).NoC_Params, rni_dma_params)
	elif isinstance(n, CHI.CHI_RNI_IO):
	rni_io_nodes.append(n)
	rni_io_params = check_same(type(n).NoC_Params, rni_io_params)
	else:
	fatal('topologies.CustomMesh: {} not supported'
	.format(n.__class__.__name__))

	# Create all mesh routers
	self._routers = [Router(router_id=i, latency = options.router_latency)\
	for i in range(num_mesh_routers)]

	self._link_count = 0
	self._int_links = []
	self._ext_links = []

	# Create all the mesh internal links.
	self._makeMesh(IntLink, self._router_link_latency, num_rows, num_cols,
	options.cross_links, options.cross_link_latency)

	# Place CHI_RNF on the mesh
	self.distributeNodes(rnf_params, rnf_nodes)

	# Place CHI_HNF on the mesh
	self.distributeNodes(hnf_params, hnf_nodes)

	# Place CHI_SNF_MainMem on the mesh
	self.distributeNodes(mem_params, mem_nodes)

	# Place all IO mem nodes on the mesh
	self.distributeNodes(io_mem_params, io_mem_nodes)

	# Place all IO request nodes on the mesh
	self.distributeNodes(rni_dma_params, rni_dma_nodes)
	self.distributeNodes(rni_io_params, rni_io_nodes)

	# Set up
	network.int_links = self._int_links
	network.ext_links = self._ext_links
	network.routers = self._routers

	pairing = getattr(options, 'pairing', None)
	if pairing != None:
	self._autoPairHNFandSNF(hnf_list, mem_ctrls, pairing)

	#--------------------------------------------------------------------------
	# _autoPair
	#--------------------------------------------------------------------------
	def _autoPairHNFandSNF(self, cache_ctrls, mem_ctrls, pairing):
	# Use the pairing defined by the configuration to reassign the
	# memory ranges
	pair_debug = False

	print("Pairing HNFs to SNFs")
	print(pairing)

	all_cache = []
	for c in cache_ctrls: all_cache.extend(c.getNetworkSideControllers())
	all_mem = []
	for c in mem_ctrls: all_mem.extend(c.getNetworkSideControllers())

	# checks and maps index from pairing map to component
	assert(len(pairing) == len(all_cache))

	def _tolist(val): return val if isinstance(val, list) else [val]

	for m in all_mem: m._pairing = []

	pairing_check = max(1, len(all_mem) / len(all_cache))
	for cidx,c in enumerate(all_cache):
	c._pairing = []
	for midx in _tolist(pairing[cidx]):
	c._pairing.append(all_mem[midx])
	if c not in all_mem[midx]._pairing:
	all_mem[midx]._pairing.append(c)
	assert(len(c._pairing) == pairing_check)
	if pair_debug:
	print(c.path())
	for r in c.addr_ranges:
	print("%s" % r)
	for p in c._pairing:
	print("\t"+p.path())
	for r in p.addr_ranges:
	print("\t%s" % r)

	# all must be paired
	for c in all_cache: assert(len(c._pairing) > 0)
	for m in all_mem: assert(len(m._pairing) > 0)

	# only support a single range for the main memory controllers
	tgt_range_start = all_mem[0].addr_ranges[0].start.value
	for mem in all_mem:
	for r in mem.addr_ranges:
	if r.start.value != tgt_range_start:
	fatal('topologies.CustomMesh: not supporting pairing of '\
	'main memory with multiple ranges')

	# reassign ranges for a 1 -> N paring
	def _rerange(src_cntrls, tgt_cntrls, fix_tgt_peer):
	assert(len(tgt_cntrls) >= len(src_cntrls))

	def _rangeToBit(addr_ranges):
	bit = None
	for r in addr_ranges:
	if bit == None:
	bit = r.intlvMatch
	else:
	assert(bit == r.intlvMatch)
	return bit

	def _getPeer(cntrl):
	return cntrl.memory_out_port.peer.simobj

	sorted_src = list(src_cntrls)
	sorted_src.sort(key = lambda x: _rangeToBit(x.addr_ranges))

	# paired controllers need to have seq. interleaving match values
	intlvMatch = 0
	for src in sorted_src:
	for tgt in src._pairing:
	for r in tgt.addr_ranges:
	r.intlvMatch = intlvMatch
	if fix_tgt_peer:
	_getPeer(tgt).range.intlvMatch = intlvMatch
	intlvMatch = intlvMatch + 1

	# recreate masks
	for src in sorted_src:
	for src_range in src.addr_ranges:
	if src_range.start.value != tgt_range_start:
	continue
	new_src_mask = []
	for m in src_range.masks:
	# TODO should mask all the way to the max range size
	new_src_mask.append(m \| (m2) \| (m4) \|
	(m8) \| (m16))
	for tgt in src._pairing:
	paired = False
	for tgt_range in tgt.addr_ranges:
	if tgt_range.start.value == \
	src_range.start.value:
	src_range.masks = new_src_mask
	new_tgt_mask = []
	lsbs = len(tgt_range.masks) - \
	len(new_src_mask)
	for i in range(lsbs):
	new_tgt_mask.append(tgt_range.masks[i])
	for m in new_src_mask:
	new_tgt_mask.append(m)
	tgt_range.masks = new_tgt_mask
	if fix_tgt_peer:
	_getPeer(tgt).range.masks = new_tgt_mask
	paired = True
	if not paired:
	fatal('topologies.CustomMesh: could not ' \
	'reassign ranges {} {}'.format(
	src.path(), tgt.path()))
	if len(all_mem) >= len(all_cache):
	_rerange(all_cache, all_mem, True)
	else:
	_rerange(all_mem, all_cache, False)

	if pair_debug:
	print("")
	for cidx,c in enumerate(all_cache):
	assert(len(c._pairing) == pairing_check)
	print(c.path())
	for r in c.addr_ranges:
	print("%s" % r)
	for p in c._pairing:
	print("\t"+p.path())
	for r in p.addr_ranges:
	print("\t%s" % r)