def apply(self, sdfg):
state = sdfg.nodes()[self.subgraph[StartStateElimination.start_state]]
# Move assignments to the nested SDFG node's symbol mappings
node = sdfg.parent_nsdfg_node
edge = sdfg.out_edges(state)[0]
for k, v in edge.data.assignments.items():
node.symbol_mapping[k] = v
sdfg.remove_node(state)
def apply(self, _, sdfg):
state = self.start_state
# Move assignments to the nested SDFG node's symbol mappings
node = sdfg.parent_nsdfg_node
edge = sdfg.out_edges(state)[0]
for k, v in edge.data.assignments.items():
node.symbol_mapping[k] = v
sdfg.remove_node(state)
def apply(self, sdfg):
state = sdfg.nodes()[self.subgraph[EndStateElimination._end_state]]
# Handle orphan symbols (due to the deletion the incoming edge)
edge = sdfg.in_edges(state)[0]
sym_assign = edge.data.assignments.keys()
sdfg.remove_node(state)
# Remove orphan symbols
for sym in sym_assign:
if sym in sdfg.free_symbols:
sdfg.remove_symbol(sym)
def apply(self, _, sdfg):
state = self.end_state
# Handle orphan symbols (due to the deletion the incoming edge)
edge = sdfg.in_edges(state)[0]
sym_assign = edge.data.assignments.keys()
sdfg.remove_node(state)
# Remove orphan symbols
for sym in sym_assign:
if sym in sdfg.free_symbols:
sdfg.remove_symbol(sym)
def apply(self, sdfg):
first_state = sdfg.nodes()[self.subgraph[StateFusion._first_state]]
second_state = sdfg.nodes()[self.subgraph[StateFusion._second_state]]
# Remove interstate edge(s)
edges = sdfg.edges_between(first_state, second_state)
for edge in edges:
if edge.data.assignments:
for src, dst, other_data in sdfg.in_edges(first_state):
other_data.assignments.update(edge.data.assignments)
sdfg.remove_edge(edge)
# Special case 1: first state is empty
if first_state.is_empty():
sdutil.change_edge_dest(sdfg, first_state, second_state)
sdfg.remove_node(first_state)
return
# Special case 2: second state is empty
if second_state.is_empty():
sdutil.change_edge_src(sdfg, second_state, first_state)
sdutil.change_edge_dest(sdfg, second_state, first_state)
sdfg.remove_node(second_state)
return
# Normal case: both states are not empty
# Find source/sink (data) nodes
first_input = [
node for node in sdutil.find_source_nodes(first_state)
if isinstance(node, nodes.AccessNode)
]
first_output = [
node for node in sdutil.find_sink_nodes(first_state)
if isinstance(node, nodes.AccessNode)
]
second_input = [
node for node in sdutil.find_source_nodes(second_state)
if isinstance(node, nodes.AccessNode)
]
# first input = first input - first output
first_input = [
node for node in first_input
if next((x for x in first_output
if x.label == node.label), None) is None
]
# Merge second state to first state
# First keep a backup of the topological sorted order of the nodes
order = [
x for x in reversed(list(nx.topological_sort(first_state._nx)))
if isinstance(x, nodes.AccessNode)
]
for node in second_state.nodes():
first_state.add_node(node)
for src, src_conn, dst, dst_conn, data in second_state.edges():
first_state.add_edge(src, src_conn, dst, dst_conn, data)
# Merge common (data) nodes
for node in second_input:
if first_state.in_degree(node) == 0:
n = next((x for x in order if x.label == node.label), None)
if n:
sdutil.change_edge_src(first_state, node, n)
first_state.remove_node(node)
n.access = dtypes.AccessType.ReadWrite
# Redirect edges and remove second state
sdutil.change_edge_src(sdfg, second_state, first_state)
sdfg.remove_node(second_state)
if Config.get_bool("debugprint"):
StateFusion._states_fused += 1
def apply(self, sdfg):
state = sdfg.nodes()[self.subgraph[EndStateElimination._end_state]]
sdfg.remove_node(state)
def apply(self, sdfg):
if isinstance(self.subgraph[StateFusion.first_state], SDFGState):
first_state: SDFGState = self.subgraph[StateFusion.first_state]
second_state: SDFGState = self.subgraph[StateFusion.second_state]
else:
first_state: SDFGState = sdfg.node(
self.subgraph[StateFusion.first_state])
second_state: SDFGState = sdfg.node(
self.subgraph[StateFusion.second_state])
# Remove interstate edge(s)
edges = sdfg.edges_between(first_state, second_state)
for edge in edges:
if edge.data.assignments:
for src, dst, other_data in sdfg.in_edges(first_state):
other_data.assignments.update(edge.data.assignments)
sdfg.remove_edge(edge)
# Special case 1: first state is empty
if first_state.is_empty():
sdutil.change_edge_dest(sdfg, first_state, second_state)
sdfg.remove_node(first_state)
if sdfg.start_state == first_state:
sdfg.start_state = sdfg.node_id(second_state)
return
# Special case 2: second state is empty
if second_state.is_empty():
sdutil.change_edge_src(sdfg, second_state, first_state)
sdutil.change_edge_dest(sdfg, second_state, first_state)
sdfg.remove_node(second_state)
if sdfg.start_state == second_state:
sdfg.start_state = sdfg.node_id(first_state)
return
# Normal case: both states are not empty
# Find source/sink (data) nodes
first_input = [
node for node in sdutil.find_source_nodes(first_state)
if isinstance(node, nodes.AccessNode)
]
first_output = [
node for node in sdutil.find_sink_nodes(first_state)
if isinstance(node, nodes.AccessNode)
]
second_input = [
node for node in sdutil.find_source_nodes(second_state)
if isinstance(node, nodes.AccessNode)
]
top2 = top_level_nodes(second_state)
# first input = first input - first output
first_input = [
node for node in first_input
if next((x for x in first_output
if x.data == node.data), None) is None
]
# Merge second state to first state
# First keep a backup of the topological sorted order of the nodes
sdict = first_state.scope_dict()
order = [
x for x in reversed(list(nx.topological_sort(first_state._nx)))
if isinstance(x, nodes.AccessNode) and sdict[x] is None
]
for node in second_state.nodes():
if isinstance(node, nodes.NestedSDFG):
# update parent information
node.sdfg.parent = first_state
first_state.add_node(node)
for src, src_conn, dst, dst_conn, data in second_state.edges():
first_state.add_edge(src, src_conn, dst, dst_conn, data)
top = top_level_nodes(first_state)
# Merge common (data) nodes
for node in second_input:
# merge only top level nodes, skip everything else
if node not in top2:
continue
if first_state.in_degree(node) == 0:
candidates = [
x for x in order if x.data == node.data and x in top
]
if len(candidates) == 0:
continue
elif len(candidates) == 1:
n = candidates[0]
else:
# Choose first candidate that intersects memlets
for cand in candidates:
if StateFusion.memlets_intersect(
first_state, [cand], False, second_state,
[node], True):
n = cand
break
else:
# No node intersects, use topologically-last node
n = candidates[0]
sdutil.change_edge_src(first_state, node, n)
first_state.remove_node(node)
n.access = dtypes.AccessType.ReadWrite
# Redirect edges and remove second state
sdutil.change_edge_src(sdfg, second_state, first_state)
sdfg.remove_node(second_state)
if sdfg.start_state == second_state:
sdfg.start_state = sdfg.node_id(first_state)
def apply(self, sdfg):
first_state = sdfg.nodes()[self.subgraph[StateFusion._first_state]]
second_state = sdfg.nodes()[self.subgraph[StateFusion._second_state]]
# Remove interstate edge(s)
edges = sdfg.edges_between(first_state, second_state)
for edge in edges:
if edge.data.assignments:
for src, dst, other_data in sdfg.in_edges(first_state):
other_data.assignments.update(edge.data.assignments)
sdfg.remove_edge(edge)
# Special case 1: first state is empty
if first_state.is_empty():
nxutil.change_edge_dest(sdfg, first_state, second_state)
sdfg.remove_node(first_state)
return
# Special case 2: second state is empty
if second_state.is_empty():
nxutil.change_edge_src(sdfg, second_state, first_state)
nxutil.change_edge_dest(sdfg, second_state, first_state)
sdfg.remove_node(second_state)
return
# Normal case: both states are not empty
# Find source/sink (data) nodes
first_input = [
node for node in nxutil.find_source_nodes(first_state)
if isinstance(node, nodes.AccessNode)
]
first_output = [
node for node in nxutil.find_sink_nodes(first_state)
if isinstance(node, nodes.AccessNode)
]
second_input = [
node for node in nxutil.find_source_nodes(second_state)
if isinstance(node, nodes.AccessNode)
]
# first input = first input - first output
first_input = [
node for node in first_input
if next((x for x in first_output
if x.label == node.label), None) is None
]
# Merge second state to first state
for node in second_state.nodes():
first_state.add_node(node)
for src, src_conn, dst, dst_conn, data in second_state.edges():
first_state.add_edge(src, src_conn, dst, dst_conn, data)
# Merge common (data) nodes
for node in first_input:
try:
old_node = next(x for x in second_input
if x.label == node.label)
except StopIteration:
continue
nxutil.change_edge_src(first_state, old_node, node)
first_state.remove_node(old_node)
second_input.remove(old_node)
for node in first_output:
try:
new_node = next(x for x in second_input
if x.label == node.label)
except StopIteration:
continue
nxutil.change_edge_dest(first_state, node, new_node)
first_state.remove_node(node)
second_input.remove(new_node)
# Redirect edges and remove second state
nxutil.change_edge_src(sdfg, second_state, first_state)
sdfg.remove_node(second_state)
if Config.get_bool("debugprint"):
StateFusion._states_fused += 1
