restruct_fsm - Restructre the STG of a finite state machine to reduce power dissipation. _________________________________________________________________ restruct_fsm [-D ] [-d ] [-E] [-F ] [-f ] [-h] [-N] [-o ] [-p ] [-s ] [-t ] [-v] This command implements an STG restructuring algorithm that exploits the existence of equivalent states to decrease power dissipation, not necessarily by collapsing the equivalence states, but by redirecting transitions in the state transition graph (STG). This algorithm is based on monolitic transition relation. The complexity of the algorithm in general increases with an increase in the size of the STG. The number of states and edges in the STG are exponential in the number of state variables and primary inputs. The memory utilization is not necessarily exponential due to symbolic representation of the STG. For more details see, "A Symbolic Algorithm for Low-Power Sequential Synthesis", ISLPED 97. This command works only if VIS is compiled with CUDD package. The algorithm can handle circuits described in both BLIF and BLIF-MV format. However, multi-valued variables are not supported. Also, the final synthesized circuit (network implementation of the restructured STG) is available only in BLIF format. The sequential circuit should have a single initial state. A network should have been created for the circuit and its primary inputs and state variables assigned BDD ids prior to the invocation of this command. A network can be created by the command flatten_hierarchy and command static_order assigns BDD ids to the input and state variables. The command proceeds by creating BDDs for the outputs and next state functions. An FSM data structure is then created on which subsequent operations are performed. After the STG is restructured a new circuit is synthesized by symbolic factorization based on Zero-Suppressed Decision Diagrams (ZDDs). The final synthesized circuit is a file in BLIF format with ".ml.blif" as the extension. The typical command flow in vis is the following: vis> read_blif foo.blif vis> flatten_hierarchy vis> static_order vis> dynamic_var_ordering -e sift vis> restruct_fsm In the above case example, the final synthesized circuit is MODEL.ml.blif if the name of the design in foo.blif is MODEL. Command options: -A Allow realignment (during symbolic factorization) of ZDDs after BDD reordering and vice versa. This option is effective when only one of the BDD or ZDD variable reordering is enabled. -D Specify the output file name for synthesized circuit. File extension is not necessary. By default, the model name of the circuit is used. For example, -D foobar, will result in foobar.ml.blif -d Choose a divisor. See synthesize_network for more details. -E Print the number of equivalence classes in the FSM. -F File with primary input probabilities, one per line. input_name -f Choose a method for factorization. See synthesize_network for more details. -h Print command usage. -i Specify the prefix to be used to generate names for internal nodes during synthesis. By default, the prefix is "_n". -N Expand the reachable set R to include those states which are equivalent to R but not reachable. The default is not to include such states. -o File to output BDD variable ordering after the restructured circuit is synthesized. -R Allow reordering in BDD and/or ZDD variables during symbolic factorization stage. 0 : (default) No reordering neither in BDD nor in ZDD. 1 : Allows reordering only in BDD, not in ZDD. 2 : Allows reordering only in ZDD, not in BDD. 3 : Allows reordering both in BDD and in ZDD. -s Heuristic to perform restructuring. Consider a fragment of an STG containing states A,B and C and an edge from A to B. Let B and C be equivalent. Since B and C are equivalent, it is possible to change the transition between A and B to A and C. In the more general case, the choice can be driven by different cost constraints. The following are the heuristics: ham : Hamming distance based heuristic. An edge is chosen that reduces the Hamming distance (or state bit transitions) between the states. fanin : Fanin oriented heuristic. A representative from the equivalence class is chosen that reduces the total average state bit switching on the incoming edges. faninout : Fanin-Fanout oriented heuristic. A representative from the equivalence class is chosen that reduces the total average state bit switching on the incoming as well as outgoing edges. cproj : A simple C-Projection. A representative from the equivalence class is chosen which is closest to the initial state. The distance d(x,y) is defined as: sum_{i=0}^{N-1}(|x_i - y_i| cdot 2^{N-i-1}). -T Try to share more nodes during symbolic factorization. Existing divisors are checked for potential reuse before extracting divisors from the current boolean function. -t Time in seconds allowed to complete the command. If the computation time goes above that limit, the process is aborted. The default is no limit. -v Turn on verbosity. See also command : synthesize_network _________________________________________________________________ Last updated on 20050519 10h16