res_verify - Verifies a combinational circuit using residue arithmetic. _________________________________________________________________ res_verify [-b] [-d ] [-h] -i [-m ] [-n ] {-o | -O} [-s ] [-t ] This command performs residue verification between two networks. The method used is based on residue arithmetic and the Chinese Remainder theorem; it is described in [1] ftp://vlsi.colorado.edu/pub/fmcad96.ps. Verification is performed by interpreting the outputs of the circuits as integers and verifying the residues of the outputs with respect to a set of moduli. The choice of moduli is directed by the Chinese Remainder Theorem in order to prove equivalence of the two circuits. This method works well with multipliers and possibly other arithmetic circuits (due to its dependence on residue arithmetic). For the same reason, it is necessary to specify an output order which determines how the outputs are interpreted as integers. Discretion should be exercised in applying this method to general combinational circuits. Residue verification is available only if vis is linked with the cu BDD package. (This is the default.) It reads both blif and blif-mv files. However, it does NOT support multi-valued variables. Residue verification is primarily for combinational verification, but may be applied to sequential circuits with the same state encoding. The latch outputs are then considered to be combinational inputs of the circuits and the latch inputs and reset are considered to be combinational outputs of the circuits. There are two ways to perform residue verification in this package. As a first option, two files describing two networks, the specification and the implementation, (in the same format, blif or blif-mv, see option -b) are given in the command line; the procedure tries to verify the equivalence of the combinational outputs as functions of the combinational inputs. vis> res_verify -o network.order -i network1.blif -s network2.blif In this case both networks are read in, flattened and the verification is performed between the combinational outputs of both networks. The -i option denotes the implementation file and the -s option denotes the specification file. The -o option specifies the order of outputs for the circuits (See Command Options below for detailed explanation). A second way to perform the verification is as follows. The specification network is taken from a hierarchy already read into VIS. Then the res_verify command compares that specification against an implementation network obtained from the file in the command line. Any previous verification, performed with the specification, can be used towards the next verification task only if the same implementation circuit is being verified against and the same number of outputs have been directly verified with sucess in the previous attempt. The typical sequence of commands given to perform such task would be: vis> read_blifmv network1.mv vis> flatten_hierarchy vis> res_verify -o network.order -i network2.mv If the hierarchy has been read but no flattened network exists at the current node, the command will return without doing anything. If one of the networks used is the one in the current node in the hierarchy, then the information regarding the verification process will be stored in that network. Note: It is important to keep the specification distinct from the implementation because most parameters specified for the res_verify command are with respect to the specification. For example, the output order is specified with respect to the specification. The file that is read in first in the second format, is considered to be the specification. There is an option to directly verify some outputs by building the BDDs for the corresponding outputs of the 2 circuits. In that case, if the user wants to use an initial ordering, the only way to do it is the second method and reading in the network, one may specify the initial order using static order. The command does not repeat residue verification if the same specification-implementation pair have been verified with success and the same number of directly verified outputs have been verified in the previous attempt. Relevant flags to be set using the set command: residue_verbosity Default is 0, turns on verbosity to the desired level between 0 and 5. residue_ignore_direct_verified_outputs Default 0 (FALSE). If 1, then ignores directly verified outputs during residue verification. residue_top_var Default "msb". The 2 possible values are "msb" and lsb"; this puts the most/least significant bit near the top or bottom of the residue decision diagram. residue_autodyn_residue_verif Default 0 (FALSE). If 1, turns on dynamic reordering during residue verification. residue_residue_dyn_method Default "groupsift". Specifies the method for dynamic reordering during residue verification. Other methods supported are "same" (same as before), "none", "random", "randompivot", "sift", "siftconverge", "symmsiftconverge", "symmsift", "window2", "window3", "window4", "window2converge", "window3converge", "window4converge", "groupsift", "groupsiftconverge", "anneal", "genetic", "linear", "linearconverge", "exact". residue_autodyn_direct_verif Default 0 (FALSE). If 1, turns on dynamic reordering during direct verification. residue_direct_dyn_method Default "groupsift". Specifies the method for dynamic reordering during direct verification. Other methods supported are "same" (same as before), "none", "random", "randompivot", "sift", "siftconverge", "symmsiftconverge", "symmsift", "window2", "window3", "window4", "window2converge", "window3converge", "window4converge", "groupsift", "groupsiftconverge", "anneal", "genetic", "linear", "linearconverge", "exact". residue_layer_schedule Default "alap". This is a flag to specify the layering strategy of the networks. The 2 options are "asap" (as soon as possible) and "alap" (as late as possible). residue_layer_size Default largest layer size in network. Specifies the maximum layer size that can be composed in (relevant for vector composition only). residue_composition_method Default "vector". Specifies the composition method to be used in composing the network into the residue ADD. The options are "vector", "onegate", "preimage" and "superG". Command Options: -b If this option is specified, the specification and the implementation files read are considered to be in blif-mv format. Default is blif format. -d n This option specifies the number of outputs to be directly verified. That is, for n least significant outputs of the circuit, this command performs like comb_verify. The actual outputs are read off the output order array. Since the output order array is specified starting with the MSB, the number of directly verified outputs will be a chunk of the bottom part of the output order array. The option "-d all" sets the number of directly verified outputs to the number of combinational outputs in the circuit i.e., all outputs are directly verified. The direct verification for small BDD sizes is faster and overall reduces the number of primes to be used in residue verification. In general, one output is checked at a time against the corresponding output of the other network and consequently , this method may be fast and use less memory resources. IMPORTANT: It is possible to specify an initial order for the direct verification. This is done by reading in the specification file and using static_order to specify the initial order. The implementation will get the same order as the specification. When specifying the initial order, one must be careful not to specify the -s option in the res_verify command. The -s option reads in the specification file again and the initial order is lost. -h Print the command usage. -i Implementation network to perform verification against. The file must be in blif format unless -b is specified, in which case the file is taken to be in blif-mv format. The blif format is the default. -m Optional file name specifying the matching pair of output names between the two networks. If not specified, it is assumed that all outputs have identical names. This option is useful when verifying two circuits whose output names do not match. The file will give pairs of the form name1 name2 to be considered as corresponding outputs in the verification process. In each pair, name1 may belong to the specification and name2 to the implementation or vice-versa. The matching procedure is not capable of dealing with some special situations. For example, when two outputs, one of each network have the same name, they must correspond to the same output. Partial orders may not be specified. -n Optional file name specifying the matching pair of input names between the two networks. If not specified, it is assumed that all inputs have identical names. This option is useful when verifying two circuits whose input names do not match. The file will give pairs of the form name1 name2 to be considered as corresponding inputs in the verification process. In each pair, name1 may belong to the specification and name2 to the implementation or vice-versa. The matching procedure is not capable of dealing with some special situations. For example, when two inputs, one of each network have the same name, they must correspond to the same input. Partial orders may not be specified. -o Required file specifying output order, starting with the MSB. The file must be a list of output names separated by spaces. The list must belong to the specification network and must contain a full order i.e., must contain all the combinational output names. It is advisable to use the -o option as far as possible to specify the order of the outputs.See also -O option. -O This option specifies whether the res_verify command should generate a default order for the outputs. If the -o option is not used, this option must be specified. The default order generated is random and is NOT the same as the input files. The set of outputs for the output order may be generated by using the print_network command to write the network into a file and extract the node name from the lines containing the word "comb-output". The set of outputs can then be ordered as required. It is advisable to use the -o option as far as possible to specify the order of the outputs. The -o option overrides the -O option. See also -o option. -s Specification network. This network will be taken as the specification of the circuit. The result of the computation will be stored in this network. If this network is not provided, the current node of the hierarchy will be taken. The file must contain a blif description of a circuit unless the option -b is specified, in which case the file is considered in blif-mv format. If two networks are specified in the command line, both of them must have the same format, either blif or blif-mv. The blif format is the default. -t Execution time in seconds allowed for verification before aborting. The default is no limit. _________________________________________________________________ Last updated on 20050519 10h16