source: vis_dev/vis-2.3/src/part/part.h @ 84

Last change on this file since 84 was 14, checked in by cecile, 13 years ago

vis2.3

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1/**CHeaderFile*****************************************************************
2
3  FileName    [part.h]
4
5  PackageName [part]
6
7  Synopsis    [Partition of a system and creation of MDDs.]
8
9  Description [Once the description of a system has been read, and the ordering
10  of the variables has been assigned, the partition package creates an
11  abstracted view of the system in which only information in terms of MDDs is
12  stored. The MDDs belong to the MDD manager of the system. Different options
13  may be considered when creating this abstracted view. If the system is
14  described as a network there are several options to create this partition. As
15  a first choice, the system may be considered as a set of functions
16  representing the combinational outputs as functions of the combinational
17  inputs. In general, the latch functions may be specified as functions of any
18  intermediate variables. These intermediate variables are themselves functions
19  of other variables, and ultimately the dependency on the combinational inputs
20  is achieved. The structure to represent these arbitrary dependencies is a
21  DAG. The combinational inputs of the network will be represented as
22  vertices. Every other function (either representing a latch or any other
23  intermediate node) is represented as a vertex with in-coming edges from the
24  vertices representing the function's domain. Hence, the vertices representing
25  the combinational inputs will not have any in-coming edges, and conversely,
26  the vertices representing the combinational outputs will not have any fanout
27  edges.<p>
28
29  The partition may have two types of vertices, called single and
30  clustered. Single vertices are the ones that represent, for example, nodes in
31  a network. Clustered vertices are used solely for the purpose of grouping
32  single vertices into disjoint sets. No clustered vertex can be member of a
33  clustered vertex, and every single vertex may be a member of a unique clustered
34  vertex. The edges of the graph are connecting only single vertices. Functions
35  are provided to access the list of vertices represented by a clustered vertex
36  as well as for testing the type of a vertex.<p>
37
38  A partition is the central input to the image computation
39  package.  However, it is important to note that there is no network-specific
40  information stored in the partition data structure itself.  Hence, it is
41  possible that another application (i.e. besides the network application)
42  could create a partition, and use that partition as input to the image
43  computation package.]
44
45  Author      [Abelardo Pardo]
46
47  Copyright   [This file was created at the University of Colorado at
48  Boulder.  The University of Colorado at Boulder makes no warranty
49  about the suitability of this software for any purpose.  It is
50  presented on an AS IS basis.]
51
52  Revision    [$Id: part.h,v 1.33 2009/04/11 01:47:18 fabio Exp $]
53
54******************************************************************************/
55
56#ifndef _PART
57#define _PART
58
59#include "ntk.h"
60
61/*---------------------------------------------------------------------------*/
62/* Constant declarations                                                     */
63/*---------------------------------------------------------------------------*/
64#define PART_NETWORK_APPL_KEY "Part_NetworkApplKey"
65
66/*---------------------------------------------------------------------------*/
67/* Structure declarations                                                     */
68/*---------------------------------------------------------------------------*/
69
70/**Enum************************************************************************
71
72  Synopsis    [Different methods of partitioning a system.]
73
74  SeeAlso     [PartPartitionInputsOutputs PartPartitionTotal
75  PartPartitionPartial]
76
77******************************************************************************/
78typedef enum {
79  Part_Default_c,  /* Default partition. (Right now Outputs as function of
80                    * inputs) */
81  Part_InOut_c,    /* Outputs as function of inputs */
82  Part_Total_c,    /* Replicates the system's structure */
83  Part_Partial_c,   /* Preserves certain user-provided nodes */
84  Part_Frontier_c,
85  Part_Boundary_c,  /* partition nodes are subckt IOs */
86  Part_Fine_c   /* partition nodes are subckt IOs */
87} Part_PartitionMethod;
88
89/**Enum************************************************************************
90
91  Synopsis    [Type of vertex in the partition.]
92
93  Description [There are two types of vertices in the partition: single and
94  clustered. A single vertex represents itself and it may have a multi-valued
95  function and a MddId attached to it. A clustered vertex represents a set of
96  single vertices. The only information stored in this type of vertex is the
97  list of single vertices being represented by the cluster. Only one level of
98  hierarchy is allowed, that is, clustered vertices may only represent single
99  vertices. Every single vertex may only be represented by a unique clustered
100  vertex. In other words, a vertex representing a cluster of vertices cannot be
101  a member of another cluster.]
102
103  SeeAlso     [PartVertexInfo]
104
105******************************************************************************/
106typedef enum {
107  Part_VertexCluster_c,  /* Vertex represents a cluster of vertices */
108  Part_VertexSingle_c    /* Vertex represents itself */
109} Part_VertexType;
110
111/**Enum************************************************************************
112
113  Synopsis    [ Methods of Breaking for State Space Decomposition ]
114
115  SeeAlso     []
116
117******************************************************************************/
118typedef enum{
119  Part_BSRR_s,    /* static round robin seed choice */
120  Part_BFix_v     /* fixed order vertex choice */
121} Part_BMethod;
122
123/**Enum************************************************************************
124
125  Synopsis    [ Method of Correlation calculation. ]
126
127  Description [ Correlation is calculated by ratio of minterm count of XOR.
128  If BDD function is not available or try to avoid using MDD operation,
129  correaltion can be calculated by second method. Then, support set is
130  generated from network and correlation is simply the ration of common support
131  to union of two support sets.]
132
133  SeeAlso     []
134
135******************************************************************************/
136typedef enum{
137  Part_CorrelationWithBDD,    /* correlation is based on BDD correlation */
138  Part_CorrelationWithSupport,   /* correlation is based on support */
139  Part_CorrelationDefault
140} Part_CMethod;
141
142/*---------------------------------------------------------------------------*/
143/* Type declarations                                                         */
144/*---------------------------------------------------------------------------*/
145typedef struct PartSubsystemInfo Part_SubsystemInfo_t;
146typedef struct PartSubsystem Part_Subsystem_t;
147
148/*---------------------------------------------------------------------------*/
149/* Variable declarations                                                     */
150/*---------------------------------------------------------------------------*/
151
152
153/*---------------------------------------------------------------------------*/
154/* Macro declarations                                                        */
155/*---------------------------------------------------------------------------*/
156
157
158/**AutomaticStart*************************************************************/
159
160/*---------------------------------------------------------------------------*/
161/* Function prototypes                                                       */
162/*---------------------------------------------------------------------------*/
163
164EXTERN void Part_Init(void);
165EXTERN void Part_End(void);
166EXTERN array_t * Part_PartitionBuildFunctions(graph_t *partition, array_t *roots, array_t *leaves, mdd_t *careSet);
167EXTERN array_t * Part_PartitionCollapse(graph_t *partition, array_t *roots, st_table *leaves, mdd_t *careSet);
168EXTERN array_t * Part_PartGroupVeriticesBasedOnHierarchy(Ntk_Network_t *network, array_t *latchDataInputNames);
169EXTERN array_t * Part_PartCreateSubsystems(Part_SubsystemInfo_t *subInfo, array_t *arrayOfLatchNames, array_t *arrayOfGroupIndex);
170EXTERN array_t * Part_PartCreateSubsystemsWithCTL(Part_SubsystemInfo_t *subInfo, array_t *ctlArray, array_t *fairArray,boolean dynamicIncrease,boolean dynamicAndDependency);
171EXTERN array_t * Part_PartCreateSubsystemsWithCtlAndLtl(Part_SubsystemInfo_t *subInfo, array_t *ctlArray, array_t *ltlArray, array_t *fairArray,boolean dynamicIncrease,boolean dynamicAndDependency,boolean strictBound);
172EXTERN st_table * Part_PartitionSubsystemReadVertexTable(Part_Subsystem_t *partitionedSubsystem);
173EXTERN array_t * Part_PartitionSubsystemReadFanIn(Part_Subsystem_t *partitionedSubsystem);
174EXTERN array_t * Part_PartitionSubsystemReadFanOut(Part_Subsystem_t *partitionedSubsystem);
175EXTERN Part_SubsystemInfo_t * Part_PartitionSubsystemInfoInit(Ntk_Network_t *network);
176EXTERN void Part_PartitionSubsystemInfoFree(Part_SubsystemInfo_t *partSubInfo);
177EXTERN void Part_PartitionSubsystemFree(Part_Subsystem_t *partSubsystem);
178EXTERN void Part_PartitionSubsystemInfoSetNetwork(Part_SubsystemInfo_t *subInfo, Ntk_Network_t *network);
179EXTERN void Part_PartitionSubsystemInfoSetBreakingMethod(Part_SubsystemInfo_t *subInfo, Part_BMethod bMethod);
180EXTERN void Part_PartitionSubsystemInfoSetBound(Part_SubsystemInfo_t *subInfo, int bound);
181EXTERN void Part_PartitionSubsystemInfoSetThreshold(Part_SubsystemInfo_t *subInfo, float threshold);
182EXTERN void Part_PartitionSubsystemInfoSetVerbosity(Part_SubsystemInfo_t *subInfo, int verbosity);
183EXTERN void Part_PartitionSubsystemInfoSetCorrelationMethod(Part_SubsystemInfo_t *subInfo, Part_CMethod corMethod);
184EXTERN void Part_PartitionSubsystemInfoSetAffinityFactor( Part_SubsystemInfo_t *subInfo, float affinity);
185EXTERN Part_Subsystem_t * Part_PartCreateSingleSubSystem( array_t *arrayOfNodes, Ntk_Network_t *network);
186EXTERN graph_t * Part_CreatePartitionFromMvfs(mdd_manager *manager, st_table *nameToMvf, st_table *nameToId,  st_table *leafTable,  char *partName);
187EXTERN graph_t * Part_NetworkCreatePartitionFromMvfs(Ntk_Network_t *network, st_table *nameToMvf);
188EXTERN void Part_PartitionFree(graph_t *partition);
189EXTERN void Part_PartitionFreeCallback(void *data);
190EXTERN vertex_t * Part_PartitionFindVertexByName(graph_t *partition, char *name);
191EXTERN vertex_t * Part_PartitionFindVertexByMddId(graph_t *partition, int mddId);
192EXTERN char * Part_PartitionReadName(graph_t *partition);
193EXTERN Part_PartitionMethod Part_PartitionReadMethod(graph_t *partition);
194EXTERN char * Part_PartitionObtainMethodAsString(graph_t *partition);
195EXTERN mdd_manager * Part_PartitionReadMddManager(graph_t *partition);
196EXTERN Part_VertexType Part_VertexReadType(vertex_t *vertexPtr);
197EXTERN char * Part_VertexReadName(vertex_t *vertexPtr);
198EXTERN array_t * Part_VertexReadClusterMembers(vertex_t *vertexPtr);
199EXTERN Mvf_Function_t * Part_VertexReadFunction(vertex_t *vertexPtr);
200EXTERN void Part_VertexSetFunction(vertex_t *vertexPtr, Mvf_Function_t *mvf);
201EXTERN int Part_VertexReadMddId(vertex_t *vertexPtr);
202EXTERN boolean Part_VertexTestIsClustered(vertex_t *vertexPtr);
203EXTERN graph_t * Part_NetworkCreatePartition(Ntk_Network_t *network, Hrc_Node_t *hnode, char *name, lsList rootList, lsList leaveList, mdd_t *careSet, Part_PartitionMethod method, lsList nodes, boolean inTermsOfLeaves, int verbose, int sanityCheck);
204EXTERN graph_t * Part_PartitionDuplicate(graph_t *partition);
205EXTERN graph_t * Part_NetworkReadPartition(Ntk_Network_t *network);
206EXTERN vertex_t * Part_PartitionCreateClusterVertex(graph_t *partition, char *name, array_t *arrayOfVertices);
207EXTERN void Part_UpdatePartitionFrontier(Ntk_Network_t *network, graph_t *partition, lsList rootList, lsList leaveList, mdd_t *careSet);
208EXTERN void Part_VertexInfoFreeCluster(vertex_t *vertexPtr);
209EXTERN boolean Part_PartitionTestCompletelySp(graph_t *partition, array_t *roots, st_table *leaves);
210EXTERN boolean Part_PartitionTestDeterministic(graph_t *partition, array_t *roots, st_table *leaves);
211EXTERN graph_t * Part_PartCreatePartitionWithCTL(Hrc_Manager_t ** hmgr, Part_PartitionMethod method, int verbose, int sanityCheck, boolean inTermsOfLeaves, array_t *ctlArray, array_t *fairArray);
212EXTERN graph_t * Part_PartCreatePartitionWithCtlAndLtl(Hrc_Manager_t ** hmgr, Part_PartitionMethod method, int verbose, int sanityCheck, boolean inTermsOfLeaves, array_t *ctlArray, array_t *ltlArray, array_t *fairArray);
213EXTERN int Part_PartitionChangeRoots(Ntk_Network_t *network, graph_t *partition, lsList rootList, int verbosity);
214EXTERN void Part_PartitionPrintStats(FILE *fp, graph_t *partition, boolean printNodeNames);
215EXTERN int Part_PartitionGetLatchInputListFromCTL(Ntk_Network_t *network, array_t *ctlArray, array_t *fairArray, lsList latchInputList);
216EXTERN int Part_PartitionGetLatchInputListFromCtlAndLtl(Ntk_Network_t *network, array_t *ctlArray, array_t *ltlArray, array_t *fairArray, lsList latchInputList, boolean stopAtLatch);
217EXTERN void Part_PartitionReadOrCreateBnvs(Ntk_Network_t *network, st_table *coiLatchTable, st_table *coiBnvTable);
218EXTERN void PartPartitionFineGrain( Ntk_Network_t *network, graph_t       *partition, mdd_t *careSet);
219EXTERN int Part_CheckLeafNodeCondition(Ntk_Node_t *node, st_table *leafTable, int fanoutFreeLimit, int numVariableLimit);
220EXTERN int Img_CutCalcTransitiveFanin(st_table *table, st_table *ownTable, Ntk_Node_t *node, Ntk_Node_t *fanin, int limit);
221EXTERN Ntk_Node_t * Part_GetFaninFreeLogic(Ntk_Node_t *node);
222EXTERN Ntk_Node_t * Part_GetFanoutFreeLogic(Ntk_Node_t *node);
223EXTERN void Part_PartitionWithExistingBnvs(Ntk_Network_t *network, graph_t *partition, st_table *coiBnvTable, st_table *absLatchTable, st_table *absBnvTable);
224
225/**AutomaticEnd***************************************************************/
226
227#endif /* _PART */
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