Commit 62e5b4ac authored by Lars Schieffer's avatar Lars Schieffer
Browse files

unique renaming

parent 41d1f09c
#include <jani2pinsPlugin.h>
#ifndef GROUPAMOUNT
#define GROUPAMOUNT 2
#endif
//Create TransitionGroupGuards
guard_t **createTransitionGroupGuardInformation()
{
// Guards of each transition group
int *transitionGuards[GROUPAMOUNT] = {(int[]){0},(int[]){1}};
int transitionGuardsSizes[GROUPAMOUNT] = {1,1};
guard_t **guard_info = malloc(GROUPAMOUNT * sizeof(guard_t *));
for (int i = 0; i < GROUPAMOUNT; i++)
{
guard_info[i] = malloc(sizeof(int[transitionGuardsSizes[i] + 1]));
memcpy(guard_info[i]->guard, transitionGuards[i], transitionGuardsSizes[i] * sizeof(int));
guard_info[i]->count = transitionGuardsSizes[i];
}
return guard_info;
}
#include <jani2pinsPlugin.h>
// Name of the PINS plugin
char pins_plugin_name[] = "jani2pins";
// Compute the remainder of Euclidean division
int remEuc(int x, int y){
int remainder = x % y;
if (remainder < 0){
return remainder + abs(y);
}
else{
return remainder;
}
}
// Compute the signum function
int sgn(int x){
if (x>0){
return 1;
}
if (x<0){
return -1;
}
return 0;
}
// Evaluate all state labels or guard
static void stateLabelsGroup(model_t model, sl_group_enum_t group, int *sourceStateVector, int *stateVectorLabels) {
if (group == GB_SL_GUARDS) {
for (int i = 0; i < guardAmount(); i++) {
stateVectorLabels[i] = stateVectorLabelLong(model, i, sourceStateVector);
}
}
if (group == GB_SL_ALL) {
for (int i = 0; i < labelAmount(); i++) {
stateVectorLabels[i] = stateVectorLabelLong(model, i, sourceStateVector);
}
}
}
// Initialise LTSmin Model
void pins_model_init(model_t model) {
// Initialise pins model
initModel(model);
// Set initial state
GBsetInitialState(model, initialStateVector());
//Set pointer to next-state function
GBsetNextStateLong(model, (next_method_grey_t)nextStateLong);
GBsetNextStateShortR2W(model, (next_method_grey_t)nextStateR2W);
GBsetActionsShortR2W(model, (next_method_grey_t)actionsR2W);
//Set pointer to label evaluation function
GBsetStateLabelLong(model, (get_label_method_t)stateVectorLabelLong);
GBsetStateLabelShort(model, (get_label_method_t)stateVectorLabelShort);
// Add new implementation
GBsetStateLabelsGroup(model, stateLabelsGroup);
// Create dependent matrices
matrix_t *rm = malloc(sizeof(matrix_t));
matrix_t *wm = malloc(sizeof(matrix_t));
matrix_t *cm = malloc(sizeof(matrix_t));
matrix_t *lm = malloc(sizeof(matrix_t));
matrix_t *dna = malloc(sizeof(matrix_t));
matrix_t *nes = malloc(sizeof(matrix_t));
matrix_t *nds = malloc(sizeof(matrix_t));
matrix_t *mce = malloc(sizeof(matrix_t));
dm_create(rm, groupAmount(), stateVectorLength());
dm_create(wm, groupAmount(), stateVectorLength());
dm_create(cm, groupAmount(), stateVectorLength());
dm_create(lm, labelAmount(), stateVectorLength());
dm_create(dna, groupAmount(), groupAmount());
dm_create(nes, guardAmount(), groupAmount());
dm_create(nds, guardAmount(), groupAmount());
dm_create(mce, guardAmount(), guardAmount());
// Set read & write dependency matrices
for (int i = 0; i < groupAmount(); i++) {
for (int j = 0; j < stateVectorLength(); j++) {
if (readDependencies(i)[j]) {
dm_set(cm, i, j);
dm_set(rm, i, j);
}
if (writeDependencies(i)[j]) {
dm_set(cm, i, j);
dm_set(wm, i, j);
}
}
}
// Set label dependency matrix
for (int i = 0; i < labelAmount(); i++) {
for (int j = 0; j < stateVectorLength(); j++) {
if (labelDependencies(i)[j]) {
dm_set(lm, i, j);
}
}
}
// Set do-not-accord matrix
for (int i = 0; i < groupAmount(); i++) {
for (int j = 0; j < groupAmount(); j++) {
if (dnaGroup(i)[j]) {
dm_set(dna, i, j);
}
}
}
// Set necessary enabling set and necessary disabling set
for (int i = 0; i < labelAmount(); i++) {
for (int j = 0; j < groupAmount(); j++) {
if (necessaryEnabling(i)[j]) {
dm_set(nes, i, j);
}
if (necessaryDisabling(i)[j]) {
dm_set(nds, i, j);
}
}
}
// Set may-be-co-enabled matrix
for (int i = 0; i < labelAmount(); i++) {
for (int j = 0; j < labelAmount(); j++) {
if (maybeCoEnabled(i)[j]) {
dm_set(mce, i, j);
}
}
}
// Set pointer to dependency matrices
GBsetDMInfoRead(model, rm);
GBsetDMInfoMustWrite(model, wm);
GBsetDMInfo(model, cm);
GBsetStateLabelInfo(model, lm);
GBsetDoNotAccordInfo(model, dna);
GBsetGuardNESInfo(model, nes);
GBsetGuardNDSInfo(model, nds);
GBsetGuardCoEnabledInfo(model, mce);
// Create Label Mapping
sl_group_t *sl_group_all = malloc(labelAmount() * sizeof(sl_group_all));
sl_group_all->count = labelAmount();
for (int i = 0; i < labelAmount(); i++) {
sl_group_all->sl_idx[i] = i;
}
// Create Guard Mapping
sl_group_t *sl_group_guards = malloc(guardAmount() * sizeof(sl_group_guards));
sl_group_guards->count = guardAmount();
for (int i = 0; i < guardAmount(); i++) {
sl_group_guards->sl_idx[i] = i;
}
// Set pointer to label & guard mappings
GBsetStateLabelGroupInfo(model, GB_SL_ALL, sl_group_all);
GBsetStateLabelGroupInfo(model, GB_SL_GUARDS, sl_group_guards);
// Add Action guards
GBsetGuardsInfo(model, createTransitionGroupGuardInformation());
// Printing Guards in stdout
GBprintStateLabelGroupInfo(stdout, model);
}
\ No newline at end of file
#include <ltsmin/dlopen-api.h>
#include <ltsmin/lts-type.h>
#include <ltsmin/ltsmin-standard.h>
#include <ltsmin/pins-util.h>
#include <ltsmin/pins.h>
#include <math.h>
//
// model.c
//
// The amount of all defined groups
int groupAmount();
// The amount of all defined labels
int labelAmount();
// The amount of all defined guards
int guardAmount();
// The length of the whole state vector
int stateVectorLength();
// Initialise the PINS model
void initModel(model_t model);
// Implementation of calculating remainder of Euclidean division
int remEuc(int x, int y);
// Compute the signum function
int sgn(int x);
//
// next-states.c
//
// The initial state vector
int *initialStateVector();
// Successor function for PINS model using a LONG state vector.
int nextStateLong(model_t model, int group, int *state_src, TransitionCB callback, void *context);
// Successor function for PINS model using a R2W state vector.
int nextStateR2W(model_t model, int group, int *state_src, TransitionCB callback, void *context);
// Update function for PINS model using a R2W state vector.
int actionsR2W(model_t model, int group, int *state_src, TransitionCB callback, void *context);
// Label function for LONG state vector:
int stateVectorLabelLong(model_t model, int label, int *state_src);
// Label function for SHORT state vector:
int stateVectorLabelShort(model_t model, int label, int *state_src);
//
// dependencies.c
//
// Read dependencies to state vector
int *readDependencies(int group);
// Write Dependencies
int *writeDependencies(int group);
// Label Dependencies
int *labelDependencies(int label);
// Do not accord
int *dnaGroup(int group);
// Necessary Enabling
int *necessaryEnabling(int guard);
// Necessary Disabling
int *necessaryDisabling(int guard);
// Maybe co-enabled
int *maybeCoEnabled(int guard);
//
// guards.c
//
//Create Action Guards
guard_t **createTransitionGroupGuardInformation();
\ No newline at end of file
#include <jani2pinsPlugin.h>
// Read dependencies to state vector
int readMatrix[2][1] = {{1},{1}};
int *readDependencies(int group){
return readMatrix[group];
}
// Write Dependencies
int writeMatrix[2][1] = {{1},{1}};
int *writeDependencies(int group){
return writeMatrix[group];
}
// Label Dependencies
int labelMatrix[2][1] = {{1},{1}};
int *labelDependencies(int label){
return labelMatrix[label];
}
// Do-not-accord
int DNAMatrix[2][2] = {{1,1},{1,1}};
int *dnaGroup(int group){
return DNAMatrix[group];
}
// Necessary Enabling
int NESMatrix[2][2] = {{1,1},{1,1}};
int *necessaryEnabling(int guard){
return NESMatrix[guard];
}
// Necessary Disabling
int NDSMatrix[2][2] = {{1,1},{1,1}};
int *necessaryDisabling(int guard){
return NDSMatrix[guard];
}
// Maybe co-enabled
int MCEMatrix[2][2] = {{1,0},{0,1}};
int *maybeCoEnabled(int guard){
return MCEMatrix[guard];
}
\ No newline at end of file
#include <jani2pinsPlugin.h>
// The amount of all defined groups
int groupAmount(){
return 2;
}
// The amount of all defined labels
int labelAmount()
{
return 2;
}
// The amount of all defined guards
int guardAmount()
{
return 2;
}
// The length of the whole state vector
int stateVectorLength()
{
return 1;
}
// Initialise the PINS model
void initModel(model_t model)
{
// Create empty lts datastructure
lts_type_t lts = lts_type_create();
// Create slot types
int intSlot = lts_type_put_type(lts, "int", LTStypeSInt32, NULL);
int actionSlot = lts_type_put_type(lts, "action", LTStypeEnum, NULL);
int guardSlot = lts_type_put_type(lts, "guard", LTStypeBool, NULL);
int boolSlot = lts_type_put_type(lts, "bool", LTStypeBool, NULL);
// Define action edges
lts_type_set_edge_label_count(lts, 1);
lts_type_set_edge_label_name(lts, 0, "action");
lts_type_set_edge_label_type(lts, 0, "action");
lts_type_set_edge_label_typeno(lts, 0, actionSlot);
// Define StateVector
lts_type_set_state_length(lts, stateVectorLength());
lts_type_set_state_name(lts, 0, "Main_instance_0");
lts_type_set_state_typeno(lts, 0, intSlot);
// Define StateLabels
lts_type_set_state_label_count(lts, labelAmount());
lts_type_set_state_label_name(lts, 0, "g_0");
lts_type_set_state_label_typeno(lts, 0, guardSlot);
lts_type_set_state_label_name(lts, 1, "g_1");
lts_type_set_state_label_typeno(lts, 1, guardSlot);
// Validate lts datastructure
lts_type_validate(lts);
// Add lts to pins model
GBsetLTStype(model, lts);
// Add names to action groups
pins_chunk_put(model, actionSlot, chunk_str("a"));
}
#include <jani2pinsPlugin.h>
#ifndef STATEVECTORLENGTH
#define STATEVECTORLENGTH 1
#endif
// Model Constants
// Transient Values
// Function Declarations
// Function Implementations
// The initial state vector
int iSV[STATEVECTORLENGTH] = {0};
int *initialStateVector()
{
return iSV;
}
// Successor function for PINS model using a LONG state vector.
int nextStateLong(model_t model, int group, int *sourceStateVector, TransitionCB callback, void *context)
{
int actionLabel[1];
transition_info_t transitionInformation = {actionLabel, group};
if (group == 0 && (sourceStateVector[0] == 0)){
actionLabel[0] = 0;
int targetStateVector[STATEVECTORLENGTH];
memcpy(targetStateVector, sourceStateVector, STATEVECTORLENGTH * sizeof(int));
int Main_instance_00 = sourceStateVector[0];
int Main_instance_01 = Main_instance_00;
if (sourceStateVector[0] == 0){
Main_instance_01 = 1;
}
targetStateVector[0] = Main_instance_01;
int copy[STATEVECTORLENGTH] = {0};
callback(context, &transitionInformation, targetStateVector, copy);
return 1;
}
if (group == 1 && (sourceStateVector[0] == 1)){
actionLabel[0] = 0;
int targetStateVector[STATEVECTORLENGTH];
memcpy(targetStateVector, sourceStateVector, STATEVECTORLENGTH * sizeof(int));
int Main_instance_00 = sourceStateVector[0];
int Main_instance_01 = Main_instance_00;
if (sourceStateVector[0] == 1){
Main_instance_01 = 2;
}
targetStateVector[0] = Main_instance_01;
int copy[STATEVECTORLENGTH] = {0};
callback(context, &transitionInformation, targetStateVector, copy);
return 1;
}
return 0;
}
// Successor function for PINS model using a R2W state vector.
int nextStateR2W(model_t model, int group, int *sourceStateVector, TransitionCB callback, void *context)
{
int actionLabel[1];
transition_info_t transitionInformation = {actionLabel, group};
if (group == 0 && (sourceStateVector[0] == 0)){
actionLabel[0] = 0;
int targetStateVector[dm_ones_in_row(GBgetDMInfoMustWrite(model), group)];
int Main_instance_00 = sourceStateVector[0];
int Main_instance_01 = Main_instance_00;
if (sourceStateVector[0] == 0){
Main_instance_01 = 1;
}
targetStateVector[0] = Main_instance_01;
callback(context, &transitionInformation, targetStateVector, NULL);
return 1;
}
if (group == 1 && (sourceStateVector[0] == 1)){
actionLabel[0] = 0;
int targetStateVector[dm_ones_in_row(GBgetDMInfoMustWrite(model), group)];
int Main_instance_00 = sourceStateVector[0];
int Main_instance_01 = Main_instance_00;
if (sourceStateVector[0] == 1){
Main_instance_01 = 2;
}
targetStateVector[0] = Main_instance_01;
callback(context, &transitionInformation, targetStateVector, NULL);
return 1;
}
return 0;
}
// Update function for PINS model using a R2W state vector.
int actionsR2W(model_t model, int group, int *sourceStateVector, TransitionCB callback, void *context)
{
int actionLabel[1];
transition_info_t transitionInformation = {actionLabel, group};
if (group == 0){
actionLabel[0] = 0;
int targetStateVector[dm_ones_in_row(GBgetDMInfoMustWrite(model), group)];
int Main_instance_00 = sourceStateVector[0];
int Main_instance_01 = Main_instance_00;
if (sourceStateVector[0] == 0){
Main_instance_01 = 1;
}
targetStateVector[0] = Main_instance_01;
callback(context, &transitionInformation, targetStateVector, NULL);
return 1;
}
if (group == 1){
actionLabel[0] = 0;
int targetStateVector[dm_ones_in_row(GBgetDMInfoMustWrite(model), group)];
int Main_instance_00 = sourceStateVector[0];
int Main_instance_01 = Main_instance_00;
if (sourceStateVector[0] == 1){
Main_instance_01 = 2;
}
targetStateVector[0] = Main_instance_01;
callback(context, &transitionInformation, targetStateVector, NULL);
return 1;
}
return 0;
}
// Label function for LONG state vector:
int stateVectorLabelLong(model_t model, int stateVectorLabel, int *sourceStateVector)
{
if(stateVectorLabel == 0) {return (sourceStateVector[0] == 0);}
if(stateVectorLabel == 1) {return (sourceStateVector[0] == 1);}
return 0;
}
// Label function for SHORT state vector:
int stateVectorLabelShort(model_t model, int stateVectorLabel, int *sourceStateVector)
{
if(stateVectorLabel == 0) {return (sourceStateVector[0] == 0);}
if(stateVectorLabel == 1) {return (sourceStateVector[0] == 1);}
return 0;
}
{
"jani-version": 1,
"name": "uniqueEdges",
"type": "lts",
"features": [ "derived-operators" ],
"actions": [
{
"name": "a"
},
{
"name": "b"
}
],
"properties": [ {
"name": "Term",
"expression": {
"op": "filter",
"fun": "∀",
"values": {
"op": "=",
"left": {
"op": "Pmin",
"exp": {
"op": "F",
"exp": true
}
},
"right": 1
},
"states": {
"op": "initial"
}
}
} ],
"automata": [
{
"name": "Main",
"locations": [
{
"name": "loc_1"
},
{
"name": "loc_3"
},
{
"name": "loc_0"
}
],
"initial-locations": [ "loc_1" ],
"edges": [
{
"location": "loc_1",
"action": "a",
"destinations": [ {
"location": "loc_3"
} ]
},
{
"location": "loc_3",
"action": "b",
"destinations": [ {
"location": "loc_0"
} ]
}
]
}
],
"system": {
"elements": [ {
"automaton": "Main"
} ],
"syncs": [
{
"synchronise": [ "a" ],
"result": "a"
},
{
"synchronise": [ "b" ],
"result": "a"
}