Examples of org.apache.commons.math3.linear.SymmLQ$State

• org.apache.commons.math3.analysis.solvers.PegasusSolver

  A simple container holding the non-final variables used in the iterations. Making the current state of the solver visible from the outside is necessary, because during the iterations, {@code x} does notexactly hold the current estimate of the solution. Indeed, {@code x} needs in general to be moved from the LQ point to the CG point.Besides, additional upudates must be carried out in case {@code goodb} isset to {@code true}.

  In all subsequent comments, the description of the state variables refer to their value after a call to {@link #update()}. In these comments, k is the current number of evaluations of matrix-vector products.

    @Override
    public CompletionContext<State> buildContext(
        SelectionModel selection, DocumentParser parser) {
      JsonArray<Token> tokens = JsonCollections.createArray();
      State state = TestUtils.createMockState();
      tokens.add(new Token(null, NULL, ""));
      ParseResult<State> parseResult = new ParseResult<State>(tokens, state) {};
      return buildContext(
          new ParseUtils.ExtendedParseResult<State>(parseResult, ParseUtils.Context.IN_CODE));
    }

   * @param anchorToUpdate the optional anchor that this method will update
   */
  private boolean parseImplCm2(Line line, int lineNumber, int numLinesToProcess,
      @Nullable Anchor anchorToUpdate, ParsedTokensRecipient tokensRecipient) {

    State parserState = loadParserStateForBeginningOfLine(line);
    if (parserState == null) {
      return false;
    }

    Line previousLine = line.getPreviousLine();

    for (int numLinesProcessed = 0; line != null && numLinesProcessed < numLinesToProcess;) {
      State stateToSave = parserState;
      if (line.getText().length() > LINE_LENGTH_LIMIT) {
        // Save the initial state instead of state at the end of line.
        stateToSave = parserState.copy(codeMirrorParser);
      }

    parseImplCm2(line, -1, 1, null, tokensRecipient);
    return tokensRecipient.tokens;
  }

  int getIndentation(Line line) {
    State stateBefore = loadParserStateForBeginningOfLine(line);
    String textAfter = line.getText();
    textAfter = textAfter.substring(StringUtils.lengthOfStartingWhitespace(textAfter));
    return codeMirrorParser.indent(stateBefore, textAfter);
  }

   *
   * @return copy of corresponding parser state, or {@code null} if the state
   *         if not known yet (previous line wasn't parsed).
   */
  private <T extends State> T loadParserStateForBeginningOfLine(TaggableLine line) {
    State state;
    if (line.isFirstLine()) {
      state = codeMirrorParser.defaultState();
    } else {
      state = line.getPreviousLine().getTag(LINE_TAG_END_OF_LINE_PARSER_STATE_SNAPSHOT);
      state = (state == null) ? null : state.copy(codeMirrorParser);
    }

    @SuppressWarnings("unchecked")
    T result = (T) state;
    return result;

   *
   * @see #loadParserStateForBeginningOfLine
   */
  @Nullable
  String getInitialMode(@Nonnull TaggableLine line) {
    State state = loadParserStateForBeginningOfLine(line);
    if (state == null) {
      return null;
    }
    return codeMirrorParser.getName(state);
  }

    }
    return codeMirrorParser.getName(state);
  }

  private void saveEndOfLineParserState(Line line, State parserState) {
    State copiedParserState = parserState.copy(codeMirrorParser);
    line.putTag(LINE_TAG_END_OF_LINE_PARSER_STATE_SNAPSHOT, copiedParserState);
  }

   *
   * @param toMatch
   * @return
   */
  public Iterator<Lookup> match(String toMatch) {
    State currentState = getInitialState();
    for (int i = 0; i < toMatch.length(); i++) {
      char currentChar = toMatch.charAt(i);
      currentState = currentState.next(currentChar);
      if (currentState == null) {
        break;
      }
      if (i==(toMatch.length()-1) && currentState.isFinal()) {  // we are at the last character
        return getLookups(currentState);
      }
    }
    return null;
  }

    kv2[0] = "KEY1of2";
    kv2[1] = "VALUE1of2";
    kv2[2] = "KEY2of2";
    kv2[3] = "VALUE2of2";
    gs.addLookup("as", info1, kv2);
    State init = gs.getInitialState();
    System.out.println("Initial State: "+init);
    State s1 = init.next('a');
    System.out.println("State after a: "+s1);
    System.out.println("isFinal: "+s1.isFinal());
    State s2 = s1.next('s');
    System.out.println("State after s: "+s2);
    System.out.println("isFinal: "+s2.isFinal());
    Iterator<Lookup> lookupIter = gs.getLookups(s2);
    System.out.println("Have lookups: "+lookupIter.hasNext());
    while(lookupIter.hasNext()) {
      Lookup l = lookupIter.next();
      System.out.println("Have a lookup"+l);
    }
    File someFile = new File("tmp.gazbin");
    try {
      gs.save(someFile);
    } catch (FileNotFoundException e) {
      e.printStackTrace();
      assertTrue("could not save trie", false);
      return;
    }
    GazStoreTrie3 gs2 = new GazStoreTrie3();
    try {
      gs2 = (GazStoreTrie3)gs2.load(someFile);
    } catch (FileNotFoundException e) {
      e.printStackTrace();
      assertTrue("could not load trie",false);
      return;
    }
    State init_2 = gs2.getInitialState();
    System.out.println("Initial State: "+init_2);
    State s1_2 = init_2.next('a');
    System.out.println("State after a: "+s1_2);
    System.out.println("isFinal: "+s1_2.isFinal());
    State s2_2 = s1_2.next('s');
    System.out.println("State after s: "+s2_2);
    System.out.println("isFinal: "+s2_2.isFinal());
    Iterator<Lookup> lookupIter_2 = gs2.getLookups(s2_2);
    System.out.println("Have lookups: "+lookupIter_2.hasNext());
    while(lookupIter_2.hasNext()) {
      Lookup l = lookupIter_2.next();
      System.out.println("Have a lookup"+l);

                return false;
            }
            final int    n = FastMath.max(1, (int) FastMath.ceil(FastMath.abs(dt) / maxCheckInterval));
            final double h = dt / n;

            final UnivariateFunction f = new UnivariateFunction() {
                public double value(final double t) throws LocalMaxCountExceededException {
                    try {
                        interpolator.setInterpolatedTime(t);
                        return handler.g(t, getCompleteState(interpolator));
                    } catch (MaxCountExceededException mcee) {
                        throw new LocalMaxCountExceededException(mcee);
                    }
                }
            };

            double ta = t0;
            double ga = g0;
            for (int i = 0; i < n; ++i) {

                // evaluate handler value at the end of the substep
                final double tb = t0 + (i + 1) * h;
                interpolator.setInterpolatedTime(tb);
                final double gb = handler.g(tb, getCompleteState(interpolator));

                // check events occurrence
                if (g0Positive ^ (gb >= 0)) {
                    // there is a sign change: an event is expected during this step

                    // variation direction, with respect to the integration direction
                    increasing = gb >= ga;

                    // find the event time making sure we select a solution just at or past the exact root
                    final double root;
                    if (solver instanceof BracketedUnivariateSolver<?>) {
                        @SuppressWarnings("unchecked")
                        BracketedUnivariateSolver<UnivariateFunction> bracketing =
                                (BracketedUnivariateSolver<UnivariateFunction>) solver;
                        root = forward ?
                               bracketing.solve(maxIterationCount, f, ta, tb, AllowedSolution.RIGHT_SIDE) :
                               bracketing.solve(maxIterationCount, f, tb, ta, AllowedSolution.LEFT_SIDE);
                    } else {
                        final double baseRoot = forward ?
                                                solver.solve(maxIterationCount, f, ta, tb) :
                                                solver.solve(maxIterationCount, f, tb, ta);
                        final int remainingEval = maxIterationCount - solver.getEvaluations();
                        BracketedUnivariateSolver<UnivariateFunction> bracketing =
                                new PegasusSolver(solver.getRelativeAccuracy(), solver.getAbsoluteAccuracy());
                        root = forward ?
                               UnivariateSolverUtils.forceSide(remainingEval, f, bracketing,
                                                                   baseRoot, ta, tb, AllowedSolution.RIGHT_SIDE) :
                               UnivariateSolverUtils.forceSide(remainingEval, f, bracketing,
                                                                   baseRoot, tb, ta, AllowedSolution.LEFT_SIDE);
                    }

                    if ((!Double.isNaN(previousEventTime)) &&
                        (FastMath.abs(root - ta) <= convergence) &&
                        (FastMath.abs(root - previousEventTime) <= convergence)) {
                        // we have either found nothing or found (again ?) a past event,
                        // retry the substep excluding this value, and taking care to have the
                        // required sign in case the g function is noisy around its zero and
                        // crosses the axis several times
                        do {
                            ta = forward ? ta + convergence : ta - convergence;
                            ga = f.value(ta);
                        } while ((g0Positive ^ (ga >= 0)) && (forward ^ (ta >= tb)));
                        --i;
                    } else if (Double.isNaN(previousEventTime) ||
                               (FastMath.abs(previousEventTime - root) > convergence)) {
                        pendingEventTime = root;

                        final double baseRoot = forward ?
                                                solver.solve(maxIterationCount, f, ta, tb) :
                                                solver.solve(maxIterationCount, f, tb, ta);
                        final int remainingEval = maxIterationCount - solver.getEvaluations();
                        BracketedUnivariateSolver<UnivariateFunction> bracketing =
                                new PegasusSolver(solver.getRelativeAccuracy(), solver.getAbsoluteAccuracy());
                        root = forward ?
                               UnivariateSolverUtils.forceSide(remainingEval, f, bracketing,
                                                                   baseRoot, ta, tb, AllowedSolution.RIGHT_SIDE) :
                               UnivariateSolverUtils.forceSide(remainingEval, f, bracketing,
                                                                   baseRoot, tb, ta, AllowedSolution.LEFT_SIDE);