| /* |
| * Copyright (C) 2015 The Android Open Source Project |
| * |
| * Licensed under the Apache License, Version 2.0 (the "License"); |
| * you may not use this file except in compliance with the License. |
| * You may obtain a copy of the License at |
| * |
| * http://www.apache.org/licenses/LICENSE-2.0 |
| * |
| * Unless required by applicable law or agreed to in writing, software |
| * distributed under the License is distributed on an "AS IS" BASIS, |
| * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| * See the License for the specific language governing permissions and |
| * limitations under the License. |
| */ |
| |
| package com.android.calculator2; |
| |
| |
| import com.hp.creals.CR; |
| import com.hp.creals.UnaryCRFunction; |
| |
| import android.content.Context; |
| import android.text.SpannableString; |
| import android.text.SpannableStringBuilder; |
| import android.text.Spanned; |
| import android.text.style.TtsSpan; |
| import android.text.style.TtsSpan.TextBuilder; |
| import android.util.Log; |
| |
| import java.math.BigInteger; |
| import java.io.DataInput; |
| import java.io.DataOutput; |
| import java.io.IOException; |
| import java.util.ArrayList; |
| import java.util.HashMap; |
| import java.util.IdentityHashMap; |
| |
| // A mathematical expression represented as a sequence of "tokens". |
| // Many tokes are represented by button ids for the corresponding operator. |
| // Parsed only when we evaluate the expression using the "eval" method. |
| class CalculatorExpr { |
| private ArrayList<Token> mExpr; // The actual representation |
| // as a list of tokens. Constant |
| // tokens are always nonempty. |
| |
| private static enum TokenKind { CONSTANT, OPERATOR, PRE_EVAL }; |
| private static TokenKind[] tokenKindValues = TokenKind.values(); |
| private final static BigInteger BIG_MILLION = BigInteger.valueOf(1000000); |
| private final static BigInteger BIG_BILLION = BigInteger.valueOf(1000000000); |
| |
| private static abstract class Token { |
| abstract TokenKind kind(); |
| |
| /** |
| * Write kind as Byte followed by data needed by subclass constructor. |
| */ |
| abstract void write(DataOutput out) throws IOException; |
| |
| /** |
| * Return a textual representation of the token. |
| * The result is suitable for either display as part od the formula or TalkBack use. |
| * It may be a SpannableString that includes added TalkBack information. |
| * @param context context used for converting button ids to strings |
| */ |
| abstract CharSequence toCharSequence(Context context); |
| } |
| |
| // An operator token |
| private static class Operator extends Token { |
| final int mId; // We use the button resource id |
| Operator(int resId) { |
| mId = resId; |
| } |
| Operator(DataInput in) throws IOException { |
| mId = in.readInt(); |
| } |
| @Override |
| void write(DataOutput out) throws IOException { |
| out.writeByte(TokenKind.OPERATOR.ordinal()); |
| out.writeInt(mId); |
| } |
| @Override |
| public CharSequence toCharSequence(Context context) { |
| String desc = KeyMaps.toDescriptiveString(context, mId); |
| if (desc != null) { |
| SpannableString result = new SpannableString(KeyMaps.toString(context, mId)); |
| Object descSpan = new TtsSpan.TextBuilder(desc).build(); |
| result.setSpan(descSpan, 0, result.length(), Spanned.SPAN_EXCLUSIVE_EXCLUSIVE); |
| return result; |
| } else { |
| return KeyMaps.toString(context, mId); |
| } |
| } |
| @Override |
| TokenKind kind() { return TokenKind.OPERATOR; } |
| } |
| |
| // A (possibly incomplete) numerical constant. |
| // Supports addition and removal of trailing characters; hence mutable. |
| private static class Constant extends Token implements Cloneable { |
| private boolean mSawDecimal; |
| String mWhole; // String preceding decimal point. |
| private String mFraction; // String after decimal point. |
| private int mExponent; // Explicit exponent, only generated through addExponent. |
| |
| Constant() { |
| mWhole = ""; |
| mFraction = ""; |
| mSawDecimal = false; |
| mExponent = 0; |
| }; |
| |
| Constant(DataInput in) throws IOException { |
| mWhole = in.readUTF(); |
| mSawDecimal = in.readBoolean(); |
| mFraction = in.readUTF(); |
| mExponent = in.readInt(); |
| } |
| |
| @Override |
| void write(DataOutput out) throws IOException { |
| out.writeByte(TokenKind.CONSTANT.ordinal()); |
| out.writeUTF(mWhole); |
| out.writeBoolean(mSawDecimal); |
| out.writeUTF(mFraction); |
| out.writeInt(mExponent); |
| } |
| |
| // Given a button press, append corresponding digit. |
| // We assume id is a digit or decimal point. |
| // Just return false if this was the second (or later) decimal point |
| // in this constant. |
| // Assumes that this constant does not have an exponent. |
| boolean add(int id) { |
| if (id == R.id.dec_point) { |
| if (mSawDecimal || mExponent != 0) return false; |
| mSawDecimal = true; |
| return true; |
| } |
| int val = KeyMaps.digVal(id); |
| if (mExponent != 0) { |
| if (Math.abs(mExponent) <= 10000) { |
| if (mExponent > 0) { |
| mExponent = 10 * mExponent + val; |
| } else { |
| mExponent = 10 * mExponent - val; |
| } |
| return true; |
| } else { // Too large; refuse |
| return false; |
| } |
| } |
| if (mSawDecimal) { |
| mFraction += val; |
| } else { |
| mWhole += val; |
| } |
| return true; |
| } |
| |
| void addExponent(int exp) { |
| // Note that adding a 0 exponent is a no-op. That's OK. |
| mExponent = exp; |
| } |
| |
| // Undo the last add. |
| // Assumes the constant is nonempty. |
| void delete() { |
| if (mExponent != 0) { |
| mExponent /= 10; |
| // Once zero, it can only be added back with addExponent. |
| } else if (!mFraction.isEmpty()) { |
| mFraction = mFraction.substring(0, mFraction.length() - 1); |
| } else if (mSawDecimal) { |
| mSawDecimal = false; |
| } else { |
| mWhole = mWhole.substring(0, mWhole.length() - 1); |
| } |
| } |
| |
| boolean isEmpty() { |
| return (mSawDecimal == false && mWhole.isEmpty()); |
| } |
| |
| // Produces human-readable string, as typed. |
| // Result is internationalized. |
| @Override |
| public String toString() { |
| String result = mWhole; |
| if (mSawDecimal) { |
| result += '.'; |
| result += mFraction; |
| } |
| if (mExponent != 0) { |
| result += "E" + mExponent; |
| } |
| return KeyMaps.translateResult(result); |
| } |
| |
| // Return non-null BoundedRational representation. |
| public BoundedRational toRational() { |
| String whole = mWhole; |
| if (whole.isEmpty()) whole = "0"; |
| BigInteger num = new BigInteger(whole + mFraction); |
| BigInteger den = BigInteger.TEN.pow(mFraction.length()); |
| if (mExponent > 0) { |
| num = num.multiply(BigInteger.TEN.pow(mExponent)); |
| } |
| if (mExponent < 0) { |
| den = den.multiply(BigInteger.TEN.pow(-mExponent)); |
| } |
| return new BoundedRational(num, den); |
| } |
| |
| @Override |
| CharSequence toCharSequence(Context context) { |
| return toString(); |
| } |
| |
| @Override |
| TokenKind kind() { return TokenKind.CONSTANT; } |
| |
| // Override clone to make it public |
| @Override |
| public Object clone() { |
| Constant res = new Constant(); |
| res.mWhole = mWhole; |
| res.mFraction = mFraction; |
| res.mSawDecimal = mSawDecimal; |
| res.mExponent = mExponent; |
| return res; |
| } |
| } |
| |
| // Hash maps used to detect duplicate subexpressions when |
| // we write out CalculatorExprs and read them back in. |
| private static final ThreadLocal<IdentityHashMap<CR,Integer>>outMap = |
| new ThreadLocal<IdentityHashMap<CR,Integer>>(); |
| // Maps expressions to indices on output |
| private static final ThreadLocal<HashMap<Integer,PreEval>>inMap = |
| new ThreadLocal<HashMap<Integer,PreEval>>(); |
| // Maps expressions to indices on output |
| private static final ThreadLocal<Integer> exprIndex = |
| new ThreadLocal<Integer>(); |
| |
| static void initExprOutput() { |
| outMap.set(new IdentityHashMap<CR,Integer>()); |
| exprIndex.set(Integer.valueOf(0)); |
| } |
| |
| static void initExprInput() { |
| inMap.set(new HashMap<Integer,PreEval>()); |
| } |
| |
| // We treat previously evaluated subexpressions as tokens |
| // These are inserted when either: |
| // - We continue an expression after evaluating some of it. |
| // - TODO: When we copy/paste expressions. |
| // The representation includes three different representations |
| // of the expression: |
| // 1) The CR value for use in computation. |
| // 2) The integer value for use in the computations, |
| // if the expression evaluates to an integer. |
| // 3a) The corresponding CalculatorExpr, together with |
| // 3b) The context (currently just deg/rad mode) used to evaluate |
| // the expression. |
| // 4) A short string representation that is used to |
| // Display the expression. |
| // |
| // (3) is present only so that we can persist the object. |
| // (4) is stored explicitly to avoid waiting for recomputation in the UI |
| // thread. |
| private static class PreEval extends Token { |
| final CR mValue; |
| final BoundedRational mRatValue; |
| private final CalculatorExpr mExpr; |
| private final EvalContext mContext; |
| private final String mShortRep; // Not internationalized. |
| PreEval(CR val, BoundedRational ratVal, CalculatorExpr expr, |
| EvalContext ec, String shortRep) { |
| mValue = val; |
| mRatValue = ratVal; |
| mExpr = expr; |
| mContext = ec; |
| mShortRep = shortRep; |
| } |
| // In writing out PreEvals, we are careful to avoid writing |
| // out duplicates. We assume that two expressions are |
| // duplicates if they have the same mVal. This avoids a |
| // potential exponential blow up in certain off cases and |
| // redundant evaluation after reading them back in. |
| // The parameter hash map maps expressions we've seen |
| // before to their index. |
| @Override |
| void write(DataOutput out) throws IOException { |
| out.writeByte(TokenKind.PRE_EVAL.ordinal()); |
| Integer index = outMap.get().get(mValue); |
| if (index == null) { |
| int nextIndex = exprIndex.get() + 1; |
| exprIndex.set(nextIndex); |
| outMap.get().put(mValue, nextIndex); |
| out.writeInt(nextIndex); |
| mExpr.write(out); |
| mContext.write(out); |
| out.writeUTF(mShortRep); |
| } else { |
| // Just write out the index |
| out.writeInt(index); |
| } |
| } |
| PreEval(DataInput in) throws IOException { |
| int index = in.readInt(); |
| PreEval prev = inMap.get().get(index); |
| if (prev == null) { |
| mExpr = new CalculatorExpr(in); |
| mContext = new EvalContext(in, mExpr.mExpr.size()); |
| // Recompute other fields |
| // We currently do this in the UI thread, but we |
| // only create PreEval expressions that were |
| // previously successfully evaluated, and thus |
| // don't diverge. We also only evaluate to a |
| // constructive real, which involves substantial |
| // work only in fairly contrived circumstances. |
| // TODO: Deal better with slow evaluations. |
| EvalRet res = null; |
| try { |
| res = mExpr.evalExpr(0, mContext); |
| } catch (SyntaxException e) { |
| // Should be impossible, since we only write out |
| // expressions that can be evaluated. |
| Log.e("Calculator", "Unexpected syntax exception" + e); |
| } |
| mValue = res.mVal; |
| mRatValue = res.mRatVal; |
| mShortRep = in.readUTF(); |
| inMap.get().put(index, this); |
| } else { |
| mValue = prev.mValue; |
| mRatValue = prev.mRatValue; |
| mExpr = prev.mExpr; |
| mContext = prev.mContext; |
| mShortRep = prev.mShortRep; |
| } |
| } |
| @Override |
| CharSequence toCharSequence(Context context) { |
| return KeyMaps.translateResult(mShortRep); |
| } |
| @Override |
| TokenKind kind() { |
| return TokenKind.PRE_EVAL; |
| } |
| boolean hasEllipsis() { |
| return mShortRep.lastIndexOf(KeyMaps.ELLIPSIS) != -1; |
| } |
| } |
| |
| static Token newToken(DataInput in) throws IOException { |
| TokenKind kind = tokenKindValues[in.readByte()]; |
| switch(kind) { |
| case CONSTANT: |
| return new Constant(in); |
| case OPERATOR: |
| return new Operator(in); |
| case PRE_EVAL: |
| return new PreEval(in); |
| default: throw new IOException("Bad save file format"); |
| } |
| } |
| |
| CalculatorExpr() { |
| mExpr = new ArrayList<Token>(); |
| } |
| |
| private CalculatorExpr(ArrayList<Token> expr) { |
| mExpr = expr; |
| } |
| |
| CalculatorExpr(DataInput in) throws IOException { |
| mExpr = new ArrayList<Token>(); |
| int size = in.readInt(); |
| for (int i = 0; i < size; ++i) { |
| mExpr.add(newToken(in)); |
| } |
| } |
| |
| void write(DataOutput out) throws IOException { |
| int size = mExpr.size(); |
| out.writeInt(size); |
| for (int i = 0; i < size; ++i) { |
| mExpr.get(i).write(out); |
| } |
| } |
| |
| boolean hasTrailingConstant() { |
| int s = mExpr.size(); |
| if (s == 0) { |
| return false; |
| } |
| Token t = mExpr.get(s-1); |
| return t instanceof Constant; |
| } |
| |
| private boolean hasTrailingBinary() { |
| int s = mExpr.size(); |
| if (s == 0) return false; |
| Token t = mExpr.get(s-1); |
| if (!(t instanceof Operator)) return false; |
| Operator o = (Operator)t; |
| return (KeyMaps.isBinary(o.mId)); |
| } |
| |
| /** |
| * Append press of button with given id to expression. |
| * If the insertion would clearly result in a syntax error, either just return false |
| * and do nothing, or make an adjustment to avoid the problem. We do the latter only |
| * for unambiguous consecutive binary operators, in which case we delete the first |
| * operator. |
| */ |
| boolean add(int id) { |
| int s = mExpr.size(); |
| int d = KeyMaps.digVal(id); |
| boolean binary = KeyMaps.isBinary(id); |
| Token lastTok = s == 0 ? null : mExpr.get(s-1); |
| int lastOp = lastTok instanceof Operator ? ((Operator) lastTok).mId : 0; |
| // Quietly replace a trailing binary operator with another one, unless the second |
| // operator is minus, in which case we just allow it as a unary minus. |
| if (binary && !KeyMaps.isPrefix(id)) { |
| if (s == 0 || lastOp == R.id.lparen || KeyMaps.isFunc(lastOp) |
| || KeyMaps.isPrefix(lastOp) && lastOp != R.id.op_sub) { |
| return false; |
| } |
| while (hasTrailingBinary()) { |
| delete(); |
| } |
| // s invalid and not used below. |
| } |
| boolean isConstPiece = (d != KeyMaps.NOT_DIGIT || id == R.id.dec_point); |
| if (isConstPiece) { |
| // Since we treat juxtaposition as multiplication, a constant can appear anywhere. |
| if (s == 0) { |
| mExpr.add(new Constant()); |
| s++; |
| } else { |
| Token last = mExpr.get(s-1); |
| if(!(last instanceof Constant)) { |
| if (last instanceof PreEval) { |
| // Add explicit multiplication to avoid confusing display. |
| mExpr.add(new Operator(R.id.op_mul)); |
| s++; |
| } |
| mExpr.add(new Constant()); |
| s++; |
| } |
| } |
| return ((Constant)(mExpr.get(s-1))).add(id); |
| } else { |
| mExpr.add(new Operator(id)); |
| return true; |
| } |
| } |
| |
| /** |
| * Add exponent to the constant at the end of the expression. |
| * Assumes there is a constant at the end of the expression. |
| */ |
| void addExponent(int exp) { |
| Token lastTok = mExpr.get(mExpr.size() - 1); |
| ((Constant) lastTok).addExponent(exp); |
| } |
| |
| /** |
| * Remove trailing op_add and op_sub operators. |
| */ |
| void removeTrailingAdditiveOperators() { |
| while (true) { |
| int s = mExpr.size(); |
| if (s == 0) break; |
| Token lastTok = mExpr.get(s-1); |
| if (!(lastTok instanceof Operator)) break; |
| int lastOp = ((Operator) lastTok).mId; |
| if (lastOp != R.id.op_add && lastOp != R.id.op_sub) break; |
| delete(); |
| } |
| } |
| |
| // Append the contents of the argument expression. |
| // It is assumed that the argument expression will not change, |
| // and thus its pieces can be reused directly. |
| // TODO: We probably only need this for expressions consisting of |
| // a single PreEval "token", and may want to check that. |
| void append(CalculatorExpr expr2) { |
| // Check that we're not concatenating Constant or PreEval |
| // tokens, since the result would look like a single constant |
| int s = mExpr.size(); |
| int s2 = expr2.mExpr.size(); |
| // Check that we're not concatenating Constant or PreEval |
| // tokens, since the result would look like a single constant, |
| // with very mysterious results for the user. |
| if (s != 0 && s2 != 0) { |
| Token last = mExpr.get(s-1); |
| Token first = expr2.mExpr.get(0); |
| if (!(first instanceof Operator) && !(last instanceof Operator)) { |
| // Fudge it by adding an explicit multiplication. |
| // We would have interpreted it as such anyway, and this |
| // makes it recognizable to the user. |
| mExpr.add(new Operator(R.id.op_mul)); |
| } |
| } |
| for (int i = 0; i < s2; ++i) { |
| mExpr.add(expr2.mExpr.get(i)); |
| } |
| } |
| |
| // Undo the last key addition, if any. |
| void delete() { |
| int s = mExpr.size(); |
| if (s == 0) return; |
| Token last = mExpr.get(s-1); |
| if (last instanceof Constant) { |
| Constant c = (Constant)last; |
| c.delete(); |
| if (!c.isEmpty()) return; |
| } |
| mExpr.remove(s-1); |
| } |
| |
| void clear() { |
| mExpr.clear(); |
| } |
| |
| boolean isEmpty() { |
| return mExpr.isEmpty(); |
| } |
| |
| // Returns a logical deep copy of the CalculatorExpr. |
| // Operator and PreEval tokens are immutable, and thus |
| // aren't really copied. |
| public Object clone() { |
| CalculatorExpr res = new CalculatorExpr(); |
| for (Token t: mExpr) { |
| if (t instanceof Constant) { |
| res.mExpr.add((Token)(((Constant)t).clone())); |
| } else { |
| res.mExpr.add(t); |
| } |
| } |
| return res; |
| } |
| |
| // Am I just a constant? |
| boolean isConstant() { |
| if (mExpr.size() != 1) return false; |
| return mExpr.get(0) instanceof Constant; |
| } |
| |
| // Return a new expression consisting of a single PreEval token |
| // representing the current expression. |
| // The caller supplies the value, degree mode, and short |
| // string representation, which must have been previously computed. |
| // Thus this is guaranteed to terminate reasonably quickly. |
| CalculatorExpr abbreviate(CR val, BoundedRational ratVal, |
| boolean dm, String sr) { |
| CalculatorExpr result = new CalculatorExpr(); |
| Token t = new PreEval(val, ratVal, |
| new CalculatorExpr( |
| (ArrayList<Token>)mExpr.clone()), |
| new EvalContext(dm, mExpr.size()), sr); |
| result.mExpr.add(t); |
| return result; |
| } |
| |
| // Internal evaluation functions return an EvalRet triple. |
| // We compute rational (BoundedRational) results when possible, both as |
| // a performance optimization, and to detect errors exactly when we can. |
| private class EvalRet { |
| int mPos; // Next position (expression index) to be parsed |
| final CR mVal; // Constructive Real result of evaluating subexpression |
| final BoundedRational mRatVal; // Exact Rational value or null if |
| // irrational or hard to compute. |
| EvalRet(int p, CR v, BoundedRational r) { |
| mPos = p; |
| mVal = v; |
| mRatVal = r; |
| } |
| } |
| |
| // And take a context argument: |
| private static class EvalContext { |
| public final int mPrefixLength; // Length of prefix to evaluate. |
| // Not explicitly saved. |
| public final boolean mDegreeMode; |
| // If we add any other kinds of evaluation modes, they go here. |
| EvalContext(boolean degreeMode, int len) { |
| mDegreeMode = degreeMode; |
| mPrefixLength = len; |
| } |
| EvalContext(DataInput in, int len) throws IOException { |
| mDegreeMode = in.readBoolean(); |
| mPrefixLength = len; |
| } |
| void write(DataOutput out) throws IOException { |
| out.writeBoolean(mDegreeMode); |
| } |
| } |
| |
| private final CR RADIANS_PER_DEGREE = CR.PI.divide(CR.valueOf(180)); |
| |
| private final CR DEGREES_PER_RADIAN = CR.valueOf(180).divide(CR.PI); |
| |
| private CR toRadians(CR x, EvalContext ec) { |
| if (ec.mDegreeMode) { |
| return x.multiply(RADIANS_PER_DEGREE); |
| } else { |
| return x; |
| } |
| } |
| |
| private CR fromRadians(CR x, EvalContext ec) { |
| if (ec.mDegreeMode) { |
| return x.multiply(DEGREES_PER_RADIAN); |
| } else { |
| return x; |
| } |
| } |
| |
| // The following methods can all throw IndexOutOfBoundsException |
| // in the event of a syntax error. We expect that to be caught in |
| // eval below. |
| |
| private boolean isOperatorUnchecked(int i, int op) { |
| Token t = mExpr.get(i); |
| if (!(t instanceof Operator)) return false; |
| return ((Operator)(t)).mId == op; |
| } |
| |
| private boolean isOperator(int i, int op, EvalContext ec) { |
| if (i >= ec.mPrefixLength) return false; |
| return isOperatorUnchecked(i, op); |
| } |
| |
| static class SyntaxException extends Exception { |
| public SyntaxException() { |
| super(); |
| } |
| public SyntaxException(String s) { |
| super(s); |
| } |
| } |
| |
| // The following functions all evaluate some kind of expression |
| // starting at position i in mExpr in a specified evaluation context. |
| // They return both the expression value (as constructive real and, |
| // if applicable, as BigInteger) and the position of the next token |
| // that was not used as part of the evaluation. |
| private EvalRet evalUnary(int i, EvalContext ec) throws SyntaxException { |
| Token t = mExpr.get(i); |
| BoundedRational ratVal; |
| CR value; |
| if (t instanceof Constant) { |
| Constant c = (Constant)t; |
| ratVal = c.toRational(); |
| value = ratVal.CRValue(); |
| return new EvalRet(i+1, value, ratVal); |
| } |
| if (t instanceof PreEval) { |
| PreEval p = (PreEval)t; |
| return new EvalRet(i+1, p.mValue, p.mRatValue); |
| } |
| EvalRet argVal; |
| switch(((Operator)(t)).mId) { |
| case R.id.const_pi: |
| return new EvalRet(i+1, CR.PI, null); |
| case R.id.const_e: |
| return new EvalRet(i+1, REAL_E, null); |
| case R.id.op_sqrt: |
| // Seems to have highest precedence. |
| // Does not add implicit paren. |
| // Does seem to accept a leading minus. |
| if (isOperator(i+1, R.id.op_sub, ec)) { |
| argVal = evalUnary(i+2, ec); |
| ratVal = BoundedRational.sqrt( |
| BoundedRational.negate(argVal.mRatVal)); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, |
| argVal.mVal.negate().sqrt(), null); |
| } else { |
| argVal = evalUnary(i+1, ec); |
| ratVal = BoundedRational.sqrt(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, argVal.mVal.sqrt(), null); |
| } |
| case R.id.lparen: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| return new EvalRet(argVal.mPos, argVal.mVal, argVal.mRatVal); |
| case R.id.fun_sin: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = ec.mDegreeMode ? BoundedRational.degreeSin(argVal.mRatVal) |
| : BoundedRational.sin(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, |
| toRadians(argVal.mVal,ec).sin(), null); |
| case R.id.fun_cos: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = ec.mDegreeMode ? BoundedRational.degreeCos(argVal.mRatVal) |
| : BoundedRational.cos(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, |
| toRadians(argVal.mVal,ec).cos(), null); |
| case R.id.fun_tan: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = ec.mDegreeMode ? BoundedRational.degreeTan(argVal.mRatVal) |
| : BoundedRational.tan(argVal.mRatVal); |
| if (ratVal != null) break; |
| CR argCR = toRadians(argVal.mVal, ec); |
| return new EvalRet(argVal.mPos, |
| argCR.sin().divide(argCR.cos()), null); |
| case R.id.fun_ln: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = BoundedRational.ln(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, argVal.mVal.ln(), null); |
| case R.id.fun_exp: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = BoundedRational.exp(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, argVal.mVal.exp(), null); |
| case R.id.fun_log: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = BoundedRational.log(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, |
| argVal.mVal.ln().divide(CR.valueOf(10).ln()), |
| null); |
| case R.id.fun_arcsin: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = ec.mDegreeMode ? BoundedRational.degreeAsin(argVal.mRatVal) |
| : BoundedRational.asin(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, |
| fromRadians(UnaryCRFunction |
| .asinFunction.execute(argVal.mVal),ec), |
| null); |
| case R.id.fun_arccos: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = ec.mDegreeMode ? BoundedRational.degreeAcos(argVal.mRatVal) |
| : BoundedRational.acos(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, |
| fromRadians(UnaryCRFunction |
| .acosFunction.execute(argVal.mVal),ec), |
| null); |
| case R.id.fun_arctan: |
| argVal = evalExpr(i+1, ec); |
| if (isOperator(argVal.mPos, R.id.rparen, ec)) argVal.mPos++; |
| ratVal = ec.mDegreeMode ? BoundedRational.degreeAtan(argVal.mRatVal) |
| : BoundedRational.atan(argVal.mRatVal); |
| if (ratVal != null) break; |
| return new EvalRet(argVal.mPos, |
| fromRadians(UnaryCRFunction |
| .atanFunction.execute(argVal.mVal),ec), |
| null); |
| default: |
| throw new SyntaxException("Unrecognized token in expression"); |
| } |
| // We have a rational value. |
| return new EvalRet(argVal.mPos, ratVal.CRValue(), ratVal); |
| } |
| |
| // Compute an integral power of a constructive real. |
| // Unlike the "general" case using logarithms, this handles a negative |
| // base. |
| private static CR pow(CR base, BigInteger exp) { |
| if (exp.compareTo(BigInteger.ZERO) < 0) { |
| return pow(base, exp.negate()).inverse(); |
| } |
| if (exp.equals(BigInteger.ONE)) return base; |
| if (exp.and(BigInteger.ONE).intValue() == 1) { |
| return pow(base, exp.subtract(BigInteger.ONE)).multiply(base); |
| } |
| if (exp.equals(BigInteger.ZERO)) { |
| return CR.valueOf(1); |
| } |
| CR tmp = pow(base, exp.shiftRight(1)); |
| return tmp.multiply(tmp); |
| } |
| |
| private static final int TEST_PREC = -100; |
| // Test for integer-ness to 100 bits past binary point. |
| private static final BigInteger MASK = |
| BigInteger.ONE.shiftLeft(-TEST_PREC).subtract(BigInteger.ONE); |
| private static final CR REAL_E = CR.valueOf(1).exp(); |
| private static final CR REAL_ONE_HUNDREDTH = CR.valueOf(100).inverse(); |
| private static final BoundedRational RATIONAL_ONE_HUNDREDTH = |
| new BoundedRational(1,100); |
| private static boolean isApprInt(CR x) { |
| BigInteger appr = x.get_appr(TEST_PREC); |
| return appr.and(MASK).signum() == 0; |
| } |
| |
| private EvalRet evalSuffix(int i, EvalContext ec) throws SyntaxException { |
| EvalRet tmp = evalUnary(i, ec); |
| int cpos = tmp.mPos; |
| CR cval = tmp.mVal; |
| BoundedRational ratVal = tmp.mRatVal; |
| boolean isFact; |
| boolean isSquared = false; |
| while ((isFact = isOperator(cpos, R.id.op_fact, ec)) || |
| (isSquared = isOperator(cpos, R.id.op_sqr, ec)) || |
| isOperator(cpos, R.id.op_pct, ec)) { |
| if (isFact) { |
| if (ratVal == null) { |
| // Assume it was an integer, but we |
| // didn't figure it out. |
| // KitKat may have used the Gamma function. |
| if (!isApprInt(cval)) { |
| throw new ArithmeticException("factorial(non-integer)"); |
| } |
| ratVal = new BoundedRational(cval.BigIntegerValue()); |
| } |
| ratVal = BoundedRational.fact(ratVal); |
| cval = ratVal.CRValue(); |
| } else if (isSquared) { |
| ratVal = BoundedRational.multiply(ratVal, ratVal); |
| if (ratVal == null) { |
| cval = cval.multiply(cval); |
| } else { |
| cval = ratVal.CRValue(); |
| } |
| } else /* percent */ { |
| ratVal = BoundedRational.multiply(ratVal, RATIONAL_ONE_HUNDREDTH); |
| if (ratVal == null) { |
| cval = cval.multiply(REAL_ONE_HUNDREDTH); |
| } else { |
| cval = ratVal.CRValue(); |
| } |
| } |
| ++cpos; |
| } |
| return new EvalRet(cpos, cval, ratVal); |
| } |
| |
| private EvalRet evalFactor(int i, EvalContext ec) throws SyntaxException { |
| final EvalRet result1 = evalSuffix(i, ec); |
| int cpos = result1.mPos; // current position |
| CR cval = result1.mVal; // value so far |
| BoundedRational ratVal = result1.mRatVal; // int value so far |
| if (isOperator(cpos, R.id.op_pow, ec)) { |
| final EvalRet exp = evalSignedFactor(cpos+1, ec); |
| cpos = exp.mPos; |
| // Try completely rational evaluation first. |
| ratVal = BoundedRational.pow(ratVal, exp.mRatVal); |
| if (ratVal != null) { |
| return new EvalRet(cpos, ratVal.CRValue(), ratVal); |
| } |
| // Power with integer exponent is defined for negative base. |
| // Thus we handle that case separately. |
| // We punt if the exponent is an integer computed from irrational |
| // values. That wouldn't work reliably with floating point either. |
| BigInteger int_exp = BoundedRational.asBigInteger(exp.mRatVal); |
| if (int_exp != null) { |
| cval = pow(cval, int_exp); |
| } else { |
| cval = cval.ln().multiply(exp.mVal).exp(); |
| } |
| ratVal = null; |
| } |
| return new EvalRet(cpos, cval, ratVal); |
| } |
| |
| private EvalRet evalSignedFactor(int i, EvalContext ec) throws SyntaxException { |
| final boolean negative = isOperator(i, R.id.op_sub, ec); |
| int cpos = negative ? i + 1 : i; |
| EvalRet tmp = evalFactor(cpos, ec); |
| cpos = tmp.mPos; |
| CR cval = negative ? tmp.mVal.negate() : tmp.mVal; |
| BoundedRational ratVal = negative ? BoundedRational.negate(tmp.mRatVal) |
| : tmp.mRatVal; |
| return new EvalRet(cpos, cval, ratVal); |
| } |
| |
| private boolean canStartFactor(int i) { |
| if (i >= mExpr.size()) return false; |
| Token t = mExpr.get(i); |
| if (!(t instanceof Operator)) return true; |
| int id = ((Operator)(t)).mId; |
| if (KeyMaps.isBinary(id)) return false; |
| switch (id) { |
| case R.id.op_fact: |
| case R.id.rparen: |
| return false; |
| default: |
| return true; |
| } |
| } |
| |
| private EvalRet evalTerm(int i, EvalContext ec) throws SyntaxException { |
| EvalRet tmp = evalSignedFactor(i, ec); |
| boolean is_mul = false; |
| boolean is_div = false; |
| int cpos = tmp.mPos; // Current position in expression. |
| CR cval = tmp.mVal; // Current value. |
| BoundedRational ratVal = tmp.mRatVal; // Current rational value. |
| while ((is_mul = isOperator(cpos, R.id.op_mul, ec)) |
| || (is_div = isOperator(cpos, R.id.op_div, ec)) |
| || canStartFactor(cpos)) { |
| if (is_mul || is_div) ++cpos; |
| tmp = evalSignedFactor(cpos, ec); |
| if (is_div) { |
| ratVal = BoundedRational.divide(ratVal, tmp.mRatVal); |
| if (ratVal == null) { |
| cval = cval.divide(tmp.mVal); |
| } else { |
| cval = ratVal.CRValue(); |
| } |
| } else { |
| ratVal = BoundedRational.multiply(ratVal, tmp.mRatVal); |
| if (ratVal == null) { |
| cval = cval.multiply(tmp.mVal); |
| } else { |
| cval = ratVal.CRValue(); |
| } |
| } |
| cpos = tmp.mPos; |
| is_mul = is_div = false; |
| } |
| return new EvalRet(cpos, cval, ratVal); |
| } |
| |
| private EvalRet evalExpr(int i, EvalContext ec) throws SyntaxException { |
| EvalRet tmp = evalTerm(i, ec); |
| boolean is_plus; |
| int cpos = tmp.mPos; |
| CR cval = tmp.mVal; |
| BoundedRational ratVal = tmp.mRatVal; |
| while ((is_plus = isOperator(cpos, R.id.op_add, ec)) |
| || isOperator(cpos, R.id.op_sub, ec)) { |
| tmp = evalTerm(cpos+1, ec); |
| if (is_plus) { |
| ratVal = BoundedRational.add(ratVal, tmp.mRatVal); |
| if (ratVal == null) { |
| cval = cval.add(tmp.mVal); |
| } else { |
| cval = ratVal.CRValue(); |
| } |
| } else { |
| ratVal = BoundedRational.subtract(ratVal, tmp.mRatVal); |
| if (ratVal == null) { |
| cval = cval.subtract(tmp.mVal); |
| } else { |
| cval = ratVal.CRValue(); |
| } |
| } |
| cpos = tmp.mPos; |
| } |
| return new EvalRet(cpos, cval, ratVal); |
| } |
| |
| // Externally visible evaluation result. |
| public class EvalResult { |
| EvalResult (CR val, BoundedRational ratVal) { |
| mVal = val; |
| mRatVal = ratVal; |
| } |
| final CR mVal; |
| final BoundedRational mRatVal; |
| } |
| |
| /** |
| * Return the starting position of the sequence of trailing binary operators. |
| */ |
| private int trailingBinaryOpsStart() { |
| int result = mExpr.size(); |
| while (result > 0) { |
| Token last = mExpr.get(result - 1); |
| if (!(last instanceof Operator)) break; |
| Operator o = (Operator)last; |
| if (!KeyMaps.isBinary(o.mId)) break; |
| --result; |
| } |
| return result; |
| } |
| |
| // Is the current expression worth evaluating? |
| public boolean hasInterestingOps() { |
| int last = trailingBinaryOpsStart(); |
| int first = 0; |
| if (last > first && isOperatorUnchecked(first, R.id.op_sub)) { |
| // Leading minus is not by itself interesting. |
| first++; |
| } |
| for (int i = first; i < last; ++i) { |
| Token t1 = mExpr.get(i); |
| if (t1 instanceof Operator |
| || t1 instanceof PreEval && ((PreEval)t1).hasEllipsis()) { |
| return true; |
| } |
| } |
| return false; |
| } |
| |
| /** |
| * Evaluate the expression excluding trailing binary operators. |
| * Errors result in exceptions, most of which are unchecked. |
| * Should not be called concurrently with modification of the expression. |
| * May take a very long time; avoid calling from UI thread. |
| * |
| * @param degreeMode use degrees rather than radians |
| */ |
| EvalResult eval(boolean degreeMode) throws SyntaxException |
| // And unchecked exceptions thrown by CR |
| // and BoundedRational. |
| { |
| try { |
| // We currently never include trailing binary operators, but include |
| // other trailing operators. |
| // Thus we usually, but not always, display results for prefixes |
| // of valid expressions, and don't generate an error where we previously |
| // displayed an instant result. This reflects the Android L design. |
| int prefixLen = trailingBinaryOpsStart(); |
| EvalContext ec = new EvalContext(degreeMode, prefixLen); |
| EvalRet res = evalExpr(0, ec); |
| if (res.mPos != prefixLen) { |
| throw new SyntaxException("Failed to parse full expression"); |
| } |
| return new EvalResult(res.mVal, res.mRatVal); |
| } catch (IndexOutOfBoundsException e) { |
| throw new SyntaxException("Unexpected expression end"); |
| } |
| } |
| |
| // Produce a string representation of the expression itself |
| SpannableStringBuilder toSpannableStringBuilder(Context context) { |
| SpannableStringBuilder ssb = new SpannableStringBuilder(); |
| for (Token t: mExpr) { |
| ssb.append(t.toCharSequence(context)); |
| } |
| return ssb; |
| } |
| } |