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      1 /*
      2  * Copyright (C) 2015 The Android Open Source Project
      3  *
      4  * Licensed under the Apache License, Version 2.0 (the "License");
      5  * you may not use this file except in compliance with the License.
      6  * You may obtain a copy of the License at
      7  *
      8  *      http://www.apache.org/licenses/LICENSE-2.0
      9  *
     10  * Unless required by applicable law or agreed to in writing, software
     11  * distributed under the License is distributed on an "AS IS" BASIS,
     12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
     13  * See the License for the specific language governing permissions and
     14  * limitations under the License.
     15  */
     16 
     17 #include <iomanip>
     18 #include <iostream>
     19 #include <cmath>
     20 #include <sstream>
     21 
     22 #include "Generator.h"
     23 #include "Specification.h"
     24 #include "Utilities.h"
     25 
     26 using namespace std;
     27 
     28 // Converts float2 to FLOAT_32 and 2, etc.
     29 static void convertToRsType(const string& name, string* dataType, char* vectorSize) {
     30     string s = name;
     31     int last = s.size() - 1;
     32     char lastChar = s[last];
     33     if (lastChar >= '1' && lastChar <= '4') {
     34         s.erase(last);
     35         *vectorSize = lastChar;
     36     } else {
     37         *vectorSize = '1';
     38     }
     39     dataType->clear();
     40     for (int i = 0; i < NUM_TYPES; i++) {
     41         if (s == TYPES[i].cType) {
     42             *dataType = TYPES[i].rsDataType;
     43             break;
     44         }
     45     }
     46 }
     47 
     48 // Returns true if any permutation of the function have tests to b
     49 static bool needTestFiles(const Function& function, unsigned int versionOfTestFiles) {
     50     for (auto spec : function.getSpecifications()) {
     51         if (spec->hasTests(versionOfTestFiles)) {
     52             return true;
     53         }
     54     }
     55     return false;
     56 }
     57 
     58 /* One instance of this class is generated for each permutation of a function for which
     59  * we are generating test code.  This instance will generate both the script and the Java
     60  * section of the test files for this permutation.  The class is mostly used to keep track
     61  * of the various names shared between script and Java files.
     62  * WARNING: Because the constructor keeps a reference to the FunctionPermutation, PermutationWriter
     63  * should not exceed the lifetime of FunctionPermutation.
     64  */
     65 class PermutationWriter {
     66 private:
     67     FunctionPermutation& mPermutation;
     68 
     69     string mRsKernelName;
     70     string mJavaArgumentsClassName;
     71     string mJavaArgumentsNClassName;
     72     string mJavaVerifierComputeMethodName;
     73     string mJavaVerifierVerifyMethodName;
     74     string mJavaCheckMethodName;
     75     string mJavaVerifyMethodName;
     76 
     77     // Pointer to the files we are generating.  Handy to avoid always passing them in the calls.
     78     GeneratedFile* mRs;
     79     GeneratedFile* mJava;
     80 
     81     /* Shortcuts to the return parameter and the first input parameter of the function
     82      * specification.
     83      */
     84     const ParameterDefinition* mReturnParam;      // Can be nullptr.  NOT OWNED.
     85     const ParameterDefinition* mFirstInputParam;  // Can be nullptr.  NOT OWNED.
     86 
     87     /* All the parameters plus the return param, if present.  Collecting them together
     88      * simplifies code generation.  NOT OWNED.
     89      */
     90     vector<const ParameterDefinition*> mAllInputsAndOutputs;
     91 
     92     /* We use a class to pass the arguments between the generated code and the CoreVerifier.  This
     93      * method generates this class.  The set keeps track if we've generated this class already
     94      * for this test file, as more than one permutation may use the same argument class.
     95      */
     96     void writeJavaArgumentClass(bool scalar, set<string>* javaGeneratedArgumentClasses) const;
     97 
     98     // Generate the Check* method that invokes the script and calls the verifier.
     99     void writeJavaCheckMethod(bool generateCallToVerifier) const;
    100 
    101     // Generate code to define and randomly initialize the input allocation.
    102     void writeJavaInputAllocationDefinition(const ParameterDefinition& param) const;
    103 
    104     /* Generate code that instantiate an allocation of floats or integers and fills it with
    105      * random data. This random data must be compatible with the specified type.  This is
    106      * used for the convert_* tests, as converting values that don't fit yield undefined results.
    107      */
    108     void writeJavaRandomCompatibleFloatAllocation(const string& dataType, const string& seed,
    109                                                   char vectorSize,
    110                                                   const NumericalType& compatibleType,
    111                                                   const NumericalType& generatedType) const;
    112     void writeJavaRandomCompatibleIntegerAllocation(const string& dataType, const string& seed,
    113                                                     char vectorSize,
    114                                                     const NumericalType& compatibleType,
    115                                                     const NumericalType& generatedType) const;
    116 
    117     // Generate code that defines an output allocation.
    118     void writeJavaOutputAllocationDefinition(const ParameterDefinition& param) const;
    119 
    120     /* Generate the code that verifies the results for RenderScript functions where each entry
    121      * of a vector is evaluated independently.  If verifierValidates is true, CoreMathVerifier
    122      * does the actual validation instead of more commonly returning the range of acceptable values.
    123      */
    124     void writeJavaVerifyScalarMethod(bool verifierValidates) const;
    125 
    126     /* Generate the code that verify the results for a RenderScript function where a vector
    127      * is a point in n-dimensional space.
    128      */
    129     void writeJavaVerifyVectorMethod() const;
    130 
    131     // Generate the line that creates the Target.
    132     void writeJavaCreateTarget() const;
    133 
    134     // Generate the method header of the verify function.
    135     void writeJavaVerifyMethodHeader() const;
    136 
    137     // Generate codes that copies the content of an allocation to an array.
    138     void writeJavaArrayInitialization(const ParameterDefinition& p) const;
    139 
    140     // Generate code that tests one value returned from the script.
    141     void writeJavaTestAndSetValid(const ParameterDefinition& p, const string& argsIndex,
    142                                   const string& actualIndex) const;
    143     void writeJavaTestOneValue(const ParameterDefinition& p, const string& argsIndex,
    144                                const string& actualIndex) const;
    145     // For test:vector cases, generate code that compares returned vector vs. expected value.
    146     void writeJavaVectorComparison(const ParameterDefinition& p) const;
    147 
    148     // Muliple functions that generates code to build the error message if an error is found.
    149     void writeJavaAppendOutputToMessage(const ParameterDefinition& p, const string& argsIndex,
    150                                         const string& actualIndex, bool verifierValidates) const;
    151     void writeJavaAppendInputToMessage(const ParameterDefinition& p, const string& actual) const;
    152     void writeJavaAppendNewLineToMessage() const;
    153     void writeJavaAppendVectorInputToMessage(const ParameterDefinition& p) const;
    154     void writeJavaAppendVectorOutputToMessage(const ParameterDefinition& p) const;
    155 
    156     // Generate the set of instructions to call the script.
    157     void writeJavaCallToRs(bool relaxed, bool generateCallToVerifier) const;
    158 
    159     // Write an allocation definition if not already emitted in the .rs file.
    160     void writeRsAllocationDefinition(const ParameterDefinition& param,
    161                                      set<string>* rsAllocationsGenerated) const;
    162 
    163 public:
    164     /* NOTE: We keep pointers to the permutation and the files.  This object should not
    165      * outlive the arguments.
    166      */
    167     PermutationWriter(FunctionPermutation& permutation, GeneratedFile* rsFile,
    168                       GeneratedFile* javaFile);
    169     string getJavaCheckMethodName() const { return mJavaCheckMethodName; }
    170 
    171     // Write the script test function for this permutation.
    172     void writeRsSection(set<string>* rsAllocationsGenerated) const;
    173     // Write the section of the Java code that calls the script and validates the results
    174     void writeJavaSection(set<string>* javaGeneratedArgumentClasses) const;
    175 };
    176 
    177 PermutationWriter::PermutationWriter(FunctionPermutation& permutation, GeneratedFile* rsFile,
    178                                      GeneratedFile* javaFile)
    179     : mPermutation(permutation),
    180       mRs(rsFile),
    181       mJava(javaFile),
    182       mReturnParam(nullptr),
    183       mFirstInputParam(nullptr) {
    184     mRsKernelName = "test" + capitalize(permutation.getName());
    185 
    186     mJavaArgumentsClassName = "Arguments";
    187     mJavaArgumentsNClassName = "Arguments";
    188     const string trunk = capitalize(permutation.getNameTrunk());
    189     mJavaCheckMethodName = "check" + trunk;
    190     mJavaVerifyMethodName = "verifyResults" + trunk;
    191 
    192     for (auto p : permutation.getParams()) {
    193         mAllInputsAndOutputs.push_back(p);
    194         if (mFirstInputParam == nullptr && !p->isOutParameter) {
    195             mFirstInputParam = p;
    196         }
    197     }
    198     mReturnParam = permutation.getReturn();
    199     if (mReturnParam) {
    200         mAllInputsAndOutputs.push_back(mReturnParam);
    201     }
    202 
    203     for (auto p : mAllInputsAndOutputs) {
    204         const string capitalizedRsType = capitalize(p->rsType);
    205         const string capitalizedBaseType = capitalize(p->rsBaseType);
    206         mRsKernelName += capitalizedRsType;
    207         mJavaArgumentsClassName += capitalizedBaseType;
    208         mJavaArgumentsNClassName += capitalizedBaseType;
    209         if (p->mVectorSize != "1") {
    210             mJavaArgumentsNClassName += "N";
    211         }
    212         mJavaCheckMethodName += capitalizedRsType;
    213         mJavaVerifyMethodName += capitalizedRsType;
    214     }
    215     mJavaVerifierComputeMethodName = "compute" + trunk;
    216     mJavaVerifierVerifyMethodName = "verify" + trunk;
    217 }
    218 
    219 void PermutationWriter::writeJavaSection(set<string>* javaGeneratedArgumentClasses) const {
    220     // By default, we test the results using item by item comparison.
    221     const string test = mPermutation.getTest();
    222     if (test == "scalar" || test == "limited") {
    223         writeJavaArgumentClass(true, javaGeneratedArgumentClasses);
    224         writeJavaCheckMethod(true);
    225         writeJavaVerifyScalarMethod(false);
    226     } else if (test == "custom") {
    227         writeJavaArgumentClass(true, javaGeneratedArgumentClasses);
    228         writeJavaCheckMethod(true);
    229         writeJavaVerifyScalarMethod(true);
    230     } else if (test == "vector") {
    231         writeJavaArgumentClass(false, javaGeneratedArgumentClasses);
    232         writeJavaCheckMethod(true);
    233         writeJavaVerifyVectorMethod();
    234     } else if (test == "noverify") {
    235         writeJavaCheckMethod(false);
    236     }
    237 }
    238 
    239 void PermutationWriter::writeJavaArgumentClass(bool scalar,
    240                                                set<string>* javaGeneratedArgumentClasses) const {
    241     string name;
    242     if (scalar) {
    243         name = mJavaArgumentsClassName;
    244     } else {
    245         name = mJavaArgumentsNClassName;
    246     }
    247 
    248     // Make sure we have not generated the argument class already.
    249     if (!testAndSet(name, javaGeneratedArgumentClasses)) {
    250         mJava->indent() << "public class " << name;
    251         mJava->startBlock();
    252 
    253         for (auto p : mAllInputsAndOutputs) {
    254             bool isFieldArray = !scalar && p->mVectorSize != "1";
    255             bool isFloatyField = p->isOutParameter && p->isFloatType && mPermutation.getTest() != "custom";
    256 
    257             mJava->indent() << "public ";
    258             if (isFloatyField) {
    259                 *mJava << "Target.Floaty";
    260             } else {
    261                 *mJava << p->javaBaseType;
    262             }
    263             if (isFieldArray) {
    264                 *mJava << "[]";
    265             }
    266             *mJava << " " << p->variableName << ";\n";
    267 
    268             // For Float16 parameters, add an extra 'double' field in the class
    269             // to hold the Double value converted from the input.
    270             if (p->isFloat16Parameter() && !isFloatyField) {
    271                 mJava->indent() << "public double";
    272                 if (isFieldArray) {
    273                     *mJava << "[]";
    274                 }
    275                 *mJava << " " + p->variableName << "Double;\n";
    276             }
    277         }
    278         mJava->endBlock();
    279         *mJava << "\n";
    280     }
    281 }
    282 
    283 void PermutationWriter::writeJavaCheckMethod(bool generateCallToVerifier) const {
    284     mJava->indent() << "private void " << mJavaCheckMethodName << "()";
    285     mJava->startBlock();
    286 
    287     // Generate the input allocations and initialization.
    288     for (auto p : mAllInputsAndOutputs) {
    289         if (!p->isOutParameter) {
    290             writeJavaInputAllocationDefinition(*p);
    291         }
    292     }
    293     // Generate code to enforce ordering between two allocations if needed.
    294     for (auto p : mAllInputsAndOutputs) {
    295         if (!p->isOutParameter && !p->smallerParameter.empty()) {
    296             string smallerAlloc = "in" + capitalize(p->smallerParameter);
    297             mJava->indent() << "enforceOrdering(" << smallerAlloc << ", " << p->javaAllocName
    298                             << ");\n";
    299         }
    300     }
    301 
    302     // Generate code to check the full and relaxed scripts.
    303     writeJavaCallToRs(false, generateCallToVerifier);
    304     writeJavaCallToRs(true, generateCallToVerifier);
    305 
    306     // Generate code to destroy input Allocations.
    307     for (auto p : mAllInputsAndOutputs) {
    308         if (!p->isOutParameter) {
    309             mJava->indent() << p->javaAllocName << ".destroy();\n";
    310         }
    311     }
    312 
    313     mJava->endBlock();
    314     *mJava << "\n";
    315 }
    316 
    317 void PermutationWriter::writeJavaInputAllocationDefinition(const ParameterDefinition& param) const {
    318     string dataType;
    319     char vectorSize;
    320     convertToRsType(param.rsType, &dataType, &vectorSize);
    321 
    322     const string seed = hashString(mJavaCheckMethodName + param.javaAllocName);
    323     mJava->indent() << "Allocation " << param.javaAllocName << " = ";
    324     if (param.compatibleTypeIndex >= 0) {
    325         if (TYPES[param.typeIndex].kind == FLOATING_POINT) {
    326             writeJavaRandomCompatibleFloatAllocation(dataType, seed, vectorSize,
    327                                                      TYPES[param.compatibleTypeIndex],
    328                                                      TYPES[param.typeIndex]);
    329         } else {
    330             writeJavaRandomCompatibleIntegerAllocation(dataType, seed, vectorSize,
    331                                                        TYPES[param.compatibleTypeIndex],
    332                                                        TYPES[param.typeIndex]);
    333         }
    334     } else if (!param.minValue.empty()) {
    335         *mJava << "createRandomFloatAllocation(mRS, Element.DataType." << dataType << ", "
    336                << vectorSize << ", " << seed << ", " << param.minValue << ", " << param.maxValue
    337                << ")";
    338     } else {
    339         /* TODO Instead of passing always false, check whether we are doing a limited test.
    340          * Use instead: (mPermutation.getTest() == "limited" ? "false" : "true")
    341          */
    342         *mJava << "createRandomAllocation(mRS, Element.DataType." << dataType << ", " << vectorSize
    343                << ", " << seed << ", false)";
    344     }
    345     *mJava << ";\n";
    346 }
    347 
    348 void PermutationWriter::writeJavaRandomCompatibleFloatAllocation(
    349             const string& dataType, const string& seed, char vectorSize,
    350             const NumericalType& compatibleType, const NumericalType& generatedType) const {
    351     *mJava << "createRandomFloatAllocation"
    352            << "(mRS, Element.DataType." << dataType << ", " << vectorSize << ", " << seed << ", ";
    353     double minValue = 0.0;
    354     double maxValue = 0.0;
    355     switch (compatibleType.kind) {
    356         case FLOATING_POINT: {
    357             // We're generating floating point values.  We just worry about the exponent.
    358             // Subtract 1 for the exponent sign.
    359             int bits = min(compatibleType.exponentBits, generatedType.exponentBits) - 1;
    360             maxValue = ldexp(0.95, (1 << bits) - 1);
    361             minValue = -maxValue;
    362             break;
    363         }
    364         case UNSIGNED_INTEGER:
    365             maxValue = maxDoubleForInteger(compatibleType.significantBits,
    366                                            generatedType.significantBits);
    367             minValue = 0.0;
    368             break;
    369         case SIGNED_INTEGER:
    370             maxValue = maxDoubleForInteger(compatibleType.significantBits,
    371                                            generatedType.significantBits);
    372             minValue = -maxValue - 1.0;
    373             break;
    374     }
    375     *mJava << scientific << std::setprecision(19);
    376     *mJava << minValue << ", " << maxValue << ")";
    377     mJava->unsetf(ios_base::floatfield);
    378 }
    379 
    380 void PermutationWriter::writeJavaRandomCompatibleIntegerAllocation(
    381             const string& dataType, const string& seed, char vectorSize,
    382             const NumericalType& compatibleType, const NumericalType& generatedType) const {
    383     *mJava << "createRandomIntegerAllocation"
    384            << "(mRS, Element.DataType." << dataType << ", " << vectorSize << ", " << seed << ", ";
    385 
    386     if (compatibleType.kind == FLOATING_POINT) {
    387         // Currently, all floating points can take any number we generate.
    388         bool isSigned = generatedType.kind == SIGNED_INTEGER;
    389         *mJava << (isSigned ? "true" : "false") << ", " << generatedType.significantBits;
    390     } else {
    391         bool isSigned =
    392                     compatibleType.kind == SIGNED_INTEGER && generatedType.kind == SIGNED_INTEGER;
    393         *mJava << (isSigned ? "true" : "false") << ", "
    394                << min(compatibleType.significantBits, generatedType.significantBits);
    395     }
    396     *mJava << ")";
    397 }
    398 
    399 void PermutationWriter::writeJavaOutputAllocationDefinition(
    400             const ParameterDefinition& param) const {
    401     string dataType;
    402     char vectorSize;
    403     convertToRsType(param.rsType, &dataType, &vectorSize);
    404     mJava->indent() << "Allocation " << param.javaAllocName << " = Allocation.createSized(mRS, "
    405                     << "getElement(mRS, Element.DataType." << dataType << ", " << vectorSize
    406                     << "), INPUTSIZE);\n";
    407 }
    408 
    409 void PermutationWriter::writeJavaVerifyScalarMethod(bool verifierValidates) const {
    410     writeJavaVerifyMethodHeader();
    411     mJava->startBlock();
    412 
    413     string vectorSize = "1";
    414     for (auto p : mAllInputsAndOutputs) {
    415         writeJavaArrayInitialization(*p);
    416         if (p->mVectorSize != "1" && p->mVectorSize != vectorSize) {
    417             if (vectorSize == "1") {
    418                 vectorSize = p->mVectorSize;
    419             } else {
    420                 cerr << "Error.  Had vector " << vectorSize << " and " << p->mVectorSize << "\n";
    421             }
    422         }
    423     }
    424 
    425     mJava->indent() << "StringBuilder message = new StringBuilder();\n";
    426     mJava->indent() << "boolean errorFound = false;\n";
    427     mJava->indent() << "for (int i = 0; i < INPUTSIZE; i++)";
    428     mJava->startBlock();
    429 
    430     mJava->indent() << "for (int j = 0; j < " << vectorSize << " ; j++)";
    431     mJava->startBlock();
    432 
    433     mJava->indent() << "// Extract the inputs.\n";
    434     mJava->indent() << mJavaArgumentsClassName << " args = new " << mJavaArgumentsClassName
    435                     << "();\n";
    436     for (auto p : mAllInputsAndOutputs) {
    437         if (!p->isOutParameter) {
    438             mJava->indent() << "args." << p->variableName << " = " << p->javaArrayName << "[i";
    439             if (p->vectorWidth != "1") {
    440                 *mJava << " * " << p->vectorWidth << " + j";
    441             }
    442             *mJava << "];\n";
    443 
    444             // Convert the Float16 parameter to double and store it in the appropriate field in the
    445             // Arguments class.
    446             if (p->isFloat16Parameter()) {
    447                 mJava->indent() << "args." << p->doubleVariableName
    448                                 << " = Float16Utils.convertFloat16ToDouble(args."
    449                                 << p->variableName << ");\n";
    450             }
    451         }
    452     }
    453     const bool hasFloat = mPermutation.hasFloatAnswers();
    454     if (verifierValidates) {
    455         mJava->indent() << "// Extract the outputs.\n";
    456         for (auto p : mAllInputsAndOutputs) {
    457             if (p->isOutParameter) {
    458                 mJava->indent() << "args." << p->variableName << " = " << p->javaArrayName
    459                                 << "[i * " << p->vectorWidth << " + j];\n";
    460                 if (p->isFloat16Parameter()) {
    461                     mJava->indent() << "args." << p->doubleVariableName
    462                                     << " = Float16Utils.convertFloat16ToDouble(args."
    463                                     << p->variableName << ");\n";
    464                 }
    465             }
    466         }
    467         mJava->indent() << "// Ask the CoreMathVerifier to validate.\n";
    468         if (hasFloat) {
    469             writeJavaCreateTarget();
    470         }
    471         mJava->indent() << "String errorMessage = CoreMathVerifier."
    472                         << mJavaVerifierVerifyMethodName << "(args";
    473         if (hasFloat) {
    474             *mJava << ", target";
    475         }
    476         *mJava << ");\n";
    477         mJava->indent() << "boolean valid = errorMessage == null;\n";
    478     } else {
    479         mJava->indent() << "// Figure out what the outputs should have been.\n";
    480         if (hasFloat) {
    481             writeJavaCreateTarget();
    482         }
    483         mJava->indent() << "CoreMathVerifier." << mJavaVerifierComputeMethodName << "(args";
    484         if (hasFloat) {
    485             *mJava << ", target";
    486         }
    487         *mJava << ");\n";
    488         mJava->indent() << "// Validate the outputs.\n";
    489         mJava->indent() << "boolean valid = true;\n";
    490         for (auto p : mAllInputsAndOutputs) {
    491             if (p->isOutParameter) {
    492                 writeJavaTestAndSetValid(*p, "", "[i * " + p->vectorWidth + " + j]");
    493             }
    494         }
    495     }
    496 
    497     mJava->indent() << "if (!valid)";
    498     mJava->startBlock();
    499     mJava->indent() << "if (!errorFound)";
    500     mJava->startBlock();
    501     mJava->indent() << "errorFound = true;\n";
    502 
    503     for (auto p : mAllInputsAndOutputs) {
    504         if (p->isOutParameter) {
    505             writeJavaAppendOutputToMessage(*p, "", "[i * " + p->vectorWidth + " + j]",
    506                                            verifierValidates);
    507         } else {
    508             writeJavaAppendInputToMessage(*p, "args." + p->variableName);
    509         }
    510     }
    511     if (verifierValidates) {
    512         mJava->indent() << "message.append(errorMessage);\n";
    513     }
    514     mJava->indent() << "message.append(\"Errors at\");\n";
    515     mJava->endBlock();
    516 
    517     mJava->indent() << "message.append(\" [\");\n";
    518     mJava->indent() << "message.append(Integer.toString(i));\n";
    519     mJava->indent() << "message.append(\", \");\n";
    520     mJava->indent() << "message.append(Integer.toString(j));\n";
    521     mJava->indent() << "message.append(\"]\");\n";
    522 
    523     mJava->endBlock();
    524     mJava->endBlock();
    525     mJava->endBlock();
    526 
    527     mJava->indent() << "assertFalse(\"Incorrect output for " << mJavaCheckMethodName << "\" +\n";
    528     mJava->indentPlus()
    529                 << "(relaxed ? \"_relaxed\" : \"\") + \":\\n\" + message.toString(), errorFound);\n";
    530 
    531     mJava->endBlock();
    532     *mJava << "\n";
    533 }
    534 
    535 void PermutationWriter::writeJavaVerifyVectorMethod() const {
    536     writeJavaVerifyMethodHeader();
    537     mJava->startBlock();
    538 
    539     for (auto p : mAllInputsAndOutputs) {
    540         writeJavaArrayInitialization(*p);
    541     }
    542     mJava->indent() << "StringBuilder message = new StringBuilder();\n";
    543     mJava->indent() << "boolean errorFound = false;\n";
    544     mJava->indent() << "for (int i = 0; i < INPUTSIZE; i++)";
    545     mJava->startBlock();
    546 
    547     mJava->indent() << mJavaArgumentsNClassName << " args = new " << mJavaArgumentsNClassName
    548                     << "();\n";
    549 
    550     mJava->indent() << "// Create the appropriate sized arrays in args\n";
    551     for (auto p : mAllInputsAndOutputs) {
    552         if (p->mVectorSize != "1") {
    553             string type = p->javaBaseType;
    554             if (p->isOutParameter && p->isFloatType) {
    555                 type = "Target.Floaty";
    556             }
    557             mJava->indent() << "args." << p->variableName << " = new " << type << "["
    558                             << p->mVectorSize << "];\n";
    559             if (p->isFloat16Parameter() && !p->isOutParameter) {
    560                 mJava->indent() << "args." << p->variableName << "Double = new double["
    561                                 << p->mVectorSize << "];\n";
    562             }
    563         }
    564     }
    565 
    566     mJava->indent() << "// Fill args with the input values\n";
    567     for (auto p : mAllInputsAndOutputs) {
    568         if (!p->isOutParameter) {
    569             if (p->mVectorSize == "1") {
    570                 mJava->indent() << "args." << p->variableName << " = " << p->javaArrayName << "[i]"
    571                                 << ";\n";
    572                 // Convert the Float16 parameter to double and store it in the appropriate field in
    573                 // the Arguments class.
    574                 if (p->isFloat16Parameter()) {
    575                     mJava->indent() << "args." << p->doubleVariableName << " = "
    576                                     << "Float16Utils.convertFloat16ToDouble(args."
    577                                     << p->variableName << ");\n";
    578                 }
    579             } else {
    580                 mJava->indent() << "for (int j = 0; j < " << p->mVectorSize << " ; j++)";
    581                 mJava->startBlock();
    582                 mJava->indent() << "args." << p->variableName << "[j] = "
    583                                 << p->javaArrayName << "[i * " << p->vectorWidth << " + j]"
    584                                 << ";\n";
    585 
    586                 // Convert the Float16 parameter to double and store it in the appropriate field in
    587                 // the Arguments class.
    588                 if (p->isFloat16Parameter()) {
    589                     mJava->indent() << "args." << p->doubleVariableName << "[j] = "
    590                                     << "Float16Utils.convertFloat16ToDouble(args."
    591                                     << p->variableName << "[j]);\n";
    592                 }
    593                 mJava->endBlock();
    594             }
    595         }
    596     }
    597     writeJavaCreateTarget();
    598     mJava->indent() << "CoreMathVerifier." << mJavaVerifierComputeMethodName
    599                     << "(args, target);\n\n";
    600 
    601     mJava->indent() << "// Compare the expected outputs to the actual values returned by RS.\n";
    602     mJava->indent() << "boolean valid = true;\n";
    603     for (auto p : mAllInputsAndOutputs) {
    604         if (p->isOutParameter) {
    605             writeJavaVectorComparison(*p);
    606         }
    607     }
    608 
    609     mJava->indent() << "if (!valid)";
    610     mJava->startBlock();
    611     mJava->indent() << "if (!errorFound)";
    612     mJava->startBlock();
    613     mJava->indent() << "errorFound = true;\n";
    614 
    615     for (auto p : mAllInputsAndOutputs) {
    616         if (p->isOutParameter) {
    617             writeJavaAppendVectorOutputToMessage(*p);
    618         } else {
    619             writeJavaAppendVectorInputToMessage(*p);
    620         }
    621     }
    622     mJava->indent() << "message.append(\"Errors at\");\n";
    623     mJava->endBlock();
    624 
    625     mJava->indent() << "message.append(\" [\");\n";
    626     mJava->indent() << "message.append(Integer.toString(i));\n";
    627     mJava->indent() << "message.append(\"]\");\n";
    628 
    629     mJava->endBlock();
    630     mJava->endBlock();
    631 
    632     mJava->indent() << "assertFalse(\"Incorrect output for " << mJavaCheckMethodName << "\" +\n";
    633     mJava->indentPlus()
    634                 << "(relaxed ? \"_relaxed\" : \"\") + \":\\n\" + message.toString(), errorFound);\n";
    635 
    636     mJava->endBlock();
    637     *mJava << "\n";
    638 }
    639 
    640 
    641 void PermutationWriter::writeJavaCreateTarget() const {
    642     string name = mPermutation.getName();
    643 
    644     const char* functionType = "NORMAL";
    645     size_t end = name.find('_');
    646     if (end != string::npos) {
    647         if (name.compare(0, end, "native") == 0) {
    648             functionType = "NATIVE";
    649         } else if (name.compare(0, end, "half") == 0) {
    650             functionType = "HALF";
    651         } else if (name.compare(0, end, "fast") == 0) {
    652             functionType = "FAST";
    653         }
    654     }
    655 
    656     string floatType = mReturnParam->specType;
    657     const char* precisionStr = "";
    658     if (floatType.compare("f16") == 0) {
    659         precisionStr = "HALF";
    660     } else if (floatType.compare("f32") == 0) {
    661         precisionStr = "FLOAT";
    662     } else if (floatType.compare("f64") == 0) {
    663         precisionStr = "DOUBLE";
    664     } else {
    665         cerr << "Error. Unreachable.  Return type is not floating point\n";
    666     }
    667 
    668     mJava->indent() << "Target target = new Target(Target.FunctionType." <<
    669                     functionType << ", Target.ReturnType." << precisionStr <<
    670                     ", relaxed);\n";
    671 }
    672 
    673 void PermutationWriter::writeJavaVerifyMethodHeader() const {
    674     mJava->indent() << "private void " << mJavaVerifyMethodName << "(";
    675     for (auto p : mAllInputsAndOutputs) {
    676         *mJava << "Allocation " << p->javaAllocName << ", ";
    677     }
    678     *mJava << "boolean relaxed)";
    679 }
    680 
    681 void PermutationWriter::writeJavaArrayInitialization(const ParameterDefinition& p) const {
    682     mJava->indent() << p.javaBaseType << "[] " << p.javaArrayName << " = new " << p.javaBaseType
    683                     << "[INPUTSIZE * " << p.vectorWidth << "];\n";
    684 
    685     /* For basic types, populate the array with values, to help understand failures.  We have had
    686      * bugs where the output buffer was all 0.  We were not sure if there was a failed copy or
    687      * the GPU driver was copying zeroes.
    688      */
    689     if (p.typeIndex >= 0) {
    690         mJava->indent() << "Arrays.fill(" << p.javaArrayName << ", (" << TYPES[p.typeIndex].javaType
    691                         << ") 42);\n";
    692     }
    693 
    694     mJava->indent() << p.javaAllocName << ".copyTo(" << p.javaArrayName << ");\n";
    695 }
    696 
    697 void PermutationWriter::writeJavaTestAndSetValid(const ParameterDefinition& p,
    698                                                  const string& argsIndex,
    699                                                  const string& actualIndex) const {
    700     writeJavaTestOneValue(p, argsIndex, actualIndex);
    701     mJava->startBlock();
    702     mJava->indent() << "valid = false;\n";
    703     mJava->endBlock();
    704 }
    705 
    706 void PermutationWriter::writeJavaTestOneValue(const ParameterDefinition& p, const string& argsIndex,
    707                                               const string& actualIndex) const {
    708     string actualOut;
    709     if (p.isFloat16Parameter()) {
    710         // For Float16 values, the output needs to be converted to Double.
    711         actualOut = "Float16Utils.convertFloat16ToDouble(" + p.javaArrayName + actualIndex + ")";
    712     } else {
    713         actualOut = p.javaArrayName + actualIndex;
    714     }
    715 
    716     mJava->indent() << "if (";
    717     if (p.isFloatType) {
    718         *mJava << "!args." << p.variableName << argsIndex << ".couldBe(" << actualOut;
    719         const string s = mPermutation.getPrecisionLimit();
    720         if (!s.empty()) {
    721             *mJava << ", " << s;
    722         }
    723         *mJava << ")";
    724     } else {
    725         *mJava << "args." << p.variableName << argsIndex << " != " << p.javaArrayName
    726                << actualIndex;
    727     }
    728 
    729     if (p.undefinedIfOutIsNan && mReturnParam) {
    730         *mJava << " && !args." << mReturnParam->variableName << argsIndex << ".isNaN()";
    731     }
    732     *mJava << ")";
    733 }
    734 
    735 void PermutationWriter::writeJavaVectorComparison(const ParameterDefinition& p) const {
    736     if (p.mVectorSize == "1") {
    737         writeJavaTestAndSetValid(p, "", "[i]");
    738     } else {
    739         mJava->indent() << "for (int j = 0; j < " << p.mVectorSize << " ; j++)";
    740         mJava->startBlock();
    741         writeJavaTestAndSetValid(p, "[j]", "[i * " + p.vectorWidth + " + j]");
    742         mJava->endBlock();
    743     }
    744 }
    745 
    746 void PermutationWriter::writeJavaAppendOutputToMessage(const ParameterDefinition& p,
    747                                                        const string& argsIndex,
    748                                                        const string& actualIndex,
    749                                                        bool verifierValidates) const {
    750     if (verifierValidates) {
    751         mJava->indent() << "message.append(\"Output " << p.variableName << ": \");\n";
    752         mJava->indent() << "appendVariableToMessage(message, args." << p.variableName << argsIndex
    753                         << ");\n";
    754         writeJavaAppendNewLineToMessage();
    755         if (p.isFloat16Parameter()) {
    756             writeJavaAppendNewLineToMessage();
    757             mJava->indent() << "message.append(\"Output " << p.variableName
    758                             << " (in double): \");\n";
    759             mJava->indent() << "appendVariableToMessage(message, args." << p.doubleVariableName
    760                             << ");\n";
    761             writeJavaAppendNewLineToMessage();
    762         }
    763     } else {
    764         mJava->indent() << "message.append(\"Expected output " << p.variableName << ": \");\n";
    765         mJava->indent() << "appendVariableToMessage(message, args." << p.variableName << argsIndex
    766                         << ");\n";
    767         writeJavaAppendNewLineToMessage();
    768 
    769         mJava->indent() << "message.append(\"Actual   output " << p.variableName << ": \");\n";
    770         mJava->indent() << "appendVariableToMessage(message, " << p.javaArrayName << actualIndex
    771                         << ");\n";
    772 
    773         if (p.isFloat16Parameter()) {
    774             writeJavaAppendNewLineToMessage();
    775             mJava->indent() << "message.append(\"Actual   output " << p.variableName
    776                             << " (in double): \");\n";
    777             mJava->indent() << "appendVariableToMessage(message, Float16Utils.convertFloat16ToDouble("
    778                             << p.javaArrayName << actualIndex << "));\n";
    779         }
    780 
    781         writeJavaTestOneValue(p, argsIndex, actualIndex);
    782         mJava->startBlock();
    783         mJava->indent() << "message.append(\" FAIL\");\n";
    784         mJava->endBlock();
    785         writeJavaAppendNewLineToMessage();
    786     }
    787 }
    788 
    789 void PermutationWriter::writeJavaAppendInputToMessage(const ParameterDefinition& p,
    790                                                       const string& actual) const {
    791     mJava->indent() << "message.append(\"Input " << p.variableName << ": \");\n";
    792     mJava->indent() << "appendVariableToMessage(message, " << actual << ");\n";
    793     writeJavaAppendNewLineToMessage();
    794 }
    795 
    796 void PermutationWriter::writeJavaAppendNewLineToMessage() const {
    797     mJava->indent() << "message.append(\"\\n\");\n";
    798 }
    799 
    800 void PermutationWriter::writeJavaAppendVectorInputToMessage(const ParameterDefinition& p) const {
    801     if (p.mVectorSize == "1") {
    802         writeJavaAppendInputToMessage(p, p.javaArrayName + "[i]");
    803     } else {
    804         mJava->indent() << "for (int j = 0; j < " << p.mVectorSize << " ; j++)";
    805         mJava->startBlock();
    806         writeJavaAppendInputToMessage(p, p.javaArrayName + "[i * " + p.vectorWidth + " + j]");
    807         mJava->endBlock();
    808     }
    809 }
    810 
    811 void PermutationWriter::writeJavaAppendVectorOutputToMessage(const ParameterDefinition& p) const {
    812     if (p.mVectorSize == "1") {
    813         writeJavaAppendOutputToMessage(p, "", "[i]", false);
    814     } else {
    815         mJava->indent() << "for (int j = 0; j < " << p.mVectorSize << " ; j++)";
    816         mJava->startBlock();
    817         writeJavaAppendOutputToMessage(p, "[j]", "[i * " + p.vectorWidth + " + j]", false);
    818         mJava->endBlock();
    819     }
    820 }
    821 
    822 void PermutationWriter::writeJavaCallToRs(bool relaxed, bool generateCallToVerifier) const {
    823     string script = "script";
    824     if (relaxed) {
    825         script += "Relaxed";
    826     }
    827 
    828     mJava->indent() << "try";
    829     mJava->startBlock();
    830 
    831     for (auto p : mAllInputsAndOutputs) {
    832         if (p->isOutParameter) {
    833             writeJavaOutputAllocationDefinition(*p);
    834         }
    835     }
    836 
    837     for (auto p : mPermutation.getParams()) {
    838         if (p != mFirstInputParam) {
    839             mJava->indent() << script << ".set_" << p->rsAllocName << "(" << p->javaAllocName
    840                             << ");\n";
    841         }
    842     }
    843 
    844     mJava->indent() << script << ".forEach_" << mRsKernelName << "(";
    845     bool needComma = false;
    846     if (mFirstInputParam) {
    847         *mJava << mFirstInputParam->javaAllocName;
    848         needComma = true;
    849     }
    850     if (mReturnParam) {
    851         if (needComma) {
    852             *mJava << ", ";
    853         }
    854         *mJava << mReturnParam->variableName << ");\n";
    855     }
    856 
    857     if (generateCallToVerifier) {
    858         mJava->indent() << mJavaVerifyMethodName << "(";
    859         for (auto p : mAllInputsAndOutputs) {
    860             *mJava << p->variableName << ", ";
    861         }
    862 
    863         if (relaxed) {
    864             *mJava << "true";
    865         } else {
    866             *mJava << "false";
    867         }
    868         *mJava << ");\n";
    869     }
    870 
    871     // Generate code to destroy output Allocations.
    872     for (auto p : mAllInputsAndOutputs) {
    873         if (p->isOutParameter) {
    874             mJava->indent() << p->javaAllocName << ".destroy();\n";
    875         }
    876     }
    877 
    878     mJava->decreaseIndent();
    879     mJava->indent() << "} catch (Exception e) {\n";
    880     mJava->increaseIndent();
    881     mJava->indent() << "throw new RSRuntimeException(\"RenderScript. Can't invoke forEach_"
    882                     << mRsKernelName << ": \" + e.toString());\n";
    883     mJava->endBlock();
    884 }
    885 
    886 /* Write the section of the .rs file for this permutation.
    887  *
    888  * We communicate the extra input and output parameters via global allocations.
    889  * For example, if we have a function that takes three arguments, two for input
    890  * and one for output:
    891  *
    892  * start:
    893  * name: gamn
    894  * ret: float3
    895  * arg: float3 a
    896  * arg: int b
    897  * arg: float3 *c
    898  * end:
    899  *
    900  * We'll produce:
    901  *
    902  * rs_allocation gAllocInB;
    903  * rs_allocation gAllocOutC;
    904  *
    905  * float3 __attribute__((kernel)) test_gamn_float3_int_float3(float3 inA, unsigned int x) {
    906  *    int inB;
    907  *    float3 outC;
    908  *    float2 out;
    909  *    inB = rsGetElementAt_int(gAllocInB, x);
    910  *    out = gamn(a, in_b, &outC);
    911  *    rsSetElementAt_float4(gAllocOutC, &outC, x);
    912  *    return out;
    913  * }
    914  *
    915  * We avoid re-using x and y from the definition because these have reserved
    916  * meanings in a .rs file.
    917  */
    918 void PermutationWriter::writeRsSection(set<string>* rsAllocationsGenerated) const {
    919     // Write the allocation declarations we'll need.
    920     for (auto p : mPermutation.getParams()) {
    921         // Don't need allocation for one input and one return value.
    922         if (p != mFirstInputParam) {
    923             writeRsAllocationDefinition(*p, rsAllocationsGenerated);
    924         }
    925     }
    926     *mRs << "\n";
    927 
    928     // Write the function header.
    929     if (mReturnParam) {
    930         *mRs << mReturnParam->rsType;
    931     } else {
    932         *mRs << "void";
    933     }
    934     *mRs << " __attribute__((kernel)) " << mRsKernelName;
    935     *mRs << "(";
    936     bool needComma = false;
    937     if (mFirstInputParam) {
    938         *mRs << mFirstInputParam->rsType << " " << mFirstInputParam->variableName;
    939         needComma = true;
    940     }
    941     if (mPermutation.getOutputCount() > 1 || mPermutation.getInputCount() > 1) {
    942         if (needComma) {
    943             *mRs << ", ";
    944         }
    945         *mRs << "unsigned int x";
    946     }
    947     *mRs << ")";
    948     mRs->startBlock();
    949 
    950     // Write the local variable declarations and initializations.
    951     for (auto p : mPermutation.getParams()) {
    952         if (p == mFirstInputParam) {
    953             continue;
    954         }
    955         mRs->indent() << p->rsType << " " << p->variableName;
    956         if (p->isOutParameter) {
    957             *mRs << " = 0;\n";
    958         } else {
    959             *mRs << " = rsGetElementAt_" << p->rsType << "(" << p->rsAllocName << ", x);\n";
    960         }
    961     }
    962 
    963     // Write the function call.
    964     if (mReturnParam) {
    965         if (mPermutation.getOutputCount() > 1) {
    966             mRs->indent() << mReturnParam->rsType << " " << mReturnParam->variableName << " = ";
    967         } else {
    968             mRs->indent() << "return ";
    969         }
    970     }
    971     *mRs << mPermutation.getName() << "(";
    972     needComma = false;
    973     for (auto p : mPermutation.getParams()) {
    974         if (needComma) {
    975             *mRs << ", ";
    976         }
    977         if (p->isOutParameter) {
    978             *mRs << "&";
    979         }
    980         *mRs << p->variableName;
    981         needComma = true;
    982     }
    983     *mRs << ");\n";
    984 
    985     if (mPermutation.getOutputCount() > 1) {
    986         // Write setting the extra out parameters into the allocations.
    987         for (auto p : mPermutation.getParams()) {
    988             if (p->isOutParameter) {
    989                 mRs->indent() << "rsSetElementAt_" << p->rsType << "(" << p->rsAllocName << ", ";
    990                 // Check if we need to use '&' for this type of argument.
    991                 char lastChar = p->variableName.back();
    992                 if (lastChar >= '0' && lastChar <= '9') {
    993                     *mRs << "&";
    994                 }
    995                 *mRs << p->variableName << ", x);\n";
    996             }
    997         }
    998         if (mReturnParam) {
    999             mRs->indent() << "return " << mReturnParam->variableName << ";\n";
   1000         }
   1001     }
   1002     mRs->endBlock();
   1003 }
   1004 
   1005 void PermutationWriter::writeRsAllocationDefinition(const ParameterDefinition& param,
   1006                                                     set<string>* rsAllocationsGenerated) const {
   1007     if (!testAndSet(param.rsAllocName, rsAllocationsGenerated)) {
   1008         *mRs << "rs_allocation " << param.rsAllocName << ";\n";
   1009     }
   1010 }
   1011 
   1012 // Open the mJavaFile and writes the header.
   1013 static bool startJavaFile(GeneratedFile* file, const Function& function, const string& directory,
   1014                           const string& testName, const string& relaxedTestName) {
   1015     const string fileName = testName + ".java";
   1016     if (!file->start(directory, fileName)) {
   1017         return false;
   1018     }
   1019     file->writeNotices();
   1020 
   1021     *file << "package android.renderscript.cts;\n\n";
   1022 
   1023     *file << "import android.renderscript.Allocation;\n";
   1024     *file << "import android.renderscript.RSRuntimeException;\n";
   1025     *file << "import android.renderscript.Element;\n";
   1026     *file << "import android.renderscript.cts.Target;\n\n";
   1027     *file << "import java.util.Arrays;\n\n";
   1028 
   1029     *file << "public class " << testName << " extends RSBaseCompute";
   1030     file->startBlock();  // The corresponding endBlock() is in finishJavaFile()
   1031     *file << "\n";
   1032 
   1033     file->indent() << "private ScriptC_" << testName << " script;\n";
   1034     file->indent() << "private ScriptC_" << relaxedTestName << " scriptRelaxed;\n\n";
   1035 
   1036     file->indent() << "@Override\n";
   1037     file->indent() << "protected void setUp() throws Exception";
   1038     file->startBlock();
   1039 
   1040     file->indent() << "super.setUp();\n";
   1041     file->indent() << "script = new ScriptC_" << testName << "(mRS);\n";
   1042     file->indent() << "scriptRelaxed = new ScriptC_" << relaxedTestName << "(mRS);\n";
   1043 
   1044     file->endBlock();
   1045     *file << "\n";
   1046 
   1047     file->indent() << "@Override\n";
   1048     file->indent() << "protected void tearDown() throws Exception";
   1049     file->startBlock();
   1050 
   1051     file->indent() << "script.destroy();\n";
   1052     file->indent() << "scriptRelaxed.destroy();\n";
   1053     file->indent() << "super.tearDown();\n";
   1054 
   1055     file->endBlock();
   1056     *file << "\n";
   1057 
   1058     return true;
   1059 }
   1060 
   1061 // Write the test method that calls all the generated Check methods.
   1062 static void finishJavaFile(GeneratedFile* file, const Function& function,
   1063                            const vector<string>& javaCheckMethods) {
   1064     file->indent() << "public void test" << function.getCapitalizedName() << "()";
   1065     file->startBlock();
   1066     for (auto m : javaCheckMethods) {
   1067         file->indent() << m << "();\n";
   1068     }
   1069     file->endBlock();
   1070 
   1071     file->endBlock();
   1072 }
   1073 
   1074 // Open the script file and write its header.
   1075 static bool startRsFile(GeneratedFile* file, const Function& function, const string& directory,
   1076                         const string& testName) {
   1077     string fileName = testName + ".rs";
   1078     if (!file->start(directory, fileName)) {
   1079         return false;
   1080     }
   1081     file->writeNotices();
   1082 
   1083     *file << "#pragma version(1)\n";
   1084     *file << "#pragma rs java_package_name(android.renderscript.cts)\n\n";
   1085     return true;
   1086 }
   1087 
   1088 // Write the entire *Relaxed.rs test file, as it only depends on the name.
   1089 static bool writeRelaxedRsFile(const Function& function, const string& directory,
   1090                                const string& testName, const string& relaxedTestName) {
   1091     string name = relaxedTestName + ".rs";
   1092 
   1093     GeneratedFile file;
   1094     if (!file.start(directory, name)) {
   1095         return false;
   1096     }
   1097     file.writeNotices();
   1098 
   1099     file << "#include \"" << testName << ".rs\"\n";
   1100     file << "#pragma rs_fp_relaxed\n";
   1101     file.close();
   1102     return true;
   1103 }
   1104 
   1105 /* Write the .java and the two .rs test files.  versionOfTestFiles is used to restrict which API
   1106  * to test.
   1107  */
   1108 static bool writeTestFilesForFunction(const Function& function, const string& directory,
   1109                                       unsigned int versionOfTestFiles) {
   1110     // Avoid creating empty files if we're not testing this function.
   1111     if (!needTestFiles(function, versionOfTestFiles)) {
   1112         return true;
   1113     }
   1114 
   1115     const string testName = "Test" + function.getCapitalizedName();
   1116     const string relaxedTestName = testName + "Relaxed";
   1117 
   1118     if (!writeRelaxedRsFile(function, directory, testName, relaxedTestName)) {
   1119         return false;
   1120     }
   1121 
   1122     GeneratedFile rsFile;    // The Renderscript test file we're generating.
   1123     GeneratedFile javaFile;  // The Jave test file we're generating.
   1124     if (!startRsFile(&rsFile, function, directory, testName)) {
   1125         return false;
   1126     }
   1127 
   1128     if (!startJavaFile(&javaFile, function, directory, testName, relaxedTestName)) {
   1129         return false;
   1130     }
   1131 
   1132     /* We keep track of the allocations generated in the .rs file and the argument classes defined
   1133      * in the Java file, as we share these between the functions created for each specification.
   1134      */
   1135     set<string> rsAllocationsGenerated;
   1136     set<string> javaGeneratedArgumentClasses;
   1137     // Lines of Java code to invoke the check methods.
   1138     vector<string> javaCheckMethods;
   1139 
   1140     for (auto spec : function.getSpecifications()) {
   1141         if (spec->hasTests(versionOfTestFiles)) {
   1142             for (auto permutation : spec->getPermutations()) {
   1143                 PermutationWriter w(*permutation, &rsFile, &javaFile);
   1144                 w.writeRsSection(&rsAllocationsGenerated);
   1145                 w.writeJavaSection(&javaGeneratedArgumentClasses);
   1146 
   1147                 // Store the check method to be called.
   1148                 javaCheckMethods.push_back(w.getJavaCheckMethodName());
   1149             }
   1150         }
   1151     }
   1152 
   1153     finishJavaFile(&javaFile, function, javaCheckMethods);
   1154     // There's no work to wrap-up in the .rs file.
   1155 
   1156     rsFile.close();
   1157     javaFile.close();
   1158     return true;
   1159 }
   1160 
   1161 bool generateTestFiles(const string& directory, unsigned int versionOfTestFiles) {
   1162     bool success = true;
   1163     for (auto f : systemSpecification.getFunctions()) {
   1164         if (!writeTestFilesForFunction(*f.second, directory, versionOfTestFiles)) {
   1165             success = false;
   1166         }
   1167     }
   1168     return success;
   1169 }
   1170