//===-- StackerCompiler.cpp - Parser for llvm assembly files ----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file was developed by Reid Spencer and donated to the LLVM research // group and is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the compiler for the "Stacker" language. // //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // Globasl - Global variables we use //===----------------------------------------------------------------------===// #include "llvm/PassManager.h" #include "llvm/Analysis/LoadValueNumbering.h" #include "llvm/Analysis/Verifier.h" #include "llvm/Assembly/Parser.h" #include "llvm/Target/TargetData.h" #include "llvm/Transforms/IPO.h" #include "llvm/Transforms/Scalar.h" #include "llvm/Instructions.h" #include "llvm/ADT/Statistic.h" #include "StackerCompiler.h" #include "StackerParser.h" #include // Lexer/Parser defined variables and functions extern std::FILE *Stackerin; extern int Stackerlineno; extern char* Stackertext; extern int Stackerleng; extern int Stackerparse(); StackerCompiler* StackerCompiler::TheInstance = 0; static Statistic<> NumDefinitions( "numdefs","The # of definitions encoutered while compiling Stacker"); StackerCompiler::StackerCompiler() : CurFilename("") , TheModule(0) , TheFunction(0) , DefinitionType(0) , TheStack(0) , TheIndex(0) , TheScanf(0) , ThePrintf(0) , TheExit(0) , StrFormat(0) , NumFormat(0) , ChrFormat(0) , InStrFormat(0) , InNumFormat(0) , InChrFormat(0) , Zero(0) , One(0) , Two(0) , Three(0) , Four(0) , Five(0) , no_arguments() , echo(false) , stack_size(256) , stack_type(0) { } StackerCompiler::~StackerCompiler() { // delete TheModule; << don't do this! // TheModule is passed to caller of the compile() method .. its their // problem. Likewise for the other allocated objects (which become part // of TheModule. TheModule = 0; DefinitionType = 0; TheStack = 0; TheIndex = 0; } Module* StackerCompiler::compile( const std::string& filename, bool should_echo, unsigned optLevel, size_t the_stack_size ) { // TODO: Provide a global lock to protect the singled-threaded compiler // and its global variables. Should be in guard object on the stack so // that its destructor causes lock to be released (multiple exits from // this function). // Assign parameters CurFilename = filename; echo = should_echo; stack_size = the_stack_size; /// Default the file to read FILE *F = stdin; /// if (filename != "-") { F = fopen(filename.c_str(), "r"); if (F == 0) { ParseError Err; Err.setError(filename, "Could not open file '" + filename + "'"); throw Err; } } try { // Create the module we'll return TheModule = new Module( CurFilename ); // Tell the module about our runtime library TheModule->addLibrary("stkr_runtime"); // Create a type to represent the stack. This is the same as the LLVM // Assembly type [ 256 x long ] stack_type = ArrayType::get( Type::LongTy, stack_size ); // Create a global variable for the stack. Note the use of appending // linkage linkage so that multiple modules will make the stack larger. // Also note that the last argument causes the global to be inserted // automatically into the module. TheStack = new GlobalVariable( /*type=*/ stack_type, /*isConstant=*/ false, /*Linkage=*/ GlobalValue::LinkOnceLinkage, /*initializer=*/ Constant::getNullValue(stack_type), /*name=*/ "_stack_", /*parent=*/ TheModule ); // Create a global variable for indexing into the stack. Note the use // of LinkOnce linkage. Only one copy of _index_ will be retained // after linking TheIndex = new GlobalVariable( /*type=*/Type::LongTy, /*isConstant=*/false, /*Linkage=*/GlobalValue::LinkOnceLinkage, /*initializer=*/ Constant::getNullValue(Type::LongTy), /*name=*/"_index_", /*parent=*/TheModule ); // Create a function prototype for definitions. No parameters, no // result. This is used below any time a function is created. std::vector params; // No parameters DefinitionType = FunctionType::get( Type::VoidTy, params, false ); // Create a function for printf(3) params.push_back( PointerType::get( Type::SByteTy ) ); FunctionType* printf_type = FunctionType::get( Type::IntTy, params, true ); ThePrintf = new Function( printf_type, GlobalValue::ExternalLinkage, "printf", TheModule); // Create a function for scanf(3) TheScanf = new Function( printf_type, GlobalValue::ExternalLinkage, "scanf", TheModule); // Create a function for exit(3) params.clear(); params.push_back( Type::IntTy ); FunctionType* exit_type = FunctionType::get( Type::VoidTy, params, false ); TheExit = new Function( exit_type, GlobalValue::ExternalLinkage, "exit", TheModule); Constant* str_format = ConstantArray::get("%s"); StrFormat = new GlobalVariable( /*type=*/ArrayType::get( Type::SByteTy, 3 ), /*isConstant=*/true, /*Linkage=*/GlobalValue::LinkOnceLinkage, /*initializer=*/str_format, /*name=*/"_str_format_", /*parent=*/TheModule ); Constant* in_str_format = ConstantArray::get(" %as"); InStrFormat = new GlobalVariable( /*type=*/ArrayType::get( Type::SByteTy, 5 ), /*isConstant=*/true, /*Linkage=*/GlobalValue::LinkOnceLinkage, /*initializer=*/in_str_format, /*name=*/"_in_str_format_", /*parent=*/TheModule ); Constant* num_format = ConstantArray::get("%d"); NumFormat = new GlobalVariable( /*type=*/ArrayType::get( Type::SByteTy, 3 ), /*isConstant=*/true, /*Linkage=*/GlobalValue::LinkOnceLinkage, /*initializer=*/num_format, /*name=*/"_num_format_", /*parent=*/TheModule ); Constant* in_num_format = ConstantArray::get(" %d"); InNumFormat = new GlobalVariable( /*type=*/ArrayType::get( Type::SByteTy, 4 ), /*isConstant=*/true, /*Linkage=*/GlobalValue::LinkOnceLinkage, /*initializer=*/in_num_format, /*name=*/"_in_num_format_", /*parent=*/TheModule ); Constant* chr_format = ConstantArray::get("%c"); ChrFormat = new GlobalVariable( /*type=*/ArrayType::get( Type::SByteTy, 3 ), /*isConstant=*/true, /*Linkage=*/GlobalValue::LinkOnceLinkage, /*initializer=*/chr_format, /*name=*/"_chr_format_", /*parent=*/TheModule ); Constant* in_chr_format = ConstantArray::get(" %c"); InChrFormat = new GlobalVariable( /*type=*/ArrayType::get( Type::SByteTy, 4 ), /*isConstant=*/true, /*Linkage=*/GlobalValue::LinkOnceLinkage, /*initializer=*/in_chr_format, /*name=*/"_in_chr_format_", /*parent=*/TheModule ); // Get some constants so we aren't always creating them Zero = ConstantInt::get( Type::LongTy, 0 ); One = ConstantInt::get( Type::LongTy, 1 ); Two = ConstantInt::get( Type::LongTy, 2 ); Three = ConstantInt::get( Type::LongTy, 3 ); Four = ConstantInt::get( Type::LongTy, 4 ); Five = ConstantInt::get( Type::LongTy, 5 ); // Reset the current line number Stackerlineno = 1; // Reset the parser's input to F Stackerin = F; // Set the input file. // Let the parse know about this instance TheInstance = this; // Parse the file. The parser (see StackParser.y) will call back to // the StackerCompiler via the "handle*" methods Stackerparse(); // Avoid potential illegal use (TheInstance might be on the stack) TheInstance = 0; // Set up a pass manager PassManager Passes; // Add in the passes we want to execute Passes.add(new TargetData(TheModule)); // Verify we start with valid Passes.add(createVerifierPass()); if (optLevel > 0) { if (optLevel > 1) { // Clean up disgusting code Passes.add(createCFGSimplificationPass()); // Remove unused globals Passes.add(createGlobalDCEPass()); // IP Constant Propagation Passes.add(createIPConstantPropagationPass()); // Clean up after IPCP Passes.add(createInstructionCombiningPass()); // Clean up after IPCP Passes.add(createCFGSimplificationPass()); // Inline small definitions (functions) Passes.add(createFunctionInliningPass()); // Simplify cfg by copying code Passes.add(createTailDuplicationPass()); if (optLevel > 2) { // Merge & remove BBs Passes.add(createCFGSimplificationPass()); // Compile silly sequences Passes.add(createInstructionCombiningPass()); // Reassociate expressions Passes.add(createReassociatePass()); // Combine silly seq's Passes.add(createInstructionCombiningPass()); // Eliminate tail calls Passes.add(createTailCallEliminationPass()); // Merge & remove BBs Passes.add(createCFGSimplificationPass()); // Hoist loop invariants Passes.add(createLICMPass()); // Clean up after the unroller Passes.add(createInstructionCombiningPass()); // Canonicalize indvars Passes.add(createIndVarSimplifyPass()); // Unroll small loops Passes.add(createLoopUnrollPass()); // Clean up after the unroller Passes.add(createInstructionCombiningPass()); // GVN for load instructions Passes.add(createLoadValueNumberingPass()); // Remove common subexprs Passes.add(createGCSEPass()); // Constant prop with SCCP Passes.add(createSCCPPass()); } if (optLevel > 3) { // Run instcombine again after redundancy elimination Passes.add(createInstructionCombiningPass()); // Delete dead stores Passes.add(createDeadStoreEliminationPass()); // SSA based 'Aggressive DCE' Passes.add(createAggressiveDCEPass()); // Merge & remove BBs Passes.add(createCFGSimplificationPass()); // Merge dup global constants Passes.add(createConstantMergePass()); } } // Merge & remove BBs Passes.add(createCFGSimplificationPass()); // Memory To Register Passes.add(createPromoteMemoryToRegisterPass()); // Compile silly sequences Passes.add(createInstructionCombiningPass()); // Make sure everything is still good. Passes.add(createVerifierPass()); } // Run our queue of passes all at once now, efficiently. Passes.run(*TheModule); } catch (...) { if (F != stdin) fclose(F); // Make sure to close file descriptor throw; // if an exception is thrown } // Close the file if (F != stdin) fclose(F); // Return the compiled module to the caller return TheModule; } //===----------------------------------------------------------------------===// // Internal Functions, used by handleXXX below. // These represent the basic stack operations. //===----------------------------------------------------------------------===// Instruction* StackerCompiler::incr_stack_index( BasicBlock* bb, Value* ival = 0 ) { // Load the value from the TheIndex LoadInst* loadop = new LoadInst( TheIndex ); bb->getInstList().push_back( loadop ); // Increment the loaded index value if ( ival == 0 ) ival = One; CastInst* caster = CastInst::createInferredCast( ival, Type::LongTy ); bb->getInstList().push_back( caster ); BinaryOperator* addop = BinaryOperator::create( Instruction::Add, loadop, caster); bb->getInstList().push_back( addop ); // Store the incremented value StoreInst* storeop = new StoreInst( addop, TheIndex ); bb->getInstList().push_back( storeop ); return storeop; } Instruction* StackerCompiler::decr_stack_index( BasicBlock* bb, Value* ival = 0 ) { // Load the value from the TheIndex LoadInst* loadop = new LoadInst( TheIndex ); bb->getInstList().push_back( loadop ); // Decrement the loaded index value if ( ival == 0 ) ival = One; CastInst* caster = CastInst::createInferredCast( ival, Type::LongTy ); bb->getInstList().push_back( caster ); BinaryOperator* subop = BinaryOperator::create( Instruction::Sub, loadop, caster); bb->getInstList().push_back( subop ); // Store the incremented value StoreInst* storeop = new StoreInst( subop, TheIndex ); bb->getInstList().push_back( storeop ); return storeop; } Instruction* StackerCompiler::get_stack_pointer( BasicBlock* bb, Value* index = 0 ) { // Load the value of the Stack Index LoadInst* loadop = new LoadInst( TheIndex ); bb->getInstList().push_back( loadop ); // Index into the stack to get its address. NOTE the use of two // elements in this vector. The first de-references the pointer that // "TheStack" represents. The second indexes into the pointed to array. // Think of the first index as getting the address of the 0th element // of the array. std::vector indexVec; indexVec.push_back( Zero ); if ( index == 0 ) { indexVec.push_back(loadop); } else { CastInst* caster = CastInst::createInferredCast( index, Type::LongTy ); bb->getInstList().push_back( caster ); BinaryOperator* subop = BinaryOperator::create( Instruction::Sub, loadop, caster ); bb->getInstList().push_back( subop ); indexVec.push_back(subop); } // Get the address of the indexed stack element GetElementPtrInst* gep = new GetElementPtrInst( TheStack, indexVec ); bb->getInstList().push_back( gep ); // Put GEP in Block return gep; } Instruction* StackerCompiler::push_value( BasicBlock* bb, Value* val ) { // Get location of incr_stack_index(bb); // Get the stack pointer GetElementPtrInst* gep = cast( get_stack_pointer( bb ) ); // Cast the value to a long .. hopefully it works CastInst* cast_inst = CastInst::createInferredCast( val, Type::LongTy ); bb->getInstList().push_back( cast_inst ); // Store the value StoreInst* storeop = new StoreInst( cast_inst, gep ); bb->getInstList().push_back( storeop ); return storeop; } Instruction* StackerCompiler::push_integer(BasicBlock* bb, int64_t value ) { // Just push a constant integer value return push_value( bb, ConstantInt::get( Type::LongTy, value ) ); } Instruction* StackerCompiler::pop_integer( BasicBlock*bb ) { // Get the stack pointer GetElementPtrInst* gep = cast( get_stack_pointer( bb )); // Load the value LoadInst* load_inst = new LoadInst( gep ); bb->getInstList().push_back( load_inst ); // Decrement the stack index decr_stack_index( bb ); // Return the value return load_inst; } Instruction* StackerCompiler::push_string( BasicBlock* bb, const char* value ) { // Get length of the string size_t len = strlen( value ); // Create a type for the string constant. Length is +1 for // the terminating 0. ArrayType* char_array = ArrayType::get( Type::SByteTy, len + 1 ); // Create an initializer for the value Constant* initVal = ConstantArray::get( value ); // Create an internal linkage global variable to hold the constant. GlobalVariable* strconst = new GlobalVariable( char_array, /*isConstant=*/true, GlobalValue::InternalLinkage, /*initializer=*/initVal, "", TheModule ); // Push the casted value return push_value( bb, strconst ); } Instruction* StackerCompiler::pop_string( BasicBlock* bb ) { // Get location of stack pointer GetElementPtrInst* gep = cast( get_stack_pointer( bb )); // Load the value from the stack LoadInst* loader = new LoadInst( gep ); bb->getInstList().push_back( loader ); // Cast the integer to a sbyte* CastInst* caster = CastInst::createInferredCast( loader, PointerType::get(Type::SByteTy) ); bb->getInstList().push_back( caster ); // Decrement stack index decr_stack_index( bb ); // Return the value return caster; } Instruction* StackerCompiler::replace_top( BasicBlock* bb, Value* new_top, Value* index = 0 ) { // Get the stack pointer GetElementPtrInst* gep = cast( get_stack_pointer( bb, index )); // Store the value there StoreInst* store_inst = new StoreInst( new_top, gep ); bb->getInstList().push_back( store_inst ); // Return the value return store_inst; } Instruction* StackerCompiler::stack_top( BasicBlock* bb, Value* index = 0 ) { // Get the stack pointer GetElementPtrInst* gep = cast( get_stack_pointer( bb, index )); // Load the value LoadInst* load_inst = new LoadInst( gep ); bb->getInstList().push_back( load_inst ); // Return the value return load_inst; } Instruction* StackerCompiler::stack_top_string( BasicBlock* bb, Value* index = 0 ) { // Get location of stack pointer GetElementPtrInst* gep = cast( get_stack_pointer( bb, index )); // Load the value from the stack LoadInst* loader = new LoadInst( gep ); bb->getInstList().push_back( loader ); // Cast the integer to a sbyte* CastInst* caster = CastInst::createInferredCast( loader, PointerType::get(Type::SByteTy) ); bb->getInstList().push_back( caster ); // Return the value return caster; } static void add_block( Function*f, BasicBlock* bb ) { if ( ! f->empty() && f->back().getTerminator() == 0 ) { BranchInst* branch = new BranchInst(bb); f->back().getInstList().push_back( branch ); } f->getBasicBlockList().push_back( bb ); } //===----------------------------------------------------------------------===// // handleXXX - Handle semantics of parser productions //===----------------------------------------------------------------------===// Module* StackerCompiler::handle_module_start( ) { // Return the newly created module return TheModule; } Module* StackerCompiler::handle_module_end( Module* mod ) { // Return the module. return mod; } Module* StackerCompiler::handle_definition_list_start() { return TheModule; } Module* StackerCompiler::handle_definition_list_end( Module* mod, Function* definition ) { if ( ! definition->empty() ) { BasicBlock& last_block = definition->back(); if ( last_block.getTerminator() == 0 ) { last_block.getInstList().push_back( new ReturnInst() ); } } // Insert the definition into the module mod->getFunctionList().push_back( definition ); // Bump our (sample) statistic. ++NumDefinitions; return mod; } Function* StackerCompiler::handle_main_definition( Function* func ) { // Set the name of the function defined as the Stacker main // This will get called by the "main" that is defined in // the runtime library. func->setName( "_MAIN_"); // Turn "_stack_" into an initialized variable since this is the main // module. This causes it to not be "external" but defined in this module. TheStack->setInitializer( Constant::getNullValue(stack_type) ); TheStack->setLinkage( GlobalValue::LinkOnceLinkage ); // Turn "_index_" into an intialized variable for the same reason. TheIndex->setInitializer( Constant::getNullValue(Type::LongTy) ); TheIndex->setLinkage( GlobalValue::LinkOnceLinkage ); return func; } Function* StackerCompiler::handle_forward( char * name ) { // Just create a placeholder function Function* the_function = new Function ( DefinitionType, GlobalValue::ExternalLinkage, name ); assert( the_function->isExternal() ); free( name ); return the_function; } Function* StackerCompiler::handle_definition( char * name, Function* f ) { // Look up the function name in the module to see if it was forward // declared. #if 0 Function* existing_function = TheModule->getNamedFunction( name ); // If the function already exists... if ( existing_function ) { // Just get rid of the placeholder existing_function->dropAllReferences(); delete existing_function; } #endif // Just set the name of the function now that we know what it is. f->setName( name ); free( name ); return f; } Function* StackerCompiler::handle_word_list_start() { TheFunction = new Function(DefinitionType, GlobalValue::ExternalLinkage); return TheFunction; } Function* StackerCompiler::handle_word_list_end( Function* f, BasicBlock* bb ) { add_block( f, bb ); return f; } BasicBlock* StackerCompiler::handle_if( char* ifTrue, char* ifFalse ) { // Create a basic block for the preamble BasicBlock* bb = new BasicBlock((echo?"if":"")); // Get the condition value LoadInst* cond = cast( pop_integer(bb) ); // Compare the condition against 0 SetCondInst* cond_inst = new SetCondInst( Instruction::SetNE, cond, ConstantInt::get( Type::LongTy, 0) ); bb->getInstList().push_back( cond_inst ); // Create an exit block BasicBlock* exit_bb = new BasicBlock((echo?"endif":"")); // Create the true_block BasicBlock* true_bb = new BasicBlock((echo?"then":"")); // Create the false_block BasicBlock* false_bb = 0; if ( ifFalse ) false_bb = new BasicBlock((echo?"else":"")); // Create a branch on the SetCond BranchInst* br_inst = new BranchInst( true_bb, ( ifFalse ? false_bb : exit_bb ), cond_inst ); bb->getInstList().push_back( br_inst ); // Fill the true block std::vector args; if ( Function* true_func = TheModule->getNamedFunction(ifTrue) ) { true_bb->getInstList().push_back( new CallInst( true_func, args ) ); true_bb->getInstList().push_back( new BranchInst( exit_bb ) ); } else { ThrowException(std::string("Function '") + ifTrue + "' must be declared first.'"); } free( ifTrue ); // Fill the false block if ( false_bb ) { if ( Function* false_func = TheModule->getNamedFunction(ifFalse) ) { false_bb->getInstList().push_back( new CallInst( false_func, args ) ); false_bb->getInstList().push_back( new BranchInst( exit_bb ) ); } else { ThrowException(std::string("Function '") + ifFalse + "' must be declared first.'"); } free( ifFalse ); } // Add the blocks to the function add_block( TheFunction, bb ); add_block( TheFunction, true_bb ); if ( false_bb ) add_block( TheFunction, false_bb ); return exit_bb; } BasicBlock* StackerCompiler::handle_while( char* todo ) { // Create a basic block for the loop test BasicBlock* test = new BasicBlock((echo?"while":"")); // Create an exit block BasicBlock* exit = new BasicBlock((echo?"end":"")); // Create a loop body block BasicBlock* body = new BasicBlock((echo?"do":"")); // Create a root node BasicBlock* bb = new BasicBlock((echo?"root":"")); BranchInst* root_br_inst = new BranchInst( test ); bb->getInstList().push_back( root_br_inst ); // Examine the condition value LoadInst* cond = cast( stack_top(test) ); // Compare the condition against 0 SetCondInst* cond_inst = new SetCondInst( Instruction::SetNE, cond, ConstantInt::get( Type::LongTy, 0)); test->getInstList().push_back( cond_inst ); // Add the branch instruction BranchInst* br_inst = new BranchInst( body, exit, cond_inst ); test->getInstList().push_back( br_inst ); // Fill in the body std::vector args; if ( Function* body_func = TheModule->getNamedFunction(todo) ) { body->getInstList().push_back( new CallInst( body_func, args ) ); body->getInstList().push_back( new BranchInst( test ) ); } else { ThrowException(std::string("Function '") + todo + "' must be declared first.'"); } free( todo ); // Add the blocks add_block( TheFunction, bb ); add_block( TheFunction, test ); add_block( TheFunction, body ); return exit; } BasicBlock* StackerCompiler::handle_identifier( char * name ) { Function* func = TheModule->getNamedFunction( name ); BasicBlock* bb = new BasicBlock((echo?"call":"")); if ( func ) { CallInst* call_def = new CallInst( func , no_arguments ); bb->getInstList().push_back( call_def ); } else { ThrowException(std::string("Definition '") + name + "' must be defined before it can be used."); } free( name ); return bb; } BasicBlock* StackerCompiler::handle_string( char * value ) { // Create a new basic block for the push operation BasicBlock* bb = new BasicBlock((echo?"string":"")); // Push the string onto the stack push_string(bb, value); // Free the strdup'd string free( value ); return bb; } BasicBlock* StackerCompiler::handle_integer( const int64_t value ) { // Create a new basic block for the push operation BasicBlock* bb = new BasicBlock((echo?"int":"")); // Push the integer onto the stack push_integer(bb, value ); return bb; } BasicBlock* StackerCompiler::handle_word( int tkn ) { // Create a new basic block to hold the instruction(s) BasicBlock* bb = new BasicBlock(); /* Fill the basic block with the appropriate instructions */ switch ( tkn ) { case DUMP : // Dump the stack (debugging aid) { if (echo) bb->setName("DUMP"); Function* f = TheModule->getOrInsertFunction( "_stacker_dump_stack_", DefinitionType); std::vector args; bb->getInstList().push_back( new CallInst( f, args ) ); break; } // Logical Operations case TRUETOK : // -- -1 { if (echo) bb->setName("TRUE"); push_integer(bb,-1); break; } case FALSETOK : // -- 0 { if (echo) bb->setName("FALSE"); push_integer(bb,0); break; } case LESS : // w1 w2 -- w2setName("LESS"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); SetCondInst* cond_inst = new SetCondInst( Instruction::SetLT, op1, op2 ); bb->getInstList().push_back( cond_inst ); push_value( bb, cond_inst ); break; } case MORE : // w1 w2 -- w2>w1 { if (echo) bb->setName("MORE"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); SetCondInst* cond_inst = new SetCondInst( Instruction::SetGT, op1, op2 ); bb->getInstList().push_back( cond_inst ); push_value( bb, cond_inst ); break; } case LESS_EQUAL : // w1 w2 -- w2<=w1 { if (echo) bb->setName("LE"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); SetCondInst* cond_inst = new SetCondInst( Instruction::SetLE, op1, op2 ); bb->getInstList().push_back( cond_inst ); push_value( bb, cond_inst ); break; } case MORE_EQUAL : // w1 w2 -- w2>=w1 { if (echo) bb->setName("GE"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); SetCondInst* cond_inst = new SetCondInst( Instruction::SetGE, op1, op2 ); bb->getInstList().push_back( cond_inst ); push_value( bb, cond_inst ); break; } case NOT_EQUAL : // w1 w2 -- w2!=w1 { if (echo) bb->setName("NE"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); SetCondInst* cond_inst = new SetCondInst( Instruction::SetNE, op1, op2 ); bb->getInstList().push_back( cond_inst ); push_value( bb, cond_inst ); break; } case EQUAL : // w1 w2 -- w1==w2 { if (echo) bb->setName("EQ"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); SetCondInst* cond_inst = new SetCondInst( Instruction::SetEQ, op1, op2 ); bb->getInstList().push_back( cond_inst ); push_value( bb, cond_inst ); break; } // Arithmetic Operations case PLUS : // w1 w2 -- w2+w1 { if (echo) bb->setName("ADD"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* addop = BinaryOperator::create( Instruction::Add, op1, op2); bb->getInstList().push_back( addop ); push_value( bb, addop ); break; } case MINUS : // w1 w2 -- w2-w1 { if (echo) bb->setName("SUB"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* subop = BinaryOperator::create( Instruction::Sub, op1, op2); bb->getInstList().push_back( subop ); push_value( bb, subop ); break; } case INCR : // w1 -- w1+1 { if (echo) bb->setName("INCR"); LoadInst* op1 = cast(pop_integer(bb)); BinaryOperator* addop = BinaryOperator::create( Instruction::Add, op1, One ); bb->getInstList().push_back( addop ); push_value( bb, addop ); break; } case DECR : // w1 -- w1-1 { if (echo) bb->setName("DECR"); LoadInst* op1 = cast(pop_integer(bb)); BinaryOperator* subop = BinaryOperator::create( Instruction::Sub, op1, ConstantInt::get( Type::LongTy, 1 ) ); bb->getInstList().push_back( subop ); push_value( bb, subop ); break; } case MULT : // w1 w2 -- w2*w1 { if (echo) bb->setName("MUL"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* multop = BinaryOperator::create( Instruction::Mul, op1, op2); bb->getInstList().push_back( multop ); push_value( bb, multop ); break; } case DIV :// w1 w2 -- w2/w1 { if (echo) bb->setName("DIV"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* divop = BinaryOperator::create( Instruction::SDiv, op1, op2); bb->getInstList().push_back( divop ); push_value( bb, divop ); break; } case MODULUS : // w1 w2 -- w2%w1 { if (echo) bb->setName("MOD"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* divop = BinaryOperator::create( Instruction::SRem, op1, op2); bb->getInstList().push_back( divop ); push_value( bb, divop ); break; } case STAR_SLASH : // w1 w2 w3 -- (w3*w2)/w1 { if (echo) bb->setName("STAR_SLASH"); // Get the operands LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); LoadInst* op3 = cast(pop_integer(bb)); // Multiply the first two BinaryOperator* multop = BinaryOperator::create( Instruction::Mul, op1, op2); bb->getInstList().push_back( multop ); // Divide by the third operand BinaryOperator* divop = BinaryOperator::create( Instruction::SDiv, multop, op3); bb->getInstList().push_back( divop ); // Push the result push_value( bb, divop ); break; } case NEGATE : // w1 -- -w1 { if (echo) bb->setName("NEG"); LoadInst* op1 = cast(pop_integer(bb)); // APPARENTLY, the following doesn't work: // BinaryOperator* negop = BinaryOperator::createNeg( op1 ); // bb->getInstList().push_back( negop ); // So we'll multiply by -1 (ugh) BinaryOperator* multop = BinaryOperator::create( Instruction::Mul, op1, ConstantInt::get( Type::LongTy, -1 ) ); bb->getInstList().push_back( multop ); push_value( bb, multop ); break; } case ABS : // w1 -- |w1| { if (echo) bb->setName("ABS"); // Get the top of stack value LoadInst* op1 = cast(stack_top(bb)); // Determine if its negative SetCondInst* cond_inst = new SetCondInst( Instruction::SetLT, op1, Zero ); bb->getInstList().push_back( cond_inst ); // Create a block for storing the result BasicBlock* exit_bb = new BasicBlock((echo?"exit":"")); // Create a block for making it a positive value BasicBlock* pos_bb = new BasicBlock((echo?"neg":"")); // Create the branch on the SetCond BranchInst* br_inst = new BranchInst( pos_bb, exit_bb, cond_inst ); bb->getInstList().push_back( br_inst ); // Fill out the negation block LoadInst* pop_op = cast( pop_integer(pos_bb) ); BinaryOperator* neg_op = BinaryOperator::createNeg( pop_op ); pos_bb->getInstList().push_back( neg_op ); push_value( pos_bb, neg_op ); pos_bb->getInstList().push_back( new BranchInst( exit_bb ) ); // Add the new blocks in the correct order add_block( TheFunction, bb ); add_block( TheFunction, pos_bb ); bb = exit_bb; break; } case MIN : // w1 w2 -- (w2setName("MIN"); // Create the three blocks BasicBlock* exit_bb = new BasicBlock((echo?"exit":"")); BasicBlock* op1_block = new BasicBlock((echo?"less":"")); BasicBlock* op2_block = new BasicBlock((echo?"more":"")); // Get the two operands LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); // Compare them SetCondInst* cond_inst = new SetCondInst( Instruction::SetLT, op1, op2); bb->getInstList().push_back( cond_inst ); // Create a branch on the SetCond BranchInst* br_inst = new BranchInst( op1_block, op2_block, cond_inst ); bb->getInstList().push_back( br_inst ); // Create a block for pushing the first one push_value(op1_block, op1); op1_block->getInstList().push_back( new BranchInst( exit_bb ) ); // Create a block for pushing the second one push_value(op2_block, op2); op2_block->getInstList().push_back( new BranchInst( exit_bb ) ); // Add the blocks add_block( TheFunction, bb ); add_block( TheFunction, op1_block ); add_block( TheFunction, op2_block ); bb = exit_bb; break; } case MAX : // w1 w2 -- (w2>w1?w2:w1) { if (echo) bb->setName("MAX"); // Get the two operands LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); // Compare them SetCondInst* cond_inst = new SetCondInst( Instruction::SetGT, op1, op2); bb->getInstList().push_back( cond_inst ); // Create an exit block BasicBlock* exit_bb = new BasicBlock((echo?"exit":"")); // Create a block for pushing the larger one BasicBlock* op1_block = new BasicBlock((echo?"more":"")); push_value(op1_block, op1); op1_block->getInstList().push_back( new BranchInst( exit_bb ) ); // Create a block for pushing the smaller or equal one BasicBlock* op2_block = new BasicBlock((echo?"less":"")); push_value(op2_block, op2); op2_block->getInstList().push_back( new BranchInst( exit_bb ) ); // Create a banch on the SetCond BranchInst* br_inst = new BranchInst( op1_block, op2_block, cond_inst ); bb->getInstList().push_back( br_inst ); // Add the blocks add_block( TheFunction, bb ); add_block( TheFunction, op1_block ); add_block( TheFunction, op2_block ); bb = exit_bb; break; } // Bitwise Operators case AND : // w1 w2 -- w2&w1 { if (echo) bb->setName("AND"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* andop = BinaryOperator::create( Instruction::And, op1, op2); bb->getInstList().push_back( andop ); push_value( bb, andop ); break; } case OR : // w1 w2 -- w2|w1 { if (echo) bb->setName("OR"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* orop = BinaryOperator::create( Instruction::Or, op1, op2); bb->getInstList().push_back( orop ); push_value( bb, orop ); break; } case XOR : // w1 w2 -- w2^w1 { if (echo) bb->setName("XOR"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); BinaryOperator* xorop = BinaryOperator::create( Instruction::Xor, op1, op2); bb->getInstList().push_back( xorop ); push_value( bb, xorop ); break; } case LSHIFT : // w1 w2 -- w1<setName("SHL"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); CastInst* castop = CastInst::createInferredCast( op1, Type::UByteTy ); bb->getInstList().push_back( castop ); ShiftInst* shlop = new ShiftInst( Instruction::Shl, op2, castop ); bb->getInstList().push_back( shlop ); push_value( bb, shlop ); break; } case RSHIFT : // w1 w2 -- w1>>w2 { if (echo) bb->setName("SHR"); LoadInst* op1 = cast(pop_integer(bb)); LoadInst* op2 = cast(pop_integer(bb)); CastInst* castop = CastInst::createInferredCast( op1, Type::UByteTy ); bb->getInstList().push_back( castop ); ShiftInst* shrop = new ShiftInst( Instruction::AShr, op2, castop ); bb->getInstList().push_back( shrop ); push_value( bb, shrop ); break; } // Stack Manipulation Operations case DROP: // w -- { if (echo) bb->setName("DROP"); decr_stack_index(bb, One); break; } case DROP2: // w1 w2 -- { if (echo) bb->setName("DROP2"); decr_stack_index( bb, Two ); break; } case NIP: // w1 w2 -- w2 { if (echo) bb->setName("NIP"); LoadInst* w2 = cast( stack_top( bb ) ); decr_stack_index( bb ); replace_top( bb, w2 ); break; } case NIP2: // w1 w2 w3 w4 -- w3 w4 { if (echo) bb->setName("NIP2"); LoadInst* w4 = cast( stack_top( bb ) ); LoadInst* w3 = cast( stack_top( bb, One ) ); decr_stack_index( bb, Two ); replace_top( bb, w4 ); replace_top( bb, w3, One ); break; } case DUP: // w -- w w { if (echo) bb->setName("DUP"); LoadInst* w = cast( stack_top( bb ) ); push_value( bb, w ); break; } case DUP2: // w1 w2 -- w1 w2 w1 w2 { if (echo) bb->setName("DUP2"); LoadInst* w2 = cast( stack_top(bb) ); LoadInst* w1 = cast( stack_top(bb, One ) ); incr_stack_index( bb, Two ); replace_top( bb, w1, One ); replace_top( bb, w2 ); break; } case SWAP: // w1 w2 -- w2 w1 { if (echo) bb->setName("SWAP"); LoadInst* w2 = cast( stack_top( bb ) ); LoadInst* w1 = cast( stack_top( bb, One ) ); replace_top( bb, w1 ); replace_top( bb, w2, One ); break; } case SWAP2: // w1 w2 w3 w4 -- w3 w4 w1 w2 { if (echo) bb->setName("SWAP2"); LoadInst* w4 = cast( stack_top( bb ) ); LoadInst* w3 = cast( stack_top( bb, One ) ); LoadInst* w2 = cast( stack_top( bb, Two ) ); LoadInst* w1 = cast( stack_top( bb, Three ) ); replace_top( bb, w2 ); replace_top( bb, w1, One ); replace_top( bb, w4, Two ); replace_top( bb, w3, Three ); break; } case OVER: // w1 w2 -- w1 w2 w1 { if (echo) bb->setName("OVER"); LoadInst* w1 = cast( stack_top( bb, One ) ); push_value( bb, w1 ); break; } case OVER2: // w1 w2 w3 w4 -- w1 w2 w3 w4 w1 w2 { if (echo) bb->setName("OVER2"); LoadInst* w2 = cast( stack_top( bb, Two ) ); LoadInst* w1 = cast( stack_top( bb, Three ) ); incr_stack_index( bb, Two ); replace_top( bb, w2 ); replace_top( bb, w1, One ); break; } case ROT: // w1 w2 w3 -- w2 w3 w1 { if (echo) bb->setName("ROT"); LoadInst* w3 = cast( stack_top( bb ) ); LoadInst* w2 = cast( stack_top( bb, One ) ); LoadInst* w1 = cast( stack_top( bb, Two ) ); replace_top( bb, w1 ); replace_top( bb, w3, One ); replace_top( bb, w2, Two ); break; } case ROT2: // w1 w2 w3 w4 w5 w6 -- w3 w4 w5 w6 w1 w2 { if (echo) bb->setName("ROT2"); LoadInst* w6 = cast( stack_top( bb ) ); LoadInst* w5 = cast( stack_top( bb, One ) ); LoadInst* w4 = cast( stack_top( bb, Two ) ); LoadInst* w3 = cast( stack_top( bb, Three) ); LoadInst* w2 = cast( stack_top( bb, Four ) ); LoadInst* w1 = cast( stack_top( bb, Five ) ); replace_top( bb, w2 ); replace_top( bb, w1, One ); replace_top( bb, w6, Two ); replace_top( bb, w5, Three ); replace_top( bb, w4, Four ); replace_top( bb, w3, Five ); break; } case RROT: // w1 w2 w3 -- w3 w1 w2 { if (echo) bb->setName("RROT2"); LoadInst* w3 = cast( stack_top( bb ) ); LoadInst* w2 = cast( stack_top( bb, One ) ); LoadInst* w1 = cast( stack_top( bb, Two ) ); replace_top( bb, w2 ); replace_top( bb, w1, One ); replace_top( bb, w3, Two ); break; } case RROT2: // w1 w2 w3 w4 w5 w6 -- w5 w6 w1 w2 w3 w4 { if (echo) bb->setName("RROT2"); LoadInst* w6 = cast( stack_top( bb ) ); LoadInst* w5 = cast( stack_top( bb, One ) ); LoadInst* w4 = cast( stack_top( bb, Two ) ); LoadInst* w3 = cast( stack_top( bb, Three) ); LoadInst* w2 = cast( stack_top( bb, Four ) ); LoadInst* w1 = cast( stack_top( bb, Five ) ); replace_top( bb, w4 ); replace_top( bb, w3, One ); replace_top( bb, w2, Two ); replace_top( bb, w1, Three ); replace_top( bb, w6, Four ); replace_top( bb, w5, Five ); break; } case TUCK: // w1 w2 -- w2 w1 w2 { if (echo) bb->setName("TUCK"); LoadInst* w2 = cast( stack_top( bb ) ); LoadInst* w1 = cast( stack_top( bb, One ) ); incr_stack_index( bb ); replace_top( bb, w2 ); replace_top( bb, w1, One ); replace_top( bb, w2, Two ); break; } case TUCK2: // w1 w2 w3 w4 -- w3 w4 w1 w2 w3 w4 { if (echo) bb->setName("TUCK2"); LoadInst* w4 = cast( stack_top( bb ) ); LoadInst* w3 = cast( stack_top( bb, One ) ); LoadInst* w2 = cast( stack_top( bb, Two ) ); LoadInst* w1 = cast( stack_top( bb, Three) ); incr_stack_index( bb, Two ); replace_top( bb, w4 ); replace_top( bb, w3, One ); replace_top( bb, w2, Two ); replace_top( bb, w1, Three ); replace_top( bb, w4, Four ); replace_top( bb, w3, Five ); break; } case ROLL: // x0 x1 .. xn n -- x1 .. xn x0 { /// THIS OEPRATOR IS OMITTED PURPOSEFULLY AND IS LEFT TO THE /// READER AS AN EXERCISE. THIS IS ONE OF THE MORE COMPLICATED /// OPERATORS. IF YOU CAN GET THIS ONE RIGHT, YOU COMPLETELY /// UNDERSTAND HOW BOTH LLVM AND STACKER WOR. /// HINT: LOOK AT PICK AND SELECT. ROLL IS SIMILAR. if (echo) bb->setName("ROLL"); break; } case PICK: // x0 ... Xn n -- x0 ... Xn x0 { if (echo) bb->setName("PICK"); LoadInst* n = cast( stack_top( bb ) ); BinaryOperator* addop = BinaryOperator::create( Instruction::Add, n, One ); bb->getInstList().push_back( addop ); LoadInst* x0 = cast( stack_top( bb, addop ) ); replace_top( bb, x0 ); break; } case SELECT: // m n X0..Xm Xm+1 .. Xn -- Xm { if (echo) bb->setName("SELECT"); LoadInst* m = cast( stack_top(bb) ); LoadInst* n = cast( stack_top(bb, One) ); BinaryOperator* index = BinaryOperator::create( Instruction::Add, m, One ); bb->getInstList().push_back( index ); LoadInst* Xm = cast( stack_top(bb, index ) ); BinaryOperator* n_plus_1 = BinaryOperator::create( Instruction::Add, n, One ); bb->getInstList().push_back( n_plus_1 ); decr_stack_index( bb, n_plus_1 ); replace_top( bb, Xm ); break; } case MALLOC : // n -- p { if (echo) bb->setName("MALLOC"); // Get the number of bytes to mallocate LoadInst* op1 = cast( pop_integer(bb) ); // Make sure its a UIntTy CastInst* caster = CastInst::createInferredCast( op1, Type::UIntTy ); bb->getInstList().push_back( caster ); // Allocate the bytes MallocInst* mi = new MallocInst( Type::SByteTy, caster ); bb->getInstList().push_back( mi ); // Push the pointer push_value( bb, mi ); break; } case FREE : // p -- { if (echo) bb->setName("FREE"); // Pop the value off the stack CastInst* ptr = cast( pop_string(bb) ); // Free the memory FreeInst* fi = new FreeInst( ptr ); bb->getInstList().push_back( fi ); break; } case GET : // p w1 -- p w2 { if (echo) bb->setName("GET"); // Get the character index LoadInst* op1 = cast( stack_top(bb) ); CastInst* chr_idx = CastInst::createInferredCast( op1, Type::LongTy ); bb->getInstList().push_back( chr_idx ); // Get the String pointer CastInst* ptr = cast( stack_top_string(bb,One) ); // Get address of op1'th element of the string std::vector indexVec; indexVec.push_back( chr_idx ); GetElementPtrInst* gep = new GetElementPtrInst( ptr, indexVec ); bb->getInstList().push_back( gep ); // Get the value and push it LoadInst* loader = new LoadInst( gep ); bb->getInstList().push_back( loader ); CastInst* caster = CastInst::createInferredCast( loader, Type::IntTy ); bb->getInstList().push_back( caster ); // Push the result back on stack replace_top( bb, caster ); break; } case PUT : // p w2 w1 -- p { if (echo) bb->setName("PUT"); // Get the value to put LoadInst* w1 = cast( pop_integer(bb) ); // Get the character index LoadInst* w2 = cast( pop_integer(bb) ); CastInst* chr_idx = CastInst::createInferredCast( w2, Type::LongTy ); bb->getInstList().push_back( chr_idx ); // Get the String pointer CastInst* ptr = cast( stack_top_string(bb) ); // Get address of op2'th element of the string std::vector indexVec; indexVec.push_back( chr_idx ); GetElementPtrInst* gep = new GetElementPtrInst( ptr, indexVec ); bb->getInstList().push_back( gep ); // Cast the value and put it CastInst* caster = CastInst::createInferredCast( w1, Type::SByteTy ); bb->getInstList().push_back( caster ); StoreInst* storer = new StoreInst( caster, gep ); bb->getInstList().push_back( storer ); break; } case RECURSE : { if (echo) bb->setName("RECURSE"); std::vector params; CallInst* call_inst = new CallInst( TheFunction, params ); bb->getInstList().push_back( call_inst ); break; } case RETURN : { if (echo) bb->setName("RETURN"); bb->getInstList().push_back( new ReturnInst() ); break; } case EXIT : { if (echo) bb->setName("EXIT"); // Get the result value LoadInst* op1 = cast(pop_integer(bb)); // Cast down to an integer CastInst* caster = CastInst::createInferredCast( op1, Type::IntTy ); bb->getInstList().push_back( caster ); // Call exit(3) std::vector params; params.push_back(caster); CallInst* call_inst = new CallInst( TheExit, params ); bb->getInstList().push_back( call_inst ); break; } case TAB : { if (echo) bb->setName("TAB"); // Get the format string for a character std::vector indexVec; indexVec.push_back( Zero ); indexVec.push_back( Zero ); GetElementPtrInst* format_gep = new GetElementPtrInst( ChrFormat, indexVec ); bb->getInstList().push_back( format_gep ); // Get the character to print (a tab) ConstantInt* newline = ConstantInt::get(Type::IntTy, static_cast('\t')); // Call printf std::vector args; args.push_back( format_gep ); args.push_back( newline ); bb->getInstList().push_back( new CallInst( ThePrintf, args ) ); break; } case SPACE : { if (echo) bb->setName("SPACE"); // Get the format string for a character std::vector indexVec; indexVec.push_back( Zero ); indexVec.push_back( Zero ); GetElementPtrInst* format_gep = new GetElementPtrInst( ChrFormat, indexVec ); bb->getInstList().push_back( format_gep ); // Get the character to print (a space) ConstantInt* newline = ConstantInt::get(Type::IntTy, static_cast(' ')); // Call printf std::vector args; args.push_back( format_gep ); args.push_back( newline ); bb->getInstList().push_back( new CallInst( ThePrintf, args ) ); break; } case CR : { if (echo) bb->setName("CR"); // Get the format string for a character std::vector indexVec; indexVec.push_back( Zero ); indexVec.push_back( Zero ); GetElementPtrInst* format_gep = new GetElementPtrInst( ChrFormat, indexVec ); bb->getInstList().push_back( format_gep ); // Get the character to print (a newline) ConstantInt* newline = ConstantInt::get(Type::IntTy, static_cast('\n')); // Call printf std::vector args; args.push_back( format_gep ); args.push_back( newline ); bb->getInstList().push_back( new CallInst( ThePrintf, args ) ); break; } case IN_STR : { if (echo) bb->setName("IN_STR"); // Make room for the value result incr_stack_index(bb); GetElementPtrInst* gep_value = cast(get_stack_pointer(bb)); CastInst* caster = new BitCastInst(gep_value, PointerType::get(Type::SByteTy)); // Make room for the count result incr_stack_index(bb); GetElementPtrInst* gep_count = cast(get_stack_pointer(bb)); // Call scanf(3) std::vector args; args.push_back( InStrFormat ); args.push_back( caster ); CallInst* scanf = new CallInst( TheScanf, args ); bb->getInstList().push_back( scanf ); // Store the result bb->getInstList().push_back( new StoreInst( scanf, gep_count ) ); break; } case IN_NUM : { if (echo) bb->setName("IN_NUM"); // Make room for the value result incr_stack_index(bb); GetElementPtrInst* gep_value = cast(get_stack_pointer(bb)); // Make room for the count result incr_stack_index(bb); GetElementPtrInst* gep_count = cast(get_stack_pointer(bb)); // Call scanf(3) std::vector args; args.push_back( InStrFormat ); args.push_back( gep_value ); CallInst* scanf = new CallInst( TheScanf, args ); bb->getInstList().push_back( scanf ); // Store the result bb->getInstList().push_back( new StoreInst( scanf, gep_count ) ); break; } case IN_CHAR : { if (echo) bb->setName("IN_CHAR"); // Make room for the value result incr_stack_index(bb); GetElementPtrInst* gep_value = cast(get_stack_pointer(bb)); // Make room for the count result incr_stack_index(bb); GetElementPtrInst* gep_count = cast(get_stack_pointer(bb)); // Call scanf(3) std::vector args; args.push_back( InChrFormat ); args.push_back( gep_value ); CallInst* scanf = new CallInst( TheScanf, args ); bb->getInstList().push_back( scanf ); // Store the result bb->getInstList().push_back( new StoreInst( scanf, gep_count ) ); break; } case OUT_STR : { if (echo) bb->setName("OUT_STR"); LoadInst* op1 = cast(stack_top(bb)); // Get the address of the format string std::vector indexVec; indexVec.push_back( Zero ); indexVec.push_back( Zero ); GetElementPtrInst* format_gep = new GetElementPtrInst( StrFormat, indexVec ); bb->getInstList().push_back( format_gep ); // Build function call arguments std::vector args; args.push_back( format_gep ); args.push_back( op1 ); // Call printf bb->getInstList().push_back( new CallInst( ThePrintf, args ) ); break; } case OUT_NUM : { if (echo) bb->setName("OUT_NUM"); // Pop the numeric operand off the stack LoadInst* op1 = cast(stack_top(bb)); // Get the address of the format string std::vector indexVec; indexVec.push_back( Zero ); indexVec.push_back( Zero ); GetElementPtrInst* format_gep = new GetElementPtrInst( NumFormat, indexVec ); bb->getInstList().push_back( format_gep ); // Build function call arguments std::vector args; args.push_back( format_gep ); args.push_back( op1 ); // Call printf bb->getInstList().push_back( new CallInst( ThePrintf, args ) ); break; } case OUT_CHAR : { if (echo) bb->setName("OUT_CHAR"); // Pop the character operand off the stack LoadInst* op1 = cast(stack_top(bb)); // Get the address of the format string std::vector indexVec; indexVec.push_back( Zero ); indexVec.push_back( Zero ); GetElementPtrInst* format_gep = new GetElementPtrInst( ChrFormat, indexVec ); bb->getInstList().push_back( format_gep ); // Build function call arguments std::vector args; args.push_back( format_gep ); args.push_back( op1 ); // Call printf bb->getInstList().push_back( new CallInst( ThePrintf, args ) ); break; } default : { ThrowException(std::string("Compiler Error: Unhandled token #")); } } // Return the basic block return bb; }