static String handle_static_float_constant(CPrintStyleModule *state, const SuifObject *obj) { FloatConstant *expr = to<FloatConstant>(obj); return(expr->get_value().c_str()); }
/* Another helper function for print_var_def(). This function * expects that it will need to add a return before printing * anything, and it expects that you will add a return after * it is done. * It returns the number of bits of initialization data that it * generates. */ int PrinterX86::process_value_block(ValueBlock *vblk) { int bits_filled = 0; if (is_a<ExpressionValueBlock>(vblk)) { // An ExpressionValueBlock either holds a constant value or a // simple expression representing either an address relative to // a symbol or a pointer generated by conversion from an integer // constant (presumably zero). ExpressionValueBlock *evb = (ExpressionValueBlock*)vblk; Expression *exp = evb->get_expression(); if (is_a<IntConstant>(exp)) { IntConstant *ic = (IntConstant*)exp; bits_filled = print_size_directive(ic->get_result_type()); fprint(out, ic->get_value()); cur_opnd_cnt++; } else if (is_a<FloatConstant>(exp)) { FloatConstant *fc = (FloatConstant*)exp; bits_filled = print_size_directive(fc->get_result_type()); fputs(fc->get_value().c_str(), out); cur_opnd_cnt++; } else { // We use non-constant ExpressionValueBlocks to hold a symbolic // address, optionally with an offset, or a pointer initializer // consisting of a `convert' expression. // A SymbolAddressExpression represents a plain symbolic // address. // An address obtained by conversion from another type is a // unary expression with opcode "convert". // A symbol+delta is represented by an add whose first operand // is the load-address and whose second is an IntConstant // expression. // No other kind of "expression" is recognized. if (is_a<UnaryExpression>(exp)) { UnaryExpression *ux = (UnaryExpression*)exp; claim(ux->get_opcode() == k_convert, "unexpected unary expression in expression block"); DataType *tt = ux->get_result_type(); // target type claim(is_kind_of<PointerType>(tt), "unexpected target type when converting initializer"); exp = ux->get_source(); if (is_a<IntConstant>(exp)) { IntConstant *ic = (IntConstant*)exp; bits_filled = print_size_directive(tt); fprint(out, ic->get_value()); cur_opnd_cnt++; return bits_filled; } // Fall through to handle symbol-relative address, on the // assumption that the front end validated the conversion. } SymbolAddressExpression *sax; long delta; if (is_a<BinaryExpression>(exp)) { BinaryExpression *bx = (BinaryExpression*)exp; claim(bx->get_opcode() == k_add, "unexpected binary expression in expression block"); Expression *s1 = bx->get_source1(); Expression *s2 = bx->get_source2(); sax = to<SymbolAddressExpression>(s1); delta = to<IntConstant>(s2)->get_value().c_long(); } else if (is_a<SymbolAddressExpression>(exp)) { sax = (SymbolAddressExpression*)exp; delta = 0; } else { claim(false, "unexpected kind of expression block"); } Sym *sym = sax->get_addressed_symbol(); // symbol initialization bits_filled = print_size_directive(type_ptr); print_sym(sym); if (delta != 0) { fprintf(out, "%+ld", delta); } // always force the start of a new data directive cur_opcode = opcode_null; cur_opnd_cnt = 0; } } else if (is_a<MultiValueBlock>(vblk)) { MultiValueBlock *mvb = (MultiValueBlock*)vblk; for (int i = 0; i < mvb->get_sub_block_count(); i++ ) { int offset = mvb->get_sub_block(i).first.c_int(); claim(offset >= bits_filled); if (bits_filled < offset) // pad to offset bits_filled += print_bit_filler(offset - bits_filled); bits_filled += process_value_block(mvb->get_sub_block(i).second); } int all_bits = get_bit_size(mvb->get_type()); if (all_bits > bits_filled) bits_filled += print_bit_filler(all_bits - bits_filled); } else if (is_a<RepeatValueBlock>(vblk)) { // Simplifying assumption: We now expect the front-end // to remove initialization code of large arrays of zeros. RepeatValueBlock *rvb = (RepeatValueBlock*)vblk; int repeat_cnt = rvb->get_num_repetitions(); if (repeat_cnt > 1) { // insert .repeat pseudo-op fprintf(out, "\n\t%s\t%d", x86_opcode_names[REPEAT], repeat_cnt); cur_opcode = opcode_null; // force new data directive } // actual data directive bits_filled = repeat_cnt * process_value_block(rvb->get_sub_block()); if (repeat_cnt > 1) { // insert .endr pseudo-op fprintf(out, "\n\t%s", x86_opcode_names[ENDR]); cur_opcode = opcode_null; // force new data directive } } else if (is_a<UndefinedValueBlock>(vblk)) { bits_filled += print_bit_filler(get_bit_size(vblk->get_type())); } else { claim(false, "unexpected kind of ValueBlock"); } return bits_filled; }
Constant* MiniConstantPropagationPass::Merge(Constant* x, Constant* y, LString opcode) { assert(theEnv != NULL) ; if (x == NULL || y == NULL) { return NULL ; } IntConstant* xInt = dynamic_cast<IntConstant*>(x) ; IntConstant* yInt = dynamic_cast<IntConstant*>(y) ; FloatConstant* xFloat = dynamic_cast<FloatConstant*>(x) ; FloatConstant* yFloat = dynamic_cast<FloatConstant*>(y) ; // This mini propagation only cares for addition and subtraction. Other // propagations will be handled in a later pass. if (opcode == LString("add")) { if (xInt != NULL && yInt != NULL) { int mergedValue = xInt->get_value().c_int() + yInt->get_value().c_int() ; return create_int_constant(theEnv, xInt->get_result_type(), IInteger(mergedValue)) ; } if (xFloat != NULL && yFloat != NULL) { float mergedValue = StringToFloat(xFloat->get_value()) + StringToFloat(yFloat->get_value()) ; return create_float_constant(theEnv, xFloat->get_result_type(), FloatToString(mergedValue)) ; } if (xInt != NULL && yFloat != NULL) { float mergedValue = xInt->get_value().c_int() + StringToFloat(yFloat->get_value()) ; return create_float_constant(theEnv, yFloat->get_result_type(), FloatToString(mergedValue)) ; } if (xFloat != NULL && yInt != NULL) { float mergedValue = StringToFloat(xFloat->get_value()) + yInt->get_value().c_int() ; return create_float_constant(theEnv, xFloat->get_result_type(), FloatToString(mergedValue)) ; } } if (opcode == LString("subtract")) { if (xInt != NULL && yInt != NULL) { int mergedValue = xInt->get_value().c_int() - yInt->get_value().c_int() ; return create_int_constant(theEnv, xInt->get_result_type(), IInteger(mergedValue)) ; } if (xFloat != NULL && yFloat != NULL) { float mergedValue = StringToFloat(xFloat->get_value()) - StringToFloat(yFloat->get_value()) ; return create_float_constant(theEnv, xFloat->get_result_type(), FloatToString(mergedValue)) ; } if (xInt != NULL && yFloat != NULL) { float mergedValue = xInt->get_value().c_int() - StringToFloat(yFloat->get_value()) ; return create_float_constant(theEnv, yFloat->get_result_type(), FloatToString(mergedValue)) ; } if (xFloat != NULL && yInt != NULL) { float mergedValue = StringToFloat(xFloat->get_value()) - yInt->get_value().c_int() ; return create_float_constant(theEnv, xFloat->get_result_type(), FloatToString(mergedValue)) ; } } return NULL ; }
void ConstantArrayPropagationPass::ReplaceLoad(LoadExpression* load, ArrayReferenceExpression* ref, VariableSymbol* var, ValueBlock* topBlock) { list<IntConstant*> allDimensions ; IntConstant* nextIndex = dynamic_cast<IntConstant*>(ref->get_index()) ; if (nextIndex == NULL) { OutputWarning("Trying to access a constant array with a nonconstant index!") ; delete var->remove_annote_by_name("ConstPropArray") ; // assert(0) ; return ; } allDimensions.push_front(nextIndex) ; ArrayReferenceExpression* nextDimension = dynamic_cast<ArrayReferenceExpression*>(ref->get_base_array_address()) ; while (nextDimension != NULL) { nextIndex = dynamic_cast<IntConstant*>(nextDimension->get_index()) ; assert(nextIndex != NULL) ; allDimensions.push_front(nextIndex) ; nextDimension = dynamic_cast<ArrayReferenceExpression*>(nextDimension->get_base_array_address()) ; } ValueBlock* currentBlock = topBlock ; list<IntConstant*>::iterator dimIter = allDimensions.begin() ; for (int i = 0 ; i < allDimensions.size() ; ++i) { MultiValueBlock* multiBlock = dynamic_cast<MultiValueBlock*>(currentBlock); assert(multiBlock != NULL) ; currentBlock = multiBlock->lookup_sub_block((*dimIter)->get_value()) ; ++dimIter ; } ExpressionValueBlock* finalBlock = dynamic_cast<ExpressionValueBlock*>(currentBlock) ; assert(finalBlock != NULL && "Attempted to use an uninitialized constant value!") ; Expression* replacementValue = finalBlock->get_expression() ; if (dynamic_cast<IntConstant*>(replacementValue) != NULL) { IntConstant* constInt = dynamic_cast<IntConstant*>(replacementValue) ; IntConstant* replacement = create_int_constant(theEnv, constInt->get_result_type(), constInt->get_value()) ; load->get_parent()->replace(load, replacement) ; delete load ; } else if (dynamic_cast<FloatConstant*>(replacementValue) != NULL) { FloatConstant* constFloat = dynamic_cast<FloatConstant*>(replacementValue) ; FloatConstant* replacement = create_float_constant(theEnv, constFloat->get_result_type(), constFloat->get_value()) ; load->get_parent()->replace(load, replacement) ; delete load ; } else { assert(0 && "Unknown constant") ; } }