jdk8-mips64-public/hotspot: src/share/vm/adlc/output

src/share/vm/adlc/output_c.cpp@a61af66fc99e (annotated)

src/share/vm/adlc/output_c.cpp

Sat, 01 Dec 2007 00:00:00 +0000

author: duke
date: Sat, 01 Dec 2007 00:00:00 +0000
changeset 435: a61af66fc99e
child 548: ba764ed4b6f2
permissions: -rw-r--r--

Initial load

 /*
  * Copyright 1998-2007 Sun Microsystems, Inc.  All Rights Reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
  * CA 95054 USA or visit www.sun.com if you need additional information or
  * have any questions.
  *
  */
 // output_c.cpp - Class CPP file output routines for architecture definition
 #include "adlc.hpp"
 // Utilities to characterize effect statements
 static bool is_def(int usedef) {
   switch(usedef) {
   case Component::DEF:
   case Component::USE_DEF: return true; break;
   }
   return false;
 }
 static bool is_use(int usedef) {
   switch(usedef) {
   case Component::USE:
   case Component::USE_DEF:
   case Component::USE_KILL: return true; break;
   }
   return false;
 }
 static bool is_kill(int usedef) {
   switch(usedef) {
   case Component::KILL:
   case Component::USE_KILL: return true; break;
   }
   return false;
 }
 // Define  an array containing the machine register names, strings.
 static void defineRegNames(FILE *fp, RegisterForm *registers) {
   if (registers) {
     fprintf(fp,"\n");
     fprintf(fp,"// An array of character pointers to machine register names.\n");
     fprintf(fp,"const char *Matcher::regName[REG_COUNT] = {\n");
     // Output the register name for each register in the allocation classes
     RegDef *reg_def = NULL;
     RegDef *next = NULL;
     registers->reset_RegDefs();
     for( reg_def = registers->iter_RegDefs(); reg_def != NULL; reg_def = next ) {
       next = registers->iter_RegDefs();
       const char *comma = (next != NULL) ? "," : " // no trailing comma";
       fprintf(fp,"  \"%s\"%s\n",
                  reg_def->_regname, comma );
     }
     // Finish defining enumeration
     fprintf(fp,"};\n");
     fprintf(fp,"\n");
     fprintf(fp,"// An array of character pointers to machine register names.\n");
     fprintf(fp,"const VMReg OptoReg::opto2vm[REG_COUNT] = {\n");
     reg_def = NULL;
     next = NULL;
     registers->reset_RegDefs();
     for( reg_def = registers->iter_RegDefs(); reg_def != NULL; reg_def = next ) {
       next = registers->iter_RegDefs();
       const char *comma = (next != NULL) ? "," : " // no trailing comma";
       fprintf(fp,"\t%s%s\n", reg_def->_concrete, comma );
     }
     // Finish defining array
     fprintf(fp,"\t};\n");
     fprintf(fp,"\n");
     fprintf(fp," OptoReg::Name OptoReg::vm2opto[ConcreteRegisterImpl::number_of_registers];\n");
   }
 }
 // Define an array containing the machine register encoding values
 static void defineRegEncodes(FILE *fp, RegisterForm *registers) {
   if (registers) {
     fprintf(fp,"\n");
     fprintf(fp,"// An array of the machine register encode values\n");
     fprintf(fp,"const unsigned char Matcher::_regEncode[REG_COUNT] = {\n");
     // Output the register encoding for each register in the allocation classes
     RegDef *reg_def = NULL;
     RegDef *next    = NULL;
     registers->reset_RegDefs();
     for( reg_def = registers->iter_RegDefs(); reg_def != NULL; reg_def = next ) {
       next = registers->iter_RegDefs();
       const char* register_encode = reg_def->register_encode();
       const char *comma = (next != NULL) ? "," : " // no trailing comma";
       int encval;
       if (!ADLParser::is_int_token(register_encode, encval)) {
         fprintf(fp,"  %s%s  // %s\n",
                 register_encode, comma, reg_def->_regname );
       } else {
         // Output known constants in hex char format (backward compatibility).
         assert(encval < 256, "Exceeded supported width for register encoding");
         fprintf(fp,"  (unsigned char)'\\x%X'%s  // %s\n",
                 encval,          comma, reg_def->_regname );
       }
     }
     // Finish defining enumeration
     fprintf(fp,"};\n");
   } // Done defining array
 }
 // Output an enumeration of register class names
 static void defineRegClassEnum(FILE *fp, RegisterForm *registers) {
   if (registers) {
     // Output an enumeration of register class names
     fprintf(fp,"\n");
     fprintf(fp,"// Enumeration of register class names\n");
     fprintf(fp, "enum machRegisterClass {\n");
     registers->_rclasses.reset();
     for( const char *class_name = NULL;
          (class_name = registers->_rclasses.iter()) != NULL; ) {
       fprintf(fp,"  %s,\n", toUpper( class_name ));
     }
     // Finish defining enumeration
     fprintf(fp, "  _last_Mach_Reg_Class\n");
     fprintf(fp, "};\n");
   }
 }
 // Declare an enumeration of user-defined register classes
 // and a list of register masks, one for each class.
 void ArchDesc::declare_register_masks(FILE *fp_hpp) {
   const char  *rc_name;
   if( _register ) {
     // Build enumeration of user-defined register classes.
     defineRegClassEnum(fp_hpp, _register);
     // Generate a list of register masks, one for each class.
     fprintf(fp_hpp,"\n");
     fprintf(fp_hpp,"// Register masks, one for each register class.\n");
     _register->_rclasses.reset();
     for( rc_name = NULL;
          (rc_name = _register->_rclasses.iter()) != NULL; ) {
       const char *prefix    = "";
       RegClass   *reg_class = _register->getRegClass(rc_name);
       assert( reg_class, "Using an undefined register class");
       int len = RegisterForm::RegMask_Size();
       fprintf(fp_hpp, "extern const RegMask %s%s_mask;\n", prefix, toUpper( rc_name ) );
       if( reg_class->_stack_or_reg ) {
         fprintf(fp_hpp, "extern const RegMask %sSTACK_OR_%s_mask;\n", prefix, toUpper( rc_name ) );
       }
     }
   }
 }
 // Generate an enumeration of user-defined register classes
 // and a list of register masks, one for each class.
 void ArchDesc::build_register_masks(FILE *fp_cpp) {
   const char  *rc_name;
   if( _register ) {
     // Generate a list of register masks, one for each class.
     fprintf(fp_cpp,"\n");
     fprintf(fp_cpp,"// Register masks, one for each register class.\n");
     _register->_rclasses.reset();
     for( rc_name = NULL;
          (rc_name = _register->_rclasses.iter()) != NULL; ) {
       const char *prefix    = "";
       RegClass   *reg_class = _register->getRegClass(rc_name);
       assert( reg_class, "Using an undefined register class");
       int len = RegisterForm::RegMask_Size();
       fprintf(fp_cpp, "const RegMask %s%s_mask(", prefix, toUpper( rc_name ) );
       { int i;
         for( i = 0; i < len-1; i++ )
           fprintf(fp_cpp," 0x%x,",reg_class->regs_in_word(i,false));
         fprintf(fp_cpp," 0x%x );\n",reg_class->regs_in_word(i,false));
       }
       if( reg_class->_stack_or_reg ) {
         int i;
         fprintf(fp_cpp, "const RegMask %sSTACK_OR_%s_mask(", prefix, toUpper( rc_name ) );
         for( i = 0; i < len-1; i++ )
           fprintf(fp_cpp," 0x%x,",reg_class->regs_in_word(i,true));
         fprintf(fp_cpp," 0x%x );\n",reg_class->regs_in_word(i,true));
       }
     }
   }
 }
 // Compute an index for an array in the pipeline_reads_NNN arrays
 static int pipeline_reads_initializer(FILE *fp_cpp, NameList &pipeline_reads, PipeClassForm *pipeclass)
 {
   int templen = 1;
   int paramcount = 0;
   const char *paramname;
   if (pipeclass->_parameters.count() == 0)
     return -1;
   pipeclass->_parameters.reset();
   paramname = pipeclass->_parameters.iter();
   const PipeClassOperandForm *pipeopnd =
     (const PipeClassOperandForm *)pipeclass->_localUsage[paramname];
   if (pipeopnd && !pipeopnd->isWrite() && strcmp(pipeopnd->_stage, "Universal"))
     pipeclass->_parameters.reset();
   while ( (paramname = pipeclass->_parameters.iter()) != NULL ) {
     const PipeClassOperandForm *pipeopnd =
         (const PipeClassOperandForm *)pipeclass->_localUsage[paramname];
     if (pipeopnd)
       templen += 10 + (int)strlen(pipeopnd->_stage);
     else
       templen += 19;
     paramcount++;
   }
   // See if the count is zero
   if (paramcount == 0) {
     return -1;
   }
   char *operand_stages = new char [templen];
   operand_stages[0] = 0;
   int i = 0;
   templen = 0;
   pipeclass->_parameters.reset();
   paramname = pipeclass->_parameters.iter();
   pipeopnd = (const PipeClassOperandForm *)pipeclass->_localUsage[paramname];
   if (pipeopnd && !pipeopnd->isWrite() && strcmp(pipeopnd->_stage, "Universal"))
     pipeclass->_parameters.reset();
   while ( (paramname = pipeclass->_parameters.iter()) != NULL ) {
     const PipeClassOperandForm *pipeopnd =
         (const PipeClassOperandForm *)pipeclass->_localUsage[paramname];
     templen += sprintf(&operand_stages[templen], "  stage_%s%c\n",
       pipeopnd ? pipeopnd->_stage : "undefined",
       (++i < paramcount ? ',' : ' ') );
   }
   // See if the same string is in the table
   int ndx = pipeline_reads.index(operand_stages);
   // No, add it to the table
   if (ndx < 0) {
     pipeline_reads.addName(operand_stages);
     ndx = pipeline_reads.index(operand_stages);
     fprintf(fp_cpp, "static const enum machPipelineStages pipeline_reads_%03d[%d] = {\n%s};\n\n",
       ndx+1, paramcount, operand_stages);
   }
   else
     delete [] operand_stages;
   return (ndx);
 }
 // Compute an index for an array in the pipeline_res_stages_NNN arrays
 static int pipeline_res_stages_initializer(
   FILE *fp_cpp,
   PipelineForm *pipeline,
   NameList &pipeline_res_stages,
   PipeClassForm *pipeclass)
 {
   const PipeClassResourceForm *piperesource;
   int * res_stages = new int [pipeline->_rescount];
   int i;
   for (i = 0; i < pipeline->_rescount; i++)
      res_stages[i] = 0;
   for (pipeclass->_resUsage.reset();
        (piperesource = (const PipeClassResourceForm *)pipeclass->_resUsage.iter()) != NULL; ) {
     int used_mask = pipeline->_resdict[piperesource->_resource]->is_resource()->mask();
     for (i = 0; i < pipeline->_rescount; i++)
       if ((1 << i) & used_mask) {
         int stage = pipeline->_stages.index(piperesource->_stage);
         if (res_stages[i] < stage+1)
           res_stages[i] = stage+1;
       }
   }
   // Compute the length needed for the resource list
   int commentlen = 0;
   int max_stage = 0;
   for (i = 0; i < pipeline->_rescount; i++) {
     if (res_stages[i] == 0) {
       if (max_stage < 9)
         max_stage = 9;
     }
     else {
       int stagelen = (int)strlen(pipeline->_stages.name(res_stages[i]-1));
       if (max_stage < stagelen)
         max_stage = stagelen;
     }
     commentlen += (int)strlen(pipeline->_reslist.name(i));
   }
   int templen = 1 + commentlen + pipeline->_rescount * (max_stage + 14);
   // Allocate space for the resource list
   char * resource_stages = new char [templen];
   templen = 0;
   for (i = 0; i < pipeline->_rescount; i++) {
     const char * const resname =
       res_stages[i] == 0 ? "undefined" : pipeline->_stages.name(res_stages[i]-1);
     templen += sprintf(&resource_stages[templen], "  stage_%s%-*s // %s\n",
       resname, max_stage - (int)strlen(resname) + 1,
       (i < pipeline->_rescount-1) ? "," : "",
       pipeline->_reslist.name(i));
   }
   // See if the same string is in the table
   int ndx = pipeline_res_stages.index(resource_stages);
   // No, add it to the table
   if (ndx < 0) {
     pipeline_res_stages.addName(resource_stages);
     ndx = pipeline_res_stages.index(resource_stages);
     fprintf(fp_cpp, "static const enum machPipelineStages pipeline_res_stages_%03d[%d] = {\n%s};\n\n",
       ndx+1, pipeline->_rescount, resource_stages);
   }
   else
     delete [] resource_stages;
   delete [] res_stages;
   return (ndx);
 }
 // Compute an index for an array in the pipeline_res_cycles_NNN arrays
 static int pipeline_res_cycles_initializer(
   FILE *fp_cpp,
   PipelineForm *pipeline,
   NameList &pipeline_res_cycles,
   PipeClassForm *pipeclass)
 {
   const PipeClassResourceForm *piperesource;
   int * res_cycles = new int [pipeline->_rescount];
   int i;
   for (i = 0; i < pipeline->_rescount; i++)
      res_cycles[i] = 0;
   for (pipeclass->_resUsage.reset();
        (piperesource = (const PipeClassResourceForm *)pipeclass->_resUsage.iter()) != NULL; ) {
     int used_mask = pipeline->_resdict[piperesource->_resource]->is_resource()->mask();
     for (i = 0; i < pipeline->_rescount; i++)
       if ((1 << i) & used_mask) {
         int cycles = piperesource->_cycles;
         if (res_cycles[i] < cycles)
           res_cycles[i] = cycles;
       }
   }
   // Pre-compute the string length
   int templen;
   int cyclelen = 0, commentlen = 0;
   int max_cycles = 0;
   char temp[32];
   for (i = 0; i < pipeline->_rescount; i++) {
     if (max_cycles < res_cycles[i])
       max_cycles = res_cycles[i];
     templen = sprintf(temp, "%d", res_cycles[i]);
     if (cyclelen < templen)
       cyclelen = templen;
     commentlen += (int)strlen(pipeline->_reslist.name(i));
   }
   templen = 1 + commentlen + (cyclelen + 8) * pipeline->_rescount;
   // Allocate space for the resource list
   char * resource_cycles = new char [templen];
   templen = 0;
   for (i = 0; i < pipeline->_rescount; i++) {
     templen += sprintf(&resource_cycles[templen], "  %*d%c // %s\n",
       cyclelen, res_cycles[i], (i < pipeline->_rescount-1) ? ',' : ' ', pipeline->_reslist.name(i));
   }
   // See if the same string is in the table
   int ndx = pipeline_res_cycles.index(resource_cycles);
   // No, add it to the table
   if (ndx < 0) {
     pipeline_res_cycles.addName(resource_cycles);
     ndx = pipeline_res_cycles.index(resource_cycles);
     fprintf(fp_cpp, "static const uint pipeline_res_cycles_%03d[%d] = {\n%s};\n\n",
       ndx+1, pipeline->_rescount, resource_cycles);
   }
   else
     delete [] resource_cycles;
   delete [] res_cycles;
   return (ndx);
 }
 //typedef unsigned long long uint64_t;
 // Compute an index for an array in the pipeline_res_mask_NNN arrays
 static int pipeline_res_mask_initializer(
   FILE *fp_cpp,
   PipelineForm *pipeline,
   NameList &pipeline_res_mask,
   NameList &pipeline_res_args,
   PipeClassForm *pipeclass)
 {
   const PipeClassResourceForm *piperesource;
   const uint rescount      = pipeline->_rescount;
   const uint maxcycleused  = pipeline->_maxcycleused;
   const uint cyclemasksize = (maxcycleused + 31) >> 5;
   int i, j;
   int element_count = 0;
   uint *res_mask = new uint [cyclemasksize];
   uint resources_used             = 0;
   uint resources_used_exclusively = 0;
   for (pipeclass->_resUsage.reset();
        (piperesource = (const PipeClassResourceForm *)pipeclass->_resUsage.iter()) != NULL; )
     element_count++;
   // Pre-compute the string length
   int templen;
   int commentlen = 0;
   int max_cycles = 0;
   int cyclelen = ((maxcycleused + 3) >> 2);
   int masklen = (rescount + 3) >> 2;
   int cycledigit = 0;
   for (i = maxcycleused; i > 0; i /= 10)
     cycledigit++;
   int maskdigit = 0;
   for (i = rescount; i > 0; i /= 10)
     maskdigit++;
   static const char * pipeline_use_cycle_mask = "Pipeline_Use_Cycle_Mask";
   static const char * pipeline_use_element    = "Pipeline_Use_Element";
   templen = 1 +
     (int)(strlen(pipeline_use_cycle_mask) + (int)strlen(pipeline_use_element) +
      (cyclemasksize * 12) + masklen + (cycledigit * 2) + 30) * element_count;
   // Allocate space for the resource list
   char * resource_mask = new char [templen];
   char * last_comma = NULL;
   templen = 0;
   for (pipeclass->_resUsage.reset();
        (piperesource = (const PipeClassResourceForm *)pipeclass->_resUsage.iter()) != NULL; ) {
     int used_mask = pipeline->_resdict[piperesource->_resource]->is_resource()->mask();
     if (!used_mask)
       fprintf(stderr, "*** used_mask is 0 ***\n");
     resources_used |= used_mask;
     uint lb, ub;
     for (lb =  0; (used_mask & (1 << lb)) == 0; lb++);
     for (ub = 31; (used_mask & (1 << ub)) == 0; ub--);
     if (lb == ub)
       resources_used_exclusively |= used_mask;
     int formatlen =
       sprintf(&resource_mask[templen], "  %s(0x%0*x, %*d, %*d, %s %s(",
         pipeline_use_element,
         masklen, used_mask,
         cycledigit, lb, cycledigit, ub,
         ((used_mask & (used_mask-1)) != 0) ? "true, " : "false,",
         pipeline_use_cycle_mask);
     templen += formatlen;
     memset(res_mask, 0, cyclemasksize * sizeof(uint));
     int cycles = piperesource->_cycles;
     uint stage          = pipeline->_stages.index(piperesource->_stage);
     uint upper_limit    = stage+cycles-1;
     uint lower_limit    = stage-1;
     uint upper_idx      = upper_limit >> 5;
     uint lower_idx      = lower_limit >> 5;
     uint upper_position = upper_limit & 0x1f;
     uint lower_position = lower_limit & 0x1f;
     uint mask = (((uint)1) << upper_position) - 1;
     while ( upper_idx > lower_idx ) {
       res_mask[upper_idx--] |= mask;
       mask = (uint)-1;
     }
     mask -= (((uint)1) << lower_position) - 1;
     res_mask[upper_idx] |= mask;
     for (j = cyclemasksize-1; j >= 0; j--) {
       formatlen =
         sprintf(&resource_mask[templen], "0x%08x%s", res_mask[j], j > 0 ? ", " : "");
       templen += formatlen;
     }
     resource_mask[templen++] = ')';
     resource_mask[templen++] = ')';
     last_comma = &resource_mask[templen];
     resource_mask[templen++] = ',';
     resource_mask[templen++] = '\n';
   }
   resource_mask[templen] = 0;
   if (last_comma)
     last_comma[0] = ' ';
   // See if the same string is in the table
   int ndx = pipeline_res_mask.index(resource_mask);
   // No, add it to the table
   if (ndx < 0) {
     pipeline_res_mask.addName(resource_mask);
     ndx = pipeline_res_mask.index(resource_mask);
     if (strlen(resource_mask) > 0)
       fprintf(fp_cpp, "static const Pipeline_Use_Element pipeline_res_mask_%03d[%d] = {\n%s};\n\n",
         ndx+1, element_count, resource_mask);
     char * args = new char [9 + 2*masklen + maskdigit];
     sprintf(args, "0x%0*x, 0x%0*x, %*d",
       masklen, resources_used,
       masklen, resources_used_exclusively,
       maskdigit, element_count);
     pipeline_res_args.addName(args);
   }
   else
     delete [] resource_mask;
   delete [] res_mask;
 //delete [] res_masks;
   return (ndx);
 }
 void ArchDesc::build_pipe_classes(FILE *fp_cpp) {
   const char *classname;
   const char *resourcename;
   int resourcenamelen = 0;
   NameList pipeline_reads;
   NameList pipeline_res_stages;
   NameList pipeline_res_cycles;
   NameList pipeline_res_masks;
   NameList pipeline_res_args;
   const int default_latency = 1;
   const int non_operand_latency = 0;
   const int node_latency = 0;
   if (!_pipeline) {
     fprintf(fp_cpp, "uint Node::latency(uint i) const {\n");
     fprintf(fp_cpp, "  // assert(false, \"pipeline functionality is not defined\");\n");
     fprintf(fp_cpp, "  return %d;\n", non_operand_latency);
     fprintf(fp_cpp, "}\n");
     return;
   }
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "//------------------Pipeline Methods-----------------------------------------\n");
   fprintf(fp_cpp, "#ifndef PRODUCT\n");
   fprintf(fp_cpp, "const char * Pipeline::stageName(uint s) {\n");
   fprintf(fp_cpp, "  static const char * const _stage_names[] = {\n");
   fprintf(fp_cpp, "    \"undefined\"");
   for (int s = 0; s < _pipeline->_stagecnt; s++)
     fprintf(fp_cpp, ", \"%s\"", _pipeline->_stages.name(s));
   fprintf(fp_cpp, "\n  };\n\n");
   fprintf(fp_cpp, "  return (s <= %d ? _stage_names[s] : \"???\");\n",
     _pipeline->_stagecnt);
   fprintf(fp_cpp, "}\n");
   fprintf(fp_cpp, "#endif\n\n");
   fprintf(fp_cpp, "uint Pipeline::functional_unit_latency(uint start, const Pipeline *pred) const {\n");
   fprintf(fp_cpp, "  // See if the functional units overlap\n");
 #if 0
   fprintf(fp_cpp, "\n#ifndef PRODUCT\n");
   fprintf(fp_cpp, "  if (TraceOptoOutput) {\n");
   fprintf(fp_cpp, "    tty->print(\"#   functional_unit_latency: start == %%d, this->exclusively == 0x%%03x, pred->exclusively == 0x%%03x\\n\", start, resourcesUsedExclusively(), pred->resourcesUsedExclusively());\n");
   fprintf(fp_cpp, "  }\n");
   fprintf(fp_cpp, "#endif\n\n");
 #endif
   fprintf(fp_cpp, "  uint mask = resourcesUsedExclusively() & pred->resourcesUsedExclusively();\n");
   fprintf(fp_cpp, "  if (mask == 0)\n    return (start);\n\n");
 #if 0
   fprintf(fp_cpp, "\n#ifndef PRODUCT\n");
   fprintf(fp_cpp, "  if (TraceOptoOutput) {\n");
   fprintf(fp_cpp, "    tty->print(\"#   functional_unit_latency: mask == 0x%%x\\n\", mask);\n");
   fprintf(fp_cpp, "  }\n");
   fprintf(fp_cpp, "#endif\n\n");
 #endif
   fprintf(fp_cpp, "  for (uint i = 0; i < pred->resourceUseCount(); i++) {\n");
   fprintf(fp_cpp, "    const Pipeline_Use_Element *predUse = pred->resourceUseElement(i);\n");
   fprintf(fp_cpp, "    if (predUse->multiple())\n");
   fprintf(fp_cpp, "      continue;\n\n");
   fprintf(fp_cpp, "    for (uint j = 0; j < resourceUseCount(); j++) {\n");
   fprintf(fp_cpp, "      const Pipeline_Use_Element *currUse = resourceUseElement(j);\n");
   fprintf(fp_cpp, "      if (currUse->multiple())\n");
   fprintf(fp_cpp, "        continue;\n\n");
   fprintf(fp_cpp, "      if (predUse->used() & currUse->used()) {\n");
   fprintf(fp_cpp, "        Pipeline_Use_Cycle_Mask x = predUse->mask();\n");
   fprintf(fp_cpp, "        Pipeline_Use_Cycle_Mask y = currUse->mask();\n\n");
   fprintf(fp_cpp, "        for ( y <<= start; x.overlaps(y); start++ )\n");
   fprintf(fp_cpp, "          y <<= 1;\n");
   fprintf(fp_cpp, "      }\n");
   fprintf(fp_cpp, "    }\n");
   fprintf(fp_cpp, "  }\n\n");
   fprintf(fp_cpp, "  // There is the potential for overlap\n");
   fprintf(fp_cpp, "  return (start);\n");
   fprintf(fp_cpp, "}\n\n");
   fprintf(fp_cpp, "// The following two routines assume that the root Pipeline_Use entity\n");
   fprintf(fp_cpp, "// consists of exactly 1 element for each functional unit\n");
   fprintf(fp_cpp, "// start is relative to the current cycle; used for latency-based info\n");
   fprintf(fp_cpp, "uint Pipeline_Use::full_latency(uint delay, const Pipeline_Use &pred) const {\n");
   fprintf(fp_cpp, "  for (uint i = 0; i < pred._count; i++) {\n");
   fprintf(fp_cpp, "    const Pipeline_Use_Element *predUse = pred.element(i);\n");
   fprintf(fp_cpp, "    if (predUse->_multiple) {\n");
   fprintf(fp_cpp, "      uint min_delay = %d;\n",
     _pipeline->_maxcycleused+1);
   fprintf(fp_cpp, "      // Multiple possible functional units, choose first unused one\n");
   fprintf(fp_cpp, "      for (uint j = predUse->_lb; j <= predUse->_ub; j++) {\n");
   fprintf(fp_cpp, "        const Pipeline_Use_Element *currUse = element(j);\n");
   fprintf(fp_cpp, "        uint curr_delay = delay;\n");
   fprintf(fp_cpp, "        if (predUse->_used & currUse->_used) {\n");
   fprintf(fp_cpp, "          Pipeline_Use_Cycle_Mask x = predUse->_mask;\n");
   fprintf(fp_cpp, "          Pipeline_Use_Cycle_Mask y = currUse->_mask;\n\n");
   fprintf(fp_cpp, "          for ( y <<= curr_delay; x.overlaps(y); curr_delay++ )\n");
   fprintf(fp_cpp, "            y <<= 1;\n");
   fprintf(fp_cpp, "        }\n");
   fprintf(fp_cpp, "        if (min_delay > curr_delay)\n          min_delay = curr_delay;\n");
   fprintf(fp_cpp, "      }\n");
   fprintf(fp_cpp, "      if (delay < min_delay)\n      delay = min_delay;\n");
   fprintf(fp_cpp, "    }\n");
   fprintf(fp_cpp, "    else {\n");
   fprintf(fp_cpp, "      for (uint j = predUse->_lb; j <= predUse->_ub; j++) {\n");
   fprintf(fp_cpp, "        const Pipeline_Use_Element *currUse = element(j);\n");
   fprintf(fp_cpp, "        if (predUse->_used & currUse->_used) {\n");
   fprintf(fp_cpp, "          Pipeline_Use_Cycle_Mask x = predUse->_mask;\n");
   fprintf(fp_cpp, "          Pipeline_Use_Cycle_Mask y = currUse->_mask;\n\n");
   fprintf(fp_cpp, "          for ( y <<= delay; x.overlaps(y); delay++ )\n");
   fprintf(fp_cpp, "            y <<= 1;\n");
   fprintf(fp_cpp, "        }\n");
   fprintf(fp_cpp, "      }\n");
   fprintf(fp_cpp, "    }\n");
   fprintf(fp_cpp, "  }\n\n");
   fprintf(fp_cpp, "  return (delay);\n");
   fprintf(fp_cpp, "}\n\n");
   fprintf(fp_cpp, "void Pipeline_Use::add_usage(const Pipeline_Use &pred) {\n");
   fprintf(fp_cpp, "  for (uint i = 0; i < pred._count; i++) {\n");
   fprintf(fp_cpp, "    const Pipeline_Use_Element *predUse = pred.element(i);\n");
   fprintf(fp_cpp, "    if (predUse->_multiple) {\n");
   fprintf(fp_cpp, "      // Multiple possible functional units, choose first unused one\n");
   fprintf(fp_cpp, "      for (uint j = predUse->_lb; j <= predUse->_ub; j++) {\n");
   fprintf(fp_cpp, "        Pipeline_Use_Element *currUse = element(j);\n");
   fprintf(fp_cpp, "        if ( !predUse->_mask.overlaps(currUse->_mask) ) {\n");
   fprintf(fp_cpp, "          currUse->_used |= (1 << j);\n");
   fprintf(fp_cpp, "          _resources_used |= (1 << j);\n");
   fprintf(fp_cpp, "          currUse->_mask.Or(predUse->_mask);\n");
   fprintf(fp_cpp, "          break;\n");
   fprintf(fp_cpp, "        }\n");
   fprintf(fp_cpp, "      }\n");
   fprintf(fp_cpp, "    }\n");
   fprintf(fp_cpp, "    else {\n");
   fprintf(fp_cpp, "      for (uint j = predUse->_lb; j <= predUse->_ub; j++) {\n");
   fprintf(fp_cpp, "        Pipeline_Use_Element *currUse = element(j);\n");
   fprintf(fp_cpp, "        currUse->_used |= (1 << j);\n");
   fprintf(fp_cpp, "        _resources_used |= (1 << j);\n");
   fprintf(fp_cpp, "        currUse->_mask.Or(predUse->_mask);\n");
   fprintf(fp_cpp, "      }\n");
   fprintf(fp_cpp, "    }\n");
   fprintf(fp_cpp, "  }\n");
   fprintf(fp_cpp, "}\n\n");
   fprintf(fp_cpp, "uint Pipeline::operand_latency(uint opnd, const Pipeline *pred) const {\n");
   fprintf(fp_cpp, "  int const default_latency = 1;\n");
   fprintf(fp_cpp, "\n");
 #if 0
   fprintf(fp_cpp, "#ifndef PRODUCT\n");
   fprintf(fp_cpp, "  if (TraceOptoOutput) {\n");
   fprintf(fp_cpp, "    tty->print(\"#   operand_latency(%%d), _read_stage_count = %%d\\n\", opnd, _read_stage_count);\n");
   fprintf(fp_cpp, "  }\n");
   fprintf(fp_cpp, "#endif\n\n");
 #endif
   fprintf(fp_cpp, "  assert(this, \"NULL pipeline info\")\n");
   fprintf(fp_cpp, "  assert(pred, \"NULL predecessor pipline info\")\n\n");
   fprintf(fp_cpp, "  if (pred->hasFixedLatency())\n    return (pred->fixedLatency());\n\n");
   fprintf(fp_cpp, "  // If this is not an operand, then assume a dependence with 0 latency\n");
   fprintf(fp_cpp, "  if (opnd > _read_stage_count)\n    return (0);\n\n");
   fprintf(fp_cpp, "  uint writeStage = pred->_write_stage;\n");
   fprintf(fp_cpp, "  uint readStage  = _read_stages[opnd-1];\n");
 #if 0
   fprintf(fp_cpp, "\n#ifndef PRODUCT\n");
   fprintf(fp_cpp, "  if (TraceOptoOutput) {\n");
   fprintf(fp_cpp, "    tty->print(\"#   operand_latency: writeStage=%%s readStage=%%s, opnd=%%d\\n\", stageName(writeStage), stageName(readStage), opnd);\n");
   fprintf(fp_cpp, "  }\n");
   fprintf(fp_cpp, "#endif\n\n");
 #endif
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "  if (writeStage == stage_undefined || readStage == stage_undefined)\n");
   fprintf(fp_cpp, "    return (default_latency);\n");
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "  int delta = writeStage - readStage;\n");
   fprintf(fp_cpp, "  if (delta < 0) delta = 0;\n\n");
 #if 0
   fprintf(fp_cpp, "\n#ifndef PRODUCT\n");
   fprintf(fp_cpp, "  if (TraceOptoOutput) {\n");
   fprintf(fp_cpp, "    tty->print(\"# operand_latency: delta=%%d\\n\", delta);\n");
   fprintf(fp_cpp, "  }\n");
   fprintf(fp_cpp, "#endif\n\n");
 #endif
   fprintf(fp_cpp, "  return (delta);\n");
   fprintf(fp_cpp, "}\n\n");
   if (!_pipeline)
     /* Do Nothing */;
   else if (_pipeline->_maxcycleused <=
 #ifdef SPARC
 
 #else
 
 #endif
       ) {
     fprintf(fp_cpp, "Pipeline_Use_Cycle_Mask operator&(const Pipeline_Use_Cycle_Mask &in1, const Pipeline_Use_Cycle_Mask &in2) {\n");
     fprintf(fp_cpp, "  return Pipeline_Use_Cycle_Mask(in1._mask & in2._mask);\n");
     fprintf(fp_cpp, "}\n\n");
     fprintf(fp_cpp, "Pipeline_Use_Cycle_Mask operator|(const Pipeline_Use_Cycle_Mask &in1, const Pipeline_Use_Cycle_Mask &in2) {\n");
     fprintf(fp_cpp, "  return Pipeline_Use_Cycle_Mask(in1._mask | in2._mask);\n");
     fprintf(fp_cpp, "}\n\n");
   }
   else {
     uint l;
     uint masklen = (_pipeline->_maxcycleused + 31) >> 5;
     fprintf(fp_cpp, "Pipeline_Use_Cycle_Mask operator&(const Pipeline_Use_Cycle_Mask &in1, const Pipeline_Use_Cycle_Mask &in2) {\n");
     fprintf(fp_cpp, "  return Pipeline_Use_Cycle_Mask(");
     for (l = 1; l <= masklen; l++)
       fprintf(fp_cpp, "in1._mask%d & in2._mask%d%s\n", l, l, l < masklen ? ", " : "");
     fprintf(fp_cpp, ");\n");
     fprintf(fp_cpp, "}\n\n");
     fprintf(fp_cpp, "Pipeline_Use_Cycle_Mask operator|(const Pipeline_Use_Cycle_Mask &in1, const Pipeline_Use_Cycle_Mask &in2) {\n");
     fprintf(fp_cpp, "  return Pipeline_Use_Cycle_Mask(");
     for (l = 1; l <= masklen; l++)
       fprintf(fp_cpp, "in1._mask%d | in2._mask%d%s", l, l, l < masklen ? ", " : "");
     fprintf(fp_cpp, ");\n");
     fprintf(fp_cpp, "}\n\n");
     fprintf(fp_cpp, "void Pipeline_Use_Cycle_Mask::Or(const Pipeline_Use_Cycle_Mask &in2) {\n ");
     for (l = 1; l <= masklen; l++)
       fprintf(fp_cpp, " _mask%d |= in2._mask%d;", l, l);
     fprintf(fp_cpp, "\n}\n\n");
   }
   /* Get the length of all the resource names */
   for (_pipeline->_reslist.reset(), resourcenamelen = 0;
        (resourcename = _pipeline->_reslist.iter()) != NULL;
        resourcenamelen += (int)strlen(resourcename));
   // Create the pipeline class description
   fprintf(fp_cpp, "static const Pipeline pipeline_class_Zero_Instructions(0, 0, true, 0, 0, false, false, false, false, NULL, NULL, NULL, Pipeline_Use(0, 0, 0, NULL));\n\n");
   fprintf(fp_cpp, "static const Pipeline pipeline_class_Unknown_Instructions(0, 0, true, 0, 0, false, true, true, false, NULL, NULL, NULL, Pipeline_Use(0, 0, 0, NULL));\n\n");
   fprintf(fp_cpp, "const Pipeline_Use_Element Pipeline_Use::elaborated_elements[%d] = {\n", _pipeline->_rescount);
   for (int i1 = 0; i1 < _pipeline->_rescount; i1++) {
     fprintf(fp_cpp, "  Pipeline_Use_Element(0, %d, %d, false, Pipeline_Use_Cycle_Mask(", i1, i1);
     uint masklen = (_pipeline->_maxcycleused + 31) >> 5;
     for (int i2 = masklen-1; i2 >= 0; i2--)
       fprintf(fp_cpp, "0%s", i2 > 0 ? ", " : "");
     fprintf(fp_cpp, "))%s\n", i1 < (_pipeline->_rescount-1) ? "," : "");
   }
   fprintf(fp_cpp, "};\n\n");
   fprintf(fp_cpp, "const Pipeline_Use Pipeline_Use::elaborated_use(0, 0, %d, (Pipeline_Use_Element *)&elaborated_elements[0]);\n\n",
     _pipeline->_rescount);
   for (_pipeline->_classlist.reset(); (classname = _pipeline->_classlist.iter()) != NULL; ) {
     fprintf(fp_cpp, "\n");
     fprintf(fp_cpp, "// Pipeline Class \"%s\"\n", classname);
     PipeClassForm *pipeclass = _pipeline->_classdict[classname]->is_pipeclass();
     int maxWriteStage = -1;
     int maxMoreInstrs = 0;
     int paramcount = 0;
     int i = 0;
     const char *paramname;
     int resource_count = (_pipeline->_rescount + 3) >> 2;
     // Scan the operands, looking for last output stage and number of inputs
     for (pipeclass->_parameters.reset(); (paramname = pipeclass->_parameters.iter()) != NULL; ) {
       const PipeClassOperandForm *pipeopnd =
           (const PipeClassOperandForm *)pipeclass->_localUsage[paramname];
       if (pipeopnd) {
         if (pipeopnd->_iswrite) {
            int stagenum  = _pipeline->_stages.index(pipeopnd->_stage);
            int moreinsts = pipeopnd->_more_instrs;
           if ((maxWriteStage+maxMoreInstrs) < (stagenum+moreinsts)) {
             maxWriteStage = stagenum;
             maxMoreInstrs = moreinsts;
           }
         }
       }
       if (i++ > 0 || (pipeopnd && !pipeopnd->isWrite()))
         paramcount++;
     }
     // Create the list of stages for the operands that are read
     // Note that we will build a NameList to reduce the number of copies
     int pipeline_reads_index = pipeline_reads_initializer(fp_cpp, pipeline_reads, pipeclass);
     int pipeline_res_stages_index = pipeline_res_stages_initializer(
       fp_cpp, _pipeline, pipeline_res_stages, pipeclass);
     int pipeline_res_cycles_index = pipeline_res_cycles_initializer(
       fp_cpp, _pipeline, pipeline_res_cycles, pipeclass);
     int pipeline_res_mask_index = pipeline_res_mask_initializer(
       fp_cpp, _pipeline, pipeline_res_masks, pipeline_res_args, pipeclass);
 #if 0
     // Process the Resources
     const PipeClassResourceForm *piperesource;
     unsigned resources_used = 0;
     unsigned exclusive_resources_used = 0;
     unsigned resource_groups = 0;
     for (pipeclass->_resUsage.reset();
          (piperesource = (const PipeClassResourceForm *)pipeclass->_resUsage.iter()) != NULL; ) {
       int used_mask = _pipeline->_resdict[piperesource->_resource]->is_resource()->mask();
       if (used_mask)
         resource_groups++;
       resources_used |= used_mask;
       if ((used_mask & (used_mask-1)) == 0)
         exclusive_resources_used |= used_mask;
     }
     if (resource_groups > 0) {
       fprintf(fp_cpp, "static const uint pipeline_res_or_masks_%03d[%d] = {",
         pipeclass->_num, resource_groups);
       for (pipeclass->_resUsage.reset(), i = 1;
            (piperesource = (const PipeClassResourceForm *)pipeclass->_resUsage.iter()) != NULL;
            i++ ) {
         int used_mask = _pipeline->_resdict[piperesource->_resource]->is_resource()->mask();
         if (used_mask) {
           fprintf(fp_cpp, " 0x%0*x%c", resource_count, used_mask, i < (int)resource_groups ? ',' : ' ');
         }
       }
       fprintf(fp_cpp, "};\n\n");
     }
 #endif
     // Create the pipeline class description
     fprintf(fp_cpp, "static const Pipeline pipeline_class_%03d(",
       pipeclass->_num);
     if (maxWriteStage < 0)
       fprintf(fp_cpp, "(uint)stage_undefined");
     else if (maxMoreInstrs == 0)
       fprintf(fp_cpp, "(uint)stage_%s", _pipeline->_stages.name(maxWriteStage));
     else
       fprintf(fp_cpp, "((uint)stage_%s)+%d", _pipeline->_stages.name(maxWriteStage), maxMoreInstrs);
     fprintf(fp_cpp, ", %d, %s, %d, %d, %s, %s, %s, %s,\n",
       paramcount,
       pipeclass->hasFixedLatency() ? "true" : "false",
       pipeclass->fixedLatency(),
       pipeclass->InstructionCount(),
       pipeclass->hasBranchDelay() ? "true" : "false",
       pipeclass->hasMultipleBundles() ? "true" : "false",
       pipeclass->forceSerialization() ? "true" : "false",
       pipeclass->mayHaveNoCode() ? "true" : "false" );
     if (paramcount > 0) {
       fprintf(fp_cpp, "\n  (enum machPipelineStages * const) pipeline_reads_%03d,\n ",
         pipeline_reads_index+1);
     }
     else
       fprintf(fp_cpp, " NULL,");
     fprintf(fp_cpp, "  (enum machPipelineStages * const) pipeline_res_stages_%03d,\n",
       pipeline_res_stages_index+1);
     fprintf(fp_cpp, "  (uint * const) pipeline_res_cycles_%03d,\n",
       pipeline_res_cycles_index+1);
     fprintf(fp_cpp, "  Pipeline_Use(%s, (Pipeline_Use_Element *)",
       pipeline_res_args.name(pipeline_res_mask_index));
     if (strlen(pipeline_res_masks.name(pipeline_res_mask_index)) > 0)
       fprintf(fp_cpp, "&pipeline_res_mask_%03d[0]",
         pipeline_res_mask_index+1);
     else
       fprintf(fp_cpp, "NULL");
     fprintf(fp_cpp, "));\n");
   }
   // Generate the Node::latency method if _pipeline defined
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "//------------------Inter-Instruction Latency--------------------------------\n");
   fprintf(fp_cpp, "uint Node::latency(uint i) {\n");
   if (_pipeline) {
 #if 0
     fprintf(fp_cpp, "#ifndef PRODUCT\n");
     fprintf(fp_cpp, " if (TraceOptoOutput) {\n");
     fprintf(fp_cpp, "    tty->print(\"# %%4d->latency(%%d)\\n\", _idx, i);\n");
     fprintf(fp_cpp, " }\n");
     fprintf(fp_cpp, "#endif\n");
 #endif
     fprintf(fp_cpp, "  uint j;\n");
     fprintf(fp_cpp, "  // verify in legal range for inputs\n");
     fprintf(fp_cpp, "  assert(i < len(), \"index not in range\");\n\n");
     fprintf(fp_cpp, "  // verify input is not null\n");
     fprintf(fp_cpp, "  Node *pred = in(i);\n");
     fprintf(fp_cpp, "  if (!pred)\n    return %d;\n\n",
       non_operand_latency);
     fprintf(fp_cpp, "  if (pred->is_Proj())\n    pred = pred->in(0);\n\n");
     fprintf(fp_cpp, "  // if either node does not have pipeline info, use default\n");
     fprintf(fp_cpp, "  const Pipeline *predpipe = pred->pipeline();\n");
     fprintf(fp_cpp, "  assert(predpipe, \"no predecessor pipeline info\");\n\n");
     fprintf(fp_cpp, "  if (predpipe->hasFixedLatency())\n    return predpipe->fixedLatency();\n\n");
     fprintf(fp_cpp, "  const Pipeline *currpipe = pipeline();\n");
     fprintf(fp_cpp, "  assert(currpipe, \"no pipeline info\");\n\n");
     fprintf(fp_cpp, "  if (!is_Mach())\n    return %d;\n\n",
       node_latency);
     fprintf(fp_cpp, "  const MachNode *m = as_Mach();\n");
     fprintf(fp_cpp, "  j = m->oper_input_base();\n");
     fprintf(fp_cpp, "  if (i < j)\n    return currpipe->functional_unit_latency(%d, predpipe);\n\n",
       non_operand_latency);
     fprintf(fp_cpp, "  // determine which operand this is in\n");
     fprintf(fp_cpp, "  uint n = m->num_opnds();\n");
     fprintf(fp_cpp, "  int delta = %d;\n\n",
       non_operand_latency);
     fprintf(fp_cpp, "  uint k;\n");
     fprintf(fp_cpp, "  for (k = 1; k < n; k++) {\n");
     fprintf(fp_cpp, "    j += m->_opnds[k]->num_edges();\n");
     fprintf(fp_cpp, "    if (i < j)\n");
     fprintf(fp_cpp, "      break;\n");
     fprintf(fp_cpp, "  }\n");
     fprintf(fp_cpp, "  if (k < n)\n");
     fprintf(fp_cpp, "    delta = currpipe->operand_latency(k,predpipe);\n\n");
     fprintf(fp_cpp, "  return currpipe->functional_unit_latency(delta, predpipe);\n");
   }
   else {
     fprintf(fp_cpp, "  // assert(false, \"pipeline functionality is not defined\");\n");
     fprintf(fp_cpp, "  return %d;\n",
       non_operand_latency);
   }
   fprintf(fp_cpp, "}\n\n");
   // Output the list of nop nodes
   fprintf(fp_cpp, "// Descriptions for emitting different functional unit nops\n");
   const char *nop;
   int nopcnt = 0;
   for ( _pipeline->_noplist.reset(); (nop = _pipeline->_noplist.iter()) != NULL; nopcnt++ );
   fprintf(fp_cpp, "void Bundle::initialize_nops(MachNode * nop_list[%d], Compile *C) {\n", nopcnt);
   int i = 0;
   for ( _pipeline->_noplist.reset(); (nop = _pipeline->_noplist.iter()) != NULL; i++ ) {
     fprintf(fp_cpp, "  nop_list[%d] = (MachNode *) new (C) %sNode();\n", i, nop);
   }
   fprintf(fp_cpp, "};\n\n");
   fprintf(fp_cpp, "#ifndef PRODUCT\n");
   fprintf(fp_cpp, "void Bundle::dump() const {\n");
   fprintf(fp_cpp, "  static const char * bundle_flags[] = {\n");
   fprintf(fp_cpp, "    \"\",\n");
   fprintf(fp_cpp, "    \"use nop delay\",\n");
   fprintf(fp_cpp, "    \"use unconditional delay\",\n");
   fprintf(fp_cpp, "    \"use conditional delay\",\n");
   fprintf(fp_cpp, "    \"used in conditional delay\",\n");
   fprintf(fp_cpp, "    \"used in unconditional delay\",\n");
   fprintf(fp_cpp, "    \"used in all conditional delays\",\n");
   fprintf(fp_cpp, "  };\n\n");
   fprintf(fp_cpp, "  static const char *resource_names[%d] = {", _pipeline->_rescount);
   for (i = 0; i < _pipeline->_rescount; i++)
     fprintf(fp_cpp, " \"%s\"%c", _pipeline->_reslist.name(i), i < _pipeline->_rescount-1 ? ',' : ' ');
   fprintf(fp_cpp, "};\n\n");
   // See if the same string is in the table
   fprintf(fp_cpp, "  bool needs_comma = false;\n\n");
   fprintf(fp_cpp, "  if (_flags) {\n");
   fprintf(fp_cpp, "    tty->print(\"%%s\", bundle_flags[_flags]);\n");
   fprintf(fp_cpp, "    needs_comma = true;\n");
   fprintf(fp_cpp, "  };\n");
   fprintf(fp_cpp, "  if (instr_count()) {\n");
   fprintf(fp_cpp, "    tty->print(\"%%s%%d instr%%s\", needs_comma ? \", \" : \"\", instr_count(), instr_count() != 1 ? \"s\" : \"\");\n");
   fprintf(fp_cpp, "    needs_comma = true;\n");
   fprintf(fp_cpp, "  };\n");
   fprintf(fp_cpp, "  uint r = resources_used();\n");
   fprintf(fp_cpp, "  if (r) {\n");
   fprintf(fp_cpp, "    tty->print(\"%%sresource%%s:\", needs_comma ? \", \" : \"\", (r & (r-1)) != 0 ? \"s\" : \"\");\n");
   fprintf(fp_cpp, "    for (uint i = 0; i < %d; i++)\n", _pipeline->_rescount);
   fprintf(fp_cpp, "      if ((r & (1 << i)) != 0)\n");
   fprintf(fp_cpp, "        tty->print(\" %%s\", resource_names[i]);\n");
   fprintf(fp_cpp, "    needs_comma = true;\n");
   fprintf(fp_cpp, "  };\n");
   fprintf(fp_cpp, "  tty->print(\"\\n\");\n");
   fprintf(fp_cpp, "}\n");
   fprintf(fp_cpp, "#endif\n");
 }
 // ---------------------------------------------------------------------------
 //------------------------------Utilities to build Instruction Classes--------
 // ---------------------------------------------------------------------------
 static void defineOut_RegMask(FILE *fp, const char *node, const char *regMask) {
   fprintf(fp,"const RegMask &%sNode::out_RegMask() const { return (%s); }\n",
           node, regMask);
 }
 // Scan the peepmatch and output a test for each instruction
 static void check_peepmatch_instruction_tree(FILE *fp, PeepMatch *pmatch, PeepConstraint *pconstraint) {
   intptr_t   parent        = -1;
   intptr_t   inst_position = 0;
   const char *inst_name    = NULL;
   intptr_t   input         = 0;
   fprintf(fp, "      // Check instruction sub-tree\n");
   pmatch->reset();
   for( pmatch->next_instruction( parent, inst_position, inst_name, input );
        inst_name != NULL;
        pmatch->next_instruction( parent, inst_position, inst_name, input ) ) {
     // If this is not a placeholder
     if( ! pmatch->is_placeholder() ) {
       // Define temporaries 'inst#', based on parent and parent's input index
       if( parent != -1 ) {                // root was initialized
         fprintf(fp, "  inst%ld = inst%ld->in(%ld);\n",
                 inst_position, parent, input);
       }
       // When not the root
       // Test we have the correct instruction by comparing the rule
       if( parent != -1 ) {
         fprintf(fp, "  matches = matches &&  ( inst%ld->rule() == %s_rule );",
                 inst_position, inst_name);
       }
     } else {
       // Check that user did not try to constrain a placeholder
       assert( ! pconstraint->constrains_instruction(inst_position),
               "fatal(): Can not constrain a placeholder instruction");
     }
   }
 }
 static void print_block_index(FILE *fp, intptr_t inst_position) {
   assert( inst_position >= 0, "Instruction number less than zero");
   fprintf(fp, "block_index");
   if( inst_position != 0 ) {
     fprintf(fp, " - %ld", inst_position);
   }
 }
 // Scan the peepmatch and output a test for each instruction
 static void check_peepmatch_instruction_sequence(FILE *fp, PeepMatch *pmatch, PeepConstraint *pconstraint) {
   intptr_t   parent        = -1;
   intptr_t   inst_position = 0;
   const char *inst_name    = NULL;
   intptr_t   input         = 0;
   fprintf(fp, "  // Check instruction sub-tree\n");
   pmatch->reset();
   for( pmatch->next_instruction( parent, inst_position, inst_name, input );
        inst_name != NULL;
        pmatch->next_instruction( parent, inst_position, inst_name, input ) ) {
     // If this is not a placeholder
     if( ! pmatch->is_placeholder() ) {
       // Define temporaries 'inst#', based on parent and parent's input index
       if( parent != -1 ) {                // root was initialized
         fprintf(fp, "  // Identify previous instruction if inside this block\n");
         fprintf(fp, "  if( ");
         print_block_index(fp, inst_position);
         fprintf(fp, " > 0 ) {\n    Node *n = block->_nodes.at(");
         print_block_index(fp, inst_position);
         fprintf(fp, ");\n    inst%ld = (n->is_Mach()) ? ", inst_position);
         fprintf(fp, "n->as_Mach() : NULL;\n  }\n");
       }
       // When not the root
       // Test we have the correct instruction by comparing the rule.
       if( parent != -1 ) {
         fprintf(fp, "  matches = matches && (inst%ld != NULL) && (inst%ld->rule() == %s_rule);\n",
                 inst_position, inst_position, inst_name);
       }
     } else {
       // Check that user did not try to constrain a placeholder
       assert( ! pconstraint->constrains_instruction(inst_position),
               "fatal(): Can not constrain a placeholder instruction");
     }
   }
 }
 // Build mapping for register indices, num_edges to input
 static void build_instruction_index_mapping( FILE *fp, FormDict &globals, PeepMatch *pmatch ) {
   intptr_t   parent        = -1;
   intptr_t   inst_position = 0;
   const char *inst_name    = NULL;
   intptr_t   input         = 0;
   fprintf(fp, "      // Build map to register info\n");
   pmatch->reset();
   for( pmatch->next_instruction( parent, inst_position, inst_name, input );
        inst_name != NULL;
        pmatch->next_instruction( parent, inst_position, inst_name, input ) ) {
     // If this is not a placeholder
     if( ! pmatch->is_placeholder() ) {
       // Define temporaries 'inst#', based on self's inst_position
       InstructForm *inst = globals[inst_name]->is_instruction();
       if( inst != NULL ) {
         char inst_prefix[]  = "instXXXX_";
         sprintf(inst_prefix, "inst%ld_",   inst_position);
         char receiver[]     = "instXXXX->";
         sprintf(receiver,    "inst%ld->", inst_position);
         inst->index_temps( fp, globals, inst_prefix, receiver );
       }
     }
   }
 }
 // Generate tests for the constraints
 static void check_peepconstraints(FILE *fp, FormDict &globals, PeepMatch *pmatch, PeepConstraint *pconstraint) {
   fprintf(fp, "\n");
   fprintf(fp, "      // Check constraints on sub-tree-leaves\n");
   // Build mapping from num_edges to local variables
   build_instruction_index_mapping( fp, globals, pmatch );
   // Build constraint tests
   if( pconstraint != NULL ) {
     fprintf(fp, "      matches = matches &&");
     bool   first_constraint = true;
     while( pconstraint != NULL ) {
       // indentation and connecting '&&'
       const char *indentation = "      ";
       fprintf(fp, "\n%s%s", indentation, (!first_constraint ? "&& " : "  "));
       // Only have '==' relation implemented
       if( strcmp(pconstraint->_relation,"==") != 0 ) {
         assert( false, "Unimplemented()" );
       }
       // LEFT
       intptr_t left_index  = pconstraint->_left_inst;
       const char *left_op  = pconstraint->_left_op;
       // Access info on the instructions whose operands are compared
       InstructForm *inst_left = globals[pmatch->instruction_name(left_index)]->is_instruction();
       assert( inst_left, "Parser should guaranty this is an instruction");
       int left_op_base  = inst_left->oper_input_base(globals);
       // Access info on the operands being compared
       int left_op_index  = inst_left->operand_position(left_op, Component::USE);
       if( left_op_index == -1 ) {
         left_op_index = inst_left->operand_position(left_op, Component::DEF);
         if( left_op_index == -1 ) {
           left_op_index = inst_left->operand_position(left_op, Component::USE_DEF);
         }
       }
       assert( left_op_index  != NameList::Not_in_list, "Did not find operand in instruction");
       ComponentList components_left = inst_left->_components;
       const char *left_comp_type = components_left.at(left_op_index)->_type;
       OpClassForm *left_opclass = globals[left_comp_type]->is_opclass();
       Form::InterfaceType left_interface_type = left_opclass->interface_type(globals);
       // RIGHT
       int right_op_index = -1;
       intptr_t right_index = pconstraint->_right_inst;
       const char *right_op = pconstraint->_right_op;
       if( right_index != -1 ) { // Match operand
         // Access info on the instructions whose operands are compared
         InstructForm *inst_right = globals[pmatch->instruction_name(right_index)]->is_instruction();
         assert( inst_right, "Parser should guaranty this is an instruction");
         int right_op_base = inst_right->oper_input_base(globals);
         // Access info on the operands being compared
         right_op_index = inst_right->operand_position(right_op, Component::USE);
         if( right_op_index == -1 ) {
           right_op_index = inst_right->operand_position(right_op, Component::DEF);
           if( right_op_index == -1 ) {
             right_op_index = inst_right->operand_position(right_op, Component::USE_DEF);
           }
         }
         assert( right_op_index != NameList::Not_in_list, "Did not find operand in instruction");
         ComponentList components_right = inst_right->_components;
         const char *right_comp_type = components_right.at(right_op_index)->_type;
         OpClassForm *right_opclass = globals[right_comp_type]->is_opclass();
         Form::InterfaceType right_interface_type = right_opclass->interface_type(globals);
         assert( right_interface_type == left_interface_type, "Both must be same interface");
       } else {                  // Else match register
         // assert( false, "should be a register" );
       }
       //
       // Check for equivalence
       //
       // fprintf(fp, "phase->eqv( ");
       // fprintf(fp, "inst%d->in(%d+%d) /* %s */, inst%d->in(%d+%d) /* %s */",
       //         left_index,  left_op_base,  left_op_index,  left_op,
       //         right_index, right_op_base, right_op_index, right_op );
       // fprintf(fp, ")");
       //
       switch( left_interface_type ) {
       case Form::register_interface: {
         // Check that they are allocated to the same register
         // Need parameter for index position if not result operand
         char left_reg_index[] = ",instXXXX_idxXXXX";
         if( left_op_index != 0 ) {
           assert( (left_index <= 9999) && (left_op_index <= 9999), "exceed string size");
           // Must have index into operands
           sprintf(left_reg_index,",inst%d_idx%d", left_index, left_op_index);
         } else {
           strcpy(left_reg_index, "");
         }
         fprintf(fp, "(inst%d->_opnds[%d]->reg(ra_,inst%d%s)  /* %d.%s */",
                 left_index,  left_op_index, left_index, left_reg_index, left_index, left_op );
         fprintf(fp, " == ");
         if( right_index != -1 ) {
           char right_reg_index[18] = ",instXXXX_idxXXXX";
           if( right_op_index != 0 ) {
             assert( (right_index <= 9999) && (right_op_index <= 9999), "exceed string size");
             // Must have index into operands
             sprintf(right_reg_index,",inst%d_idx%d", right_index, right_op_index);
           } else {
             strcpy(right_reg_index, "");
           }
           fprintf(fp, "/* %d.%s */ inst%d->_opnds[%d]->reg(ra_,inst%d%s)",
                   right_index, right_op, right_index, right_op_index, right_index, right_reg_index );
         } else {
           fprintf(fp, "%s_enc", right_op );
         }
         fprintf(fp,")");
         break;
       }
       case Form::constant_interface: {
         // Compare the '->constant()' values
         fprintf(fp, "(inst%d->_opnds[%d]->constant()  /* %d.%s */",
                 left_index,  left_op_index,  left_index, left_op );
         fprintf(fp, " == ");
         fprintf(fp, "/* %d.%s */ inst%d->_opnds[%d]->constant())",
                 right_index, right_op, right_index, right_op_index );
         break;
       }
       case Form::memory_interface: {
         // Compare 'base', 'index', 'scale', and 'disp'
         // base
         fprintf(fp, "( \n");
         fprintf(fp, "  (inst%d->_opnds[%d]->base(ra_,inst%d,inst%d_idx%d)  /* %d.%s$$base */",
           left_index, left_op_index, left_index, left_index, left_op_index, left_index, left_op );
         fprintf(fp, " == ");
         fprintf(fp, "/* %d.%s$$base */ inst%d->_opnds[%d]->base(ra_,inst%d,inst%d_idx%d)) &&\n",
                 right_index, right_op, right_index, right_op_index, right_index, right_index, right_op_index );
         // index
         fprintf(fp, "  (inst%d->_opnds[%d]->index(ra_,inst%d,inst%d_idx%d)  /* %d.%s$$index */",
                 left_index, left_op_index, left_index, left_index, left_op_index, left_index, left_op );
         fprintf(fp, " == ");
         fprintf(fp, "/* %d.%s$$index */ inst%d->_opnds[%d]->index(ra_,inst%d,inst%d_idx%d)) &&\n",
                 right_index, right_op, right_index, right_op_index, right_index, right_index, right_op_index );
         // scale
         fprintf(fp, "  (inst%d->_opnds[%d]->scale()  /* %d.%s$$scale */",
                 left_index,  left_op_index,  left_index, left_op );
         fprintf(fp, " == ");
         fprintf(fp, "/* %d.%s$$scale */ inst%d->_opnds[%d]->scale()) &&\n",
                 right_index, right_op, right_index, right_op_index );
         // disp
         fprintf(fp, "  (inst%d->_opnds[%d]->disp(ra_,inst%d,inst%d_idx%d)  /* %d.%s$$disp */",
                 left_index, left_op_index, left_index, left_index, left_op_index, left_index, left_op );
         fprintf(fp, " == ");
         fprintf(fp, "/* %d.%s$$disp */ inst%d->_opnds[%d]->disp(ra_,inst%d,inst%d_idx%d))\n",
                 right_index, right_op, right_index, right_op_index, right_index, right_index, right_op_index );
         fprintf(fp, ") \n");
         break;
       }
       case Form::conditional_interface: {
         // Compare the condition code being tested
         assert( false, "Unimplemented()" );
         break;
       }
       default: {
         assert( false, "ShouldNotReachHere()" );
         break;
       }
       }
       // Advance to next constraint
       pconstraint = pconstraint->next();
       first_constraint = false;
     }
     fprintf(fp, ";\n");
   }
 }
 // // EXPERIMENTAL -- TEMPORARY code
 // static Form::DataType get_operand_type(FormDict &globals, InstructForm *instr, const char *op_name ) {
 //   int op_index = instr->operand_position(op_name, Component::USE);
 //   if( op_index == -1 ) {
 //     op_index = instr->operand_position(op_name, Component::DEF);
 //     if( op_index == -1 ) {
 //       op_index = instr->operand_position(op_name, Component::USE_DEF);
 //     }
 //   }
 //   assert( op_index != NameList::Not_in_list, "Did not find operand in instruction");
 //
 //   ComponentList components_right = instr->_components;
 //   char *right_comp_type = components_right.at(op_index)->_type;
 //   OpClassForm *right_opclass = globals[right_comp_type]->is_opclass();
 //   Form::InterfaceType  right_interface_type = right_opclass->interface_type(globals);
 //
 //   return;
 // }
 // Construct the new sub-tree
 static void generate_peepreplace( FILE *fp, FormDict &globals, PeepMatch *pmatch, PeepConstraint *pconstraint, PeepReplace *preplace, int max_position ) {
   fprintf(fp, "      // IF instructions and constraints matched\n");
   fprintf(fp, "      if( matches ) {\n");
   fprintf(fp, "        // generate the new sub-tree\n");
   fprintf(fp, "        assert( true, \"Debug stopping point\");\n");
   if( preplace != NULL ) {
     // Get the root of the new sub-tree
     const char *root_inst = NULL;
     preplace->next_instruction(root_inst);
     InstructForm *root_form = globals[root_inst]->is_instruction();
     assert( root_form != NULL, "Replacement instruction was not previously defined");
     fprintf(fp, "        %sNode *root = new (C) %sNode();\n", root_inst, root_inst);
     intptr_t    inst_num;
     const char *op_name;
     int         opnds_index = 0;            // define result operand
     // Then install the use-operands for the new sub-tree
     // preplace->reset();             // reset breaks iteration
     for( preplace->next_operand( inst_num, op_name );
          op_name != NULL;
          preplace->next_operand( inst_num, op_name ) ) {
       InstructForm *inst_form;
       inst_form  = globals[pmatch->instruction_name(inst_num)]->is_instruction();
       assert( inst_form, "Parser should guaranty this is an instruction");
       int op_base     = inst_form->oper_input_base(globals);
       int inst_op_num = inst_form->operand_position(op_name, Component::USE);
       if( inst_op_num == NameList::Not_in_list )
         inst_op_num = inst_form->operand_position(op_name, Component::USE_DEF);
       assert( inst_op_num != NameList::Not_in_list, "Did not find operand as USE");
       // find the name of the OperandForm from the local name
       const Form *form   = inst_form->_localNames[op_name];
       OperandForm  *op_form = form->is_operand();
       if( opnds_index == 0 ) {
         // Initial setup of new instruction
         fprintf(fp, "        // ----- Initial setup -----\n");
         //
         // Add control edge for this node
         fprintf(fp, "        root->add_req(_in[0]);                // control edge\n");
         // Add unmatched edges from root of match tree
         int op_base = root_form->oper_input_base(globals);
         for( int unmatched_edge = 1; unmatched_edge < op_base; ++unmatched_edge ) {
           fprintf(fp, "        root->add_req(inst%ld->in(%d));        // unmatched ideal edge\n",
                                           inst_num, unmatched_edge);
         }
         // If new instruction captures bottom type
         if( root_form->captures_bottom_type() ) {
           // Get bottom type from instruction whose result we are replacing
           fprintf(fp, "        root->_bottom_type = inst%ld->bottom_type();\n", inst_num);
         }
         // Define result register and result operand
         fprintf(fp, "        ra_->add_reference(root, inst%ld);\n", inst_num);
         fprintf(fp, "        ra_->set_oop (root, ra_->is_oop(inst%ld));\n", inst_num);
         fprintf(fp, "        ra_->set_pair(root->_idx, ra_->get_reg_second(inst%ld), ra_->get_reg_first(inst%ld));\n", inst_num, inst_num);
         fprintf(fp, "        root->_opnds[0] = inst%ld->_opnds[0]->clone(C); // result\n", inst_num);
         fprintf(fp, "        // ----- Done with initial setup -----\n");
       } else {
         if( (op_form == NULL) || (op_form->is_base_constant(globals) == Form::none) ) {
           // Do not have ideal edges for constants after matching
           fprintf(fp, "        for( unsigned x%d = inst%ld_idx%d; x%d < inst%ld_idx%d; x%d++ )\n",
                   inst_op_num, inst_num, inst_op_num,
                   inst_op_num, inst_num, inst_op_num+1, inst_op_num );
           fprintf(fp, "          root->add_req( inst%ld->in(x%d) );\n",
                   inst_num, inst_op_num );
         } else {
           fprintf(fp, "        // no ideal edge for constants after matching\n");
         }
         fprintf(fp, "        root->_opnds[%d] = inst%ld->_opnds[%d]->clone(C);\n",
                 opnds_index, inst_num, inst_op_num );
       }
       ++opnds_index;
     }
   }else {
     // Replacing subtree with empty-tree
     assert( false, "ShouldNotReachHere();");
   }
   // Return the new sub-tree
   fprintf(fp, "        deleted = %d;\n", max_position+1 /*zero to one based*/);
   fprintf(fp, "        return root;  // return new root;\n");
   fprintf(fp, "      }\n");
 }
 // Define the Peephole method for an instruction node
 void ArchDesc::definePeephole(FILE *fp, InstructForm *node) {
   // Generate Peephole function header
   fprintf(fp, "MachNode *%sNode::peephole( Block *block, int block_index, PhaseRegAlloc *ra_, int &deleted, Compile* C ) {\n", node->_ident);
   fprintf(fp, "  bool  matches = true;\n");
   // Identify the maximum instruction position,
   // generate temporaries that hold current instruction
   //
   //   MachNode  *inst0 = NULL;
   //   ...
   //   MachNode  *instMAX = NULL;
   //
   int max_position = 0;
   Peephole *peep;
   for( peep = node->peepholes(); peep != NULL; peep = peep->next() ) {
     PeepMatch *pmatch = peep->match();
     assert( pmatch != NULL, "fatal(), missing peepmatch rule");
     if( max_position < pmatch->max_position() )  max_position = pmatch->max_position();
   }
   for( int i = 0; i <= max_position; ++i ) {
     if( i == 0 ) {
       fprintf(fp, "  MachNode *inst0 = this;\n", i);
     } else {
       fprintf(fp, "  MachNode *inst%d = NULL;\n", i);
     }
   }
   // For each peephole rule in architecture description
   //   Construct a test for the desired instruction sub-tree
   //   then check the constraints
   //   If these match, Generate the new subtree
   for( peep = node->peepholes(); peep != NULL; peep = peep->next() ) {
     int         peephole_number = peep->peephole_number();
     PeepMatch      *pmatch      = peep->match();
     PeepConstraint *pconstraint = peep->constraints();
     PeepReplace    *preplace    = peep->replacement();
     // Root of this peephole is the current MachNode
     assert( true, // %%name?%% strcmp( node->_ident, pmatch->name(0) ) == 0,
             "root of PeepMatch does not match instruction");
     // Make each peephole rule individually selectable
     fprintf(fp, "  if( (OptoPeepholeAt == -1) || (OptoPeepholeAt==%d) ) {\n", peephole_number);
     fprintf(fp, "    matches = true;\n");
     // Scan the peepmatch and output a test for each instruction
     check_peepmatch_instruction_sequence( fp, pmatch, pconstraint );
     // Check constraints and build replacement inside scope
     fprintf(fp, "    // If instruction subtree matches\n");
     fprintf(fp, "    if( matches ) {\n");
     // Generate tests for the constraints
     check_peepconstraints( fp, _globalNames, pmatch, pconstraint );
     // Construct the new sub-tree
     generate_peepreplace( fp, _globalNames, pmatch, pconstraint, preplace, max_position );
     // End of scope for this peephole's constraints
     fprintf(fp, "    }\n");
     // Closing brace '}' to make each peephole rule individually selectable
     fprintf(fp, "  } // end of peephole rule #%d\n", peephole_number);
     fprintf(fp, "\n");
   }
   fprintf(fp, "  return NULL;  // No peephole rules matched\n");
   fprintf(fp, "}\n");
   fprintf(fp, "\n");
 }
 // Define the Expand method for an instruction node
 void ArchDesc::defineExpand(FILE *fp, InstructForm *node) {
   unsigned      cnt  = 0;          // Count nodes we have expand into
   unsigned      i;
   // Generate Expand function header
   fprintf(fp,"MachNode *%sNode::Expand(State *state, Node_List &proj_list) {\n", node->_ident);
   fprintf(fp,"Compile* C = Compile::current();\n");
   // Generate expand code
   if( node->expands() ) {
     const char   *opid;
     int           new_pos, exp_pos;
     const char   *new_id   = NULL;
     const Form   *frm      = NULL;
     InstructForm *new_inst = NULL;
     OperandForm  *new_oper = NULL;
     unsigned      numo     = node->num_opnds() +
                                 node->_exprule->_newopers.count();
     // If necessary, generate any operands created in expand rule
     if (node->_exprule->_newopers.count()) {
       for(node->_exprule->_newopers.reset();
           (new_id = node->_exprule->_newopers.iter()) != NULL; cnt++) {
         frm = node->_localNames[new_id];
         assert(frm, "Invalid entry in new operands list of expand rule");
         new_oper = frm->is_operand();
         char *tmp = (char *)node->_exprule->_newopconst[new_id];
         if (tmp == NULL) {
           fprintf(fp,"  MachOper *op%d = new (C) %sOper();\n",
                   cnt, new_oper->_ident);
         }
         else {
           fprintf(fp,"  MachOper *op%d = new (C) %sOper(%s);\n",
                   cnt, new_oper->_ident, tmp);
         }
       }
     }
     cnt = 0;
     // Generate the temps to use for DAG building
     for(i = 0; i < numo; i++) {
       if (i < node->num_opnds()) {
         fprintf(fp,"  MachNode *tmp%d = this;\n", i);
       }
       else {
         fprintf(fp,"  MachNode *tmp%d = NULL;\n", i);
       }
     }
     // Build mapping from num_edges to local variables
     fprintf(fp,"  unsigned num0 = 0;\n");
     for( i = 1; i < node->num_opnds(); i++ ) {
       fprintf(fp,"  unsigned num%d = opnd_array(%d)->num_edges();\n",i,i);
     }
     // Build a mapping from operand index to input edges
     fprintf(fp,"  unsigned idx0 = oper_input_base();\n");
     for( i = 0; i < node->num_opnds(); i++ ) {
       fprintf(fp,"  unsigned idx%d = idx%d + num%d;\n",
               i+1,i,i);
     }
     // Declare variable to hold root of expansion
     fprintf(fp,"  MachNode *result = NULL;\n");
     // Iterate over the instructions 'node' expands into
     ExpandRule  *expand       = node->_exprule;
     NameAndList *expand_instr = NULL;
     for(expand->reset_instructions();
         (expand_instr = expand->iter_instructions()) != NULL; cnt++) {
       new_id = expand_instr->name();
       InstructForm* expand_instruction = (InstructForm*)globalAD->globalNames()[new_id];
       if (expand_instruction->has_temps()) {
         globalAD->syntax_err(node->_linenum, "In %s: expand rules using instructs with TEMPs aren't supported: %s",
                              node->_ident, new_id);
       }
       // Build the node for the instruction
       fprintf(fp,"\n  %sNode *n%d = new (C) %sNode();\n", new_id, cnt, new_id);
       // Add control edge for this node
       fprintf(fp,"  n%d->add_req(_in[0]);\n", cnt);
       // Build the operand for the value this node defines.
       Form *form = (Form*)_globalNames[new_id];
       assert( form, "'new_id' must be a defined form name");
       // Grab the InstructForm for the new instruction
       new_inst = form->is_instruction();
       assert( new_inst, "'new_id' must be an instruction name");
       if( node->is_ideal_if() && new_inst->is_ideal_if() ) {
         fprintf(fp, "  ((MachIfNode*)n%d)->_prob = _prob;\n",cnt);
         fprintf(fp, "  ((MachIfNode*)n%d)->_fcnt = _fcnt;\n",cnt);
       }
       if( node->is_ideal_fastlock() && new_inst->is_ideal_fastlock() ) {
         fprintf(fp, "  ((MachFastLockNode*)n%d)->_counters = _counters;\n",cnt);
       }
       const char *resultOper = new_inst->reduce_result();
       fprintf(fp,"  n%d->set_opnd_array(0, state->MachOperGenerator( %s, C ));\n",
               cnt, machOperEnum(resultOper));
       // get the formal operand NameList
       NameList *formal_lst = &new_inst->_parameters;
       formal_lst->reset();
       // Handle any memory operand
       int memory_operand = new_inst->memory_operand(_globalNames);
       if( memory_operand != InstructForm::NO_MEMORY_OPERAND ) {
         int node_mem_op = node->memory_operand(_globalNames);
         assert( node_mem_op != InstructForm::NO_MEMORY_OPERAND,
                 "expand rule member needs memory but top-level inst doesn't have any" );
         // Copy memory edge
         fprintf(fp,"  n%d->add_req(_in[1]);\t// Add memory edge\n", cnt);
       }
       // Iterate over the new instruction's operands
       for( expand_instr->reset(); (opid = expand_instr->iter()) != NULL; ) {
         // Use 'parameter' at current position in list of new instruction's formals
         // instead of 'opid' when looking up info internal to new_inst
         const char *parameter = formal_lst->iter();
         // Check for an operand which is created in the expand rule
         if ((exp_pos = node->_exprule->_newopers.index(opid)) != -1) {
           new_pos = new_inst->operand_position(parameter,Component::USE);
           exp_pos += node->num_opnds();
           // If there is no use of the created operand, just skip it
           if (new_pos != -1) {
             //Copy the operand from the original made above
             fprintf(fp,"  n%d->set_opnd_array(%d, op%d->clone(C)); // %s\n",
                     cnt, new_pos, exp_pos-node->num_opnds(), opid);
             // Check for who defines this operand & add edge if needed
             fprintf(fp,"  if(tmp%d != NULL)\n", exp_pos);
             fprintf(fp,"    n%d->add_req(tmp%d);\n", cnt, exp_pos);
           }
         }
         else {
           // Use operand name to get an index into instruction component list
           // ins = (InstructForm *) _globalNames[new_id];
           exp_pos = node->operand_position_format(opid);
           assert(exp_pos != -1, "Bad expand rule");
           new_pos = new_inst->operand_position(parameter,Component::USE);
           if (new_pos != -1) {
             // Copy the operand from the ExpandNode to the new node
             fprintf(fp,"  n%d->set_opnd_array(%d, opnd_array(%d)->clone(C)); // %s\n",
                     cnt, new_pos, exp_pos, opid);
             // For each operand add appropriate input edges by looking at tmp's
             fprintf(fp,"  if(tmp%d == this) {\n", exp_pos);
             // Grab corresponding edges from ExpandNode and insert them here
             fprintf(fp,"    for(unsigned i = 0; i < num%d; i++) {\n", exp_pos);
             fprintf(fp,"      n%d->add_req(_in[i + idx%d]);\n", cnt, exp_pos);
             fprintf(fp,"    }\n");
             fprintf(fp,"  }\n");
             // This value is generated by one of the new instructions
             fprintf(fp,"  else n%d->add_req(tmp%d);\n", cnt, exp_pos);
           }
         }
         // Update the DAG tmp's for values defined by this instruction
         int new_def_pos = new_inst->operand_position(parameter,Component::DEF);
         Effect *eform = (Effect *)new_inst->_effects[parameter];
         // If this operand is a definition in either an effects rule
         // or a match rule
         if((eform) && (is_def(eform->_use_def))) {
           // Update the temp associated with this operand
           fprintf(fp,"  tmp%d = n%d;\n", exp_pos, cnt);
         }
         else if( new_def_pos != -1 ) {
           // Instruction defines a value but user did not declare it
           // in the 'effect' clause
           fprintf(fp,"  tmp%d = n%d;\n", exp_pos, cnt);
         }
       } // done iterating over a new instruction's operands
       // Invoke Expand() for the newly created instruction.
       fprintf(fp,"  result = n%d->Expand( state, proj_list );\n", cnt);
       assert( !new_inst->expands(), "Do not have complete support for recursive expansion");
     } // done iterating over new instructions
     fprintf(fp,"\n");
   } // done generating expand rule
   else if( node->_matrule != NULL ) {
     // Remove duplicated operands and inputs which use the same name.
     // Seach through match operands for the same name usage.
     uint cur_num_opnds = node->num_opnds();
     if( cur_num_opnds > 1 && cur_num_opnds != node->num_unique_opnds() ) {
       Component *comp = NULL;
       // Build mapping from num_edges to local variables
       fprintf(fp,"  unsigned num0 = 0;\n");
       for( i = 1; i < cur_num_opnds; i++ ) {
         fprintf(fp,"  unsigned num%d = opnd_array(%d)->num_edges();\n",i,i);
       }
       // Build a mapping from operand index to input edges
       fprintf(fp,"  unsigned idx0 = oper_input_base();\n");
       for( i = 0; i < cur_num_opnds; i++ ) {
         fprintf(fp,"  unsigned idx%d = idx%d + num%d;\n",
                 i+1,i,i);
       }
       uint new_num_opnds = 1;
       node->_components.reset();
       // Skip first unique operands.
       for( i = 1; i < cur_num_opnds; i++ ) {
         comp = node->_components.iter();
         if( (int)i != node->unique_opnds_idx(i) ) {
           break;
         }
         new_num_opnds++;
       }
       // Replace not unique operands with next unique operands.
       for( ; i < cur_num_opnds; i++ ) {
         comp = node->_components.iter();
         int j = node->unique_opnds_idx(i);
         // unique_opnds_idx(i) is unique if unique_opnds_idx(j) is not unique.
         if( j != node->unique_opnds_idx(j) ) {
           fprintf(fp,"  set_opnd_array(%d, opnd_array(%d)->clone(C)); // %s\n",
                   new_num_opnds, i, comp->_name);
           // delete not unique edges here
           fprintf(fp,"  for(unsigned i = 0; i < num%d; i++) {\n", i);
           fprintf(fp,"    set_req(i + idx%d, _in[i + idx%d]);\n", new_num_opnds, i);
           fprintf(fp,"  }\n");
           fprintf(fp,"  num%d = num%d;\n", new_num_opnds, i);
           fprintf(fp,"  idx%d = idx%d + num%d;\n", new_num_opnds+1, new_num_opnds, new_num_opnds);
           new_num_opnds++;
         }
       }
       // delete the rest of edges
       fprintf(fp,"  for(int i = idx%d - 1; i >= (int)idx%d; i--) {\n", cur_num_opnds, new_num_opnds);
       fprintf(fp,"    del_req(i);\n", i);
       fprintf(fp,"  }\n");
       fprintf(fp,"  _num_opnds = %d;\n", new_num_opnds);
     }
   }
   // Generate projections for instruction's additional DEFs and KILLs
   if( ! node->expands() && (node->needs_projections() || node->has_temps())) {
     // Get string representing the MachNode that projections point at
     const char *machNode = "this";
     // Generate the projections
     fprintf(fp,"  // Add projection edges for additional defs or kills\n");
     // Examine each component to see if it is a DEF or KILL
     node->_components.reset();
     // Skip the first component, if already handled as (SET dst (...))
     Component *comp = NULL;
     // For kills, the choice of projection numbers is arbitrary
     int proj_no = 1;
     bool declared_def  = false;
     bool declared_kill = false;
     while( (comp = node->_components.iter()) != NULL ) {
       // Lookup register class associated with operand type
       Form        *form = (Form*)_globalNames[comp->_type];
       assert( form, "component type must be a defined form");
       OperandForm *op   = form->is_operand();
       if (comp->is(Component::TEMP)) {
         fprintf(fp, "  // TEMP %s\n", comp->_name);
         if (!declared_def) {
           // Define the variable "def" to hold new MachProjNodes
           fprintf(fp, "  MachTempNode *def;\n");
           declared_def = true;
         }
         if (op && op->_interface && op->_interface->is_RegInterface()) {
           fprintf(fp,"  def = new (C) MachTempNode(state->MachOperGenerator( %s, C ));\n",
                   machOperEnum(op->_ident));
           fprintf(fp,"  add_req(def);\n");
           int idx  = node->operand_position_format(comp->_name);
           fprintf(fp,"  set_opnd_array(%d, state->MachOperGenerator( %s, C ));\n",
                   idx, machOperEnum(op->_ident));
         } else {
           assert(false, "can't have temps which aren't registers");
         }
       } else if (comp->isa(Component::KILL)) {
         fprintf(fp, "  // DEF/KILL %s\n", comp->_name);
         if (!declared_kill) {
           // Define the variable "kill" to hold new MachProjNodes
           fprintf(fp, "  MachProjNode *kill;\n");
           declared_kill = true;
         }
         assert( op, "Support additional KILLS for base operands");
         const char *regmask    = reg_mask(*op);
         const char *ideal_type = op->ideal_type(_globalNames, _register);
         if (!op->is_bound_register()) {
           syntax_err(node->_linenum, "In %s only bound registers can be killed: %s %s\n",
                      node->_ident, comp->_type, comp->_name);
         }
         fprintf(fp,"  kill = ");
         fprintf(fp,"new (C, 1) MachProjNode( %s, %d, (%s), Op_%s );\n",
                 machNode, proj_no++, regmask, ideal_type);
         fprintf(fp,"  proj_list.push(kill);\n");
       }
     }
   }
   fprintf(fp,"\n");
   if( node->expands() ) {
     fprintf(fp,"  return result;\n",cnt-1);
   } else {
     fprintf(fp,"  return this;\n");
   }
   fprintf(fp,"}\n");
   fprintf(fp,"\n");
 }
 //------------------------------Emit Routines----------------------------------
 // Special classes and routines for defining node emit routines which output
 // target specific instruction object encodings.
 // Define the ___Node::emit() routine
 //
 // (1) void  ___Node::emit(CodeBuffer &cbuf, PhaseRegAlloc *ra_) const {
 // (2)   // ...  encoding defined by user
 // (3)
 // (4) }
 //
 class DefineEmitState {
 private:
   enum reloc_format { RELOC_NONE        = -1,
                       RELOC_IMMEDIATE   =  0,
                       RELOC_DISP        =  1,
                       RELOC_CALL_DISP   =  2 };
   enum literal_status{ LITERAL_NOT_SEEN  = 0,
                        LITERAL_SEEN      = 1,
                        LITERAL_ACCESSED  = 2,
                        LITERAL_OUTPUT    = 3 };
   // Temporaries that describe current operand
   bool          _cleared;
   OpClassForm  *_opclass;
   OperandForm  *_operand;
   int           _operand_idx;
   const char   *_local_name;
   const char   *_operand_name;
   bool          _doing_disp;
   bool          _doing_constant;
   Form::DataType _constant_type;
   DefineEmitState::literal_status _constant_status;
   DefineEmitState::literal_status _reg_status;
   bool          _doing_emit8;
   bool          _doing_emit_d32;
   bool          _doing_emit_d16;
   bool          _doing_emit_hi;
   bool          _doing_emit_lo;
   bool          _may_reloc;
   bool          _must_reloc;
   reloc_format  _reloc_form;
   const char *  _reloc_type;
   bool          _processing_noninput;
   NameList      _strings_to_emit;
   // Stable state, set by constructor
   ArchDesc     &_AD;
   FILE         *_fp;
   EncClass     &_encoding;
   InsEncode    &_ins_encode;
   InstructForm &_inst;
 public:
   DefineEmitState(FILE *fp, ArchDesc &AD, EncClass &encoding,
                   InsEncode &ins_encode, InstructForm &inst)
     : _AD(AD), _fp(fp), _encoding(encoding), _ins_encode(ins_encode), _inst(inst) {
       clear();
   }
   void clear() {
     _cleared       = true;
     _opclass       = NULL;
     _operand       = NULL;
     _operand_idx   = 0;
     _local_name    = "";
     _operand_name  = "";
     _doing_disp    = false;
     _doing_constant= false;
     _constant_type = Form::none;
     _constant_status = LITERAL_NOT_SEEN;
     _reg_status      = LITERAL_NOT_SEEN;
     _doing_emit8   = false;
     _doing_emit_d32= false;
     _doing_emit_d16= false;
     _doing_emit_hi = false;
     _doing_emit_lo = false;
     _may_reloc     = false;
     _must_reloc    = false;
     _reloc_form    = RELOC_NONE;
     _reloc_type    = AdlcVMDeps::none_reloc_type();
     _strings_to_emit.clear();
   }
   // Track necessary state when identifying a replacement variable
   void update_state(const char *rep_var) {
     // A replacement variable or one of its subfields
     // Obtain replacement variable from list
     if ( (*rep_var) != '$' ) {
       // A replacement variable, '$' prefix
       // check_rep_var( rep_var );
       if ( Opcode::as_opcode_type(rep_var) != Opcode::NOT_AN_OPCODE ) {
         // No state needed.
         assert( _opclass == NULL,
                 "'primary', 'secondary' and 'tertiary' don't follow operand.");
       } else {
         // Lookup its position in parameter list
         int   param_no  = _encoding.rep_var_index(rep_var);
         if ( param_no == -1 ) {
           _AD.syntax_err( _encoding._linenum,
                           "Replacement variable %s not found in enc_class %s.\n",
                           rep_var, _encoding._name);
         }
         // Lookup the corresponding ins_encode parameter
         const char *inst_rep_var = _ins_encode.rep_var_name(_inst, param_no);
         if (inst_rep_var == NULL) {
           _AD.syntax_err( _ins_encode._linenum,
                           "Parameter %s not passed to enc_class %s from instruct %s.\n",
                           rep_var, _encoding._name, _inst._ident);
         }
         // Check if instruction's actual parameter is a local name in the instruction
         const Form  *local     = _inst._localNames[inst_rep_var];
         OpClassForm *opc       = (local != NULL) ? local->is_opclass() : NULL;
         // Note: assert removed to allow constant and symbolic parameters
         // assert( opc, "replacement variable was not found in local names");
         // Lookup the index position iff the replacement variable is a localName
         int idx  = (opc != NULL) ? _inst.operand_position_format(inst_rep_var) : -1;
         if ( idx != -1 ) {
           // This is a local in the instruction
           // Update local state info.
           _opclass        = opc;
           _operand_idx    = idx;
           _local_name     = rep_var;
           _operand_name   = inst_rep_var;
           // !!!!!
           // Do not support consecutive operands.
           assert( _operand == NULL, "Unimplemented()");
           _operand = opc->is_operand();
         }
         else if( ADLParser::is_literal_constant(inst_rep_var) ) {
           // Instruction provided a constant expression
           // Check later that encoding specifies $$$constant to resolve as constant
           _constant_status   = LITERAL_SEEN;
         }
         else if( Opcode::as_opcode_type(inst_rep_var) != Opcode::NOT_AN_OPCODE ) {
           // Instruction provided an opcode: "primary", "secondary", "tertiary"
           // Check later that encoding specifies $$$constant to resolve as constant
           _constant_status   = LITERAL_SEEN;
         }
         else if((_AD.get_registers() != NULL ) && (_AD.get_registers()->getRegDef(inst_rep_var) != NULL)) {
           // Instruction provided a literal register name for this parameter
           // Check that encoding specifies $$$reg to resolve.as register.
           _reg_status        = LITERAL_SEEN;
         }
         else {
           // Check for unimplemented functionality before hard failure
           assert( strcmp(opc->_ident,"label")==0, "Unimplemented() Label");
           assert( false, "ShouldNotReachHere()");
         }
       } // done checking which operand this is.
     } else {
       //
       // A subfield variable, '$$' prefix
       // Check for fields that may require relocation information.
       // Then check that literal register parameters are accessed with 'reg' or 'constant'
       //
       if ( strcmp(rep_var,"$disp") == 0 ) {
         _doing_disp = true;
         assert( _opclass, "Must use operand or operand class before '$disp'");
         if( _operand == NULL ) {
           // Only have an operand class, generate run-time check for relocation
           _may_reloc    = true;
           _reloc_form   = RELOC_DISP;
           _reloc_type   = AdlcVMDeps::oop_reloc_type();
         } else {
           // Do precise check on operand: is it a ConP or not
           //
           // Check interface for value of displacement
           assert( ( _operand->_interface != NULL ),
                   "$disp can only follow memory interface operand");
           MemInterface *mem_interface= _operand->_interface->is_MemInterface();
           assert( mem_interface != NULL,
                   "$disp can only follow memory interface operand");
           const char *disp = mem_interface->_disp;
           if( disp != NULL && (*disp == '$') ) {
             // MemInterface::disp contains a replacement variable,
             // Check if this matches a ConP
             //
             // Lookup replacement variable, in operand's component list
             const char *rep_var_name = disp + 1; // Skip '$'
             const Component *comp = _operand->_components.search(rep_var_name);
             assert( comp != NULL,"Replacement variable not found in components");
             const char      *type = comp->_type;
             // Lookup operand form for replacement variable's type
             const Form *form = _AD.globalNames()[type];
             assert( form != NULL, "Replacement variable's type not found");
             OperandForm *op = form->is_operand();
             assert( op, "Attempting to emit a non-register or non-constant");
             // Check if this is a constant
             if (op->_matrule && op->_matrule->is_base_constant(_AD.globalNames())) {
               // Check which constant this name maps to: _c0, _c1, ..., _cn
               // const int idx = _operand.constant_position(_AD.globalNames(), comp);
               // assert( idx != -1, "Constant component not found in operand");
               Form::DataType dtype = op->is_base_constant(_AD.globalNames());
               if ( dtype == Form::idealP ) {
                 _may_reloc    = true;
                 // No longer true that idealP is always an oop
                 _reloc_form   = RELOC_DISP;
                 _reloc_type   = AdlcVMDeps::oop_reloc_type();
               }
             }
             else if( _operand->is_user_name_for_sReg() != Form::none ) {
               // The only non-constant allowed access to disp is an operand sRegX in a stackSlotX
               assert( op->ideal_to_sReg_type(type) != Form::none, "StackSlots access displacements using 'sRegs'");
               _may_reloc   = false;
             } else {
               assert( false, "fatal(); Only stackSlots can access a non-constant using 'disp'");
             }
           }
         } // finished with precise check of operand for relocation.
       } // finished with subfield variable
       else if ( strcmp(rep_var,"$constant") == 0 ) {
         _doing_constant = true;
         if ( _constant_status == LITERAL_NOT_SEEN ) {
           // Check operand for type of constant
           assert( _operand, "Must use operand before '$$constant'");
           Form::DataType dtype = _operand->is_base_constant(_AD.globalNames());
           _constant_type = dtype;
           if ( dtype == Form::idealP ) {
             _may_reloc    = true;
             // No longer true that idealP is always an oop
             // // _must_reloc   = true;
             _reloc_form   = RELOC_IMMEDIATE;
             _reloc_type   = AdlcVMDeps::oop_reloc_type();
           } else {
             // No relocation information needed
           }
         } else {
           // User-provided literals may not require relocation information !!!!!
           assert( _constant_status == LITERAL_SEEN, "Must know we are processing a user-provided literal");
         }
       }
       else if ( strcmp(rep_var,"$label") == 0 ) {
         // Calls containing labels require relocation
         if ( _inst.is_ideal_call() )  {
           _may_reloc    = true;
           // !!!!! !!!!!
           _reloc_type   = AdlcVMDeps::none_reloc_type();
         }
       }
       // literal register parameter must be accessed as a 'reg' field.
       if ( _reg_status != LITERAL_NOT_SEEN ) {
         assert( _reg_status == LITERAL_SEEN, "Must have seen register literal before now");
         if (strcmp(rep_var,"$reg") == 0 || reg_conversion(rep_var) != NULL) {
           _reg_status  = LITERAL_ACCESSED;
         } else {
           assert( false, "invalid access to literal register parameter");
         }
       }
       // literal constant parameters must be accessed as a 'constant' field
       if ( _constant_status != LITERAL_NOT_SEEN ) {
         assert( _constant_status == LITERAL_SEEN, "Must have seen constant literal before now");
         if( strcmp(rep_var,"$constant") == 0 ) {
           _constant_status  = LITERAL_ACCESSED;
         } else {
           assert( false, "invalid access to literal constant parameter");
         }
       }
     } // end replacement and/or subfield
   }
   void add_rep_var(const char *rep_var) {
     // Handle subfield and replacement variables.
     if ( ( *rep_var == '$' ) && ( *(rep_var+1) == '$' ) ) {
       // Check for emit prefix, '$$emit32'
       assert( _cleared, "Can not nest $$$emit32");
       if ( strcmp(rep_var,"$$emit32") == 0 ) {
         _doing_emit_d32 = true;
       }
       else if ( strcmp(rep_var,"$$emit16") == 0 ) {
         _doing_emit_d16 = true;
       }
       else if ( strcmp(rep_var,"$$emit_hi") == 0 ) {
         _doing_emit_hi  = true;
       }
       else if ( strcmp(rep_var,"$$emit_lo") == 0 ) {
         _doing_emit_lo  = true;
       }
       else if ( strcmp(rep_var,"$$emit8") == 0 ) {
         _doing_emit8    = true;
       }
       else {
         _AD.syntax_err(_encoding._linenum, "Unsupported $$operation '%s'\n",rep_var);
         assert( false, "fatal();");
       }
     }
     else {
       // Update state for replacement variables
       update_state( rep_var );
       _strings_to_emit.addName(rep_var);
     }
     _cleared  = false;
   }
   void emit_replacement() {
     // A replacement variable or one of its subfields
     // Obtain replacement variable from list
     // const char *ec_rep_var = encoding->_rep_vars.iter();
     const char *rep_var;
     _strings_to_emit.reset();
     while ( (rep_var = _strings_to_emit.iter()) != NULL ) {
       if ( (*rep_var) == '$' ) {
         // A subfield variable, '$$' prefix
         emit_field( rep_var );
       } else {
         // A replacement variable, '$' prefix
         emit_rep_var( rep_var );
       } // end replacement and/or subfield
     }
   }
   void emit_reloc_type(const char* type) {
     fprintf(_fp, "%s", type)
       ;
   }
   void gen_emit_x_reloc(const char *d32_lo_hi ) {
     fprintf(_fp,"emit_%s_reloc(cbuf, ", d32_lo_hi );
     emit_replacement();             fprintf(_fp,", ");
     emit_reloc_type( _reloc_type ); fprintf(_fp,", ");
     fprintf(_fp, "%d", _reloc_form);fprintf(_fp, ");");
   }
   void emit() {
     //
     //   "emit_d32_reloc(" or "emit_hi_reloc" or "emit_lo_reloc"
     //
     // Emit the function name when generating an emit function
     if ( _doing_emit_d32 || _doing_emit_hi || _doing_emit_lo ) {
       const char *d32_hi_lo = _doing_emit_d32 ? "d32" : (_doing_emit_hi ? "hi" : "lo");
       // In general, relocatable isn't known at compiler compile time.
       // Check results of prior scan
       if ( ! _may_reloc ) {
         // Definitely don't need relocation information
         fprintf( _fp, "emit_%s(cbuf, ", d32_hi_lo );
         emit_replacement(); fprintf(_fp, ")");
       }
       else if ( _must_reloc ) {
         // Must emit relocation information
         gen_emit_x_reloc( d32_hi_lo );
       }
       else {
         // Emit RUNTIME CHECK to see if value needs relocation info
         // If emitting a relocatable address, use 'emit_d32_reloc'
         const char *disp_constant = _doing_disp ? "disp" : _doing_constant ? "constant" : "INVALID";
         assert( (_doing_disp || _doing_constant)
                 && !(_doing_disp && _doing_constant),
                 "Must be emitting either a displacement or a constant");
         fprintf(_fp,"\n");
         fprintf(_fp,"if ( opnd_array(%d)->%s_is_oop() ) {\n",
                 _operand_idx, disp_constant);
         fprintf(_fp,"  ");
         gen_emit_x_reloc( d32_hi_lo ); fprintf(_fp,"\n");
         fprintf(_fp,"} else {\n");
         fprintf(_fp,"  emit_%s(cbuf, ", d32_hi_lo);
         emit_replacement(); fprintf(_fp, ");\n"); fprintf(_fp,"}");
       }
     }
     else if ( _doing_emit_d16 ) {
       // Relocation of 16-bit values is not supported
       fprintf(_fp,"emit_d16(cbuf, ");
       emit_replacement(); fprintf(_fp, ")");
       // No relocation done for 16-bit values
     }
     else if ( _doing_emit8 ) {
       // Relocation of 8-bit values is not supported
       fprintf(_fp,"emit_d8(cbuf, ");
       emit_replacement(); fprintf(_fp, ")");
       // No relocation done for 8-bit values
     }
     else {
       // Not an emit# command, just output the replacement string.
       emit_replacement();
     }
     // Get ready for next state collection.
     clear();
   }
 private:
   // recognizes names which represent MacroAssembler register types
   // and return the conversion function to build them from OptoReg
   const char* reg_conversion(const char* rep_var) {
     if (strcmp(rep_var,"$Register") == 0)      return "as_Register";
     if (strcmp(rep_var,"$FloatRegister") == 0) return "as_FloatRegister";
 #if defined(IA32) || defined(AMD64)
     if (strcmp(rep_var,"$XMMRegister") == 0)   return "as_XMMRegister";
 #endif
     return NULL;
   }
   void emit_field(const char *rep_var) {
     const char* reg_convert = reg_conversion(rep_var);
     // A subfield variable, '$$subfield'
     if ( strcmp(rep_var, "$reg") == 0 || reg_convert != NULL) {
       // $reg form or the $Register MacroAssembler type conversions
       assert( _operand_idx != -1,
               "Must use this subfield after operand");
       if( _reg_status == LITERAL_NOT_SEEN ) {
         if (_processing_noninput) {
           const Form  *local     = _inst._localNames[_operand_name];
           OperandForm *oper      = local->is_operand();
           const RegDef* first = oper->get_RegClass()->find_first_elem();
           if (reg_convert != NULL) {
             fprintf(_fp, "%s(%s_enc)", reg_convert, first->_regname);
           } else {
             fprintf(_fp, "%s_enc", first->_regname);
           }
         } else {
           fprintf(_fp,"->%s(ra_,this", reg_convert != NULL ? reg_convert : "reg");
           // Add parameter for index position, if not result operand
           if( _operand_idx != 0 ) fprintf(_fp,",idx%d", _operand_idx);
           fprintf(_fp,")");
         }
       } else {
         assert( _reg_status == LITERAL_OUTPUT, "should have output register literal in emit_rep_var");
         // Register literal has already been sent to output file, nothing more needed
       }
     }
     else if ( strcmp(rep_var,"$base") == 0 ) {
       assert( _operand_idx != -1,
               "Must use this subfield after operand");
       assert( ! _may_reloc, "UnImplemented()");
       fprintf(_fp,"->base(ra_,this,idx%d)", _operand_idx);
     }
     else if ( strcmp(rep_var,"$index") == 0 ) {
       assert( _operand_idx != -1,
               "Must use this subfield after operand");
       assert( ! _may_reloc, "UnImplemented()");
       fprintf(_fp,"->index(ra_,this,idx%d)", _operand_idx);
     }
     else if ( strcmp(rep_var,"$scale") == 0 ) {
       assert( ! _may_reloc, "UnImplemented()");
       fprintf(_fp,"->scale()");
     }
     else if ( strcmp(rep_var,"$cmpcode") == 0 ) {
       assert( ! _may_reloc, "UnImplemented()");
       fprintf(_fp,"->ccode()");
     }
     else if ( strcmp(rep_var,"$constant") == 0 ) {
       if( _constant_status == LITERAL_NOT_SEEN ) {
         if ( _constant_type == Form::idealD ) {
           fprintf(_fp,"->constantD()");
         } else if ( _constant_type == Form::idealF ) {
           fprintf(_fp,"->constantF()");
         } else if ( _constant_type == Form::idealL ) {
           fprintf(_fp,"->constantL()");
         } else {
           fprintf(_fp,"->constant()");
         }
       } else {
         assert( _constant_status == LITERAL_OUTPUT, "should have output constant literal in emit_rep_var");
         // Cosntant literal has already been sent to output file, nothing more needed
       }
     }
     else if ( strcmp(rep_var,"$disp") == 0 ) {
       Form::DataType stack_type = _operand ? _operand->is_user_name_for_sReg() : Form::none;
       if( _operand  && _operand_idx==0 && stack_type != Form::none ) {
         fprintf(_fp,"->disp(ra_,this,0)");
       } else {
         fprintf(_fp,"->disp(ra_,this,idx%d)", _operand_idx);
       }
     }
     else if ( strcmp(rep_var,"$label") == 0 ) {
       fprintf(_fp,"->label()");
     }
     else if ( strcmp(rep_var,"$method") == 0 ) {
       fprintf(_fp,"->method()");
     }
     else {
       printf("emit_field: %s\n",rep_var);
       assert( false, "UnImplemented()");
     }
   }
   void emit_rep_var(const char *rep_var) {
     _processing_noninput = false;
     // A replacement variable, originally '$'
     if ( Opcode::as_opcode_type(rep_var) != Opcode::NOT_AN_OPCODE ) {
       _inst._opcode->print_opcode(_fp, Opcode::as_opcode_type(rep_var) );
     }
     else {
       // Lookup its position in parameter list
       int   param_no  = _encoding.rep_var_index(rep_var);
       if ( param_no == -1 ) {
         _AD.syntax_err( _encoding._linenum,
                         "Replacement variable %s not found in enc_class %s.\n",
                         rep_var, _encoding._name);
       }
       // Lookup the corresponding ins_encode parameter
       const char *inst_rep_var = _ins_encode.rep_var_name(_inst, param_no);
       // Check if instruction's actual parameter is a local name in the instruction
       const Form  *local     = _inst._localNames[inst_rep_var];
       OpClassForm *opc       = (local != NULL) ? local->is_opclass() : NULL;
       // Note: assert removed to allow constant and symbolic parameters
       // assert( opc, "replacement variable was not found in local names");
       // Lookup the index position iff the replacement variable is a localName
       int idx  = (opc != NULL) ? _inst.operand_position_format(inst_rep_var) : -1;
       if( idx != -1 ) {
         if (_inst.is_noninput_operand(idx)) {
           // This operand isn't a normal input so printing it is done
           // specially.
           _processing_noninput = true;
         } else {
           // Output the emit code for this operand
           fprintf(_fp,"opnd_array(%d)",idx);
         }
         assert( _operand == opc->is_operand(),
                 "Previous emit $operand does not match current");
       }
       else if( ADLParser::is_literal_constant(inst_rep_var) ) {
         // else check if it is a constant expression
         // Removed following assert to allow primitive C types as arguments to encodings
         // assert( _constant_status == LITERAL_ACCESSED, "Must be processing a literal constant parameter");
         fprintf(_fp,"(%s)", inst_rep_var);
         _constant_status = LITERAL_OUTPUT;
       }
       else if( Opcode::as_opcode_type(inst_rep_var) != Opcode::NOT_AN_OPCODE ) {
         // else check if "primary", "secondary", "tertiary"
         assert( _constant_status == LITERAL_ACCESSED, "Must be processing a literal constant parameter");
         _inst._opcode->print_opcode(_fp, Opcode::as_opcode_type(inst_rep_var) );
         _constant_status = LITERAL_OUTPUT;
       }
       else if((_AD.get_registers() != NULL ) && (_AD.get_registers()->getRegDef(inst_rep_var) != NULL)) {
         // Instruction provided a literal register name for this parameter
         // Check that encoding specifies $$$reg to resolve.as register.
         assert( _reg_status == LITERAL_ACCESSED, "Must be processing a literal register parameter");
         fprintf(_fp,"(%s_enc)", inst_rep_var);
         _reg_status = LITERAL_OUTPUT;
       }
       else {
         // Check for unimplemented functionality before hard failure
         assert( strcmp(opc->_ident,"label")==0, "Unimplemented() Label");
         assert( false, "ShouldNotReachHere()");
       }
       // all done
     }
   }
 };  // end class DefineEmitState
 void ArchDesc::defineSize(FILE *fp, InstructForm &inst) {
   //(1)
   // Output instruction's emit prototype
   fprintf(fp,"uint  %sNode::size(PhaseRegAlloc *ra_) const {\n",
           inst._ident);
   //(2)
   // Print the size
   fprintf(fp, " return (VerifyOops ? MachNode::size(ra_) : %s);\n", inst._size);
   // (3) and (4)
   fprintf(fp,"}\n");
 }
 void ArchDesc::defineEmit(FILE *fp, InstructForm &inst) {
   InsEncode *ins_encode = inst._insencode;
   // (1)
   // Output instruction's emit prototype
   fprintf(fp,"void  %sNode::emit(CodeBuffer &cbuf, PhaseRegAlloc *ra_) const {\n",
           inst._ident);
   // If user did not define an encode section,
   // provide stub that does not generate any machine code.
   if( (_encode == NULL) || (ins_encode == NULL) ) {
     fprintf(fp, "  // User did not define an encode section.\n");
     fprintf(fp,"}\n");
     return;
   }
   // Save current instruction's starting address (helps with relocation).
   fprintf( fp, "    cbuf.set_inst_mark();\n");
   // // // idx0 is only needed for syntactic purposes and only by "storeSSI"
   // fprintf( fp, "    unsigned idx0  = 0;\n");
   // Output each operand's offset into the array of registers.
   inst.index_temps( fp, _globalNames );
   // Output this instruction's encodings
   const char *ec_name;
   bool        user_defined = false;
   ins_encode->reset();
   while ( (ec_name = ins_encode->encode_class_iter()) != NULL ) {
     fprintf(fp, "  {");
     // Output user-defined encoding
     user_defined           = true;
     const char *ec_code    = NULL;
     const char *ec_rep_var = NULL;
     EncClass   *encoding   = _encode->encClass(ec_name);
     if (encoding == NULL) {
       fprintf(stderr, "User did not define contents of this encode_class: %s\n", ec_name);
       abort();
     }
     if (ins_encode->current_encoding_num_args() != encoding->num_args()) {
       globalAD->syntax_err(ins_encode->_linenum, "In %s: passing %d arguments to %s but expecting %d",
                            inst._ident, ins_encode->current_encoding_num_args(),
                            ec_name, encoding->num_args());
     }
     DefineEmitState  pending(fp, *this, *encoding, *ins_encode, inst );
     encoding->_code.reset();
     encoding->_rep_vars.reset();
     // Process list of user-defined strings,
     // and occurrences of replacement variables.
     // Replacement Vars are pushed into a list and then output
     while ( (ec_code = encoding->_code.iter()) != NULL ) {
       if ( ! encoding->_code.is_signal( ec_code ) ) {
         // Emit pending code
         pending.emit();
         pending.clear();
         // Emit this code section
         fprintf(fp,"%s", ec_code);
       } else {
         // A replacement variable or one of its subfields
         // Obtain replacement variable from list
         ec_rep_var  = encoding->_rep_vars.iter();
         pending.add_rep_var(ec_rep_var);
       }
     }
     // Emit pending code
     pending.emit();
     pending.clear();
     fprintf(fp, "}\n");
   } // end while instruction's encodings
   // Check if user stated which encoding to user
   if ( user_defined == false ) {
     fprintf(fp, "  // User did not define which encode class to use.\n");
   }
   // (3) and (4)
   fprintf(fp,"}\n");
 }
 // ---------------------------------------------------------------------------
 //--------Utilities to build MachOper and MachNode derived Classes------------
 // ---------------------------------------------------------------------------
 //------------------------------Utilities to build Operand Classes------------
 static void defineIn_RegMask(FILE *fp, FormDict &globals, OperandForm &oper) {
   uint num_edges = oper.num_edges(globals);
   if( num_edges != 0 ) {
     // Method header
     fprintf(fp, "const RegMask *%sOper::in_RegMask(int index) const {\n",
             oper._ident);
     // Assert that the index is in range.
     fprintf(fp, "  assert(0 <= index && index < %d, \"index out of range\");\n",
             num_edges);
     // Figure out if all RegMasks are the same.
     const char* first_reg_class = oper.in_reg_class(0, globals);
     bool all_same = true;
     assert(first_reg_class != NULL, "did not find register mask");
     for (uint index = 1; all_same && index < num_edges; index++) {
       const char* some_reg_class = oper.in_reg_class(index, globals);
       assert(some_reg_class != NULL, "did not find register mask");
       if (strcmp(first_reg_class, some_reg_class) != 0) {
         all_same = false;
       }
     }
     if (all_same) {
       // Return the sole RegMask.
       if (strcmp(first_reg_class, "stack_slots") == 0) {
         fprintf(fp,"  return &(Compile::current()->FIRST_STACK_mask());\n");
       } else {
         fprintf(fp,"  return &%s_mask;\n", toUpper(first_reg_class));
       }
     } else {
       // Build a switch statement to return the desired mask.
       fprintf(fp,"  switch (index) {\n");
       for (uint index = 0; index < num_edges; index++) {
         const char *reg_class = oper.in_reg_class(index, globals);
         assert(reg_class != NULL, "did not find register mask");
         if( !strcmp(reg_class, "stack_slots") ) {
           fprintf(fp, "  case %d: return &(Compile::current()->FIRST_STACK_mask());\n", index);
         } else {
           fprintf(fp, "  case %d: return &%s_mask;\n", index, toUpper(reg_class));
         }
       }
       fprintf(fp,"  }\n");
       fprintf(fp,"  ShouldNotReachHere();\n");
       fprintf(fp,"  return NULL;\n");
     }
     // Method close
     fprintf(fp, "}\n\n");
   }
 }
 // generate code to create a clone for a class derived from MachOper
 //
 // (0)  MachOper  *MachOperXOper::clone(Compile* C) const {
 // (1)    return new (C) MachXOper( _ccode, _c0, _c1, ..., _cn);
 // (2)  }
 //
 static void defineClone(FILE *fp, FormDict &globalNames, OperandForm &oper) {
   fprintf(fp,"MachOper  *%sOper::clone(Compile* C) const {\n", oper._ident);
   // Check for constants that need to be copied over
   const int  num_consts    = oper.num_consts(globalNames);
   const bool is_ideal_bool = oper.is_ideal_bool();
   if( (num_consts > 0) ) {
     fprintf(fp,"  return  new (C) %sOper(", oper._ident);
     // generate parameters for constants
     int i = 0;
     fprintf(fp,"_c%d", i);
     for( i = 1; i < num_consts; ++i) {
       fprintf(fp,", _c%d", i);
     }
     // finish line (1)
     fprintf(fp,");\n");
   }
   else {
     assert( num_consts == 0, "Currently support zero or one constant per operand clone function");
     fprintf(fp,"  return  new (C) %sOper();\n", oper._ident);
   }
   // finish method
   fprintf(fp,"}\n");
 }
 static void define_hash(FILE *fp, char *operand) {
   fprintf(fp,"uint %sOper::hash() const { return 5; }\n", operand);
 }
 static void define_cmp(FILE *fp, char *operand) {
   fprintf(fp,"uint %sOper::cmp( const MachOper &oper ) const { return opcode() == oper.opcode(); }\n", operand);
 }
 // Helper functions for bug 4796752, abstracted with minimal modification
 // from define_oper_interface()
 OperandForm *rep_var_to_operand(const char *encoding, OperandForm &oper, FormDict &globals) {
   OperandForm *op = NULL;
   // Check for replacement variable
   if( *encoding == '$' ) {
     // Replacement variable
     const char *rep_var = encoding + 1;
     // Lookup replacement variable, rep_var, in operand's component list
     const Component *comp = oper._components.search(rep_var);
     assert( comp != NULL, "Replacement variable not found in components");
     // Lookup operand form for replacement variable's type
     const char      *type = comp->_type;
     Form            *form = (Form*)globals[type];
     assert( form != NULL, "Replacement variable's type not found");
     op = form->is_operand();
     assert( op, "Attempting to emit a non-register or non-constant");
   }
   return op;
 }
 int rep_var_to_constant_index(const char *encoding, OperandForm &oper, FormDict &globals) {
   int idx = -1;
   // Check for replacement variable
   if( *encoding == '$' ) {
     // Replacement variable
     const char *rep_var = encoding + 1;
     // Lookup replacement variable, rep_var, in operand's component list
     const Component *comp = oper._components.search(rep_var);
     assert( comp != NULL, "Replacement variable not found in components");
     // Lookup operand form for replacement variable's type
     const char      *type = comp->_type;
     Form            *form = (Form*)globals[type];
     assert( form != NULL, "Replacement variable's type not found");
     OperandForm *op = form->is_operand();
     assert( op, "Attempting to emit a non-register or non-constant");
     // Check that this is a constant and find constant's index:
     if (op->_matrule && op->_matrule->is_base_constant(globals)) {
       idx  = oper.constant_position(globals, comp);
     }
   }
   return idx;
 }
 bool is_regI(const char *encoding, OperandForm &oper, FormDict &globals ) {
   bool is_regI = false;
   OperandForm *op = rep_var_to_operand(encoding, oper, globals);
   if( op != NULL ) {
     // Check that this is a register
     if ( (op->_matrule && op->_matrule->is_base_register(globals)) ) {
       // Register
       const char* ideal  = op->ideal_type(globals);
       is_regI = (ideal && (op->ideal_to_Reg_type(ideal) == Form::idealI));
     }
   }
   return is_regI;
 }
 bool is_conP(const char *encoding, OperandForm &oper, FormDict &globals ) {
   bool is_conP = false;
   OperandForm *op = rep_var_to_operand(encoding, oper, globals);
   if( op != NULL ) {
     // Check that this is a constant pointer
     if (op->_matrule && op->_matrule->is_base_constant(globals)) {
       // Constant
       Form::DataType dtype = op->is_base_constant(globals);
       is_conP = (dtype == Form::idealP);
     }
   }
   return is_conP;
 }
 // Define a MachOper interface methods
 void ArchDesc::define_oper_interface(FILE *fp, OperandForm &oper, FormDict &globals,
                                      const char *name, const char *encoding) {
   bool emit_position = false;
   int position = -1;
   fprintf(fp,"  virtual int            %s", name);
   // Generate access method for base, index, scale, disp, ...
   if( (strcmp(name,"base") == 0) || (strcmp(name,"index") == 0) ) {
     fprintf(fp,"(PhaseRegAlloc *ra_, const Node *node, int idx) const { \n");
     emit_position = true;
   } else if ( (strcmp(name,"disp") == 0) ) {
     fprintf(fp,"(PhaseRegAlloc *ra_, const Node *node, int idx) const { \n");
   } else {
     fprintf(fp,"() const { ");
   }
   // Check for hexadecimal value OR replacement variable
   if( *encoding == '$' ) {
     // Replacement variable
     const char *rep_var = encoding + 1;
     fprintf(fp,"// Replacement variable: %s\n", encoding+1);
     // Lookup replacement variable, rep_var, in operand's component list
     const Component *comp = oper._components.search(rep_var);
     assert( comp != NULL, "Replacement variable not found in components");
     // Lookup operand form for replacement variable's type
     const char      *type = comp->_type;
     Form            *form = (Form*)globals[type];
     assert( form != NULL, "Replacement variable's type not found");
     OperandForm *op = form->is_operand();
     assert( op, "Attempting to emit a non-register or non-constant");
     // Check that this is a register or a constant and generate code:
     if ( (op->_matrule && op->_matrule->is_base_register(globals)) ) {
       // Register
       int idx_offset = oper.register_position( globals, rep_var);
       position = idx_offset;
       fprintf(fp,"    return (int)ra_->get_encode(node->in(idx");
       if ( idx_offset > 0 ) fprintf(fp,                      "+%d",idx_offset);
       fprintf(fp,"));\n");
     } else if ( op->ideal_to_sReg_type(op->_ident) != Form::none ) {
       // StackSlot for an sReg comes either from input node or from self, when idx==0
       fprintf(fp,"    if( idx != 0 ) {\n");
       fprintf(fp,"      // Access register number for input operand\n");
       fprintf(fp,"      return ra_->reg2offset(ra_->get_reg_first(node->in(idx)));/* sReg */\n");
       fprintf(fp,"    }\n");
       fprintf(fp,"    // Access register number from myself\n");
       fprintf(fp,"    return ra_->reg2offset(ra_->get_reg_first(node));/* sReg */\n");
     } else if (op->_matrule && op->_matrule->is_base_constant(globals)) {
       // Constant
       // Check which constant this name maps to: _c0, _c1, ..., _cn
       const int idx = oper.constant_position(globals, comp);
       assert( idx != -1, "Constant component not found in operand");
       // Output code for this constant, type dependent.
       fprintf(fp,"    return (int)" );
       oper.access_constant(fp, globals, (uint)idx /* , const_type */);
       fprintf(fp,";\n");
     } else {
       assert( false, "Attempting to emit a non-register or non-constant");
     }
   }
   else if( *encoding == '0' && *(encoding+1) == 'x' ) {
     // Hex value
     fprintf(fp,"return %s;", encoding);
   } else {
     assert( false, "Do not support octal or decimal encode constants");
   }
   fprintf(fp,"  }\n");
   if( emit_position && (position != -1) && (oper.num_edges(globals) > 0) ) {
     fprintf(fp,"  virtual int            %s_position() const { return %d; }\n", name, position);
     MemInterface *mem_interface = oper._interface->is_MemInterface();
     const char *base = mem_interface->_base;
     const char *disp = mem_interface->_disp;
     if( emit_position && (strcmp(name,"base") == 0)
         && base != NULL && is_regI(base, oper, globals)
         && disp != NULL && is_conP(disp, oper, globals) ) {
       // Found a memory access using a constant pointer for a displacement
       // and a base register containing an integer offset.
       // In this case the base and disp are reversed with respect to what
       // is expected by MachNode::get_base_and_disp() and MachNode::adr_type().
       // Provide a non-NULL return for disp_as_type() that will allow adr_type()
       // to correctly compute the access type for alias analysis.
       //
       // See BugId 4796752, operand indOffset32X in i486.ad
       int idx = rep_var_to_constant_index(disp, oper, globals);
       fprintf(fp,"  virtual const TypePtr *disp_as_type() const { return _c%d; }\n", idx);
     }
   }
 }
 //
 // Construct the method to copy _idx, inputs and operands to new node.
 static void define_fill_new_machnode(bool used, FILE *fp_cpp) {
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "// Copy _idx, inputs and operands to new node\n");
   fprintf(fp_cpp, "void MachNode::fill_new_machnode( MachNode* node, Compile* C) const {\n");
   if( !used ) {
     fprintf(fp_cpp, "  // This architecture does not have cisc or short branch instructions\n");
     fprintf(fp_cpp, "  ShouldNotCallThis();\n");
     fprintf(fp_cpp, "}\n");
   } else {
     // New node must use same node index for access through allocator's tables
     fprintf(fp_cpp, "  // New node must use same node index\n");
     fprintf(fp_cpp, "  node->set_idx( _idx );\n");
     // Copy machine-independent inputs
     fprintf(fp_cpp, "  // Copy machine-independent inputs\n");
     fprintf(fp_cpp, "  for( uint j = 0; j < req(); j++ ) {\n");
     fprintf(fp_cpp, "    node->add_req(in(j));\n");
     fprintf(fp_cpp, "  }\n");
     // Copy machine operands to new MachNode
     fprintf(fp_cpp, "  // Copy my operands, except for cisc position\n");
     fprintf(fp_cpp, "  int nopnds = num_opnds();\n");
     fprintf(fp_cpp, "  assert( node->num_opnds() == (uint)nopnds, \"Must have same number of operands\");\n");
     fprintf(fp_cpp, "  MachOper **to = node->_opnds;\n");
     fprintf(fp_cpp, "  for( int i = 0; i < nopnds; i++ ) {\n");
     fprintf(fp_cpp, "    if( i != cisc_operand() ) \n");
     fprintf(fp_cpp, "      to[i] = _opnds[i]->clone(C);\n");
     fprintf(fp_cpp, "  }\n");
     fprintf(fp_cpp, "}\n");
   }
   fprintf(fp_cpp, "\n");
 }
 //------------------------------defineClasses----------------------------------
 // Define members of MachNode and MachOper classes based on
 // operand and instruction lists
 void ArchDesc::defineClasses(FILE *fp) {
   // Define the contents of an array containing the machine register names
   defineRegNames(fp, _register);
   // Define an array containing the machine register encoding values
   defineRegEncodes(fp, _register);
   // Generate an enumeration of user-defined register classes
   // and a list of register masks, one for each class.
   // Only define the RegMask value objects in the expand file.
   // Declare each as an extern const RegMask ...; in ad_<arch>.hpp
   declare_register_masks(_HPP_file._fp);
   // build_register_masks(fp);
   build_register_masks(_CPP_EXPAND_file._fp);
   // Define the pipe_classes
   build_pipe_classes(_CPP_PIPELINE_file._fp);
   // Generate Machine Classes for each operand defined in AD file
   fprintf(fp,"\n");
   fprintf(fp,"\n");
   fprintf(fp,"//------------------Define classes derived from MachOper---------------------\n");
   // Iterate through all operands
   _operands.reset();
   OperandForm *oper;
   for( ; (oper = (OperandForm*)_operands.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( oper->ideal_only() ) continue;
     // !!!!!
     // The declaration of labelOper is in machine-independent file: machnode
     if ( strcmp(oper->_ident,"label") == 0 ) {
       defineIn_RegMask(_CPP_MISC_file._fp, _globalNames, *oper);
       fprintf(fp,"MachOper  *%sOper::clone(Compile* C) const {\n", oper->_ident);
       fprintf(fp,"  return  new (C) %sOper(_label, _block_num);\n", oper->_ident);
       fprintf(fp,"}\n");
       fprintf(fp,"uint %sOper::opcode() const { return %s; }\n",
               oper->_ident, machOperEnum(oper->_ident));
       // // Currently all XXXOper::Hash() methods are identical (990820)
       // define_hash(fp, oper->_ident);
       // // Currently all XXXOper::Cmp() methods are identical (990820)
       // define_cmp(fp, oper->_ident);
       fprintf(fp,"\n");
       continue;
     }
     // The declaration of methodOper is in machine-independent file: machnode
     if ( strcmp(oper->_ident,"method") == 0 ) {
       defineIn_RegMask(_CPP_MISC_file._fp, _globalNames, *oper);
       fprintf(fp,"MachOper  *%sOper::clone(Compile* C) const {\n", oper->_ident);
       fprintf(fp,"  return  new (C) %sOper(_method);\n", oper->_ident);
       fprintf(fp,"}\n");
       fprintf(fp,"uint %sOper::opcode() const { return %s; }\n",
               oper->_ident, machOperEnum(oper->_ident));
       // // Currently all XXXOper::Hash() methods are identical (990820)
       // define_hash(fp, oper->_ident);
       // // Currently all XXXOper::Cmp() methods are identical (990820)
       // define_cmp(fp, oper->_ident);
       fprintf(fp,"\n");
       continue;
     }
     defineIn_RegMask(fp, _globalNames, *oper);
     defineClone(_CPP_CLONE_file._fp, _globalNames, *oper);
     // // Currently all XXXOper::Hash() methods are identical (990820)
     // define_hash(fp, oper->_ident);
     // // Currently all XXXOper::Cmp() methods are identical (990820)
     // define_cmp(fp, oper->_ident);
     // side-call to generate output that used to be in the header file:
     extern void gen_oper_format(FILE *fp, FormDict &globals, OperandForm &oper, bool for_c_file);
     gen_oper_format(_CPP_FORMAT_file._fp, _globalNames, *oper, true);
   }
   // Generate Machine Classes for each instruction defined in AD file
   fprintf(fp,"//------------------Define members for classes derived from MachNode----------\n");
   // Output the definitions for out_RegMask() // & kill_RegMask()
   _instructions.reset();
   InstructForm *instr;
   MachNodeForm *machnode;
   for( ; (instr = (InstructForm*)_instructions.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( instr->ideal_only() ) continue;
     defineOut_RegMask(_CPP_MISC_file._fp, instr->_ident, reg_mask(*instr));
   }
   bool used = false;
   // Output the definitions for expand rules & peephole rules
   _instructions.reset();
   for( ; (instr = (InstructForm*)_instructions.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( instr->ideal_only() ) continue;
     // If there are multiple defs/kills, or an explicit expand rule, build rule
     if( instr->expands() || instr->needs_projections() ||
         instr->has_temps() ||
         instr->_matrule != NULL &&
         instr->num_opnds() != instr->num_unique_opnds() )
       defineExpand(_CPP_EXPAND_file._fp, instr);
     // If there is an explicit peephole rule, build it
     if ( instr->peepholes() )
       definePeephole(_CPP_PEEPHOLE_file._fp, instr);
     // Output code to convert to the cisc version, if applicable
     used |= instr->define_cisc_version(*this, fp);
     // Output code to convert to the short branch version, if applicable
     used |= instr->define_short_branch_methods(fp);
   }
   // Construct the method called by cisc_version() to copy inputs and operands.
   define_fill_new_machnode(used, fp);
   // Output the definitions for labels
   _instructions.reset();
   while( (instr = (InstructForm*)_instructions.iter()) != NULL ) {
     // Ensure this is a machine-world instruction
     if ( instr->ideal_only() ) continue;
     // Access the fields for operand Label
     int label_position = instr->label_position();
     if( label_position != -1 ) {
       // Set the label
       fprintf(fp,"void %sNode::label_set( Label& label, uint block_num ) {\n", instr->_ident);
       fprintf(fp,"  labelOper* oper  = (labelOper*)(opnd_array(%d));\n",
               label_position );
       fprintf(fp,"  oper->_label     = &label;\n");
       fprintf(fp,"  oper->_block_num = block_num;\n");
       fprintf(fp,"}\n");
     }
   }
   // Output the definitions for methods
   _instructions.reset();
   while( (instr = (InstructForm*)_instructions.iter()) != NULL ) {
     // Ensure this is a machine-world instruction
     if ( instr->ideal_only() ) continue;
     // Access the fields for operand Label
     int method_position = instr->method_position();
     if( method_position != -1 ) {
       // Access the method's address
       fprintf(fp,"void %sNode::method_set( intptr_t method ) {\n", instr->_ident);
       fprintf(fp,"  ((methodOper*)opnd_array(%d))->_method = method;\n",
               method_position );
       fprintf(fp,"}\n");
       fprintf(fp,"\n");
     }
   }
   // Define this instruction's number of relocation entries, base is '0'
   _instructions.reset();
   while( (instr = (InstructForm*)_instructions.iter()) != NULL ) {
     // Output the definition for number of relocation entries
     uint reloc_size = instr->reloc(_globalNames);
     if ( reloc_size != 0 ) {
       fprintf(fp,"int  %sNode::reloc()   const {\n", instr->_ident);
       fprintf(fp,  "  return  %d;\n", reloc_size );
       fprintf(fp,"}\n");
       fprintf(fp,"\n");
     }
   }
   fprintf(fp,"\n");
   // Output the definitions for code generation
   //
   // address  ___Node::emit(address ptr, PhaseRegAlloc *ra_) const {
   //   // ...  encoding defined by user
   //   return ptr;
   // }
   //
   _instructions.reset();
   for( ; (instr = (InstructForm*)_instructions.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( instr->ideal_only() ) continue;
     if (instr->_insencode) defineEmit(fp, *instr);
     if (instr->_size)      defineSize(fp, *instr);
     // side-call to generate output that used to be in the header file:
     extern void gen_inst_format(FILE *fp, FormDict &globals, InstructForm &oper, bool for_c_file);
     gen_inst_format(_CPP_FORMAT_file._fp, _globalNames, *instr, true);
   }
   // Output the definitions for alias analysis
   _instructions.reset();
   for( ; (instr = (InstructForm*)_instructions.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( instr->ideal_only() ) continue;
     // Analyze machine instructions that either USE or DEF memory.
     int memory_operand = instr->memory_operand(_globalNames);
     // Some guys kill all of memory
     if ( instr->is_wide_memory_kill(_globalNames) ) {
       memory_operand = InstructForm::MANY_MEMORY_OPERANDS;
     }
     if ( memory_operand != InstructForm::NO_MEMORY_OPERAND ) {
       if( memory_operand == InstructForm::MANY_MEMORY_OPERANDS ) {
         fprintf(fp,"const TypePtr *%sNode::adr_type() const { return TypePtr::BOTTOM; }\n", instr->_ident);
         fprintf(fp,"const MachOper* %sNode::memory_operand() const { return (MachOper*)-1; }\n", instr->_ident);
       } else {
         fprintf(fp,"const MachOper* %sNode::memory_operand() const { return _opnds[%d]; }\n", instr->_ident, memory_operand);
   }
     }
   }
   // Get the length of the longest identifier
   int max_ident_len = 0;
   _instructions.reset();
   for ( ; (instr = (InstructForm*)_instructions.iter()) != NULL; ) {
     if (instr->_ins_pipe && _pipeline->_classlist.search(instr->_ins_pipe)) {
       int ident_len = (int)strlen(instr->_ident);
       if( max_ident_len < ident_len )
         max_ident_len = ident_len;
     }
   }
   // Emit specifically for Node(s)
   fprintf(_CPP_PIPELINE_file._fp, "const Pipeline * %*s::pipeline_class() { return %s; }\n",
     max_ident_len, "Node", _pipeline ? "(&pipeline_class_Zero_Instructions)" : "NULL");
   fprintf(_CPP_PIPELINE_file._fp, "const Pipeline * %*s::pipeline() const { return %s; }\n",
     max_ident_len, "Node", _pipeline ? "(&pipeline_class_Zero_Instructions)" : "NULL");
   fprintf(_CPP_PIPELINE_file._fp, "\n");
   fprintf(_CPP_PIPELINE_file._fp, "const Pipeline * %*s::pipeline_class() { return %s; }\n",
     max_ident_len, "MachNode", _pipeline ? "(&pipeline_class_Unknown_Instructions)" : "NULL");
   fprintf(_CPP_PIPELINE_file._fp, "const Pipeline * %*s::pipeline() const { return pipeline_class(); }\n",
     max_ident_len, "MachNode");
   fprintf(_CPP_PIPELINE_file._fp, "\n");
   // Output the definitions for machine node specific pipeline data
   _machnodes.reset();
   for ( ; (machnode = (MachNodeForm*)_machnodes.iter()) != NULL; ) {
     fprintf(_CPP_PIPELINE_file._fp, "const Pipeline * %sNode::pipeline() const { return (&pipeline_class_%03d); }\n",
       machnode->_ident, ((class PipeClassForm *)_pipeline->_classdict[machnode->_machnode_pipe])->_num);
   }
   fprintf(_CPP_PIPELINE_file._fp, "\n");
   // Output the definitions for instruction pipeline static data references
   _instructions.reset();
   for ( ; (instr = (InstructForm*)_instructions.iter()) != NULL; ) {
     if (instr->_ins_pipe && _pipeline->_classlist.search(instr->_ins_pipe)) {
       fprintf(_CPP_PIPELINE_file._fp, "\n");
       fprintf(_CPP_PIPELINE_file._fp, "const Pipeline * %*sNode::pipeline_class() { return (&pipeline_class_%03d); }\n",
         max_ident_len, instr->_ident, ((class PipeClassForm *)_pipeline->_classdict[instr->_ins_pipe])->_num);
       fprintf(_CPP_PIPELINE_file._fp, "const Pipeline * %*sNode::pipeline() const { return (&pipeline_class_%03d); }\n",
         max_ident_len, instr->_ident, ((class PipeClassForm *)_pipeline->_classdict[instr->_ins_pipe])->_num);
     }
   }
 }
 // -------------------------------- maps ------------------------------------
 // Information needed to generate the ReduceOp mapping for the DFA
 class OutputReduceOp : public OutputMap {
 public:
   OutputReduceOp(FILE *hpp, FILE *cpp, FormDict &globals, ArchDesc &AD)
     : OutputMap(hpp, cpp, globals, AD) {};
   void declaration() { fprintf(_hpp, "extern const int   reduceOp[];\n"); }
   void definition()  { fprintf(_cpp, "const        int   reduceOp[] = {\n"); }
   void closing()     { fprintf(_cpp, "  0 // no trailing comma\n");
                        OutputMap::closing();
   }
   void map(OpClassForm &opc)  {
     const char *reduce = opc._ident;
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
   void map(OperandForm &oper) {
     // Most operands without match rules, e.g.  eFlagsReg, do not have a result operand
     const char *reduce = (oper._matrule ? oper.reduce_result() : NULL);
     // operand stackSlot does not have a match rule, but produces a stackSlot
     if( oper.is_user_name_for_sReg() != Form::none ) reduce = oper.reduce_result();
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
   void map(InstructForm &inst) {
     const char *reduce = (inst._matrule ? inst.reduce_result() : NULL);
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
   void map(char         *reduce) {
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
 };
 // Information needed to generate the LeftOp mapping for the DFA
 class OutputLeftOp : public OutputMap {
 public:
   OutputLeftOp(FILE *hpp, FILE *cpp, FormDict &globals, ArchDesc &AD)
     : OutputMap(hpp, cpp, globals, AD) {};
   void declaration() { fprintf(_hpp, "extern const int   leftOp[];\n"); }
   void definition()  { fprintf(_cpp, "const        int   leftOp[] = {\n"); }
   void closing()     { fprintf(_cpp, "  0 // no trailing comma\n");
                        OutputMap::closing();
   }
   void map(OpClassForm &opc)  { fprintf(_cpp, "  0"); }
   void map(OperandForm &oper) {
     const char *reduce = oper.reduce_left(_globals);
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
   void map(char        *name) {
     const char *reduce = _AD.reduceLeft(name);
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
   void map(InstructForm &inst) {
     const char *reduce = inst.reduce_left(_globals);
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
 };
 // Information needed to generate the RightOp mapping for the DFA
 class OutputRightOp : public OutputMap {
 public:
   OutputRightOp(FILE *hpp, FILE *cpp, FormDict &globals, ArchDesc &AD)
     : OutputMap(hpp, cpp, globals, AD) {};
   void declaration() { fprintf(_hpp, "extern const int   rightOp[];\n"); }
   void definition()  { fprintf(_cpp, "const        int   rightOp[] = {\n"); }
   void closing()     { fprintf(_cpp, "  0 // no trailing comma\n");
                        OutputMap::closing();
   }
   void map(OpClassForm &opc)  { fprintf(_cpp, "  0"); }
   void map(OperandForm &oper) {
     const char *reduce = oper.reduce_right(_globals);
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
   void map(char        *name) {
     const char *reduce = _AD.reduceRight(name);
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
   void map(InstructForm &inst) {
     const char *reduce = inst.reduce_right(_globals);
     if( reduce )  fprintf(_cpp, "  %s_rule", reduce);
     else          fprintf(_cpp, "  0");
   }
 };
 // Information needed to generate the Rule names for the DFA
 class OutputRuleName : public OutputMap {
 public:
   OutputRuleName(FILE *hpp, FILE *cpp, FormDict &globals, ArchDesc &AD)
     : OutputMap(hpp, cpp, globals, AD) {};
   void declaration() { fprintf(_hpp, "extern const char *ruleName[];\n"); }
   void definition()  { fprintf(_cpp, "const char        *ruleName[] = {\n"); }
   void closing()     { fprintf(_cpp, "  \"no trailing comma\"\n");
                        OutputMap::closing();
   }
   void map(OpClassForm &opc)  { fprintf(_cpp, "  \"%s\"", _AD.machOperEnum(opc._ident) ); }
   void map(OperandForm &oper) { fprintf(_cpp, "  \"%s\"", _AD.machOperEnum(oper._ident) ); }
   void map(char        *name) { fprintf(_cpp, "  \"%s\"", name ? name : "0"); }
   void map(InstructForm &inst){ fprintf(_cpp, "  \"%s\"", inst._ident ? inst._ident : "0"); }
 };
 // Information needed to generate the swallowed mapping for the DFA
 class OutputSwallowed : public OutputMap {
 public:
   OutputSwallowed(FILE *hpp, FILE *cpp, FormDict &globals, ArchDesc &AD)
     : OutputMap(hpp, cpp, globals, AD) {};
   void declaration() { fprintf(_hpp, "extern const bool  swallowed[];\n"); }
   void definition()  { fprintf(_cpp, "const        bool  swallowed[] = {\n"); }
   void closing()     { fprintf(_cpp, "  false // no trailing comma\n");
                        OutputMap::closing();
   }
   void map(OperandForm &oper) { // Generate the entry for this opcode
     const char *swallowed = oper.swallowed(_globals) ? "true" : "false";
     fprintf(_cpp, "  %s", swallowed);
   }
   void map(OpClassForm &opc)  { fprintf(_cpp, "  false"); }
   void map(char        *name) { fprintf(_cpp, "  false"); }
   void map(InstructForm &inst){ fprintf(_cpp, "  false"); }
 };
 // Information needed to generate the decision array for instruction chain rule
 class OutputInstChainRule : public OutputMap {
 public:
   OutputInstChainRule(FILE *hpp, FILE *cpp, FormDict &globals, ArchDesc &AD)
     : OutputMap(hpp, cpp, globals, AD) {};
   void declaration() { fprintf(_hpp, "extern const bool  instruction_chain_rule[];\n"); }
   void definition()  { fprintf(_cpp, "const        bool  instruction_chain_rule[] = {\n"); }
   void closing()     { fprintf(_cpp, "  false // no trailing comma\n");
                        OutputMap::closing();
   }
   void map(OpClassForm &opc)   { fprintf(_cpp, "  false"); }
   void map(OperandForm &oper)  { fprintf(_cpp, "  false"); }
   void map(char        *name)  { fprintf(_cpp, "  false"); }
   void map(InstructForm &inst) { // Check for simple chain rule
     const char *chain = inst.is_simple_chain_rule(_globals) ? "true" : "false";
     fprintf(_cpp, "  %s", chain);
   }
 };
 //---------------------------build_map------------------------------------
 // Build  mapping from enumeration for densely packed operands
 // TO result and child types.
 void ArchDesc::build_map(OutputMap &map) {
   FILE         *fp_hpp = map.decl_file();
   FILE         *fp_cpp = map.def_file();
   int           idx    = 0;
   OperandForm  *op;
   OpClassForm  *opc;
   InstructForm *inst;
   // Construct this mapping
   map.declaration();
   fprintf(fp_cpp,"\n");
   map.definition();
   // Output the mapping for operands
   map.record_position(OutputMap::BEGIN_OPERANDS, idx );
   _operands.reset();
   for(; (op = (OperandForm*)_operands.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( op->ideal_only() )  continue;
     // Generate the entry for this opcode
     map.map(*op);    fprintf(fp_cpp, ", // %d\n", idx);
     ++idx;
   };
   fprintf(fp_cpp, "  // last operand\n");
   // Place all user-defined operand classes into the mapping
   map.record_position(OutputMap::BEGIN_OPCLASSES, idx );
   _opclass.reset();
   for(; (opc = (OpClassForm*)_opclass.iter()) != NULL; ) {
     map.map(*opc);    fprintf(fp_cpp, ", // %d\n", idx);
     ++idx;
   };
   fprintf(fp_cpp, "  // last operand class\n");
   // Place all internally defined operands into the mapping
   map.record_position(OutputMap::BEGIN_INTERNALS, idx );
   _internalOpNames.reset();
   char *name = NULL;
   for(; (name = (char *)_internalOpNames.iter()) != NULL; ) {
     map.map(name);    fprintf(fp_cpp, ", // %d\n", idx);
     ++idx;
   };
   fprintf(fp_cpp, "  // last internally defined operand\n");
   // Place all user-defined instructions into the mapping
   if( map.do_instructions() ) {
     map.record_position(OutputMap::BEGIN_INSTRUCTIONS, idx );
     // Output all simple instruction chain rules first
     map.record_position(OutputMap::BEGIN_INST_CHAIN_RULES, idx );
     {
       _instructions.reset();
       for(; (inst = (InstructForm*)_instructions.iter()) != NULL; ) {
         // Ensure this is a machine-world instruction
         if ( inst->ideal_only() )  continue;
         if ( ! inst->is_simple_chain_rule(_globalNames) ) continue;
         if ( inst->rematerialize(_globalNames, get_registers()) ) continue;
         map.map(*inst);      fprintf(fp_cpp, ", // %d\n", idx);
         ++idx;
       };
       map.record_position(OutputMap::BEGIN_REMATERIALIZE, idx );
       _instructions.reset();
       for(; (inst = (InstructForm*)_instructions.iter()) != NULL; ) {
         // Ensure this is a machine-world instruction
         if ( inst->ideal_only() )  continue;
         if ( ! inst->is_simple_chain_rule(_globalNames) ) continue;
         if ( ! inst->rematerialize(_globalNames, get_registers()) ) continue;
         map.map(*inst);      fprintf(fp_cpp, ", // %d\n", idx);
         ++idx;
       };
       map.record_position(OutputMap::END_INST_CHAIN_RULES, idx );
     }
     // Output all instructions that are NOT simple chain rules
     {
       _instructions.reset();
       for(; (inst = (InstructForm*)_instructions.iter()) != NULL; ) {
         // Ensure this is a machine-world instruction
         if ( inst->ideal_only() )  continue;
         if ( inst->is_simple_chain_rule(_globalNames) ) continue;
         if ( ! inst->rematerialize(_globalNames, get_registers()) ) continue;
         map.map(*inst);      fprintf(fp_cpp, ", // %d\n", idx);
         ++idx;
       };
       map.record_position(OutputMap::END_REMATERIALIZE, idx );
       _instructions.reset();
       for(; (inst = (InstructForm*)_instructions.iter()) != NULL; ) {
         // Ensure this is a machine-world instruction
         if ( inst->ideal_only() )  continue;
         if ( inst->is_simple_chain_rule(_globalNames) ) continue;
         if ( inst->rematerialize(_globalNames, get_registers()) ) continue;
         map.map(*inst);      fprintf(fp_cpp, ", // %d\n", idx);
         ++idx;
       };
     }
     fprintf(fp_cpp, "  // last instruction\n");
     map.record_position(OutputMap::END_INSTRUCTIONS, idx );
   }
   // Finish defining table
   map.closing();
 };
 // Helper function for buildReduceMaps
 char reg_save_policy(const char *calling_convention) {
   char callconv;
   if      (!strcmp(calling_convention, "NS"))  callconv = 'N';
   else if (!strcmp(calling_convention, "SOE")) callconv = 'E';
   else if (!strcmp(calling_convention, "SOC")) callconv = 'C';
   else if (!strcmp(calling_convention, "AS"))  callconv = 'A';
   else                                         callconv = 'Z';
   return callconv;
 }
 //---------------------------generate_assertion_checks-------------------
 void ArchDesc::generate_adlc_verification(FILE *fp_cpp) {
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "#ifndef PRODUCT\n");
   fprintf(fp_cpp, "void Compile::adlc_verification() {\n");
   globalDefs().print_asserts(fp_cpp);
   fprintf(fp_cpp, "}\n");
   fprintf(fp_cpp, "#endif\n");
   fprintf(fp_cpp, "\n");
 }
 //---------------------------addSourceBlocks-----------------------------
 void ArchDesc::addSourceBlocks(FILE *fp_cpp) {
   if (_source.count() > 0)
     _source.output(fp_cpp);
   generate_adlc_verification(fp_cpp);
 }
 //---------------------------addHeaderBlocks-----------------------------
 void ArchDesc::addHeaderBlocks(FILE *fp_hpp) {
   if (_header.count() > 0)
     _header.output(fp_hpp);
 }
 //-------------------------addPreHeaderBlocks----------------------------
 void ArchDesc::addPreHeaderBlocks(FILE *fp_hpp) {
   // Output #defines from definition block
   globalDefs().print_defines(fp_hpp);
   if (_pre_header.count() > 0)
     _pre_header.output(fp_hpp);
 }
 //---------------------------buildReduceMaps-----------------------------
 // Build  mapping from enumeration for densely packed operands
 // TO result and child types.
 void ArchDesc::buildReduceMaps(FILE *fp_hpp, FILE *fp_cpp) {
   RegDef       *rdef;
   RegDef       *next;
   // The emit bodies currently require functions defined in the source block.
   // Build external declarations for mappings
   fprintf(fp_hpp, "\n");
   fprintf(fp_hpp, "extern const char  register_save_policy[];\n");
   fprintf(fp_hpp, "extern const char  c_reg_save_policy[];\n");
   fprintf(fp_hpp, "extern const int   register_save_type[];\n");
   fprintf(fp_hpp, "\n");
   // Construct Save-Policy array
   fprintf(fp_cpp, "// Map from machine-independent register number to register_save_policy\n");
   fprintf(fp_cpp, "const        char register_save_policy[] = {\n");
   _register->reset_RegDefs();
   for( rdef = _register->iter_RegDefs(); rdef != NULL; rdef = next ) {
     next              = _register->iter_RegDefs();
     char policy       = reg_save_policy(rdef->_callconv);
     const char *comma = (next != NULL) ? "," : " // no trailing comma";
     fprintf(fp_cpp, "  '%c'%s\n", policy, comma);
   }
   fprintf(fp_cpp, "};\n\n");
   // Construct Native Save-Policy array
   fprintf(fp_cpp, "// Map from machine-independent register number to c_reg_save_policy\n");
   fprintf(fp_cpp, "const        char c_reg_save_policy[] = {\n");
   _register->reset_RegDefs();
   for( rdef = _register->iter_RegDefs(); rdef != NULL; rdef = next ) {
     next        = _register->iter_RegDefs();
     char policy = reg_save_policy(rdef->_c_conv);
     const char *comma = (next != NULL) ? "," : " // no trailing comma";
     fprintf(fp_cpp, "  '%c'%s\n", policy, comma);
   }
   fprintf(fp_cpp, "};\n\n");
   // Construct Register Save Type array
   fprintf(fp_cpp, "// Map from machine-independent register number to register_save_type\n");
   fprintf(fp_cpp, "const        int register_save_type[] = {\n");
   _register->reset_RegDefs();
   for( rdef = _register->iter_RegDefs(); rdef != NULL; rdef = next ) {
     next = _register->iter_RegDefs();
     const char *comma = (next != NULL) ? "," : " // no trailing comma";
     fprintf(fp_cpp, "  %s%s\n", rdef->_idealtype, comma);
   }
   fprintf(fp_cpp, "};\n\n");
   // Construct the table for reduceOp
   OutputReduceOp output_reduce_op(fp_hpp, fp_cpp, _globalNames, *this);
   build_map(output_reduce_op);
   // Construct the table for leftOp
   OutputLeftOp output_left_op(fp_hpp, fp_cpp, _globalNames, *this);
   build_map(output_left_op);
   // Construct the table for rightOp
   OutputRightOp output_right_op(fp_hpp, fp_cpp, _globalNames, *this);
   build_map(output_right_op);
   // Construct the table of rule names
   OutputRuleName output_rule_name(fp_hpp, fp_cpp, _globalNames, *this);
   build_map(output_rule_name);
   // Construct the boolean table for subsumed operands
   OutputSwallowed output_swallowed(fp_hpp, fp_cpp, _globalNames, *this);
   build_map(output_swallowed);
   // // // Preserve in case we decide to use this table instead of another
   //// Construct the boolean table for instruction chain rules
   //OutputInstChainRule output_inst_chain(fp_hpp, fp_cpp, _globalNames, *this);
   //build_map(output_inst_chain);
 }
 //---------------------------buildMachOperGenerator---------------------------
 // Recurse through match tree, building path through corresponding state tree,
 // Until we reach the constant we are looking for.
 static void path_to_constant(FILE *fp, FormDict &globals,
                              MatchNode *mnode, uint idx) {
   if ( ! mnode) return;
   unsigned    position = 0;
   const char *result   = NULL;
   const char *name     = NULL;
   const char *optype   = NULL;
   // Base Case: access constant in ideal node linked to current state node
   // Each type of constant has its own access function
   if ( (mnode->_lChild == NULL) && (mnode->_rChild == NULL)
        && mnode->base_operand(position, globals, result, name, optype) ) {
     if (         strcmp(optype,"ConI") == 0 ) {
       fprintf(fp, "_leaf->get_int()");
     } else if ( (strcmp(optype,"ConP") == 0) ) {
       fprintf(fp, "_leaf->bottom_type()->is_ptr()");
     } else if ( (strcmp(optype,"ConF") == 0) ) {
       fprintf(fp, "_leaf->getf()");
     } else if ( (strcmp(optype,"ConD") == 0) ) {
       fprintf(fp, "_leaf->getd()");
     } else if ( (strcmp(optype,"ConL") == 0) ) {
       fprintf(fp, "_leaf->get_long()");
     } else if ( (strcmp(optype,"Con")==0) ) {
       // !!!!! - Update if adding a machine-independent constant type
       fprintf(fp, "_leaf->get_int()");
       assert( false, "Unsupported constant type, pointer or indefinite");
     } else if ( (strcmp(optype,"Bool") == 0) ) {
       fprintf(fp, "_leaf->as_Bool()->_test._test");
     } else {
       assert( false, "Unsupported constant type");
     }
     return;
   }
   // If constant is in left child, build path and recurse
   uint lConsts = (mnode->_lChild) ? (mnode->_lChild->num_consts(globals) ) : 0;
   uint rConsts = (mnode->_rChild) ? (mnode->_rChild->num_consts(globals) ) : 0;
   if ( (mnode->_lChild) && (lConsts > idx) ) {
     fprintf(fp, "_kids[0]->");
     path_to_constant(fp, globals, mnode->_lChild, idx);
     return;
   }
   // If constant is in right child, build path and recurse
   if ( (mnode->_rChild) && (rConsts > (idx - lConsts) ) ) {
     idx = idx - lConsts;
     fprintf(fp, "_kids[1]->");
     path_to_constant(fp, globals, mnode->_rChild, idx);
     return;
   }
   assert( false, "ShouldNotReachHere()");
 }
 // Generate code that is executed when generating a specific Machine Operand
 static void genMachOperCase(FILE *fp, FormDict &globalNames, ArchDesc &AD,
                             OperandForm &op) {
   const char *opName         = op._ident;
   const char *opEnumName     = AD.machOperEnum(opName);
   uint        num_consts     = op.num_consts(globalNames);
   // Generate the case statement for this opcode
   fprintf(fp, "  case %s:", opEnumName);
   fprintf(fp, "\n    return new (C) %sOper(", opName);
   // Access parameters for constructor from the stat object
   //
   // Build access to condition code value
   if ( (num_consts > 0) ) {
     uint i = 0;
     path_to_constant(fp, globalNames, op._matrule, i);
     for ( i = 1; i < num_consts; ++i ) {
       fprintf(fp, ", ");
       path_to_constant(fp, globalNames, op._matrule, i);
     }
   }
   fprintf(fp, " );\n");
 }
 // Build switch to invoke "new" MachNode or MachOper
 void ArchDesc::buildMachOperGenerator(FILE *fp_cpp) {
   int idx = 0;
   // Build switch to invoke 'new' for a specific MachOper
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp,
           "//------------------------- MachOper Generator ---------------\n");
   fprintf(fp_cpp,
           "// A switch statement on the dense-packed user-defined type system\n"
           "// that invokes 'new' on the corresponding class constructor.\n");
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "MachOper *State::MachOperGenerator");
   fprintf(fp_cpp, "(int opcode, Compile* C)");
   fprintf(fp_cpp, "{\n");
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "  switch(opcode) {\n");
   // Place all user-defined operands into the mapping
   _operands.reset();
   int  opIndex = 0;
   OperandForm *op;
   for( ; (op =  (OperandForm*)_operands.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( op->ideal_only() )  continue;
     genMachOperCase(fp_cpp, _globalNames, *this, *op);
   };
   // Do not iterate over operand classes for the  operand generator!!!
   // Place all internal operands into the mapping
   _internalOpNames.reset();
   const char *iopn;
   for( ; (iopn =  _internalOpNames.iter()) != NULL; ) {
     const char *opEnumName = machOperEnum(iopn);
     // Generate the case statement for this opcode
     fprintf(fp_cpp, "  case %s:", opEnumName);
     fprintf(fp_cpp, "    return NULL;\n");
   };
   // Generate the default case for switch(opcode)
   fprintf(fp_cpp, "  \n");
   fprintf(fp_cpp, "  default:\n");
   fprintf(fp_cpp, "    fprintf(stderr, \"Default MachOper Generator invoked for: \\n\");\n");
   fprintf(fp_cpp, "    fprintf(stderr, \"   opcode = %cd\\n\", opcode);\n", '%');
   fprintf(fp_cpp, "    break;\n");
   fprintf(fp_cpp, "  }\n");
   // Generate the closing for method Matcher::MachOperGenerator
   fprintf(fp_cpp, "  return NULL;\n");
   fprintf(fp_cpp, "};\n");
 }
 //---------------------------buildMachNode-------------------------------------
 // Build a new MachNode, for MachNodeGenerator or cisc-spilling
 void ArchDesc::buildMachNode(FILE *fp_cpp, InstructForm *inst, const char *indent) {
   const char *opType  = NULL;
   const char *opClass = inst->_ident;
   // Create the MachNode object
   fprintf(fp_cpp, "%s %sNode *node = new (C) %sNode();\n",indent, opClass,opClass);
   if ( (inst->num_post_match_opnds() != 0) ) {
     // Instruction that contains operands which are not in match rule.
     //
     // Check if the first post-match component may be an interesting def
     bool           dont_care = false;
     ComponentList &comp_list = inst->_components;
     Component     *comp      = NULL;
     comp_list.reset();
     if ( comp_list.match_iter() != NULL )    dont_care = true;
     // Insert operands that are not in match-rule.
     // Only insert a DEF if the do_care flag is set
     comp_list.reset();
     while ( comp = comp_list.post_match_iter() ) {
       // Check if we don't care about DEFs or KILLs that are not USEs
       if ( dont_care && (! comp->isa(Component::USE)) ) {
         continue;
       }
       dont_care = true;
       // For each operand not in the match rule, call MachOperGenerator
       // with the enum for the opcode that needs to be built
       // and the node just built, the parent of the operand.
       ComponentList clist = inst->_components;
       int         index  = clist.operand_position(comp->_name, comp->_usedef);
       const char *opcode = machOperEnum(comp->_type);
       const char *parent = "node";
       fprintf(fp_cpp, "%s node->set_opnd_array(%d, ", indent, index);
       fprintf(fp_cpp, "MachOperGenerator(%s, C));\n", opcode);
       }
   }
   else if ( inst->is_chain_of_constant(_globalNames, opType) ) {
     // An instruction that chains from a constant!
     // In this case, we need to subsume the constant into the node
     // at operand position, oper_input_base().
     //
     // Fill in the constant
     fprintf(fp_cpp, "%s node->_opnd_array[%d] = ", indent,
             inst->oper_input_base(_globalNames));
     // #####
     // Check for multiple constants and then fill them in.
     // Just like MachOperGenerator
     const char *opName = inst->_matrule->_rChild->_opType;
     fprintf(fp_cpp, "new (C) %sOper(", opName);
     // Grab operand form
     OperandForm *op = (_globalNames[opName])->is_operand();
     // Look up the number of constants
     uint num_consts = op->num_consts(_globalNames);
     if ( (num_consts > 0) ) {
       uint i = 0;
       path_to_constant(fp_cpp, _globalNames, op->_matrule, i);
       for ( i = 1; i < num_consts; ++i ) {
         fprintf(fp_cpp, ", ");
         path_to_constant(fp_cpp, _globalNames, op->_matrule, i);
       }
     }
     fprintf(fp_cpp, " );\n");
     // #####
   }
   // Fill in the bottom_type where requested
   if ( inst->captures_bottom_type() ) {
     fprintf(fp_cpp, "%s node->_bottom_type = _leaf->bottom_type();\n", indent);
   }
   if( inst->is_ideal_if() ) {
     fprintf(fp_cpp, "%s node->_prob = _leaf->as_If()->_prob;\n", indent);
     fprintf(fp_cpp, "%s node->_fcnt = _leaf->as_If()->_fcnt;\n", indent);
   }
   if( inst->is_ideal_fastlock() ) {
     fprintf(fp_cpp, "%s node->_counters = _leaf->as_FastLock()->counters();\n", indent);
   }
 }
 //---------------------------declare_cisc_version------------------------------
 // Build CISC version of this instruction
 void InstructForm::declare_cisc_version(ArchDesc &AD, FILE *fp_hpp) {
   if( AD.can_cisc_spill() ) {
     InstructForm *inst_cisc = cisc_spill_alternate();
     if (inst_cisc != NULL) {
       fprintf(fp_hpp, "  virtual int            cisc_operand() const { return %d; }\n", cisc_spill_operand());
       fprintf(fp_hpp, "  virtual MachNode      *cisc_version(int offset, Compile* C);\n");
       fprintf(fp_hpp, "  virtual void           use_cisc_RegMask();\n");
       fprintf(fp_hpp, "  virtual const RegMask *cisc_RegMask() const { return _cisc_RegMask; }\n");
     }
   }
 }
 //---------------------------define_cisc_version-------------------------------
 // Build CISC version of this instruction
 bool InstructForm::define_cisc_version(ArchDesc &AD, FILE *fp_cpp) {
   InstructForm *inst_cisc = this->cisc_spill_alternate();
   if( AD.can_cisc_spill() && (inst_cisc != NULL) ) {
     const char   *name      = inst_cisc->_ident;
     assert( inst_cisc->num_opnds() == this->num_opnds(), "Must have same number of operands");
     OperandForm *cisc_oper = AD.cisc_spill_operand();
     assert( cisc_oper != NULL, "insanity check");
     const char *cisc_oper_name  = cisc_oper->_ident;
     assert( cisc_oper_name != NULL, "insanity check");
     //
     // Set the correct reg_mask_or_stack for the cisc operand
     fprintf(fp_cpp, "\n");
     fprintf(fp_cpp, "void %sNode::use_cisc_RegMask() {\n", this->_ident);
     // Lookup the correct reg_mask_or_stack
     const char *reg_mask_name = cisc_reg_mask_name();
     fprintf(fp_cpp, "  _cisc_RegMask = &STACK_OR_%s;\n", reg_mask_name);
     fprintf(fp_cpp, "}\n");
     //
     // Construct CISC version of this instruction
     fprintf(fp_cpp, "\n");
     fprintf(fp_cpp, "// Build CISC version of this instruction\n");
     fprintf(fp_cpp, "MachNode *%sNode::cisc_version( int offset, Compile* C ) {\n", this->_ident);
     // Create the MachNode object
     fprintf(fp_cpp, "  %sNode *node = new (C) %sNode();\n", name, name);
     // Fill in the bottom_type where requested
     if ( this->captures_bottom_type() ) {
       fprintf(fp_cpp, "  node->_bottom_type = bottom_type();\n");
     }
     fprintf(fp_cpp, "\n");
     fprintf(fp_cpp, "  // Copy _idx, inputs and operands to new node\n");
     fprintf(fp_cpp, "  fill_new_machnode(node, C);\n");
     // Construct operand to access [stack_pointer + offset]
     fprintf(fp_cpp, "  // Construct operand to access [stack_pointer + offset]\n");
     fprintf(fp_cpp, "  node->set_opnd_array(cisc_operand(), new (C) %sOper(offset));\n", cisc_oper_name);
     fprintf(fp_cpp, "\n");
     // Return result and exit scope
     fprintf(fp_cpp, "  return node;\n");
     fprintf(fp_cpp, "}\n");
     fprintf(fp_cpp, "\n");
     return true;
   }
   return false;
 }
 //---------------------------declare_short_branch_methods----------------------
 // Build prototypes for short branch methods
 void InstructForm::declare_short_branch_methods(FILE *fp_hpp) {
   if (has_short_branch_form()) {
     fprintf(fp_hpp, "  virtual MachNode      *short_branch_version(Compile* C);\n");
   }
 }
 //---------------------------define_short_branch_methods-----------------------
 // Build definitions for short branch methods
 bool InstructForm::define_short_branch_methods(FILE *fp_cpp) {
   if (has_short_branch_form()) {
     InstructForm *short_branch = short_branch_form();
     const char   *name         = short_branch->_ident;
     // Construct short_branch_version() method.
     fprintf(fp_cpp, "// Build short branch version of this instruction\n");
     fprintf(fp_cpp, "MachNode *%sNode::short_branch_version(Compile* C) {\n", this->_ident);
     // Create the MachNode object
     fprintf(fp_cpp, "  %sNode *node = new (C) %sNode();\n", name, name);
     if( is_ideal_if() ) {
       fprintf(fp_cpp, "  node->_prob = _prob;\n");
       fprintf(fp_cpp, "  node->_fcnt = _fcnt;\n");
     }
     // Fill in the bottom_type where requested
     if ( this->captures_bottom_type() ) {
       fprintf(fp_cpp, "  node->_bottom_type = bottom_type();\n");
     }
     fprintf(fp_cpp, "\n");
     // Short branch version must use same node index for access
     // through allocator's tables
     fprintf(fp_cpp, "  // Copy _idx, inputs and operands to new node\n");
     fprintf(fp_cpp, "  fill_new_machnode(node, C);\n");
     // Return result and exit scope
     fprintf(fp_cpp, "  return node;\n");
     fprintf(fp_cpp, "}\n");
     fprintf(fp_cpp,"\n");
     return true;
   }
   return false;
 }
 //---------------------------buildMachNodeGenerator----------------------------
 // Build switch to invoke appropriate "new" MachNode for an opcode
 void ArchDesc::buildMachNodeGenerator(FILE *fp_cpp) {
   // Build switch to invoke 'new' for a specific MachNode
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp,
           "//------------------------- MachNode Generator ---------------\n");
   fprintf(fp_cpp,
           "// A switch statement on the dense-packed user-defined type system\n"
           "// that invokes 'new' on the corresponding class constructor.\n");
   fprintf(fp_cpp, "\n");
   fprintf(fp_cpp, "MachNode *State::MachNodeGenerator");
   fprintf(fp_cpp, "(int opcode, Compile* C)");
   fprintf(fp_cpp, "{\n");
   fprintf(fp_cpp, "  switch(opcode) {\n");
   // Provide constructor for all user-defined instructions
   _instructions.reset();
   int  opIndex = operandFormCount();
   InstructForm *inst;
   for( ; (inst = (InstructForm*)_instructions.iter()) != NULL; ) {
     // Ensure that matrule is defined.
     if ( inst->_matrule == NULL ) continue;
     int         opcode  = opIndex++;
     const char *opClass = inst->_ident;
     char       *opType  = NULL;
     // Generate the case statement for this instruction
     fprintf(fp_cpp, "  case %s_rule:", opClass);
     // Start local scope
     fprintf(fp_cpp, "  {\n");
     // Generate code to construct the new MachNode
     buildMachNode(fp_cpp, inst, "     ");
     // Return result and exit scope
     fprintf(fp_cpp, "      return node;\n");
     fprintf(fp_cpp, "    }\n");
   }
   // Generate the default case for switch(opcode)
   fprintf(fp_cpp, "  \n");
   fprintf(fp_cpp, "  default:\n");
   fprintf(fp_cpp, "    fprintf(stderr, \"Default MachNode Generator invoked for: \\n\");\n");
   fprintf(fp_cpp, "    fprintf(stderr, \"   opcode = %cd\\n\", opcode);\n", '%');
   fprintf(fp_cpp, "    break;\n");
   fprintf(fp_cpp, "  };\n");
   // Generate the closing for method Matcher::MachNodeGenerator
   fprintf(fp_cpp, "  return NULL;\n");
   fprintf(fp_cpp, "}\n");
 }
 //---------------------------buildInstructMatchCheck--------------------------
 // Output the method to Matcher which checks whether or not a specific
 // instruction has a matching rule for the host architecture.
 void ArchDesc::buildInstructMatchCheck(FILE *fp_cpp) const {
   fprintf(fp_cpp, "\n\n");
   fprintf(fp_cpp, "const bool Matcher::has_match_rule(int opcode) {\n");
   fprintf(fp_cpp, "  assert(_last_machine_leaf < opcode && opcode < _last_opcode, \"opcode in range\");\n");
   fprintf(fp_cpp, "  return _hasMatchRule[opcode];\n");
   fprintf(fp_cpp, "}\n\n");
   fprintf(fp_cpp, "const bool Matcher::_hasMatchRule[_last_opcode] = {\n");
   int i;
   for (i = 0; i < _last_opcode - 1; i++) {
     fprintf(fp_cpp, "    %-5s,  // %s\n",
             _has_match_rule[i] ? "true" : "false",
             NodeClassNames[i]);
   }
   fprintf(fp_cpp, "    %-5s   // %s\n",
           _has_match_rule[i] ? "true" : "false",
           NodeClassNames[i]);
   fprintf(fp_cpp, "};\n");
 }
 //---------------------------buildFrameMethods---------------------------------
 // Output the methods to Matcher which specify frame behavior
 void ArchDesc::buildFrameMethods(FILE *fp_cpp) {
   fprintf(fp_cpp,"\n\n");
   // Stack Direction
   fprintf(fp_cpp,"bool Matcher::stack_direction() const { return %s; }\n\n",
           _frame->_direction ? "true" : "false");
   // Sync Stack Slots
   fprintf(fp_cpp,"int Compile::sync_stack_slots() const { return %s; }\n\n",
           _frame->_sync_stack_slots);
   // Java Stack Alignment
   fprintf(fp_cpp,"uint Matcher::stack_alignment_in_bytes() { return %s; }\n\n",
           _frame->_alignment);
   // Java Return Address Location
   fprintf(fp_cpp,"OptoReg::Name Matcher::return_addr() const {");
   if (_frame->_return_addr_loc) {
     fprintf(fp_cpp," return OptoReg::Name(%s_num); }\n\n",
             _frame->_return_addr);
   }
   else {
     fprintf(fp_cpp," return OptoReg::stack2reg(%s); }\n\n",
             _frame->_return_addr);
   }
   // Java Stack Slot Preservation
   fprintf(fp_cpp,"uint Compile::in_preserve_stack_slots() ");
   fprintf(fp_cpp,"{ return %s; }\n\n", _frame->_in_preserve_slots);
   // Top Of Stack Slot Preservation, for both Java and C
   fprintf(fp_cpp,"uint Compile::out_preserve_stack_slots() ");
   fprintf(fp_cpp,"{ return SharedRuntime::out_preserve_stack_slots(); }\n\n");
   // varargs C out slots killed
   fprintf(fp_cpp,"uint Compile::varargs_C_out_slots_killed() const ");
   fprintf(fp_cpp,"{ return %s; }\n\n", _frame->_varargs_C_out_slots_killed);
   // Java Argument Position
   fprintf(fp_cpp,"void Matcher::calling_convention(BasicType *sig_bt, VMRegPair *regs, uint length, bool is_outgoing) {\n");
   fprintf(fp_cpp,"%s\n", _frame->_calling_convention);
   fprintf(fp_cpp,"}\n\n");
   // Native Argument Position
   fprintf(fp_cpp,"void Matcher::c_calling_convention(BasicType *sig_bt, VMRegPair *regs, uint length) {\n");
   fprintf(fp_cpp,"%s\n", _frame->_c_calling_convention);
   fprintf(fp_cpp,"}\n\n");
   // Java Return Value Location
   fprintf(fp_cpp,"OptoRegPair Matcher::return_value(int ideal_reg, bool is_outgoing) {\n");
   fprintf(fp_cpp,"%s\n", _frame->_return_value);
   fprintf(fp_cpp,"}\n\n");
   // Native Return Value Location
   fprintf(fp_cpp,"OptoRegPair Matcher::c_return_value(int ideal_reg, bool is_outgoing) {\n");
   fprintf(fp_cpp,"%s\n", _frame->_c_return_value);
   fprintf(fp_cpp,"}\n\n");
   // Inline Cache Register, mask definition, and encoding
   fprintf(fp_cpp,"OptoReg::Name Matcher::inline_cache_reg() {");
   fprintf(fp_cpp," return OptoReg::Name(%s_num); }\n\n",
           _frame->_inline_cache_reg);
   fprintf(fp_cpp,"const RegMask &Matcher::inline_cache_reg_mask() {");
   fprintf(fp_cpp," return INLINE_CACHE_REG_mask; }\n\n");
   fprintf(fp_cpp,"int Matcher::inline_cache_reg_encode() {");
   fprintf(fp_cpp," return _regEncode[inline_cache_reg()]; }\n\n");
   // Interpreter's Method Oop Register, mask definition, and encoding
   fprintf(fp_cpp,"OptoReg::Name Matcher::interpreter_method_oop_reg() {");
   fprintf(fp_cpp," return OptoReg::Name(%s_num); }\n\n",
           _frame->_interpreter_method_oop_reg);
   fprintf(fp_cpp,"const RegMask &Matcher::interpreter_method_oop_reg_mask() {");
   fprintf(fp_cpp," return INTERPRETER_METHOD_OOP_REG_mask; }\n\n");
   fprintf(fp_cpp,"int Matcher::interpreter_method_oop_reg_encode() {");
   fprintf(fp_cpp," return _regEncode[interpreter_method_oop_reg()]; }\n\n");
   // Interpreter's Frame Pointer Register, mask definition, and encoding
   fprintf(fp_cpp,"OptoReg::Name Matcher::interpreter_frame_pointer_reg() {");
   if (_frame->_interpreter_frame_pointer_reg == NULL)
     fprintf(fp_cpp," return OptoReg::Bad; }\n\n");
   else
     fprintf(fp_cpp," return OptoReg::Name(%s_num); }\n\n",
             _frame->_interpreter_frame_pointer_reg);
   fprintf(fp_cpp,"const RegMask &Matcher::interpreter_frame_pointer_reg_mask() {");
   if (_frame->_interpreter_frame_pointer_reg == NULL)
     fprintf(fp_cpp," static RegMask dummy; return dummy; }\n\n");
   else
     fprintf(fp_cpp," return INTERPRETER_FRAME_POINTER_REG_mask; }\n\n");
   // Frame Pointer definition
   /* CNC - I can not contemplate having a different frame pointer between
      Java and native code; makes my head hurt to think about it.
   fprintf(fp_cpp,"OptoReg::Name Matcher::frame_pointer() const {");
   fprintf(fp_cpp," return OptoReg::Name(%s_num); }\n\n",
           _frame->_frame_pointer);
   */
   // (Native) Frame Pointer definition
   fprintf(fp_cpp,"OptoReg::Name Matcher::c_frame_pointer() const {");
   fprintf(fp_cpp," return OptoReg::Name(%s_num); }\n\n",
           _frame->_frame_pointer);
   // Number of callee-save + always-save registers for calling convention
   fprintf(fp_cpp, "// Number of callee-save + always-save registers\n");
   fprintf(fp_cpp, "int  Matcher::number_of_saved_registers() {\n");
   RegDef *rdef;
   int nof_saved_registers = 0;
   _register->reset_RegDefs();
   while( (rdef = _register->iter_RegDefs()) != NULL ) {
     if( !strcmp(rdef->_callconv, "SOE") ||  !strcmp(rdef->_callconv, "AS") )
       ++nof_saved_registers;
   }
   fprintf(fp_cpp, "  return %d;\n", nof_saved_registers);
   fprintf(fp_cpp, "};\n\n");
 }
 static int PrintAdlcCisc = 0;
 //---------------------------identify_cisc_spilling----------------------------
 // Get info for the CISC_oracle and MachNode::cisc_version()
 void ArchDesc::identify_cisc_spill_instructions() {
   // Find the user-defined operand for cisc-spilling
   if( _frame->_cisc_spilling_operand_name != NULL ) {
     const Form *form = _globalNames[_frame->_cisc_spilling_operand_name];
     OperandForm *oper = form ? form->is_operand() : NULL;
     // Verify the user's suggestion
     if( oper != NULL ) {
       // Ensure that match field is defined.
       if ( oper->_matrule != NULL )  {
         MatchRule &mrule = *oper->_matrule;
         if( strcmp(mrule._opType,"AddP") == 0 ) {
           MatchNode *left = mrule._lChild;
           MatchNode *right= mrule._rChild;
           if( left != NULL && right != NULL ) {
             const Form *left_op  = _globalNames[left->_opType]->is_operand();
             const Form *right_op = _globalNames[right->_opType]->is_operand();
             if(  (left_op != NULL && right_op != NULL)
               && (left_op->interface_type(_globalNames) == Form::register_interface)
               && (right_op->interface_type(_globalNames) == Form::constant_interface) ) {
               // Successfully verified operand
               set_cisc_spill_operand( oper );
               if( _cisc_spill_debug ) {
                 fprintf(stderr, "\n\nVerified CISC-spill operand %s\n\n", oper->_ident);
              }
             }
           }
         }
       }
     }
   }
   if( cisc_spill_operand() != NULL ) {
     // N^2 comparison of instructions looking for a cisc-spilling version
     _instructions.reset();
     InstructForm *instr;
     for( ; (instr = (InstructForm*)_instructions.iter()) != NULL; ) {
       // Ensure that match field is defined.
       if ( instr->_matrule == NULL )  continue;
       MatchRule &mrule = *instr->_matrule;
       Predicate *pred  =  instr->build_predicate();
       // Grab the machine type of the operand
       const char *rootOp = instr->_ident;
       mrule._machType    = rootOp;
       // Find result type for match
       const char *result = instr->reduce_result();
       if( PrintAdlcCisc ) fprintf(stderr, "  new instruction %s \n", instr->_ident ? instr->_ident : " ");
       bool  found_cisc_alternate = false;
       _instructions.reset2();
       InstructForm *instr2;
       for( ; !found_cisc_alternate && (instr2 = (InstructForm*)_instructions.iter2()) != NULL; ) {
         // Ensure that match field is defined.
         if( PrintAdlcCisc ) fprintf(stderr, "  instr2 == %s \n", instr2->_ident ? instr2->_ident : " ");
         if ( instr2->_matrule != NULL
             && (instr != instr2 )                // Skip self
             && (instr2->reduce_result() != NULL) // want same result
             && (strcmp(result, instr2->reduce_result()) == 0)) {
           MatchRule &mrule2 = *instr2->_matrule;
           Predicate *pred2  =  instr2->build_predicate();
           found_cisc_alternate = instr->cisc_spills_to(*this, instr2);
         }
       }
     }
   }
 }
 //---------------------------build_cisc_spilling-------------------------------
 // Get info for the CISC_oracle and MachNode::cisc_version()
 void ArchDesc::build_cisc_spill_instructions(FILE *fp_hpp, FILE *fp_cpp) {
   // Output the table for cisc spilling
   fprintf(fp_cpp, "//  The following instructions can cisc-spill\n");
   _instructions.reset();
   InstructForm *inst = NULL;
   for(; (inst = (InstructForm*)_instructions.iter()) != NULL; ) {
     // Ensure this is a machine-world instruction
     if ( inst->ideal_only() )  continue;
     const char *inst_name = inst->_ident;
     int   operand   = inst->cisc_spill_operand();
     if( operand != AdlcVMDeps::Not_cisc_spillable ) {
       InstructForm *inst2 = inst->cisc_spill_alternate();
       fprintf(fp_cpp, "//  %s can cisc-spill operand %d to %s\n", inst->_ident, operand, inst2->_ident);
     }
   }
   fprintf(fp_cpp, "\n\n");
 }
 //---------------------------identify_short_branches----------------------------
 // Get info for our short branch replacement oracle.
 void ArchDesc::identify_short_branches() {
   // Walk over all instructions, checking to see if they match a short
   // branching alternate.
   _instructions.reset();
   InstructForm *instr;
   while( (instr = (InstructForm*)_instructions.iter()) != NULL ) {
     // The instruction must have a match rule.
     if (instr->_matrule != NULL &&
         instr->is_short_branch()) {
       _instructions.reset2();
       InstructForm *instr2;
       while( (instr2 = (InstructForm*)_instructions.iter2()) != NULL ) {
         instr2->check_branch_variant(*this, instr);
       }
     }
   }
 }
 //---------------------------identify_unique_operands---------------------------
 // Identify unique operands.
 void ArchDesc::identify_unique_operands() {
   // Walk over all instructions.
   _instructions.reset();
   InstructForm *instr;
   while( (instr = (InstructForm*)_instructions.iter()) != NULL ) {
     // Ensure this is a machine-world instruction
     if (!instr->ideal_only()) {
       instr->set_unique_opnds();
     }
   }
 }

Mercurial > jdk8-mips64-public > hotspot / annotate

src/share/vm/adlc/output_c.cpp@a61af66fc99e (annotated)

src/share/vm/adlc/output_c.cpp