src/hotspot/share/compiler/abstractDisassembler.cpp - toolchain/jdk/jdk21 - Git at Google

 /*
  * Copyright (c) 2019, 2023, Oracle and/or its affiliates. All rights reserved.
  * Copyright (c) 2019 SAP SE. 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 Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 // AbstractDisassembler is the base class for
 // platform-specific Disassembler classes.

 #include "precompiled.hpp"
 #include "asm/assembler.inline.hpp"
 #include "compiler/abstractDisassembler.hpp"
 #include "oops/oop.inline.hpp"
 #include "utilities/debug.hpp"
 #include "utilities/ostream.hpp"

 // Default values for what is being printed as line prefix when disassembling a single instruction.
 // Can be overridden by command line parameter PrintAssemblyOptions.
 bool AbstractDisassembler::_show_data_hex      = true;
 bool AbstractDisassembler::_show_data_int      = false;
 bool AbstractDisassembler::_show_data_float    = false;
 bool AbstractDisassembler::_align_instr        = true;
 bool AbstractDisassembler::_show_pc            = true;
 bool AbstractDisassembler::_show_offset        = false;
 bool AbstractDisassembler::_show_structs       = true;
 bool AbstractDisassembler::_show_comment       = true;
 bool AbstractDisassembler::_show_block_comment = true;

 // set "true" to see what's in memory bit by bit
 // might prove cumbersome on platforms where instr_len is hard to find out
 bool AbstractDisassembler::_show_bytes         = false;

 // Return #bytes printed. Callers may use that for output alignment.
 // Print instruction address, and offset from blob begin.
 // Offset width (2, 4, 6, 8 bytes) is adapted to size of blob.
 // Working assumption: we are at st->bol() upon entry. If not, it's the
 //                     caller's responsibility to guarantee proper alignment.
 int AbstractDisassembler::print_location(address here, address begin, address end, outputStream* st, bool align, bool print_header) {
   const int     pos_0  = st->position();

   if (show_pc() || show_offset()) {
     st->print(" ");
   }

   if (show_pc()) {
     if (print_header) {
       st->print(" %*s", 18, "Address");
     } else {
       st->print(" " PTR_FORMAT, p2i(here));
     }
   }

   if (show_offset()) {
 #ifdef ASSERT
     if ((uintptr_t)begin > (uintptr_t)here) st->print(">>begin(" PTR_FORMAT ") > here(" PTR_FORMAT ")<<", p2i(begin), p2i(here));
     if ((uintptr_t)end   < (uintptr_t)here) st->print(">>  end(" PTR_FORMAT ") < here(" PTR_FORMAT ")<<", p2i(end),   p2i(here));
     assert((uintptr_t)begin <= (uintptr_t)end, "inverted address range");
 #endif
     const int blob_len = end - begin;
     const int offset   = here - begin;
     const int width    = (blob_len < (1<< 8)) ? 2 : (blob_len < (1<<16)) ? 4 : (blob_len < (1<<24)) ? 6 : 8;
     if (print_header) {
       st->print(" %*s", width+5, "offset");
     } else {
       st->print(" (+0x%*.*x)", width, width, offset);
     }
   }

   if ((show_pc() || show_offset()) && !print_header) {
     st->print(": ");
   }

   if (align) {
     const uint tabspacing  = 8;
     const uint pos         = st->position();
     const uint aligned_pos = ((pos+tabspacing-1)/tabspacing)*tabspacing /* - 1 */;
     st->fill_to(aligned_pos);
   }

   return st->position() - pos_0;
 }


 // Return #bytes printed. Callers may use that for output alignment.
 // Print instruction in hexadecimal representation, using 2-byte blocks.
 // Used with real disassemblies. Not so useful with abstract disassemblies.
 int AbstractDisassembler::print_instruction(address here, int len, int max_len, outputStream* st, bool align, bool print_header) {
   if (show_bytes()) {
     const int block_bytes = 2;
     const int pos_0       = st->position();
     address   pos         = here;

     //---<  print instruction bytes in blocks  >---
     // must print byte by byte: address might be unaligned.
     for (; pos <= here + len - block_bytes; pos += block_bytes) {
       for (address byte = pos; byte < pos + block_bytes; byte++) {
         st->print("%2.2x", *byte);
       }
       st->print(" ");
     }

     //---<  Print the remaining bytes of the instruction  >---
     if ((len & (block_bytes - 1)) != 0) {
       for (; pos < here + len; pos++) {
         st->print("%2.2x", *pos);
       }
     }

     //---<  filler for shorter than max_len instructions  >---
     for (int i = len+1; i < max_len; i++) {
       st->print("  ");
     }

     st->print(" "); // separator space.
     print_delimiter(st);
     return st->position() - pos_0;
   }

   if (align) {
     const uint tabspacing  = 8;
     const uint pos         = st->position();
     const uint aligned_pos = ((pos+tabspacing-1)/tabspacing)*tabspacing /* - 1 */;
     st->fill_to(aligned_pos);
   }

   return 0;
 }


 // Return #bytes printed. Callers may use that for output alignment.
 // Print data (e.g. constant pool entries) in hex format.
 // Depending on the alignment, short, int, and long entities are printed.
 // If selected, data is formatted as int/long and float/double values in addition.
 int AbstractDisassembler::print_hexdata(address here, int len, outputStream* st, bool print_header) {
   const int tsize = 8;
   const int pos_0 = st->position();
   int pos   = pos_0;
   int align = ((pos+tsize-1)/tsize)*tsize;
   st->fill_to(align);

   //---<  printing hex data  >---
   if (show_data_hex()) {
     switch (len) {
       case 1: if (print_header) {
                 st->print("hex1");
               } else {
                 st->print("0x%02x", *here);
               }
               st->fill_to(align += tsize);
       case 2: if (print_header) {
                 st->print("  hex2");
               } else {
                 if (((uintptr_t)(here)&0x01) == 0) {
                   st->print("0x%04x",   *((jushort*)here));
                 }
               }
               st->fill_to(align += tsize);
       case 4: if (print_header) {
                 st->print("      hex4");
               } else {
                 if (((uintptr_t)(here)&0x03) == 0) {
                   st->print("0x%08x",   *((juint*)here));
                 }
               }
               st->fill_to(align += 2*tsize);
       case 8: if (print_header) {
                 st->print("              hex8");
               } else {
                 if (((uintptr_t)(here)&0x07) == 0) {
                   st->print(PTR_FORMAT, *((uintptr_t*)here));
                 }
               }
               st->fill_to(align += 3*tsize);
               break;
       default: ;
     }
     pos   = st->position();
     align = ((pos+tsize-1)/tsize)*tsize;
     st->fill_to(align);
   }

   //---<  printing int/long data  >---
   if (show_data_int()) {
     switch (len) {
       case 4: if (print_header) {
                 st->print("         int");
               } else {
                 if (((uintptr_t)(here)&0x03) == 0) {
                   st->print("%12.1d",  *((jint*)here));
                 }
               }
               st->fill_to(align += 2*tsize);
       case 8: if (print_header) {
                 st->print("                   long");
               } else {
                 if (((uintptr_t)(here)&0x07) == 0) {
                   st->print(JLONG_FORMAT_W(23), *((jlong*)here));
                 }
               }
               st->fill_to(align += 3*tsize);
               break;
       default: ;
     }
     pos   = st->position();
     align = ((pos+tsize-1)/tsize)*tsize;
     st->fill_to(align);
   }

   //---<  printing float/double data  >---
   if (show_data_float()) {
     switch (len) {
       case 4: if (print_header) {
                 st->print("          float");
               } else {
                 if (((uintptr_t)(here)&0x03) == 0) {
                   st->print("%15.7e",  (double)*((float*)here));
                 }
               }
               st->fill_to(align += 2*tsize);
       case 8: if (print_header) {
                 st->print("                 double");
               } else {
                 if (((uintptr_t)(here)&0x07) == 0) {
                   st->print("%23.15e",         *((double*)here));
                 }
               }
               st->fill_to(align += 3*tsize);
               break;
       default: ;
     }
   }

   return st->position() - pos_0;
 }


 // Return #bytes printed. Callers may use that for output alignment.
 // Print an instruction delimiter.
 int AbstractDisassembler::print_delimiter(outputStream* st) {
   if (align_instr()) { st->print("| "); return 2; }
   else               return 0;
 }


 // Decodes the one instruction at address start in a platform-independent format.
 // Returns the start of the next instruction (which is 'start' plus 'instruction_size_in_bytes').
 // The parameter max_instr_size_in_bytes is used for output alignment purposes only.
 address AbstractDisassembler::decode_instruction_abstract(address start,
                                                           outputStream* st,
                                                           const int instruction_size_in_bytes,
                                                           const int max_instr_size_in_bytes) {
   assert(instruction_size_in_bytes > 0, "no zero-size instructions!");
   assert(max_instr_size_in_bytes >= instruction_size_in_bytes, "inconsistent call parameters");

   //---<  current instruction is at the start address  >---
   unsigned char* current = (unsigned char*) start;
   int            filler_limit = align_instr() ? max_instr_size_in_bytes : ((instruction_size_in_bytes+abstract_instruction_bytes_per_block-1)/abstract_instruction_bytes_per_block)
                                                                           *abstract_instruction_bytes_per_block;

   //---<  print the instruction's bytes  >---
   for (int i = 1; i <= instruction_size_in_bytes; i++) {
     st->print("%02x", *current);
     ++current;
     if (abstract_instruction_bytes_per_block <= max_instr_size_in_bytes) {
       if (i%abstract_instruction_bytes_per_block == 0) st->print(" ");
     } else {
       if (i == instruction_size_in_bytes) st->print(" ");
     }
   }

   //---<  print some filler spaces to column-align instructions  >---
   for (int i = instruction_size_in_bytes+1; i <= filler_limit; i++) {
     st->print("  ");
     if (abstract_instruction_bytes_per_block <= max_instr_size_in_bytes) {
       if (i%abstract_instruction_bytes_per_block == 0) st->print(" ");
     } else {
       if (i == instruction_size_in_bytes) st->print(" ");
     }
   }

   //---<  the address of the next instruction  >---
   return (address) current;
 }


 // Decodes all instructions in the given range [start..end)
 // calling decode_instruction_abstract for each instruction.
 // The format is platform dependent only to the extend that
 // it respects the actual instruction length where possible.
 // Does not print any markers or decorators.
 void AbstractDisassembler::decode_range_abstract(address range_start, address range_end,
                                                  address start, address end,
                                                  outputStream* st,
                                                  const int max_instr_size_in_bytes) {
   assert(st != nullptr, "need an output stream (no default)!");
   int     idx = 0;
   address pos = range_start;

   while ((pos != nullptr) && (pos < range_end)) {
     int instr_size_in_bytes = Assembler::instr_len(pos);

     if (idx == 0) print_location(pos, start, end, st, false, false);
     else          print_delimiter(st);

     //---<  print the instruction's bytes  >---
     // don't access storage beyond end of range
     if (pos + instr_size_in_bytes <= range_end) {
       pos = decode_instruction_abstract(pos, st, instr_size_in_bytes, max_instr_size_in_bytes);
     } else {
       // If the range to be decoded contains garbage at the end (e.g. 0xcc initializer bytes),
       // instruction size calculation may run out of sync. Just terminate in that case.
       pos = range_end;
     }

     idx += instr_size_in_bytes;
     if (start_newline(idx)) {
       st->cr();
       idx = 0;
     }
   }
 }


 // Decodes all instructions in the given range [start..end).
 // The output is enclosed in [MachCode] and [/MachCode] tags for later recognition.
 // The format is platform dependent only to the extend that
 // it respects the actual instruction length where possible.
 void AbstractDisassembler::decode_abstract(address start, address end, outputStream* ost,
                                            const int max_instr_size_in_bytes) {
   int     idx = 0;
   address pos = start;

   outputStream* st = (ost == nullptr) ? tty : ost;

   //---<  Open the output (Marker for post-mortem disassembler)  >---
   st->bol();
   st->print_cr("[MachCode]");

   decode_range_abstract(start, end, start, end, st, max_instr_size_in_bytes);

   //---<  Close the output (Marker for post-mortem disassembler)  >---
   st->bol();
   st->print_cr("[/MachCode]");
 }
	/*
	* Copyright (c) 2019, 2023, Oracle and/or its affiliates. All rights reserved.
	* Copyright (c) 2019 SAP SE. 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 Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	// AbstractDisassembler is the base class for
	// platform-specific Disassembler classes.

	#include "precompiled.hpp"
	#include "asm/assembler.inline.hpp"
	#include "compiler/abstractDisassembler.hpp"
	#include "oops/oop.inline.hpp"
	#include "utilities/debug.hpp"
	#include "utilities/ostream.hpp"

	// Default values for what is being printed as line prefix when disassembling a single instruction.
	// Can be overridden by command line parameter PrintAssemblyOptions.
	bool AbstractDisassembler::_show_data_hex = true;
	bool AbstractDisassembler::_show_data_int = false;
	bool AbstractDisassembler::_show_data_float = false;
	bool AbstractDisassembler::_align_instr = true;
	bool AbstractDisassembler::_show_pc = true;
	bool AbstractDisassembler::_show_offset = false;
	bool AbstractDisassembler::_show_structs = true;
	bool AbstractDisassembler::_show_comment = true;
	bool AbstractDisassembler::_show_block_comment = true;

	// set "true" to see what's in memory bit by bit
	// might prove cumbersome on platforms where instr_len is hard to find out
	bool AbstractDisassembler::_show_bytes = false;

	// Return #bytes printed. Callers may use that for output alignment.
	// Print instruction address, and offset from blob begin.
	// Offset width (2, 4, 6, 8 bytes) is adapted to size of blob.
	// Working assumption: we are at st->bol() upon entry. If not, it's the
	// caller's responsibility to guarantee proper alignment.
	int AbstractDisassembler::print_location(address here, address begin, address end, outputStream* st, bool align, bool print_header) {
	const int pos_0 = st->position();

	if (show_pc() \|\| show_offset()) {
	st->print(" ");
	}

	if (show_pc()) {
	if (print_header) {
	st->print(" %*s", 18, "Address");
	} else {
	st->print(" " PTR_FORMAT, p2i(here));
	}
	}

	if (show_offset()) {
	#ifdef ASSERT
	if ((uintptr_t)begin > (uintptr_t)here) st->print(">>begin(" PTR_FORMAT ") > here(" PTR_FORMAT ")<<", p2i(begin), p2i(here));
	if ((uintptr_t)end < (uintptr_t)here) st->print(">> end(" PTR_FORMAT ") < here(" PTR_FORMAT ")<<", p2i(end), p2i(here));
	assert((uintptr_t)begin <= (uintptr_t)end, "inverted address range");
	#endif
	const int blob_len = end - begin;
	const int offset = here - begin;
	const int width = (blob_len < (1<< 8)) ? 2 : (blob_len < (1<<16)) ? 4 : (blob_len < (1<<24)) ? 6 : 8;
	if (print_header) {
	st->print(" %*s", width+5, "offset");
	} else {
	st->print(" (+0x%.x)", width, width, offset);
	}
	}

	if ((show_pc() \|\| show_offset()) && !print_header) {
	st->print(": ");
	}

	if (align) {
	const uint tabspacing = 8;
	const uint pos = st->position();
	const uint aligned_pos = ((pos+tabspacing-1)/tabspacing)tabspacing / - 1 */;
	st->fill_to(aligned_pos);
	}

	return st->position() - pos_0;
	}


	// Return #bytes printed. Callers may use that for output alignment.
	// Print instruction in hexadecimal representation, using 2-byte blocks.
	// Used with real disassemblies. Not so useful with abstract disassemblies.
	int AbstractDisassembler::print_instruction(address here, int len, int max_len, outputStream* st, bool align, bool print_header) {
	if (show_bytes()) {
	const int block_bytes = 2;
	const int pos_0 = st->position();
	address pos = here;

	//---< print instruction bytes in blocks >---
	// must print byte by byte: address might be unaligned.
	for (; pos <= here + len - block_bytes; pos += block_bytes) {
	for (address byte = pos; byte < pos + block_bytes; byte++) {
	st->print("%2.2x", *byte);
	}
	st->print(" ");
	}

	//---< Print the remaining bytes of the instruction >---
	if ((len & (block_bytes - 1)) != 0) {
	for (; pos < here + len; pos++) {
	st->print("%2.2x", *pos);
	}
	}

	//---< filler for shorter than max_len instructions >---
	for (int i = len+1; i < max_len; i++) {
	st->print(" ");
	}

	st->print(" "); // separator space.
	print_delimiter(st);
	return st->position() - pos_0;
	}

	if (align) {
	const uint tabspacing = 8;
	const uint pos = st->position();
	const uint aligned_pos = ((pos+tabspacing-1)/tabspacing)tabspacing / - 1 */;
	st->fill_to(aligned_pos);
	}

	return 0;
	}


	// Return #bytes printed. Callers may use that for output alignment.
	// Print data (e.g. constant pool entries) in hex format.
	// Depending on the alignment, short, int, and long entities are printed.
	// If selected, data is formatted as int/long and float/double values in addition.
	int AbstractDisassembler::print_hexdata(address here, int len, outputStream* st, bool print_header) {
	const int tsize = 8;
	const int pos_0 = st->position();
	int pos = pos_0;
	int align = ((pos+tsize-1)/tsize)*tsize;
	st->fill_to(align);

	//---< printing hex data >---
	if (show_data_hex()) {
	switch (len) {
	case 1: if (print_header) {
	st->print("hex1");
	} else {
	st->print("0x%02x", *here);
	}
	st->fill_to(align += tsize);
	case 2: if (print_header) {
	st->print(" hex2");
	} else {
	if (((uintptr_t)(here)&0x01) == 0) {
	st->print("0x%04x", ((jushort)here));
	}
	}
	st->fill_to(align += tsize);
	case 4: if (print_header) {
	st->print(" hex4");
	} else {
	if (((uintptr_t)(here)&0x03) == 0) {
	st->print("0x%08x", ((juint)here));
	}
	}
	st->fill_to(align += 2*tsize);
	case 8: if (print_header) {
	st->print(" hex8");
	} else {
	if (((uintptr_t)(here)&0x07) == 0) {
	st->print(PTR_FORMAT, ((uintptr_t)here));
	}
	}
	st->fill_to(align += 3*tsize);
	break;
	default: ;
	}
	pos = st->position();
	align = ((pos+tsize-1)/tsize)*tsize;
	st->fill_to(align);
	}

	//---< printing int/long data >---
	if (show_data_int()) {
	switch (len) {
	case 4: if (print_header) {
	st->print(" int");
	} else {
	if (((uintptr_t)(here)&0x03) == 0) {
	st->print("%12.1d", ((jint)here));
	}
	}
	st->fill_to(align += 2*tsize);
	case 8: if (print_header) {
	st->print(" long");
	} else {
	if (((uintptr_t)(here)&0x07) == 0) {
	st->print(JLONG_FORMAT_W(23), ((jlong)here));
	}
	}
	st->fill_to(align += 3*tsize);
	break;
	default: ;
	}
	pos = st->position();
	align = ((pos+tsize-1)/tsize)*tsize;
	st->fill_to(align);
	}

	//---< printing float/double data >---
	if (show_data_float()) {
	switch (len) {
	case 4: if (print_header) {
	st->print(" float");
	} else {
	if (((uintptr_t)(here)&0x03) == 0) {
	st->print("%15.7e", (double)((float)here));
	}
	}
	st->fill_to(align += 2*tsize);
	case 8: if (print_header) {
	st->print(" double");
	} else {
	if (((uintptr_t)(here)&0x07) == 0) {
	st->print("%23.15e", ((double)here));
	}
	}
	st->fill_to(align += 3*tsize);
	break;
	default: ;
	}
	}

	return st->position() - pos_0;
	}


	// Return #bytes printed. Callers may use that for output alignment.
	// Print an instruction delimiter.
	int AbstractDisassembler::print_delimiter(outputStream* st) {
	if (align_instr()) { st->print("\| "); return 2; }
	else return 0;
	}


	// Decodes the one instruction at address start in a platform-independent format.
	// Returns the start of the next instruction (which is 'start' plus 'instruction_size_in_bytes').
	// The parameter max_instr_size_in_bytes is used for output alignment purposes only.
	address AbstractDisassembler::decode_instruction_abstract(address start,
	outputStream* st,
	const int instruction_size_in_bytes,
	const int max_instr_size_in_bytes) {
	assert(instruction_size_in_bytes > 0, "no zero-size instructions!");
	assert(max_instr_size_in_bytes >= instruction_size_in_bytes, "inconsistent call parameters");

	//---< current instruction is at the start address >---
	unsigned char* current = (unsigned char*) start;
	int filler_limit = align_instr() ? max_instr_size_in_bytes : ((instruction_size_in_bytes+abstract_instruction_bytes_per_block-1)/abstract_instruction_bytes_per_block)
	*abstract_instruction_bytes_per_block;

	//---< print the instruction's bytes >---
	for (int i = 1; i <= instruction_size_in_bytes; i++) {
	st->print("%02x", *current);
	++current;
	if (abstract_instruction_bytes_per_block <= max_instr_size_in_bytes) {
	if (i%abstract_instruction_bytes_per_block == 0) st->print(" ");
	} else {
	if (i == instruction_size_in_bytes) st->print(" ");
	}
	}

	//---< print some filler spaces to column-align instructions >---
	for (int i = instruction_size_in_bytes+1; i <= filler_limit; i++) {
	st->print(" ");
	if (abstract_instruction_bytes_per_block <= max_instr_size_in_bytes) {
	if (i%abstract_instruction_bytes_per_block == 0) st->print(" ");
	} else {
	if (i == instruction_size_in_bytes) st->print(" ");
	}
	}

	//---< the address of the next instruction >---
	return (address) current;
	}


	// Decodes all instructions in the given range [start..end)
	// calling decode_instruction_abstract for each instruction.
	// The format is platform dependent only to the extend that
	// it respects the actual instruction length where possible.
	// Does not print any markers or decorators.
	void AbstractDisassembler::decode_range_abstract(address range_start, address range_end,
	address start, address end,
	outputStream* st,
	const int max_instr_size_in_bytes) {
	assert(st != nullptr, "need an output stream (no default)!");
	int idx = 0;
	address pos = range_start;

	while ((pos != nullptr) && (pos < range_end)) {
	int instr_size_in_bytes = Assembler::instr_len(pos);

	if (idx == 0) print_location(pos, start, end, st, false, false);
	else print_delimiter(st);

	//---< print the instruction's bytes >---
	// don't access storage beyond end of range
	if (pos + instr_size_in_bytes <= range_end) {
	pos = decode_instruction_abstract(pos, st, instr_size_in_bytes, max_instr_size_in_bytes);
	} else {
	// If the range to be decoded contains garbage at the end (e.g. 0xcc initializer bytes),
	// instruction size calculation may run out of sync. Just terminate in that case.
	pos = range_end;
	}

	idx += instr_size_in_bytes;
	if (start_newline(idx)) {
	st->cr();
	idx = 0;
	}
	}
	}


	// Decodes all instructions in the given range [start..end).
	// The output is enclosed in [MachCode] and [/MachCode] tags for later recognition.
	// The format is platform dependent only to the extend that
	// it respects the actual instruction length where possible.
	void AbstractDisassembler::decode_abstract(address start, address end, outputStream* ost,
	const int max_instr_size_in_bytes) {
	int idx = 0;
	address pos = start;

	outputStream* st = (ost == nullptr) ? tty : ost;

	//---< Open the output (Marker for post-mortem disassembler) >---
	st->bol();
	st->print_cr("[MachCode]");

	decode_range_abstract(start, end, start, end, st, max_instr_size_in_bytes);

	//---< Close the output (Marker for post-mortem disassembler) >---
	st->bol();
	st->print_cr("[/MachCode]");
	}