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//####COPYRIGHTBEGIN#### // // ---------------------------------------------------------------------------- // Copyright (C) 1998, 1999, 2000 Red Hat, Inc. // // This program is part of the eCos host tools. // // This program is free software; you can redistribute it and/or modify it // under the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 of the License, or (at your option) // any later version. // // This program 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 for // more details. // // You should have received a copy of the GNU General Public License along with // this program; if not, write to the Free Software Foundation, Inc., // 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. // // ---------------------------------------------------------------------------- // //####COPYRIGHTEND#### //================================================================= // // memmap.cpp // // Memory Layout Tool map data structure manipulation class // //================================================================= //#####DESCRIPTIONBEGIN#### // // Author(s): John Dallaway // Contact(s): jld // Date: 1998/07/29 $RcsDate$ {or whatever} // Version: 0.00+ $RcsVersion$ {or whatever} // Purpose: Provides functions to create and destroy memory regions // and sections within the memory map. // Description: Each function manipulates data structures representing // memory regions, memory sections and the view of memory // sections as presented to the user. The section view // structure organises the sections by region and // will contain two instances of each relocated section // Requires: memmap.h // Provides: create_memory_region() // delete_memory_region() // edit_memory_region() // create_memory_section() // delete_memory_section() // edit_memory_section() // delete_all_memory_sections() // set_map_size() // section_list // region_list // See also: memmap.h // Known bugs: <UPDATE_ME_AT_RELEASE_TIME> // WARNING: Do not modify data structures other than by using the // provided functions // Usage: #include "memmap.h" // ... // status = set_map_size (0x8000); // //####DESCRIPTIONEND#### #pragma warning (disable:4514) /* unreferenced inline function */ #pragma warning (disable:4710) /* function not inlined */ #include "memmap.h" using namespace std; #ifdef _DEBUG #undef THIS_FILE static char THIS_FILE[]=__FILE__; //define new DEBUG_NEW #endif ////////////////////////////////////////////////////////////////////// // Construction/Destruction ////////////////////////////////////////////////////////////////////// mem_map::mem_map() { map_modified_flag = true; map_size = (mem_address) 0; } mem_map::~mem_map() { } mem_section::mem_section() { } mem_section::~mem_section() { } /////////////////////////////////////////////////////////////////////// // get_memory_region() retrieves the parameters of a memory region bool mem_map::get_memory_region (string region_name, mem_address * region_address, mem_address * region_size, mem_type * region_type, string * note) { for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end (); ++region) if (region->name == region_name) { *region_address = region->address; *region_size = region->size; *region_type = region->type; *note = region->note; return true; } return false; } /////////////////////////////////////////////////////////////////////// // create_memory_region() inserts a new item into the memory region list // in order of memory address int mem_map::create_memory_region (string new_region_name, mem_address new_region_address, mem_address new_region_size, mem_type new_region_type, string note) { const mem_address new_region_end = new_region_address + new_region_size; // the byte after the new region end // check that the new region name is specified if (new_region_name == "") return ERR_MEMMAP_REGION_NONAME; // the new region name must be specified // check that the new region lies within the memory map if (new_region_end > map_size) return ERR_MEMMAP_REGION_MAPSIZE; // the new region does not lie within the memory map // check that the region end address hasn't exceeded the storage size if (new_region_end < new_region_address) return ERR_MEMMAP_REGION_MAPSIZE; // the new region does not lie within the memory map // initialise the insertion point for the new region list <mem_region>::iterator insertion_point = region_list.end (); // check that the new region does not overlap existing regions and does not already exist for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end (); ++region) { const mem_address region_end = region->address + region->size; // the byte after the region end if ((new_region_address >= region->address) && (new_region_address < region_end)) { error_info = region->name; return ERR_MEMMAP_REGION_INTERSECT; // the start of the new region is within an existing region } if ((new_region_end > region->address) && (new_region_end <= region_end)) { error_info = region->name; return ERR_MEMMAP_REGION_INTERSECT; // the end of the new region is within an existing region } if ((new_region_address < region->address) && (new_region_end > region_end)) { error_info = region->name; return ERR_MEMMAP_REGION_INTERSECT; // an existing region lies within the new region } if (region->name == new_region_name) return ERR_MEMMAP_REGION_NAMEINUSE; // the new region name is not unique if ((insertion_point == region_list.end ()) && (region->address > new_region_address)) insertion_point = region; // insert the new region here } // add the new region to the region list list <mem_region>::iterator new_region = region_list.insert (insertion_point); new_region->name = new_region_name; new_region->address = new_region_address; new_region->size = new_region_size; new_region->type = new_region_type; new_region->note = note; // initialise the section list for the new region calc_section_list (new_region); map_modified_flag = true; return 0; } /////////////////////////////////////////////////////////////////////// // edit_memory_region() edits an item in the memory region list int mem_map::edit_memory_region (string old_region_name, string new_region_name, mem_address new_region_address, mem_address new_region_size, mem_type new_region_type, string note) { list <mem_region>::iterator edit_region = find_memory_region (old_region_name); if (edit_region == NULL) return ERR_MEMMAP_REGION_NOTFOUND; // the region to be modified does not exist // check that the new region name is specified if (new_region_name == "") return ERR_MEMMAP_REGION_NONAME; // the new region name must be specified // check that the region end address hasn't exceeded the storage size if (new_region_address + new_region_size < new_region_address) return ERR_MEMMAP_REGION_MAPSIZE; // the new region does not lie within the memory map // check region name change if ((old_region_name != new_region_name) && (find_memory_region (new_region_name) != NULL)) return ERR_MEMMAP_REGION_NAMEINUSE; // new region name is not unique // check region address/size change wrt other regions const mem_address new_region_end = new_region_address + new_region_size; if ((new_region_address != edit_region->address) || (new_region_size != edit_region->size)) { for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end (); ++region) if (region != edit_region) { const mem_address region_end = region->address + region->size; // the byte after the region end if ((new_region_address >= region->address) && (new_region_address < region_end)) { error_info = region->name; return ERR_MEMMAP_REGION_INTERSECT; // the start of the modified region is within another region } if ((new_region_end > region->address) && (new_region_end <= region_end)) { error_info = region->name; return ERR_MEMMAP_REGION_INTERSECT; // the end of the modified region is within an existing region } if ((new_region_address < region->address) && (new_region_end > region_end)) { error_info = region->name; return ERR_MEMMAP_REGION_INTERSECT; // another region lies within the modified region } } } // check region size change wrt sections within region (if any) for (list <mem_section_view>::iterator section_view = edit_region->section_view_list.begin (); section_view != edit_region->section_view_list.end (); ++section_view) if (section_view->section != NULL) { if ((section_view->section_location == final_location) || (section_view->section_location == fixed_location)) if (section_view->section->final_location->anchor == absolute) if (section_view->section->final_location->address + section_view->section->size - edit_region->address > new_region_size) return ERR_MEMMAP_REGION_SIZE; // region is now too small if (section_view->section_location == initial_location) if (section_view->section->initial_location->anchor == absolute) if (section_view->section->initial_location->address + section_view->section->size - edit_region->address > new_region_size) return ERR_MEMMAP_REGION_SIZE; // region is now too small } // check region read-only change FIXME // move sections within the region having absolute anchors for (section_view = edit_region->section_view_list.begin (); section_view != edit_region->section_view_list.end (); ++section_view) if (section_view->section != NULL) { if ((section_view->section_location == final_location) || (section_view->section_location == fixed_location)) if (section_view->section->final_location->anchor == absolute) section_view->section->final_location->address += (new_region_address - edit_region->address); if ((section_view->section_location == initial_location) || (section_view->section_location == fixed_location)) if (section_view->section->initial_location->anchor == absolute) section_view->section->initial_location->address += (new_region_address - edit_region->address); } // deleteZ(the region and recreate it to make sure the region list is ordered correctly) region_list.erase (edit_region); if (create_memory_region (new_region_name, new_region_address, new_region_size, new_region_type, note)) return ERR_MEMMAP_ALLOC; map_modified_flag = true; return 0; } ////////////////////////////////////////////////////////////////// // delete_memory_region() removes an existing item from the memory // region list bool mem_map::delete_memory_region (string name) { // make sure that there are no used sections in this region before deleting it for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end (); ++region) { if ((region->name == name) && (region->section_view_list.size () == 1) && (region->section_view_list.front ().section == NULL)) { region_list.erase (region); map_modified_flag = true; return true; } } return false; } /////////////////////////////////////////////////////////////////// // set_map_size() sets the maximum permitted address for the end // of any memory region bool mem_map::set_map_size (mem_address new_map_size) { // check that the new size is sufficient for all previously defined memory regions for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end (); ++region) { if (region->address + region->size > new_map_size) return false; // the new map size is too small } // set the map size map_size = new_map_size; return true; } //////////////////////////////////////////////////////////////////// // edit_memory_section() edits an item to the memory section map int mem_map::edit_memory_section (string old_section_name, string new_section_name, mem_address section_size, mem_address section_alignment, mem_anchor initial_section_anchor, string initial_anchor_section_name, mem_address initial_anchor_address, mem_anchor final_section_anchor, string final_anchor_section_name, mem_address final_anchor_address, bool relocates, bool anchor_to_initial_location, bool linker_defined, string note) { // do all the parameter validation if (new_section_name == "") // the new section name must be specified return ERR_MEMMAP_SECTION_NONAME; if ((new_section_name != old_section_name) && (find_memory_section (new_section_name) != NULL)) return ERR_MEMMAP_SECTION_NAMEINUSE; // the new section name is not unique list <mem_section>::iterator section = find_memory_section (old_section_name); if (section == NULL) return ERR_MEMMAP_SECTION_NOTFOUND; // the specified old section name could not be found // check that the LMA (if absolute) is within a memory region list <mem_region>::iterator region; if (initial_section_anchor == absolute) { region = find_region_by_address (initial_anchor_address); if (region == NULL) return ERR_MEMMAP_SECTION_LMA_NOTINREGION; // section LMA is not within a memory region if ((section_size > 0) && (initial_anchor_address + section_size > region->address + region->size)) return ERR_MEMMAP_SECTION_LMA_NOTINREGION; // end of section is not within the memory region if (relocates && (region->type == read_write)) return ERR_MEMMAP_SECTION_LMA_READWRITE; // section LMA must be in a read-only memory region } // check that the VMA (if absolute) is within a memory region if (final_section_anchor == absolute) { region = find_region_by_address (final_anchor_address); if (region == NULL) return ERR_MEMMAP_SECTION_VMA_NOTINREGION; // section VMA is not within a memory region if ((section_size > 0) && (final_anchor_address + section_size > region->address + region->size)) return ERR_MEMMAP_SECTION_VMA_NOTINREGION; // end of section is not within the memory region if (relocates && (region->type == read_only)) return ERR_MEMMAP_SECTION_VMA_READONLY; // section VMA must be in a read/write memory region } // check relative location information as appropriate if (relocates) // only check the initial parent section if the section relocates { if (initial_section_anchor == relative) { list <mem_section>::iterator parent_section = find_memory_section (initial_anchor_section_name); if (parent_section == section_list.end ()) return ERR_MEMMAP_SECTION_LMA_ANCHORNOTFOUND; // initial anchor name not found if ((parent_section->initial_location->following_section != section) && (parent_section->initial_location->following_section != NULL)) return ERR_MEMMAP_SECTION_LMA_ANCHORNOTAVAIL; // initial anchor specified has changed and is unavailable if ((parent_section->size == 0) && (! parent_section->linker_defined)) return ERR_MEMMAP_SECTION_LMA_ANCHORNOTAVAIL; // initial anchor specified expands to fit available space if (find_region_by_section (parent_section, initial_location)->type == read_write) return ERR_MEMMAP_SECTION_LMA_READWRITE; // initial anchor must be in a read-only memory region } } if (final_section_anchor == relative) { list <mem_section>::iterator parent_section = find_memory_section (final_anchor_section_name); if (parent_section == NULL) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTFOUND; // final anchor name not found if ((parent_section->size == 0) && (! parent_section->linker_defined)) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTAVAIL; // final anchor specified expands to fit available space if ((!relocates) && anchor_to_initial_location) // final anchor to initial location of parent section { if ((parent_section->initial_location->following_section != section) && (parent_section->initial_location->following_section != NULL)) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTAVAIL; // final anchor specified has changed and is unavailable } else { if ((parent_section->final_location->following_section != section) && (parent_section->final_location->following_section != NULL)) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTAVAIL; // final anchor specified has changed and is unavailable } if (relocates && (find_region_by_section (parent_section, final_location)->type == read_only)) return ERR_MEMMAP_SECTION_VMA_READONLY; // final anchor of relocating section must be in a read/write memory region } // check for a non-relocating section changing to relocating where the final // location moves from a read_only region to a read_write region and there // is a following non-relocating section if (relocates && (! section->relocates) && (find_region_by_section (section, fixed_location)->type == read_only) && (section->final_location->following_section != NULL) && (! section->final_location->following_section->relocates)) { return ERR_MEMMAP_SECTION_ILLEGAL_RELOCATION; } // FIXME check for overlap of absolute sections // modify the initial section location data if (section->initial_location->anchor == relative) // initial section anchor was relative find_preceding_section (section, true)->initial_location->following_section = NULL; if (initial_section_anchor == absolute) // initial location now absolute section->initial_location->address = initial_anchor_address; else // initial location now relative { list <mem_section>::iterator initial_parent = find_memory_section (initial_anchor_section_name); if (relocates || (! initial_parent->relocates)) initial_parent->initial_location->following_section = section; } // modify the final section location data if (section->final_location->anchor == relative) // final section anchor was relative find_preceding_section (section, false)->final_location->following_section = NULL; if (final_section_anchor == absolute) // final location now absolute section->final_location->address = final_anchor_address; else // final location now relative { list <mem_section>::iterator final_parent = find_memory_section (final_anchor_section_name); final_parent->final_location->following_section = section; } // handle relocation changes if (relocates && (! section->relocates)) // section was non-relocating but now relocates { if (find_region_by_section (section, fixed_location)->type == read_only) // the section was in a read_only region section->final_location->following_section = NULL; // there is now no section following the final location else section->initial_location->following_section = NULL; // there is now no section following the initial location } else if ((! relocates) && section->relocates) // section was relocating but is now non-relocating { // determine the type of memory region in which the section now resides mem_type type; if ((final_section_anchor == relative) && anchor_to_initial_location) type = find_region_by_section (find_memory_section (final_anchor_section_name), initial_location)->type; else if (final_section_anchor == relative) // anchored to final location of preceding section type = find_region_by_section (find_memory_section (final_anchor_section_name), final_location)->type; else // final_section_anchor must be absolute type = find_region_by_address (final_anchor_address)->type; if (type == read_only) // the section is now in a read-only memory region { if ((section->initial_location->following_section != NULL) && ! section->initial_location->following_section->relocates) section->final_location->following_section = section->initial_location->following_section; else section->final_location->following_section = NULL; } else // the section is now in a read-write memory region { if ((section->final_location->following_section != NULL) && ! section->final_location->following_section->relocates) section->initial_location->following_section = section->final_location->following_section; else section->initial_location->following_section = NULL; } } // modify the remaining section data section->name = new_section_name; section->size = section_size; section->alignment = section_alignment; section->relocates = relocates; section->note = note; section->linker_defined = linker_defined; section->initial_location->anchor = initial_section_anchor; section->final_location->anchor = final_section_anchor; // recalculate section lists for all regions calc_section_lists (); map_modified_flag = true; return 0; } //////////////////////////////////////////////////////////////////// // create_memory_section() adds a new item to the memory section map // either a section name (for relative locations) or an anchor address // (for absolute locations) must be specified int mem_map::create_memory_section (string section_name, mem_address section_size, mem_address section_alignment, mem_anchor initial_section_anchor, string initial_anchor_section_name, mem_address initial_anchor_address, mem_anchor final_section_anchor, string final_anchor_section_name, mem_address final_anchor_address, bool relocates, bool anchor_to_initial_location, bool linker_defined, string note) { list <mem_region>::iterator region; // check that the new section name is specified if (section_name == "") return ERR_MEMMAP_SECTION_NONAME; // the new section name must be specified // check that the new section name is unique if (find_memory_section (section_name) != NULL) return ERR_MEMMAP_SECTION_NAMEINUSE; // the new section name is not unique // check that the LMA (if absolute) is within a memory region if (initial_section_anchor == absolute) { region = find_region_by_address (initial_anchor_address); if (region == NULL) return ERR_MEMMAP_SECTION_LMA_NOTINREGION; // section LMA is not within a memory region if ((section_size > 0) && (initial_anchor_address + section_size > region->address + region->size)) return ERR_MEMMAP_SECTION_LMA_NOTINREGION; // end of section is not within the memory region if (relocates && (region->type == read_write)) return ERR_MEMMAP_SECTION_LMA_READWRITE; // section LMA must be in a read-only memory region } // check that the VMA (if absolute) is within a memory region if (final_section_anchor == absolute) { region = find_region_by_address (final_anchor_address); if (region == NULL) return ERR_MEMMAP_SECTION_VMA_NOTINREGION; // section VMA is not within a memory region if ((section_size > 0) && (final_anchor_address + section_size > region->address + region->size)) return ERR_MEMMAP_SECTION_VMA_NOTINREGION; // end of section is not within the memory region if (relocates && (region->type == read_only)) return ERR_MEMMAP_SECTION_VMA_READONLY; // section VMA must be in a read/write memory region } // FIXME check for overlap of absolute sections // check that specified parent(s) (for relative anchors) are available if (relocates) // only check the initial parent section if the section relocates { if (initial_section_anchor == relative) { list <mem_section>::iterator parent_section = find_memory_section (initial_anchor_section_name); if (parent_section == section_list.end ()) return ERR_MEMMAP_SECTION_LMA_ANCHORNOTFOUND; // initial anchor name not found /* if (parent_section->initial_location->following_section != NULL) return ERR_MEMMAP_SECTION_LMA_ANCHORNOTAVAIL; // initial anchor specified is unavailable */ if ((parent_section->size == 0) && (! parent_section->linker_defined)) return ERR_MEMMAP_SECTION_LMA_ANCHORNOTAVAIL; // initial anchor specified expands to fit available space if (find_region_by_section (parent_section, initial_location)->type == read_write) return ERR_MEMMAP_SECTION_LMA_READWRITE; // initial anchor must be in a read-only memory region } } if (final_section_anchor == relative) { list <mem_section>::iterator parent_section = find_memory_section (final_anchor_section_name); if (parent_section == NULL) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTFOUND; // final anchor name not found if ((parent_section->size == 0) && (! parent_section->linker_defined)) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTAVAIL; // final anchor specified expands to fit available space /* if ((!relocates) && anchor_to_initial_location) // final anchor to initial location of parent section { if (parent_section->initial_location->following_section != NULL) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTAVAIL; // final anchor specified is unavailable } else { if (parent_section->final_location->following_section != NULL) return ERR_MEMMAP_SECTION_VMA_ANCHORNOTAVAIL; // final anchor specified is unavailable } */ if (relocates && (find_region_by_section (parent_section, final_location)->type == read_only)) return ERR_MEMMAP_SECTION_VMA_READONLY; // final anchor of relocating section must be in a read/write memory region } // add the new section to the section map mem_section new_mem_section; list <mem_section>::iterator new_section = section_list.insert (section_list.begin (), new_mem_section); new_section->name = section_name; new_section->size = section_size; new_section->alignment = section_alignment; new_section->relocates = relocates; new_section->note = note; new_section->linker_defined = linker_defined; new_section->initial_location = new mem_location; new_section->final_location = new mem_location; new_section->initial_location->following_section = NULL; // initialize struct new_section->final_location->following_section = NULL; // initialize struct new_section->initial_location->anchor = initial_section_anchor; new_section->final_location->anchor = final_section_anchor; if ((initial_section_anchor == relative) && (!relocates) && (find_memory_section (initial_anchor_section_name)->relocates)) { // a non-relocating relative section anchored to a relocating section if (anchor_to_initial_location) // new section is anchored to the initial location of a relocating section { list <mem_section>::iterator anchor_section = find_memory_section (initial_anchor_section_name); new_section->initial_location->following_section = anchor_section->initial_location->following_section; anchor_section->initial_location->following_section = new_section; } else // new section is anchored to the final location of a relocating section { list <mem_section>::iterator anchor_section = find_memory_section (initial_anchor_section_name); new_section->final_location->following_section = anchor_section->final_location->following_section; anchor_section->final_location->following_section = new_section; } } else { // copy initial location data if (initial_section_anchor == relative) // new section follows the named anchor section { list <mem_section>::iterator anchor_section = find_memory_section (initial_anchor_section_name); new_section->initial_location->following_section = anchor_section->initial_location->following_section; // move anchor of the following section anchor_section->initial_location->following_section = new_section; // anchor the new section } else // new section has an absolute anchor new_section->initial_location->address = initial_anchor_address; // copy final location data if (final_section_anchor == relative) // new section follows the named anchor section { list <mem_section>::iterator anchor_section = find_memory_section (final_anchor_section_name); new_section->final_location->following_section = anchor_section->final_location->following_section; // move anchor of the following section anchor_section->final_location->following_section = new_section; // anchor the new section } else // new section has an absolute anchor new_section->final_location->address = final_anchor_address; } // recalculate section lists for all regions calc_section_lists (); map_modified_flag = true; return 0; } //////////////////////////////////////////////////////////////////////// // calc_section_lists() updates the lists of memory sections for all // memory regions bool mem_map::calc_section_lists () { for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end(); ++region) calc_section_list (region); return true; } //////////////////////////////////////////////////////////////////////// // calc_section_list() updates the list of memory sections which reside // in the specified memory region. It is called whenever the section // map is modified. bool mem_map::calc_section_list (list <mem_region>::iterator region) { // clear the old list (if any) TRACE (_T("Calculating section list for region '%s'\n"), CString (region->name.c_str())); region->section_view_list.clear (); // add the initial and final locations of each absolute section as necessary for (list <mem_section>::iterator section = section_list.begin (); section != section_list.end (); ++section) { if (section->relocates) // the section is relocated and must be added to the view twice { add_absolute_section_to_list (region, section, initial_location); add_absolute_section_to_list (region, section, final_location); } else // the section is not relocated and must be added to the view once only add_absolute_section_to_list (region, section, fixed_location); } // add unused sections to section view list where appropriate list <mem_section_view>::iterator previous_section_view = region->section_view_list.begin (); if (previous_section_view == region->section_view_list.end ()) // no used sections in this region { // add a single unused section to the section view list mem_section_view new_section_view; new_section_view.section = NULL; // an unused section region->section_view_list.push_back (new_section_view); // add to the section list for this region } else // there are used sections in this region { list <mem_section_view>::iterator second_section_view = region->section_view_list.begin (); ++second_section_view; // add unused sections between used sections where they do not meet in either initial or final locations for (list <mem_section_view>::iterator section_view = second_section_view; section_view != region->section_view_list.end (); ++section_view) { if (! (absolute_sections_meet (previous_section_view->section, section_view->section))) { list <mem_section_view>::iterator new_section_view = region->section_view_list.insert (section_view); // add an unused section new_section_view->section = NULL; } previous_section_view = section_view; } // add an unused section to end of region if the last section does not reach the end of the region in initial or final locations if (! at_end_of_region (region->section_view_list.back().section, region)) { mem_section_view new_section_view; new_section_view.section = NULL; // an unused section region->section_view_list.push_back (new_section_view); // add an unused section } // add an unused section to start of region if the first section does not start at the start of the region in initial or final locations if (! at_start_of_region (region->section_view_list.front().section, region)) { mem_section_view new_section_view; new_section_view.section = NULL; // an unused section region->section_view_list.push_front (new_section_view); // add an unused section } } // add the initial and final locations of the each relative section as necessary for (list <mem_section_view>::iterator section_view = region->section_view_list.begin (); section_view != region->section_view_list.end (); ++section_view) if (section_view->section != NULL) // if section is used { list <mem_section>::iterator section = section_view->section; TRACE (_T("Calculating relative sections for section view '%s' %s\n"), CString (section->name.c_str ()), section_view->section_location == final_location ? _T("(final)") : section_view->section_location == initial_location ? _T("(initial)") : _T("(fixed)")); if (section_view->section_location == final_location) { if (section->final_location->anchor == absolute) add_relative_sections_to_list (region, section_view, final_location); } else if (section_view->section_location == initial_location) { if (section->initial_location->anchor == absolute) add_relative_sections_to_list (region, section_view, initial_location); } else // section_view->section_location == fixed_location { if (section->initial_location->anchor == absolute) add_relative_sections_to_list (region, section_view, initial_location); if (section->final_location->anchor == absolute) add_relative_sections_to_list (region, section_view, final_location); } } // remove unused sections where user-defined section of unknown size will be placed section_view = region->section_view_list.begin (); while (section_view != region->section_view_list.end ()) { bool expanding_section = false; if ((section_view->section != NULL) && (section_view->section->size == 0) && (! section_view->section->linker_defined)) expanding_section = true; ++section_view; if (expanding_section && (section_view != region->section_view_list.end ()) && (section_view->section == NULL)) section_view = region->section_view_list.erase (section_view); } return true; } ///////////////////////////////////////////////////////////////////// // add_relative_sections_to_list() inserts the sections defined relative // to the specified section list item to the section list for the // specified region in the appropriate order bool mem_map::add_relative_sections_to_list (list <mem_region>::iterator region, list <mem_section_view>::iterator section_view, section_location_type location_type) { // insert following relative sections of type 'location_type' in region_view.section_view_list list <mem_section>::iterator new_section = section_view->section; mem_location * new_section_location = (location_type == initial_location ? new_section->initial_location : new_section->final_location); list <mem_section_view>::iterator insertion_point = section_view; ++insertion_point; bool no_relocation = true; while (new_section_location->following_section != NULL) { // add the new section to the section view list mem_section_view new_section_view; new_section_view.section = new_section_location->following_section; const bool section_relocates = new_section->relocates; new_section = new_section_view.section; new_section_view.section_location = (new_section->relocates ? location_type : fixed_location); if ((new_section_view.section_location == fixed_location) && (location_type == final_location) && (! section_view->section->relocates) && (! section_relocates) && no_relocation) { // section already added to the view so add nothing but // increment insertion point for following sections TRACE (_T("Skipping section %s %s location (relative) preceding %s\n"), CString (new_section_location->following_section->name.c_str()), location_type == initial_location ? _T("initial") : _T("final"), ((insertion_point != region->section_view_list.end ()) && (insertion_point->section != NULL)) ? CString (insertion_point->section->name.c_str()) : _T("(null)")); ++insertion_point; } else { TRACE (_T("Inserting section %s %s location (relative) preceding %s\n"), CString (new_section_location->following_section->name.c_str()), location_type == initial_location ? _T("initial") : _T("final"), ((insertion_point != region->section_view_list.end ()) && (insertion_point->section != NULL)) ? CString (insertion_point->section->name.c_str()) : _T("(null)")); region->section_view_list.insert (insertion_point, new_section_view); no_relocation = no_relocation && ! new_section_view.section->relocates; } new_section_location = (location_type == initial_location ? new_section->initial_location : new_section->final_location); } return true; } ///////////////////////////////////////////////////////////////////// // add_absolute_section_to_list() inserts the specified section to the // specified section list at the appropriate place if it has an // absolute location and that location is within the specified memory // region bool mem_map::add_absolute_section_to_list (list <mem_region>::iterator region, list <mem_section>::iterator additional_section, section_location_type location_type) { // get location of new section mem_location * new_section_location = (location_type == initial_location ? additional_section->initial_location : additional_section->final_location); if ((new_section_location->anchor == absolute) && (new_section_location->address >= region->address) && (new_section_location->address < region->address + region->size)) { // the section lies in the region // initialise the insertion point for the new section list <mem_section_view>::iterator insertion_point = region->section_view_list.end (); for (list <mem_section_view>::iterator section = region->section_view_list.begin (); section != region->section_view_list.end (); ++section) { // get location of section mem_location * section_location = (section->section_location == initial_location ? section->section->initial_location : section->section->final_location); // compare with location of new section if ((new_section_location->anchor == absolute) && (section_location->address >= new_section_location->address)) { // insert new section here if the current section has a higher address insertion_point = section; break; } } // add the new section to the section view list TRACE (_T("Inserting section %s %s location (absolute) preceding %s\n"), CString (additional_section->name.c_str()), location_type == initial_location ? _T("initial") : _T("final"), insertion_point != region->section_view_list.end () ? CString (insertion_point->section->name.c_str()) : _T("(end)")); mem_section_view new_section_view; new_section_view.section = additional_section; new_section_view.section_location = location_type; region->section_view_list.insert (insertion_point, new_section_view); } return true; } //////////////////////////////////////////////////////////////////// // absolute_sections_meet() determines whether the specified // absolute memory sections meet. It assumes that section2 comes // after section1 in the memory map. bool mem_map::absolute_sections_meet(list <mem_section>::iterator section1, list <mem_section>::iterator section2) { if (section1->size == 0) // size of section1 is unknown return false; // check if initial section locations meet if ((section1->initial_location->anchor == absolute) && ((section2->initial_location->anchor == absolute) && section1->initial_location->address + section1->size == section2->initial_location->address)) return true; // check if final section locations meet if ((section1->final_location->anchor == absolute) && ((section2->final_location->anchor == absolute) && section1->final_location->address + section1->size == section2->final_location->address)) return true; return false; } ////////////////////////////////////////////////////////////// // at_start_of_region() determines whether the specified section // is located at the very start of the specified region bool mem_map::at_start_of_region (list <mem_section>::iterator section, list <mem_region>::iterator region) { // check initial section location if ((section->initial_location->anchor == absolute) && (section->initial_location->address == region->address)) return true; // check final section location if ((section->final_location->anchor == absolute) && (section->final_location->address == region->address)) return true; return false; } ////////////////////////////////////////////////////////////// // at_end_of_region() determines whether the specified section // is located at the very end of the specified region bool mem_map::at_end_of_region (list <mem_section>::iterator section, list <mem_region>::iterator region) { if (section->size == 0) // size of section is unknown return false; // check initial section location if ((section->initial_location->anchor == absolute) && section->initial_location->address + section->size == region->address + region->size) return true; // check final section location if ((section->final_location->anchor == absolute) && section->final_location->address + section->size == region->address + region->size) return true; return false; } //////////////////////////////////////////////////////////////////////// // find_preceding_section() finds the preceding section in the // memory section list list <mem_section>::iterator mem_map::find_preceding_section (list <mem_section>::iterator reference_section, bool initial_location) { for (list <mem_section>::iterator section = section_list.begin (); section != section_list.end (); ++section) { if (reference_section == (reference_section->relocates && initial_location ? section->initial_location->following_section : section->final_location->following_section)) // if preceding section found return section; // return the section iterator } return NULL; // section not found } //////////////////////////////////////////////////////////////////////// // find_memory_section() finds an existing section in the // memory section list list <mem_section>::iterator mem_map::find_memory_section (string section_name) { for (list <mem_section>::iterator section = section_list.begin (); section != section_list.end (); ++section) if (section->name == section_name) // if section found return section; // return the section iterator return NULL; // section not found } //////////////////////////////////////////////////////////////////////// // find_memory_region() finds an existing region in the // memory region list list <mem_region>::iterator mem_map::find_memory_region (string region_name) { for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end (); ++region) if (region->name == region_name) // if region found return region; // return the region iterator return NULL; // region not found } //////////////////////////////////////////////////////////////////////// // delete_memory_section() removes an existing item from the // memory section map bool mem_map::delete_memory_section (string name) { // make sure that the section exists list <mem_section>::iterator section = find_memory_section (name); if (section == NULL) return false; // there is no section with this name /* // make sure that there are no sections defined relative to this section before deleting it if (section->initial_location->following_section != NULL) return false; if (section->final_location->following_section != NULL) return false; */ // if section is absolute, copy the initial and final location information to // the following sections (if any) if ((section->initial_location->anchor == absolute) && (section->initial_location->following_section != NULL)) { section->initial_location->following_section->initial_location->anchor = absolute; section->initial_location->following_section->initial_location->address = section->initial_location->address; // FIXME adjust new address of following section for alignment here } if ((section->final_location->anchor == absolute) && (section->final_location->following_section != NULL)) { section->final_location->following_section->final_location->anchor = absolute; section->final_location->following_section->final_location->address = section->final_location->address; // FIXME adjust new address of following section for alignment here } // if section is relative, find the initial and final sections to which it is attached // and set their pointers to the sections following the one to be deleted (if any) list <mem_section>::iterator related_section; if (section->initial_location->anchor == relative) for (related_section = section_list.begin (); related_section != section_list.end (); ++related_section) if (related_section->initial_location->following_section == section) related_section->initial_location->following_section = section->initial_location->following_section; if (section->final_location->anchor == relative) for (related_section = section_list.begin (); related_section != section_list.end (); ++related_section) if (related_section->final_location->following_section == section) related_section->final_location->following_section = section->final_location->following_section; // delete the section deleteZ(section->initial_location); deleteZ(section->final_location); section_list.erase (section); // recalculate section lists for all regions calc_section_lists (); map_modified_flag = true; return true; } //////////////////////////////////////////////////////////////////////// // delete_memory_sections() deletes all memory sections in preparation // for layout loading or application closure bool mem_map::delete_all_memory_sections () { // deleteZ(each section in turn) while (section_list.size () > 0) { list <mem_section>::iterator section = section_list.begin (); deleteZ(section->initial_location); deleteZ(section->final_location); section_list.erase (section); } // section_list.clear (); // recalculate section view lists for all regions calc_section_lists (); map_modified_flag = true; return true; } //////////////////////////////////////////////////////////////////////// // export_sections() exports section-related info for regions of the // specified type to the linker script fragment and header file bool mem_map::export_sections (FILE * script_stream, FILE * header_stream, mem_type type) { for (list <mem_region>::iterator region = region_list.begin (); region != region_list.end(); ++region) if (region->type == type) { for (list <mem_section_view>::iterator section_view = region->section_view_list.begin (); section_view != region->section_view_list.end (); ++section_view) { if ((section_view->section != NULL) && (section_view->section_location != initial_location)) { if (section_view->section->linker_defined) // section is linker-defined { // output section name and region name fprintf (script_stream, " SECTION_%s (%s, ", encode_section_name (section_view->section->name).c_str (), region->name.c_str ()); // output VMA if (section_view->section->final_location->anchor == absolute) // an absolute VMA fprintf (script_stream, "%#lx, ", section_view->section->final_location->address); // specify absolute address else // a relative VMA fprintf (script_stream, "ALIGN (%#lx), ", section_view->section->alignment); // specify alignment // output LMA if (! section_view->section->relocates) // section does not relocate so LMA == VMA fprintf (script_stream, "LMA_EQ_VMA)"); else if (section_view->section->initial_location->anchor == absolute) // an absolute LMA fprintf (script_stream, "AT (%#lx))", section_view->section->initial_location->address); else // a relative LMA { list <mem_section>::iterator parent_section; for (parent_section = section_list.begin (); parent_section != section_list.end (); ++parent_section) if (parent_section->initial_location->following_section == section_view->section) break; if (parent_section->linker_defined) // parent section is linker-defined fprintf (script_stream, "FOLLOWING (.%s))", parent_section->name.c_str ()); else // parent section is user-defined fprintf (script_stream, "AT (__%s + %#lx))", parent_section->name.c_str (), parent_section->size); } } else // section is user-defined { // output section symbol if (section_view->section->final_location->anchor == absolute) // an absolute VMA fprintf (script_stream, " CYG_LABEL_DEFN(__%s) = %#lx;", section_view->section->name.c_str (), section_view->section->final_location->address); else // a relative VMA fprintf (script_stream, " CYG_LABEL_DEFN(__%s) = ALIGN (%#lx);", section_view->section->name.c_str (), section_view->section->alignment); // update current location pointer if (section_view->section->size != 0) // size is known fprintf (script_stream, " . = CYG_LABEL_DEFN(__%s) + %#lx;", section_view->section->name.c_str (), section_view->section->size); // output reference to symbol in header file fprintf (header_stream, "#ifndef __ASSEMBLER__\nextern char CYG_LABEL_NAME (__%s) [];\n#endif\n", section_view->section->name.c_str ()); fprintf (header_stream, "#define CYGMEM_SECTION_%s (CYG_LABEL_NAME (__%s))\n", section_view->section->name.c_str (), section_view->section->name.c_str ()); if (section_view->section->size == 0) // a section of unknown size { mem_address section_end_address; ++section_view; // move to next section_view if (section_view == region->section_view_list.end ()) // section continues to end of region section_end_address = region->address + region->size; else // section continues to next section with an absolute location section_end_address = section_view->section->final_location->address; --section_view; // move back to previous section view fprintf (header_stream, "#define CYGMEM_SECTION_%s_SIZE (%#lx - (size_t) CYG_LABEL_NAME (__%s))\n", section_view->section->name.c_str (), section_end_address, section_view->section->name.c_str ()); } else // a section of known size fprintf (header_stream, "#define CYGMEM_SECTION_%s_SIZE (%#lx)\n", section_view->section->name.c_str (), section_view->section->size); } // end of section description fprintf (script_stream, "\n"); // new line } } } return true; } //////////////////////////////////////////////////////////////////////// // export_files() creates a fragment of linker script and a header file // describing the memory layout bool mem_map::export_files (LPCTSTR script_name, LPCTSTR header_name) { FILE * script_stream; FILE * header_stream; list <mem_region>::iterator region; // do not export files if the memory layout is empty // assume that there are default LDI files available if (region_list.size () == 0) return false; // open the script fragment file for writing script_stream = _tfopen (script_name, _T("wt")); if (script_stream == NULL) return false; // open the header file for writing header_stream = _tfopen (header_name, _T("wt")); if (header_stream == NULL) { fclose (script_stream); return false; } // output the linker script fragment header time_t export_time; time (&export_time); struct tm * local = localtime (&export_time); fprintf (script_stream, "// eCos memory layout - %s\n%s\n\n", asctime (local), MLT_GENERATED_WARNING); fprintf (script_stream, "#include <cyg/infra/cyg_type.inc>\n\n"); // output the header file header fprintf (header_stream, "// eCos memory layout - %s\n%s\n\n", asctime (local), MLT_GENERATED_WARNING); fprintf (header_stream, "#ifndef __ASSEMBLER__\n"); fprintf (header_stream, "#include <cyg/infra/cyg_type.h>\n"); // for the CYG_LABEL_NAME macro definition fprintf (header_stream, "#include <stddef.h>\n\n"); // for size_t fprintf (header_stream, "#endif\n"); // output the MEMORY block fprintf (script_stream, "MEMORY\n{\n"); // start of MEMORY block for (region = region_list.begin (); region != region_list.end(); ++region) { fprintf (script_stream, " %s : ORIGIN = %#lx, LENGTH = %#lx\n", region->name.c_str(), region->address, region->size); fprintf (header_stream, "#define CYGMEM_REGION_%s (%#lx)\n", region->name.c_str(), region->address); fprintf (header_stream, "#define CYGMEM_REGION_%s_SIZE (%#lx)\n", region->name.c_str(), region->size); fprintf (header_stream, "#define CYGMEM_REGION_%s_ATTR (CYGMEM_REGION_ATTR_R%s)\n", region->name.c_str(), (read_write == region->type) ? " | CYGMEM_REGION_ATTR_W" : ""); } fprintf (script_stream, "}\n\n"); // end of MEMORY block // output the SECTIONS block fprintf (script_stream, "SECTIONS\n{\n"); // start of SECTIONS block fprintf (script_stream, " SECTIONS_BEGIN\n"); // SECTIONS block initial script macro call export_sections (script_stream, header_stream, read_only); // export sections in read-only regions first export_sections (script_stream, header_stream, read_write); // followed by sections in read-write regions fprintf (script_stream, " SECTIONS_END\n"); // SECTIONS block final script macro call fprintf (script_stream, "}\n"); // end of SECTIONS block // close the files fclose (script_stream); fclose (header_stream); return true; } //////////////////////////////////////////////////////////////////////// // import_linker_defined_sections() reads a the linker-defined section // names from the "SECTION_*" CPP macro definitions within the linker // script bool mem_map::import_linker_defined_sections (LPCTSTR filename) { // clear the linker-defined section name list linker_defined_section_list.clear (); // open the linker script file for reading FILE * stream; stream = _tfopen (filename, _T("rt")); if (stream == NULL) return false; bool macro = false; // not reading a CPP macro definition initially char input_string [32]; while (! feof (stream)) { if (macro) { if (fscanf (stream, "%8s", input_string) == EOF) // read the next 8 chars (not including whitespace) break; if (strcmp (input_string, "SECTION_") == 0) // an MLT section macro definition { if (fscanf (stream, "%31[^(]", input_string) == EOF) // read the section name up to the '(' character break; string section_name = decode_section_name (input_string); if (find (linker_defined_section_list.begin (), linker_defined_section_list.end (), section_name) == linker_defined_section_list.end ()) // if section name is unique linker_defined_section_list.push_back (section_name); } macro = false; } else { if (fscanf (stream, "%31s", input_string) == EOF) break; if (strcmp (input_string, "#define") == 0) macro = true; // macro starts with "#define" } } // close the file if (fclose (stream)) return false; return true; } //////////////////////////////////////////////////////////////////////// // encode_note() encodes newlines in note string mem_map::encode_note (string in) { string out = "!"; // dummy first character to ensure output string length > 0 for (unsigned int item = 0; item < in.size (); item++) if (in [item] == _TCHAR('\n')) // an LF character out += "\x07F"; // output substitution character 0x7F instead else if (in [item] != _TCHAR('\r')) // ignore the CR (present under Win32 only) out += in [item]; // copy other characters to output string unprocessed return out; } //////////////////////////////////////////////////////////////////////// // decode_note() decodes newlines in note string mem_map::decode_note (string in) { string out; for (unsigned int item = 1; item < in.size (); item++) // ignore dummy first character if (in [item] == _TCHAR('\x07F')) // the newline substitution character out += "\r\n"; // output CRLF instead else out += in [item]; return out; } //////////////////////////////////////////////////////////////////////// // encode_section_name() encodes period -> double underscore in section name string mem_map::encode_section_name (string in) { string out; for (unsigned int item = 0; item < in.size (); item++) if (in [item] == '.') // a period character out += "__"; // output a double underscore instead else out += in [item]; return out; } //////////////////////////////////////////////////////////////////////// // decode_section_name() decodes double underscore -> period in section name string mem_map::decode_section_name (string in) { string out; for (unsigned int item = 0; item < in.size (); item++) if ((item + 1 < in.size ()) && (in [item] == '_') && (in [item + 1] == '_')) // two consecutive underscore characters { out += "."; // output a period instead item++; // skip the second underscore } else out += in [item]; return out; } //////////////////////////////////////////////////////////////////////// // save_memory_layout() saves the memory layout to file for later use bool mem_map::save_memory_layout (LPCTSTR filename) { FILE * stream; list <mem_region>::iterator region; // open the save file for writing stream = _tfopen (filename, _T("wt")); if (stream == NULL) return false; // write the save file format version number fprintf (stream, "version %u\n", (unsigned int) MLT_FILE_VERSION); // save the memory region data in address order for (region = region_list.begin (); region != region_list.end (); ++region) fprintf (stream, "region %s %lx %lx %d %s\n", region->name.c_str (), region->address, region->size, (region->type == read_only), encode_note (region->note).c_str ()); // save the memory section data in VMA order for (region = region_list.begin (); region != region_list.end(); ++region) { for (list <mem_section_view>::iterator section_view = region->section_view_list.begin (); section_view != region->section_view_list.end (); ++section_view) { if ((section_view->section != NULL) && (section_view->section_location != initial_location)) { list <mem_section>::iterator section = section_view->section; fprintf (stream, "section %s %lx %lx %d %d %d %d %d %d", section->name.c_str (), section->size, section->alignment, section->relocates, section->linker_defined, section->final_location->anchor == absolute, section->final_location->following_section != NULL, section->initial_location->anchor == absolute, section->initial_location->following_section != NULL); if (section->final_location->anchor == absolute) fprintf (stream, " %lx", section->final_location->address); if (section->initial_location->anchor == absolute) fprintf (stream, " %lx", section->initial_location->address); if (section->final_location->following_section != NULL) fprintf (stream, " %s", section->final_location->following_section->name.c_str ()); if (section->initial_location->following_section != NULL) fprintf (stream, " %s", section->initial_location->following_section->name.c_str ()); fprintf (stream, " %s", encode_note (section->note).c_str ()); // end of section description fprintf (stream, "\n"); // new line } } } // close the file if (fclose (stream)) return false; map_modified_flag = false; return true; } //////////////////////////////////////////////////////////////////////// // load_memory_layout() loads a previously saved memory layout from file bool mem_map::load_memory_layout (LPCTSTR filename) { FILE * stream; // open the save file for reading stream = _tfopen (filename, _T("rt")); if (stream == NULL) return false; // read the file version unsigned int file_version; if ((fscanf (stream, "%*s %u", &file_version) != 1) || (file_version != MLT_FILE_VERSION)) { fclose (stream); // missing or incorrect file version return false; } new_memory_layout (); // read the new memory layout (first pass) while (! feof (stream)) { char record_type [32]; if (fscanf (stream, "%31s", record_type) == EOF) break; if (strcmp (record_type, "section") == 0) // a section record { if (! load_memory_section_1 (stream)) break; } else if (strcmp (record_type, "region") == 0) // a region record { mem_address address, size; bool read_only_region; char name [32]; char note [1024]; fscanf (stream, "%s %lx %lx %d %1023[^\n]", name, &address, &size, &read_only_region, note); if (create_memory_region (name, address, size, (read_only_region ? read_only : read_write), decode_note (note))) break; } else // an unknown record type break; } // quit if the end of the file was not reached (due to an error) if (! feof (stream)) { new_memory_layout (); fclose (stream); return false; } // move the file pointer back to the beginning of the file fseek (stream, 0, SEEK_SET); while (! feof (stream)) // read the memory layout (second pass) { char record_type [32]; if (fscanf (stream, "%31s", record_type) == EOF) break; if ((strcmp (record_type, "section") == 0) && (! load_memory_section_2 (stream))) break; } // close the file if (fclose (stream)) { new_memory_layout (); return false; } // recalculate section view lists for all regions calc_section_lists (); map_modified_flag = false; return true; } //////////////////////////////////////////////////////////////////////// // load_memory_section_1() loads a previously saved memory section from // file (first pass) bool mem_map::load_memory_section_1 (FILE * stream) { char section_name [32]; int relocates, linker_defined; int final_absolute, initial_absolute, final_following, initial_following; mem_section new_section; new_section.initial_location = new mem_location; new_section.initial_location->following_section = NULL; new_section.final_location = new mem_location; new_section.final_location->following_section = NULL; fscanf (stream,"%31s %lx %lx %d %d %d %d %d %d", section_name, &new_section.size, &new_section.alignment, &relocates, &linker_defined, &final_absolute, &final_following, &initial_absolute, &initial_following); new_section.name = section_name; new_section.relocates = (relocates != 0); new_section.linker_defined = (linker_defined != 0); new_section.final_location->anchor = (final_absolute ? absolute : relative); if (final_absolute) // final location is absolute fscanf (stream, "%lx", &new_section.final_location->address); new_section.initial_location->anchor = (initial_absolute ? absolute : relative); if (initial_absolute) // initial location is absolute fscanf (stream, "%lx", &new_section.initial_location->address); if (final_following) fscanf (stream, "%*s"); // skip the final following section field on first pass if (initial_following) fscanf (stream, "%*s"); // skip the initial following section field on first pass char note [1024]; fscanf (stream, " %1023[^\n]", note); new_section.note = decode_note (note); // add the new section to the section map section_list.push_front (new_section); return true; } //////////////////////////////////////////////////////////////////////// // load_memory_section_2() loads a previously saved memory section from // file (second pass) bool mem_map::load_memory_section_2 (FILE * stream) { char section_name [32]; char following_section_name [32]; int final_absolute, initial_absolute, final_following, initial_following; fscanf (stream,"%31s %*lx %*lx %*d %*d %d %d %d %d", section_name, &final_absolute, &final_following, &initial_absolute, &initial_following); if (final_absolute) // final location is absolute fscanf (stream, "%*lx"); // skip the final location if (initial_absolute) // initial location is absolute fscanf (stream, "%*lx"); // skip the initial location if (initial_following || final_following) // the section is a parent { list <mem_section>::iterator section = find_memory_section (section_name); if (final_following) { fscanf (stream, "%31s", following_section_name); // read the final following section name section->final_location->following_section = find_memory_section (following_section_name); } if (initial_following) { fscanf (stream, "%31s", following_section_name); // read the initial following section name section->initial_location->following_section = find_memory_section (following_section_name); } } fscanf (stream, "%*1023[^\n]"); // skip the note return true; } //////////////////////////////////////////////////////////////////////// // new_memory_layout() clears the memory layout bool mem_map::new_memory_layout () { delete_all_memory_sections (); // section_list.clear (); region_list.clear (); map_modified_flag = false; // no need to save an empty memory layout return true; } //////////////////////////////////////////////////////////////////////// // section_exists() determines if the specified section is defined bool mem_map::section_exists (string section_name) { return (find_memory_section (section_name) != NULL); } //////////////////////////////////////////////////////////////////////// // find_region_by_address() finds the region containing the specified // memory address list <mem_region>::iterator mem_map::find_region_by_address (mem_address address) { for (list <mem_region>::iterator region = region_list.begin (); region !=region_list.end(); ++region) if ((address >= region->address) && (address < region->address + region->size)) return region; return NULL; // the specified address is not in a memory region } //////////////////////////////////////////////////////////////////////// // find_region_by_section() finds the region containing the specified // section list <mem_region>::iterator mem_map::find_region_by_section (list <mem_section>::iterator section, section_location_type location_type) { for (list <mem_region>::iterator region = region_list.begin (); region !=region_list.end(); ++region) for (list <mem_section_view>::iterator section_view = region->section_view_list.begin (); section_view != region->section_view_list.end (); ++section_view) if ((section_view->section != NULL) && (section_view->section == section) && (section_view->section_location == (section_view->section->relocates ? location_type : fixed_location))) return region; return NULL; // the specified section location type was not found (you probably searched for the fixed_location of a relocating section) }