src/quipper/address_mapper.cc - platform/external/perf_data_converter - Git at Google

 // Copyright (c) 2013 The Chromium OS Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "address_mapper.h"

 #include <stdint.h>

 #include <vector>

 #include "base/logging.h"

 namespace quipper {

 AddressMapper::AddressMapper(const AddressMapper& other) {
   // Copy over most members naively.
   mappings_ = other.mappings_;
   page_alignment_ = other.page_alignment_;

   // Reconstruct mapping of real addresses to mapped ranges.
   for (auto iter = mappings_.begin(); iter != mappings_.end(); ++iter) {
     real_addr_to_mapped_range_[iter->real_addr] = iter;
   }
 }

 bool AddressMapper::MapWithID(const uint64_t real_addr, const uint64_t size,
                               const uint64_t id, const uint64_t offset_base,
                               bool remove_existing_mappings) {
   if (size == 0) {
     LOG(ERROR) << "Must allocate a nonzero-length address range.";
     return false;
   }

   // Check that this mapping does not overflow the address space.
   if (real_addr + size - 1 != UINT64_MAX && !(real_addr + size > real_addr)) {
     DumpToLog();
     LOG(ERROR) << "Address mapping at " << std::hex << real_addr
                << " with size " << std::hex << size << " overflows.";
     return false;
   }

   MappedRange range;
   range.real_addr = real_addr;
   range.size = size;
   range.id = id;
   range.offset_base = offset_base;

   // Check for collision with an existing mapping. This must be an overlap that
   // does not result in one range being completely covered by another.

   // First determine the range of mappings that could overlap with the new
   // mapping in real space.

   // lower_bound returns the first range with starting addr >= |real_addr|. The
   // preceding range could also possibly overlap with the new range.
   auto map_iter_start = real_addr_to_mapped_range_.lower_bound(real_addr);
   if (map_iter_start != real_addr_to_mapped_range_.begin()) --map_iter_start;
   // lower_bound returns the first range with starting addr beyond the end of
   // the new mapping range.
   auto map_iter_end = real_addr_to_mapped_range_.lower_bound(real_addr + size);

   std::vector<MappingList::iterator> mappings_to_delete;
   MappingList::iterator old_range_iter = mappings_.end();
   for (auto map_iter = map_iter_start; map_iter != map_iter_end; ++map_iter) {
     auto iter = map_iter->second;
     if (!iter->Intersects(range)) continue;
     // Quit if existing ranges that collide aren't supposed to be removed.
     if (!remove_existing_mappings) return false;
     if (old_range_iter == mappings_.end() && iter->Covers(range) &&
         iter->size > range.size) {
       old_range_iter = iter;
       continue;
     }
     mappings_to_delete.push_back(iter);
   }

   for (MappingList::iterator mapping_iter : mappings_to_delete)
     Unmap(mapping_iter);
   mappings_to_delete.clear();

   // Otherwise check for this range being covered by another range.  If that
   // happens, split or reduce the existing range to make room.
   if (old_range_iter != mappings_.end()) {
     // Make a copy of the old mapping before removing it.
     const MappedRange old_range = *old_range_iter;
     Unmap(old_range_iter);

     uint64_t gap_before = range.real_addr - old_range.real_addr;
     uint64_t gap_after =
         (old_range.real_addr + old_range.size) - (range.real_addr + range.size);

     // If the new mapping is not aligned to a page boundary at either its start
     // or end, it will require the end of the old mapping range to be moved,
     // which is not allowed.
     if (page_alignment_) {
       if ((gap_before && GetAlignedOffset(range.real_addr)) ||
           (gap_after && GetAlignedOffset(range.real_addr + range.size))) {
         LOG(ERROR) << "Split mapping must result in page-aligned mappings.";
         return false;
       }
     }

     if (gap_before) {
       if (!MapWithID(old_range.real_addr, gap_before, old_range.id,
                      old_range.offset_base, false)) {
         LOG(ERROR) << "Could not map old range from " << std::hex
                    << old_range.real_addr << " to "
                    << old_range.real_addr + gap_before;
         return false;
       }
     }

     if (!MapWithID(range.real_addr, range.size, id, offset_base, false)) {
       LOG(ERROR) << "Could not map new range at " << std::hex << range.real_addr
                  << " to " << range.real_addr + range.size << " over old range";
       return false;
     }

     if (gap_after) {
       if (!MapWithID(range.real_addr + range.size, gap_after, old_range.id,
                      old_range.offset_base + gap_before + range.size, false)) {
         LOG(ERROR) << "Could not map old range from " << std::hex
                    << old_range.real_addr << " to "
                    << old_range.real_addr + gap_before;
         return false;
       }
     }

     return true;
   }

   // Now search for a location for the new range.  It should be in the first
   // free block in quipper space.

   uint64_t page_offset =
       page_alignment_ ? GetAlignedOffset(range.real_addr) : 0;

   // If there is no existing mapping, add it to the beginning of quipper space.
   if (IsEmpty()) {
     range.mapped_addr = page_offset;
     range.unmapped_space_after = UINT64_MAX - range.size - page_offset;
     mappings_.push_back(range);
     real_addr_to_mapped_range_.insert(
         std::make_pair(range.real_addr, mappings_.begin()));
     return true;
   }

   // If there is space before the first mapped range in quipper space, use it.
   if (mappings_.begin()->mapped_addr >= range.size + page_offset) {
     range.mapped_addr = page_offset;
     range.unmapped_space_after =
         mappings_.begin()->mapped_addr - range.size - page_offset;
     mappings_.push_front(range);
     MappingList::iterator iter = mappings_.begin();
     real_addr_to_mapped_range_.insert(std::make_pair(range.real_addr, iter));
     return true;
   }

   // Otherwise, search through the existing mappings for a free block after one
   // of them.
   for (auto iter = mappings_.begin(); iter != mappings_.end(); ++iter) {
     MappedRange& existing_mapping = *iter;
     if (page_alignment_) {
       uint64_t end_of_existing_mapping =
           existing_mapping.mapped_addr + existing_mapping.size;

       // Find next page boundary after end of this existing mapping.
       uint64_t existing_page_offset = GetAlignedOffset(end_of_existing_mapping);
       uint64_t next_page_boundary =
           existing_page_offset
               ? end_of_existing_mapping - existing_page_offset + page_alignment_
               : end_of_existing_mapping;
       // Compute where the new mapping would end if it were aligned to this
       // page boundary.
       uint64_t mapping_offset = GetAlignedOffset(range.real_addr);
       uint64_t end_of_new_mapping =
           next_page_boundary + mapping_offset + range.size;
       uint64_t end_of_unmapped_space_after =
           end_of_existing_mapping + existing_mapping.unmapped_space_after;

       // Check if there's enough room in the unmapped space following the
       // current existing mapping for the page-aligned mapping.
       if (end_of_new_mapping > end_of_unmapped_space_after) continue;

       range.mapped_addr = next_page_boundary + mapping_offset;
       range.unmapped_space_after =
           end_of_unmapped_space_after - end_of_new_mapping;
       existing_mapping.unmapped_space_after =
           range.mapped_addr - end_of_existing_mapping;
     } else {
       if (existing_mapping.unmapped_space_after < range.size) continue;
       // Insert the new mapping range immediately after the existing one.
       range.mapped_addr = existing_mapping.mapped_addr + existing_mapping.size;
       range.unmapped_space_after =
           existing_mapping.unmapped_space_after - range.size;
       existing_mapping.unmapped_space_after = 0;
     }

     mappings_.insert(++iter, range);
     --iter;
     real_addr_to_mapped_range_.insert(std::make_pair(range.real_addr, iter));
     return true;
   }

   // If it still hasn't succeeded in mapping, it means there is no free space in
   // quipper space large enough for a mapping of this size.
   DumpToLog();
   LOG(ERROR) << "Could not find space to map addr=" << std::hex << real_addr
              << " with size " << std::hex << size;
   return false;
 }

 void AddressMapper::DumpToLog() const {
   MappingList::const_iterator it;
   for (it = mappings_.begin(); it != mappings_.end(); ++it) {
     LOG(INFO) << " real_addr: " << std::hex << it->real_addr
               << " mapped: " << std::hex << it->mapped_addr
               << " id: " << std::hex << it->id
               << " size: " << std::hex << it->size;
   }
 }

 bool AddressMapper::GetMappedAddressAndListIterator(
     const uint64_t real_addr, uint64_t* mapped_addr,
     MappingList::const_iterator* iter) const {
   CHECK(mapped_addr);
   CHECK(iter);

   *iter = GetRangeContainingAddress(real_addr);
   if (*iter == mappings_.end()) return false;
   *mapped_addr = (*iter)->mapped_addr + real_addr - (*iter)->real_addr;
   return true;
 }

 void AddressMapper::GetMappedIDAndOffset(
     const uint64_t real_addr, MappingList::const_iterator real_addr_iter,
     uint64_t* id, uint64_t* offset) const {
   CHECK(real_addr_iter != mappings_.end());
   CHECK(id);
   CHECK(offset);

   *id = real_addr_iter->id;
   *offset = real_addr - real_addr_iter->real_addr + real_addr_iter->offset_base;
 }

 uint64_t AddressMapper::GetMaxMappedLength() const {
   if (IsEmpty()) return 0;

   uint64_t min = mappings_.begin()->mapped_addr;

   MappingList::const_iterator iter = mappings_.end();
   --iter;
   uint64_t max = iter->mapped_addr + iter->size;

   return max - min;
 }

 void AddressMapper::Unmap(MappingList::iterator mapping_iter) {
   // Add the freed up space to the free space counter of the previous
   // mapped region, if it exists.
   if (mapping_iter != mappings_.begin()) {
     const MappedRange& range = *mapping_iter;
     MappingList::iterator previous_range_iter = std::prev(mapping_iter);
     previous_range_iter->unmapped_space_after +=
         range.size + range.unmapped_space_after;
   }
   real_addr_to_mapped_range_.erase(mapping_iter->real_addr);
   mappings_.erase(mapping_iter);
 }

 AddressMapper::MappingList::const_iterator
 AddressMapper::GetRangeContainingAddress(uint64_t real_addr) const {
   // Find the first range that has a higher real address than the given one.
   MappingMap::const_iterator target_map_iter =
       real_addr_to_mapped_range_.upper_bound(real_addr);

   if (target_map_iter == real_addr_to_mapped_range_.begin()) {
     // The lowest real address in existing mappings is higher than the new
     // mapping address, so |real_addr| does not fall into any mapping.
     return mappings_.end();
   }

   // Otherwise, the previous mapping could possibly contain |real_addr|.
   --target_map_iter;
   MappingList::const_iterator list_iter = target_map_iter->second;
   if (!list_iter->ContainsAddress(real_addr)) return mappings_.end();

   return list_iter;
 }

 }  // namespace quipper
	// Copyright (c) 2013 The Chromium OS Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "address_mapper.h"

	#include <stdint.h>

	#include <vector>

	#include "base/logging.h"

	namespace quipper {

	AddressMapper::AddressMapper(const AddressMapper& other) {
	// Copy over most members naively.
	mappings_ = other.mappings_;
	page_alignment_ = other.page_alignment_;

	// Reconstruct mapping of real addresses to mapped ranges.
	for (auto iter = mappings_.begin(); iter != mappings_.end(); ++iter) {
	real_addr_to_mapped_range_[iter->real_addr] = iter;
	}
	}

	bool AddressMapper::MapWithID(const uint64_t real_addr, const uint64_t size,
	const uint64_t id, const uint64_t offset_base,
	bool remove_existing_mappings) {
	if (size == 0) {
	LOG(ERROR) << "Must allocate a nonzero-length address range.";
	return false;
	}

	// Check that this mapping does not overflow the address space.
	if (real_addr + size - 1 != UINT64_MAX && !(real_addr + size > real_addr)) {
	DumpToLog();
	LOG(ERROR) << "Address mapping at " << std::hex << real_addr
	<< " with size " << std::hex << size << " overflows.";
	return false;
	}

	MappedRange range;
	range.real_addr = real_addr;
	range.size = size;
	range.id = id;
	range.offset_base = offset_base;

	// Check for collision with an existing mapping. This must be an overlap that
	// does not result in one range being completely covered by another.

	// First determine the range of mappings that could overlap with the new
	// mapping in real space.

	// lower_bound returns the first range with starting addr >= \|real_addr\|. The
	// preceding range could also possibly overlap with the new range.
	auto map_iter_start = real_addr_to_mapped_range_.lower_bound(real_addr);
	if (map_iter_start != real_addr_to_mapped_range_.begin()) --map_iter_start;
	// lower_bound returns the first range with starting addr beyond the end of
	// the new mapping range.
	auto map_iter_end = real_addr_to_mapped_range_.lower_bound(real_addr + size);

	std::vector<MappingList::iterator> mappings_to_delete;
	MappingList::iterator old_range_iter = mappings_.end();
	for (auto map_iter = map_iter_start; map_iter != map_iter_end; ++map_iter) {
	auto iter = map_iter->second;
	if (!iter->Intersects(range)) continue;
	// Quit if existing ranges that collide aren't supposed to be removed.
	if (!remove_existing_mappings) return false;
	if (old_range_iter == mappings_.end() && iter->Covers(range) &&
	iter->size > range.size) {
	old_range_iter = iter;
	continue;
	}
	mappings_to_delete.push_back(iter);
	}

	for (MappingList::iterator mapping_iter : mappings_to_delete)
	Unmap(mapping_iter);
	mappings_to_delete.clear();

	// Otherwise check for this range being covered by another range. If that
	// happens, split or reduce the existing range to make room.
	if (old_range_iter != mappings_.end()) {
	// Make a copy of the old mapping before removing it.
	const MappedRange old_range = *old_range_iter;
	Unmap(old_range_iter);

	uint64_t gap_before = range.real_addr - old_range.real_addr;
	uint64_t gap_after =
	(old_range.real_addr + old_range.size) - (range.real_addr + range.size);

	// If the new mapping is not aligned to a page boundary at either its start
	// or end, it will require the end of the old mapping range to be moved,
	// which is not allowed.
	if (page_alignment_) {
	if ((gap_before && GetAlignedOffset(range.real_addr)) \|\|
	(gap_after && GetAlignedOffset(range.real_addr + range.size))) {
	LOG(ERROR) << "Split mapping must result in page-aligned mappings.";
	return false;
	}
	}

	if (gap_before) {
	if (!MapWithID(old_range.real_addr, gap_before, old_range.id,
	old_range.offset_base, false)) {
	LOG(ERROR) << "Could not map old range from " << std::hex
	<< old_range.real_addr << " to "
	<< old_range.real_addr + gap_before;
	return false;
	}
	}

	if (!MapWithID(range.real_addr, range.size, id, offset_base, false)) {
	LOG(ERROR) << "Could not map new range at " << std::hex << range.real_addr
	<< " to " << range.real_addr + range.size << " over old range";
	return false;
	}

	if (gap_after) {
	if (!MapWithID(range.real_addr + range.size, gap_after, old_range.id,
	old_range.offset_base + gap_before + range.size, false)) {
	LOG(ERROR) << "Could not map old range from " << std::hex
	<< old_range.real_addr << " to "
	<< old_range.real_addr + gap_before;
	return false;
	}
	}

	return true;
	}

	// Now search for a location for the new range. It should be in the first
	// free block in quipper space.

	uint64_t page_offset =
	page_alignment_ ? GetAlignedOffset(range.real_addr) : 0;

	// If there is no existing mapping, add it to the beginning of quipper space.
	if (IsEmpty()) {
	range.mapped_addr = page_offset;
	range.unmapped_space_after = UINT64_MAX - range.size - page_offset;
	mappings_.push_back(range);
	real_addr_to_mapped_range_.insert(
	std::make_pair(range.real_addr, mappings_.begin()));
	return true;
	}

	// If there is space before the first mapped range in quipper space, use it.
	if (mappings_.begin()->mapped_addr >= range.size + page_offset) {
	range.mapped_addr = page_offset;
	range.unmapped_space_after =
	mappings_.begin()->mapped_addr - range.size - page_offset;
	mappings_.push_front(range);
	MappingList::iterator iter = mappings_.begin();
	real_addr_to_mapped_range_.insert(std::make_pair(range.real_addr, iter));
	return true;
	}

	// Otherwise, search through the existing mappings for a free block after one
	// of them.
	for (auto iter = mappings_.begin(); iter != mappings_.end(); ++iter) {
	MappedRange& existing_mapping = *iter;
	if (page_alignment_) {
	uint64_t end_of_existing_mapping =
	existing_mapping.mapped_addr + existing_mapping.size;

	// Find next page boundary after end of this existing mapping.
	uint64_t existing_page_offset = GetAlignedOffset(end_of_existing_mapping);
	uint64_t next_page_boundary =
	existing_page_offset
	? end_of_existing_mapping - existing_page_offset + page_alignment_
	: end_of_existing_mapping;
	// Compute where the new mapping would end if it were aligned to this
	// page boundary.
	uint64_t mapping_offset = GetAlignedOffset(range.real_addr);
	uint64_t end_of_new_mapping =
	next_page_boundary + mapping_offset + range.size;
	uint64_t end_of_unmapped_space_after =
	end_of_existing_mapping + existing_mapping.unmapped_space_after;

	// Check if there's enough room in the unmapped space following the
	// current existing mapping for the page-aligned mapping.
	if (end_of_new_mapping > end_of_unmapped_space_after) continue;

	range.mapped_addr = next_page_boundary + mapping_offset;
	range.unmapped_space_after =
	end_of_unmapped_space_after - end_of_new_mapping;
	existing_mapping.unmapped_space_after =
	range.mapped_addr - end_of_existing_mapping;
	} else {
	if (existing_mapping.unmapped_space_after < range.size) continue;
	// Insert the new mapping range immediately after the existing one.
	range.mapped_addr = existing_mapping.mapped_addr + existing_mapping.size;
	range.unmapped_space_after =
	existing_mapping.unmapped_space_after - range.size;
	existing_mapping.unmapped_space_after = 0;
	}

	mappings_.insert(++iter, range);
	--iter;
	real_addr_to_mapped_range_.insert(std::make_pair(range.real_addr, iter));
	return true;
	}

	// If it still hasn't succeeded in mapping, it means there is no free space in
	// quipper space large enough for a mapping of this size.
	DumpToLog();
	LOG(ERROR) << "Could not find space to map addr=" << std::hex << real_addr
	<< " with size " << std::hex << size;
	return false;
	}

	void AddressMapper::DumpToLog() const {
	MappingList::const_iterator it;
	for (it = mappings_.begin(); it != mappings_.end(); ++it) {
	LOG(INFO) << " real_addr: " << std::hex << it->real_addr
	<< " mapped: " << std::hex << it->mapped_addr
	<< " id: " << std::hex << it->id
	<< " size: " << std::hex << it->size;
	}
	}

	bool AddressMapper::GetMappedAddressAndListIterator(
	const uint64_t real_addr, uint64_t* mapped_addr,
	MappingList::const_iterator* iter) const {
	CHECK(mapped_addr);
	CHECK(iter);

	*iter = GetRangeContainingAddress(real_addr);
	if (*iter == mappings_.end()) return false;
	mapped_addr = (iter)->mapped_addr + real_addr - (*iter)->real_addr;
	return true;
	}

	void AddressMapper::GetMappedIDAndOffset(
	const uint64_t real_addr, MappingList::const_iterator real_addr_iter,
	uint64_t* id, uint64_t* offset) const {
	CHECK(real_addr_iter != mappings_.end());
	CHECK(id);
	CHECK(offset);

	*id = real_addr_iter->id;
	*offset = real_addr - real_addr_iter->real_addr + real_addr_iter->offset_base;
	}

	uint64_t AddressMapper::GetMaxMappedLength() const {
	if (IsEmpty()) return 0;

	uint64_t min = mappings_.begin()->mapped_addr;

	MappingList::const_iterator iter = mappings_.end();
	--iter;
	uint64_t max = iter->mapped_addr + iter->size;

	return max - min;
	}

	void AddressMapper::Unmap(MappingList::iterator mapping_iter) {
	// Add the freed up space to the free space counter of the previous
	// mapped region, if it exists.
	if (mapping_iter != mappings_.begin()) {
	const MappedRange& range = *mapping_iter;
	MappingList::iterator previous_range_iter = std::prev(mapping_iter);
	previous_range_iter->unmapped_space_after +=
	range.size + range.unmapped_space_after;
	}
	real_addr_to_mapped_range_.erase(mapping_iter->real_addr);
	mappings_.erase(mapping_iter);
	}

	AddressMapper::MappingList::const_iterator
	AddressMapper::GetRangeContainingAddress(uint64_t real_addr) const {
	// Find the first range that has a higher real address than the given one.
	MappingMap::const_iterator target_map_iter =
	real_addr_to_mapped_range_.upper_bound(real_addr);

	if (target_map_iter == real_addr_to_mapped_range_.begin()) {
	// The lowest real address in existing mappings is higher than the new
	// mapping address, so \|real_addr\| does not fall into any mapping.
	return mappings_.end();
	}

	// Otherwise, the previous mapping could possibly contain \|real_addr\|.
	--target_map_iter;
	MappingList::const_iterator list_iter = target_map_iter->second;
	if (!list_iter->ContainsAddress(real_addr)) return mappings_.end();

	return list_iter;
	}

	} // namespace quipper