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rpcs3/Utilities/address_range.h

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#pragma once
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#include "util/types.hpp"
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#include "StrFmt.h"
#include <vector>
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#include <algorithm>
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namespace utils
{
class address_range_vector;
/**
* Constexprs
*/
constexpr inline u32 page_start(u32 addr)
{
return addr & ~4095u;
}
constexpr inline u32 next_page(u32 addr)
{
return page_start(addr + 4096u);
}
constexpr inline u32 page_end(u32 addr)
{
return next_page(addr) - 1;
}
constexpr inline u32 is_page_aligned(u32 addr)
{
return page_start(addr) == addr;
}
/**
* Address Range utility class
*/
class address_range
{
public:
u32 start = umax; // First address in range
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u32 end = 0; // Last address
private:
// Helper constexprs
static constexpr inline bool range_overlaps(u32 start1, u32 end1, u32 start2, u32 end2)
{
return (start1 <= end2 && start2 <= end1);
}
static constexpr inline bool address_overlaps(u32 address, u32 start, u32 end)
{
return (start <= address && address <= end);
}
static constexpr inline bool range_inside_range(u32 start1, u32 end1, u32 start2, u32 end2)
{
return (start1 >= start2 && end1 <= end2);
}
constexpr address_range(u32 _start, u32 _end) : start(_start), end(_end) {}
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public:
// Constructors
constexpr address_range() = default;
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static constexpr address_range start_length(u32 _start, u32 _length)
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{
if (!_length)
{
return {};
}
return {_start, _start + (_length - 1)};
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}
static constexpr address_range start_end(u32 _start, u32 _end)
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{
return {_start, _end};
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}
// Length
u32 length() const
{
AUDIT(valid());
return end - start + 1;
}
void set_length(const u32 new_length)
{
end = start + new_length - 1;
ensure(valid());
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}
u32 next_address() const
{
return end + 1;
}
u32 prev_address() const
{
return start - 1;
}
// Overlapping checks
bool overlaps(const address_range &other) const
{
AUDIT(valid() && other.valid());
return range_overlaps(start, end, other.start, other.end);
}
bool overlaps(const u32 addr) const
{
AUDIT(valid());
return address_overlaps(addr, start, end);
}
bool inside(const address_range &other) const
{
AUDIT(valid() && other.valid());
return range_inside_range(start, end, other.start, other.end);
}
inline bool inside(const address_range_vector &vec) const;
inline bool overlaps(const address_range_vector &vec) const;
bool touches(const address_range &other) const
{
AUDIT(valid() && other.valid());
// returns true if there is overlap, or if sections are side-by-side
return overlaps(other) || other.start == next_address() || other.end == prev_address();
}
// Utilities
s32 signed_distance(const address_range &other) const
{
if (touches(other))
{
return 0;
}
// other after this
if (other.start > end)
{
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return static_cast<s32>(other.start - end - 1);
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}
// this after other
AUDIT(start > other.end);
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return -static_cast<s32>(start - other.end - 1);
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}
u32 distance(const address_range &other) const
{
if (touches(other))
{
return 0;
}
// other after this
if (other.start > end)
{
return (other.start - end - 1);
}
// this after other
AUDIT(start > other.end);
return (start - other.end - 1);
}
address_range get_min_max(const address_range &other) const
{
return {
std::min(valid() ? start : umax, other.valid() ? other.start : umax),
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std::max(valid() ? end : 0, other.valid() ? other.end : 0)
};
}
void set_min_max(const address_range &other)
{
*this = get_min_max(other);
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}
bool is_page_range() const
{
return (valid() && start % 4096u == 0 && length() % 4096u == 0);
}
address_range to_page_range() const
{
AUDIT(valid());
return { page_start(start), page_end(end) };
}
void page_align()
{
AUDIT(valid());
start = page_start(start);
end = page_end(end);
AUDIT(is_page_range());
}
address_range get_intersect(const address_range &clamp) const
{
if (!valid() || !clamp.valid())
{
return {};
}
return { std::max(start, clamp.start), std::min(end, clamp.end) };
}
void intersect(const address_range &clamp)
{
if (!clamp.valid())
{
invalidate();
}
else
{
start = std::max(start, clamp.start);
end = std::min(end, clamp.end);
}
}
// Validity
bool valid() const
{
return (start <= end);
}
void invalidate()
{
start = umax;
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end = 0;
}
// Comparison Operators
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bool operator ==(const address_range& other) const
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{
return (start == other.start && end == other.end);
}
/**
* Debug
*/
std::string str() const
{
return fmt::format("{0x%x->0x%x}", start, end);
}
};
static inline address_range page_for(u32 addr)
{
return address_range::start_end(page_start(addr), page_end(addr));
}
/**
* Address Range Vector utility class
*
* Collection of address_range objects. Allows for merging and removing ranges from the set.
*/
class address_range_vector
{
public:
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using vector_type = std::vector<address_range>;
using iterator = vector_type::iterator;
using const_iterator = vector_type::const_iterator;
using size_type = vector_type::size_type;
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private:
vector_type data;
public:
// Wrapped functions
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inline void reserve(usz nr) { data.reserve(nr); }
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inline void clear() { data.clear(); }
inline size_type size() const { return data.size(); }
inline bool empty() const { return data.empty(); }
inline address_range& operator[](size_type n) { return data[n]; }
inline const address_range& operator[](size_type n) const { return data[n]; }
inline iterator begin() { return data.begin(); }
inline const_iterator begin() const { return data.begin(); }
inline iterator end() { return data.end(); }
inline const_iterator end() const { return data.end(); }
// Search for ranges that touch new_range. If found, merge instead of adding new_range.
// When adding a new range, re-use invalid ranges whenever possible
void merge(const address_range &new_range)
{
// Note the case where we have
// AAAA BBBB
// CCCC
// If we have data={A,B}, and new_range=C, we have to merge A with C, then B with A and invalidate B
if (!new_range.valid())
{
return;
}
address_range *found = nullptr;
address_range *invalid = nullptr;
for (auto &existing : data)
{
if (!existing.valid())
{
invalid = &existing;
continue;
}
// range1 overlaps, is immediately before, or is immediately after range2
if (existing.touches(new_range))
{
if (found != nullptr)
{
// Already found a match, merge and invalidate "existing"
found->set_min_max(existing);
existing.invalidate();
}
else
{
// First match, merge "new_range"
existing.set_min_max(new_range);
found = &existing;
}
}
}
if (found != nullptr)
{
return;
}
if (invalid != nullptr)
{
*invalid = new_range;
}
else
{
data.push_back(new_range);
}
AUDIT(check_consistency());
}
void merge(const address_range_vector &other)
{
for (const address_range &new_range : other)
{
merge(new_range);
}
}
// Exclude a given range from data
void exclude(const address_range &exclusion)
{
// Note the case where we have
// AAAAAAA
// EEE
// where data={A} and exclusion=E.
// In this case, we need to reduce A to the head (before E starts), and then create a new address_range B for the tail (after E ends), i.e.
// AA BB
// EEE
if (!exclusion.valid())
{
return;
}
address_range *invalid = nullptr; // try to re-use an invalid range instead of calling push_back
// We use index access because we might have to push_back within the loop, which could invalidate the iterators
size_type _size = data.size();
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for (size_type n = 0; n < _size; ++n)
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{
address_range &existing = data[n];
if (!existing.valid())
{
// Null
invalid = &existing;
continue;
}
if (!existing.overlaps(exclusion))
{
// No overlap, skip
continue;
}
const bool head_excluded = exclusion.overlaps(existing.start); // This section has its start inside excluded range
const bool tail_excluded = exclusion.overlaps(existing.end); // This section has its end inside excluded range
if (head_excluded && tail_excluded)
{
// Cannot be salvaged, fully excluded
existing.invalidate();
invalid = &existing;
}
else if (head_excluded)
{
// Head overlaps, truncate head
existing.start = exclusion.next_address();
}
else if (tail_excluded)
{
// Tail overlaps, truncate tail
existing.end = exclusion.prev_address();
}
else
{
// Section sits in the middle (see comment above function header)
AUDIT(exclusion.inside(existing));
const auto tail_end = existing.end;
// Head
existing.end = exclusion.prev_address();
// Tail
if (invalid != nullptr)
{
invalid->start = exclusion.next_address();
invalid->end = tail_end;
invalid = nullptr;
}
else
{
// IMPORTANT: adding to data invalidates "existing". This must be done last!
data.push_back(address_range::start_end(exclusion.next_address(), tail_end));
}
}
}
AUDIT(check_consistency());
AUDIT(!overlaps(exclusion));
}
void exclude(const address_range_vector &other)
{
for (const address_range &exclusion : other)
{
exclude(exclusion);
}
}
// Checks the consistency of this vector.
// Will fail if ranges within the vector overlap our touch each-other
bool check_consistency() const
{
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const usz _size = data.size();
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for (usz i = 0; i < _size; ++i)
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{
const auto &r1 = data[i];
if (!r1.valid())
{
continue;
}
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for (usz j = i + 1; j < _size; ++j)
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{
const auto &r2 = data[j];
if (!r2.valid())
{
continue;
}
if (r1.touches(r2))
{
return false;
}
}
}
return true;
}
// Test for overlap with a given range
bool overlaps(const address_range &range) const
{
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return std::any_of(data.cbegin(), data.cend(), [&range](const address_range& cur)
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{
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return cur.valid() && cur.overlaps(range);
});
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}
// Test for overlap with a given address_range vector
bool overlaps(const address_range_vector &other) const
{
for (const address_range &rng1 : data)
{
if (!rng1.valid())
{
continue;
}
for (const address_range &rng2 : other.data)
{
if (!rng2.valid())
{
continue;
}
if (rng1.overlaps(rng2))
{
return true;
}
}
}
return false;
}
// Test if a given range is fully contained inside this vector
bool contains(const address_range &range) const
{
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return std::any_of(this->begin(), this->end(), [&range](const address_range& cur)
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{
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return cur.valid() && cur.inside(range);
});
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}
// Test if all ranges in this vector are full contained inside a specific range
bool inside(const address_range &range) const
{
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return std::all_of(this->begin(), this->end(), [&range](const address_range& cur)
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{
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return !cur.valid() || cur.inside(range);
});
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}
};
// These declarations must be done after address_range_vector has been defined
bool address_range::inside(const address_range_vector &vec) const
{
return vec.contains(*this);
}
bool address_range::overlaps(const address_range_vector &vec) const
{
return vec.overlaps(*this);
}
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} // namespace utils
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namespace std
{
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static_assert(sizeof(usz) >= 2 * sizeof(u32), "usz must be at least twice the size of u32");
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template <>
struct hash<utils::address_range>
{
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usz operator()(const utils::address_range& k) const
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{
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// we can guarantee a unique hash since our type is 64 bits and usz as well
return (usz{ k.start } << 32) | usz{ k.end };
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}
};
}