using System;
using System.Runtime.Versioning;
namespace Ryujinx.Memory.WindowsShared
{
///
/// Windows 4KB memory placeholder manager.
///
[SupportedOSPlatform("windows")]
class PlaceholderManager4KB
{
private const int PageSize = MemoryManagementWindows.PageSize;
private readonly IntervalTree _mappings;
///
/// Creates a new instance of the Windows 4KB memory placeholder manager.
///
public PlaceholderManager4KB()
{
_mappings = new IntervalTree();
}
///
/// Unmaps the specified range of memory and marks it as mapped internally.
///
///
/// Since this marks the range as mapped, the expectation is that the range will be mapped after calling this method.
///
/// Memory address to unmap and mark as mapped
/// Size of the range in bytes
public void UnmapAndMarkRangeAsMapped(IntPtr location, IntPtr size)
{
ulong startAddress = (ulong)location;
ulong unmapSize = (ulong)size;
ulong endAddress = startAddress + unmapSize;
var overlaps = Array.Empty>();
int count = 0;
lock (_mappings)
{
count = _mappings.Get(startAddress, endAddress, ref overlaps);
}
for (int index = 0; index < count; index++)
{
var overlap = overlaps[index];
// Tree operations might modify the node start/end values, so save a copy before we modify the tree.
ulong overlapStart = overlap.Start;
ulong overlapEnd = overlap.End;
ulong overlapValue = overlap.Value;
_mappings.Remove(overlap);
ulong unmapStart = Math.Max(overlapStart, startAddress);
ulong unmapEnd = Math.Min(overlapEnd, endAddress);
if (overlapStart < startAddress)
{
startAddress = overlapStart;
}
if (overlapEnd > endAddress)
{
endAddress = overlapEnd;
}
ulong currentAddress = unmapStart;
while (currentAddress < unmapEnd)
{
WindowsApi.UnmapViewOfFile2(WindowsApi.CurrentProcessHandle, (IntPtr)currentAddress, 2);
currentAddress += PageSize;
}
}
_mappings.Add(startAddress, endAddress, 0);
}
///
/// Unmaps views at the specified memory range.
///
/// Address of the range
/// Size of the range in bytes
public void UnmapView(IntPtr location, IntPtr size)
{
ulong startAddress = (ulong)location;
ulong unmapSize = (ulong)size;
ulong endAddress = startAddress + unmapSize;
var overlaps = Array.Empty>();
int count = 0;
lock (_mappings)
{
count = _mappings.Get(startAddress, endAddress, ref overlaps);
}
for (int index = 0; index < count; index++)
{
var overlap = overlaps[index];
// Tree operations might modify the node start/end values, so save a copy before we modify the tree.
ulong overlapStart = overlap.Start;
ulong overlapEnd = overlap.End;
_mappings.Remove(overlap);
if (overlapStart < startAddress)
{
_mappings.Add(overlapStart, startAddress, 0);
}
if (overlapEnd > endAddress)
{
_mappings.Add(endAddress, overlapEnd, 0);
}
ulong unmapStart = Math.Max(overlapStart, startAddress);
ulong unmapEnd = Math.Min(overlapEnd, endAddress);
ulong currentAddress = unmapStart;
while (currentAddress < unmapEnd)
{
WindowsApi.UnmapViewOfFile2(WindowsApi.CurrentProcessHandle, (IntPtr)currentAddress, 2);
currentAddress += PageSize;
}
}
}
///
/// Unmaps mapped memory at a given range.
///
/// Address of the range
/// Size of the range in bytes
public void UnmapRange(IntPtr location, IntPtr size)
{
ulong startAddress = (ulong)location;
ulong unmapSize = (ulong)size;
ulong endAddress = startAddress + unmapSize;
var overlaps = Array.Empty>();
int count = 0;
lock (_mappings)
{
count = _mappings.Get(startAddress, endAddress, ref overlaps);
}
for (int index = 0; index < count; index++)
{
var overlap = overlaps[index];
// Tree operations might modify the node start/end values, so save a copy before we modify the tree.
ulong unmapStart = Math.Max(overlap.Start, startAddress);
ulong unmapEnd = Math.Min(overlap.End, endAddress);
_mappings.Remove(overlap);
ulong currentAddress = unmapStart;
while (currentAddress < unmapEnd)
{
WindowsApi.UnmapViewOfFile2(WindowsApi.CurrentProcessHandle, (IntPtr)currentAddress, 2);
currentAddress += PageSize;
}
}
}
}
}