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0ad/source/lib/sysdep/os/win/wnuma.cpp
phosit 08d8f0f61c Remove UNUSED2 
The remaining uses can be changed to `std::ignore`.
Fix #7760
2025-07-28 13:16:37 +02:00

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/* Copyright (C) 2025 Wildfire Games.
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#include "precompiled.h"
#include "lib/sysdep/numa.h"
#include "lib/bits.h" // PopulationCount
#include "lib/alignment.h"
#include "lib/lib.h"
#include "lib/timer.h"
#include "lib/module_init.h"
#include "lib/sysdep/vm.h"
#include "lib/sysdep/os_cpu.h"
#include "lib/sysdep/os/win/acpi.h"
#include "lib/sysdep/os/win/win.h"
#include "lib/sysdep/os/win/wutil.h"
#include "lib/sysdep/os/win/wcpu.h"
#include <map>
#include <Psapi.h>
#include <utility>
#if ARCH_X86_X64
#include "lib/sysdep/arch/x86_x64/apic.h" // ProcessorFromApicId
#endif
//-----------------------------------------------------------------------------
// nodes
struct Node // POD
{
// (Windows doesn't guarantee node numbers are contiguous, so
// we associate them with contiguous indices in nodes[])
UCHAR nodeNumber;
u32 proximityDomainNumber;
uintptr_t processorMask;
};
static Node nodes[os_cpu_MaxProcessors];
static size_t numNodes;
static Node* AddNode()
{
ENSURE(numNodes < ARRAY_SIZE(nodes));
return &nodes[numNodes++];
}
static Node* FindNodeWithProcessorMask(uintptr_t processorMask)
{
for(size_t node = 0; node < numNodes; node++)
{
if(nodes[node].processorMask == processorMask)
return &nodes[node];
}
return 0;
}
static Node* FindNodeWithProcessor(size_t processor)
{
for(size_t node = 0; node < numNodes; node++)
{
if(IsBitSet(nodes[node].processorMask, processor))
return &nodes[node];
}
return 0;
}
//-----------------------------------------------------------------------------
// Windows topology
static UCHAR HighestNodeNumber()
{
WUTIL_FUNC(pGetNumaHighestNodeNumber, BOOL, (PULONG));
WUTIL_IMPORT_KERNEL32(GetNumaHighestNodeNumber, pGetNumaHighestNodeNumber);
if(!pGetNumaHighestNodeNumber)
return 0; // NUMA not supported => only one node
ULONG highestNodeNumber;
const BOOL ok = pGetNumaHighestNodeNumber(&highestNodeNumber);
WARN_IF_FALSE(ok);
return (UCHAR)highestNodeNumber;
}
static void PopulateNodes()
{
WUTIL_FUNC(pGetNumaNodeProcessorMask, BOOL, (UCHAR, PULONGLONG));
WUTIL_IMPORT_KERNEL32(GetNumaNodeProcessorMask, pGetNumaNodeProcessorMask);
if(!pGetNumaNodeProcessorMask)
return;
DWORD_PTR processAffinity, systemAffinity;
{
const BOOL ok = GetProcessAffinityMask(GetCurrentProcess(), &processAffinity, &systemAffinity);
WARN_IF_FALSE(ok);
}
ENSURE(PopulationCount(processAffinity) <= PopulationCount(systemAffinity));
for(UCHAR nodeNumber = 0; nodeNumber <= HighestNodeNumber(); nodeNumber++)
{
ULONGLONG affinity;
{
const BOOL ok = pGetNumaNodeProcessorMask(nodeNumber, &affinity);
WARN_IF_FALSE(ok);
}
if(!affinity)
continue; // empty node, skip
Node* node = AddNode();
node->nodeNumber = nodeNumber;
node->processorMask = wcpu_ProcessorMaskFromAffinity(processAffinity, (DWORD_PTR)affinity);
}
}
//-----------------------------------------------------------------------------
// ACPI SRAT topology
#if ARCH_X86_X64
#pragma pack(push, 1)
// fields common to Affinity* structures
struct AffinityHeader
{
u8 type;
u8 length; // size [bytes], including this header
};
struct AffinityAPIC
{
static const u8 type = 0;
AffinityHeader header;
u8 proximityDomainNumber0;
u8 apicId;
u32 flags;
u8 sapicId;
u8 proximityDomainNumber123[3];
u32 clockDomain;
u32 ProximityDomainNumber() const
{
// (this is the apparent result of backwards compatibility, ugh.)
u32 proximityDomainNumber;
memcpy(&proximityDomainNumber, &proximityDomainNumber123[0]-1, sizeof(proximityDomainNumber));
proximityDomainNumber &= ~0xFF;
proximityDomainNumber |= proximityDomainNumber0;
return proximityDomainNumber;
}
};
struct AffinityMemory
{
static const u8 type = 1;
AffinityHeader header;
u32 proximityDomainNumber;
u16 reserved1;
u64 baseAddress;
u64 length;
u32 reserved2;
u32 flags;
u64 reserved3;
};
// AffinityX2APIC omitted, since the APIC ID is sufficient for our purposes
// Static Resource Affinity Table
struct SRAT
{
AcpiTable header;
u32 reserved1;
u8 reserved2[8];
AffinityHeader affinities[1];
};
#pragma pack(pop)
template<class Affinity>
static const Affinity* DynamicCastFromHeader(const AffinityHeader* header)
{
if(header->type != Affinity::type)
return 0;
// sanity check: ensure no padding was inserted
ENSURE(header->length == sizeof(Affinity));
const Affinity* affinity = (const Affinity*)header;
if(!IsBitSet(affinity->flags, 0)) // not enabled
return 0;
return affinity;
}
struct ProximityDomain
{
uintptr_t processorMask;
// (AffinityMemory's fields are not currently needed)
};
typedef std::map<u32, ProximityDomain> ProximityDomains;
static ProximityDomains ExtractProximityDomainsFromSRAT(const SRAT* srat)
{
ProximityDomains proximityDomains;
for(const AffinityHeader* header = srat->affinities;
header < (const AffinityHeader*)(uintptr_t(srat)+srat->header.size);
header = (const AffinityHeader*)(uintptr_t(header) + header->length))
{
const AffinityAPIC* affinityAPIC = DynamicCastFromHeader<AffinityAPIC>(header);
if(!affinityAPIC)
continue;
if(!IsProcessorKnown(affinityAPIC->apicId))
{
debug_printf("Processor with APIC ID %d found in SRAT but not known to CPUID.", affinityAPIC->apicId);
continue;
}
const size_t processor = ProcessorFromApicId(affinityAPIC->apicId);
const u32 proximityDomainNumber = affinityAPIC->ProximityDomainNumber();
ProximityDomain& proximityDomain = proximityDomains[proximityDomainNumber];
proximityDomain.processorMask |= Bit<uintptr_t>(processor);
}
return proximityDomains;
}
static void PopulateNodesFromProximityDomains(const ProximityDomains& proximityDomains)
{
for(ProximityDomains::const_iterator it = proximityDomains.begin(); it != proximityDomains.end(); ++it)
{
const u32 proximityDomainNumber = it->first;
const ProximityDomain& proximityDomain = it->second;
Node* node = FindNodeWithProcessorMask(proximityDomain.processorMask);
if(!node)
node = AddNode();
// (we don't know Windows' nodeNumber; it has hopefully already been set)
node->proximityDomainNumber = proximityDomainNumber;
node->processorMask = proximityDomain.processorMask;
}
}
#endif // #if ARCH_X86_X64
//-----------------------------------------------------------------------------
static ModuleInitState initState{ 0 };
static Status InitTopology()
{
PopulateNodes();
#if ARCH_X86_X64
const SRAT* srat = (const SRAT*)acpi_GetTable("SRAT");
if(srat && AreApicIdsReliable())
{
const ProximityDomains proximityDomains = ExtractProximityDomainsFromSRAT(srat);
PopulateNodesFromProximityDomains(proximityDomains);
}
#endif
// neither OS nor ACPI information is available
if(numNodes == 0)
{
// add dummy node that contains all system processors
Node* node = AddNode();
node->nodeNumber = 0;
node->proximityDomainNumber = 0;
node->processorMask = os_cpu_ProcessorMask();
}
return INFO::OK;
}
size_t numa_NumNodes()
{
std::ignore = ModuleInit(&initState, InitTopology);
return numNodes;
}
size_t numa_NodeFromProcessor(size_t processor)
{
std::ignore = ModuleInit(&initState, InitTopology);
ENSURE(processor < os_cpu_NumProcessors());
Node* node = FindNodeWithProcessor(processor);
ENSURE(node);
return nodes-node;
}
uintptr_t numa_ProcessorMaskFromNode(size_t node)
{
std::ignore = ModuleInit(&initState, InitTopology);
ENSURE(node < numNodes);
return nodes[node].processorMask;
}
static UCHAR NodeNumberFromNode(size_t node)
{
std::ignore = ModuleInit(&initState, InitTopology);
ENSURE(node < numa_NumNodes());
return nodes[node].nodeNumber;
}
//-----------------------------------------------------------------------------
// memory info
size_t numa_AvailableMemory(size_t node)
{
// note: it is said that GetNumaAvailableMemoryNode sometimes incorrectly
// reports zero bytes. the actual cause may however be unexpected
// RAM configuration, e.g. not all slots filled.
WUTIL_FUNC(pGetNumaAvailableMemoryNode, BOOL, (UCHAR, PULONGLONG));
WUTIL_IMPORT_KERNEL32(GetNumaAvailableMemoryNode, pGetNumaAvailableMemoryNode);
if(pGetNumaAvailableMemoryNode)
{
const UCHAR nodeNumber = NodeNumberFromNode(node);
ULONGLONG availableBytes;
const BOOL ok = pGetNumaAvailableMemoryNode(nodeNumber, &availableBytes);
WARN_IF_FALSE(ok);
const size_t availableMiB = size_t(availableBytes / MiB);
return availableMiB;
}
// NUMA not supported - return available system memory
else
return os_cpu_MemoryAvailable();
}
#pragma pack(push, 1)
// ACPI System Locality Information Table
// (System Locality == Proximity Domain)
struct SLIT
{
AcpiTable header;
u64 numSystemLocalities;
u8 entries[1]; // numSystemLocalities*numSystemLocalities entries
};
#pragma pack(pop)
static double ReadRelativeDistanceFromSLIT(const SLIT* slit)
{
const size_t n = slit->numSystemLocalities;
ENSURE(slit->header.size == sizeof(SLIT)-sizeof(slit->entries)+n*n);
// diagonals are specified to be 10
for(size_t i = 0; i < n; i++)
ENSURE(slit->entries[i*n+i] == 10);
// entries = relativeDistance * 10
return *std::max_element(slit->entries, slit->entries+n*n) / 10.0;
}
// @return ratio between max/min time required to access one node's
// memory from each processor.
static double MeasureRelativeDistance()
{
const size_t size = 32*MiB;
void* mem = vm::Allocate(size);
const uintptr_t previousProcessorMask = os_cpu_SetThreadAffinityMask(os_cpu_ProcessorMask());
double minTime = 1e10, maxTime = 0.0;
for(size_t node = 0; node < numa_NumNodes(); node++)
{
const uintptr_t processorMask = numa_ProcessorMaskFromNode(node);
os_cpu_SetThreadAffinityMask(processorMask);
const double startTime = timer_Time();
memset(mem, 0, size);
const double elapsedTime = timer_Time() - startTime;
minTime = std::min(minTime, elapsedTime);
maxTime = std::max(maxTime, elapsedTime);
}
std::ignore = os_cpu_SetThreadAffinityMask(previousProcessorMask);
vm::Free(mem, size);
return maxTime / minTime;
}
static double relativeDistance;
static Status InitRelativeDistance()
{
// early-out for non-NUMA systems (saves some time)
if(numa_NumNodes() == 1)
{
relativeDistance = 1.0;
return INFO::OK;
}
// trust values reported by the BIOS, if available
const SLIT* slit = (const SLIT*)acpi_GetTable("SLIT");
if(slit)
relativeDistance = ReadRelativeDistanceFromSLIT(slit);
else
relativeDistance = MeasureRelativeDistance();
ENSURE(relativeDistance >= 1.0);
ENSURE(relativeDistance <= 4.0);
return INFO::OK;
}
double numa_Factor()
{
static ModuleInitState _initState{ 0 };
std::ignore = ModuleInit(&_initState, InitRelativeDistance);
return relativeDistance;
}
static bool IsMemoryInterleaved()
{
if(numa_NumNodes() == 1)
return false;
if(!acpi_GetTable("FACP")) // no ACPI tables available
return false; // indeterminate, assume not interleaved
if(acpi_GetTable("SRAT")) // present iff not interleaved
return false;
return true;
}
static bool isMemoryInterleaved;
static Status InitMemoryInterleaved()
{
isMemoryInterleaved = IsMemoryInterleaved();
return INFO::OK;
}
bool numa_IsMemoryInterleaved()
{
static ModuleInitState _initState{ 0 };
std::ignore = ModuleInit(&_initState, InitMemoryInterleaved);
return isMemoryInterleaved;
}
//-----------------------------------------------------------------------------
#if 0
static bool VerifyPages([[maybe_unused]] void* mem, [[maybe_unused]] size_t size,
[[maybe_unused]] size_t pageSize, [[maybe_unused]] size_t node)
{
WUTIL_FUNC(pQueryWorkingSetEx, BOOL, (HANDLE, PVOID, DWORD));
WUTIL_IMPORT_KERNEL32(QueryWorkingSetEx, pQueryWorkingSetEx);
if(!pQueryWorkingSetEx)
return true; // can't do anything
#if WINVER >= 0x600
size_t largePageSize = os_cpu_LargePageSize();
ENSURE(largePageSize != 0); // this value is needed for later
// retrieve attributes of all pages constituting mem
const size_t numPages = (size + pageSize-1) / pageSize;
PSAPI_WORKING_SET_EX_INFORMATION* wsi = new PSAPI_WORKING_SET_EX_INFORMATION[numPages];
for(size_t i = 0; i < numPages; i++)
wsi[i].VirtualAddress = (u8*)mem + i*pageSize;
pQueryWorkingSetEx(GetCurrentProcess(), wsi, DWORD(sizeof(PSAPI_WORKING_SET_EX_INFORMATION)*numPages));
// ensure each is valid and allocated on the correct node
for(size_t i = 0; i < numPages; i++)
{
const PSAPI_WORKING_SET_EX_BLOCK& attributes = wsi[i].VirtualAttributes;
if(!attributes.Valid)
return false;
if((attributes.LargePage != 0) != (pageSize == largePageSize))
{
debug_printf("NUMA: is not a large page\n");
return false;
}
if(attributes.Node != node)
{
debug_printf("NUMA: allocated from remote node\n");
return false;
}
}
delete[] wsi;
#endif
return true;
}
#endif
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