ollama/discover/gpu_windows.go

package discover

import (
	"fmt"
	"log/slog"
	"syscall"
	"unsafe"
)

type MEMORYSTATUSEX struct {
	length               uint32
	MemoryLoad           uint32
	TotalPhys            uint64
	AvailPhys            uint64
	TotalPageFile        uint64
	AvailPageFile        uint64
	TotalVirtual         uint64
	AvailVirtual         uint64
	AvailExtendedVirtual uint64
}

var (
	k32                              = syscall.NewLazyDLL("kernel32.dll")
	globalMemoryStatusExProc         = k32.NewProc("GlobalMemoryStatusEx")
	sizeofMemoryStatusEx             = uint32(unsafe.Sizeof(MEMORYSTATUSEX{}))
	GetLogicalProcessorInformationEx = k32.NewProc("GetLogicalProcessorInformationEx")
)

var CudartGlobs = []string{
	"c:\\Program Files\\NVIDIA GPU Computing Toolkit\\CUDA\\v*\\bin\\cudart64_*.dll",
}

var NvmlGlobs = []string{
	"c:\\Windows\\System32\\nvml.dll",
}

var NvcudaGlobs = []string{
	"c:\\windows\\system*\\nvcuda.dll",
}

var OneapiGlobs = []string{
	"c:\\Windows\\System32\\DriverStore\\FileRepository\\*\\ze_intel_gpu64.dll",
}

var (
	CudartMgmtName = "cudart64_*.dll"
	NvcudaMgmtName = "nvcuda.dll"
	NvmlMgmtName   = "nvml.dll"
	OneapiMgmtName = "ze_intel_gpu64.dll"
)

func GetCPUMem() (memInfo, error) {
	memStatus := MEMORYSTATUSEX{length: sizeofMemoryStatusEx}
	r1, _, err := globalMemoryStatusExProc.Call(uintptr(unsafe.Pointer(&memStatus)))
	if r1 == 0 {
		return memInfo{}, fmt.Errorf("GlobalMemoryStatusEx failed: %w", err)
	}
	return memInfo{TotalMemory: memStatus.TotalPhys, FreeMemory: memStatus.AvailPhys, FreeSwap: memStatus.AvailPageFile}, nil
}

type LOGICAL_PROCESSOR_RELATIONSHIP uint32

const (
	RelationProcessorCore LOGICAL_PROCESSOR_RELATIONSHIP = iota
	RelationNumaNode
	RelationCache
	RelationProcessorPackage
	RelationGroup
	RelationProcessorDie
	RelationNumaNodeEx
	RelationProcessorModule
)
const RelationAll LOGICAL_PROCESSOR_RELATIONSHIP = 0xffff

type GROUP_AFFINITY struct {
	Mask     uintptr // KAFFINITY
	Group    uint16
	Reserved [3]uint16
}

type PROCESSOR_RELATIONSHIP struct {
	Flags           byte
	EfficiencyClass byte
	Reserved        [20]byte
	GroupCount      uint16
	GroupMask       [1]GROUP_AFFINITY // len GroupCount
}

// Omitted unused structs: NUMA_NODE_RELATIONSHIP CACHE_RELATIONSHIP GROUP_RELATIONSHIP

type SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX struct {
	Relationship LOGICAL_PROCESSOR_RELATIONSHIP
	Size         uint32
	U            [1]byte // Union len Size
	// PROCESSOR_RELATIONSHIP
	// NUMA_NODE_RELATIONSHIP
	// CACHE_RELATIONSHIP
	// GROUP_RELATIONSHIP
}

func (group *GROUP_AFFINITY) IsMember(target *GROUP_AFFINITY) bool {
	if group == nil || target == nil {
		return false
	}
	return group.Mask&target.Mask != 0
}

type winPackage struct {
	groups              []*GROUP_AFFINITY
	coreCount           int // performance cores = coreCount - efficiencyCoreCount
	efficiencyCoreCount int
	threadCount         int
}

func (pkg *winPackage) IsMember(target *GROUP_AFFINITY) bool {
	for _, group := range pkg.groups {
		if group.IsMember(target) {
			return true
		}
	}
	return false
}

func getLogicalProcessorInformationEx() ([]byte, error) {
	buf := make([]byte, 1)
	bufSize := len(buf)
	ret, _, err := GetLogicalProcessorInformationEx.Call(
		uintptr(RelationAll),
		uintptr(unsafe.Pointer(&buf[0])),
		uintptr(unsafe.Pointer(&bufSize)),
	)
	if ret != 0 {
		return nil, fmt.Errorf("failed to determine size info ret:%d %w", ret, err)
	}

	buf = make([]byte, bufSize)
	ret, _, err = GetLogicalProcessorInformationEx.Call(
		uintptr(RelationAll),
		uintptr(unsafe.Pointer(&buf[0])),
		uintptr(unsafe.Pointer(&bufSize)),
	)
	if ret == 0 {
		return nil, fmt.Errorf("failed to gather processor information ret:%d buflen:%d %w", ret, bufSize, err)
	}
	return buf, nil
}

func processSystemLogicalProcessorInforationList(buf []byte) []*winPackage {
	var slpi *SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX
	// Find all the packages first
	packages := []*winPackage{}
	for bufOffset := 0; bufOffset < len(buf); bufOffset += int(slpi.Size) {
		slpi = (*SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX)(unsafe.Pointer(&buf[bufOffset]))
		if slpi.Relationship != RelationProcessorPackage {
			continue
		}
		pr := (*PROCESSOR_RELATIONSHIP)(unsafe.Pointer(&slpi.U[0]))
		pkg := &winPackage{}
		ga0 := unsafe.Pointer(&pr.GroupMask[0])
		for j := range pr.GroupCount {
			gm := (*GROUP_AFFINITY)(unsafe.Pointer(uintptr(ga0) + uintptr(j)*unsafe.Sizeof(GROUP_AFFINITY{})))
			pkg.groups = append(pkg.groups, gm)
		}
		packages = append(packages, pkg)
	}

	slog.Info("packages", "count", len(packages))

	// To identify efficiency cores we have to compare the relative values
	// Larger values are "less efficient" (aka, more performant)
	var maxEfficiencyClass byte
	for bufOffset := 0; bufOffset < len(buf); bufOffset += int(slpi.Size) {
		slpi = (*SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX)(unsafe.Pointer(&buf[bufOffset]))
		if slpi.Relationship != RelationProcessorCore {
			continue
		}
		pr := (*PROCESSOR_RELATIONSHIP)(unsafe.Pointer(&slpi.U[0]))
		if pr.EfficiencyClass > maxEfficiencyClass {
			maxEfficiencyClass = pr.EfficiencyClass
		}
	}
	if maxEfficiencyClass > 0 {
		slog.Info("efficiency cores detected", "maxEfficiencyClass", maxEfficiencyClass)
	}

	// then match up the Cores to the Packages, count up cores, threads and efficiency cores
	for bufOffset := 0; bufOffset < len(buf); bufOffset += int(slpi.Size) {
		slpi = (*SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX)(unsafe.Pointer(&buf[bufOffset]))
		if slpi.Relationship != RelationProcessorCore {
			continue
		}
		pr := (*PROCESSOR_RELATIONSHIP)(unsafe.Pointer(&slpi.U[0]))
		ga0 := unsafe.Pointer(&pr.GroupMask[0])
		for j := range pr.GroupCount {
			gm := (*GROUP_AFFINITY)(unsafe.Pointer(uintptr(ga0) + uintptr(j)*unsafe.Sizeof(GROUP_AFFINITY{})))
			for _, pkg := range packages {
				if pkg.IsMember(gm) {
					pkg.coreCount++
					if pr.Flags == 0 {
						pkg.threadCount++
					} else {
						pkg.threadCount += 2
					}
					if pr.EfficiencyClass < maxEfficiencyClass {
						pkg.efficiencyCoreCount++
					}
				}
			}
		}
	}

	// Sumarize the results
	for i, pkg := range packages {
		slog.Info("", "package", i, "cores", pkg.coreCount, "efficiency", pkg.efficiencyCoreCount, "threads", pkg.threadCount)
	}

	return packages
}

func GetCPUDetails() ([]CPU, error) {
	buf, err := getLogicalProcessorInformationEx()
	if err != nil {
		return nil, err
	}
	packages := processSystemLogicalProcessorInforationList(buf)
	cpus := make([]CPU, len(packages))

	for i, pkg := range packages {
		cpus[i].CoreCount = pkg.coreCount
		cpus[i].EfficiencyCoreCount = pkg.efficiencyCoreCount
		cpus[i].ThreadCount = pkg.threadCount
	}
	return cpus, nil
}
Rename gpu package discover (#7143) Cleaning up go package naming 2024-10-17 00:45:00 +00:00			`package discover`
review comments and coverage 2024-06-05 19:07:20 +00:00
			`import (`
			`"fmt"`
Discovery CPU details for default thread selection (#6264) On windows, detect large multi-socket systems and reduce to the number of cores in one socket for best performance 2024-10-15 18:36:08 +00:00			`"log/slog"`
review comments and coverage 2024-06-05 19:07:20 +00:00			`"syscall"`
			`"unsafe"`
			`)`

			`type MEMORYSTATUSEX struct {`
			`length uint32`
			`MemoryLoad uint32`
			`TotalPhys uint64`
			`AvailPhys uint64`
			`TotalPageFile uint64`
			`AvailPageFile uint64`
			`TotalVirtual uint64`
			`AvailVirtual uint64`
			`AvailExtendedVirtual uint64`
			`}`

			`var (`
Discovery CPU details for default thread selection (#6264) On windows, detect large multi-socket systems and reduce to the number of cores in one socket for best performance 2024-10-15 18:36:08 +00:00			`k32 = syscall.NewLazyDLL("kernel32.dll")`
			`globalMemoryStatusExProc = k32.NewProc("GlobalMemoryStatusEx")`
			`sizeofMemoryStatusEx = uint32(unsafe.Sizeof(MEMORYSTATUSEX{}))`
			`GetLogicalProcessorInformationEx = k32.NewProc("GetLogicalProcessorInformationEx")`
review comments and coverage 2024-06-05 19:07:20 +00:00			`)`

			`var CudartGlobs = []string{`
			`"c:\\Program Files\\NVIDIA GPU Computing Toolkit\\CUDA\\v\\bin\\cudart64_.dll",`
			`}`

			`var NvmlGlobs = []string{`
			`"c:\\Windows\\System32\\nvml.dll",`
			`}`

			`var NvcudaGlobs = []string{`
			`"c:\\windows\\system*\\nvcuda.dll",`
			`}`

			`var OneapiGlobs = []string{`
			`"c:\\Windows\\System32\\DriverStore\\FileRepository\\*\\ze_intel_gpu64.dll",`
			`}`

lint 2024-08-01 21:52:15 +00:00			`var (`
			`CudartMgmtName = "cudart64_*.dll"`
			`NvcudaMgmtName = "nvcuda.dll"`
			`NvmlMgmtName = "nvml.dll"`
			`OneapiMgmtName = "ze_intel_gpu64.dll"`
			`)`
review comments and coverage 2024-06-05 19:07:20 +00:00
			`func GetCPUMem() (memInfo, error) {`
			`memStatus := MEMORYSTATUSEX{length: sizeofMemoryStatusEx}`
			`r1, _, err := globalMemoryStatusExProc.Call(uintptr(unsafe.Pointer(&memStatus)))`
			`if r1 == 0 {`
			`return memInfo{}, fmt.Errorf("GlobalMemoryStatusEx failed: %w", err)`
			`}`
llm: avoid loading model if system memory is too small (#5637) * llm: avoid loading model if system memory is too small * update log * Instrument swap free space On linux and windows, expose how much swap space is available so we can take that into consideration when scheduling models * use `systemSwapFreeMemory` in check --------- Co-authored-by: Daniel Hiltgen <daniel@ollama.com> 2024-07-11 23:42:57 +00:00			`return memInfo{TotalMemory: memStatus.TotalPhys, FreeMemory: memStatus.AvailPhys, FreeSwap: memStatus.AvailPageFile}, nil`
review comments and coverage 2024-06-05 19:07:20 +00:00			`}`
Discovery CPU details for default thread selection (#6264) On windows, detect large multi-socket systems and reduce to the number of cores in one socket for best performance 2024-10-15 18:36:08 +00:00
			`type LOGICAL_PROCESSOR_RELATIONSHIP uint32`

			`const (`
			`RelationProcessorCore LOGICAL_PROCESSOR_RELATIONSHIP = iota`
			`RelationNumaNode`
			`RelationCache`
			`RelationProcessorPackage`
			`RelationGroup`
			`RelationProcessorDie`
			`RelationNumaNodeEx`
			`RelationProcessorModule`
			`)`
			`const RelationAll LOGICAL_PROCESSOR_RELATIONSHIP = 0xffff`

			`type GROUP_AFFINITY struct {`
			`Mask uintptr // KAFFINITY`
			`Group uint16`
			`Reserved [3]uint16`
			`}`

			`type PROCESSOR_RELATIONSHIP struct {`
			`Flags byte`
			`EfficiencyClass byte`
			`Reserved [20]byte`
			`GroupCount uint16`
			`GroupMask [1]GROUP_AFFINITY // len GroupCount`
			`}`

			`// Omitted unused structs: NUMA_NODE_RELATIONSHIP CACHE_RELATIONSHIP GROUP_RELATIONSHIP`

			`type SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX struct {`
			`Relationship LOGICAL_PROCESSOR_RELATIONSHIP`
			`Size uint32`
			`U [1]byte // Union len Size`
			`// PROCESSOR_RELATIONSHIP`
			`// NUMA_NODE_RELATIONSHIP`
			`// CACHE_RELATIONSHIP`
			`// GROUP_RELATIONSHIP`
			`}`

			`func (group GROUP_AFFINITY) IsMember(target GROUP_AFFINITY) bool {`
			`if group == nil \|\| target == nil {`
			`return false`
			`}`
			`return group.Mask&target.Mask != 0`
			`}`

			`type winPackage struct {`
			`groups []*GROUP_AFFINITY`
			`coreCount int // performance cores = coreCount - efficiencyCoreCount`
			`efficiencyCoreCount int`
			`threadCount int`
			`}`

			`func (pkg winPackage) IsMember(target GROUP_AFFINITY) bool {`
			`for _, group := range pkg.groups {`
			`if group.IsMember(target) {`
			`return true`
			`}`
			`}`
			`return false`
			`}`

			`func getLogicalProcessorInformationEx() ([]byte, error) {`
			`buf := make([]byte, 1)`
			`bufSize := len(buf)`
			`ret, _, err := GetLogicalProcessorInformationEx.Call(`
			`uintptr(RelationAll),`
			`uintptr(unsafe.Pointer(&buf[0])),`
			`uintptr(unsafe.Pointer(&bufSize)),`
			`)`
			`if ret != 0 {`
			`return nil, fmt.Errorf("failed to determine size info ret:%d %w", ret, err)`
			`}`

			`buf = make([]byte, bufSize)`
			`ret, _, err = GetLogicalProcessorInformationEx.Call(`
			`uintptr(RelationAll),`
			`uintptr(unsafe.Pointer(&buf[0])),`
			`uintptr(unsafe.Pointer(&bufSize)),`
			`)`
			`if ret == 0 {`
			`return nil, fmt.Errorf("failed to gather processor information ret:%d buflen:%d %w", ret, bufSize, err)`
			`}`
			`return buf, nil`
			`}`

			`func processSystemLogicalProcessorInforationList(buf []byte) []*winPackage {`
			`var slpi *SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX`
			`// Find all the packages first`
			`packages := []*winPackage{}`
			`for bufOffset := 0; bufOffset < len(buf); bufOffset += int(slpi.Size) {`
			`slpi = (*SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX)(unsafe.Pointer(&buf[bufOffset]))`
			`if slpi.Relationship != RelationProcessorPackage {`
			`continue`
			`}`
			`pr := (*PROCESSOR_RELATIONSHIP)(unsafe.Pointer(&slpi.U[0]))`
			`pkg := &winPackage{}`
			`ga0 := unsafe.Pointer(&pr.GroupMask[0])`
			`for j := range pr.GroupCount {`
			`gm := (GROUP_AFFINITY)(unsafe.Pointer(uintptr(ga0) + uintptr(j)unsafe.Sizeof(GROUP_AFFINITY{})))`
			`pkg.groups = append(pkg.groups, gm)`
			`}`
			`packages = append(packages, pkg)`
			`}`

			`slog.Info("packages", "count", len(packages))`

			`// To identify efficiency cores we have to compare the relative values`
			`// Larger values are "less efficient" (aka, more performant)`
			`var maxEfficiencyClass byte`
			`for bufOffset := 0; bufOffset < len(buf); bufOffset += int(slpi.Size) {`
			`slpi = (*SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX)(unsafe.Pointer(&buf[bufOffset]))`
			`if slpi.Relationship != RelationProcessorCore {`
			`continue`
			`}`
			`pr := (*PROCESSOR_RELATIONSHIP)(unsafe.Pointer(&slpi.U[0]))`
			`if pr.EfficiencyClass > maxEfficiencyClass {`
			`maxEfficiencyClass = pr.EfficiencyClass`
			`}`
			`}`
			`if maxEfficiencyClass > 0 {`
			`slog.Info("efficiency cores detected", "maxEfficiencyClass", maxEfficiencyClass)`
			`}`

			`// then match up the Cores to the Packages, count up cores, threads and efficiency cores`
			`for bufOffset := 0; bufOffset < len(buf); bufOffset += int(slpi.Size) {`
			`slpi = (*SYSTEM_LOGICAL_PROCESSOR_INFORMATION_EX)(unsafe.Pointer(&buf[bufOffset]))`
			`if slpi.Relationship != RelationProcessorCore {`
			`continue`
			`}`
			`pr := (*PROCESSOR_RELATIONSHIP)(unsafe.Pointer(&slpi.U[0]))`
			`ga0 := unsafe.Pointer(&pr.GroupMask[0])`
			`for j := range pr.GroupCount {`
			`gm := (GROUP_AFFINITY)(unsafe.Pointer(uintptr(ga0) + uintptr(j)unsafe.Sizeof(GROUP_AFFINITY{})))`
			`for _, pkg := range packages {`
			`if pkg.IsMember(gm) {`
			`pkg.coreCount++`
			`if pr.Flags == 0 {`
			`pkg.threadCount++`
			`} else {`
			`pkg.threadCount += 2`
			`}`
			`if pr.EfficiencyClass < maxEfficiencyClass {`
			`pkg.efficiencyCoreCount++`
			`}`
			`}`
			`}`
			`}`
			`}`

			`// Sumarize the results`
			`for i, pkg := range packages {`
			`slog.Info("", "package", i, "cores", pkg.coreCount, "efficiency", pkg.efficiencyCoreCount, "threads", pkg.threadCount)`
			`}`

			`return packages`
			`}`

			`func GetCPUDetails() ([]CPU, error) {`
			`buf, err := getLogicalProcessorInformationEx()`
			`if err != nil {`
			`return nil, err`
			`}`
			`packages := processSystemLogicalProcessorInforationList(buf)`
			`cpus := make([]CPU, len(packages))`

			`for i, pkg := range packages {`
			`cpus[i].CoreCount = pkg.coreCount`
			`cpus[i].EfficiencyCoreCount = pkg.efficiencyCoreCount`
			`cpus[i].ThreadCount = pkg.threadCount`
			`}`
			`return cpus, nil`
			`}`