rcmgr

package
v0.2.0-fix-4 Latest Latest
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Published: May 19, 2023 License: GPL-3.0 Imports: 10 Imported by: 0

Documentation

Index

Constants

View Source
const (
	LimitFactor              = 0.85
	DefaultMemorySize uint64 = 8 * 1024 * 1024
)
View Source
const (
	// ReservationPriorityLow is a reservation priority that indicates a reservation if the scope
	// memory utilization is at 40% or less.
	ReservationPriorityLow uint8 = 101
	// ReservationPriorityMedium is a reservation priority that indicates a reservation if the scope
	// memory utilization is at 60% or less.
	ReservationPriorityMedium uint8 = 152
	// ReservationPriorityHigh is a reservation priority that indicates a reservation if the scope
	// memory utilization is at 80% or less.
	ReservationPriorityHigh uint8 = 203
	// ReservationPriorityAlways is a reservation priority that indicates a reservation if there is
	// enough memory, regardless of scope utilization.
	ReservationPriorityAlways uint8 = 255
)

Variables

View Source
var DefaultLimitConfig = &LimitConfig{
	SystemLimit: &InfiniteBaseLimit,
	Service:     make(map[string]*BaseLimit),
}
View Source
var ErrResourceLimitExceeded = errors.New("resource limit exceeded")

ErrResourceLimitExceeded is returned when attempting to perform an operation that would exceed system resource limits.

View Source
var ErrResourceScopeClosed = errors.New("resource scope closed")

ErrResourceScopeClosed is returned when attempting to reserve resources in a closed resource scope.

View Source
var InfiniteBaseLimit = BaseLimit{
	Conns:         math.MaxInt,
	ConnsInbound:  math.MaxInt,
	ConnsOutbound: math.MaxInt,
	FD:            math.MaxInt,
	Memory:        math.MaxInt64,
}

InfiniteBaseLimit are a limiter configuration that uses unlimited limits, thus effectively not limiting anything. Keep in mind that the operating system limits the number of file descriptors that an application can use.

Functions

func GetServiceState added in v0.1.1

func GetServiceState(name string) string

func GetSystemState added in v0.1.1

func GetSystemState() string

Types

type BaseLimit

type BaseLimit struct {
	Conns         int   `json:",omitempty"`
	ConnsInbound  int   `json:",omitempty"`
	ConnsOutbound int   `json:",omitempty"`
	FD            int   `json:",omitempty"`
	Memory        int64 `json:",omitempty"`
}

BaseLimit is a mixin type for basic resource limits.

func (*BaseLimit) GetConnLimit

func (limit *BaseLimit) GetConnLimit(direction Direction) int

GetConnLimit returns the connection limit, for inbound or outbound connections.

func (*BaseLimit) GetConnTotalLimit

func (limit *BaseLimit) GetConnTotalLimit() int

GetConnTotalLimit returns the total connection limit

func (*BaseLimit) GetFDLimit

func (limit *BaseLimit) GetFDLimit() int

GetFDLimit returns the file descriptor limit.

func (*BaseLimit) GetMemoryLimit

func (limit *BaseLimit) GetMemoryLimit() int64

GetMemoryLimit returns the (current) memory limit.

func (*BaseLimit) String

func (limit *BaseLimit) String() string

String returns the Limit state string TODO:: supports connection and fd field

type Direction

type Direction int

Direction represents which peer in a stream initiated a connection.

const (
	// DirUnknown is the default direction.
	DirUnknown Direction = iota
	// DirInbound is for when the remote peer initiated a connection.
	DirInbound
	// DirOutbound is for when the local peer initiated a connection.
	DirOutbound
)

type ErrConnLimitExceeded

type ErrConnLimitExceeded struct {
	// contains filtered or unexported fields
}

func (*ErrConnLimitExceeded) Error

func (e *ErrConnLimitExceeded) Error() string

func (*ErrConnLimitExceeded) Unwrap

func (e *ErrConnLimitExceeded) Unwrap() error

type ErrMemoryLimitExceeded

type ErrMemoryLimitExceeded struct {
	// contains filtered or unexported fields
}

func (*ErrMemoryLimitExceeded) Error

func (e *ErrMemoryLimitExceeded) Error() string

func (*ErrMemoryLimitExceeded) Unwrap

func (e *ErrMemoryLimitExceeded) Unwrap() error

type Limit

type Limit interface {
	// GetMemoryLimit returns the (current) memory limit.
	GetMemoryLimit() int64
	// GetConnLimit returns the connection limit, for inbound or outbound connections.
	GetConnLimit(Direction) int
	// GetConnTotalLimit returns the total connection limit
	GetConnTotalLimit() int
	// GetFDLimit returns the file descriptor limit.
	GetFDLimit() int
	// String returns the Limit state string
	String() string
}

Limit is an interface that that specifies basic resource limits.

type LimitConfig

type LimitConfig struct {
	SystemLimit *BaseLimit
	Service     map[string]*BaseLimit
}

func NewLimitConfigFromToml

func NewLimitConfigFromToml(file string) (*LimitConfig, error)

func (*LimitConfig) GetServiceLimits

func (cfg *LimitConfig) GetServiceLimits(svc string) Limit

func (*LimitConfig) GetSystemLimits

func (cfg *LimitConfig) GetSystemLimits() Limit

func (*LimitConfig) GetTransientLimits

func (cfg *LimitConfig) GetTransientLimits() Limit

func (*LimitConfig) String

func (cfg *LimitConfig) String() string

type Limiter

type Limiter interface {
	GetSystemLimits() Limit
	GetTransientLimits() Limit
	GetServiceLimits(svc string) Limit
	String() string
}

Limiter is an interface for providing limits to the resource manager.

type NullResourceManager

type NullResourceManager struct{}

NullResourceManager is a stub for tests and initialization of default values

func (*NullResourceManager) Close

func (n *NullResourceManager) Close() error

func (*NullResourceManager) OpenService

func (n *NullResourceManager) OpenService(svc string) (ResourceScope, error)

func (*NullResourceManager) ViewService

func (n *NullResourceManager) ViewService(svc string, f func(ResourceScope) error) error

func (*NullResourceManager) ViewSystem

func (n *NullResourceManager) ViewSystem(f func(ResourceScope) error) error

func (*NullResourceManager) ViewTransient

func (n *NullResourceManager) ViewTransient(f func(ResourceScope) error) error

type NullScope

type NullScope struct{}

NullScope is a stub for tests and initialization of default values

func (*NullScope) BeginSpan

func (n *NullScope) BeginSpan() (ResourceScopeSpan, error)

func (*NullScope) Done

func (n *NullScope) Done()

func (*NullScope) Name

func (n *NullScope) Name() string

func (*NullScope) Release

func (n *NullScope) Release()

func (*NullScope) ReleaseMemory

func (n *NullScope) ReleaseMemory(size int)

func (*NullScope) ReserveMemory

func (n *NullScope) ReserveMemory(size int, prio uint8) error

func (*NullScope) Stat

func (n *NullScope) Stat() ScopeStat

type ResourceManager

type ResourceManager interface {
	ResourceScopeViewer
	// OpenService creates a new Service scope associated with System/Transient Scope
	// The caller owns the returned scope and is responsible for calling Done in order
	// to signify the end of the scope's span.
	OpenService(svc string) (ResourceScope, error)
	// Close closes the resource manager
	Close() error
}

ResourceManager is the interface to the resource management subsystem. The ResourceManager tracks and accounts for resource usage in the stack, from the internals to the application, and provides a mechanism to limit resource usage according to a user configurable policy.

Resource Management through the ResourceManager is based on the concept of Resource Management Scopes, whereby resource usage is constrained by a DAG of scopes, The following diagram illustrates the structure of the resource constraint DAG: System

+------------> Transient............+................+
|                                   .                .
+------------> Service------------- . ----------+    .
|                                   .           |    .
		   	   +--->  Connection--- . ----------+    .

The basic resources accounted by the ResourceManager include memory, connections, and file descriptors. These account for both space and time used by the stack, as each resource has a direct effect on the system availability and performance.

The modus operandi of the resource manager is to restrict resource usage at the time of reservation. When a component of the stack needs to use a resource, it reserves it in the appropriate scope. The resource manager gates the reservation against the scope applicable limits; if the limit is exceeded, then an error is up the component to act accordingly. At the lower levels of the stack, this will normally signal a failure of some sorts, like failing to opening a connection, which will propagate to the programmer. Some components may be able to handle resource reservation failure more gracefully. All resources reserved in some scopes are released when the scope is closed. For low level scopes, mainly Service and Connection scopes, this happens when the service or connection is closed.

Service programmers will typically use the resource manager to reserve memory for their subsystem. This happens with two avenues: the programmer can attach a connection to a service, whereby resources reserved by the connection are automatically accounted in the service budget; or the programmer may directly interact with the service scope, by using ViewService through the resource manager interface.

Application programmers can also directly reserve memory in some applicable scope. In order to facilitate control flow delimited resource accounting, all scopes defined in the system allow for the user to create spans. Spans are temporary scopes rooted at some other scope and release their resources when the programmer is done with them. Span scopes can form trees, with nested spans.

Typical Usage:

  • Low level components of the system all have access to the resource manager and create connection scopes through it. These scopes are accessible to the user, albeit with a narrower interface, through Conn objects who have a Scope method.
  • Services typically center around connections, where the programmer can attach connections to a particular service. They can also directly reserve memory for a service by accessing the service scope using the ResourceManager interface.
  • Applications that want to account for their resource usage can reserve memory, typically using a span, directly in the System or a Service scope.

func NewResourceManager

func NewResourceManager(limits Limiter) (ResourceManager, error)

NewResourceManager inits and returns singleton instance of ResourceManager

func ResrcManager

func ResrcManager() ResourceManager

ResrcManager return the global singleton instance of ResourceManager

type ResourceScope

type ResourceScope interface {
	// ReserveMemory reserves memory/buffer space in the scope; the unit is bytes.
	//
	// If ReserveMemory returns an error, then no memory was reserved and the caller
	// should handle the failure condition.
	//
	// The priority argument indicates the priority of the memory reservation. A reservation
	// will fail if the available memory is less than (1+prio)/256 of the scope limit, providing
	// a mechanism to gracefully handle optional reservations that might overload the system.
	//
	// There are 4 predefined priority levels, Low, Medium, High and Always, capturing common
	// patterns, but the user is free to use any granularity applicable to his case.
	ReserveMemory(size int, prio uint8) error
	// ReleaseMemory explicitly releases memory previously reserved with ReserveMemory
	ReleaseMemory(size int)
	// Stat retrieves current resource usage for the scope.
	Stat() ScopeStat
	// Name returns the name of this scope
	Name() string
	// BeginSpan creates a new span scope rooted at this scope
	BeginSpan() (ResourceScopeSpan, error)
	// Release resource at this scope
	Release()
}

ResourceScope is the interface for all scopes.

type ResourceScopeSpan

type ResourceScopeSpan interface {
	ResourceScope
	// Done ends the span and releases associated resources.
	Done()
}

ResourceScopeSpan is a ResourceScope with a delimited span. Span scopes are control flow delimited and release all their associated resources when the programmer calls Done.

Example:

s, err := someScope.BeginSpan()
if err != nil { ... }
defer s.Done()

if err := s.ReserveMemory(...); err != nil { ... }
// ... use memory

type ResourceScopeViewer

type ResourceScopeViewer interface {
	// ViewSystem views the system wide resource scope.
	// The system scope is the top level scope that accounts for global
	// resource usage at all levels of the system. This scope constrains all
	// other scopes and institutes global hard limits.
	ViewSystem(func(ResourceScope) error) error
	// ViewTransient views the transient (DMZ) resource scope.
	// The transient scope accounts for resources that are in the process of
	// full establishment.  For instance, a new connection prior to the
	// handshake does not belong to any service, but it still needs to be
	// constrained as this opens an avenue for attacks in transient resource
	// usage.
	ViewTransient(func(ResourceScope) error) error
	// ViewService retrieves a service-specific scope.
	ViewService(string, func(ResourceScope) error) error
}

ResourceScopeViewer is a mixin interface providing view methods for accessing top level scopes

type ScopeStat

type ScopeStat struct {
	NumConnsInbound  int
	NumConnsOutbound int
	NumFD            int
	Memory           int64
}

ScopeStat is a struct containing resource accounting information.

func (ScopeStat) String

func (s ScopeStat) String() string

String returns the state string of ScopeStat TODO:: supports connections and fd field

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