graphvent/graph.go

453 lines
11 KiB
Go

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package graphvent
import (
"sync"
"reflect"
"github.com/google/uuid"
"os"
"github.com/rs/zerolog"
"fmt"
badger "github.com/dgraph-io/badger/v3"
"encoding/json"
)
type GraphContext struct {
DB * badger.DB
Log Logger
}
func NewGraphContext(db * badger.DB, log Logger) * GraphContext {
return &GraphContext{DB: db, Log: log}
}
// A Logger is passed around to record events happening to components enabled by SetComponents
type Logger interface {
SetComponents(components []string) error
// Log a formatted string
Logf(component string, format string, items ... interface{})
// Log a map of attributes and a format string
Logm(component string, fields map[string]interface{}, format string, items ... interface{})
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// Log a structure to a file by marshalling and unmarshalling the json
Logj(component string, s interface{}, format string, items ... interface{})
}
func NewConsoleLogger(components []string) *ConsoleLogger {
logger := &ConsoleLogger{
loggers: map[string]zerolog.Logger{},
components: []string{},
}
logger.SetComponents(components)
return logger
}
// A ConsoleLogger logs to stdout
type ConsoleLogger struct {
loggers map[string]zerolog.Logger
components_lock sync.Mutex
components []string
}
func (logger * ConsoleLogger) SetComponents(components []string) error {
logger.components_lock.Lock()
defer logger.components_lock.Unlock()
component_enabled := func (component string) bool {
for _, c := range(components) {
if c == component {
return true
}
}
return false
}
for c, _ := range(logger.loggers) {
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if component_enabled(c) == false {
delete(logger.loggers, c)
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}
}
for _, c := range(components) {
_, exists := logger.loggers[c]
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if component_enabled(c) == true && exists == false {
logger.loggers[c] = zerolog.New(os.Stdout).With().Timestamp().Str("component", c).Logger()
}
}
return nil
}
func (logger * ConsoleLogger) Logm(component string, fields map[string]interface{}, format string, items ... interface{}) {
l, exists := logger.loggers[component]
if exists == true {
log := l.Log()
for key, value := range(fields) {
log = log.Str(key, fmt.Sprintf("%+v", value))
}
log.Msg(fmt.Sprintf(format, items...))
}
}
func (logger * ConsoleLogger) Logf(component string, format string, items ... interface{}) {
l, exists := logger.loggers[component]
if exists == true {
l.Log().Msg(fmt.Sprintf(format, items...))
}
}
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func (logger * ConsoleLogger) Logj(component string, s interface{}, format string, items ... interface{}) {
m := map[string]interface{}{}
ser, err := json.Marshal(s)
if err != nil {
panic("LOG_MARSHAL_ERR")
}
err = json.Unmarshal(ser, &m)
if err != nil {
panic("LOG_UNMARSHAL_ERR")
}
logger.Logm(component, m, format, items...)
}
type NodeID string
// Generate a random id
func RandID() NodeID {
uuid_str := uuid.New().String()
return NodeID(uuid_str)
}
type SignalDirection int
const (
Up SignalDirection = iota
Down
Direct
)
// GraphSignals are passed around the event tree/resource DAG and cast by Type()
type GraphSignal interface {
// How to propogate the signal
Direction() SignalDirection
Source() NodeID
Type() string
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String() string
}
// BaseSignal is the most basic type of signal, it has no additional data
type BaseSignal struct {
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FDirection SignalDirection `json:"direction"`
FSource NodeID `json:"source"`
FType string `json:"type"`
}
func (state BaseSignal) String() string {
ser, err := json.Marshal(state)
if err != nil {
return "STATE_SER_ERR"
}
return string(ser)
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}
func (signal BaseSignal) Direction() SignalDirection {
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return signal.FDirection
}
func (signal BaseSignal) Source() NodeID {
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return signal.FSource
}
func (signal BaseSignal) Type() string {
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return signal.FType
}
func NewBaseSignal(source GraphNode, _type string, direction SignalDirection) BaseSignal {
var source_id NodeID = ""
if source != nil {
source_id = source.ID()
}
signal := BaseSignal{
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FDirection: direction,
FSource: source_id,
FType: _type,
}
return signal
}
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func NewDownSignal(source GraphNode, _type string) BaseSignal {
return NewBaseSignal(source, _type, Down)
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}
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func NewSignal(source GraphNode, _type string) BaseSignal {
return NewBaseSignal(source, _type, Up)
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}
func NewDirectSignal(source GraphNode, _type string) BaseSignal {
return NewBaseSignal(source, _type, Direct)
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}
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func AbortSignal(source GraphNode) BaseSignal {
return NewBaseSignal(source, "abort", Down)
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}
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func CancelSignal(source GraphNode) BaseSignal {
return NewBaseSignal(source, "cancel", Down)
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}
type NodeState interface {
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Name() string
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}
// GraphNode is the interface common to both DAG nodes and Event tree nodes
// They have a NodeState interface which is saved to the database every update
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type GraphNode interface {
ID() NodeID
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State() NodeState
StateLock() *sync.RWMutex
SetState(new_state NodeState)
// Signal propagation function for listener channels
UpdateListeners(ctx * GraphContext, update GraphSignal)
// Signal propagation function for connected nodes(defined in state)
PropagateUpdate(ctx * GraphContext, update GraphSignal)
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// Get an update channel for the node to be notified of signals
UpdateChannel(buffer int) chan GraphSignal
// Register and unregister a channel to propogate updates to
RegisterChannel(listener chan GraphSignal)
UnregisterChannel(listener chan GraphSignal)
// Get a handle to the nodes internal signal channel
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SignalChannel() chan GraphSignal
}
// Create a new base node with a new ID
func NewNode(ctx * GraphContext, state NodeState) (BaseNode, error) {
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node := BaseNode{
id: RandID(),
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signal: make(chan GraphSignal, 512),
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listeners: map[chan GraphSignal]chan GraphSignal{},
state: state,
}
err := WriteDBState(ctx, node.id, state)
if err != nil {
return node, fmt.Errorf("DB_NEW_WRITE_ERROR: %e", err)
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}
ctx.Log.Logf("graph", "NEW_NODE: %s - %+v", node.id, state)
return node, nil
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}
// BaseNode is the minimum set of fields needed to implement a GraphNode,
// and provides a template for more complicated Nodes
type BaseNode struct {
id NodeID
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state NodeState
state_lock sync.RWMutex
signal chan GraphSignal
listeners_lock sync.Mutex
listeners map[chan GraphSignal]chan GraphSignal
}
func (node * BaseNode) ID() NodeID {
return node.id
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}
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func (node * BaseNode) State() NodeState {
return node.state
}
func (node * BaseNode) StateLock() * sync.RWMutex {
return &node.state_lock
}
func WriteDBState(ctx * GraphContext, id NodeID, state NodeState) error {
ctx.Log.Logf("db", "DB_WRITE: %s - %+v", id, state)
var serialized_state []byte = nil
if state != nil {
ser, err := json.Marshal(state)
if err != nil {
return fmt.Errorf("DB_MARSHAL_ERROR: %e", err)
}
serialized_state = ser
} else {
serialized_state = []byte{}
}
err := ctx.DB.Update(func(txn *badger.Txn) error {
err := txn.Set([]byte(id), serialized_state)
return err
})
return err
}
func (node * BaseNode) SetState(new_state NodeState) {
node.state = new_state
}
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func checkForDuplicate(nodes []GraphNode) error {
found := map[NodeID]bool{}
for _, node := range(nodes) {
if node == nil {
return fmt.Errorf("Cannot get state of nil node")
}
_, exists := found[node.ID()]
if exists == true {
return fmt.Errorf("Attempted to get state of %s twice", node.ID())
}
found[node.ID()] = true
}
return nil
}
func UseStates(ctx * GraphContext, nodes []GraphNode, states_fn func(states []NodeState)(interface{}, error)) (interface{}, error) {
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err := checkForDuplicate(nodes)
if err != nil {
return nil, err
}
for _, node := range(nodes) {
node.StateLock().RLock()
}
states := make([]NodeState, len(nodes))
for i, node := range(nodes) {
states[i] = node.State()
}
val, err := states_fn(states)
for _, node := range(nodes) {
node.StateLock().RUnlock()
}
return val, err
}
func UpdateStates(ctx * GraphContext, nodes []GraphNode, states_fn func(states []NodeState)([]NodeState, interface{}, error)) (interface{}, error) {
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err := checkForDuplicate(nodes)
if err != nil {
return nil, err
}
for _, node := range(nodes) {
node.StateLock().Lock()
}
states := make([]NodeState, len(nodes))
for i, node := range(nodes) {
states[i] = node.State()
}
new_states, val, err := states_fn(states)
if new_states != nil {
if len(new_states) != len(nodes) {
panic(fmt.Sprintf("NODE_NEW_STATE_LEN_MISMATCH: %d/%d", len(new_states), len(nodes)))
}
for i, new_state := range(new_states) {
if new_state != nil {
old_state_type := reflect.TypeOf(states[i])
new_state_type := reflect.TypeOf(new_state)
if old_state_type != new_state_type {
panic(fmt.Sprintf("NODE_STATE_MISMATCH: old - %+v, new - %+v", old_state_type, new_state_type))
}
err := WriteDBState(ctx, nodes[i].ID(), new_state)
if err != nil {
panic(fmt.Sprintf("DB_WRITE_ERROR: %s", err))
}
nodes[i].SetState(new_state)
}
}
}
for _, node := range(nodes) {
node.StateLock().Unlock()
}
return val, err
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}
func (node * BaseNode) UpdateListeners(ctx * GraphContext, update GraphSignal) {
node.listeners_lock.Lock()
defer node.listeners_lock.Unlock()
closed := []chan GraphSignal{}
for _, listener := range node.listeners {
ctx.Log.Logf("listeners", "UPDATE_LISTENER %s: %p", node.ID(), listener)
select {
case listener <- update:
default:
ctx.Log.Logf("listeners", "CLOSED_LISTENER %s: %p", node.ID(), listener)
go func(node GraphNode, listener chan GraphSignal) {
listener <- NewSignal(node, "listener_closed")
close(listener)
}(node, listener)
closed = append(closed, listener)
}
}
for _, listener := range(closed) {
delete(node.listeners, listener)
}
}
func (node * BaseNode) PropagateUpdate(ctx * GraphContext, update GraphSignal) {
}
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func (node * BaseNode) RegisterChannel(listener chan GraphSignal) {
node.listeners_lock.Lock()
_, exists := node.listeners[listener]
if exists == false {
node.listeners[listener] = listener
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}
node.listeners_lock.Unlock()
}
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func (node * BaseNode) UnregisterChannel(listener chan GraphSignal) {
node.listeners_lock.Lock()
_, exists := node.listeners[listener]
if exists == false {
panic("Attempting to unregister non-registered listener")
} else {
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delete(node.listeners, listener)
}
node.listeners_lock.Unlock()
}
func (node * BaseNode) SignalChannel() chan GraphSignal {
return node.signal
}
// Create a new GraphSinal channel with a buffer of size buffer and register it to a node
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func (node * BaseNode) UpdateChannel(buffer int) chan GraphSignal {
new_listener := make(chan GraphSignal, buffer)
node.RegisterChannel(new_listener)
return new_listener
}
// Propogate a signal starting at a node
func SendUpdate(ctx * GraphContext, node GraphNode, signal GraphSignal) {
if node == nil {
panic("Cannot start an update from no node")
}
ctx.Log.Logf("update", "UPDATE %s <- %s: %+v", node.ID(), signal.Source(), signal)
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node.UpdateListeners(ctx, signal)
node.PropagateUpdate(ctx, signal)
}