Synopsis The context is a data structure intended to be passed from function to function that carries information about the current state of the application. It provides access to a branched storage (a safe branch of the entire state) as well as useful objects and information like gasMeter, block height, consensus parameters and more.

Pre-requisites Readings

Context Definition

The Cosmos SDK Context is a custom data structure that contains Go’s stdlib context as its base, and has many additional types within its definition that are specific to the Cosmos SDK. The Context is integral to transaction processing in that it allows modules to easily access their respective store in the multistore and retrieve transactional context such as the block header and gas meter. 
package types

import (
    
	"context"
    "time"
    "github.com/cosmos/gogoproto/proto"
	abci "github.com/tendermint/tendermint/abci/types"
	tmbytes "github.com/tendermint/tendermint/libs/bytes"
    "github.com/tendermint/tendermint/libs/log"
	tmproto "github.com/tendermint/tendermint/proto/tendermint/types"
    "github.com/cosmos/cosmos-sdk/store/gaskv"
	storetypes "github.com/cosmos/cosmos-sdk/store/types"
)

/*
Context is an immutable object contains all information needed to
process a request.

It contains a context.Context object inside if you want to use that,
but please do not over-use it. We try to keep all data structured
and standard additions here would be better just to add to the Context struct
*/
type Context struct {
    baseCtx              context.Context
	ms                   MultiStore
	header               tmproto.Header
	headerHash           tmbytes.HexBytes
	chainID              string
	txBytes              []byte
	logger               log.Logger
	voteInfo             []abci.VoteInfo
	gasMeter             GasMeter
	blockGasMeter        GasMeter
	checkTx              bool
	recheckTx            bool // if recheckTx == true, then checkTx must also be true
	minGasPrice          DecCoins
	consParams           *tmproto.ConsensusParams
	eventManager         *EventManager
	priority             int64 // The tx priority, only relevant in CheckTx
	kvGasConfig          storetypes.GasConfig
	transientKVGasConfig storetypes.GasConfig
}

// Proposed rename, not done to avoid API breakage
type Request = Context

// Read-only accessors
func (c Context)

Context()

context.Context                   {
    return c.baseCtx
}

func (c Context)

MultiStore()

MultiStore                     {
    return c.ms
}

func (c Context)

BlockHeight()

int64                         {
    return c.header.Height
}

func (c Context)

BlockTime()

time.Time                       {
    return c.header.Time
}

func (c Context)

ChainID()

string                            {
    return c.chainID
}

func (c Context)

TxBytes() []byte                            {
    return c.txBytes
}

func (c Context)

Logger()

log.Logger                         {
    return c.logger
}

func (c Context)

VoteInfos() []abci.VoteInfo                 {
    return c.voteInfo
}

func (c Context)

GasMeter()

GasMeter                         {
    return c.gasMeter
}

func (c Context)

BlockGasMeter()

GasMeter                    {
    return c.blockGasMeter
}

func (c Context)

IsCheckTx()

bool                            {
    return c.checkTx
}

func (c Context)

IsReCheckTx()

bool                          {
    return c.recheckTx
}

func (c Context)

MinGasPrices()

DecCoins                     {
    return c.minGasPrice
}

func (c Context)

EventManager() *EventManager                {
    return c.eventManager
}

func (c Context)

Priority()

int64                            {
    return c.priority
}

func (c Context)

KVGasConfig()

storetypes.GasConfig          {
    return c.kvGasConfig
}

func (c Context)

TransientKVGasConfig()

storetypes.GasConfig {
    return c.transientKVGasConfig
}

// clone the header before returning
func (c Context)

BlockHeader()

tmproto.Header {
    msg := proto.Clone(&c.header).(*tmproto.Header)

return *msg
}

// HeaderHash returns a copy of the header hash obtained during abci.RequestBeginBlock
func (c Context)

HeaderHash()

tmbytes.HexBytes {
    hash := make([]byte, len(c.headerHash))

copy(hash, c.headerHash)

return hash
}

func (c Context)

ConsensusParams() *tmproto.ConsensusParams {
    return proto.Clone(c.consParams).(*tmproto.ConsensusParams)
}

func (c Context)

Deadline() (deadline time.Time, ok bool) {
    return c.baseCtx.Deadline()
}

func (c Context)

Done() <-chan struct{
} {
    return c.baseCtx.Done()
}

func (c Context)

Err()

error {
    return c.baseCtx.Err()
}

// create a new context
func NewContext(ms MultiStore, header tmproto.Header, isCheckTx bool, logger log.Logger)

Context {
	// https://github.com/gogo/protobuf/issues/519
	header.Time = header.Time.UTC()

return Context{
    baseCtx:              context.Background(),
		ms:                   ms,
		header:               header,
		chainID:              header.ChainID,
		checkTx:              isCheckTx,
		logger:               logger,
		gasMeter:             storetypes.NewInfiniteGasMeter(),
		minGasPrice:          DecCoins{
},
		eventManager:         NewEventManager(),
		kvGasConfig:          storetypes.KVGasConfig(),
		transientKVGasConfig: storetypes.TransientGasConfig(),
}
}

// WithContext returns a Context with an updated context.Context.
func (c Context)

WithContext(ctx context.Context)

Context {
    c.baseCtx = ctx
	return c
}

// WithMultiStore returns a Context with an updated MultiStore.
func (c Context)

WithMultiStore(ms MultiStore)

Context {
    c.ms = ms
	return c
}

// WithBlockHeader returns a Context with an updated tendermint block header in UTC time.
func (c Context)

WithBlockHeader(header tmproto.Header)

Context {
	// https://github.com/gogo/protobuf/issues/519
	header.Time = header.Time.UTC()

c.header = header
	return c
}

// WithHeaderHash returns a Context with an updated tendermint block header hash.
func (c Context)

WithHeaderHash(hash []byte)

Context {
    temp := make([]byte, len(hash))

copy(temp, hash)

c.headerHash = temp
	return c
}

// WithBlockTime returns a Context with an updated tendermint block header time in UTC time
func (c Context)

WithBlockTime(newTime time.Time)

Context {
    newHeader := c.BlockHeader()
	// https://github.com/gogo/protobuf/issues/519
	newHeader.Time = newTime.UTC()

return c.WithBlockHeader(newHeader)
}

// WithProposer returns a Context with an updated proposer consensus address.
func (c Context)

WithProposer(addr ConsAddress)

Context {
    newHeader := c.BlockHeader()

newHeader.ProposerAddress = addr.Bytes()

return c.WithBlockHeader(newHeader)
}

// WithBlockHeight returns a Context with an updated block height.
func (c Context)

WithBlockHeight(height int64)

Context {
    newHeader := c.BlockHeader()

newHeader.Height = height
	return c.WithBlockHeader(newHeader)
}

// WithChainID returns a Context with an updated chain identifier.
func (c Context)

WithChainID(chainID string)

Context {
    c.chainID = chainID
	return c
}

// WithTxBytes returns a Context with an updated txBytes.
func (c Context)

WithTxBytes(txBytes []byte)

Context {
    c.txBytes = txBytes
	return c
}

// WithLogger returns a Context with an updated logger.
func (c Context)

WithLogger(logger log.Logger)

Context {
    c.logger = logger
	return c
}

// WithVoteInfos returns a Context with an updated consensus VoteInfo.
func (c Context)

WithVoteInfos(voteInfo []abci.VoteInfo)

Context {
    c.voteInfo = voteInfo
	return c
}

// WithGasMeter returns a Context with an updated transaction GasMeter.
func (c Context)

WithGasMeter(meter GasMeter)

Context {
    c.gasMeter = meter
	return c
}

// WithBlockGasMeter returns a Context with an updated block GasMeter
func (c Context)

WithBlockGasMeter(meter GasMeter)

Context {
    c.blockGasMeter = meter
	return c
}

// WithKVGasConfig returns a Context with an updated gas configuration for
// the KVStore
func (c Context)

WithKVGasConfig(gasConfig storetypes.GasConfig)

Context {
    c.kvGasConfig = gasConfig
	return c
}

// WithTransientKVGasConfig returns a Context with an updated gas configuration for
// the transient KVStore
func (c Context)

WithTransientKVGasConfig(gasConfig storetypes.GasConfig)

Context {
    c.transientKVGasConfig = gasConfig
	return c
}

// WithIsCheckTx enables or disables CheckTx value for verifying transactions and returns an updated Context
func (c Context)

WithIsCheckTx(isCheckTx bool)

Context {
    c.checkTx = isCheckTx
	return c
}

// WithIsRecheckTx called with true will also set true on checkTx in order to
// enforce the invariant that if recheckTx = true then checkTx = true as well.
func (c Context)

WithIsReCheckTx(isRecheckTx bool)

Context {
    if isRecheckTx {
    c.checkTx = true
}

c.recheckTx = isRecheckTx
	return c
}

// WithMinGasPrices returns a Context with an updated minimum gas price value
func (c Context)

WithMinGasPrices(gasPrices DecCoins)

Context {
    c.minGasPrice = gasPrices
	return c
}

// WithConsensusParams returns a Context with an updated consensus params
func (c Context)

WithConsensusParams(params *tmproto.ConsensusParams)

Context {
    c.consParams = params
	return c
}

// WithEventManager returns a Context with an updated event manager
func (c Context)

WithEventManager(em *EventManager)

Context {
    c.eventManager = em
	return c
}

// WithPriority returns a Context with an updated tx priority
func (c Context)

WithPriority(p int64)

Context {
    c.priority = p
	return c
}

// TODO: remove???
func (c Context)

IsZero()

bool {
    return c.ms == nil
}

func (c Context)

WithValue(key, value interface{
})

Context {
    c.baseCtx = context.WithValue(c.baseCtx, key, value)

return c
}

func (c Context)

Value(key interface{
})

interface{
} {
    if key == SdkContextKey {
    return c
}

return c.baseCtx.Value(key)
}

// ----------------------------------------------------------------------------
// Store / Caching
// ----------------------------------------------------------------------------

// KVStore fetches a KVStore from the MultiStore.
func (c Context)

KVStore(key storetypes.StoreKey)

KVStore {
    return gaskv.NewStore(c.MultiStore().GetKVStore(key), c.GasMeter(), c.kvGasConfig)
}

// TransientStore fetches a TransientStore from the MultiStore.
func (c Context)

TransientStore(key storetypes.StoreKey)

KVStore {
    return gaskv.NewStore(c.MultiStore().GetKVStore(key), c.GasMeter(), c.transientKVGasConfig)
}

// CacheContext returns a new Context with the multi-store cached and a new
// EventManager. The cached context is written to the context when writeCache
// is called. Note, events are automatically emitted on the parent context's
// EventManager when the caller executes the write.
func (c Context)

CacheContext() (cc Context, writeCache func()) {
    cms := c.MultiStore().CacheMultiStore()

cc = c.WithMultiStore(cms).WithEventManager(NewEventManager())

writeCache = func() {
    c.EventManager().EmitEvents(cc.EventManager().Events())

cms.Write()
}

return cc, writeCache
}

var _ context.Context = Context{
}

// ContextKey defines a type alias for a stdlib Context key.
type ContextKey string

// SdkContextKey is the key in the context.Context which holds the sdk.Context.
const SdkContextKey ContextKey = "sdk-context"

// WrapSDKContext returns a stdlib context.Context with the provided sdk.Context's internal
// context as a value. It is useful for passing an sdk.Context  through methods that take a
// stdlib context.Context parameter such as generated gRPC methods. To get the original
// sdk.Context back, call UnwrapSDKContext.
func WrapSDKContext(ctx Context)

context.Context {
    return ctx
}

// UnwrapSDKContext retrieves a Context from a context.Context instance
// attached with WrapSDKContext. It panics if a Context was not properly
// attached
func UnwrapSDKContext(ctx context.Context)

Context {
    if sdkCtx, ok := ctx.(Context); ok {
    return sdkCtx
}

return ctx.Value(SdkContextKey).(Context)
}
  • Base Context: The base type is a Go Context, which is explained further in the Go Context Package section below.
  • Multistore: Every application’s BaseApp contains a CommitMultiStore which is provided when a Context is created. Calling the KVStore() and TransientStore() methods allows modules to fetch their respective KVStore using their unique StoreKey.
  • Header: The header is a Blockchain type. It carries important information about the state of the blockchain, such as block height and proposer of the current block.
  • Header Hash: The current block header hash, obtained during abci.RequestBeginBlock.
  • Chain ID: The unique identification number of the blockchain a block pertains to.
  • Transaction Bytes: The []byte representation of a transaction being processed using the context. Every transaction is processed by various parts of the Cosmos SDK and consensus engine (e.g. CometBFT) throughout its lifecycle, some of which do not have any understanding of transaction types. Thus, transactions are marshaled into the generic []byte type using some kind of encoding format such as Amino.
  • Logger: A logger from the CometBFT libraries. Learn more about logs here. Modules call this method to create their own unique module-specific logger.
  • VoteInfo: A list of the ABCI type VoteInfo, which includes the name of a validator and a boolean indicating whether they have signed the block.
  • Gas Meters: Specifically, a gasMeter for the transaction currently being processed using the context and a blockGasMeter for the entire block it belongs to. Users specify how much in fees they wish to pay for the execution of their transaction; these gas meters keep track of how much gas has been used in the transaction or block so far. If the gas meter runs out, execution halts.
  • CheckTx Mode: A boolean value indicating whether a transaction should be processed in CheckTx or DeliverTx mode.
  • Min Gas Price: The minimum gas price a node is willing to take in order to include a transaction in its block. This price is a local value configured by each node individually, and should therefore not be used in any functions used in sequences leading to state-transitions.
  • Consensus Params: The ABCI type Consensus Parameters, which specify certain limits for the blockchain, such as maximum gas for a block.
  • Event Manager: The event manager allows any caller with access to a Context to emit Events. Modules may define module specific Events by defining various Types and Attributes or use the common definitions found in types/. Clients can subscribe or query for these Events. These Events are collected throughout DeliverTx, BeginBlock, and EndBlock and are returned to CometBFT for indexing. For example:
  • Priority: The transaction priority, only relevant in CheckTx.
  • KV GasConfig: Enables applications to set a custom GasConfig for the KVStore.
  • Transient KV GasConfig: Enables applications to set a custom GasConfig for the transiant KVStore.

Go Context Package

A basic Context is defined in the Golang Context Package. A Context is an immutable data structure that carries request-scoped data across APIs and processes. Contexts are also designed to enable concurrency and to be used in goroutines. Contexts are intended to be immutable; they should never be edited. Instead, the convention is to create a child context from its parent using a With function. For example: 
childCtx = parentCtx.WithBlockHeader(header)
The Golang Context Package documentation instructs developers to explicitly pass a context ctx as the first argument of a process.

Store branching

The Context contains a MultiStore, which allows for branchinig and caching functionality using CacheMultiStore (queries in CacheMultiStore are cached to avoid future round trips). Each KVStore is branched in a safe and isolated ephemeral storage. Processes are free to write changes to the CacheMultiStore. If a state-transition sequence is performed without issue, the store branch can be committed to the underlying store at the end of the sequence or disregard them if something goes wrong. The pattern of usage for a Context is as follows:
  1. A process receives a Context ctx from its parent process, which provides information needed to perform the process.
  2. The ctx.ms is a branched store, i.e. a branch of the multistore is made so that the process can make changes to the state as it executes, without changing the originalctx.ms. This is useful to protect the underlying multistore in case the changes need to be reverted at some point in the execution.
  3. The process may read and write from ctx as it is executing. It may call a subprocess and pass ctx to it as needed.
  4. When a subprocess returns, it checks if the result is a success or failure. If a failure, nothing needs to be done - the branch ctx is simply discarded. If successful, the changes made to the CacheMultiStore can be committed to the original ctx.ms via Write().
For example, here is a snippet from the runTx function in baseapp: 
runMsgCtx, msCache := app.cacheTxContext(ctx, txBytes)

result = app.runMsgs(runMsgCtx, msgs, mode)

result.GasWanted = gasWanted
    if mode != runTxModeDeliver {
    return result
}
    if result.IsOK() {
    msCache.Write()
}
Here is the process:
  1. Prior to calling runMsgs on the message(s) in the transaction, it uses app.cacheTxContext() to branch and cache the context and multistore.
  2. runMsgCtx - the context with branched store, is used in runMsgs to return a result.
  3. If the process is running in checkTxMode, there is no need to write the changes - the result is returned immediately.
  4. If the process is running in deliverTxMode and the result indicates a successful run over all the messages, the branched multistore is written back to the original.