docs/spec/abci: improve docs on AppHash (#2363)

6 years ago · 503de8c9b8
--- a/docs/spec/abci/abci.md
+++ b/docs/spec/abci/abci.md
@ -175,7 +175,8 @@ Commit are included in the header of the next block.
  - `Index (int64)`: The index of the key in the tree.
  - `Key ([]byte)`: The key of the matching data.
  - `Value ([]byte)`: The value of the matching data.
  - `Proof ([]byte)`: Proof for the data, if requested.
  - `Proof ([]byte)`: Serialized proof for the data, if requested, to be
    verified against the `AppHash` for the given Height.
  - `Height (int64)`: The block height from which data was derived.
    Note that this is the height of the block containing the
    application's Merkle root hash, which represents the state as it
@ -275,13 +276,18 @@ Commit are included in the header of the next block.
 ### Commit

 - **Response**:
  - `Data ([]byte)`: The Merkle root hash
  - `Data ([]byte)`: The Merkle root hash of the application state
 - **Usage**:
  - Persist the application state.
  - Return a Merkle root hash of the application state.
  - It's critical that all application instances return the
    same hash. If not, they will not be able to agree on the next
    block, because the hash is included in the next block!
  - Return an (optional) Merkle root hash of the application state
  - `ResponseCommit.Data` is included as the `Header.AppHash` in the next block
    - it may be empty
  - Later calls to `Query` can return proofs about the application state anchored
    in this Merkle root hash
  - Note developers can return whatever they want here (could be nothing, or a
    constant string, etc.), so long as it is deterministic - it must not be a
    function of anything that did not come from the
    BeginBlock/DeliverTx/EndBlock methods.

 ## Data Types

--- a/docs/spec/abci/apps.md
+++ b/docs/spec/abci/apps.md
@ -4,19 +4,20 @@ Please ensure you've first read the spec for [ABCI Methods and Types](abci.md)

 Here we cover the following components of ABCI applications:

 - [State](#state) - the interplay between ABCI connections and application state
 - [Connection State](#state) - the interplay between ABCI connections and application state
  and the differences between `CheckTx` and `DeliverTx`.
 - [Transaction Results](#transaction-results) - rules around transaction
  results and validity
 - [Validator Set Updates](#validator-updates) - how validator sets are
  changed during `InitChain` and `EndBlock`
 - [Query](#query) - standards for using the `Query` method
 - [Query](#query) - standards for using the `Query` method and proofs about the
  application state
 - [Crash Recovery](#crash-recovery) - handshake protocol to synchronize
  Tendermint and the application on startup.

 ## State

 Since Tendermint maintains multiple concurrent ABCI connections, it is typical
 Since Tendermint maintains three concurrent ABCI connections, it is typical
 for an application to maintain a distinct state for each, and for the states to
 be synchronized during `Commit`.

@ -96,7 +97,7 @@ though see issues
 [#1861](https://github.com/tendermint/tendermint/issues/1861),
 [#2299](https://github.com/tendermint/tendermint/issues/2299) and
 [#2310](https://github.com/tendermint/tendermint/issues/2310) for how this may
 change.
 soon change.

 ### CheckTx

@ -180,11 +181,46 @@ Note the updates returned in block `H` will only take effect at block `H+2`.

 ## Query

 Query is a generic message type with lots of flexibility to enable diverse sets
 of queries from applications. Tendermint has no requirements from the Query
 message for normal operation - that is, the ABCI app developer need not implement Query functionality if they do not wish too.
 That said, Tendermint makes a number of queries to support some optional
 features. These are:
 Query is a generic method with lots of flexibility to enable diverse sets
 of queries on application state. Tendermint makes use of Query to filter new peers
 based on ID and IP, and exposes Query to the user over RPC.
 Note that calls to Query are not replicated across nodes, but rather query the
 local node's state - hence they may provide stale reads. For reads that require
 consensus, a transaction is required.

 The most important use of Query is to return Merkle proofs of the application state at some height
 that can be used for efficient application-specific lite-clients.

 Note Tendermint has technically no requirements from the Query
 message for normal operation - that is, the ABCI app developer need not implement
 Query functionality if they do not wish too.

 ### Query Proofs

 The Tendermint block header includes a number of hashes, each providing an
 anchor for some type of proof about the blockchain. The `ValidatorsHash` enables
 quick verification of the validator set, the `DataHash` gives quick
 verification of the transactions included in the block, etc.

 The `AppHash` is unique in that it is application specific, and allows for
 application-specific Merkle proofs about the state of the application.
 While some applications keep all relevant state in the transactions themselves
 (like Bitcoin and its UTXOs), others maintain a separated state that is
 computed deterministically *from* transactions, but is not contained directly in
 the transactions themselves (like Ethereum contracts and accounts).
 For such applications, the `AppHash` provides a much more efficient way to verify lite-client proofs.

 ABCI applications can take advantage of more efficient lite-client proofs for
 their state as follows:

 - return the Merkle root of the deterministic application state in
 `ResponseCommit.Data`.
 - it will be included as the `AppHash` in the next block.
 - return efficient Merkle proofs about that application state in `ResponseQuery.Proof`
  that can be verified using the `AppHash` of the corresponding block.

 For instance, this allows an application's lite-client to verify proofs of
 absence in the application state, something which is much less efficient to do using the block hash.

 ### Peer Filtering