The example_test.py is a heavily commented example of a test case that uses both the RPC and P2P interfaces. If you are writing your first test, copy that file and modify to fit your needs.
Running test_runner.py
with the --coverage
argument tracks which RPCs are
called by the tests and prints a report of uncovered RPCs in the summary. This
can be used (along with the --extended
argument) to find out which RPCs we
don't have test cases for.
- Where possible, try to adhere to PEP-8 guidelines
- Use a python linter like flake8 before submitting PRs to catch common style nits (eg trailing whitespace, unused imports, etc)
- Avoid wildcard imports where possible
- Use a module-level docstring to describe what the test is testing, and how it is testing it.
- When subclassing the BitcoinTestFramwork, place overrides for the
__init__()
, andsetup_xxxx()
methods at the top of the subclass, then locally-defined helper methods, then therun_test()
method.
- Set
self.num_nodes
to the minimum number of nodes necessary for the test. Having additional unrequired nodes adds to the execution time of the test as well as memory/CPU/disk requirements (which is important when running tests in parallel or on Travis). - Avoid stop-starting the nodes multiple times during the test if possible. A stop-start takes several seconds, so doing it several times blows up the runtime of the test.
- Set the
self.setup_clean_chain
variable in__init__()
to control whether or not to use the cached data directories. The cached data directories contain a 200-block pre-mined blockchain and wallets for four nodes. Each node has 25 mature blocks (25x50=1250 BTC) in its wallet. - When calling RPCs with lots of arguments, consider using named keyword arguments instead of positional arguments to make the intent of the call clear to readers.
Test writers may find it helpful to refer to the definitions for the RPC and P2P messages. These can be found in the following source files:
/src/rpc/*
for RPCs/src/wallet/rpc*
for wallet RPCsProcessMessage()
in/src/net_processing.cpp
for parsing P2P messages
-
mininode.py
contains all the definitions for objects that pass over the network (CBlock
,CTransaction
, etc, along with the network-level wrappers for them,msg_block
,msg_tx
, etc). -
P2P tests have two threads. One thread handles all network communication with the bitcored(s) being tested (using python's asyncore package); the other implements the test logic.
-
NodeConn
is the class used to connect to a bitcored. If you implement a callback class that derives fromNodeConnCB
and pass that to theNodeConn
object, your code will receive the appropriate callbacks when events of interest arrive. -
Call
NetworkThread.start()
after allNodeConn
objects are created to start the networking thread. (Continue with the test logic in your existing thread.) -
Can be used to write tests where specific P2P protocol behavior is tested. Examples tests are
p2p-accept-block.py
,p2p-compactblocks.py
.
-
Comptool is a Testing framework for writing tests that compare the block/tx acceptance behavior of a bitcored against 1 or more other bitcored instances. It should not be used to write static tests with known outcomes, since that type of test is easier to write and maintain using the standard BitcoinTestFramework.
-
Set the
num_nodes
variable (defined inComparisonTestFramework
) to start up 1 or more nodes. If using 1 node, then--testbinary
can be used as a command line option to change the bitcored binary used by the test. If using 2 or more nodes, then--refbinary
can be optionally used to change the bitcored that will be used on nodes 2 and up. -
Implement a (generator) function called
get_tests()
which yieldsTestInstance
s. EachTestInstance
consists of:- A list of
[object, outcome, hash]
entriesobject
is aCBlock
,CTransaction
, orCBlockHeader
.CBlock
's andCTransaction
's are tested for acceptance.CBlockHeader
s can be used so that the test runner can deliver complete headers-chains when requested from the bitcored, to allow writing tests where blocks can be delivered out of order but still processed by headers-first bitcored's.outcome
isTrue
,False
, orNone
. IfTrue
orFalse
, the tip is compared with the expected tip -- either the block passed in, or the hash specified as the optional 3rd entry. IfNone
is specified, then the test will compare all the bitcored's being tested to see if they all agree on what the best tip is.hash
is the block hash of the tip to compare against. Optional to specify; if left out then the hash of the block passed in will be used as the expected tip. This allows for specifying an expected tip while testing the handling of either invalid blocks or blocks delivered out of order, which complete a longer chain.
sync_every_block
:True/False
. IfFalse
, then all blocks are inv'ed together, and the test runner waits until the node receives the last one, and tests only the last block for tip acceptance using the outcome and specified tip. IfTrue
, then each block is tested in sequence and synced (this is slower when processing many blocks).sync_every_transaction
:True/False
. Analogous tosync_every_block
, except if the outcome on the last tx is "None", then the contents of the entire mempool are compared across all bitcored connections. IfTrue
orFalse
, then only the last tx's acceptance is tested against the given outcome.
- A list of
-
For examples of tests written in this framework, see
invalidblockrequest.py
andp2p-fullblocktest.py
.
Taken from the python-bitcorerpc repository.
Base class for functional tests.
Generally useful functions.
Basic code to support P2P connectivity to a bitcored.
Framework for comparison-tool style, P2P tests.
Utilities for manipulating transaction scripts (originally from python-bitcorelib)
Implements disk-backed block and tx storage.
Wrapper around OpenSSL EC_Key (originally from python-bitcorelib)
Helpers for script.py
Helper functions for creating blocks and transactions.