// This file is part of Substrate. // Copyright (C) 2020-2021 Parity Technologies (UK) Ltd. // SPDX-License-Identifier: Apache-2.0 // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. //! Macro for benchmarking a FRAME runtime. #![cfg_attr(not(feature = "std"), no_std)] mod tests; mod utils; #[cfg(feature = "std")] mod analysis; pub use utils::*; #[cfg(feature = "std")] pub use analysis::{Analysis, BenchmarkSelector, RegressionModel}; #[doc(hidden)] pub use sp_io::storage::root as storage_root; pub use sp_runtime::traits::Zero; pub use frame_support; pub use paste; pub use sp_storage::TrackedStorageKey; /// Construct pallet benchmarks for weighing dispatchables. /// /// Works around the idea of complexity parameters, named by a single letter (which is usually /// upper cased in complexity notation but is lower-cased for use in this macro). /// /// Complexity parameters ("parameters") have a range which is a `u32` pair. Every time a benchmark /// is prepared and run, this parameter takes a concrete value within the range. There is an /// associated instancing block, which is a single expression that is evaluated during /// preparation. It may use `?` (`i.e. `return Err(...)`) to bail with a string error. Here's a /// few examples: /// /// ```ignore /// // These two are equivalent: /// let x in 0 .. 10; /// let x in 0 .. 10 => (); /// // This one calls a setup function and might return an error (which would be terminal). /// let y in 0 .. 10 => setup(y)?; /// // This one uses a code block to do lots of stuff: /// let z in 0 .. 10 => { /// let a = z * z / 5; /// let b = do_something(a)?; /// combine_into(z, b); /// } /// ``` /// /// Note that due to parsing restrictions, if the `from` expression is not a single token (i.e. a /// literal or constant), then it must be parenthesised. /// /// The macro allows for a number of "arms", each representing an individual benchmark. Using the /// simple syntax, the associated dispatchable function maps 1:1 with the benchmark and the name of /// the benchmark is the same as that of the associated function. However, extended syntax allows /// for arbitrary expresions to be evaluated in a benchmark (including for example, /// `on_initialize`). /// /// Note that the ranges are *inclusive* on both sides. This is in contrast to ranges in Rust which /// are left-inclusive right-exclusive. /// /// Each arm may also have a block of code which is run prior to any instancing and a block of code /// which is run afterwards. All code blocks may draw upon the specific value of each parameter /// at any time. Local variables are shared between the two pre- and post- code blocks, but do not /// leak from the interior of any instancing expressions. /// /// Example: /// ```ignore /// benchmarks! { /// where_clause { where T::A: From } // Optional line to give additional bound on `T`. /// /// // first dispatchable: foo; this is a user dispatchable and operates on a `u8` vector of /// // size `l` /// foo { /// let caller = account::(b"caller", 0, benchmarks_seed); /// let l in 1 .. MAX_LENGTH => initialize_l(l); /// }: _(Origin::Signed(caller), vec![0u8; l]) /// /// // second dispatchable: bar; this is a root dispatchable and accepts a `u8` vector of size /// // `l`. /// // In this case, we explicitly name the call using `bar` instead of `_`. /// bar { /// let l in 1 .. MAX_LENGTH => initialize_l(l); /// }: bar(Origin::Root, vec![0u8; l]) /// /// // third dispatchable: baz; this is a user dispatchable. It isn't dependent on length like the /// // other two but has its own complexity `c` that needs setting up. It uses `caller` (in the /// // pre-instancing block) within the code block. This is only allowed in the param instancers /// // of arms. /// baz1 { /// let caller = account::(b"caller", 0, benchmarks_seed); /// let c = 0 .. 10 => setup_c(&caller, c); /// }: baz(Origin::Signed(caller)) /// /// // this is a second benchmark of the baz dispatchable with a different setup. /// baz2 { /// let caller = account::(b"caller", 0, benchmarks_seed); /// let c = 0 .. 10 => setup_c_in_some_other_way(&caller, c); /// }: baz(Origin::Signed(caller)) /// /// // this is benchmarking some code that is not a dispatchable. /// populate_a_set { /// let x in 0 .. 10_000; /// let mut m = Vec::::new(); /// for i in 0..x { /// m.insert(i); /// } /// }: { m.into_iter().collect::() } /// } /// ``` /// /// Test functions are automatically generated for each benchmark and are accessible to you when you /// run `cargo test`. All tests are named `test_benchmark_`, expect you to pass them /// the Runtime Config, and run them in a test externalities environment. The test function runs your /// benchmark just like a regular benchmark, but only testing at the lowest and highest values for /// each component. The function will return `Ok(())` if the benchmarks return no errors. /// /// You can optionally add a `verify` code block at the end of a benchmark to test any final state /// of your benchmark in a unit test. For example: /// /// ```ignore /// sort_vector { /// let x in 1 .. 10000; /// let mut m = Vec::::new(); /// for i in (0..x).rev() { /// m.push(i); /// } /// }: { /// m.sort(); /// } verify { /// ensure!(m[0] == 0, "You forgot to sort!") /// } /// ``` /// /// These `verify` blocks will not affect your benchmark results! /// /// You can construct benchmark tests like so: /// /// ```ignore /// #[test] /// fn test_benchmarks() { /// new_test_ext().execute_with(|| { /// assert_ok!(test_benchmark_dummy::()); /// assert_err!(test_benchmark_other_name::(), "Bad origin"); /// assert_ok!(test_benchmark_sort_vector::()); /// assert_err!(test_benchmark_broken_benchmark::(), "You forgot to sort!"); /// }); /// } /// ``` #[macro_export] macro_rules! benchmarks { ( $( $rest:tt )* ) => { $crate::benchmarks_iter!( { } { } ( ) ( ) $( $rest )* ); } } /// Same as [`benchmarks`] but for instantiable module. #[macro_export] macro_rules! benchmarks_instance { ( $( $rest:tt )* ) => { $crate::benchmarks_iter!( { I } { } ( ) ( ) $( $rest )* ); } } #[macro_export] #[doc(hidden)] macro_rules! benchmarks_iter { // detect and extract where clause: ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) where_clause { where $( $where_ty:ty: $where_bound:path ),* $(,)? } $( $rest:tt )* ) => { $crate::benchmarks_iter! { { $( $instance)? } { $( $where_ty: $where_bound ),* } ( $( $names )* ) ( $( $names_extra )* ) $( $rest )* } }; // detect and extract extra tag: ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) #[extra] $name:ident $( $rest:tt )* ) => { $crate::benchmarks_iter! { { $( $instance)? } { $( $where_clause )* } ( $( $names )* ) ( $( $names_extra )* $name ) $name $( $rest )* } }; // mutation arm: ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) // This contains $( $( { $instance } )? $name:ident )* ( $( $names_extra:tt )* ) $name:ident { $( $code:tt )* }: _ ( $origin:expr $( , $arg:expr )* ) verify $postcode:block $( $rest:tt )* ) => { $crate::benchmarks_iter! { { $( $instance)? } { $( $where_clause )* } ( $( $names )* ) ( $( $names_extra )* ) $name { $( $code )* }: $name ( $origin $( , $arg )* ) verify $postcode $( $rest )* } }; // mutation arm: ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) $name:ident { $( $code:tt )* }: $dispatch:ident ( $origin:expr $( , $arg:expr )* ) verify $postcode:block $( $rest:tt )* ) => { $crate::benchmarks_iter! { { $( $instance)? } { $( $where_clause )* } ( $( $names )* ) ( $( $names_extra )* ) $name { $( $code )* }: { < Call as $crate::frame_support::traits::UnfilteredDispatchable >::dispatch_bypass_filter( Call::::$dispatch($($arg),*), $origin.into() )?; } verify $postcode $( $rest )* } }; // iteration arm: ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) $name:ident { $( $code:tt )* }: $eval:block verify $postcode:block $( $rest:tt )* ) => { $crate::benchmark_backend! { { $( $instance)? } $name { $( $where_clause )* } { } { $eval } { $( $code )* } $postcode } #[cfg(test)] $crate::impl_benchmark_test!( { $( $where_clause )* } { $( $instance)? } $name ); $crate::benchmarks_iter!( { $( $instance)? } { $( $where_clause )* } ( $( $names )* { $( $instance )? } $name ) ( $( $names_extra )* ) $( $rest )* ); }; // iteration-exit arm ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) ) => { $crate::selected_benchmark!( { $( $where_clause)* } { $( $instance)? } $( $names )* ); $crate::impl_benchmark!( { $( $where_clause )* } { $( $instance)? } ( $( $names )* ) ( $( $names_extra ),* ) ); }; // add verify block to _() format ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) $name:ident { $( $code:tt )* }: _ ( $origin:expr $( , $arg:expr )* ) $( $rest:tt )* ) => { $crate::benchmarks_iter! { { $( $instance)? } { $( $where_clause )* } ( $( $names )* ) ( $( $names_extra )* ) $name { $( $code )* }: _ ( $origin $( , $arg )* ) verify { } $( $rest )* } }; // add verify block to name() format ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) $name:ident { $( $code:tt )* }: $dispatch:ident ( $origin:expr $( , $arg:expr )* ) $( $rest:tt )* ) => { $crate::benchmarks_iter! { { $( $instance)? } { $( $where_clause )* } ( $( $names )* ) ( $( $names_extra )* ) $name { $( $code )* }: $dispatch ( $origin $( , $arg )* ) verify { } $( $rest )* } }; // add verify block to {} format ( { $( $instance:ident )? } { $( $where_clause:tt )* } ( $( $names:tt )* ) ( $( $names_extra:tt )* ) $name:ident { $( $code:tt )* }: $eval:block $( $rest:tt )* ) => { $crate::benchmarks_iter!( { $( $instance)? } { $( $where_clause )* } ( $( $names )* ) ( $( $names_extra )* ) $name { $( $code )* }: $eval verify { } $( $rest )* ); }; } #[macro_export] #[doc(hidden)] macro_rules! benchmark_backend { // parsing arms ( { $( $instance:ident )? } $name:ident { $( $where_clause:tt )* } { $( PRE { $( $pre_parsed:tt )* } )* } { $eval:block } { let $pre_id:tt : $pre_ty:ty = $pre_ex:expr; $( $rest:tt )* } $postcode:block ) => { $crate::benchmark_backend! { { $( $instance)? } $name { $( $where_clause )* } { $( PRE { $( $pre_parsed )* } )* PRE { $pre_id , $pre_ty , $pre_ex } } { $eval } { $( $rest )* } $postcode } }; ( { $( $instance:ident )? } $name:ident { $( $where_clause:tt )* } { $( $parsed:tt )* } { $eval:block } { let $param:ident in ( $param_from:expr ) .. $param_to:expr => $param_instancer:expr; $( $rest:tt )* } $postcode:block ) => { $crate::benchmark_backend! { { $( $instance)? } $name { $( $where_clause )* } { $( $parsed )* PARAM { $param , $param_from , $param_to , $param_instancer } } { $eval } { $( $rest )* } $postcode } }; // mutation arm to look after a single tt for param_from. ( { $( $instance:ident )? } $name:ident { $( $where_clause:tt )* } { $( $parsed:tt )* } { $eval:block } { let $param:ident in $param_from:tt .. $param_to:expr => $param_instancer:expr ; $( $rest:tt )* } $postcode:block ) => { $crate::benchmark_backend! { { $( $instance)? } $name { $( $where_clause )* } { $( $parsed )* } { $eval } { let $param in ( $param_from ) .. $param_to => $param_instancer; $( $rest )* } $postcode } }; // mutation arm to look after the default tail of `=> ()` ( { $( $instance:ident )? } $name:ident { $( $where_clause:tt )* } { $( $parsed:tt )* } { $eval:block } { let $param:ident in $param_from:tt .. $param_to:expr; $( $rest:tt )* } $postcode:block ) => { $crate::benchmark_backend! { { $( $instance)? } $name { $( $where_clause )* } { $( $parsed )* } { $eval } { let $param in $param_from .. $param_to => (); $( $rest )* } $postcode } }; // mutation arm to look after `let _ =` ( { $( $instance:ident )? } $name:ident { $( $where_clause:tt )* } { $( $parsed:tt )* } { $eval:block } { let $pre_id:tt = $pre_ex:expr; $( $rest:tt )* } $postcode:block ) => { $crate::benchmark_backend! { { $( $instance)? } $name { $( $where_clause )* } { $( $parsed )* } { $eval } { let $pre_id : _ = $pre_ex; $( $rest )* } $postcode } }; // actioning arm ( { $( $instance:ident )? } $name:ident { $( $where_clause:tt )* } { $( PRE { $pre_id:tt , $pre_ty:ty , $pre_ex:expr } )* $( PARAM { $param:ident , $param_from:expr , $param_to:expr , $param_instancer:expr } )* } { $eval:block } { $( $post:tt )* } $postcode:block ) => { #[allow(non_camel_case_types)] struct $name; #[allow(unused_variables)] impl, I: Instance)? > $crate::BenchmarkingSetup for $name where $( $where_clause )* { fn components(&self) -> Vec<($crate::BenchmarkParameter, u32, u32)> { vec! [ $( ($crate::BenchmarkParameter::$param, $param_from, $param_to) ),* ] } fn instance( &self, components: &[($crate::BenchmarkParameter, u32)], verify: bool ) -> Result Result<(), &'static str>>, &'static str> { $( // Prepare instance let $param = components.iter() .find(|&c| c.0 == $crate::BenchmarkParameter::$param) .ok_or("Could not find component in benchmark preparation.")? .1; )* $( let $pre_id : $pre_ty = $pre_ex; )* $( $param_instancer ; )* $( $post )* Ok(Box::new(move || -> Result<(), &'static str> { $eval; if verify { $postcode; } Ok(()) })) } } }; } // Creates a `SelectedBenchmark` enum implementing `BenchmarkingSetup`. // // Every variant must implement [`BenchmarkingSetup`]. // // ```nocompile // // struct Transfer; // impl BenchmarkingSetup for Transfer { ... } // // struct SetBalance; // impl BenchmarkingSetup for SetBalance { ... } // // selected_benchmark!({} Transfer {} SetBalance); // ``` #[macro_export] #[doc(hidden)] macro_rules! selected_benchmark { ( { $( $where_clause:tt )* } { $( $instance:ident )? } $( { $( $bench_inst:ident )? } $bench:ident )* ) => { // The list of available benchmarks for this pallet. #[allow(non_camel_case_types)] enum SelectedBenchmark { $( $bench, )* } // Allow us to select a benchmark from the list of available benchmarks. impl, I: Instance )? > $crate::BenchmarkingSetup for SelectedBenchmark where $( $where_clause )* { fn components(&self) -> Vec<($crate::BenchmarkParameter, u32, u32)> { match self { $( Self::$bench => < $bench as $crate::BenchmarkingSetup >::components(&$bench), )* } } fn instance( &self, components: &[($crate::BenchmarkParameter, u32)], verify: bool ) -> Result Result<(), &'static str>>, &'static str> { match self { $( Self::$bench => < $bench as $crate::BenchmarkingSetup >::instance(&$bench, components, verify), )* } } } }; } #[macro_export] #[doc(hidden)] macro_rules! impl_benchmark { ( { $( $where_clause:tt )* } { $( $instance:ident )? } ( $( { $( $name_inst:ident )? } $name:ident )* ) ( $( $name_extra:ident ),* ) ) => { impl, I: Instance)? > $crate::Benchmarking<$crate::BenchmarkResults> for Module where T: frame_system::Config, $( $where_clause )* { fn benchmarks(extra: bool) -> Vec<&'static [u8]> { let mut all = vec![ $( stringify!($name).as_ref() ),* ]; if !extra { let extra = [ $( stringify!($name_extra).as_ref() ),* ]; all.retain(|x| !extra.contains(x)); } all } fn run_benchmark( extrinsic: &[u8], lowest_range_values: &[u32], highest_range_values: &[u32], steps: &[u32], repeat: u32, whitelist: &[$crate::TrackedStorageKey], verify: bool, ) -> Result, &'static str> { // Map the input to the selected benchmark. let extrinsic = sp_std::str::from_utf8(extrinsic) .map_err(|_| "`extrinsic` is not a valid utf8 string!")?; let selected_benchmark = match extrinsic { $( stringify!($name) => SelectedBenchmark::$name, )* _ => return Err("Could not find extrinsic."), }; let mut results: Vec<$crate::BenchmarkResults> = Vec::new(); if repeat == 0 { return Ok(results); } // Add whitelist to DB including whitelisted caller let mut whitelist = whitelist.to_vec(); let whitelisted_caller_key = as frame_support::storage::StorageMap<_,_>>::hashed_key_for( $crate::whitelisted_caller::() ); whitelist.push(whitelisted_caller_key.into()); $crate::benchmarking::set_whitelist(whitelist); // Warm up the DB $crate::benchmarking::commit_db(); $crate::benchmarking::wipe_db(); let components = < SelectedBenchmark as $crate::BenchmarkingSetup >::components(&selected_benchmark); // Default number of steps for a component. let mut prev_steps = 10; let repeat_benchmark = | repeat: u32, c: &[($crate::BenchmarkParameter, u32)], results: &mut Vec<$crate::BenchmarkResults>, verify: bool, | -> Result<(), &'static str> { // Run the benchmark `repeat` times. for _ in 0..repeat { // Set up the externalities environment for the setup we want to // benchmark. let closure_to_benchmark = < SelectedBenchmark as $crate::BenchmarkingSetup >::instance(&selected_benchmark, c, verify)?; // Set the block number to at least 1 so events are deposited. if $crate::Zero::is_zero(&frame_system::Module::::block_number()) { frame_system::Module::::set_block_number(1u32.into()); } // Commit the externalities to the database, flushing the DB cache. // This will enable worst case scenario for reading from the database. $crate::benchmarking::commit_db(); // Reset the read/write counter so we don't count operations in the setup process. $crate::benchmarking::reset_read_write_count(); if verify { closure_to_benchmark()?; } else { // Time the extrinsic logic. frame_support::debug::trace!( target: "benchmark", "Start Benchmark: {:?}", c ); let start_extrinsic = $crate::benchmarking::current_time(); closure_to_benchmark()?; let finish_extrinsic = $crate::benchmarking::current_time(); let elapsed_extrinsic = finish_extrinsic - start_extrinsic; // Commit the changes to get proper write count $crate::benchmarking::commit_db(); frame_support::debug::trace!( target: "benchmark", "End Benchmark: {} ns", elapsed_extrinsic ); let read_write_count = $crate::benchmarking::read_write_count(); frame_support::debug::trace!( target: "benchmark", "Read/Write Count {:?}", read_write_count ); // Time the storage root recalculation. let start_storage_root = $crate::benchmarking::current_time(); $crate::storage_root(); let finish_storage_root = $crate::benchmarking::current_time(); let elapsed_storage_root = finish_storage_root - start_storage_root; results.push($crate::BenchmarkResults { components: c.to_vec(), extrinsic_time: elapsed_extrinsic, storage_root_time: elapsed_storage_root, reads: read_write_count.0, repeat_reads: read_write_count.1, writes: read_write_count.2, repeat_writes: read_write_count.3, }); } // Wipe the DB back to the genesis state. $crate::benchmarking::wipe_db(); } Ok(()) }; if components.is_empty() { if verify { // If `--verify` is used, run the benchmark once to verify it would complete. repeat_benchmark(1, Default::default(), &mut Vec::new(), true)?; } repeat_benchmark(repeat, Default::default(), &mut results, false)?; } else { // Select the component we will be benchmarking. Each component will be benchmarked. for (idx, (name, low, high)) in components.iter().enumerate() { // Get the number of steps for this component. let steps = steps.get(idx).cloned().unwrap_or(prev_steps); prev_steps = steps; // Skip this loop if steps is zero if steps == 0 { continue } let lowest = lowest_range_values.get(idx).cloned().unwrap_or(*low); let highest = highest_range_values.get(idx).cloned().unwrap_or(*high); let diff = highest - lowest; // Create up to `STEPS` steps for that component between high and low. let step_size = (diff / steps).max(1); let num_of_steps = diff / step_size + 1; for s in 0..num_of_steps { // This is the value we will be testing for component `name` let component_value = lowest + step_size * s; // Select the max value for all the other components. let c: Vec<($crate::BenchmarkParameter, u32)> = components.iter() .enumerate() .map(|(idx, (n, _, h))| if n == name { (*n, component_value) } else { (*n, *highest_range_values.get(idx).unwrap_or(h)) } ) .collect(); if verify { // If `--verify` is used, run the benchmark once to verify it would complete. repeat_benchmark(1, &c, &mut Vec::new(), true)?; } repeat_benchmark(repeat, &c, &mut results, false)?; } } } return Ok(results); } } }; } // This creates a unit test for one benchmark of the main benchmark macro. // It runs the benchmark using the `high` and `low` value for each component // and ensure that everything completes successfully. #[macro_export] #[doc(hidden)] macro_rules! impl_benchmark_test { ( { $( $where_clause:tt )* } { $( $instance:ident )? } $name:ident ) => { $crate::paste::item! { fn [] () -> Result<(), &'static str> where T: frame_system::Config, $( $where_clause )* { let selected_benchmark = SelectedBenchmark::$name; let components = < SelectedBenchmark as $crate::BenchmarkingSetup >::components(&selected_benchmark); let execute_benchmark = | c: Vec<($crate::BenchmarkParameter, u32)> | -> Result<(), &'static str> { // Set up the benchmark, return execution + verification function. let closure_to_verify = < SelectedBenchmark as $crate::BenchmarkingSetup >::instance(&selected_benchmark, &c, true)?; // Set the block number to at least 1 so events are deposited. if $crate::Zero::is_zero(&frame_system::Module::::block_number()) { frame_system::Module::::set_block_number(1u32.into()); } // Run execution + verification closure_to_verify()?; // Reset the state $crate::benchmarking::wipe_db(); Ok(()) }; if components.is_empty() { execute_benchmark(Default::default())?; } else { for (_, (name, low, high)) in components.iter().enumerate() { // Test only the low and high value, assuming values in the middle won't break for component_value in vec![low, high] { // Select the max value for all the other components. let c: Vec<($crate::BenchmarkParameter, u32)> = components.iter() .enumerate() .map(|(_, (n, _, h))| if n == name { (*n, *component_value) } else { (*n, *h) } ) .collect(); execute_benchmark(c)?; } } } Ok(()) } } }; } /// show error message and debugging info for the case of an error happening /// during a benchmark pub fn show_benchmark_debug_info( instance_string: &[u8], benchmark: &[u8], lowest_range_values: &sp_std::prelude::Vec, highest_range_values: &sp_std::prelude::Vec, steps: &sp_std::prelude::Vec, repeat: &u32, verify: &bool, error_message: &str, ) -> sp_runtime::RuntimeString { sp_runtime::format_runtime_string!( "\n* Pallet: {}\n\ * Benchmark: {}\n\ * Lowest_range_values: {:?}\n\ * Highest_range_values: {:?}\n\ * Steps: {:?}\n\ * Repeat: {:?}\n\ * Verify: {:?}\n\ * Error message: {}", sp_std::str::from_utf8(instance_string) .expect("it's all just strings ran through the wasm interface. qed"), sp_std::str::from_utf8(benchmark) .expect("it's all just strings ran through the wasm interface. qed"), lowest_range_values, highest_range_values, steps, repeat, verify, error_message, ) } /// This macro adds pallet benchmarks to a `Vec` object. /// /// First create an object that holds in the input parameters for the benchmark: /// /// ```ignore /// let params = (&config, &whitelist); /// ``` /// /// The `whitelist` is a parameter you pass to control the DB read/write tracking. /// We use a vector of [TrackedStorageKey](./struct.TrackedStorageKey.html), which is a simple struct used to set /// if a key has been read or written to. /// /// For values that should be skipped entirely, we can just pass `key.into()`. For example: /// /// ``` /// use frame_benchmarking::TrackedStorageKey; /// let whitelist: Vec = vec![ /// // Block Number /// hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef702a5c1b19ab7a04f536c519aca4983ac").to_vec().into(), /// // Total Issuance /// hex_literal::hex!("c2261276cc9d1f8598ea4b6a74b15c2f57c875e4cff74148e4628f264b974c80").to_vec().into(), /// // Execution Phase /// hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef7ff553b5a9862a516939d82b3d3d8661a").to_vec().into(), /// // Event Count /// hex_literal::hex!("26aa394eea5630e07c48ae0c9558cef70a98fdbe9ce6c55837576c60c7af3850").to_vec().into(), /// ]; /// ``` /// /// Then define a mutable local variable to hold your `BenchmarkBatch` object: /// /// ```ignore /// let mut batches = Vec::::new(); /// ```` /// /// Then add the pallets you want to benchmark to this object, using their crate name and generated /// module struct: /// /// ```ignore /// add_benchmark!(params, batches, pallet_balances, Balances); /// add_benchmark!(params, batches, pallet_session, SessionBench::); /// add_benchmark!(params, batches, frame_system, SystemBench::); /// ... /// ``` /// /// At the end of `dispatch_benchmark`, you should return this batches object. /// /// In the case where you have multiple instances of a pallet that you need to separately benchmark, /// the name of your module struct will be used as a suffix to your outputted weight file. For /// example: /// /// ```ignore /// add_benchmark!(params, batches, pallet_balances, Balances); // pallet_balances.rs /// add_benchmark!(params, batches, pallet_collective, Council); // pallet_collective_council.rs /// add_benchmark!(params, batches, pallet_collective, TechnicalCommittee); // pallet_collective_technical_committee.rs /// ``` /// /// You can manipulate this suffixed string by using a type alias if needed. For example: /// /// ```ignore /// type Council2 = TechnicalCommittee; /// add_benchmark!(params, batches, pallet_collective, Council2); // pallet_collective_council_2.rs /// ``` #[macro_export] macro_rules! add_benchmark { ( $params:ident, $batches:ident, $name:path, $( $location:tt )* ) => ( let name_string = stringify!($name).as_bytes(); let instance_string = stringify!( $( $location )* ).as_bytes(); let (config, whitelist) = $params; let $crate::BenchmarkConfig { pallet, benchmark, lowest_range_values, highest_range_values, steps, repeat, verify, extra, } = config; if &pallet[..] == &name_string[..] || &pallet[..] == &b"*"[..] { if &pallet[..] == &b"*"[..] || &benchmark[..] == &b"*"[..] { for benchmark in $( $location )*::benchmarks(*extra).into_iter() { $batches.push($crate::BenchmarkBatch { pallet: name_string.to_vec(), instance: instance_string.to_vec(), benchmark: benchmark.to_vec(), results: $( $location )*::run_benchmark( benchmark, &lowest_range_values[..], &highest_range_values[..], &steps[..], *repeat, whitelist, *verify, ).map_err(|e| { $crate::show_benchmark_debug_info( instance_string, benchmark, lowest_range_values, highest_range_values, steps, repeat, verify, e, ) })?, }); } } else { $batches.push($crate::BenchmarkBatch { pallet: name_string.to_vec(), instance: instance_string.to_vec(), benchmark: benchmark.clone(), results: $( $location )*::run_benchmark( &benchmark[..], &lowest_range_values[..], &highest_range_values[..], &steps[..], *repeat, whitelist, *verify, ).map_err(|e| { $crate::show_benchmark_debug_info( instance_string, benchmark, lowest_range_values, highest_range_values, steps, repeat, verify, e, ) })?, }); } } ) }