src/diagnostics/inspect_validator/src/metrics.rs - fuchsia - Git at Google

 // Copyright 2019 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 use {
     failure::Error,
     fuchsia_inspect::{
         self,
         format::{
             block::{Block, PropertyFormat},
             block_type::BlockType,
         },
     },
     serde_derive::Serialize,
     std::{self, collections::HashMap},
 };

 // Blocks such as Node, Extent, and Name may or may not be part of the Inspect tree. We want to
 // count each case separately. Also, Extent blocks can't be fully analyzed when first scanned,
 // since they don't store their own data size. So there's a three-step process to gather metrics.
 // All these take place while Scanner is reading the VMO:
 //
 // 1) Analyze each block in the VMO with Metrics::analyze().
 // 2) While building the tree,
 //   2A) set the data size for Extent blocks;
 //   2B) record the metrics for all blocks in the tree.
 // 3) Record metrics as "NotUsed" for all remaining blocks, first setting their data size to 0.
 //
 // This can be combined for blocks that are never part of the tree, like Free and Reserved blocks.

 // How many bytes are used to store a single number (same for i, u, and f, defined in the VMO spec)
 const NUMERIC_TYPE_SIZE: usize = 8;

 // Metrics for an individual block - will be remembered alongside the block's data by the Scanner.
 #[derive(Debug)]
 pub struct BlockMetrics {
     description: String,
     header_bytes: usize,
     data_bytes: usize,
     total_bytes: usize,
 }

 impl BlockMetrics {
     pub fn set_data_bytes(&mut self, bytes: usize) {
         self.data_bytes = bytes;
     }

     #[cfg(test)]
     pub(crate) fn sample_for_test(
         description: String,
         header_bytes: usize,
         data_bytes: usize,
         total_bytes: usize,
     ) -> BlockMetrics {
         BlockMetrics { description, header_bytes, data_bytes, total_bytes }
     }
 }

 // Tells whether the block was used in the Inspect tree or not.
 #[derive(PartialEq)]
 pub(crate) enum BlockStatus {
     Used,
     NotUsed,
 }

 // Gathers statistics for a type of block.
 #[derive(Debug, Serialize, PartialEq)]
 pub struct BlockStatistics {
     pub count: u64,
     pub header_bytes: usize,
     pub data_bytes: usize,
     pub total_bytes: usize,
     pub data_percent: u64,
 }

 impl BlockStatistics {
     fn new() -> BlockStatistics {
         BlockStatistics {
             count: 0,
             header_bytes: 0,
             data_bytes: 0,
             total_bytes: 0,
             data_percent: 0,
         }
     }

     fn update(&mut self, numbers: &BlockMetrics, status: BlockStatus) {
         let BlockMetrics { header_bytes, data_bytes, total_bytes, .. } = numbers;
         self.header_bytes += header_bytes;
         if status == BlockStatus::Used {
             self.data_bytes += data_bytes;
         }
         self.total_bytes += total_bytes;
         if self.total_bytes > 0 {
             self.data_percent = (self.data_bytes * 100 / self.total_bytes) as u64;
         }
     }
 }

 // Stores statistics for every type (description) of block, plus VMO as a whole.
 #[derive(Debug, Serialize)]
 pub struct Metrics {
     pub block_count: u64,
     pub size: usize,
     pub block_statistics: HashMap<String, BlockStatistics>,
 }

 trait Description {
     fn description(&self) -> Result<String, Error>;
 }

 // Describes the block, distinguishing array and histogram types.
 impl Description for Block<&[u8]> {
     fn description(&self) -> Result<String, Error> {
         match self.block_type_or()? {
             BlockType::ArrayValue => {
                 Ok(format!("ARRAY({:?}, {})", self.array_format()?, self.array_entry_type()?))
             }
             BlockType::PropertyValue => match self.property_format()? {
                 PropertyFormat::String => Ok("STRING".to_owned()),
                 PropertyFormat::Bytes => Ok("BYTES".to_owned()),
             },
             _ => Ok(format!("{}", self.block_type_or()?)),
         }
     }
 }

 impl Metrics {
     pub fn new() -> Metrics {
         Metrics { block_count: 0, size: 0, block_statistics: HashMap::new() }
     }

     pub(crate) fn record(&mut self, metrics: &BlockMetrics, status: BlockStatus) {
         let description = match status {
             BlockStatus::NotUsed => format!("{}(UNUSED)", metrics.description),
             BlockStatus::Used => metrics.description.clone(),
         };
         let statistics =
             self.block_statistics.entry(description).or_insert_with(|| BlockStatistics::new());
         statistics.count += 1;
         statistics.update(metrics, status);
         self.block_count += 1;
         self.size += metrics.total_bytes;
     }

     // Process (in a single operation) a block of a type that will never be part of the Inspect
     // data tree.
     pub fn process(&mut self, block: Block<&[u8]>) -> Result<(), Error> {
         self.record(&Metrics::analyze(block)?, BlockStatus::Used);
         Ok(())
     }

     pub fn analyze(block: Block<&[u8]>) -> Result<BlockMetrics, Error> {
         let description = block.description()?;
         let block_type = block.block_type_or()?;

         let data_bytes = match block_type {
             BlockType::Header
             | BlockType::Reserved
             | BlockType::NodeValue
             | BlockType::Free
             | BlockType::Extent
             | BlockType::PropertyValue
             | BlockType::Tombstone
             | BlockType::LinkValue => 0,
             BlockType::IntValue | BlockType::UintValue | BlockType::DoubleValue => {
                 NUMERIC_TYPE_SIZE
             }

             BlockType::ArrayValue => NUMERIC_TYPE_SIZE * block.array_slots()?,
             BlockType::Name => block.name_length()?,
         };

         let header_bytes = match block_type {
             BlockType::Header
             | BlockType::NodeValue
             | BlockType::PropertyValue
             | BlockType::Free
             | BlockType::Reserved
             | BlockType::Tombstone
             | BlockType::ArrayValue
             | BlockType::LinkValue => 16,
             BlockType::IntValue
             | BlockType::DoubleValue
             | BlockType::UintValue
             | BlockType::Name
             | BlockType::Extent => 8,
         };

         let total_bytes = 16 << block.order();
         Ok(BlockMetrics { description, data_bytes, header_bytes, total_bytes })
     }
 }

 #[cfg(test)]
 mod tests {
     use num_traits::ToPrimitive;
     use std::convert::TryFrom;
     use {
         super::*,
         crate::{data, puppet, results::Results},
         failure::bail,
         fuchsia_async as fasync,
         fuchsia_inspect::format::{
             bitfields::{BlockHeader, Payload},
             block::{ArrayFormat, PropertyFormat},
             block_type::BlockType,
             constants,
         },
     };

     #[fasync::run_singlethreaded(test)]
     async fn metrics_work() -> Result<(), Error> {
         let puppet = puppet::tests::local_incomplete_puppet().await?;
         let metrics = puppet.metrics().unwrap();
         let mut results = Results::new();
         results.remember_metrics(metrics, "trialfoo", 42, "stepfoo");
         let json = results.to_json();
         assert!(json.contains("\"trial_name\":\"trialfoo\""), json);
         assert!(json.contains(&format!("\"size\":{}", puppet::VMO_SIZE)), json);
         assert!(json.contains("\"step_index\":42"), json);
         assert!(json.contains("\"step_name\":\"stepfoo\""), json);
         assert!(json.contains("\"block_count\":9"), json);
         assert!(json.contains("\"HEADER\":{\"count\":1,\"header_bytes\":16,\"data_bytes\":0,\"total_bytes\":16,\"data_percent\":0}"), json);
         Ok(())
     }

     fn test_metrics(
         buffer: &[u8],
         block_count: u64,
         size: usize,
         description: &str,
         count: u64,
         header_bytes: usize,
         data_bytes: usize,
         total_bytes: usize,
         data_percent: u64,
     ) -> Result<(), Error> {
         let metrics = data::Scanner::try_from(buffer).map(|d| d.metrics())?;
         assert_eq!(metrics.block_count, block_count, "Bad block_count for {}", description);
         assert_eq!(metrics.size, size, "Bad size for {}", description);
         let correct_statistics =
             BlockStatistics { count, header_bytes, data_bytes, total_bytes, data_percent };
         match metrics.block_statistics.get(description) {
             None => {
                 bail!("block {} not found in {:?}", description, metrics.block_statistics.keys())
             }
             Some(statistics) if statistics == &correct_statistics => {}
             Some(unexpected) => bail!(
                 "Value mismatch, {:?} vs {:?} for {}",
                 unexpected,
                 correct_statistics,
                 description
             ),
         }
         Ok(())
     }

     fn copy_into(source: &[u8], dest: &mut [u8], index: usize, offset: usize) {
         let offset = index * 16 + offset;
         dest[offset..offset + source.len()].copy_from_slice(source);
     }

     macro_rules! enum_value {
         ($name:expr) => {
             $name.to_u8().unwrap()
         };
     }
     macro_rules! put_header {
         ($header:ident, $index:expr, $buffer:expr) => {
             copy_into(&$header.value().to_le_bytes(), $buffer, $index, 0);
         };
     }
     macro_rules! put_payload {
         ($header:ident, $index:expr, $buffer:expr) => {
             copy_into(&$header.value().to_le_bytes(), $buffer, $index, 8);
         };
     }
     macro_rules! set_type {
         ($header:ident, $block_type:ident) => {
             $header.set_block_type(enum_value!(BlockType::$block_type))
         };
     }

     const NAME_INDEX: u32 = 2;

     // Creates the required Header block. Also creates a Name block because
     // lots of things use it.
     // Note that \0 is a valid UTF-8 character so there's no need to set string data.
     fn init_vmo_contents(mut buffer: &mut [u8]) {
         const HEADER_INDEX: usize = 0;

         let mut header = BlockHeader(0);
         header.set_order(0);
         set_type!(header, Header);
         header.set_header_magic(constants::HEADER_MAGIC_NUMBER);
         header.set_header_version(constants::HEADER_VERSION_NUMBER);
         put_header!(header, HEADER_INDEX, &mut buffer);
         let mut name_header = BlockHeader(0);
         set_type!(name_header, Name);
         name_header.set_name_length(4);
         put_header!(name_header, NAME_INDEX as usize, &mut buffer);
     }

     #[test]
     fn header_metrics() -> Result<(), Error> {
         let mut buffer = [0u8; 256];
         init_vmo_contents(&mut buffer);
         test_metrics(&buffer, 16, 256, "HEADER", 1, 16, 0, 16, 0)?;
         test_metrics(&buffer, 16, 256, "FREE", 14, 224, 0, 224, 0)?;
         test_metrics(&buffer, 16, 256, "NAME(UNUSED)", 1, 8, 0, 16, 0)?;
         Ok(())
     }

     #[test]
     fn reserved_metrics() -> Result<(), Error> {
         let mut buffer = [0u8; 256];
         init_vmo_contents(&mut buffer);
         let mut reserved_header = BlockHeader(0);
         set_type!(reserved_header, Reserved);
         reserved_header.set_order(1);
         put_header!(reserved_header, 1, &mut buffer);
         test_metrics(&buffer, 15, 256, "RESERVED", 1, 16, 0, 32, 0)?;
         Ok(())
     }

     #[test]
     fn node_metrics() -> Result<(), Error> {
         let mut buffer = [0u8; 256];
         init_vmo_contents(&mut buffer);
         let mut node_header = BlockHeader(0);
         set_type!(node_header, NodeValue);
         node_header.set_value_parent_index(1);
         put_header!(node_header, 1, &mut buffer);
         test_metrics(&buffer, 16, 256, "NODE_VALUE(UNUSED)", 1, 16, 0, 16, 0)?;
         node_header.set_value_name_index(NAME_INDEX);
         node_header.set_value_parent_index(0);
         put_header!(node_header, 1, &mut buffer);
         test_metrics(&buffer, 16, 256, "NODE_VALUE", 1, 16, 0, 16, 0)?;
         test_metrics(&buffer, 16, 256, "NAME", 1, 8, 4, 16, 25)?;
         set_type!(node_header, Tombstone);
         put_header!(node_header, 1, &mut buffer);
         test_metrics(&buffer, 16, 256, "TOMBSTONE", 1, 16, 0, 16, 0)?;
         test_metrics(&buffer, 16, 256, "NAME(UNUSED)", 1, 8, 0, 16, 0)?;
         Ok(())
     }

     #[test]
     fn number_metrics() -> Result<(), Error> {
         let mut buffer = [0u8; 256];
         init_vmo_contents(&mut buffer);
         macro_rules! test_number {
             ($number_type:ident, $parent:expr, $block_string:expr, $data_size:expr, $data_percent:expr) => {
                 let mut value_header = BlockHeader(0);
                 set_type!(value_header, $number_type);
                 value_header.set_value_name_index(NAME_INDEX);
                 value_header.set_value_parent_index($parent);
                 put_header!(value_header, 1, &mut buffer);
                 test_metrics(&buffer, 16, 256, $block_string, 1, 8, $data_size, 16, $data_percent)?;
             };
         }
         test_number!(IntValue, 0, "INT_VALUE", 8, 50);
         test_number!(IntValue, 5, "INT_VALUE(UNUSED)", 0, 0);
         test_number!(DoubleValue, 0, "DOUBLE_VALUE", 8, 50);
         test_number!(DoubleValue, 5, "DOUBLE_VALUE(UNUSED)", 0, 0);
         test_number!(UintValue, 0, "UINT_VALUE", 8, 50);
         test_number!(UintValue, 5, "UINT_VALUE(UNUSED)", 0, 0);
         Ok(())
     }

     #[test]
     fn property_metrics() -> Result<(), Error> {
         let mut buffer = [0u8; 256];
         init_vmo_contents(&mut buffer);
         let mut value_header = BlockHeader(0);
         set_type!(value_header, PropertyValue);
         value_header.set_value_name_index(NAME_INDEX);
         value_header.set_value_parent_index(0);
         put_header!(value_header, 1, &mut buffer);
         let mut property_payload = Payload(0);
         property_payload.set_property_total_length(12);
         property_payload.set_property_extent_index(4);
         property_payload.set_property_flags(enum_value!(PropertyFormat::String));
         put_payload!(property_payload, 1, &mut buffer);
         let mut extent_header = BlockHeader(0);
         set_type!(extent_header, Extent);
         extent_header.set_extent_next_index(5);
         put_header!(extent_header, 4, &mut buffer);
         extent_header.set_extent_next_index(0);
         put_header!(extent_header, 5, &mut buffer);
         test_metrics(&buffer, 16, 256, "EXTENT", 2, 16, 12, 32, 37)?;
         test_metrics(&buffer, 16, 256, "STRING", 1, 16, 0, 16, 0)?;
         property_payload.set_property_flags(enum_value!(PropertyFormat::Bytes));
         put_payload!(property_payload, 1, &mut buffer);
         test_metrics(&buffer, 16, 256, "EXTENT", 2, 16, 12, 32, 37)?;
         test_metrics(&buffer, 16, 256, "BYTES", 1, 16, 0, 16, 0)?;
         value_header.set_value_parent_index(7);
         put_header!(value_header, 1, &mut buffer);
         test_metrics(&buffer, 16, 256, "EXTENT(UNUSED)", 2, 16, 0, 32, 0)?;
         test_metrics(&buffer, 16, 256, "BYTES(UNUSED)", 1, 16, 0, 16, 0)?;
         Ok(())
     }

     #[test]
     fn array_metrics() -> Result<(), Error> {
         let mut buffer = [0u8; 256];
         init_vmo_contents(&mut buffer);
         let mut value_header = BlockHeader(0);
         set_type!(value_header, ArrayValue);
         value_header.set_order(3);
         value_header.set_value_name_index(NAME_INDEX);
         value_header.set_value_parent_index(0);
         put_header!(value_header, 4, &mut buffer);
         let mut property_payload = Payload(0);
         property_payload.set_array_entry_type(enum_value!(BlockType::IntValue));
         property_payload.set_array_flags(enum_value!(ArrayFormat::Default));
         property_payload.set_array_slots_count(4);
         put_payload!(property_payload, 4, &mut buffer);
         test_metrics(&buffer, 9, 256, "ARRAY(Default, INT_VALUE)", 1, 16, 32, 128, 25)?;
         property_payload.set_array_flags(enum_value!(ArrayFormat::LinearHistogram));
         property_payload.set_array_slots_count(8);
         put_payload!(property_payload, 4, &mut buffer);
         test_metrics(&buffer, 9, 256, "ARRAY(LinearHistogram, INT_VALUE)", 1, 16, 64, 128, 50)?;
         property_payload.set_array_flags(enum_value!(ArrayFormat::ExponentialHistogram));
         // avoid line-wrapping the parameter list of test_metrics()
         let name = "ARRAY(ExponentialHistogram, INT_VALUE)";
         put_payload!(property_payload, 4, &mut buffer);
         test_metrics(&buffer, 9, 256, name, 1, 16, 64, 128, 50)?;
         property_payload.set_array_entry_type(enum_value!(BlockType::UintValue));
         let name = "ARRAY(ExponentialHistogram, UINT_VALUE)";
         put_payload!(property_payload, 4, &mut buffer);
         test_metrics(&buffer, 9, 256, name, 1, 16, 64, 128, 50)?;
         property_payload.set_array_entry_type(enum_value!(BlockType::DoubleValue));
         let name = "ARRAY(ExponentialHistogram, DOUBLE_VALUE)";
         put_payload!(property_payload, 4, &mut buffer);
         test_metrics(&buffer, 9, 256, name, 1, 16, 64, 128, 50)?;
         value_header.set_value_parent_index(1);
         let name = "ARRAY(ExponentialHistogram, DOUBLE_VALUE)(UNUSED)";
         put_header!(value_header, 4, &mut buffer);
         test_metrics(&buffer, 9, 256, name, 1, 16, 0, 128, 0)?;
         Ok(())
     }
 }
	// Copyright 2019 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	use {
	failure::Error,
	fuchsia_inspect::{
	self,
	format::{
	block::{Block, PropertyFormat},
	block_type::BlockType,
	},
	},
	serde_derive::Serialize,
	std::{self, collections::HashMap},
	};

	// Blocks such as Node, Extent, and Name may or may not be part of the Inspect tree. We want to
	// count each case separately. Also, Extent blocks can't be fully analyzed when first scanned,
	// since they don't store their own data size. So there's a three-step process to gather metrics.
	// All these take place while Scanner is reading the VMO:
	//
	// 1) Analyze each block in the VMO with Metrics::analyze().
	// 2) While building the tree,
	// 2A) set the data size for Extent blocks;
	// 2B) record the metrics for all blocks in the tree.
	// 3) Record metrics as "NotUsed" for all remaining blocks, first setting their data size to 0.
	//
	// This can be combined for blocks that are never part of the tree, like Free and Reserved blocks.

	// How many bytes are used to store a single number (same for i, u, and f, defined in the VMO spec)
	const NUMERIC_TYPE_SIZE: usize = 8;

	// Metrics for an individual block - will be remembered alongside the block's data by the Scanner.
	#[derive(Debug)]
	pub struct BlockMetrics {
	description: String,
	header_bytes: usize,
	data_bytes: usize,
	total_bytes: usize,
	}

	impl BlockMetrics {
	pub fn set_data_bytes(&mut self, bytes: usize) {
	self.data_bytes = bytes;
	}

	#[cfg(test)]
	pub(crate) fn sample_for_test(
	description: String,
	header_bytes: usize,
	data_bytes: usize,
	total_bytes: usize,
	) -> BlockMetrics {
	BlockMetrics { description, header_bytes, data_bytes, total_bytes }
	}
	}

	// Tells whether the block was used in the Inspect tree or not.
	#[derive(PartialEq)]
	pub(crate) enum BlockStatus {
	Used,
	NotUsed,
	}

	// Gathers statistics for a type of block.
	#[derive(Debug, Serialize, PartialEq)]
	pub struct BlockStatistics {
	pub count: u64,
	pub header_bytes: usize,
	pub data_bytes: usize,
	pub total_bytes: usize,
	pub data_percent: u64,
	}

	impl BlockStatistics {
	fn new() -> BlockStatistics {
	BlockStatistics {
	count: 0,
	header_bytes: 0,
	data_bytes: 0,
	total_bytes: 0,
	data_percent: 0,
	}
	}

	fn update(&mut self, numbers: &BlockMetrics, status: BlockStatus) {
	let BlockMetrics { header_bytes, data_bytes, total_bytes, .. } = numbers;
	self.header_bytes += header_bytes;
	if status == BlockStatus::Used {
	self.data_bytes += data_bytes;
	}
	self.total_bytes += total_bytes;
	if self.total_bytes > 0 {
	self.data_percent = (self.data_bytes * 100 / self.total_bytes) as u64;
	}
	}
	}

	// Stores statistics for every type (description) of block, plus VMO as a whole.
	#[derive(Debug, Serialize)]
	pub struct Metrics {
	pub block_count: u64,
	pub size: usize,
	pub block_statistics: HashMap<String, BlockStatistics>,
	}

	trait Description {
	fn description(&self) -> Result<String, Error>;
	}

	// Describes the block, distinguishing array and histogram types.
	impl Description for Block<&[u8]> {
	fn description(&self) -> Result<String, Error> {
	match self.block_type_or()? {
	BlockType::ArrayValue => {
	Ok(format!("ARRAY({:?}, {})", self.array_format()?, self.array_entry_type()?))
	}
	BlockType::PropertyValue => match self.property_format()? {
	PropertyFormat::String => Ok("STRING".to_owned()),
	PropertyFormat::Bytes => Ok("BYTES".to_owned()),
	},
	_ => Ok(format!("{}", self.block_type_or()?)),
	}
	}
	}

	impl Metrics {
	pub fn new() -> Metrics {
	Metrics { block_count: 0, size: 0, block_statistics: HashMap::new() }
	}

	pub(crate) fn record(&mut self, metrics: &BlockMetrics, status: BlockStatus) {
	let description = match status {
	BlockStatus::NotUsed => format!("{}(UNUSED)", metrics.description),
	BlockStatus::Used => metrics.description.clone(),
	};
	let statistics =
	self.block_statistics.entry(description).or_insert_with(\|\| BlockStatistics::new());
	statistics.count += 1;
	statistics.update(metrics, status);
	self.block_count += 1;
	self.size += metrics.total_bytes;
	}

	// Process (in a single operation) a block of a type that will never be part of the Inspect
	// data tree.
	pub fn process(&mut self, block: Block<&[u8]>) -> Result<(), Error> {
	self.record(&Metrics::analyze(block)?, BlockStatus::Used);
	Ok(())
	}

	pub fn analyze(block: Block<&[u8]>) -> Result<BlockMetrics, Error> {
	let description = block.description()?;
	let block_type = block.block_type_or()?;

	let data_bytes = match block_type {
	BlockType::Header
	\| BlockType::Reserved
	\| BlockType::NodeValue
	\| BlockType::Free
	\| BlockType::Extent
	\| BlockType::PropertyValue
	\| BlockType::Tombstone
	\| BlockType::LinkValue => 0,
	BlockType::IntValue \| BlockType::UintValue \| BlockType::DoubleValue => {
	NUMERIC_TYPE_SIZE
	}

	BlockType::ArrayValue => NUMERIC_TYPE_SIZE * block.array_slots()?,
	BlockType::Name => block.name_length()?,
	};

	let header_bytes = match block_type {
	BlockType::Header
	\| BlockType::NodeValue
	\| BlockType::PropertyValue
	\| BlockType::Free
	\| BlockType::Reserved
	\| BlockType::Tombstone
	\| BlockType::ArrayValue
	\| BlockType::LinkValue => 16,
	BlockType::IntValue
	\| BlockType::DoubleValue
	\| BlockType::UintValue
	\| BlockType::Name
	\| BlockType::Extent => 8,
	};

	let total_bytes = 16 << block.order();
	Ok(BlockMetrics { description, data_bytes, header_bytes, total_bytes })
	}
	}

	#[cfg(test)]
	mod tests {
	use num_traits::ToPrimitive;
	use std::convert::TryFrom;
	use {
	super::*,
	crate::{data, puppet, results::Results},
	failure::bail,
	fuchsia_async as fasync,
	fuchsia_inspect::format::{
	bitfields::{BlockHeader, Payload},
	block::{ArrayFormat, PropertyFormat},
	block_type::BlockType,
	constants,
	},
	};

	#[fasync::run_singlethreaded(test)]
	async fn metrics_work() -> Result<(), Error> {
	let puppet = puppet::tests::local_incomplete_puppet().await?;
	let metrics = puppet.metrics().unwrap();
	let mut results = Results::new();
	results.remember_metrics(metrics, "trialfoo", 42, "stepfoo");
	let json = results.to_json();
	assert!(json.contains("\"trial_name\":\"trialfoo\""), json);
	assert!(json.contains(&format!("\"size\":{}", puppet::VMO_SIZE)), json);
	assert!(json.contains("\"step_index\":42"), json);
	assert!(json.contains("\"step_name\":\"stepfoo\""), json);
	assert!(json.contains("\"block_count\":9"), json);
	assert!(json.contains("\"HEADER\":{\"count\":1,\"header_bytes\":16,\"data_bytes\":0,\"total_bytes\":16,\"data_percent\":0}"), json);
	Ok(())
	}

	fn test_metrics(
	buffer: &[u8],
	block_count: u64,
	size: usize,
	description: &str,
	count: u64,
	header_bytes: usize,
	data_bytes: usize,
	total_bytes: usize,
	data_percent: u64,
	) -> Result<(), Error> {
	let metrics = data::Scanner::try_from(buffer).map(\|d\| d.metrics())?;
	assert_eq!(metrics.block_count, block_count, "Bad block_count for {}", description);
	assert_eq!(metrics.size, size, "Bad size for {}", description);
	let correct_statistics =
	BlockStatistics { count, header_bytes, data_bytes, total_bytes, data_percent };
	match metrics.block_statistics.get(description) {
	None => {
	bail!("block {} not found in {:?}", description, metrics.block_statistics.keys())
	}
	Some(statistics) if statistics == &correct_statistics => {}
	Some(unexpected) => bail!(
	"Value mismatch, {:?} vs {:?} for {}",
	unexpected,
	correct_statistics,
	description
	),
	}
	Ok(())
	}

	fn copy_into(source: &[u8], dest: &mut [u8], index: usize, offset: usize) {
	let offset = index * 16 + offset;
	dest[offset..offset + source.len()].copy_from_slice(source);
	}

	macro_rules! enum_value {
	($name:expr) => {
	$name.to_u8().unwrap()
	};
	}
	macro_rules! put_header {
	($header:ident, $index:expr, $buffer:expr) => {
	copy_into(&$header.value().to_le_bytes(), $buffer, $index, 0);
	};
	}
	macro_rules! put_payload {
	($header:ident, $index:expr, $buffer:expr) => {
	copy_into(&$header.value().to_le_bytes(), $buffer, $index, 8);
	};
	}
	macro_rules! set_type {
	($header:ident, $block_type:ident) => {
	$header.set_block_type(enum_value!(BlockType::$block_type))
	};
	}

	const NAME_INDEX: u32 = 2;

	// Creates the required Header block. Also creates a Name block because
	// lots of things use it.
	// Note that \0 is a valid UTF-8 character so there's no need to set string data.
	fn init_vmo_contents(mut buffer: &mut [u8]) {
	const HEADER_INDEX: usize = 0;

	let mut header = BlockHeader(0);
	header.set_order(0);
	set_type!(header, Header);
	header.set_header_magic(constants::HEADER_MAGIC_NUMBER);
	header.set_header_version(constants::HEADER_VERSION_NUMBER);
	put_header!(header, HEADER_INDEX, &mut buffer);
	let mut name_header = BlockHeader(0);
	set_type!(name_header, Name);
	name_header.set_name_length(4);
	put_header!(name_header, NAME_INDEX as usize, &mut buffer);
	}

	#[test]
	fn header_metrics() -> Result<(), Error> {
	let mut buffer = [0u8; 256];
	init_vmo_contents(&mut buffer);
	test_metrics(&buffer, 16, 256, "HEADER", 1, 16, 0, 16, 0)?;
	test_metrics(&buffer, 16, 256, "FREE", 14, 224, 0, 224, 0)?;
	test_metrics(&buffer, 16, 256, "NAME(UNUSED)", 1, 8, 0, 16, 0)?;
	Ok(())
	}

	#[test]
	fn reserved_metrics() -> Result<(), Error> {
	let mut buffer = [0u8; 256];
	init_vmo_contents(&mut buffer);
	let mut reserved_header = BlockHeader(0);
	set_type!(reserved_header, Reserved);
	reserved_header.set_order(1);
	put_header!(reserved_header, 1, &mut buffer);
	test_metrics(&buffer, 15, 256, "RESERVED", 1, 16, 0, 32, 0)?;
	Ok(())
	}

	#[test]
	fn node_metrics() -> Result<(), Error> {
	let mut buffer = [0u8; 256];
	init_vmo_contents(&mut buffer);
	let mut node_header = BlockHeader(0);
	set_type!(node_header, NodeValue);
	node_header.set_value_parent_index(1);
	put_header!(node_header, 1, &mut buffer);
	test_metrics(&buffer, 16, 256, "NODE_VALUE(UNUSED)", 1, 16, 0, 16, 0)?;
	node_header.set_value_name_index(NAME_INDEX);
	node_header.set_value_parent_index(0);
	put_header!(node_header, 1, &mut buffer);
	test_metrics(&buffer, 16, 256, "NODE_VALUE", 1, 16, 0, 16, 0)?;
	test_metrics(&buffer, 16, 256, "NAME", 1, 8, 4, 16, 25)?;
	set_type!(node_header, Tombstone);
	put_header!(node_header, 1, &mut buffer);
	test_metrics(&buffer, 16, 256, "TOMBSTONE", 1, 16, 0, 16, 0)?;
	test_metrics(&buffer, 16, 256, "NAME(UNUSED)", 1, 8, 0, 16, 0)?;
	Ok(())
	}

	#[test]
	fn number_metrics() -> Result<(), Error> {
	let mut buffer = [0u8; 256];
	init_vmo_contents(&mut buffer);
	macro_rules! test_number {
	($number_type:ident, $parent:expr, $block_string:expr, $data_size:expr, $data_percent:expr) => {
	let mut value_header = BlockHeader(0);
	set_type!(value_header, $number_type);
	value_header.set_value_name_index(NAME_INDEX);
	value_header.set_value_parent_index($parent);
	put_header!(value_header, 1, &mut buffer);
	test_metrics(&buffer, 16, 256, $block_string, 1, 8, $data_size, 16, $data_percent)?;
	};
	}
	test_number!(IntValue, 0, "INT_VALUE", 8, 50);
	test_number!(IntValue, 5, "INT_VALUE(UNUSED)", 0, 0);
	test_number!(DoubleValue, 0, "DOUBLE_VALUE", 8, 50);
	test_number!(DoubleValue, 5, "DOUBLE_VALUE(UNUSED)", 0, 0);
	test_number!(UintValue, 0, "UINT_VALUE", 8, 50);
	test_number!(UintValue, 5, "UINT_VALUE(UNUSED)", 0, 0);
	Ok(())
	}

	#[test]
	fn property_metrics() -> Result<(), Error> {
	let mut buffer = [0u8; 256];
	init_vmo_contents(&mut buffer);
	let mut value_header = BlockHeader(0);
	set_type!(value_header, PropertyValue);
	value_header.set_value_name_index(NAME_INDEX);
	value_header.set_value_parent_index(0);
	put_header!(value_header, 1, &mut buffer);
	let mut property_payload = Payload(0);
	property_payload.set_property_total_length(12);
	property_payload.set_property_extent_index(4);
	property_payload.set_property_flags(enum_value!(PropertyFormat::String));
	put_payload!(property_payload, 1, &mut buffer);
	let mut extent_header = BlockHeader(0);
	set_type!(extent_header, Extent);
	extent_header.set_extent_next_index(5);
	put_header!(extent_header, 4, &mut buffer);
	extent_header.set_extent_next_index(0);
	put_header!(extent_header, 5, &mut buffer);
	test_metrics(&buffer, 16, 256, "EXTENT", 2, 16, 12, 32, 37)?;
	test_metrics(&buffer, 16, 256, "STRING", 1, 16, 0, 16, 0)?;
	property_payload.set_property_flags(enum_value!(PropertyFormat::Bytes));
	put_payload!(property_payload, 1, &mut buffer);
	test_metrics(&buffer, 16, 256, "EXTENT", 2, 16, 12, 32, 37)?;
	test_metrics(&buffer, 16, 256, "BYTES", 1, 16, 0, 16, 0)?;
	value_header.set_value_parent_index(7);
	put_header!(value_header, 1, &mut buffer);
	test_metrics(&buffer, 16, 256, "EXTENT(UNUSED)", 2, 16, 0, 32, 0)?;
	test_metrics(&buffer, 16, 256, "BYTES(UNUSED)", 1, 16, 0, 16, 0)?;
	Ok(())
	}

	#[test]
	fn array_metrics() -> Result<(), Error> {
	let mut buffer = [0u8; 256];
	init_vmo_contents(&mut buffer);
	let mut value_header = BlockHeader(0);
	set_type!(value_header, ArrayValue);
	value_header.set_order(3);
	value_header.set_value_name_index(NAME_INDEX);
	value_header.set_value_parent_index(0);
	put_header!(value_header, 4, &mut buffer);
	let mut property_payload = Payload(0);
	property_payload.set_array_entry_type(enum_value!(BlockType::IntValue));
	property_payload.set_array_flags(enum_value!(ArrayFormat::Default));
	property_payload.set_array_slots_count(4);
	put_payload!(property_payload, 4, &mut buffer);
	test_metrics(&buffer, 9, 256, "ARRAY(Default, INT_VALUE)", 1, 16, 32, 128, 25)?;
	property_payload.set_array_flags(enum_value!(ArrayFormat::LinearHistogram));
	property_payload.set_array_slots_count(8);
	put_payload!(property_payload, 4, &mut buffer);
	test_metrics(&buffer, 9, 256, "ARRAY(LinearHistogram, INT_VALUE)", 1, 16, 64, 128, 50)?;
	property_payload.set_array_flags(enum_value!(ArrayFormat::ExponentialHistogram));
	// avoid line-wrapping the parameter list of test_metrics()
	let name = "ARRAY(ExponentialHistogram, INT_VALUE)";
	put_payload!(property_payload, 4, &mut buffer);
	test_metrics(&buffer, 9, 256, name, 1, 16, 64, 128, 50)?;
	property_payload.set_array_entry_type(enum_value!(BlockType::UintValue));
	let name = "ARRAY(ExponentialHistogram, UINT_VALUE)";
	put_payload!(property_payload, 4, &mut buffer);
	test_metrics(&buffer, 9, 256, name, 1, 16, 64, 128, 50)?;
	property_payload.set_array_entry_type(enum_value!(BlockType::DoubleValue));
	let name = "ARRAY(ExponentialHistogram, DOUBLE_VALUE)";
	put_payload!(property_payload, 4, &mut buffer);
	test_metrics(&buffer, 9, 256, name, 1, 16, 64, 128, 50)?;
	value_header.set_value_parent_index(1);
	let name = "ARRAY(ExponentialHistogram, DOUBLE_VALUE)(UNUSED)";
	put_header!(value_header, 4, &mut buffer);
	test_metrics(&buffer, 9, 256, name, 1, 16, 0, 128, 0)?;
	Ok(())
	}
	}