Traits and associated procedural macros to inspect recursively the memory usage and layout of a value.
The trait MemSize
can be used to compute the overall memory usage of a value
in bytes; the standard library function std::mem::size_of
returns the
stack size of a type in bytes, but it does not take into consideration heap
memory. We provide implementations for most basic types, a derive macro for
structs and enums whose fields implement MemSize
, and support for a few other
crates.
The trait MemDbg
, which depends on MemSize
, can be used to display the
recursive layout of a value, together with the size of each part and the
associated padding bytes. Also in this case we provide implementations for most
basic types, a derive macro for structs and enums whose fields implement
MemDbg
, and support for a few other crates.
Other traits partially provide the functionality of MemSize
, but either they
require implementing manually a trait, which is prone to error, or they do not
provide the flexibility necessary for MemDbg
. Most importantly, MemSize
uses the type system to avoid iterating over the content of a container (a
vector, etc.) when it is not necessary, making it possible to compute instantly
the size of values occupying hundreds of gigabytes of heap memory.
This is the result of the benchmark bench_hash_map
contained in the examples
directory. It builds a hash map with a hundred million entries and then measures
its heap size:
Allocated: 2281701509
get_size: 1879048240 152477833 ns
deep_size_of: 1879048240 152482000 ns
size_of: 2281701432 152261958 ns
mem_size: 2281701424 209 ns
The first line is the number of bytes allocated by the program as returned by
cap
. Then, we display the result of get-size
, deepsize
, size-of
,
and our own MemSize
. Note that the first two crates are just measuring the
space used by the items, and not by the data structure (i.e., they are not
taking into account the load factor and the power-of-two size constraint of the
hash map). Moreover, all other crates are about six orders of magnitude slower
than our implementation, due to the necessity to iterate over all elements.
The trait MemDbg
is useful to display the layout of a value and understand
how much memory is used by each part. In particular, it exploits the new stable
macro [std::mem::offset_of
] to display the padding of each field in square
brackets; moreover, the flag DbgFlags::RUST_LAYOUT
makes it possible to
display structures in the layout used by the Rust compiler, rather than
that given by declaration order.
These features are also available for enums using the feature offset_of_enum
,
which however needs the nightly compiler, as it enables the unstable features
offset_of_enum
and offset_of_nested
.
offset_of_enum
: support for padding and for theDbgFlags::RUST_LAYOUT
flag for enums. Requires the nightly compiler as it enables the unstable featuresoffset_of_enum
andoffset_of_nested
. Callingmem_dbg
with the flagDbgFlags::RUST_LAYOUT
without this feature enabled will result in a panic.half
: support for thehalf
crate.maligned
: support for themaligned
crate.mmap-rs
: support for themmap-rs
crate.rand
: support for therand
crate.
# #![cfg_attr(feature = "offset_of_enum", feature(offset_of_enum, offset_of_nested))]
# fn main() -> Result<(), Box<dyn std::error::Error>> {
use mem_dbg::*;
#[derive(MemSize, MemDbg)]
struct Struct<A, B> {
a: A,
b: B,
test: isize,
}
#[derive(MemSize, MemDbg)]
struct Data<A> {
a: A,
b: Vec<i32>,
c: (u8, String),
}
#[derive(MemSize, MemDbg)]
union SingletonUnion<A: Copy> {
a: A
}
#[derive(MemSize, MemDbg)]
enum TestEnum {
Unit,
Unit2(),
Unit3 {},
Union(SingletonUnion<u8>),
Unnamed(usize, u8),
Named { first: usize, second: u8 },
}
let b = Vec::with_capacity(100);
let s = Struct {
a: TestEnum::Unnamed(0, 16),
b: Data {
a: vec![0x42_u8; 700],
b,
c: (1, "foo".to_owned()),
},
test: -0xbadf00d,
};
println!("size: {}", s.mem_size(SizeFlags::default()));
println!("capacity: {}", s.mem_size(SizeFlags::CAPACITY));
println!();
s.mem_dbg(DbgFlags::empty())?;
println!();
println!("size: {}", s.mem_size(SizeFlags::default()));
println!("capacity: {}", s.mem_size(SizeFlags::CAPACITY));
println!();
s.mem_dbg(DbgFlags::default() | DbgFlags::CAPACITY | DbgFlags::HUMANIZE)?;
#[cfg(feature = "offset_of_enum")]
{
println!();
println!("size: {}", s.mem_size(SizeFlags::default()));
println!("capacity: {}", s.mem_size(SizeFlags::CAPACITY));
println!();
s.mem_dbg(DbgFlags::empty() | DbgFlags::RUST_LAYOUT)?;
}
# Ok(())
# }
The previous program prints:
size: 807
capacity: 1207
807 B ⏺
16 B ├╴a
│ ├╴Variant: Unnamed
8 B │ ├╴0
1 B │ ╰╴1
783 B ├╴b
724 B │ ├╴a
24 B │ ├╴b
35 B │ ╰╴c
1 B │ ├╴0 [7B]
27 B │ ╰╴1
8 B ╰╴test
size: 807
capacity: 1207
1.207 kB 100.00% ⏺: readme::main::Struct<readme::main::TestEnum, readme::main::Data<alloc::vec::Vec<u8>>>
16 B 1.33% ├╴a: readme::main::TestEnum
│ ├╴Variant: Unnamed
8 B 0.66% │ ├╴0: usize
1 B 0.08% │ ╰╴1: u8
1.183 kB 98.01% ├╴b: readme::main::Data<alloc::vec::Vec<u8>>
724 B 59.98% │ ├╴a: alloc::vec::Vec<u8>
424 B 35.13% │ ├╴b: alloc::vec::Vec<i32>
35 B 2.90% │ ╰╴c: (u8, alloc::string::String)
1 B 0.08% │ ├╴0: u8 [7B]
27 B 2.24% │ ╰╴1: alloc::string::String
8 B 0.66% ╰╴test: isize
If run with the feature offset_of_enum
, it prints:
size: 807
capacity: 1207
807 B ⏺
16 B ├╴a
│ ├╴Variant: Unnamed
8 B │ ├╴0
1 B │ ╰╴1 [6B]
783 B ├╴b
724 B │ ├╴a
24 B │ ├╴b
35 B │ ╰╴c
1 B │ ├╴0 [7B]
27 B │ ╰╴1
8 B ╰╴test
size: 807
capacity: 1207
1.207 kB 100.00% ⏺: readme::main::Struct<readme::main::TestEnum, readme::main::Data<alloc::vec::Vec<u8>>>
16 B 1.33% ├╴a: readme::main::TestEnum
│ ├╴Variant: Unnamed
8 B 0.66% │ ├╴0: usize
1 B 0.08% │ ╰╴1: u8 [6B]
1.183 kB 98.01% ├╴b: readme::main::Data<alloc::vec::Vec<u8>>
724 B 59.98% │ ├╴a: alloc::vec::Vec<u8>
424 B 35.13% │ ├╴b: alloc::vec::Vec<i32>
35 B 2.90% │ ╰╴c: (u8, alloc::string::String)
1 B 0.08% │ ├╴0: u8 [7B]
27 B 2.24% │ ╰╴1: alloc::string::String
8 B 0.66% ╰╴test: isize
size: 807
capacity: 1207
807 B ⏺
783 B ├╴b
724 B │ ├╴a
24 B │ ├╴b
35 B │ ╰╴c
1 B │ ├╴0 [7B]
27 B │ ╰╴1
16 B ├╴a
│ ├╴Variant: Unnamed
1 B │ ├╴1 [6B]
8 B │ ╰╴0
8 B ╰╴test
-
We support out-of-the-box most basic types, and tuples up to size ten. The derive macros
MemSize
/MemDbg
will generate implementations for structs and enums whose fields implement the associated interface: if this is not the case (e.g., because of the orphan rule) one can implement the traits manually. -
If you invoke the methods of this crate on a shared reference, the compiler will automatically dereference it, and the method will be invoked on the referenced type:
# fn main() -> Result<(), Box<dyn std::error::Error>> {
use mem_dbg::*;
let mut x: [i32; 4] = [0, 0, 0, 0];
assert_eq!(
(&x).mem_size(SizeFlags::default()),
std::mem::size_of::<[i32; 4]>()
);
assert_eq!(
(&mut x).mem_size(SizeFlags::default()),
std::mem::size_of::<&mut [i32; 4]>()
);
assert_eq!(
<&[i32; 4] as MemSize>::mem_size(&&x, SizeFlags::default()),
std::mem::size_of::<&[i32; 4]>()
);
# Ok(())
# }
-
Computation of the size of arrays, slices, and vectors will be performed by iterating over their elements unless the type is a copy type that does not contain non-
'static
references and it is declared as such using the attribute#[copy_type]
. SeeCopyType
for more details. -
The content of vectors and slices is not expanded recursively as the output might be too complex; this might change in the future (e.g., via a flag) should interesting use cases arise.
-
BTreeMap
/BTreeSet
are not currently supported as we still have to figure out a way to precisely measure their memory size and capacity. -
Regarding
union
s, we only support completely the special case of the single fieldunion
, for which we implement both the derive macrosMemSize
/MemDbg
. For the more complex cases of unions with multiple fields, we only provide theMemSize
derive macro with partial support, excluding support for theSizeFlags::FOLLOW_REFS
flag. If full support for derive macrosMemSize
/MemDbg
in the case of an union with multiple fields, one can implement the traits manually.