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|
/// Collects statistics about the SKS packet dump using the openpgp
/// crate, Sequoia's low-level API.
///
/// Note that to achieve reasonable performance, you need to compile
/// Sequoia and this program with optimizations:
///
/// % cargo run -p sequoia-openpgp --example statistics --release \
/// -- <packet-dump>
use std::env;
use std::collections::HashMap;
use anyhow::Context;
use sequoia_openpgp as openpgp;
use crate::openpgp::{Packet, Fingerprint, KeyID, KeyHandle};
use crate::openpgp::crypto::mpi;
use crate::openpgp::types::*;
use crate::openpgp::packet::{user_attribute, header::BodyLength, Tag};
use crate::openpgp::packet::signature::subpacket::SubpacketTag;
use crate::openpgp::parse::{Parse, PacketParserResult, PacketParser};
use crate::openpgp::serialize::MarshalInto;
fn main() -> openpgp::Result<()> {
let args: Vec<String> = env::args().collect();
if args.len() < 2 {
return Err(anyhow::anyhow!("Collects statistics about OpenPGP packet dumps.\n\n\
Usage: {} <packet-dump> [<packet-dump>...]\n", args[0]));
}
// Global stats.
let mut packet_count = 0;
let mut packet_size = 0 as usize;
// Per-tag statistics.
let mut tags_count = vec![0; 64];
let mut tags_unknown = vec![0; 64];
let mut tags_size_bytes = vec![0 as usize; 64];
let mut tags_size_count = vec![0; 64];
let mut tags_size_min = vec![::std::u32::MAX; 64];
let mut tags_size_max = vec![0; 64];
// Signature statistics.
let mut sigs_count = vec![0; 256];
let mut sigs_count_1st_party = vec![0; 256];
// Signature Subpacket statistics.
let mut sigs_subpacket_tags_count = vec![0; 256];
let mut sigs_subpacket_tags_unknown = vec![0; 256];
let mut sigs_subpacket_tags_size_bytes = vec![0 as usize; 256];
let mut sigs_subpacket_tags_size_count = vec![0; 256];
let mut sigs_subpacket_tags_size_min = vec![::std::u32::MAX; 256];
let mut sigs_subpacket_tags_size_max = vec![0; 256];
let mut sigs_subpacket_exportable_true = 0;
let mut sigs_subpacket_exportable_false = 0;
let mut sigs_subpacket_re_zero_terminated = 0;
let mut sigs_subpacket_re_inner_zero = 0;
// Per-Signature statistics.
let mut signature_min = PerSignature::max();
let mut signature_max = PerSignature::min();
// Various SubpacketValue-related counters.
let mut key_flags: HashMap<KeyFlags, usize> = Default::default();
let mut p_sym: HashMap<Vec<SymmetricAlgorithm>, usize> =
Default::default();
let mut p_hashes: HashMap<Vec<HashAlgorithm>, usize> =
Default::default();
let mut p_comp: HashMap<Vec<CompressionAlgorithm>, usize> =
Default::default();
let mut p_aead_ciphersuites: HashMap<Vec<(SymmetricAlgorithm, AEADAlgorithm)>, usize> =
Default::default();
// Per-Cert statistics.
let mut cert_count = 0;
let mut cert = PerCert::min();
let mut cert_min = PerCert::max();
let mut cert_max = PerCert::min();
// UserAttribute statistics.
let mut ua_image_count = vec![0; 256];
let mut ua_image_unknown_variant_count = 0;
let mut ua_unknown_count = vec![0; 256];
let mut ua_invalid_count = 0;
let mut ua_unknown_variant_count = 0;
// Key statistics.
let mut pk_algo_size: HashMap<PublicKeyAlgorithm, HashMap<usize, usize>> =
Default::default();
// ECDH Parameter (KDF and KEK) statistics.
let mut ecdh_params: HashMap<(HashAlgorithm, SymmetricAlgorithm), usize> =
Default::default();
let mut ecdh_params_by_curve: HashMap<(Curve, HashAlgorithm, SymmetricAlgorithm), usize> =
Default::default();
// Current certificate.
let mut current_fingerprint =
KeyHandle::Fingerprint(Fingerprint::from_bytes(4, &vec![0; 20])?);
let mut current_keyid = KeyHandle::KeyID(KeyID::wildcard());
// For each input file, create a parser.
for input in &args[1..] {
eprintln!("Parsing {}...", input);
let mut ppr = PacketParser::from_file(input)
.context("Failed to create reader")?;
// Iterate over all packets.
while let PacketParserResult::Some(pp) = ppr {
// While the packet is in the parser, get some data for later.
let size = match pp.header().length() {
&BodyLength::Full(n) => Some(n),
_ => None,
};
// Get the packet and advance the parser.
let (packet, tmp) = pp.next().context("Failed to get next packet")?;
ppr = tmp;
packet_count += 1;
if let Some(n) = size {
packet_size += n as usize;
}
let i = u8::from(packet.tag()) as usize;
tags_count[i] += 1;
match packet {
// If a new Cert starts, update Cert statistics.
Packet::PublicKey(ref k) => {
if cert_count > 0 {
cert.update_min_max(&mut cert_min, &mut cert_max);
}
cert_count += 1;
cert = PerCert::min();
current_fingerprint = k.fingerprint().into();
current_keyid = k.keyid().into();
},
Packet::SecretKey(ref k) => {
if cert_count > 0 {
cert.update_min_max(&mut cert_min, &mut cert_max);
}
cert_count += 1;
cert = PerCert::min();
current_fingerprint = k.fingerprint().into();
current_keyid = k.keyid().into();
},
Packet::Signature(ref sig) => {
sigs_count[u8::from(sig.typ()) as usize] += 1;
let issuers = sig.get_issuers();
if issuers.contains(¤t_keyid)
|| issuers.contains(¤t_fingerprint)
{
sigs_count_1st_party[u8::from(sig.typ()) as usize] += 1;
}
cert.sigs[u8::from(sig.typ()) as usize] += 1;
let mut signature = PerSignature::min();
for sub in sig.hashed_area().iter()
.chain(sig.unhashed_area().iter())
{
use crate::openpgp::packet::signature::subpacket::*;
let i = u8::from(sub.tag()) as usize;
sigs_subpacket_tags_count[i] += 1;
cert.sigs_subpacket_tags_count[i] += 1;
signature.subpacket_tags_count[i] += 1;
if let SubpacketValue::Unknown { .. } = sub.value() {
sigs_subpacket_tags_unknown
[u8::from(sub.tag()) as usize] += 1;
} else {
let len = sub.serialized_len();
sigs_subpacket_tags_size_bytes[i] += len;
sigs_subpacket_tags_size_count[i] += 1;
let len = len as u32;
if len < sigs_subpacket_tags_size_min[i] {
sigs_subpacket_tags_size_min[i] = len;
}
if len > sigs_subpacket_tags_size_max[i] {
sigs_subpacket_tags_size_max[i] = len;
}
#[allow(deprecated)]
match sub.value() {
SubpacketValue::Unknown { .. } =>
unreachable!(),
SubpacketValue::KeyFlags(k) =>
if let Some(count) = key_flags.get_mut(k) {
*count += 1;
} else {
key_flags.insert(k.clone(), 1);
},
SubpacketValue::PreferredSymmetricAlgorithms(a)
=>
if let Some(count) = p_sym.get_mut(a) {
*count += 1;
} else {
p_sym.insert(a.clone(), 1);
},
SubpacketValue::PreferredHashAlgorithms(a)
=>
if let Some(count) = p_hashes.get_mut(a) {
*count += 1;
} else {
p_hashes.insert(a.clone(), 1);
},
SubpacketValue::PreferredCompressionAlgorithms(a)
=>
if let Some(count) = p_comp.get_mut(a) {
*count += 1;
} else {
p_comp.insert(a.clone(), 1);
},
SubpacketValue::PreferredAEADCiphersuites(a)
=>
if let Some(count) = p_aead_ciphersuites.get_mut(a) {
*count += 1;
} else {
p_aead_ciphersuites.insert(a.clone(), 1);
},
SubpacketValue::ExportableCertification(v) =>
if *v {
sigs_subpacket_exportable_true += 1;
} else {
sigs_subpacket_exportable_false += 1;
},
SubpacketValue::RegularExpression(r) =>
if r.last() == Some(&0) {
sigs_subpacket_re_zero_terminated += 1;
} else if r.iter().any(|&b| b == 0) {
sigs_subpacket_re_inner_zero += 1;
},
_ => (),
}
}
}
signature.update_min_max(&mut signature_min,
&mut signature_max);
},
Packet::UserAttribute(ref ua) => {
use crate::user_attribute::Subpacket;
use crate::user_attribute::Image;
for subpacket in ua.subpackets() {
match subpacket {
Ok(Subpacket::Image(i)) => match i {
Image::JPEG(_) =>
ua_image_count[1] += 1,
Image::Private(n, _) =>
ua_image_count[n as usize] += 1,
Image::Unknown(n, _) =>
ua_image_count[n as usize] += 1,
_ =>
ua_image_unknown_variant_count += 1,
},
Ok(Subpacket::Unknown(n, _)) =>
ua_unknown_count[n as usize] += 1,
Ok(_) =>
ua_unknown_variant_count += 1,
Err(_) => ua_invalid_count += 1,
}
}
},
_ => (),
}
// Public key algorithm and size statistics.
let mut handle_key = |k: &openpgp::packet::Key<_, _>| {
let pk = k.pk_algo();
let bits = k.mpis().bits().unwrap_or(0);
if let Some(size_hash) = pk_algo_size.get_mut(&pk) {
if let Some(count) = size_hash.get_mut(&bits) {
*count = *count + 1;
} else {
size_hash.insert(bits, 1);
}
} else {
let mut size_hash: HashMap<usize, usize>
= Default::default();
size_hash.insert(bits, 1);
pk_algo_size.insert(pk, size_hash);
}
fn inc<T>(counter: &mut HashMap<T, usize>, key: T)
where
T: std::hash::Hash + Eq,
{
if let Some(count) = counter.get_mut(&key) {
*count += 1;
} else {
counter.insert(key, 1);
}
}
if let mpi::PublicKey::ECDH { curve, hash, sym, .. } = k.mpis() {
inc(&mut ecdh_params,
(hash.clone(), sym.clone()));
inc(&mut ecdh_params_by_curve,
(curve.clone(), hash.clone(), sym.clone()));
}
};
match packet {
Packet::PublicKey(ref k) =>
handle_key(k.parts_as_public().role_as_unspecified()),
Packet::SecretKey(ref k) =>
handle_key(k.parts_as_public().role_as_unspecified()),
Packet::PublicSubkey(ref k) =>
handle_key(k.parts_as_public().role_as_unspecified()),
Packet::SecretSubkey(ref k) =>
handle_key(k.parts_as_public().role_as_unspecified()),
_ => (),
}
if let Packet::Unknown(_) = packet {
tags_unknown[i] += 1;
} else {
// Only record size statistics of packets we successfully
// parsed.
if let Some(n) = size {
tags_size_bytes[i] += n as usize;
tags_size_count[i] += 1;
if n < tags_size_min[i] {
tags_size_min[i] = n;
}
if n > tags_size_max[i] {
tags_size_max[i] = n;
}
cert.bytes += n as usize;
}
cert.packets += 1;
cert.tags[i] += 1;
}
}
cert.update_min_max(&mut cert_min, &mut cert_max);
}
// Print statistics.
println!("# Packet statistics");
println!();
println!("{:>14} {:>9} {:>9} {:>9} {:>9} {:>9} {:>12}",
"", "count", "unknown",
"min size", "mean size", "max size", "sum size");
println!("-------------------------------------------------------\
-----------------------");
for t in 0..64 {
let count = tags_count[t];
if count > 0 {
println!("{:>14} {:>9} {:>9} {:>9} {:>9} {:>9} {:>12}",
format!("{:?}", Tag::from(t as u8)),
count,
tags_unknown[t],
tags_size_min[t],
tags_size_bytes[t] / tags_size_count[t],
tags_size_max[t],
tags_size_bytes[t]);
}
}
let signature_count = tags_count[u8::from(Tag::Signature) as usize];
if signature_count > 0 {
println!();
println!("# Signature statistics");
println!();
println!("{:>22} {:>9}",
"", "count",);
println!("--------------------------------");
for t in 0..256 {
let max = cert_max.sigs[t];
if max > 0 {
println!("{:>22} {:>9}",
format!("{:?}", SignatureType::from(t as u8)),
sigs_count[t]);
println!("{:>22} {:>9}", "1st party", sigs_count_1st_party[t]);
println!("{:>22} {:>9}", "3rd party",
sigs_count[t] - sigs_count_1st_party[t]);
}
}
println!();
println!("# Per-Signature Subpacket statistics");
println!();
println!("{:>30} {:>9} {:>9} {:>9}", "", "min", "mean", "max");
println!("----------------------------------------------------\
--------");
for t in 0..256 {
let max = signature_max.subpacket_tags_count[t];
if max > 0 {
println!("{:>30} {:>9} {:>9} {:>9}",
subpacket_short_name(t),
signature_min.subpacket_tags_count[t],
sigs_subpacket_tags_count[t] / signature_count,
max);
}
}
println!();
println!("# Signature Subpacket statistics");
println!();
println!("{:>30} {:>8} {:>6} {:>4} {:>4} {:>5} {:>14}",
"", "", "",
"min", "mean", "max", "sum");
println!("{:>30} {:>8} {:>6} {:>4} {:>4} {:>5} {:>14}",
"", "#", "?",
"size", "size", "size", "size");
println!("-------------------------------------------------------\
----------------------");
for t in 0..256 {
let count = sigs_subpacket_tags_count[t];
let size_count = sigs_subpacket_tags_size_count[t];
if size_count > 0 {
println!("{:>30} {:>8} {:>6} {:>4} {:>4} {:>5} {:>14}",
subpacket_short_name(t),
count,
sigs_subpacket_tags_unknown[t],
sigs_subpacket_tags_size_min[t],
sigs_subpacket_tags_size_bytes[t] / size_count,
sigs_subpacket_tags_size_max[t],
sigs_subpacket_tags_size_bytes[t]);
} else if count > 0 {
println!("{:>30} {:>8} {:>6} {:>4} {:>4} {:>5} {:>14}",
subpacket_short_name(t),
count,
sigs_subpacket_tags_unknown[t],
"-", "-", "-", "-");
}
match SubpacketTag::from(t as u8) {
SubpacketTag::ExportableCertification => {
if sigs_subpacket_exportable_true > 0 {
println!("{:>30} {:>8}",
"ExportableCertification(true)",
sigs_subpacket_exportable_true);
}
if sigs_subpacket_exportable_false > 0 {
println!("{:>30} {:>8}",
"ExportableCertification(false)",
sigs_subpacket_exportable_false);
}
},
SubpacketTag::RegularExpression => {
println!("{:>30} {:>8}",
"RegularExpression 0-terminated",
sigs_subpacket_re_zero_terminated);
println!("{:>30} {:>8}",
"RegularExpression inner 0",
sigs_subpacket_re_inner_zero);
},
_ => (),
}
}
}
if !key_flags.is_empty() {
println!();
println!("# KeyFlags statistics");
println!();
println!("{:>22} {:>9}", "", "count",);
println!("--------------------------------");
// Sort by the number of occurrences.
let mut kf = key_flags.iter().map(|(f, n)| (format!("{:?}", f), n))
.collect::<Vec<_>>();
kf.sort_unstable_by(|a, b| b.1.cmp(a.1));
for (f, n) in kf.iter() {
println!("{:>22} {:>9}", f, n);
}
}
if !p_sym.is_empty() {
println!();
println!("# PreferredSymmetricAlgorithms statistics");
println!();
println!("{:>70} {:>9}", "", "count",);
println!("----------------------------------------\
----------------------------------------");
// Sort by the number of occurrences.
let mut preferences = p_sym.iter().map(|(a, n)| {
let a = format!("{:?}", a);
(a[1..a.len()-1].to_string(), n)
}).collect::<Vec<_>>();
preferences.sort_unstable_by(|a, b| b.1.cmp(a.1));
for (a, n) in preferences {
println!("{:>70} {:>9}", a, n);
}
}
if !p_hashes.is_empty() {
println!();
println!("# PreferredHashlgorithms statistics");
println!();
println!("{:>70} {:>9}", "", "count",);
println!("----------------------------------------\
----------------------------------------");
// Sort by the number of occurrences.
let mut preferences = p_hashes.iter().map(|(a, n)| {
let a = format!("{:?}", a);
(a[1..a.len()-1].to_string(), n)
}).collect::<Vec<_>>();
preferences.sort_unstable_by(|a, b| b.1.cmp(a.1));
for (a, n) in preferences {
let a = format!("{:?}", a);
println!("{:>70} {:>9}", &a[1..a.len()-1], n);
}
}
if !p_comp.is_empty() {
println!();
println!("# PreferredCompressionAlgorithms statistics");
println!();
println!("{:>70} {:>9}", "", "count",);
println!("----------------------------------------\
----------------------------------------");
// Sort by the number of occurrences.
let mut preferences = p_comp.iter().map(|(a, n)| {
let a = format!("{:?}", a);
(a[1..a.len()-1].to_string(), n)
}).collect::<Vec<_>>();
preferences.sort_unstable_by(|a, b| b.1.cmp(a.1));
for (a, n) in preferences {
let a = format!("{:?}", a);
println!("{:>70} {:>9}", &a[1..a.len()-1], n);
}
}
if !p_aead_ciphersuites.is_empty() {
println!();
println!("# PreferredAEADCiphersuites statistics");
println!();
println!("{:>70} {:>9}", "", "count",);
println!("----------------------------------------\
----------------------------------------");
for (a, n) in p_aead_ciphersuites.iter() {
let a = format!("{:?}", a);
println!("{:>70} {:>9}", &a[1..a.len()-1], n);
}
}
if ua_invalid_count > 0
|| ua_image_count.iter().any(|c| *c > 0)
|| ua_unknown_count.iter().any(|c| *c > 0)
{
println!();
println!("# User Attribute Subpacket statistics");
println!();
println!("{:>21} {:>9}",
"", "count",);
println!("----------------------------");
for t in 0..256 {
let n = ua_image_count[t];
if n > 0 {
println!("{:>21} {:>9}",
match t {
1 => "Image::JPEG".into(),
100..=110 => format!("Image::Private({})", t),
_ => format!("Image::Unknown({})", t),
}, n);
}
}
if ua_image_unknown_variant_count > 0 {
println!("{:>21} {:>9}", "Unknown image variant",
ua_image_unknown_variant_count);
}
for t in 0..256 {
let n = ua_unknown_count[t];
if n > 0 {
println!("{:>21} {:>9}", format!("Unknown({})", t), n);
}
}
if ua_unknown_variant_count > 0 {
println!("{:>21} {:>9}", "Unknown variant",
ua_unknown_variant_count);
}
if ua_invalid_count > 0 {
println!("{:>21} {:>9}", "Invalid", ua_invalid_count);
}
}
if cert_count == 0 {
return Ok(());
}
println!();
println!("# Key statistics\n\n\
{:>50} {:>9} {:>9}",
"Algorithm", "Key Size", "count");
println!("----------------------------------------------------------------------");
for t in 0..255u8 {
let pk = PublicKeyAlgorithm::from(t);
if let Some(size_hash) = pk_algo_size.get(&pk) {
let mut sizes: Vec<_> = size_hash.iter().collect();
sizes.sort_by_key(|(size, _count)| *size);
for (size, count) in sizes {
println!("{:>50} {:>9} {:>9}", pk.to_string(), size, count);
}
}
}
if !ecdh_params.is_empty() {
println!();
println!("# ECDH Parameter statistics");
println!();
println!("{:>70} {:>9}", "", "count",);
println!("----------------------------------------\
----------------------------------------");
// Sort by the number of occurrences.
let mut params = ecdh_params.iter()
.map(|((hash, sym), count)| {
(format!("{:?}, {:?}", hash, sym), count)
}).collect::<Vec<_>>();
params.sort_unstable_by(|a, b| b.1.cmp(a.1));
for (a, n) in params {
println!("{:>70} {:>9}", a, n);
}
println!();
println!("# ECDH Parameter statistics by curve");
println!();
println!("{:>70} {:>9}", "", "count",);
println!("----------------------------------------\
----------------------------------------");
// Sort by the number of occurrences.
let mut params = ecdh_params_by_curve.iter()
.map(|((curve, hash, sym), count)| {
(format!("{:?}, {:?}, {:?}", curve, hash, sym), count)
}).collect::<Vec<_>>();
params.sort_unstable_by(|a, b| b.1.cmp(a.1));
for (a, n) in params {
println!("{:>70} {:>9}", a, n);
}
}
println!();
println!("# Cert statistics\n\n\
{:>30} {:>9} {:>9} {:>9}",
"", "min", "mean", "max");
println!("------------------------------------------------------------");
println!("{:>30} {:>9} {:>9} {:>9}",
"Size (packets)",
cert_min.packets, packet_count / cert_count, cert_max.packets);
println!("{:>30} {:>9} {:>9} {:>9}",
"Size (bytes)",
cert_min.bytes, packet_size / cert_count, cert_max.bytes);
println!("\n{:>30}", "- Packets -");
for t in 0..64 {
let max = cert_max.tags[t];
if t as u8 != Tag::PublicKey.into() && max > 0 {
println!("{:>30} {:>9} {:>9} {:>9}",
format!("{:?}", Tag::from(t as u8)),
cert_min.tags[t],
tags_count[t] / cert_count,
max);
}
}
println!("\n{:>30}", "- Signatures -");
for t in 0..256 {
let max = cert_max.sigs[t];
if max > 0 {
println!("{:>30} {:>9} {:>9} {:>9}",
format!("{:?}",
SignatureType::from(t as u8)),
cert_min.sigs[t],
sigs_count[t] / cert_count,
max);
}
}
println!("\n{:>30}", "- Signature Subpackets -");
for t in 0..256 {
let max = cert_max.sigs_subpacket_tags_count[t];
if max > 0 {
println!("{:>30} {:>9} {:>9} {:>9}",
subpacket_short_name(t),
cert_min.sigs_subpacket_tags_count[t],
sigs_subpacket_tags_count[t] / cert_count,
max);
}
}
Ok(())
}
fn subpacket_short_name(t: usize) -> String {
let tag_name = format!("{:?}", SubpacketTag::from(t as u8));
String::from_utf8_lossy(
tag_name.as_bytes().chunks(30).next().unwrap()).into()
}
struct PerCert {
packets: usize,
bytes: usize,
tags: Vec<u32>,
sigs: Vec<u32>,
sigs_subpacket_tags_count: Vec<u32>,
}
impl PerCert {
fn min() -> Self {
PerCert {
packets: 0,
bytes: 0,
tags: vec![0; 64],
sigs: vec![0; 256],
sigs_subpacket_tags_count: vec![0; 256],
}
}
fn max() -> Self {
PerCert {
packets: ::std::usize::MAX,
bytes: ::std::usize::MAX,
tags: vec![::std::u32::MAX; 64],
sigs: vec![::std::u32::MAX; 256],
sigs_subpacket_tags_count: vec![::std::u32::MAX; 256],
}
}
fn update_min_max(&self, min: &mut PerCert, max: &mut PerCert) {
if self.packets < min.packets {
min.packets = self.packets;
}
if self.packets > max.packets {
max.packets = self.packets;
}
if self.bytes < min.bytes {
min.bytes = self.bytes;
}
if self.bytes > max.bytes {
max.bytes = self.bytes;
}
for i in 0..64 {
if self.tags[i] < min.tags[i] {
min.tags[i] = self.tags[i];
}
if self.tags[i] > max.tags[i] {
max.tags[i] = self.tags[i];
}
}
for i in 0..256 {
if self.sigs[i] < min.sigs[i] {
min.sigs[i] = self.sigs[i];
}
if self.sigs[i] > max.sigs[i] {
max.sigs[i] = self.sigs[i];
}
}
for i in 0..256 {
if self.sigs_subpacket_tags_count[i] < min.sigs_subpacket_tags_count[i] {
min.sigs_subpacket_tags_count[i] = self.sigs_subpacket_tags_count[i];
}
if self.sigs_subpacket_tags_count[i] > max.sigs_subpacket_tags_count[i] {
max.sigs_subpacket_tags_count[i] = self.sigs_subpacket_tags_count[i];
}
}
}
}
struct PerSignature {
subpacket_tags_count: Vec<u32>,
}
impl PerSignature {
fn min() -> Self {
PerSignature {
subpacket_tags_count: vec![0; 256],
}
}
fn max() -> Self {
PerSignature {
subpacket_tags_count: vec![::std::u32::MAX; 256],
}
}
fn update_min_max(&self, min: &mut PerSignature, max: &mut PerSignature) {
for i in 0..256 {
if self.subpacket_tags_count[i] < min.subpacket_tags_count[i] {
min.subpacket_tags_count[i] = self.subpacket_tags_count[i];
}
if self.subpacket_tags_count[i] > max.subpacket_tags_count[i] {
max.subpacket_tags_count[i] = self.subpacket_tags_count[i];
}
}
}
}
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