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HeaderTable
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staticTable: HeaderField[]
-
STATIC_TABLE_LENGTH: int
-
ENTRY_SIZE: int
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staticIndexes: Map<String, LinkedHashMap<String, Integer>>
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static class initializer
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dynamicTable: Table
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maxSize: int
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size: int
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HeaderTable(int): void
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indexOf(CharSequence, CharSequence): int
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size(): int
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maxSize(): int
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length(): int
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get(int): HeaderField
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put(CharSequence, CharSequence): void
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put(HeaderField): void
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setMaxSize(int): void
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evictEntry(): HeaderField
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toString(): String
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checkIndex(int): int
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sizeOf(HeaderField): int
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getStateString(): String
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HeaderField
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Table
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CircularBuffer
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https://projects.eclipse.org/projects/ee4j.grizzly/grizzly-http2: Grizzly Bill of Materials (BOM)
(Oracle Corporation)
- Jeanfrancois Arcand (Async IO)
- Justin Lee
- Marc Arens (Open Xchange)
- Matt Swift
/*
* Copyright (c) 2016, 2017 Oracle and/or its affiliates. All rights reserved.
*
* This program and the accompanying materials are made available under the
* terms of the Eclipse Public License v. 2.0, which is available at
* http://www.eclipse.org/legal/epl-2.0.
*
* This Source Code may also be made available under the following Secondary
* Licenses when the conditions for such availability set forth in the
* Eclipse Public License v. 2.0 are satisfied: GNU General Public License,
* version 2 with the GNU Classpath Exception, which is available at
* https://www.gnu.org/software/classpath/license.html.
*
* SPDX-License-Identifier: EPL-2.0 OR GPL-2.0 WITH Classpath-exception-2.0
*/
package org.glassfish.grizzly.http2.hpack;
import java.util.HashMap;
import java.util.LinkedHashMap;
import java.util.Map;
import java.util.NoSuchElementException;
import static java.lang.String.format;
//
// Header Table combined from two tables: static and dynamic.
//
// There is a single address space for index values. Index-aware methods
// correspond to the table as a whole. Size-aware methods only to the dynamic
// part of it.
//
final class HeaderTable {
private static final HeaderField[] staticTable = {
null, // To make index 1-based, instead of 0-based
new HeaderField(":authority"),
new HeaderField(":method", "GET"),
new HeaderField(":method", "POST"),
new HeaderField(":path", "/"),
new HeaderField(":path", "/index.html"),
new HeaderField(":scheme", "http"),
new HeaderField(":scheme", "https"),
new HeaderField(":status", "200"),
new HeaderField(":status", "204"),
new HeaderField(":status", "206"),
new HeaderField(":status", "304"),
new HeaderField(":status", "400"),
new HeaderField(":status", "404"),
new HeaderField(":status", "500"),
new HeaderField("accept-charset"),
new HeaderField("accept-encoding", "gzip, deflate"),
new HeaderField("accept-language"),
new HeaderField("accept-ranges"),
new HeaderField("accept"),
new HeaderField("access-control-allow-origin"),
new HeaderField("age"),
new HeaderField("allow"),
new HeaderField("authorization"),
new HeaderField("cache-control"),
new HeaderField("content-disposition"),
new HeaderField("content-encoding"),
new HeaderField("content-language"),
new HeaderField("content-length"),
new HeaderField("content-location"),
new HeaderField("content-range"),
new HeaderField("content-type"),
new HeaderField("cookie"),
new HeaderField("date"),
new HeaderField("etag"),
new HeaderField("expect"),
new HeaderField("expires"),
new HeaderField("from"),
new HeaderField("host"),
new HeaderField("if-match"),
new HeaderField("if-modified-since"),
new HeaderField("if-none-match"),
new HeaderField("if-range"),
new HeaderField("if-unmodified-since"),
new HeaderField("last-modified"),
new HeaderField("link"),
new HeaderField("location"),
new HeaderField("max-forwards"),
new HeaderField("proxy-authenticate"),
new HeaderField("proxy-authorization"),
new HeaderField("range"),
new HeaderField("referer"),
new HeaderField("refresh"),
new HeaderField("retry-after"),
new HeaderField("server"),
new HeaderField("set-cookie"),
new HeaderField("strict-transport-security"),
new HeaderField("transfer-encoding"),
new HeaderField("user-agent"),
new HeaderField("vary"),
new HeaderField("via"),
new HeaderField("www-authenticate")
};
private static final int STATIC_TABLE_LENGTH = staticTable.length - 1;
private static final int ENTRY_SIZE = 32;
private static final Map<String, LinkedHashMap<String, Integer>> staticIndexes;
static {
staticIndexes = new HashMap<>(STATIC_TABLE_LENGTH);
for (int i = 1; i <= STATIC_TABLE_LENGTH; i++) {
HeaderField f = staticTable[i];
LinkedHashMap<String,Integer> values = staticIndexes.get(f.name);
if (values == null) {
values = new LinkedHashMap<>();
values.put(f.value, i);
}
staticIndexes.put(f.name, values);
}
}
private final Table dynamicTable = new Table(0);
private int maxSize;
private int size;
public HeaderTable(int maxSize) {
setMaxSize(maxSize);
}
//
// The method returns:
//
// * a positive integer i where i (i = [1..Integer.MAX_VALUE]) is an
// index of an entry with a header (n, v), where n.equals(name) &&
// v.equals(value)
//
// * a negative integer j where j (j = [-Integer.MAX_VALUE..-1]) is an
// index of an entry with a header (n, v), where n.equals(name)
//
// * 0 if there's no entry e such that e.getName().equals(name)
//
// The rationale behind this design is to allow to pack more useful data
// into a single invocation, facilitating a single pass where possible
// (the idea is the same as in java.util.Arrays.binarySearch(int[], int)).
//
public int indexOf(CharSequence name, CharSequence value) {
// Invoking toString() will possibly allocate Strings for the sake of
// the search, which doesn't feel right.
String n = name.toString();
String v = value.toString();
// 1. Try exact match in the static region
Map<String, Integer> values = staticIndexes.get(n);
if (values != null) {
Integer idx = values.get(v);
if (idx != null) {
return idx;
}
}
// 2. Try exact match in the dynamic region
int didx = dynamicTable.indexOf(n, v);
if (didx > 0) {
return STATIC_TABLE_LENGTH + didx;
} else if (didx < 0) {
if (values != null) {
// 3. Return name match from the static region
return -values.values().iterator().next(); // Iterator allocation
} else {
// 4. Return name match from the dynamic region
return -STATIC_TABLE_LENGTH + didx;
}
} else {
if (values != null) {
// 3. Return name match from the static region
return -values.values().iterator().next(); // Iterator allocation
} else {
return 0;
}
}
}
public int size() {
return size;
}
@SuppressWarnings("unused")
public int maxSize() {
return maxSize;
}
public int length() {
return STATIC_TABLE_LENGTH + dynamicTable.size();
}
HeaderField get(int index) {
checkIndex(index);
if (index <= STATIC_TABLE_LENGTH) {
return staticTable[index];
} else {
return dynamicTable.get(index - STATIC_TABLE_LENGTH);
}
}
void put(CharSequence name, CharSequence value) {
// Invoking toString() will possibly allocate Strings. But that's
// unavoidable at this stage. If a CharSequence is going to be stored in
// the table, it must not be mutable (e.g. for the sake of hashing).
put(new HeaderField(name.toString(), value.toString()));
}
private void put(HeaderField h) {
int entrySize = sizeOf(h);
while (entrySize > maxSize - size && size != 0) {
evictEntry();
}
if (entrySize > maxSize - size) {
return;
}
size += entrySize;
dynamicTable.add(h);
}
void setMaxSize(int maxSize) {
if (maxSize < 0) {
throw new IllegalArgumentException
("maxSize >= 0: maxSize=" + maxSize);
}
while (maxSize < size && size != 0) {
evictEntry();
}
this.maxSize = maxSize;
int upperBound = (maxSize / ENTRY_SIZE) + 1;
this.dynamicTable.setCapacity(upperBound);
}
HeaderField evictEntry() {
HeaderField f = dynamicTable.remove();
size -= sizeOf(f);
return f;
}
@Override
public String toString() {
double used = maxSize == 0 ? 0 : 100 * (((double) size) / maxSize);
return format("entries: %d; used %s/%s (%.1f%%)", dynamicTable.size(),
size, maxSize, used);
}
int checkIndex(int index) {
if (index < 1 || index > STATIC_TABLE_LENGTH + dynamicTable.size()) {
throw new IllegalArgumentException(
format("1 <= index <= length(): index=%s, length()=%s",
index, length()));
}
return index;
}
int sizeOf(HeaderField f) {
return f.name.length() + f.value.length() + ENTRY_SIZE;
}
//
// Diagnostic information in the form used in the RFC 7541
//
@SuppressWarnings("unused")
String getStateString() {
if (size == 0) {
return "empty.";
}
StringBuilder b = new StringBuilder();
for (int i = 1, size = dynamicTable.size(); i <= size; i++) {
HeaderField e = dynamicTable.get(i);
b.append(format("[%3d] (s = %3d) %s: %s%n", i,
sizeOf(e), e.name, e.value));
}
b.append(format(" Table size:%4s", this.size));
return b.toString();
}
// Convert to a Value Object (JDK-8046159)?
static final class HeaderField {
final String name;
final String value;
public HeaderField(String name) {
this(name, "");
}
public HeaderField(String name, String value) {
this.name = name;
this.value = value;
}
@Override
public String toString() {
return value.isEmpty() ? name : name + ": " + value;
}
@Override
public boolean equals(Object o) {
if (this == o) {
return true;
}
if (o == null || getClass() != o.getClass()) {
return false;
}
HeaderField that = (HeaderField) o;
return name.equals(that.name) && value.equals(that.value);
}
@Override
public int hashCode() {
return 31 * name.hashCode() + value.hashCode();
}
}
//
// To quickly find an index of an entry in the dynamic table with the given
// contents an effective inverse mapping is needed. Here's a simple idea
// behind such a mapping.
//
// # The problem:
//
// We have a queue with an O(1) lookup by index:
//
// get: index -> x
//
// What we want is an O(1) reverse lookup:
//
// indexOf: x -> index
//
// # Solution:
//
// Let's store an inverse mapping in a Map<x, Integer>. This have a problem
// that when a new element is added to the queue, all indexes in the map
// become invalid. Namely, the new element is assigned with an index of 1,
// and each index i, i > 1 becomes shifted by 1 to the left:
//
// 1, 1, 2, 3, ... , n-1, n
//
// Re-establishing the invariant would seem to require a pass through the
// map incrementing all indexes (map values) by 1, which is O(n).
//
// The good news is we can do much better then this!
//
// Let's create a single field of type long, called 'counter'. Then each
// time a new element 'x' is added to the queue, a value of this field gets
// incremented. Then the resulting value of the 'counter_x' is then put as a
// value under key 'x' to the map:
//
// map.put(x, counter_x)
//
// It gives us a map that maps an element to a value the counter had at the
// time the element had been added.
//
// In order to retrieve an index of any element 'x' in the queue (at any
// given time) we simply need to subtract the value (the snapshot of the
// counter at the time when the 'x' was added) from the current value of the
// counter. This operation basically answers the question:
//
// How many elements ago 'x' was the tail of the queue?
//
// Which is the same as its index in the queue now. Given, of course, it's
// still in the queue.
//
// I'm pretty sure in a real life long overflow will never happen, so it's
// not too practical to add recalibrating code, but a pedantic person might
// want to do so:
//
// if (counter == Long.MAX_VALUE) {
// recalibrate();
// }
//
// Where 'recalibrate()' goes through the table doing this:
//
// value -= counter
//
// That's given, of course, the size of the table itself is less than
// Long.MAX_VALUE :-)
//
private static final class Table {
private final Map<String, Map<String, Long>> map;
private final CircularBuffer<HeaderField> buffer;
private long counter = 1;
Table(int capacity) {
buffer = new CircularBuffer<>(capacity);
map = new HashMap<>(capacity);
}
void add(HeaderField f) {
buffer.add(f);
Map<String, Long> values = map.get(f.name);
if (values == null) {
values = new HashMap<>();
values.put(f.value, counter++);
}
map.put(f.name, values);
}
HeaderField get(int index) {
return buffer.get(index - 1);
}
int indexOf(String name, String value) {
Map<String, Long> values = map.get(name);
if (values == null) {
return 0;
}
Long index = values.get(value);
if (index != null) {
return (int) (counter - index);
} else {
assert !values.isEmpty();
Long any = values.values().iterator().next(); // Iterator allocation
return -(int) (counter - any);
}
}
HeaderField remove() {
HeaderField f = buffer.remove();
Map<String, Long> values = map.get(f.name);
Long index = values.remove(f.value);
assert index != null;
if (values.isEmpty()) {
map.remove(f.name);
}
return f;
}
int size() {
return buffer.size;
}
public void setCapacity(int capacity) {
buffer.resize(capacity);
}
}
// head
// v
// [ ][ ][A][B][C][D][ ][ ][ ]
// ^
// tail
//
// |<- size ->| (4)
// |<------ capacity ------->| (9)
//
static final class CircularBuffer<E> {
int tail, head, size, capacity;
Object[] elements;
CircularBuffer(int capacity) {
this.capacity = capacity;
elements = new Object[capacity];
}
void add(E elem) {
if (size == capacity) {
throw new IllegalStateException(
format("No room for '%s': capacity=%s", elem, capacity));
}
elements[head] = elem;
head = (head + 1) % capacity;
size++;
}
@SuppressWarnings("unchecked")
E remove() {
if (size == 0) {
throw new NoSuchElementException("Empty");
}
E elem = (E) elements[tail];
elements[tail] = null;
tail = (tail + 1) % capacity;
size--;
return elem;
}
@SuppressWarnings("unchecked")
E get(int index) {
if (index < 0 || index >= size) {
throw new IndexOutOfBoundsException(
format("0 <= index <= capacity: index=%s, capacity=%s",
index, capacity));
}
int idx = (tail + (size - index - 1)) % capacity;
return (E) elements[idx];
}
public void resize(int newCapacity) {
if (newCapacity < size) {
throw new IllegalStateException(
format("newCapacity >= size: newCapacity=%s, size=%s",
newCapacity, size));
}
Object[] newElements = new Object[newCapacity];
if (tail < head || size == 0) {
System.arraycopy(elements, tail, newElements, 0, size);
} else {
System.arraycopy(elements, tail, newElements, 0, elements.length - tail);
System.arraycopy(elements, 0, newElements, elements.length - tail, head);
}
elements = newElements;
tail = 0;
head = size;
this.capacity = newCapacity;
}
}
}