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update dependencies to point to latest k8s api release (#4157)

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Tariq Ibrahim 2018-11-05 14:08:00 -08:00 коммит произвёл Jack Francis
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Коммит b23fd663a8
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113
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@ -144,6 +144,14 @@
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@ -323,6 +351,22 @@
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@ -379,10 +423,11 @@
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"html",
"html/atom",
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@ -394,6 +439,17 @@
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@ -503,7 +575,8 @@
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@ -517,10 +590,12 @@
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@ -530,17 +605,18 @@
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@ -569,6 +645,7 @@
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"pkg/util/net",
"pkg/util/runtime",
"pkg/util/sets",
@ -581,11 +658,10 @@
"third_party/forked/golang/reflect",
]
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@ -602,10 +678,12 @@
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"kubernetes/typed/core/v1",
"kubernetes/typed/events/v1beta1",
"kubernetes/typed/extensions/v1beta1",
@ -615,12 +693,14 @@
"kubernetes/typed/rbac/v1alpha1",
"kubernetes/typed/rbac/v1beta1",
"kubernetes/typed/scheduling/v1alpha1",
"kubernetes/typed/scheduling/v1beta1",
"kubernetes/typed/settings/v1alpha1",
"kubernetes/typed/storage/v1",
"kubernetes/typed/storage/v1alpha1",
"kubernetes/typed/storage/v1beta1",
"pkg/apis/clientauthentication",
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"pkg/apis/clientauthentication/v1beta1",
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@ -634,13 +714,14 @@
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"transport",
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"util/flowcontrol",
"util/homedir",
"util/integer",
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version = "v7.0.0"
revision = "1638f8970cefaa404ff3a62950f88b08292b2696"
version = "v9.0.0"
[solve-meta]
analyzer-name = "dep"

10
Gopkg.toml
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@ -98,17 +98,9 @@ required = [
name = "gopkg.in/yaml.v2"
version = "2.0.0"
[[constraint]]
name = "k8s.io/api"
version = "kubernetes-1.10.0"
[[constraint]]
name = "k8s.io/apimachinery"
version = "kubernetes-1.10.0"
[[constraint]]
name = "k8s.io/client-go"
version = "~7.0.0"
version = "v9.0.0"
[[constraint]]
name = "github.com/onsi/ginkgo"

1
vendor/github.com/google/btree/.travis.yml сгенерированный поставляемый Normal file
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@ -0,0 +1 @@
language: go

202
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@ -0,0 +1,202 @@
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vendor/github.com/google/btree/README.md сгенерированный поставляемый Normal file
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@ -0,0 +1,12 @@
# BTree implementation for Go
![Travis CI Build Status](https://api.travis-ci.org/google/btree.svg?branch=master)
This package provides an in-memory B-Tree implementation for Go, useful as
an ordered, mutable data structure.
The API is based off of the wonderful
http://godoc.org/github.com/petar/GoLLRB/llrb, and is meant to allow btree to
act as a drop-in replacement for gollrb trees.
See http://godoc.org/github.com/google/btree for documentation.

890
vendor/github.com/google/btree/btree.go сгенерированный поставляемый Normal file
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// Copyright 2014 Google Inc.
//
// 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.
// Package btree implements in-memory B-Trees of arbitrary degree.
//
// btree implements an in-memory B-Tree for use as an ordered data structure.
// It is not meant for persistent storage solutions.
//
// It has a flatter structure than an equivalent red-black or other binary tree,
// which in some cases yields better memory usage and/or performance.
// See some discussion on the matter here:
// http://google-opensource.blogspot.com/2013/01/c-containers-that-save-memory-and-time.html
// Note, though, that this project is in no way related to the C++ B-Tree
// implementation written about there.
//
// Within this tree, each node contains a slice of items and a (possibly nil)
// slice of children. For basic numeric values or raw structs, this can cause
// efficiency differences when compared to equivalent C++ template code that
// stores values in arrays within the node:
// * Due to the overhead of storing values as interfaces (each
// value needs to be stored as the value itself, then 2 words for the
// interface pointing to that value and its type), resulting in higher
// memory use.
// * Since interfaces can point to values anywhere in memory, values are
// most likely not stored in contiguous blocks, resulting in a higher
// number of cache misses.
// These issues don't tend to matter, though, when working with strings or other
// heap-allocated structures, since C++-equivalent structures also must store
// pointers and also distribute their values across the heap.
//
// This implementation is designed to be a drop-in replacement to gollrb.LLRB
// trees, (http://github.com/petar/gollrb), an excellent and probably the most
// widely used ordered tree implementation in the Go ecosystem currently.
// Its functions, therefore, exactly mirror those of
// llrb.LLRB where possible. Unlike gollrb, though, we currently don't
// support storing multiple equivalent values.
package btree
import (
"fmt"
"io"
"sort"
"strings"
"sync"
)
// Item represents a single object in the tree.
type Item interface {
// Less tests whether the current item is less than the given argument.
//
// This must provide a strict weak ordering.
// If !a.Less(b) && !b.Less(a), we treat this to mean a == b (i.e. we can only
// hold one of either a or b in the tree).
Less(than Item) bool
}
const (
DefaultFreeListSize = 32
)
var (
nilItems = make(items, 16)
nilChildren = make(children, 16)
)
// FreeList represents a free list of btree nodes. By default each
// BTree has its own FreeList, but multiple BTrees can share the same
// FreeList.
// Two Btrees using the same freelist are safe for concurrent write access.
type FreeList struct {
mu sync.Mutex
freelist []*node
}
// NewFreeList creates a new free list.
// size is the maximum size of the returned free list.
func NewFreeList(size int) *FreeList {
return &FreeList{freelist: make([]*node, 0, size)}
}
func (f *FreeList) newNode() (n *node) {
f.mu.Lock()
index := len(f.freelist) - 1
if index < 0 {
f.mu.Unlock()
return new(node)
}
n = f.freelist[index]
f.freelist[index] = nil
f.freelist = f.freelist[:index]
f.mu.Unlock()
return
}
// freeNode adds the given node to the list, returning true if it was added
// and false if it was discarded.
func (f *FreeList) freeNode(n *node) (out bool) {
f.mu.Lock()
if len(f.freelist) < cap(f.freelist) {
f.freelist = append(f.freelist, n)
out = true
}
f.mu.Unlock()
return
}
// ItemIterator allows callers of Ascend* to iterate in-order over portions of
// the tree. When this function returns false, iteration will stop and the
// associated Ascend* function will immediately return.
type ItemIterator func(i Item) bool
// New creates a new B-Tree with the given degree.
//
// New(2), for example, will create a 2-3-4 tree (each node contains 1-3 items
// and 2-4 children).
func New(degree int) *BTree {
return NewWithFreeList(degree, NewFreeList(DefaultFreeListSize))
}
// NewWithFreeList creates a new B-Tree that uses the given node free list.
func NewWithFreeList(degree int, f *FreeList) *BTree {
if degree <= 1 {
panic("bad degree")
}
return &BTree{
degree: degree,
cow: &copyOnWriteContext{freelist: f},
}
}
// items stores items in a node.
type items []Item
// insertAt inserts a value into the given index, pushing all subsequent values
// forward.
func (s *items) insertAt(index int, item Item) {
*s = append(*s, nil)
if index < len(*s) {
copy((*s)[index+1:], (*s)[index:])
}
(*s)[index] = item
}
// removeAt removes a value at a given index, pulling all subsequent values
// back.
func (s *items) removeAt(index int) Item {
item := (*s)[index]
copy((*s)[index:], (*s)[index+1:])
(*s)[len(*s)-1] = nil
*s = (*s)[:len(*s)-1]
return item
}
// pop removes and returns the last element in the list.
func (s *items) pop() (out Item) {
index := len(*s) - 1
out = (*s)[index]
(*s)[index] = nil
*s = (*s)[:index]
return
}
// truncate truncates this instance at index so that it contains only the
// first index items. index must be less than or equal to length.
func (s *items) truncate(index int) {
var toClear items
*s, toClear = (*s)[:index], (*s)[index:]
for len(toClear) > 0 {
toClear = toClear[copy(toClear, nilItems):]
}
}
// find returns the index where the given item should be inserted into this
// list. 'found' is true if the item already exists in the list at the given
// index.
func (s items) find(item Item) (index int, found bool) {
i := sort.Search(len(s), func(i int) bool {
return item.Less(s[i])
})
if i > 0 && !s[i-1].Less(item) {
return i - 1, true
}
return i, false
}
// children stores child nodes in a node.
type children []*node
// insertAt inserts a value into the given index, pushing all subsequent values
// forward.
func (s *children) insertAt(index int, n *node) {
*s = append(*s, nil)
if index < len(*s) {
copy((*s)[index+1:], (*s)[index:])
}
(*s)[index] = n
}
// removeAt removes a value at a given index, pulling all subsequent values
// back.
func (s *children) removeAt(index int) *node {
n := (*s)[index]
copy((*s)[index:], (*s)[index+1:])
(*s)[len(*s)-1] = nil
*s = (*s)[:len(*s)-1]
return n
}
// pop removes and returns the last element in the list.
func (s *children) pop() (out *node) {
index := len(*s) - 1
out = (*s)[index]
(*s)[index] = nil
*s = (*s)[:index]
return
}
// truncate truncates this instance at index so that it contains only the
// first index children. index must be less than or equal to length.
func (s *children) truncate(index int) {
var toClear children
*s, toClear = (*s)[:index], (*s)[index:]
for len(toClear) > 0 {
toClear = toClear[copy(toClear, nilChildren):]
}
}
// node is an internal node in a tree.
//
// It must at all times maintain the invariant that either
// * len(children) == 0, len(items) unconstrained
// * len(children) == len(items) + 1
type node struct {
items items
children children
cow *copyOnWriteContext
}
func (n *node) mutableFor(cow *copyOnWriteContext) *node {
if n.cow == cow {
return n
}
out := cow.newNode()
if cap(out.items) >= len(n.items) {
out.items = out.items[:len(n.items)]
} else {
out.items = make(items, len(n.items), cap(n.items))
}
copy(out.items, n.items)
// Copy children
if cap(out.children) >= len(n.children) {
out.children = out.children[:len(n.children)]
} else {
out.children = make(children, len(n.children), cap(n.children))
}
copy(out.children, n.children)
return out
}
func (n *node) mutableChild(i int) *node {
c := n.children[i].mutableFor(n.cow)
n.children[i] = c
return c
}
// split splits the given node at the given index. The current node shrinks,
// and this function returns the item that existed at that index and a new node
// containing all items/children after it.
func (n *node) split(i int) (Item, *node) {
item := n.items[i]
next := n.cow.newNode()
next.items = append(next.items, n.items[i+1:]...)
n.items.truncate(i)
if len(n.children) > 0 {
next.children = append(next.children, n.children[i+1:]...)
n.children.truncate(i + 1)
}
return item, next
}
// maybeSplitChild checks if a child should be split, and if so splits it.
// Returns whether or not a split occurred.
func (n *node) maybeSplitChild(i, maxItems int) bool {
if len(n.children[i].items) < maxItems {
return false
}
first := n.mutableChild(i)
item, second := first.split(maxItems / 2)
n.items.insertAt(i, item)
n.children.insertAt(i+1, second)
return true
}
// insert inserts an item into the subtree rooted at this node, making sure
// no nodes in the subtree exceed maxItems items. Should an equivalent item be
// be found/replaced by insert, it will be returned.
func (n *node) insert(item Item, maxItems int) Item {
i, found := n.items.find(item)
if found {
out := n.items[i]
n.items[i] = item
return out
}
if len(n.children) == 0 {
n.items.insertAt(i, item)
return nil
}
if n.maybeSplitChild(i, maxItems) {
inTree := n.items[i]
switch {
case item.Less(inTree):
// no change, we want first split node
case inTree.Less(item):
i++ // we want second split node
default:
out := n.items[i]
n.items[i] = item
return out
}
}
return n.mutableChild(i).insert(item, maxItems)
}
// get finds the given key in the subtree and returns it.
func (n *node) get(key Item) Item {
i, found := n.items.find(key)
if found {
return n.items[i]
} else if len(n.children) > 0 {
return n.children[i].get(key)
}
return nil
}
// min returns the first item in the subtree.
func min(n *node) Item {
if n == nil {
return nil
}
for len(n.children) > 0 {
n = n.children[0]
}
if len(n.items) == 0 {
return nil
}
return n.items[0]
}
// max returns the last item in the subtree.
func max(n *node) Item {
if n == nil {
return nil
}
for len(n.children) > 0 {
n = n.children[len(n.children)-1]
}
if len(n.items) == 0 {
return nil
}
return n.items[len(n.items)-1]
}
// toRemove details what item to remove in a node.remove call.
type toRemove int
const (
removeItem toRemove = iota // removes the given item
removeMin // removes smallest item in the subtree
removeMax // removes largest item in the subtree
)
// remove removes an item from the subtree rooted at this node.
func (n *node) remove(item Item, minItems int, typ toRemove) Item {
var i int
var found bool
switch typ {
case removeMax:
if len(n.children) == 0 {
return n.items.pop()
}
i = len(n.items)
case removeMin:
if len(n.children) == 0 {
return n.items.removeAt(0)
}
i = 0
case removeItem:
i, found = n.items.find(item)
if len(n.children) == 0 {
if found {
return n.items.removeAt(i)
}
return nil
}
default:
panic("invalid type")
}
// If we get to here, we have children.
if len(n.children[i].items) <= minItems {
return n.growChildAndRemove(i, item, minItems, typ)
}
child := n.mutableChild(i)
// Either we had enough items to begin with, or we've done some
// merging/stealing, because we've got enough now and we're ready to return
// stuff.
if found {
// The item exists at index 'i', and the child we've selected can give us a
// predecessor, since if we've gotten here it's got > minItems items in it.
out := n.items[i]
// We use our special-case 'remove' call with typ=maxItem to pull the
// predecessor of item i (the rightmost leaf of our immediate left child)
// and set it into where we pulled the item from.
n.items[i] = child.remove(nil, minItems, removeMax)
return out
}
// Final recursive call. Once we're here, we know that the item isn't in this
// node and that the child is big enough to remove from.
return child.remove(item, minItems, typ)
}
// growChildAndRemove grows child 'i' to make sure it's possible to remove an
// item from it while keeping it at minItems, then calls remove to actually
// remove it.
//
// Most documentation says we have to do two sets of special casing:
// 1) item is in this node
// 2) item is in child
// In both cases, we need to handle the two subcases:
// A) node has enough values that it can spare one
// B) node doesn't have enough values
// For the latter, we have to check:
// a) left sibling has node to spare
// b) right sibling has node to spare
// c) we must merge
// To simplify our code here, we handle cases #1 and #2 the same:
// If a node doesn't have enough items, we make sure it does (using a,b,c).
// We then simply redo our remove call, and the second time (regardless of
// whether we're in case 1 or 2), we'll have enough items and can guarantee
// that we hit case A.
func (n *node) growChildAndRemove(i int, item Item, minItems int, typ toRemove) Item {
if i > 0 && len(n.children[i-1].items) > minItems {
// Steal from left child
child := n.mutableChild(i)
stealFrom := n.mutableChild(i - 1)
stolenItem := stealFrom.items.pop()
child.items.insertAt(0, n.items[i-1])
n.items[i-1] = stolenItem
if len(stealFrom.children) > 0 {
child.children.insertAt(0, stealFrom.children.pop())
}
} else if i < len(n.items) && len(n.children[i+1].items) > minItems {
// steal from right child
child := n.mutableChild(i)
stealFrom := n.mutableChild(i + 1)
stolenItem := stealFrom.items.removeAt(0)
child.items = append(child.items, n.items[i])
n.items[i] = stolenItem
if len(stealFrom.children) > 0 {
child.children = append(child.children, stealFrom.children.removeAt(0))
}
} else {
if i >= len(n.items) {
i--
}
child := n.mutableChild(i)
// merge with right child
mergeItem := n.items.removeAt(i)
mergeChild := n.children.removeAt(i + 1)
child.items = append(child.items, mergeItem)
child.items = append(child.items, mergeChild.items...)
child.children = append(child.children, mergeChild.children...)
n.cow.freeNode(mergeChild)
}
return n.remove(item, minItems, typ)
}
type direction int
const (
descend = direction(-1)
ascend = direction(+1)
)
// iterate provides a simple method for iterating over elements in the tree.
//
// When ascending, the 'start' should be less than 'stop' and when descending,
// the 'start' should be greater than 'stop'. Setting 'includeStart' to true
// will force the iterator to include the first item when it equals 'start',
// thus creating a "greaterOrEqual" or "lessThanEqual" rather than just a
// "greaterThan" or "lessThan" queries.
func (n *node) iterate(dir direction, start, stop Item, includeStart bool, hit bool, iter ItemIterator) (bool, bool) {
var ok, found bool
var index int
switch dir {
case ascend:
if start != nil {
index, _ = n.items.find(start)
}
for i := index; i < len(n.items); i++ {
if len(n.children) > 0 {
if hit, ok = n.children[i].iterate(dir, start, stop, includeStart, hit, iter); !ok {
return hit, false
}
}
if !includeStart && !hit && start != nil && !start.Less(n.items[i]) {
hit = true
continue
}
hit = true
if stop != nil && !n.items[i].Less(stop) {
return hit, false
}
if !iter(n.items[i]) {
return hit, false
}
}
if len(n.children) > 0 {
if hit, ok = n.children[len(n.children)-1].iterate(dir, start, stop, includeStart, hit, iter); !ok {
return hit, false
}
}
case descend:
if start != nil {
index, found = n.items.find(start)
if !found {
index = index - 1
}
} else {
index = len(n.items) - 1
}
for i := index; i >= 0; i-- {
if start != nil && !n.items[i].Less(start) {
if !includeStart || hit || start.Less(n.items[i]) {
continue
}
}
if len(n.children) > 0 {
if hit, ok = n.children[i+1].iterate(dir, start, stop, includeStart, hit, iter); !ok {
return hit, false
}
}
if stop != nil && !stop.Less(n.items[i]) {
return hit, false // continue
}
hit = true
if !iter(n.items[i]) {
return hit, false
}
}
if len(n.children) > 0 {
if hit, ok = n.children[0].iterate(dir, start, stop, includeStart, hit, iter); !ok {
return hit, false
}
}
}
return hit, true
}
// Used for testing/debugging purposes.
func (n *node) print(w io.Writer, level int) {
fmt.Fprintf(w, "%sNODE:%v\n", strings.Repeat(" ", level), n.items)
for _, c := range n.children {
c.print(w, level+1)
}
}
// BTree is an implementation of a B-Tree.
//
// BTree stores Item instances in an ordered structure, allowing easy insertion,
// removal, and iteration.
//
// Write operations are not safe for concurrent mutation by multiple
// goroutines, but Read operations are.
type BTree struct {
degree int
length int
root *node
cow *copyOnWriteContext
}
// copyOnWriteContext pointers determine node ownership... a tree with a write
// context equivalent to a node's write context is allowed to modify that node.
// A tree whose write context does not match a node's is not allowed to modify
// it, and must create a new, writable copy (IE: it's a Clone).
//
// When doing any write operation, we maintain the invariant that the current
// node's context is equal to the context of the tree that requested the write.
// We do this by, before we descend into any node, creating a copy with the
// correct context if the contexts don't match.
//
// Since the node we're currently visiting on any write has the requesting
// tree's context, that node is modifiable in place. Children of that node may
// not share context, but before we descend into them, we'll make a mutable
// copy.
type copyOnWriteContext struct {
freelist *FreeList
}
// Clone clones the btree, lazily. Clone should not be called concurrently,
// but the original tree (t) and the new tree (t2) can be used concurrently
// once the Clone call completes.
//
// The internal tree structure of b is marked read-only and shared between t and
// t2. Writes to both t and t2 use copy-on-write logic, creating new nodes
// whenever one of b's original nodes would have been modified. Read operations
// should have no performance degredation. Write operations for both t and t2
// will initially experience minor slow-downs caused by additional allocs and
// copies due to the aforementioned copy-on-write logic, but should converge to
// the original performance characteristics of the original tree.
func (t *BTree) Clone() (t2 *BTree) {
// Create two entirely new copy-on-write contexts.
// This operation effectively creates three trees:
// the original, shared nodes (old b.cow)
// the new b.cow nodes
// the new out.cow nodes
cow1, cow2 := *t.cow, *t.cow
out := *t
t.cow = &cow1
out.cow = &cow2
return &out
}
// maxItems returns the max number of items to allow per node.
func (t *BTree) maxItems() int {
return t.degree*2 - 1
}
// minItems returns the min number of items to allow per node (ignored for the
// root node).
func (t *BTree) minItems() int {
return t.degree - 1
}
func (c *copyOnWriteContext) newNode() (n *node) {
n = c.freelist.newNode()
n.cow = c
return
}
type freeType int
const (
ftFreelistFull freeType = iota // node was freed (available for GC, not stored in freelist)
ftStored // node was stored in the freelist for later use
ftNotOwned // node was ignored by COW, since it's owned by another one
)
// freeNode frees a node within a given COW context, if it's owned by that
// context. It returns what happened to the node (see freeType const
// documentation).
func (c *copyOnWriteContext) freeNode(n *node) freeType {
if n.cow == c {
// clear to allow GC
n.items.truncate(0)
n.children.truncate(0)
n.cow = nil
if c.freelist.freeNode(n) {
return ftStored
} else {
return ftFreelistFull
}
} else {
return ftNotOwned
}
}
// ReplaceOrInsert adds the given item to the tree. If an item in the tree
// already equals the given one, it is removed from the tree and returned.
// Otherwise, nil is returned.
//
// nil cannot be added to the tree (will panic).
func (t *BTree) ReplaceOrInsert(item Item) Item {
if item == nil {
panic("nil item being added to BTree")
}
if t.root == nil {
t.root = t.cow.newNode()
t.root.items = append(t.root.items, item)
t.length++
return nil
} else {
t.root = t.root.mutableFor(t.cow)
if len(t.root.items) >= t.maxItems() {
item2, second := t.root.split(t.maxItems() / 2)
oldroot := t.root
t.root = t.cow.newNode()
t.root.items = append(t.root.items, item2)
t.root.children = append(t.root.children, oldroot, second)
}
}
out := t.root.insert(item, t.maxItems())
if out == nil {
t.length++
}
return out
}
// Delete removes an item equal to the passed in item from the tree, returning
// it. If no such item exists, returns nil.
func (t *BTree) Delete(item Item) Item {
return t.deleteItem(item, removeItem)
}
// DeleteMin removes the smallest item in the tree and returns it.
// If no such item exists, returns nil.
func (t *BTree) DeleteMin() Item {
return t.deleteItem(nil, removeMin)
}
// DeleteMax removes the largest item in the tree and returns it.
// If no such item exists, returns nil.
func (t *BTree) DeleteMax() Item {
return t.deleteItem(nil, removeMax)
}
func (t *BTree) deleteItem(item Item, typ toRemove) Item {
if t.root == nil || len(t.root.items) == 0 {
return nil
}
t.root = t.root.mutableFor(t.cow)
out := t.root.remove(item, t.minItems(), typ)
if len(t.root.items) == 0 && len(t.root.children) > 0 {
oldroot := t.root
t.root = t.root.children[0]
t.cow.freeNode(oldroot)
}
if out != nil {
t.length--
}
return out
}
// AscendRange calls the iterator for every value in the tree within the range
// [greaterOrEqual, lessThan), until iterator returns false.
func (t *BTree) AscendRange(greaterOrEqual, lessThan Item, iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(ascend, greaterOrEqual, lessThan, true, false, iterator)
}
// AscendLessThan calls the iterator for every value in the tree within the range
// [first, pivot), until iterator returns false.
func (t *BTree) AscendLessThan(pivot Item, iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(ascend, nil, pivot, false, false, iterator)
}
// AscendGreaterOrEqual calls the iterator for every value in the tree within
// the range [pivot, last], until iterator returns false.
func (t *BTree) AscendGreaterOrEqual(pivot Item, iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(ascend, pivot, nil, true, false, iterator)
}
// Ascend calls the iterator for every value in the tree within the range
// [first, last], until iterator returns false.
func (t *BTree) Ascend(iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(ascend, nil, nil, false, false, iterator)
}
// DescendRange calls the iterator for every value in the tree within the range
// [lessOrEqual, greaterThan), until iterator returns false.
func (t *BTree) DescendRange(lessOrEqual, greaterThan Item, iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(descend, lessOrEqual, greaterThan, true, false, iterator)
}
// DescendLessOrEqual calls the iterator for every value in the tree within the range
// [pivot, first], until iterator returns false.
func (t *BTree) DescendLessOrEqual(pivot Item, iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(descend, pivot, nil, true, false, iterator)
}
// DescendGreaterThan calls the iterator for every value in the tree within
// the range (pivot, last], until iterator returns false.
func (t *BTree) DescendGreaterThan(pivot Item, iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(descend, nil, pivot, false, false, iterator)
}
// Descend calls the iterator for every value in the tree within the range
// [last, first], until iterator returns false.
func (t *BTree) Descend(iterator ItemIterator) {
if t.root == nil {
return
}
t.root.iterate(descend, nil, nil, false, false, iterator)
}
// Get looks for the key item in the tree, returning it. It returns nil if
// unable to find that item.
func (t *BTree) Get(key Item) Item {
if t.root == nil {
return nil
}
return t.root.get(key)
}
// Min returns the smallest item in the tree, or nil if the tree is empty.
func (t *BTree) Min() Item {
return min(t.root)
}
// Max returns the largest item in the tree, or nil if the tree is empty.
func (t *BTree) Max() Item {
return max(t.root)
}
// Has returns true if the given key is in the tree.
func (t *BTree) Has(key Item) bool {
return t.Get(key) != nil
}
// Len returns the number of items currently in the tree.
func (t *BTree) Len() int {
return t.length
}
// Clear removes all items from the btree. If addNodesToFreelist is true,
// t's nodes are added to its freelist as part of this call, until the freelist
// is full. Otherwise, the root node is simply dereferenced and the subtree
// left to Go's normal GC processes.
//
// This can be much faster
// than calling Delete on all elements, because that requires finding/removing
// each element in the tree and updating the tree accordingly. It also is
// somewhat faster than creating a new tree to replace the old one, because
// nodes from the old tree are reclaimed into the freelist for use by the new
// one, instead of being lost to the garbage collector.
//
// This call takes:
// O(1): when addNodesToFreelist is false, this is a single operation.
// O(1): when the freelist is already full, it breaks out immediately
// O(freelist size): when the freelist is empty and the nodes are all owned
// by this tree, nodes are added to the freelist until full.
// O(tree size): when all nodes are owned by another tree, all nodes are
// iterated over looking for nodes to add to the freelist, and due to
// ownership, none are.
func (t *BTree) Clear(addNodesToFreelist bool) {
if t.root != nil && addNodesToFreelist {
t.root.reset(t.cow)
}
t.root, t.length = nil, 0
}
// reset returns a subtree to the freelist. It breaks out immediately if the
// freelist is full, since the only benefit of iterating is to fill that
// freelist up. Returns true if parent reset call should continue.
func (n *node) reset(c *copyOnWriteContext) bool {
for _, child := range n.children {
if !child.reset(c) {
return false
}
}
return c.freeNode(n) != ftFreelistFull
}
// Int implements the Item interface for integers.
type Int int
// Less returns true if int(a) < int(b).
func (a Int) Less(b Item) bool {
return a < b.(Int)
}

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vendor/github.com/google/btree/btree_mem.go сгенерированный поставляемый Normal file
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@ -0,0 +1,76 @@
// Copyright 2014 Google Inc.
//
// 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.
// +build ignore
// This binary compares memory usage between btree and gollrb.
package main
import (
"flag"
"fmt"
"math/rand"
"runtime"
"time"
"github.com/google/btree"
"github.com/petar/GoLLRB/llrb"
)
var (
size = flag.Int("size", 1000000, "size of the tree to build")
degree = flag.Int("degree", 8, "degree of btree")
gollrb = flag.Bool("llrb", false, "use llrb instead of btree")
)
func main() {
flag.Parse()
vals := rand.Perm(*size)
var t, v interface{}
v = vals
var stats runtime.MemStats
for i := 0; i < 10; i++ {
runtime.GC()
}
fmt.Println("-------- BEFORE ----------")
runtime.ReadMemStats(&stats)
fmt.Printf("%+v\n", stats)
start := time.Now()
if *gollrb {
tr := llrb.New()
for _, v := range vals {
tr.ReplaceOrInsert(llrb.Int(v))
}
t = tr // keep it around
} else {
tr := btree.New(*degree)
for _, v := range vals {
tr.ReplaceOrInsert(btree.Int(v))
}
t = tr // keep it around
}
fmt.Printf("%v inserts in %v\n", *size, time.Since(start))
fmt.Println("-------- AFTER ----------")
runtime.ReadMemStats(&stats)
fmt.Printf("%+v\n", stats)
for i := 0; i < 10; i++ {
runtime.GC()
}
fmt.Println("-------- AFTER GC ----------")
runtime.ReadMemStats(&stats)
fmt.Printf("%+v\n", stats)
if t == v {
fmt.Println("to make sure vals and tree aren't GC'd")
}
}

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sudo: false
language: go
go:
- 1.6.x
- 1.7.x
- 1.8.x
- 1.9.x
- master
matrix:
allow_failures:
- go: master
fast_finish: true
install:
- # Do nothing. This is needed to prevent default install action "go get -t -v ./..." from happening here (we want it to happen inside script step).
script:
- go get -t -v ./...
- diff -u <(echo -n) <(gofmt -d .)
- go tool vet .
- go test -v -race ./...

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Copyright © 2012 Greg Jones (greg.jones@gmail.com)
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the “Software”), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED “AS IS”, WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

25
vendor/github.com/gregjones/httpcache/README.md сгенерированный поставляемый Normal file
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httpcache
=========
[![Build Status](https://travis-ci.org/gregjones/httpcache.svg?branch=master)](https://travis-ci.org/gregjones/httpcache) [![GoDoc](https://godoc.org/github.com/gregjones/httpcache?status.svg)](https://godoc.org/github.com/gregjones/httpcache)
Package httpcache provides a http.RoundTripper implementation that works as a mostly [RFC 7234](https://tools.ietf.org/html/rfc7234) compliant cache for http responses.
It is only suitable for use as a 'private' cache (i.e. for a web-browser or an API-client and not for a shared proxy).
Cache Backends
--------------
- The built-in 'memory' cache stores responses in an in-memory map.
- [`github.com/gregjones/httpcache/diskcache`](https://github.com/gregjones/httpcache/tree/master/diskcache) provides a filesystem-backed cache using the [diskv](https://github.com/peterbourgon/diskv) library.
- [`github.com/gregjones/httpcache/memcache`](https://github.com/gregjones/httpcache/tree/master/memcache) provides memcache implementations, for both App Engine and 'normal' memcache servers.
- [`sourcegraph.com/sourcegraph/s3cache`](https://sourcegraph.com/github.com/sourcegraph/s3cache) uses Amazon S3 for storage.
- [`github.com/gregjones/httpcache/leveldbcache`](https://github.com/gregjones/httpcache/tree/master/leveldbcache) provides a filesystem-backed cache using [leveldb](https://github.com/syndtr/goleveldb/leveldb).
- [`github.com/die-net/lrucache`](https://github.com/die-net/lrucache) provides an in-memory cache that will evict least-recently used entries.
- [`github.com/die-net/lrucache/twotier`](https://github.com/die-net/lrucache/tree/master/twotier) allows caches to be combined, for example to use lrucache above with a persistent disk-cache.
- [`github.com/birkelund/boltdbcache`](https://github.com/birkelund/boltdbcache) provides a BoltDB implementation (based on the [bbolt](https://github.com/coreos/bbolt) fork).
License
-------
- [MIT License](LICENSE.txt)

61
vendor/github.com/gregjones/httpcache/diskcache/diskcache.go сгенерированный поставляемый Normal file
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// Package diskcache provides an implementation of httpcache.Cache that uses the diskv package
// to supplement an in-memory map with persistent storage
//
package diskcache
import (
"bytes"
"crypto/md5"
"encoding/hex"
"github.com/peterbourgon/diskv"
"io"
)
// Cache is an implementation of httpcache.Cache that supplements the in-memory map with persistent storage
type Cache struct {
d *diskv.Diskv
}
// Get returns the response corresponding to key if present
func (c *Cache) Get(key string) (resp []byte, ok bool) {
key = keyToFilename(key)
resp, err := c.d.Read(key)
if err != nil {
return []byte{}, false
}
return resp, true
}
// Set saves a response to the cache as key
func (c *Cache) Set(key string, resp []byte) {
key = keyToFilename(key)
c.d.WriteStream(key, bytes.NewReader(resp), true)
}
// Delete removes the response with key from the cache
func (c *Cache) Delete(key string) {
key = keyToFilename(key)
c.d.Erase(key)
}
func keyToFilename(key string) string {
h := md5.New()
io.WriteString(h, key)
return hex.EncodeToString(h.Sum(nil))
}
// New returns a new Cache that will store files in basePath
func New(basePath string) *Cache {
return &Cache{
d: diskv.New(diskv.Options{
BasePath: basePath,
CacheSizeMax: 100 * 1024 * 1024, // 100MB
}),
}
}
// NewWithDiskv returns a new Cache using the provided Diskv as underlying
// storage.
func NewWithDiskv(d *diskv.Diskv) *Cache {
return &Cache{d}
}

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// Package httpcache provides a http.RoundTripper implementation that works as a
// mostly RFC-compliant cache for http responses.
//
// It is only suitable for use as a 'private' cache (i.e. for a web-browser or an API-client
// and not for a shared proxy).
//
package httpcache
import (
"bufio"
"bytes"
"errors"
"io"
"io/ioutil"
"net/http"
"net/http/httputil"
"strings"
"sync"
"time"
)
const (
stale = iota
fresh
transparent
// XFromCache is the header added to responses that are returned from the cache
XFromCache = "X-From-Cache"
)
// A Cache interface is used by the Transport to store and retrieve responses.
type Cache interface {
// Get returns the []byte representation of a cached response and a bool
// set to true if the value isn't empty
Get(key string) (responseBytes []byte, ok bool)
// Set stores the []byte representation of a response against a key
Set(key string, responseBytes []byte)
// Delete removes the value associated with the key
Delete(key string)
}
// cacheKey returns the cache key for req.
func cacheKey(req *http.Request) string {
if req.Method == http.MethodGet {
return req.URL.String()
} else {
return req.Method + " " + req.URL.String()
}
}
// CachedResponse returns the cached http.Response for req if present, and nil
// otherwise.
func CachedResponse(c Cache, req *http.Request) (resp *http.Response, err error) {
cachedVal, ok := c.Get(cacheKey(req))
if !ok {
return
}
b := bytes.NewBuffer(cachedVal)
return http.ReadResponse(bufio.NewReader(b), req)
}
// MemoryCache is an implemtation of Cache that stores responses in an in-memory map.
type MemoryCache struct {
mu sync.RWMutex
items map[string][]byte
}
// Get returns the []byte representation of the response and true if present, false if not
func (c *MemoryCache) Get(key string) (resp []byte, ok bool) {
c.mu.RLock()
resp, ok = c.items[key]
c.mu.RUnlock()
return resp, ok
}
// Set saves response resp to the cache with key
func (c *MemoryCache) Set(key string, resp []byte) {
c.mu.Lock()
c.items[key] = resp
c.mu.Unlock()
}
// Delete removes key from the cache
func (c *MemoryCache) Delete(key string) {
c.mu.Lock()
delete(c.items, key)
c.mu.Unlock()
}
// NewMemoryCache returns a new Cache that will store items in an in-memory map
func NewMemoryCache() *MemoryCache {
c := &MemoryCache{items: map[string][]byte{}}
return c
}
// Transport is an implementation of http.RoundTripper that will return values from a cache
// where possible (avoiding a network request) and will additionally add validators (etag/if-modified-since)
// to repeated requests allowing servers to return 304 / Not Modified
type Transport struct {
// The RoundTripper interface actually used to make requests
// If nil, http.DefaultTransport is used
Transport http.RoundTripper
Cache Cache
// If true, responses returned from the cache will be given an extra header, X-From-Cache
MarkCachedResponses bool
}
// NewTransport returns a new Transport with the
// provided Cache implementation and MarkCachedResponses set to true
func NewTransport(c Cache) *Transport {
return &Transport{Cache: c, MarkCachedResponses: true}
}
// Client returns an *http.Client that caches responses.
func (t *Transport) Client() *http.Client {
return &http.Client{Transport: t}
}
// varyMatches will return false unless all of the cached values for the headers listed in Vary
// match the new request
func varyMatches(cachedResp *http.Response, req *http.Request) bool {
for _, header := range headerAllCommaSepValues(cachedResp.Header, "vary") {
header = http.CanonicalHeaderKey(header)
if header != "" && req.Header.Get(header) != cachedResp.Header.Get("X-Varied-"+header) {
return false
}
}
return true
}
// RoundTrip takes a Request and returns a Response
//
// If there is a fresh Response already in cache, then it will be returned without connecting to
// the server.
//
// If there is a stale Response, then any validators it contains will be set on the new request
// to give the server a chance to respond with NotModified. If this happens, then the cached Response
// will be returned.
func (t *Transport) RoundTrip(req *http.Request) (resp *http.Response, err error) {
cacheKey := cacheKey(req)
cacheable := (req.Method == "GET" || req.Method == "HEAD") && req.Header.Get("range") == ""
var cachedResp *http.Response
if cacheable {
cachedResp, err = CachedResponse(t.Cache, req)
} else {
// Need to invalidate an existing value
t.Cache.Delete(cacheKey)
}
transport := t.Transport
if transport == nil {
transport = http.DefaultTransport
}
if cacheable && cachedResp != nil && err == nil {
if t.MarkCachedResponses {
cachedResp.Header.Set(XFromCache, "1")
}
if varyMatches(cachedResp, req) {
// Can only use cached value if the new request doesn't Vary significantly
freshness := getFreshness(cachedResp.Header, req.Header)
if freshness == fresh {
return cachedResp, nil
}
if freshness == stale {
var req2 *http.Request
// Add validators if caller hasn't already done so
etag := cachedResp.Header.Get("etag")
if etag != "" && req.Header.Get("etag") == "" {
req2 = cloneRequest(req)
req2.Header.Set("if-none-match", etag)
}
lastModified := cachedResp.Header.Get("last-modified")
if lastModified != "" && req.Header.Get("last-modified") == "" {
if req2 == nil {
req2 = cloneRequest(req)
}
req2.Header.Set("if-modified-since", lastModified)
}
if req2 != nil {
req = req2
}
}
}
resp, err = transport.RoundTrip(req)
if err == nil && req.Method == "GET" && resp.StatusCode == http.StatusNotModified {
// Replace the 304 response with the one from cache, but update with some new headers
endToEndHeaders := getEndToEndHeaders(resp.Header)
for _, header := range endToEndHeaders {
cachedResp.Header[header] = resp.Header[header]
}
resp = cachedResp
} else if (err != nil || (cachedResp != nil && resp.StatusCode >= 500)) &&
req.Method == "GET" && canStaleOnError(cachedResp.Header, req.Header) {
// In case of transport failure and stale-if-error activated, returns cached content
// when available
return cachedResp, nil
} else {
if err != nil || resp.StatusCode != http.StatusOK {
t.Cache.Delete(cacheKey)
}
if err != nil {
return nil, err
}
}
} else {
reqCacheControl := parseCacheControl(req.Header)
if _, ok := reqCacheControl["only-if-cached"]; ok {
resp = newGatewayTimeoutResponse(req)
} else {
resp, err = transport.RoundTrip(req)
if err != nil {
return nil, err
}
}
}
if cacheable && canStore(parseCacheControl(req.Header), parseCacheControl(resp.Header)) {
for _, varyKey := range headerAllCommaSepValues(resp.Header, "vary") {
varyKey = http.CanonicalHeaderKey(varyKey)
fakeHeader := "X-Varied-" + varyKey
reqValue := req.Header.Get(varyKey)
if reqValue != "" {
resp.Header.Set(fakeHeader, reqValue)
}
}
switch req.Method {
case "GET":
// Delay caching until EOF is reached.
resp.Body = &cachingReadCloser{
R: resp.Body,
OnEOF: func(r io.Reader) {
resp := *resp
resp.Body = ioutil.NopCloser(r)
respBytes, err := httputil.DumpResponse(&resp, true)
if err == nil {
t.Cache.Set(cacheKey, respBytes)
}
},
}
default:
respBytes, err := httputil.DumpResponse(resp, true)
if err == nil {
t.Cache.Set(cacheKey, respBytes)
}
}
} else {
t.Cache.Delete(cacheKey)
}
return resp, nil
}
// ErrNoDateHeader indicates that the HTTP headers contained no Date header.
var ErrNoDateHeader = errors.New("no Date header")
// Date parses and returns the value of the Date header.
func Date(respHeaders http.Header) (date time.Time, err error) {
dateHeader := respHeaders.Get("date")
if dateHeader == "" {
err = ErrNoDateHeader
return
}
return time.Parse(time.RFC1123, dateHeader)
}
type realClock struct{}
func (c *realClock) since(d time.Time) time.Duration {
return time.Since(d)
}
type timer interface {
since(d time.Time) time.Duration
}
var clock timer = &realClock{}
// getFreshness will return one of fresh/stale/transparent based on the cache-control
// values of the request and the response
//
// fresh indicates the response can be returned
// stale indicates that the response needs validating before it is returned
// transparent indicates the response should not be used to fulfil the request
//
// Because this is only a private cache, 'public' and 'private' in cache-control aren't
// signficant. Similarly, smax-age isn't used.
func getFreshness(respHeaders, reqHeaders http.Header) (freshness int) {
respCacheControl := parseCacheControl(respHeaders)
reqCacheControl := parseCacheControl(reqHeaders)
if _, ok := reqCacheControl["no-cache"]; ok {
return transparent
}
if _, ok := respCacheControl["no-cache"]; ok {
return stale
}
if _, ok := reqCacheControl["only-if-cached"]; ok {
return fresh
}
date, err := Date(respHeaders)
if err != nil {
return stale
}
currentAge := clock.since(date)
var lifetime time.Duration
var zeroDuration time.Duration
// If a response includes both an Expires header and a max-age directive,
// the max-age directive overrides the Expires header, even if the Expires header is more restrictive.
if maxAge, ok := respCacheControl["max-age"]; ok {
lifetime, err = time.ParseDuration(maxAge + "s")
if err != nil {
lifetime = zeroDuration
}
} else {
expiresHeader := respHeaders.Get("Expires")
if expiresHeader != "" {
expires, err := time.Parse(time.RFC1123, expiresHeader)
if err != nil {
lifetime = zeroDuration
} else {
lifetime = expires.Sub(date)
}
}
}
if maxAge, ok := reqCacheControl["max-age"]; ok {
// the client is willing to accept a response whose age is no greater than the specified time in seconds
lifetime, err = time.ParseDuration(maxAge + "s")
if err != nil {
lifetime = zeroDuration
}
}
if minfresh, ok := reqCacheControl["min-fresh"]; ok {
// the client wants a response that will still be fresh for at least the specified number of seconds.
minfreshDuration, err := time.ParseDuration(minfresh + "s")
if err == nil {
currentAge = time.Duration(currentAge + minfreshDuration)
}
}
if maxstale, ok := reqCacheControl["max-stale"]; ok {
// Indicates that the client is willing to accept a response that has exceeded its expiration time.
// If max-stale is assigned a value, then the client is willing to accept a response that has exceeded
// its expiration time by no more than the specified number of seconds.
// If no value is assigned to max-stale, then the client is willing to accept a stale response of any age.
//
// Responses served only because of a max-stale value are supposed to have a Warning header added to them,
// but that seems like a hassle, and is it actually useful? If so, then there needs to be a different
// return-value available here.
if maxstale == "" {
return fresh
}
maxstaleDuration, err := time.ParseDuration(maxstale + "s")
if err == nil {
currentAge = time.Duration(currentAge - maxstaleDuration)
}
}
if lifetime > currentAge {
return fresh
}
return stale
}
// Returns true if either the request or the response includes the stale-if-error
// cache control extension: https://tools.ietf.org/html/rfc5861
func canStaleOnError(respHeaders, reqHeaders http.Header) bool {
respCacheControl := parseCacheControl(respHeaders)
reqCacheControl := parseCacheControl(reqHeaders)
var err error
lifetime := time.Duration(-1)
if staleMaxAge, ok := respCacheControl["stale-if-error"]; ok {
if staleMaxAge != "" {
lifetime, err = time.ParseDuration(staleMaxAge + "s")
if err != nil {
return false
}
} else {
return true
}
}
if staleMaxAge, ok := reqCacheControl["stale-if-error"]; ok {
if staleMaxAge != "" {
lifetime, err = time.ParseDuration(staleMaxAge + "s")
if err != nil {
return false
}
} else {
return true
}
}
if lifetime >= 0 {
date, err := Date(respHeaders)
if err != nil {
return false
}
currentAge := clock.since(date)
if lifetime > currentAge {
return true
}
}
return false
}
func getEndToEndHeaders(respHeaders http.Header) []string {
// These headers are always hop-by-hop
hopByHopHeaders := map[string]struct{}{
"Connection": struct{}{},
"Keep-Alive": struct{}{},
"Proxy-Authenticate": struct{}{},
"Proxy-Authorization": struct{}{},
"Te": struct{}{},
"Trailers": struct{}{},
"Transfer-Encoding": struct{}{},
"Upgrade": struct{}{},
}
for _, extra := range strings.Split(respHeaders.Get("connection"), ",") {
// any header listed in connection, if present, is also considered hop-by-hop
if strings.Trim(extra, " ") != "" {
hopByHopHeaders[http.CanonicalHeaderKey(extra)] = struct{}{}
}
}
endToEndHeaders := []string{}
for respHeader, _ := range respHeaders {
if _, ok := hopByHopHeaders[respHeader]; !ok {
endToEndHeaders = append(endToEndHeaders, respHeader)
}
}
return endToEndHeaders
}
func canStore(reqCacheControl, respCacheControl cacheControl) (canStore bool) {
if _, ok := respCacheControl["no-store"]; ok {
return false
}
if _, ok := reqCacheControl["no-store"]; ok {
return false
}
return true
}
func newGatewayTimeoutResponse(req *http.Request) *http.Response {
var braw bytes.Buffer
braw.WriteString("HTTP/1.1 504 Gateway Timeout\r\n\r\n")
resp, err := http.ReadResponse(bufio.NewReader(&braw), req)
if err != nil {
panic(err)
}
return resp
}
// cloneRequest returns a clone of the provided *http.Request.
// The clone is a shallow copy of the struct and its Header map.
// (This function copyright goauth2 authors: https://code.google.com/p/goauth2)
func cloneRequest(r *http.Request) *http.Request {
// shallow copy of the struct
r2 := new(http.Request)
*r2 = *r
// deep copy of the Header
r2.Header = make(http.Header)
for k, s := range r.Header {
r2.Header[k] = s
}
return r2
}
type cacheControl map[string]string
func parseCacheControl(headers http.Header) cacheControl {
cc := cacheControl{}
ccHeader := headers.Get("Cache-Control")
for _, part := range strings.Split(ccHeader, ",") {
part = strings.Trim(part, " ")
if part == "" {
continue
}
if strings.ContainsRune(part, '=') {
keyval := strings.Split(part, "=")
cc[strings.Trim(keyval[0], " ")] = strings.Trim(keyval[1], ",")
} else {
cc[part] = ""
}
}
return cc
}
// headerAllCommaSepValues returns all comma-separated values (each
// with whitespace trimmed) for header name in headers. According to
// Section 4.2 of the HTTP/1.1 spec
// (http://www.w3.org/Protocols/rfc2616/rfc2616-sec4.html#sec4.2),
// values from multiple occurrences of a header should be concatenated, if
// the header's value is a comma-separated list.
func headerAllCommaSepValues(headers http.Header, name string) []string {
var vals []string
for _, val := range headers[http.CanonicalHeaderKey(name)] {
fields := strings.Split(val, ",")
for i, f := range fields {
fields[i] = strings.TrimSpace(f)
}
vals = append(vals, fields...)
}
return vals
}
// cachingReadCloser is a wrapper around ReadCloser R that calls OnEOF
// handler with a full copy of the content read from R when EOF is
// reached.
type cachingReadCloser struct {
// Underlying ReadCloser.
R io.ReadCloser
// OnEOF is called with a copy of the content of R when EOF is reached.
OnEOF func(io.Reader)
buf bytes.Buffer // buf stores a copy of the content of R.
}
// Read reads the next len(p) bytes from R or until R is drained. The
// return value n is the number of bytes read. If R has no data to
// return, err is io.EOF and OnEOF is called with a full copy of what
// has been read so far.
func (r *cachingReadCloser) Read(p []byte) (n int, err error) {
n, err = r.R.Read(p)
r.buf.Write(p[:n])
if err == io.EOF {
r.OnEOF(bytes.NewReader(r.buf.Bytes()))
}
return n, err
}
func (r *cachingReadCloser) Close() error {
return r.R.Close()
}
// NewMemoryCacheTransport returns a new Transport using the in-memory cache implementation
func NewMemoryCacheTransport() *Transport {
c := NewMemoryCache()
t := NewTransport(c)
return t
}

11
vendor/github.com/howeyc/gopass/.travis.yml сгенерированный поставляемый
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language: go
os:
- linux
- osx
go:
- 1.3
- 1.4
- 1.5
- tip

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vendor/github.com/howeyc/gopass/LICENSE.txt сгенерированный поставляемый
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ISC License
Copyright (c) 2012 Chris Howey
Permission to use, copy, modify, and distribute this software for any
purpose with or without fee is hereby granted, provided that the above
copyright notice and this permission notice appear in all copies.
THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

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vendor/github.com/howeyc/gopass/OPENSOLARIS.LICENSE сгенерированный поставляемый
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@ -1,384 +0,0 @@
Unless otherwise noted, all files in this distribution are released
under the Common Development and Distribution License (CDDL).
Exceptions are noted within the associated source files.
--------------------------------------------------------------------
COMMON DEVELOPMENT AND DISTRIBUTION LICENSE Version 1.0
1. Definitions.
1.1. "Contributor" means each individual or entity that creates
or contributes to the creation of Modifications.
1.2. "Contributor Version" means the combination of the Original
Software, prior Modifications used by a Contributor (if any),
and the Modifications made by that particular Contributor.
1.3. "Covered Software" means (a) the Original Software, or (b)
Modifications, or (c) the combination of files containing
Original Software with files containing Modifications, in
each case including portions thereof.
1.4. "Executable" means the Covered Software in any form other
than Source Code.
1.5. "Initial Developer" means the individual or entity that first
makes Original Software available under this License.
1.6. "Larger Work" means a work which combines Covered Software or
portions thereof with code not governed by the terms of this
License.
1.7. "License" means this document.
1.8. "Licensable" means having the right to grant, to the maximum
extent possible, whether at the time of the initial grant or
subsequently acquired, any and all of the rights conveyed
herein.
1.9. "Modifications" means the Source Code and Executable form of
any of the following:
A. Any file that results from an addition to, deletion from or
modification of the contents of a file containing Original
Software or previous Modifications;
B. Any new file that contains any part of the Original
Software or previous Modifications; or
C. Any new file that is contributed or otherwise made
available under the terms of this License.
1.10. "Original Software" means the Source Code and Executable
form of computer software code that is originally released
under this License.
1.11. "Patent Claims" means any patent claim(s), now owned or
hereafter acquired, including without limitation, method,
process, and apparatus claims, in any patent Licensable by
grantor.
1.12. "Source Code" means (a) the common form of computer software
code in which modifications are made and (b) associated
documentation included in or with such code.
1.13. "You" (or "Your") means an individual or a legal entity
exercising rights under, and complying with all of the terms
of, this License. For legal entities, "You" includes any
entity which controls, is controlled by, or is under common
control with You. For purposes of this definition,
"control" means (a) the power, direct or indirect, to cause
the direction or management of such entity, whether by
contract or otherwise, or (b) ownership of more than fifty
percent (50%) of the outstanding shares or beneficial
ownership of such entity.
2. License Grants.
2.1. The Initial Developer Grant.
Conditioned upon Your compliance with Section 3.1 below and
subject to third party intellectual property claims, the Initial
Developer hereby grants You a world-wide, royalty-free,
non-exclusive license:
(a) under intellectual property rights (other than patent or
trademark) Licensable by Initial Developer, to use,
reproduce, modify, display, perform, sublicense and
distribute the Original Software (or portions thereof),
with or without Modifications, and/or as part of a Larger
Work; and
(b) under Patent Claims infringed by the making, using or
selling of Original Software, to make, have made, use,
practice, sell, and offer for sale, and/or otherwise
dispose of the Original Software (or portions thereof).
(c) The licenses granted in Sections 2.1(a) and (b) are
effective on the date Initial Developer first distributes
or otherwise makes the Original Software available to a
third party under the terms of this License.
(d) Notwithstanding Section 2.1(b) above, no patent license is
granted: (1) for code that You delete from the Original
Software, or (2) for infringements caused by: (i) the
modification of the Original Software, or (ii) the
combination of the Original Software with other software
or devices.
2.2. Contributor Grant.
Conditioned upon Your compliance with Section 3.1 below and
subject to third party intellectual property claims, each
Contributor hereby grants You a world-wide, royalty-free,
non-exclusive license:
(a) under intellectual property rights (other than patent or
trademark) Licensable by Contributor to use, reproduce,
modify, display, perform, sublicense and distribute the
Modifications created by such Contributor (or portions
thereof), either on an unmodified basis, with other
Modifications, as Covered Software and/or as part of a
Larger Work; and
(b) under Patent Claims infringed by the making, using, or
selling of Modifications made by that Contributor either
alone and/or in combination with its Contributor Version
(or portions of such combination), to make, use, sell,
offer for sale, have made, and/or otherwise dispose of:
(1) Modifications made by that Contributor (or portions
thereof); and (2) the combination of Modifications made by
that Contributor with its Contributor Version (or portions
of such combination).
(c) The licenses granted in Sections 2.2(a) and 2.2(b) are
effective on the date Contributor first distributes or
otherwise makes the Modifications available to a third
party.
(d) Notwithstanding Section 2.2(b) above, no patent license is
granted: (1) for any code that Contributor has deleted
from the Contributor Version; (2) for infringements caused
by: (i) third party modifications of Contributor Version,
or (ii) the combination of Modifications made by that
Contributor with other software (except as part of the
Contributor Version) or other devices; or (3) under Patent
Claims infringed by Covered Software in the absence of
Modifications made by that Contributor.
3. Distribution Obligations.
3.1. Availability of Source Code.
Any Covered Software that You distribute or otherwise make
available in Executable form must also be made available in Source
Code form and that Source Code form must be distributed only under
the terms of this License. You must include a copy of this
License with every copy of the Source Code form of the Covered
Software You distribute or otherwise make available. You must
inform recipients of any such Covered Software in Executable form
as to how they can obtain such Covered Software in Source Code
form in a reasonable manner on or through a medium customarily
used for software exchange.
3.2. Modifications.
The Modifications that You create or to which You contribute are
governed by the terms of this License. You represent that You
believe Your Modifications are Your original creation(s) and/or
You have sufficient rights to grant the rights conveyed by this
License.
3.3. Required Notices.
You must include a notice in each of Your Modifications that
identifies You as the Contributor of the Modification. You may
not remove or alter any copyright, patent or trademark notices
contained within the Covered Software, or any notices of licensing
or any descriptive text giving attribution to any Contributor or
the Initial Developer.
3.4. Application of Additional Terms.
You may not offer or impose any terms on any Covered Software in
Source Code form that alters or restricts the applicable version
of this License or the recipients' rights hereunder. You may
choose to offer, and to charge a fee for, warranty, support,
indemnity or liability obligations to one or more recipients of
Covered Software. However, you may do so only on Your own behalf,
and not on behalf of the Initial Developer or any Contributor.
You must make it absolutely clear that any such warranty, support,
indemnity or liability obligation is offered by You alone, and You
hereby agree to indemnify the Initial Developer and every
Contributor for any liability incurred by the Initial Developer or
such Contributor as a result of warranty, support, indemnity or
liability terms You offer.
3.5. Distribution of Executable Versions.
You may distribute the Executable form of the Covered Software
under the terms of this License or under the terms of a license of
Your choice, which may contain terms different from this License,
provided that You are in compliance with the terms of this License
and that the license for the Executable form does not attempt to
limit or alter the recipient's rights in the Source Code form from
the rights set forth in this License. If You distribute the
Covered Software in Executable form under a different license, You
must make it absolutely clear that any terms which differ from
this License are offered by You alone, not by the Initial
Developer or Contributor. You hereby agree to indemnify the
Initial Developer and every Contributor for any liability incurred
by the Initial Developer or such Contributor as a result of any
such terms You offer.
3.6. Larger Works.
You may create a Larger Work by combining Covered Software with
other code not governed by the terms of this License and
distribute the Larger Work as a single product. In such a case,
You must make sure the requirements of this License are fulfilled
for the Covered Software.
4. Versions of the License.
4.1. New Versions.
Sun Microsystems, Inc. is the initial license steward and may
publish revised and/or new versions of this License from time to
time. Each version will be given a distinguishing version number.
Except as provided in Section 4.3, no one other than the license
steward has the right to modify this License.
4.2. Effect of New Versions.
You may always continue to use, distribute or otherwise make the
Covered Software available under the terms of the version of the
License under which You originally received the Covered Software.
If the Initial Developer includes a notice in the Original
Software prohibiting it from being distributed or otherwise made
available under any subsequent version of the License, You must
distribute and make the Covered Software available under the terms
of the version of the License under which You originally received
the Covered Software. Otherwise, You may also choose to use,
distribute or otherwise make the Covered Software available under
the terms of any subsequent version of the License published by
the license steward.
4.3. Modified Versions.
When You are an Initial Developer and You want to create a new
license for Your Original Software, You may create and use a
modified version of this License if You: (a) rename the license
and remove any references to the name of the license steward
(except to note that the license differs from this License); and
(b) otherwise make it clear that the license contains terms which
differ from this License.
5. DISCLAIMER OF WARRANTY.
COVERED SOFTWARE IS PROVIDED UNDER THIS LICENSE ON AN "AS IS"
BASIS, WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESSED OR IMPLIED,
INCLUDING, WITHOUT LIMITATION, WARRANTIES THAT THE COVERED
SOFTWARE IS FREE OF DEFECTS, MERCHANTABLE, FIT FOR A PARTICULAR
PURPOSE OR NON-INFRINGING. THE ENTIRE RISK AS TO THE QUALITY AND
PERFORMANCE OF THE COVERED SOFTWARE IS WITH YOU. SHOULD ANY
COVERED SOFTWARE PROVE DEFECTIVE IN ANY RESPECT, YOU (NOT THE
INITIAL DEVELOPER OR ANY OTHER CONTRIBUTOR) ASSUME THE COST OF ANY
NECESSARY SERVICING, REPAIR OR CORRECTION. THIS DISCLAIMER OF
WARRANTY CONSTITUTES AN ESSENTIAL PART OF THIS LICENSE. NO USE OF
ANY COVERED SOFTWARE IS AUTHORIZED HEREUNDER EXCEPT UNDER THIS
DISCLAIMER.
6. TERMINATION.
6.1. This License and the rights granted hereunder will terminate
automatically if You fail to comply with terms herein and fail to
cure such breach within 30 days of becoming aware of the breach.
Provisions which, by their nature, must remain in effect beyond
the termination of this License shall survive.
6.2. If You assert a patent infringement claim (excluding
declaratory judgment actions) against Initial Developer or a
Contributor (the Initial Developer or Contributor against whom You
assert such claim is referred to as "Participant") alleging that
the Participant Software (meaning the Contributor Version where
the Participant is a Contributor or the Original Software where
the Participant is the Initial Developer) directly or indirectly
infringes any patent, then any and all rights granted directly or
indirectly to You by such Participant, the Initial Developer (if
the Initial Developer is not the Participant) and all Contributors
under Sections 2.1 and/or 2.2 of this License shall, upon 60 days
notice from Participant terminate prospectively and automatically
at the expiration of such 60 day notice period, unless if within
such 60 day period You withdraw Your claim with respect to the
Participant Software against such Participant either unilaterally
or pursuant to a written agreement with Participant.
6.3. In the event of termination under Sections 6.1 or 6.2 above,
all end user licenses that have been validly granted by You or any
distributor hereunder prior to termination (excluding licenses
granted to You by any distributor) shall survive termination.
7. LIMITATION OF LIABILITY.
UNDER NO CIRCUMSTANCES AND UNDER NO LEGAL THEORY, WHETHER TORT
(INCLUDING NEGLIGENCE), CONTRACT, OR OTHERWISE, SHALL YOU, THE
INITIAL DEVELOPER, ANY OTHER CONTRIBUTOR, OR ANY DISTRIBUTOR OF
COVERED SOFTWARE, OR ANY SUPPLIER OF ANY OF SUCH PARTIES, BE
LIABLE TO ANY PERSON FOR ANY INDIRECT, SPECIAL, INCIDENTAL, OR
CONSEQUENTIAL DAMAGES OF ANY CHARACTER INCLUDING, WITHOUT
LIMITATION, DAMAGES FOR LOST PROFITS, LOSS OF GOODWILL, WORK
STOPPAGE, COMPUTER FAILURE OR MALFUNCTION, OR ANY AND ALL OTHER
COMMERCIAL DAMAGES OR LOSSES, EVEN IF SUCH PARTY SHALL HAVE BEEN
INFORMED OF THE POSSIBILITY OF SUCH DAMAGES. THIS LIMITATION OF
LIABILITY SHALL NOT APPLY TO LIABILITY FOR DEATH OR PERSONAL
INJURY RESULTING FROM SUCH PARTY'S NEGLIGENCE TO THE EXTENT
APPLICABLE LAW PROHIBITS SUCH LIMITATION. SOME JURISDICTIONS DO
NOT ALLOW THE EXCLUSION OR LIMITATION OF INCIDENTAL OR
CONSEQUENTIAL DAMAGES, SO THIS EXCLUSION AND LIMITATION MAY NOT
APPLY TO YOU.
8. U.S. GOVERNMENT END USERS.
The Covered Software is a "commercial item," as that term is
defined in 48 C.F.R. 2.101 (Oct. 1995), consisting of "commercial
computer software" (as that term is defined at 48
C.F.R. 252.227-7014(a)(1)) and "commercial computer software
documentation" as such terms are used in 48 C.F.R. 12.212
(Sept. 1995). Consistent with 48 C.F.R. 12.212 and 48
C.F.R. 227.7202-1 through 227.7202-4 (June 1995), all
U.S. Government End Users acquire Covered Software with only those
rights set forth herein. This U.S. Government Rights clause is in
lieu of, and supersedes, any other FAR, DFAR, or other clause or
provision that addresses Government rights in computer software
under this License.
9. MISCELLANEOUS.
This License represents the complete agreement concerning subject
matter hereof. If any provision of this License is held to be
unenforceable, such provision shall be reformed only to the extent
necessary to make it enforceable. This License shall be governed
by the law of the jurisdiction specified in a notice contained
within the Original Software (except to the extent applicable law,
if any, provides otherwise), excluding such jurisdiction's
conflict-of-law provisions. Any litigation relating to this
License shall be subject to the jurisdiction of the courts located
in the jurisdiction and venue specified in a notice contained
within the Original Software, with the losing party responsible
for costs, including, without limitation, court costs and
reasonable attorneys' fees and expenses. The application of the
United Nations Convention on Contracts for the International Sale
of Goods is expressly excluded. Any law or regulation which
provides that the language of a contract shall be construed
against the drafter shall not apply to this License. You agree
that You alone are responsible for compliance with the United
States export administration regulations (and the export control
laws and regulation of any other countries) when You use,
distribute or otherwise make available any Covered Software.
10. RESPONSIBILITY FOR CLAIMS.
As between Initial Developer and the Contributors, each party is
responsible for claims and damages arising, directly or
indirectly, out of its utilization of rights under this License
and You agree to work with Initial Developer and Contributors to
distribute such responsibility on an equitable basis. Nothing
herein is intended or shall be deemed to constitute any admission
of liability.
--------------------------------------------------------------------
NOTICE PURSUANT TO SECTION 9 OF THE COMMON DEVELOPMENT AND
DISTRIBUTION LICENSE (CDDL)
For Covered Software in this distribution, this License shall
be governed by the laws of the State of California (excluding
conflict-of-law provisions).
Any litigation relating to this License shall be subject to the
jurisdiction of the Federal Courts of the Northern District of
California and the state courts of the State of California, with
venue lying in Santa Clara County, California.

27
vendor/github.com/howeyc/gopass/README.md сгенерированный поставляемый
Просмотреть файл

@ -1,27 +0,0 @@
# getpasswd in Go [![GoDoc](https://godoc.org/github.com/howeyc/gopass?status.svg)](https://godoc.org/github.com/howeyc/gopass) [![Build Status](https://secure.travis-ci.org/howeyc/gopass.png?branch=master)](http://travis-ci.org/howeyc/gopass)
Retrieve password from user terminal or piped input without echo.
Verified on BSD, Linux, and Windows.
Example:
```go
package main
import "fmt"
import "github.com/howeyc/gopass"
func main() {
fmt.Printf("Password: ")
// Silent. For printing *'s use gopass.GetPasswdMasked()
pass, err := gopass.GetPasswd()
if err != nil {
// Handle gopass.ErrInterrupted or getch() read error
}
// Do something with pass
}
```
Caution: Multi-byte characters not supported!

110
vendor/github.com/howeyc/gopass/pass.go сгенерированный поставляемый
Просмотреть файл

@ -1,110 +0,0 @@
package gopass
import (
"errors"
"fmt"
"io"
"os"
)
type FdReader interface {
io.Reader
Fd() uintptr
}
var defaultGetCh = func(r io.Reader) (byte, error) {
buf := make([]byte, 1)
if n, err := r.Read(buf); n == 0 || err != nil {
if err != nil {
return 0, err
}
return 0, io.EOF
}
return buf[0], nil
}
var (
maxLength = 512
ErrInterrupted = errors.New("interrupted")
ErrMaxLengthExceeded = fmt.Errorf("maximum byte limit (%v) exceeded", maxLength)
// Provide variable so that tests can provide a mock implementation.
getch = defaultGetCh
)
// getPasswd returns the input read from terminal.
// If prompt is not empty, it will be output as a prompt to the user
// If masked is true, typing will be matched by asterisks on the screen.
// Otherwise, typing will echo nothing.
func getPasswd(prompt string, masked bool, r FdReader, w io.Writer) ([]byte, error) {
var err error
var pass, bs, mask []byte
if masked {
bs = []byte("\b \b")
mask = []byte("*")
}
if isTerminal(r.Fd()) {
if oldState, err := makeRaw(r.Fd()); err != nil {
return pass, err
} else {
defer func() {
restore(r.Fd(), oldState)
fmt.Fprintln(w)
}()
}
}
if prompt != "" {
fmt.Fprint(w, prompt)
}
// Track total bytes read, not just bytes in the password. This ensures any
// errors that might flood the console with nil or -1 bytes infinitely are
// capped.
var counter int
for counter = 0; counter <= maxLength; counter++ {
if v, e := getch(r); e != nil {
err = e
break
} else if v == 127 || v == 8 {
if l := len(pass); l > 0 {
pass = pass[:l-1]
fmt.Fprint(w, string(bs))
}
} else if v == 13 || v == 10 {
break
} else if v == 3 {
err = ErrInterrupted
break
} else if v != 0 {
pass = append(pass, v)
fmt.Fprint(w, string(mask))
}
}
if counter > maxLength {
err = ErrMaxLengthExceeded
}
return pass, err
}
// GetPasswd returns the password read from the terminal without echoing input.
// The returned byte array does not include end-of-line characters.
func GetPasswd() ([]byte, error) {
return getPasswd("", false, os.Stdin, os.Stdout)
}
// GetPasswdMasked returns the password read from the terminal, echoing asterisks.
// The returned byte array does not include end-of-line characters.
func GetPasswdMasked() ([]byte, error) {
return getPasswd("", true, os.Stdin, os.Stdout)
}
// GetPasswdPrompt prompts the user and returns the password read from the terminal.
// If mask is true, then asterisks are echoed.
// The returned byte array does not include end-of-line characters.
func GetPasswdPrompt(prompt string, mask bool, r FdReader, w io.Writer) ([]byte, error) {
return getPasswd(prompt, mask, r, w)
}

25
vendor/github.com/howeyc/gopass/terminal.go сгенерированный поставляемый
Просмотреть файл

@ -1,25 +0,0 @@
// +build !solaris
package gopass
import "golang.org/x/crypto/ssh/terminal"
type terminalState struct {
state *terminal.State
}
func isTerminal(fd uintptr) bool {
return terminal.IsTerminal(int(fd))
}
func makeRaw(fd uintptr) (*terminalState, error) {
state, err := terminal.MakeRaw(int(fd))
return &terminalState{
state: state,
}, err
}
func restore(fd uintptr, oldState *terminalState) error {
return terminal.Restore(int(fd), oldState.state)
}

69
vendor/github.com/howeyc/gopass/terminal_solaris.go сгенерированный поставляемый
Просмотреть файл

@ -1,69 +0,0 @@
/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License, Version 1.0 only
* (the "License"). You may not use this file except in compliance
* with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
// Below is derived from Solaris source, so CDDL license is included.
package gopass
import (
"syscall"
"golang.org/x/sys/unix"
)
type terminalState struct {
state *unix.Termios
}
// isTerminal returns true if there is a terminal attached to the given
// file descriptor.
// Source: http://src.illumos.org/source/xref/illumos-gate/usr/src/lib/libbc/libc/gen/common/isatty.c
func isTerminal(fd uintptr) bool {
var termio unix.Termio
err := unix.IoctlSetTermio(int(fd), unix.TCGETA, &termio)
return err == nil
}
// makeRaw puts the terminal connected to the given file descriptor into raw
// mode and returns the previous state of the terminal so that it can be
// restored.
// Source: http://src.illumos.org/source/xref/illumos-gate/usr/src/lib/libast/common/uwin/getpass.c
func makeRaw(fd uintptr) (*terminalState, error) {
oldTermiosPtr, err := unix.IoctlGetTermios(int(fd), unix.TCGETS)
if err != nil {
return nil, err
}
oldTermios := *oldTermiosPtr
newTermios := oldTermios
newTermios.Lflag &^= syscall.ECHO | syscall.ECHOE | syscall.ECHOK | syscall.ECHONL
if err := unix.IoctlSetTermios(int(fd), unix.TCSETS, &newTermios); err != nil {
return nil, err
}
return &terminalState{
state: oldTermiosPtr,
}, nil
}
func restore(fd uintptr, oldState *terminalState) error {
return unix.IoctlSetTermios(int(fd), unix.TCSETS, oldState.state)
}

28
vendor/github.com/json-iterator/go/Gopkg.lock сгенерированный поставляемый
Просмотреть файл

@ -2,32 +2,20 @@
[[projects]]
name = "github.com/davecgh/go-spew"
packages = ["spew"]
revision = "346938d642f2ec3594ed81d874461961cd0faa76"
version = "v1.1.0"
[[projects]]
branch = "master"
name = "github.com/google/gofuzz"
name = "github.com/modern-go/concurrent"
packages = ["."]
revision = "24818f796faf91cd76ec7bddd72458fbced7a6c1"
revision = "e0a39a4cb4216ea8db28e22a69f4ec25610d513a"
version = "1.0.0"
[[projects]]
name = "github.com/pmezard/go-difflib"
packages = ["difflib"]
revision = "792786c7400a136282c1664665ae0a8db921c6c2"
version = "v1.0.0"
[[projects]]
name = "github.com/stretchr/testify"
packages = ["assert","require"]
revision = "69483b4bd14f5845b5a1e55bca19e954e827f1d0"
version = "v1.1.4"
name = "github.com/modern-go/reflect2"
packages = ["."]
revision = "4b7aa43c6742a2c18fdef89dd197aaae7dac7ccd"
version = "1.0.1"
[solve-meta]
analyzer-name = "dep"
analyzer-version = 1
inputs-digest = "f8b7cf3941d3792cbbd570bb53c093adaf774334d1162c651565c97a58dc9d09"
inputs-digest = "ea54a775e5a354cb015502d2e7aa4b74230fc77e894f34a838b268c25ec8eeb8"
solver-name = "gps-cdcl"
solver-version = 1

13
vendor/github.com/json-iterator/go/Gopkg.toml сгенерированный поставляемый
Просмотреть файл

@ -19,15 +19,8 @@
# name = "github.com/x/y"
# version = "2.4.0"
ignored = ["github.com/davecgh/go-spew*","github.com/google/gofuzz*","github.com/stretchr/testify*"]
[[constraint]]
name = "github.com/davecgh/go-spew"
version = "1.1.0"
[[constraint]]
branch = "master"
name = "github.com/google/gofuzz"
[[constraint]]
name = "github.com/stretchr/testify"
version = "1.1.4"
name = "github.com/modern-go/reflect2"
version = "1.0.1"

5
vendor/github.com/json-iterator/go/README.md сгенерированный поставляемый
Просмотреть файл

@ -8,6 +8,8 @@
A high-performance 100% compatible drop-in replacement of "encoding/json"
You can also use thrift like JSON using [thrift-iterator](https://github.com/thrift-iterator/go)
```
Go开发者们请加入我们滴滴出行平台技术部 taowen@didichuxing.com
```
@ -29,6 +31,9 @@ Raw Result (easyjson requires static code generation)
| easyjson encode | 883 ns/op | 576 B/op | 3 allocs/op |
| jsoniter encode | 837 ns/op | 384 B/op | 4 allocs/op |
Always benchmark with your own workload.
The result depends heavily on the data input.
# Usage
100% compatibility with standard lib

49
vendor/github.com/json-iterator/go/feature_adapter.go → vendor/github.com/json-iterator/go/adapter.go сгенерированный поставляемый
Просмотреть файл

@ -16,15 +16,6 @@ func Unmarshal(data []byte, v interface{}) error {
return ConfigDefault.Unmarshal(data, v)
}
func lastNotSpacePos(data []byte) int {
for i := len(data) - 1; i >= 0; i-- {
if data[i] != ' ' && data[i] != '\t' && data[i] != '\r' && data[i] != '\n' {
return i + 1
}
}
return 0
}
// UnmarshalFromString convenient method to read from string instead of []byte
func UnmarshalFromString(str string, v interface{}) error {
return ConfigDefault.UnmarshalFromString(str, v)
@ -71,6 +62,11 @@ type Decoder struct {
// Decode decode JSON into interface{}
func (adapter *Decoder) Decode(obj interface{}) error {
if adapter.iter.head == adapter.iter.tail && adapter.iter.reader != nil {
if !adapter.iter.loadMore() {
return io.EOF
}
}
adapter.iter.ReadVal(obj)
err := adapter.iter.Error
if err == io.EOF {
@ -81,7 +77,16 @@ func (adapter *Decoder) Decode(obj interface{}) error {
// More is there more?
func (adapter *Decoder) More() bool {
return adapter.iter.head != adapter.iter.tail
iter := adapter.iter
if iter.Error != nil {
return false
}
c := iter.nextToken()
if c == 0 {
return false
}
iter.unreadByte()
return c != ']' && c != '}'
}
// Buffered remaining buffer
@ -90,11 +95,21 @@ func (adapter *Decoder) Buffered() io.Reader {
return bytes.NewReader(remaining)
}
// UseNumber for number JSON element, use float64 or json.NumberValue (alias of string)
// UseNumber causes the Decoder to unmarshal a number into an interface{} as a
// Number instead of as a float64.
func (adapter *Decoder) UseNumber() {
origCfg := adapter.iter.cfg.configBeforeFrozen
origCfg.UseNumber = true
adapter.iter.cfg = origCfg.Froze().(*frozenConfig)
cfg := adapter.iter.cfg.configBeforeFrozen
cfg.UseNumber = true
adapter.iter.cfg = cfg.frozeWithCacheReuse(adapter.iter.cfg.extraExtensions)
}
// DisallowUnknownFields causes the Decoder to return an error when the destination
// is a struct and the input contains object keys which do not match any
// non-ignored, exported fields in the destination.
func (adapter *Decoder) DisallowUnknownFields() {
cfg := adapter.iter.cfg.configBeforeFrozen
cfg.DisallowUnknownFields = true
adapter.iter.cfg = cfg.frozeWithCacheReuse(adapter.iter.cfg.extraExtensions)
}
// NewEncoder same as json.NewEncoder
@ -117,14 +132,16 @@ func (adapter *Encoder) Encode(val interface{}) error {
// SetIndent set the indention. Prefix is not supported
func (adapter *Encoder) SetIndent(prefix, indent string) {
adapter.stream.cfg.indentionStep = len(indent)
config := adapter.stream.cfg.configBeforeFrozen
config.IndentionStep = len(indent)
adapter.stream.cfg = config.frozeWithCacheReuse(adapter.stream.cfg.extraExtensions)
}
// SetEscapeHTML escape html by default, set to false to disable
func (adapter *Encoder) SetEscapeHTML(escapeHTML bool) {
config := adapter.stream.cfg.configBeforeFrozen
config.EscapeHTML = escapeHTML
adapter.stream.cfg = config.Froze().(*frozenConfig)
adapter.stream.cfg = config.frozeWithCacheReuse(adapter.stream.cfg.extraExtensions)
}
// Valid reports whether data is a valid JSON encoding.

82
vendor/github.com/json-iterator/go/feature_any.go → vendor/github.com/json-iterator/go/any.go сгенерированный поставляемый
Просмотреть файл

@ -3,8 +3,11 @@ package jsoniter
import (
"errors"
"fmt"
"github.com/modern-go/reflect2"
"io"
"reflect"
"strconv"
"unsafe"
)
// Any generic object representation.
@ -25,7 +28,6 @@ type Any interface {
ToString() string
ToVal(val interface{})
Get(path ...interface{}) Any
// TODO: add Set
Size() int
Keys() []string
GetInterface() interface{}
@ -35,7 +37,7 @@ type Any interface {
type baseAny struct{}
func (any *baseAny) Get(path ...interface{}) Any {
return &invalidAny{baseAny{}, fmt.Errorf("Get %v from simple value", path)}
return &invalidAny{baseAny{}, fmt.Errorf("GetIndex %v from simple value", path)}
}
func (any *baseAny) Size() int {
@ -89,7 +91,7 @@ func Wrap(val interface{}) Any {
if isAny {
return asAny
}
typ := reflect.TypeOf(val)
typ := reflect2.TypeOf(val)
switch typ.Kind() {
case reflect.Slice:
return wrapArray(val)
@ -100,6 +102,9 @@ func Wrap(val interface{}) Any {
case reflect.String:
return WrapString(val.(string))
case reflect.Int:
if strconv.IntSize == 32 {
return WrapInt32(int32(val.(int)))
}
return WrapInt64(int64(val.(int)))
case reflect.Int8:
return WrapInt32(int32(val.(int8)))
@ -110,7 +115,15 @@ func Wrap(val interface{}) Any {
case reflect.Int64:
return WrapInt64(val.(int64))
case reflect.Uint:
if strconv.IntSize == 32 {
return WrapUint32(uint32(val.(uint)))
}
return WrapUint64(uint64(val.(uint)))
case reflect.Uintptr:
if ptrSize == 32 {
return WrapUint32(uint32(val.(uintptr)))
}
return WrapUint64(uint64(val.(uintptr)))
case reflect.Uint8:
return WrapUint32(uint32(val.(uint8)))
case reflect.Uint16:
@ -243,3 +256,66 @@ func locatePath(iter *Iterator, path []interface{}) Any {
}
return iter.readAny()
}
var anyType = reflect2.TypeOfPtr((*Any)(nil)).Elem()
func createDecoderOfAny(ctx *ctx, typ reflect2.Type) ValDecoder {
if typ == anyType {
return &directAnyCodec{}
}
if typ.Implements(anyType) {
return &anyCodec{
valType: typ,
}
}
return nil
}
func createEncoderOfAny(ctx *ctx, typ reflect2.Type) ValEncoder {
if typ == anyType {
return &directAnyCodec{}
}
if typ.Implements(anyType) {
return &anyCodec{
valType: typ,
}
}
return nil
}
type anyCodec struct {
valType reflect2.Type
}
func (codec *anyCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
panic("not implemented")
}
func (codec *anyCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
obj := codec.valType.UnsafeIndirect(ptr)
any := obj.(Any)
any.WriteTo(stream)
}
func (codec *anyCodec) IsEmpty(ptr unsafe.Pointer) bool {
obj := codec.valType.UnsafeIndirect(ptr)
any := obj.(Any)
return any.Size() == 0
}
type directAnyCodec struct {
}
func (codec *directAnyCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*(*Any)(ptr) = iter.readAny()
}
func (codec *directAnyCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
any := *(*Any)(ptr)
any.WriteTo(stream)
}
func (codec *directAnyCodec) IsEmpty(ptr unsafe.Pointer) bool {
any := *(*Any)(ptr)
return any.Size() == 0
}

0
vendor/github.com/json-iterator/go/feature_any_array.go → vendor/github.com/json-iterator/go/any_array.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_any_bool.go → vendor/github.com/json-iterator/go/any_bool.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_any_float.go → vendor/github.com/json-iterator/go/any_float.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_any_int32.go → vendor/github.com/json-iterator/go/any_int32.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_any_int64.go → vendor/github.com/json-iterator/go/any_int64.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_any_invalid.go → vendor/github.com/json-iterator/go/any_invalid.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_any_nil.go → vendor/github.com/json-iterator/go/any_nil.go сгенерированный поставляемый
Просмотреть файл

37
vendor/github.com/json-iterator/go/feature_any_number.go → vendor/github.com/json-iterator/go/any_number.go сгенерированный поставляемый
Просмотреть файл

@ -1,6 +1,9 @@
package jsoniter
import "unsafe"
import (
"io"
"unsafe"
)
type numberLazyAny struct {
baseAny
@ -29,7 +32,9 @@ func (any *numberLazyAny) ToInt() int {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadInt()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}
@ -37,7 +42,9 @@ func (any *numberLazyAny) ToInt32() int32 {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadInt32()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}
@ -45,7 +52,9 @@ func (any *numberLazyAny) ToInt64() int64 {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadInt64()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}
@ -53,7 +62,9 @@ func (any *numberLazyAny) ToUint() uint {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadUint()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}
@ -61,7 +72,9 @@ func (any *numberLazyAny) ToUint32() uint32 {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadUint32()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}
@ -69,7 +82,9 @@ func (any *numberLazyAny) ToUint64() uint64 {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadUint64()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}
@ -77,7 +92,9 @@ func (any *numberLazyAny) ToFloat32() float32 {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadFloat32()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}
@ -85,7 +102,9 @@ func (any *numberLazyAny) ToFloat64() float64 {
iter := any.cfg.BorrowIterator(any.buf)
defer any.cfg.ReturnIterator(iter)
val := iter.ReadFloat64()
any.err = iter.Error
if iter.Error != nil && iter.Error != io.EOF {
any.err = iter.Error
}
return val
}

0
vendor/github.com/json-iterator/go/feature_any_object.go → vendor/github.com/json-iterator/go/any_object.go сгенерированный поставляемый
Просмотреть файл

2
vendor/github.com/json-iterator/go/feature_any_string.go → vendor/github.com/json-iterator/go/any_str.go сгенерированный поставляемый
Просмотреть файл

@ -14,7 +14,7 @@ func (any *stringAny) Get(path ...interface{}) Any {
if len(path) == 0 {
return any
}
return &invalidAny{baseAny{}, fmt.Errorf("Get %v from simple value", path)}
return &invalidAny{baseAny{}, fmt.Errorf("GetIndex %v from simple value", path)}
}
func (any *stringAny) Parse() *Iterator {

0
vendor/github.com/json-iterator/go/feature_any_uint32.go → vendor/github.com/json-iterator/go/any_uint32.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_any_uint64.go → vendor/github.com/json-iterator/go/any_uint64.go сгенерированный поставляемый
Просмотреть файл

257
vendor/github.com/json-iterator/go/feature_config.go → vendor/github.com/json-iterator/go/config.go сгенерированный поставляемый
Просмотреть файл

@ -2,11 +2,13 @@ package jsoniter
import (
"encoding/json"
"errors"
"io"
"reflect"
"sync/atomic"
"sync"
"unsafe"
"github.com/modern-go/concurrent"
"github.com/modern-go/reflect2"
)
// Config customize how the API should behave.
@ -17,21 +19,12 @@ type Config struct {
EscapeHTML bool
SortMapKeys bool
UseNumber bool
DisallowUnknownFields bool
TagKey string
OnlyTaggedField bool
ValidateJsonRawMessage bool
ObjectFieldMustBeSimpleString bool
}
type frozenConfig struct {
configBeforeFrozen Config
sortMapKeys bool
indentionStep int
objectFieldMustBeSimpleString bool
decoderCache unsafe.Pointer
encoderCache unsafe.Pointer
extensions []Extension
streamPool chan *Stream
iteratorPool chan *Iterator
CaseSensitive bool
}
// API the public interface of this package.
@ -49,6 +42,8 @@ type API interface {
NewDecoder(reader io.Reader) *Decoder
Valid(data []byte) bool
RegisterExtension(extension Extension)
DecoderOf(typ reflect2.Type) ValDecoder
EncoderOf(typ reflect2.Type) ValEncoder
}
// ConfigDefault the default API
@ -70,35 +65,121 @@ var ConfigFastest = Config{
ObjectFieldMustBeSimpleString: true, // do not unescape object field
}.Froze()
type frozenConfig struct {
configBeforeFrozen Config
sortMapKeys bool
indentionStep int
objectFieldMustBeSimpleString bool
onlyTaggedField bool
disallowUnknownFields bool
decoderCache *concurrent.Map
encoderCache *concurrent.Map
encoderExtension Extension
decoderExtension Extension
extraExtensions []Extension
streamPool *sync.Pool
iteratorPool *sync.Pool
caseSensitive bool
}
func (cfg *frozenConfig) initCache() {
cfg.decoderCache = concurrent.NewMap()
cfg.encoderCache = concurrent.NewMap()
}
func (cfg *frozenConfig) addDecoderToCache(cacheKey uintptr, decoder ValDecoder) {
cfg.decoderCache.Store(cacheKey, decoder)
}
func (cfg *frozenConfig) addEncoderToCache(cacheKey uintptr, encoder ValEncoder) {
cfg.encoderCache.Store(cacheKey, encoder)
}
func (cfg *frozenConfig) getDecoderFromCache(cacheKey uintptr) ValDecoder {
decoder, found := cfg.decoderCache.Load(cacheKey)
if found {
return decoder.(ValDecoder)
}
return nil
}
func (cfg *frozenConfig) getEncoderFromCache(cacheKey uintptr) ValEncoder {
encoder, found := cfg.encoderCache.Load(cacheKey)
if found {
return encoder.(ValEncoder)
}
return nil
}
var cfgCache = concurrent.NewMap()
func getFrozenConfigFromCache(cfg Config) *frozenConfig {
obj, found := cfgCache.Load(cfg)
if found {
return obj.(*frozenConfig)
}
return nil
}
func addFrozenConfigToCache(cfg Config, frozenConfig *frozenConfig) {
cfgCache.Store(cfg, frozenConfig)
}
// Froze forge API from config
func (cfg Config) Froze() API {
// TODO: cache frozen config
frozenConfig := &frozenConfig{
api := &frozenConfig{
sortMapKeys: cfg.SortMapKeys,
indentionStep: cfg.IndentionStep,
objectFieldMustBeSimpleString: cfg.ObjectFieldMustBeSimpleString,
streamPool: make(chan *Stream, 16),
iteratorPool: make(chan *Iterator, 16),
onlyTaggedField: cfg.OnlyTaggedField,
disallowUnknownFields: cfg.DisallowUnknownFields,
caseSensitive: cfg.CaseSensitive,
}
atomic.StorePointer(&frozenConfig.decoderCache, unsafe.Pointer(&map[string]ValDecoder{}))
atomic.StorePointer(&frozenConfig.encoderCache, unsafe.Pointer(&map[string]ValEncoder{}))
api.streamPool = &sync.Pool{
New: func() interface{} {
return NewStream(api, nil, 512)
},
}
api.iteratorPool = &sync.Pool{
New: func() interface{} {
return NewIterator(api)
},
}
api.initCache()
encoderExtension := EncoderExtension{}
decoderExtension := DecoderExtension{}
if cfg.MarshalFloatWith6Digits {
frozenConfig.marshalFloatWith6Digits()
api.marshalFloatWith6Digits(encoderExtension)
}
if cfg.EscapeHTML {
frozenConfig.escapeHTML()
api.escapeHTML(encoderExtension)
}
if cfg.UseNumber {
frozenConfig.useNumber()
api.useNumber(decoderExtension)
}
if cfg.ValidateJsonRawMessage {
frozenConfig.validateJsonRawMessage()
api.validateJsonRawMessage(encoderExtension)
}
frozenConfig.configBeforeFrozen = cfg
return frozenConfig
api.encoderExtension = encoderExtension
api.decoderExtension = decoderExtension
api.configBeforeFrozen = cfg
return api
}
func (cfg *frozenConfig) validateJsonRawMessage() {
func (cfg Config) frozeWithCacheReuse(extraExtensions []Extension) *frozenConfig {
api := getFrozenConfigFromCache(cfg)
if api != nil {
return api
}
api = cfg.Froze().(*frozenConfig)
for _, extension := range extraExtensions {
api.RegisterExtension(extension)
}
addFrozenConfigToCache(cfg, api)
return api
}
func (cfg *frozenConfig) validateJsonRawMessage(extension EncoderExtension) {
encoder := &funcEncoder{func(ptr unsafe.Pointer, stream *Stream) {
rawMessage := *(*json.RawMessage)(ptr)
iter := cfg.BorrowIterator([]byte(rawMessage))
@ -110,20 +191,25 @@ func (cfg *frozenConfig) validateJsonRawMessage() {
stream.WriteRaw(string(rawMessage))
}
}, func(ptr unsafe.Pointer) bool {
return false
return len(*((*json.RawMessage)(ptr))) == 0
}}
cfg.addEncoderToCache(reflect.TypeOf((*json.RawMessage)(nil)).Elem(), encoder)
cfg.addEncoderToCache(reflect.TypeOf((*RawMessage)(nil)).Elem(), encoder)
extension[reflect2.TypeOfPtr((*json.RawMessage)(nil)).Elem()] = encoder
extension[reflect2.TypeOfPtr((*RawMessage)(nil)).Elem()] = encoder
}
func (cfg *frozenConfig) useNumber() {
cfg.addDecoderToCache(reflect.TypeOf((*interface{})(nil)).Elem(), &funcDecoder{func(ptr unsafe.Pointer, iter *Iterator) {
func (cfg *frozenConfig) useNumber(extension DecoderExtension) {
extension[reflect2.TypeOfPtr((*interface{})(nil)).Elem()] = &funcDecoder{func(ptr unsafe.Pointer, iter *Iterator) {
exitingValue := *((*interface{})(ptr))
if exitingValue != nil && reflect.TypeOf(exitingValue).Kind() == reflect.Ptr {
iter.ReadVal(exitingValue)
return
}
if iter.WhatIsNext() == NumberValue {
*((*interface{})(ptr)) = json.Number(iter.readNumberAsString())
} else {
*((*interface{})(ptr)) = iter.Read()
}
}})
}}
}
func (cfg *frozenConfig) getTagKey() string {
tagKey := cfg.configBeforeFrozen.TagKey
@ -134,7 +220,9 @@ func (cfg *frozenConfig) getTagKey() string {
}
func (cfg *frozenConfig) RegisterExtension(extension Extension) {
cfg.extensions = append(cfg.extensions, extension)
cfg.extraExtensions = append(cfg.extraExtensions, extension)
copied := cfg.configBeforeFrozen
cfg.configBeforeFrozen = copied
}
type lossyFloat32Encoder struct {
@ -144,10 +232,6 @@ func (encoder *lossyFloat32Encoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteFloat32Lossy(*((*float32)(ptr)))
}
func (encoder *lossyFloat32Encoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *lossyFloat32Encoder) IsEmpty(ptr unsafe.Pointer) bool {
return *((*float32)(ptr)) == 0
}
@ -159,20 +243,16 @@ func (encoder *lossyFloat64Encoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteFloat64Lossy(*((*float64)(ptr)))
}
func (encoder *lossyFloat64Encoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *lossyFloat64Encoder) IsEmpty(ptr unsafe.Pointer) bool {
return *((*float64)(ptr)) == 0
}
// EnableLossyFloatMarshalling keeps 10**(-6) precision
// for float variables for better performance.
func (cfg *frozenConfig) marshalFloatWith6Digits() {
func (cfg *frozenConfig) marshalFloatWith6Digits(extension EncoderExtension) {
// for better performance
cfg.addEncoderToCache(reflect.TypeOf((*float32)(nil)).Elem(), &lossyFloat32Encoder{})
cfg.addEncoderToCache(reflect.TypeOf((*float64)(nil)).Elem(), &lossyFloat64Encoder{})
extension[reflect2.TypeOfPtr((*float32)(nil)).Elem()] = &lossyFloat32Encoder{}
extension[reflect2.TypeOfPtr((*float64)(nil)).Elem()] = &lossyFloat64Encoder{}
}
type htmlEscapedStringEncoder struct {
@ -183,56 +263,12 @@ func (encoder *htmlEscapedStringEncoder) Encode(ptr unsafe.Pointer, stream *Stre
stream.WriteStringWithHTMLEscaped(str)
}
func (encoder *htmlEscapedStringEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *htmlEscapedStringEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return *((*string)(ptr)) == ""
}
func (cfg *frozenConfig) escapeHTML() {
cfg.addEncoderToCache(reflect.TypeOf((*string)(nil)).Elem(), &htmlEscapedStringEncoder{})
}
func (cfg *frozenConfig) addDecoderToCache(cacheKey reflect.Type, decoder ValDecoder) {
done := false
for !done {
ptr := atomic.LoadPointer(&cfg.decoderCache)
cache := *(*map[reflect.Type]ValDecoder)(ptr)
copied := map[reflect.Type]ValDecoder{}
for k, v := range cache {
copied[k] = v
}
copied[cacheKey] = decoder
done = atomic.CompareAndSwapPointer(&cfg.decoderCache, ptr, unsafe.Pointer(&copied))
}
}
func (cfg *frozenConfig) addEncoderToCache(cacheKey reflect.Type, encoder ValEncoder) {
done := false
for !done {
ptr := atomic.LoadPointer(&cfg.encoderCache)
cache := *(*map[reflect.Type]ValEncoder)(ptr)
copied := map[reflect.Type]ValEncoder{}
for k, v := range cache {
copied[k] = v
}
copied[cacheKey] = encoder
done = atomic.CompareAndSwapPointer(&cfg.encoderCache, ptr, unsafe.Pointer(&copied))
}
}
func (cfg *frozenConfig) getDecoderFromCache(cacheKey reflect.Type) ValDecoder {
ptr := atomic.LoadPointer(&cfg.decoderCache)
cache := *(*map[reflect.Type]ValDecoder)(ptr)
return cache[cacheKey]
}
func (cfg *frozenConfig) getEncoderFromCache(cacheKey reflect.Type) ValEncoder {
ptr := atomic.LoadPointer(&cfg.encoderCache)
cache := *(*map[reflect.Type]ValEncoder)(ptr)
return cache[cacheKey]
func (cfg *frozenConfig) escapeHTML(encoderExtension EncoderExtension) {
encoderExtension[reflect2.TypeOfPtr((*string)(nil)).Elem()] = &htmlEscapedStringEncoder{}
}
func (cfg *frozenConfig) cleanDecoders() {
@ -281,24 +317,22 @@ func (cfg *frozenConfig) MarshalIndent(v interface{}, prefix, indent string) ([]
}
newCfg := cfg.configBeforeFrozen
newCfg.IndentionStep = len(indent)
return newCfg.Froze().Marshal(v)
return newCfg.frozeWithCacheReuse(cfg.extraExtensions).Marshal(v)
}
func (cfg *frozenConfig) UnmarshalFromString(str string, v interface{}) error {
data := []byte(str)
data = data[:lastNotSpacePos(data)]
iter := cfg.BorrowIterator(data)
defer cfg.ReturnIterator(iter)
iter.ReadVal(v)
if iter.head == iter.tail {
iter.loadMore()
}
if iter.Error == io.EOF {
return nil
}
if iter.Error == nil {
iter.ReportError("UnmarshalFromString", "there are bytes left after unmarshal")
c := iter.nextToken()
if c == 0 {
if iter.Error == io.EOF {
return nil
}
return iter.Error
}
iter.ReportError("Unmarshal", "there are bytes left after unmarshal")
return iter.Error
}
@ -309,24 +343,17 @@ func (cfg *frozenConfig) Get(data []byte, path ...interface{}) Any {
}
func (cfg *frozenConfig) Unmarshal(data []byte, v interface{}) error {
data = data[:lastNotSpacePos(data)]
iter := cfg.BorrowIterator(data)
defer cfg.ReturnIterator(iter)
typ := reflect.TypeOf(v)
if typ.Kind() != reflect.Ptr {
// return non-pointer error
return errors.New("the second param must be ptr type")
}
iter.ReadVal(v)
if iter.head == iter.tail {
iter.loadMore()
}
if iter.Error == io.EOF {
return nil
}
if iter.Error == nil {
iter.ReportError("Unmarshal", "there are bytes left after unmarshal")
c := iter.nextToken()
if c == 0 {
if iter.Error == io.EOF {
return nil
}
return iter.Error
}
iter.ReportError("Unmarshal", "there are bytes left after unmarshal")
return iter.Error
}

31
vendor/github.com/json-iterator/go/feature_json_number.go сгенерированный поставляемый
Просмотреть файл

@ -1,31 +0,0 @@
package jsoniter
import (
"encoding/json"
"strconv"
)
type Number string
// String returns the literal text of the number.
func (n Number) String() string { return string(n) }
// Float64 returns the number as a float64.
func (n Number) Float64() (float64, error) {
return strconv.ParseFloat(string(n), 64)
}
// Int64 returns the number as an int64.
func (n Number) Int64() (int64, error) {
return strconv.ParseInt(string(n), 10, 64)
}
func CastJsonNumber(val interface{}) (string, bool) {
switch typedVal := val.(type) {
case json.Number:
return string(typedVal), true
case Number:
return string(typedVal), true
}
return "", false
}

727
vendor/github.com/json-iterator/go/feature_reflect.go сгенерированный поставляемый
Просмотреть файл

@ -1,727 +0,0 @@
package jsoniter
import (
"encoding"
"encoding/json"
"fmt"
"reflect"
"time"
"unsafe"
)
// ValDecoder is an internal type registered to cache as needed.
// Don't confuse jsoniter.ValDecoder with json.Decoder.
// For json.Decoder's adapter, refer to jsoniter.AdapterDecoder(todo link).
//
// Reflection on type to create decoders, which is then cached
// Reflection on value is avoided as we can, as the reflect.Value itself will allocate, with following exceptions
// 1. create instance of new value, for example *int will need a int to be allocated
// 2. append to slice, if the existing cap is not enough, allocate will be done using Reflect.New
// 3. assignment to map, both key and value will be reflect.Value
// For a simple struct binding, it will be reflect.Value free and allocation free
type ValDecoder interface {
Decode(ptr unsafe.Pointer, iter *Iterator)
}
// ValEncoder is an internal type registered to cache as needed.
// Don't confuse jsoniter.ValEncoder with json.Encoder.
// For json.Encoder's adapter, refer to jsoniter.AdapterEncoder(todo godoc link).
type ValEncoder interface {
IsEmpty(ptr unsafe.Pointer) bool
Encode(ptr unsafe.Pointer, stream *Stream)
EncodeInterface(val interface{}, stream *Stream)
}
type checkIsEmpty interface {
IsEmpty(ptr unsafe.Pointer) bool
}
// WriteToStream the default implementation for TypeEncoder method EncodeInterface
func WriteToStream(val interface{}, stream *Stream, encoder ValEncoder) {
e := (*emptyInterface)(unsafe.Pointer(&val))
if e.word == nil {
stream.WriteNil()
return
}
if reflect.TypeOf(val).Kind() == reflect.Ptr {
encoder.Encode(unsafe.Pointer(&e.word), stream)
} else {
encoder.Encode(e.word, stream)
}
}
var jsonNumberType reflect.Type
var jsoniterNumberType reflect.Type
var jsonRawMessageType reflect.Type
var jsoniterRawMessageType reflect.Type
var anyType reflect.Type
var marshalerType reflect.Type
var unmarshalerType reflect.Type
var textMarshalerType reflect.Type
var textUnmarshalerType reflect.Type
func init() {
jsonNumberType = reflect.TypeOf((*json.Number)(nil)).Elem()
jsoniterNumberType = reflect.TypeOf((*Number)(nil)).Elem()
jsonRawMessageType = reflect.TypeOf((*json.RawMessage)(nil)).Elem()
jsoniterRawMessageType = reflect.TypeOf((*RawMessage)(nil)).Elem()
anyType = reflect.TypeOf((*Any)(nil)).Elem()
marshalerType = reflect.TypeOf((*json.Marshaler)(nil)).Elem()
unmarshalerType = reflect.TypeOf((*json.Unmarshaler)(nil)).Elem()
textMarshalerType = reflect.TypeOf((*encoding.TextMarshaler)(nil)).Elem()
textUnmarshalerType = reflect.TypeOf((*encoding.TextUnmarshaler)(nil)).Elem()
}
type OptionalDecoder struct {
ValueType reflect.Type
ValueDecoder ValDecoder
}
func (decoder *OptionalDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
if iter.ReadNil() {
*((*unsafe.Pointer)(ptr)) = nil
} else {
if *((*unsafe.Pointer)(ptr)) == nil {
//pointer to null, we have to allocate memory to hold the value
value := reflect.New(decoder.ValueType)
newPtr := extractInterface(value.Interface()).word
decoder.ValueDecoder.Decode(newPtr, iter)
*((*uintptr)(ptr)) = uintptr(newPtr)
} else {
//reuse existing instance
decoder.ValueDecoder.Decode(*((*unsafe.Pointer)(ptr)), iter)
}
}
}
type deferenceDecoder struct {
// only to deference a pointer
valueType reflect.Type
valueDecoder ValDecoder
}
func (decoder *deferenceDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
if *((*unsafe.Pointer)(ptr)) == nil {
//pointer to null, we have to allocate memory to hold the value
value := reflect.New(decoder.valueType)
newPtr := extractInterface(value.Interface()).word
decoder.valueDecoder.Decode(newPtr, iter)
*((*uintptr)(ptr)) = uintptr(newPtr)
} else {
//reuse existing instance
decoder.valueDecoder.Decode(*((*unsafe.Pointer)(ptr)), iter)
}
}
type OptionalEncoder struct {
ValueEncoder ValEncoder
}
func (encoder *OptionalEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if *((*unsafe.Pointer)(ptr)) == nil {
stream.WriteNil()
} else {
encoder.ValueEncoder.Encode(*((*unsafe.Pointer)(ptr)), stream)
}
}
func (encoder *OptionalEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *OptionalEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return *((*unsafe.Pointer)(ptr)) == nil
}
type optionalMapEncoder struct {
valueEncoder ValEncoder
}
func (encoder *optionalMapEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if *((*unsafe.Pointer)(ptr)) == nil {
stream.WriteNil()
} else {
encoder.valueEncoder.Encode(*((*unsafe.Pointer)(ptr)), stream)
}
}
func (encoder *optionalMapEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *optionalMapEncoder) IsEmpty(ptr unsafe.Pointer) bool {
p := *((*unsafe.Pointer)(ptr))
return p == nil || encoder.valueEncoder.IsEmpty(p)
}
type placeholderEncoder struct {
cfg *frozenConfig
cacheKey reflect.Type
}
func (encoder *placeholderEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
encoder.getRealEncoder().Encode(ptr, stream)
}
func (encoder *placeholderEncoder) EncodeInterface(val interface{}, stream *Stream) {
encoder.getRealEncoder().EncodeInterface(val, stream)
}
func (encoder *placeholderEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.getRealEncoder().IsEmpty(ptr)
}
func (encoder *placeholderEncoder) getRealEncoder() ValEncoder {
for i := 0; i < 500; i++ {
realDecoder := encoder.cfg.getEncoderFromCache(encoder.cacheKey)
_, isPlaceholder := realDecoder.(*placeholderEncoder)
if isPlaceholder {
time.Sleep(10 * time.Millisecond)
} else {
return realDecoder
}
}
panic(fmt.Sprintf("real encoder not found for cache key: %v", encoder.cacheKey))
}
type placeholderDecoder struct {
cfg *frozenConfig
cacheKey reflect.Type
}
func (decoder *placeholderDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
for i := 0; i < 500; i++ {
realDecoder := decoder.cfg.getDecoderFromCache(decoder.cacheKey)
_, isPlaceholder := realDecoder.(*placeholderDecoder)
if isPlaceholder {
time.Sleep(10 * time.Millisecond)
} else {
realDecoder.Decode(ptr, iter)
return
}
}
panic(fmt.Sprintf("real decoder not found for cache key: %v", decoder.cacheKey))
}
// emptyInterface is the header for an interface{} value.
type emptyInterface struct {
typ unsafe.Pointer
word unsafe.Pointer
}
// emptyInterface is the header for an interface with method (not interface{})
type nonEmptyInterface struct {
// see ../runtime/iface.go:/Itab
itab *struct {
ityp unsafe.Pointer // static interface type
typ unsafe.Pointer // dynamic concrete type
link unsafe.Pointer
bad int32
unused int32
fun [100000]unsafe.Pointer // method table
}
word unsafe.Pointer
}
// ReadVal copy the underlying JSON into go interface, same as json.Unmarshal
func (iter *Iterator) ReadVal(obj interface{}) {
typ := reflect.TypeOf(obj)
cacheKey := typ.Elem()
decoder, err := decoderOfType(iter.cfg, cacheKey)
if err != nil {
iter.Error = err
return
}
e := (*emptyInterface)(unsafe.Pointer(&obj))
decoder.Decode(e.word, iter)
}
// WriteVal copy the go interface into underlying JSON, same as json.Marshal
func (stream *Stream) WriteVal(val interface{}) {
if nil == val {
stream.WriteNil()
return
}
typ := reflect.TypeOf(val)
cacheKey := typ
encoder, err := encoderOfType(stream.cfg, cacheKey)
if err != nil {
stream.Error = err
return
}
encoder.EncodeInterface(val, stream)
}
type prefix string
func (p prefix) addToDecoder(decoder ValDecoder, err error) (ValDecoder, error) {
if err != nil {
return nil, fmt.Errorf("%s: %s", p, err.Error())
}
return decoder, err
}
func (p prefix) addToEncoder(encoder ValEncoder, err error) (ValEncoder, error) {
if err != nil {
return nil, fmt.Errorf("%s: %s", p, err.Error())
}
return encoder, err
}
func decoderOfType(cfg *frozenConfig, typ reflect.Type) (ValDecoder, error) {
cacheKey := typ
decoder := cfg.getDecoderFromCache(cacheKey)
if decoder != nil {
return decoder, nil
}
decoder = getTypeDecoderFromExtension(cfg, typ)
if decoder != nil {
cfg.addDecoderToCache(cacheKey, decoder)
return decoder, nil
}
decoder = &placeholderDecoder{cfg: cfg, cacheKey: cacheKey}
cfg.addDecoderToCache(cacheKey, decoder)
decoder, err := createDecoderOfType(cfg, typ)
for _, extension := range extensions {
decoder = extension.DecorateDecoder(typ, decoder)
}
for _, extension := range cfg.extensions {
decoder = extension.DecorateDecoder(typ, decoder)
}
cfg.addDecoderToCache(cacheKey, decoder)
return decoder, err
}
func createDecoderOfType(cfg *frozenConfig, typ reflect.Type) (ValDecoder, error) {
typeName := typ.String()
if typ == jsonRawMessageType {
return &jsonRawMessageCodec{}, nil
}
if typ == jsoniterRawMessageType {
return &jsoniterRawMessageCodec{}, nil
}
if typ.AssignableTo(jsonNumberType) {
return &jsonNumberCodec{}, nil
}
if typ.AssignableTo(jsoniterNumberType) {
return &jsoniterNumberCodec{}, nil
}
if typ.Implements(unmarshalerType) {
templateInterface := reflect.New(typ).Elem().Interface()
var decoder ValDecoder = &unmarshalerDecoder{extractInterface(templateInterface)}
if typ.Kind() == reflect.Ptr {
decoder = &OptionalDecoder{typ.Elem(), decoder}
}
return decoder, nil
}
if reflect.PtrTo(typ).Implements(unmarshalerType) {
templateInterface := reflect.New(typ).Interface()
var decoder ValDecoder = &unmarshalerDecoder{extractInterface(templateInterface)}
return decoder, nil
}
if typ.Implements(textUnmarshalerType) {
templateInterface := reflect.New(typ).Elem().Interface()
var decoder ValDecoder = &textUnmarshalerDecoder{extractInterface(templateInterface)}
if typ.Kind() == reflect.Ptr {
decoder = &OptionalDecoder{typ.Elem(), decoder}
}
return decoder, nil
}
if reflect.PtrTo(typ).Implements(textUnmarshalerType) {
templateInterface := reflect.New(typ).Interface()
var decoder ValDecoder = &textUnmarshalerDecoder{extractInterface(templateInterface)}
return decoder, nil
}
if typ.Kind() == reflect.Slice && typ.Elem().Kind() == reflect.Uint8 {
sliceDecoder, err := prefix("[slice]").addToDecoder(decoderOfSlice(cfg, typ))
if err != nil {
return nil, err
}
return &base64Codec{sliceDecoder: sliceDecoder}, nil
}
if typ.Implements(anyType) {
return &anyCodec{}, nil
}
switch typ.Kind() {
case reflect.String:
if typeName != "string" {
return decoderOfType(cfg, reflect.TypeOf((*string)(nil)).Elem())
}
return &stringCodec{}, nil
case reflect.Int:
if typeName != "int" {
return decoderOfType(cfg, reflect.TypeOf((*int)(nil)).Elem())
}
return &intCodec{}, nil
case reflect.Int8:
if typeName != "int8" {
return decoderOfType(cfg, reflect.TypeOf((*int8)(nil)).Elem())
}
return &int8Codec{}, nil
case reflect.Int16:
if typeName != "int16" {
return decoderOfType(cfg, reflect.TypeOf((*int16)(nil)).Elem())
}
return &int16Codec{}, nil
case reflect.Int32:
if typeName != "int32" {
return decoderOfType(cfg, reflect.TypeOf((*int32)(nil)).Elem())
}
return &int32Codec{}, nil
case reflect.Int64:
if typeName != "int64" {
return decoderOfType(cfg, reflect.TypeOf((*int64)(nil)).Elem())
}
return &int64Codec{}, nil
case reflect.Uint:
if typeName != "uint" {
return decoderOfType(cfg, reflect.TypeOf((*uint)(nil)).Elem())
}
return &uintCodec{}, nil
case reflect.Uint8:
if typeName != "uint8" {
return decoderOfType(cfg, reflect.TypeOf((*uint8)(nil)).Elem())
}
return &uint8Codec{}, nil
case reflect.Uint16:
if typeName != "uint16" {
return decoderOfType(cfg, reflect.TypeOf((*uint16)(nil)).Elem())
}
return &uint16Codec{}, nil
case reflect.Uint32:
if typeName != "uint32" {
return decoderOfType(cfg, reflect.TypeOf((*uint32)(nil)).Elem())
}
return &uint32Codec{}, nil
case reflect.Uintptr:
if typeName != "uintptr" {
return decoderOfType(cfg, reflect.TypeOf((*uintptr)(nil)).Elem())
}
return &uintptrCodec{}, nil
case reflect.Uint64:
if typeName != "uint64" {
return decoderOfType(cfg, reflect.TypeOf((*uint64)(nil)).Elem())
}
return &uint64Codec{}, nil
case reflect.Float32:
if typeName != "float32" {
return decoderOfType(cfg, reflect.TypeOf((*float32)(nil)).Elem())
}
return &float32Codec{}, nil
case reflect.Float64:
if typeName != "float64" {
return decoderOfType(cfg, reflect.TypeOf((*float64)(nil)).Elem())
}
return &float64Codec{}, nil
case reflect.Bool:
if typeName != "bool" {
return decoderOfType(cfg, reflect.TypeOf((*bool)(nil)).Elem())
}
return &boolCodec{}, nil
case reflect.Interface:
if typ.NumMethod() == 0 {
return &emptyInterfaceCodec{}, nil
}
return &nonEmptyInterfaceCodec{}, nil
case reflect.Struct:
return prefix(fmt.Sprintf("[%s]", typeName)).addToDecoder(decoderOfStruct(cfg, typ))
case reflect.Array:
return prefix("[array]").addToDecoder(decoderOfArray(cfg, typ))
case reflect.Slice:
return prefix("[slice]").addToDecoder(decoderOfSlice(cfg, typ))
case reflect.Map:
return prefix("[map]").addToDecoder(decoderOfMap(cfg, typ))
case reflect.Ptr:
return prefix("[optional]").addToDecoder(decoderOfOptional(cfg, typ))
default:
return nil, fmt.Errorf("unsupported type: %v", typ)
}
}
func encoderOfType(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
cacheKey := typ
encoder := cfg.getEncoderFromCache(cacheKey)
if encoder != nil {
return encoder, nil
}
encoder = getTypeEncoderFromExtension(cfg, typ)
if encoder != nil {
cfg.addEncoderToCache(cacheKey, encoder)
return encoder, nil
}
encoder = &placeholderEncoder{cfg: cfg, cacheKey: cacheKey}
cfg.addEncoderToCache(cacheKey, encoder)
encoder, err := createEncoderOfType(cfg, typ)
for _, extension := range extensions {
encoder = extension.DecorateEncoder(typ, encoder)
}
for _, extension := range cfg.extensions {
encoder = extension.DecorateEncoder(typ, encoder)
}
cfg.addEncoderToCache(cacheKey, encoder)
return encoder, err
}
func createEncoderOfType(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
if typ == jsonRawMessageType {
return &jsonRawMessageCodec{}, nil
}
if typ == jsoniterRawMessageType {
return &jsoniterRawMessageCodec{}, nil
}
if typ.AssignableTo(jsonNumberType) {
return &jsonNumberCodec{}, nil
}
if typ.AssignableTo(jsoniterNumberType) {
return &jsoniterNumberCodec{}, nil
}
if typ.Implements(marshalerType) {
checkIsEmpty, err := createCheckIsEmpty(cfg, typ)
if err != nil {
return nil, err
}
templateInterface := reflect.New(typ).Elem().Interface()
var encoder ValEncoder = &marshalerEncoder{
templateInterface: extractInterface(templateInterface),
checkIsEmpty: checkIsEmpty,
}
if typ.Kind() == reflect.Ptr {
encoder = &OptionalEncoder{encoder}
}
return encoder, nil
}
if reflect.PtrTo(typ).Implements(marshalerType) {
checkIsEmpty, err := createCheckIsEmpty(cfg, reflect.PtrTo(typ))
if err != nil {
return nil, err
}
templateInterface := reflect.New(typ).Interface()
var encoder ValEncoder = &marshalerEncoder{
templateInterface: extractInterface(templateInterface),
checkIsEmpty: checkIsEmpty,
}
return encoder, nil
}
if typ.Implements(textMarshalerType) {
checkIsEmpty, err := createCheckIsEmpty(cfg, typ)
if err != nil {
return nil, err
}
templateInterface := reflect.New(typ).Elem().Interface()
var encoder ValEncoder = &textMarshalerEncoder{
templateInterface: extractInterface(templateInterface),
checkIsEmpty: checkIsEmpty,
}
if typ.Kind() == reflect.Ptr {
encoder = &OptionalEncoder{encoder}
}
return encoder, nil
}
if typ.Kind() == reflect.Slice && typ.Elem().Kind() == reflect.Uint8 {
return &base64Codec{}, nil
}
if typ.Implements(anyType) {
return &anyCodec{}, nil
}
return createEncoderOfSimpleType(cfg, typ)
}
func createCheckIsEmpty(cfg *frozenConfig, typ reflect.Type) (checkIsEmpty, error) {
kind := typ.Kind()
switch kind {
case reflect.String:
return &stringCodec{}, nil
case reflect.Int:
return &intCodec{}, nil
case reflect.Int8:
return &int8Codec{}, nil
case reflect.Int16:
return &int16Codec{}, nil
case reflect.Int32:
return &int32Codec{}, nil
case reflect.Int64:
return &int64Codec{}, nil
case reflect.Uint:
return &uintCodec{}, nil
case reflect.Uint8:
return &uint8Codec{}, nil
case reflect.Uint16:
return &uint16Codec{}, nil
case reflect.Uint32:
return &uint32Codec{}, nil
case reflect.Uintptr:
return &uintptrCodec{}, nil
case reflect.Uint64:
return &uint64Codec{}, nil
case reflect.Float32:
return &float32Codec{}, nil
case reflect.Float64:
return &float64Codec{}, nil
case reflect.Bool:
return &boolCodec{}, nil
case reflect.Interface:
if typ.NumMethod() == 0 {
return &emptyInterfaceCodec{}, nil
}
return &nonEmptyInterfaceCodec{}, nil
case reflect.Struct:
return &structEncoder{}, nil
case reflect.Array:
return &arrayEncoder{}, nil
case reflect.Slice:
return &sliceEncoder{}, nil
case reflect.Map:
return encoderOfMap(cfg, typ)
case reflect.Ptr:
return &OptionalEncoder{}, nil
default:
return nil, fmt.Errorf("unsupported type: %v", typ)
}
}
func createEncoderOfSimpleType(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
typeName := typ.String()
kind := typ.Kind()
switch kind {
case reflect.String:
if typeName != "string" {
return encoderOfType(cfg, reflect.TypeOf((*string)(nil)).Elem())
}
return &stringCodec{}, nil
case reflect.Int:
if typeName != "int" {
return encoderOfType(cfg, reflect.TypeOf((*int)(nil)).Elem())
}
return &intCodec{}, nil
case reflect.Int8:
if typeName != "int8" {
return encoderOfType(cfg, reflect.TypeOf((*int8)(nil)).Elem())
}
return &int8Codec{}, nil
case reflect.Int16:
if typeName != "int16" {
return encoderOfType(cfg, reflect.TypeOf((*int16)(nil)).Elem())
}
return &int16Codec{}, nil
case reflect.Int32:
if typeName != "int32" {
return encoderOfType(cfg, reflect.TypeOf((*int32)(nil)).Elem())
}
return &int32Codec{}, nil
case reflect.Int64:
if typeName != "int64" {
return encoderOfType(cfg, reflect.TypeOf((*int64)(nil)).Elem())
}
return &int64Codec{}, nil
case reflect.Uint:
if typeName != "uint" {
return encoderOfType(cfg, reflect.TypeOf((*uint)(nil)).Elem())
}
return &uintCodec{}, nil
case reflect.Uint8:
if typeName != "uint8" {
return encoderOfType(cfg, reflect.TypeOf((*uint8)(nil)).Elem())
}
return &uint8Codec{}, nil
case reflect.Uint16:
if typeName != "uint16" {
return encoderOfType(cfg, reflect.TypeOf((*uint16)(nil)).Elem())
}
return &uint16Codec{}, nil
case reflect.Uint32:
if typeName != "uint32" {
return encoderOfType(cfg, reflect.TypeOf((*uint32)(nil)).Elem())
}
return &uint32Codec{}, nil
case reflect.Uintptr:
if typeName != "uintptr" {
return encoderOfType(cfg, reflect.TypeOf((*uintptr)(nil)).Elem())
}
return &uintptrCodec{}, nil
case reflect.Uint64:
if typeName != "uint64" {
return encoderOfType(cfg, reflect.TypeOf((*uint64)(nil)).Elem())
}
return &uint64Codec{}, nil
case reflect.Float32:
if typeName != "float32" {
return encoderOfType(cfg, reflect.TypeOf((*float32)(nil)).Elem())
}
return &float32Codec{}, nil
case reflect.Float64:
if typeName != "float64" {
return encoderOfType(cfg, reflect.TypeOf((*float64)(nil)).Elem())
}
return &float64Codec{}, nil
case reflect.Bool:
if typeName != "bool" {
return encoderOfType(cfg, reflect.TypeOf((*bool)(nil)).Elem())
}
return &boolCodec{}, nil
case reflect.Interface:
if typ.NumMethod() == 0 {
return &emptyInterfaceCodec{}, nil
}
return &nonEmptyInterfaceCodec{}, nil
case reflect.Struct:
return prefix(fmt.Sprintf("[%s]", typeName)).addToEncoder(encoderOfStruct(cfg, typ))
case reflect.Array:
return prefix("[array]").addToEncoder(encoderOfArray(cfg, typ))
case reflect.Slice:
return prefix("[slice]").addToEncoder(encoderOfSlice(cfg, typ))
case reflect.Map:
return prefix("[map]").addToEncoder(encoderOfMap(cfg, typ))
case reflect.Ptr:
return prefix("[optional]").addToEncoder(encoderOfOptional(cfg, typ))
default:
return nil, fmt.Errorf("unsupported type: %v", typ)
}
}
func decoderOfOptional(cfg *frozenConfig, typ reflect.Type) (ValDecoder, error) {
elemType := typ.Elem()
decoder, err := decoderOfType(cfg, elemType)
if err != nil {
return nil, err
}
return &OptionalDecoder{elemType, decoder}, nil
}
func encoderOfOptional(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
elemType := typ.Elem()
elemEncoder, err := encoderOfType(cfg, elemType)
if err != nil {
return nil, err
}
encoder := &OptionalEncoder{elemEncoder}
if elemType.Kind() == reflect.Map {
encoder = &OptionalEncoder{encoder}
}
return encoder, nil
}
func decoderOfMap(cfg *frozenConfig, typ reflect.Type) (ValDecoder, error) {
decoder, err := decoderOfType(cfg, typ.Elem())
if err != nil {
return nil, err
}
mapInterface := reflect.New(typ).Interface()
return &mapDecoder{typ, typ.Key(), typ.Elem(), decoder, extractInterface(mapInterface)}, nil
}
func extractInterface(val interface{}) emptyInterface {
return *((*emptyInterface)(unsafe.Pointer(&val)))
}
func encoderOfMap(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
elemType := typ.Elem()
encoder, err := encoderOfType(cfg, elemType)
if err != nil {
return nil, err
}
mapInterface := reflect.New(typ).Elem().Interface()
if cfg.sortMapKeys {
return &sortKeysMapEncoder{typ, elemType, encoder, *((*emptyInterface)(unsafe.Pointer(&mapInterface)))}, nil
}
return &mapEncoder{typ, elemType, encoder, *((*emptyInterface)(unsafe.Pointer(&mapInterface)))}, nil
}

99
vendor/github.com/json-iterator/go/feature_reflect_array.go сгенерированный поставляемый
Просмотреть файл

@ -1,99 +0,0 @@
package jsoniter
import (
"fmt"
"io"
"reflect"
"unsafe"
)
func decoderOfArray(cfg *frozenConfig, typ reflect.Type) (ValDecoder, error) {
decoder, err := decoderOfType(cfg, typ.Elem())
if err != nil {
return nil, err
}
return &arrayDecoder{typ, typ.Elem(), decoder}, nil
}
func encoderOfArray(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
encoder, err := encoderOfType(cfg, typ.Elem())
if err != nil {
return nil, err
}
if typ.Elem().Kind() == reflect.Map {
encoder = &OptionalEncoder{encoder}
}
return &arrayEncoder{typ, typ.Elem(), encoder}, nil
}
type arrayEncoder struct {
arrayType reflect.Type
elemType reflect.Type
elemEncoder ValEncoder
}
func (encoder *arrayEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteArrayStart()
elemPtr := unsafe.Pointer(ptr)
encoder.elemEncoder.Encode(elemPtr, stream)
for i := 1; i < encoder.arrayType.Len(); i++ {
stream.WriteMore()
elemPtr = unsafe.Pointer(uintptr(elemPtr) + encoder.elemType.Size())
encoder.elemEncoder.Encode(unsafe.Pointer(elemPtr), stream)
}
stream.WriteArrayEnd()
if stream.Error != nil && stream.Error != io.EOF {
stream.Error = fmt.Errorf("%v: %s", encoder.arrayType, stream.Error.Error())
}
}
func (encoder *arrayEncoder) EncodeInterface(val interface{}, stream *Stream) {
// special optimization for interface{}
e := (*emptyInterface)(unsafe.Pointer(&val))
if e.word == nil {
stream.WriteArrayStart()
stream.WriteNil()
stream.WriteArrayEnd()
return
}
elemType := encoder.arrayType.Elem()
if encoder.arrayType.Len() == 1 && (elemType.Kind() == reflect.Ptr || elemType.Kind() == reflect.Map) {
ptr := uintptr(e.word)
e.word = unsafe.Pointer(&ptr)
}
if reflect.TypeOf(val).Kind() == reflect.Ptr {
encoder.Encode(unsafe.Pointer(&e.word), stream)
} else {
encoder.Encode(e.word, stream)
}
}
func (encoder *arrayEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return false
}
type arrayDecoder struct {
arrayType reflect.Type
elemType reflect.Type
elemDecoder ValDecoder
}
func (decoder *arrayDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.doDecode(ptr, iter)
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.arrayType, iter.Error.Error())
}
}
func (decoder *arrayDecoder) doDecode(ptr unsafe.Pointer, iter *Iterator) {
offset := uintptr(0)
iter.ReadArrayCB(func(iter *Iterator) bool {
if offset < decoder.arrayType.Size() {
decoder.elemDecoder.Decode(unsafe.Pointer(uintptr(ptr)+offset), iter)
offset += decoder.elemType.Size()
} else {
iter.Skip()
}
return true
})
}

244
vendor/github.com/json-iterator/go/feature_reflect_map.go сгенерированный поставляемый
Просмотреть файл

@ -1,244 +0,0 @@
package jsoniter
import (
"encoding"
"encoding/json"
"reflect"
"sort"
"strconv"
"unsafe"
)
type mapDecoder struct {
mapType reflect.Type
keyType reflect.Type
elemType reflect.Type
elemDecoder ValDecoder
mapInterface emptyInterface
}
func (decoder *mapDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
// dark magic to cast unsafe.Pointer back to interface{} using reflect.Type
mapInterface := decoder.mapInterface
mapInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&mapInterface))
realVal := reflect.ValueOf(*realInterface).Elem()
if iter.ReadNil() {
realVal.Set(reflect.Zero(decoder.mapType))
return
}
if realVal.IsNil() {
realVal.Set(reflect.MakeMap(realVal.Type()))
}
iter.ReadMapCB(func(iter *Iterator, keyStr string) bool {
elem := reflect.New(decoder.elemType)
decoder.elemDecoder.Decode(unsafe.Pointer(elem.Pointer()), iter)
// to put into map, we have to use reflection
keyType := decoder.keyType
// TODO: remove this from loop
switch {
case keyType.Kind() == reflect.String:
realVal.SetMapIndex(reflect.ValueOf(keyStr).Convert(keyType), elem.Elem())
return true
case keyType.Implements(textUnmarshalerType):
textUnmarshaler := reflect.New(keyType.Elem()).Interface().(encoding.TextUnmarshaler)
err := textUnmarshaler.UnmarshalText([]byte(keyStr))
if err != nil {
iter.ReportError("read map key as TextUnmarshaler", err.Error())
return false
}
realVal.SetMapIndex(reflect.ValueOf(textUnmarshaler), elem.Elem())
return true
case reflect.PtrTo(keyType).Implements(textUnmarshalerType):
textUnmarshaler := reflect.New(keyType).Interface().(encoding.TextUnmarshaler)
err := textUnmarshaler.UnmarshalText([]byte(keyStr))
if err != nil {
iter.ReportError("read map key as TextUnmarshaler", err.Error())
return false
}
realVal.SetMapIndex(reflect.ValueOf(textUnmarshaler).Elem(), elem.Elem())
return true
default:
switch keyType.Kind() {
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
n, err := strconv.ParseInt(keyStr, 10, 64)
if err != nil || reflect.Zero(keyType).OverflowInt(n) {
iter.ReportError("read map key as int64", "read int64 failed")
return false
}
realVal.SetMapIndex(reflect.ValueOf(n).Convert(keyType), elem.Elem())
return true
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
n, err := strconv.ParseUint(keyStr, 10, 64)
if err != nil || reflect.Zero(keyType).OverflowUint(n) {
iter.ReportError("read map key as uint64", "read uint64 failed")
return false
}
realVal.SetMapIndex(reflect.ValueOf(n).Convert(keyType), elem.Elem())
return true
}
}
iter.ReportError("read map key", "unexpected map key type "+keyType.String())
return true
})
}
type mapEncoder struct {
mapType reflect.Type
elemType reflect.Type
elemEncoder ValEncoder
mapInterface emptyInterface
}
func (encoder *mapEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
mapInterface := encoder.mapInterface
mapInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&mapInterface))
realVal := reflect.ValueOf(*realInterface)
stream.WriteObjectStart()
for i, key := range realVal.MapKeys() {
if i != 0 {
stream.WriteMore()
}
encodeMapKey(key, stream)
if stream.indention > 0 {
stream.writeTwoBytes(byte(':'), byte(' '))
} else {
stream.writeByte(':')
}
val := realVal.MapIndex(key).Interface()
encoder.elemEncoder.EncodeInterface(val, stream)
}
stream.WriteObjectEnd()
}
func encodeMapKey(key reflect.Value, stream *Stream) {
if key.Kind() == reflect.String {
stream.WriteString(key.String())
return
}
if tm, ok := key.Interface().(encoding.TextMarshaler); ok {
buf, err := tm.MarshalText()
if err != nil {
stream.Error = err
return
}
stream.writeByte('"')
stream.Write(buf)
stream.writeByte('"')
return
}
switch key.Kind() {
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
stream.writeByte('"')
stream.WriteInt64(key.Int())
stream.writeByte('"')
return
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
stream.writeByte('"')
stream.WriteUint64(key.Uint())
stream.writeByte('"')
return
}
stream.Error = &json.UnsupportedTypeError{Type: key.Type()}
}
func (encoder *mapEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *mapEncoder) IsEmpty(ptr unsafe.Pointer) bool {
mapInterface := encoder.mapInterface
mapInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&mapInterface))
realVal := reflect.ValueOf(*realInterface)
return realVal.Len() == 0
}
type sortKeysMapEncoder struct {
mapType reflect.Type
elemType reflect.Type
elemEncoder ValEncoder
mapInterface emptyInterface
}
func (encoder *sortKeysMapEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
mapInterface := encoder.mapInterface
mapInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&mapInterface))
realVal := reflect.ValueOf(*realInterface)
// Extract and sort the keys.
keys := realVal.MapKeys()
sv := stringValues(make([]reflectWithString, len(keys)))
for i, v := range keys {
sv[i].v = v
if err := sv[i].resolve(); err != nil {
stream.Error = err
return
}
}
sort.Sort(sv)
stream.WriteObjectStart()
for i, key := range sv {
if i != 0 {
stream.WriteMore()
}
stream.WriteVal(key.s) // might need html escape, so can not WriteString directly
if stream.indention > 0 {
stream.writeTwoBytes(byte(':'), byte(' '))
} else {
stream.writeByte(':')
}
val := realVal.MapIndex(key.v).Interface()
encoder.elemEncoder.EncodeInterface(val, stream)
}
stream.WriteObjectEnd()
}
// stringValues is a slice of reflect.Value holding *reflect.StringValue.
// It implements the methods to sort by string.
type stringValues []reflectWithString
type reflectWithString struct {
v reflect.Value
s string
}
func (w *reflectWithString) resolve() error {
if w.v.Kind() == reflect.String {
w.s = w.v.String()
return nil
}
if tm, ok := w.v.Interface().(encoding.TextMarshaler); ok {
buf, err := tm.MarshalText()
w.s = string(buf)
return err
}
switch w.v.Kind() {
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
w.s = strconv.FormatInt(w.v.Int(), 10)
return nil
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
w.s = strconv.FormatUint(w.v.Uint(), 10)
return nil
}
return &json.UnsupportedTypeError{Type: w.v.Type()}
}
func (sv stringValues) Len() int { return len(sv) }
func (sv stringValues) Swap(i, j int) { sv[i], sv[j] = sv[j], sv[i] }
func (sv stringValues) Less(i, j int) bool { return sv[i].s < sv[j].s }
func (encoder *sortKeysMapEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *sortKeysMapEncoder) IsEmpty(ptr unsafe.Pointer) bool {
mapInterface := encoder.mapInterface
mapInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&mapInterface))
realVal := reflect.ValueOf(*realInterface)
return realVal.Len() == 0
}

764
vendor/github.com/json-iterator/go/feature_reflect_native.go сгенерированный поставляемый
Просмотреть файл

@ -1,764 +0,0 @@
package jsoniter
import (
"encoding"
"encoding/base64"
"encoding/json"
"reflect"
"unsafe"
)
type stringCodec struct {
}
func (codec *stringCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*((*string)(ptr)) = iter.ReadString()
}
func (codec *stringCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
str := *((*string)(ptr))
stream.WriteString(str)
}
func (codec *stringCodec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *stringCodec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*string)(ptr)) == ""
}
type intCodec struct {
}
func (codec *intCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int)(ptr)) = iter.ReadInt()
}
}
func (codec *intCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt(*((*int)(ptr)))
}
func (codec *intCodec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *intCodec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int)(ptr)) == 0
}
type uintptrCodec struct {
}
func (codec *uintptrCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uintptr)(ptr)) = uintptr(iter.ReadUint64())
}
}
func (codec *uintptrCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint64(uint64(*((*uintptr)(ptr))))
}
func (codec *uintptrCodec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *uintptrCodec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uintptr)(ptr)) == 0
}
type int8Codec struct {
}
func (codec *int8Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int8)(ptr)) = iter.ReadInt8()
}
}
func (codec *int8Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt8(*((*int8)(ptr)))
}
func (codec *int8Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *int8Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int8)(ptr)) == 0
}
type int16Codec struct {
}
func (codec *int16Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int16)(ptr)) = iter.ReadInt16()
}
}
func (codec *int16Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt16(*((*int16)(ptr)))
}
func (codec *int16Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *int16Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int16)(ptr)) == 0
}
type int32Codec struct {
}
func (codec *int32Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int32)(ptr)) = iter.ReadInt32()
}
}
func (codec *int32Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt32(*((*int32)(ptr)))
}
func (codec *int32Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *int32Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int32)(ptr)) == 0
}
type int64Codec struct {
}
func (codec *int64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int64)(ptr)) = iter.ReadInt64()
}
}
func (codec *int64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt64(*((*int64)(ptr)))
}
func (codec *int64Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *int64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int64)(ptr)) == 0
}
type uintCodec struct {
}
func (codec *uintCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint)(ptr)) = iter.ReadUint()
return
}
}
func (codec *uintCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint(*((*uint)(ptr)))
}
func (codec *uintCodec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *uintCodec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint)(ptr)) == 0
}
type uint8Codec struct {
}
func (codec *uint8Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint8)(ptr)) = iter.ReadUint8()
}
}
func (codec *uint8Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint8(*((*uint8)(ptr)))
}
func (codec *uint8Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *uint8Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint8)(ptr)) == 0
}
type uint16Codec struct {
}
func (codec *uint16Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint16)(ptr)) = iter.ReadUint16()
}
}
func (codec *uint16Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint16(*((*uint16)(ptr)))
}
func (codec *uint16Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *uint16Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint16)(ptr)) == 0
}
type uint32Codec struct {
}
func (codec *uint32Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint32)(ptr)) = iter.ReadUint32()
}
}
func (codec *uint32Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint32(*((*uint32)(ptr)))
}
func (codec *uint32Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *uint32Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint32)(ptr)) == 0
}
type uint64Codec struct {
}
func (codec *uint64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint64)(ptr)) = iter.ReadUint64()
}
}
func (codec *uint64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint64(*((*uint64)(ptr)))
}
func (codec *uint64Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *uint64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint64)(ptr)) == 0
}
type float32Codec struct {
}
func (codec *float32Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*float32)(ptr)) = iter.ReadFloat32()
}
}
func (codec *float32Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteFloat32(*((*float32)(ptr)))
}
func (codec *float32Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *float32Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*float32)(ptr)) == 0
}
type float64Codec struct {
}
func (codec *float64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*float64)(ptr)) = iter.ReadFloat64()
}
}
func (codec *float64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteFloat64(*((*float64)(ptr)))
}
func (codec *float64Codec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *float64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*float64)(ptr)) == 0
}
type boolCodec struct {
}
func (codec *boolCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*bool)(ptr)) = iter.ReadBool()
}
}
func (codec *boolCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteBool(*((*bool)(ptr)))
}
func (codec *boolCodec) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, codec)
}
func (codec *boolCodec) IsEmpty(ptr unsafe.Pointer) bool {
return !(*((*bool)(ptr)))
}
type emptyInterfaceCodec struct {
}
func (codec *emptyInterfaceCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
existing := *((*interface{})(ptr))
// Checking for both typed and untyped nil pointers.
if existing != nil &&
reflect.TypeOf(existing).Kind() == reflect.Ptr &&
!reflect.ValueOf(existing).IsNil() {
var ptrToExisting interface{}
for {
elem := reflect.ValueOf(existing).Elem()
if elem.Kind() != reflect.Ptr || elem.IsNil() {
break
}
ptrToExisting = existing
existing = elem.Interface()
}
if iter.ReadNil() {
if ptrToExisting != nil {
nilPtr := reflect.Zero(reflect.TypeOf(ptrToExisting).Elem())
reflect.ValueOf(ptrToExisting).Elem().Set(nilPtr)
} else {
*((*interface{})(ptr)) = nil
}
} else {
iter.ReadVal(existing)
}
return
}
if iter.ReadNil() {
*((*interface{})(ptr)) = nil
} else {
*((*interface{})(ptr)) = iter.Read()
}
}
func (codec *emptyInterfaceCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteVal(*((*interface{})(ptr)))
}
func (codec *emptyInterfaceCodec) EncodeInterface(val interface{}, stream *Stream) {
stream.WriteVal(val)
}
func (codec *emptyInterfaceCodec) IsEmpty(ptr unsafe.Pointer) bool {
emptyInterface := (*emptyInterface)(ptr)
return emptyInterface.typ == nil
}
type nonEmptyInterfaceCodec struct {
}
func (codec *nonEmptyInterfaceCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
nonEmptyInterface := (*nonEmptyInterface)(ptr)
if nonEmptyInterface.itab == nil {
iter.ReportError("read non-empty interface", "do not know which concrete type to decode to")
return
}
var i interface{}
e := (*emptyInterface)(unsafe.Pointer(&i))
e.typ = nonEmptyInterface.itab.typ
e.word = nonEmptyInterface.word
iter.ReadVal(&i)
if e.word == nil {
nonEmptyInterface.itab = nil
}
nonEmptyInterface.word = e.word
}
func (codec *nonEmptyInterfaceCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
nonEmptyInterface := (*nonEmptyInterface)(ptr)
var i interface{}
if nonEmptyInterface.itab != nil {
e := (*emptyInterface)(unsafe.Pointer(&i))
e.typ = nonEmptyInterface.itab.typ
e.word = nonEmptyInterface.word
}
stream.WriteVal(i)
}
func (codec *nonEmptyInterfaceCodec) EncodeInterface(val interface{}, stream *Stream) {
stream.WriteVal(val)
}
func (codec *nonEmptyInterfaceCodec) IsEmpty(ptr unsafe.Pointer) bool {
nonEmptyInterface := (*nonEmptyInterface)(ptr)
return nonEmptyInterface.word == nil
}
type anyCodec struct {
}
func (codec *anyCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*((*Any)(ptr)) = iter.ReadAny()
}
func (codec *anyCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
(*((*Any)(ptr))).WriteTo(stream)
}
func (codec *anyCodec) EncodeInterface(val interface{}, stream *Stream) {
(val.(Any)).WriteTo(stream)
}
func (codec *anyCodec) IsEmpty(ptr unsafe.Pointer) bool {
return (*((*Any)(ptr))).Size() == 0
}
type jsonNumberCodec struct {
}
func (codec *jsonNumberCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
switch iter.WhatIsNext() {
case StringValue:
*((*json.Number)(ptr)) = json.Number(iter.ReadString())
case NilValue:
iter.skipFourBytes('n', 'u', 'l', 'l')
*((*json.Number)(ptr)) = ""
default:
*((*json.Number)(ptr)) = json.Number([]byte(iter.readNumberAsString()))
}
}
func (codec *jsonNumberCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteRaw(string(*((*json.Number)(ptr))))
}
func (codec *jsonNumberCodec) EncodeInterface(val interface{}, stream *Stream) {
stream.WriteRaw(string(val.(json.Number)))
}
func (codec *jsonNumberCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*json.Number)(ptr))) == 0
}
type jsoniterNumberCodec struct {
}
func (codec *jsoniterNumberCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
switch iter.WhatIsNext() {
case StringValue:
*((*Number)(ptr)) = Number(iter.ReadString())
case NilValue:
iter.skipFourBytes('n', 'u', 'l', 'l')
*((*Number)(ptr)) = ""
default:
*((*Number)(ptr)) = Number([]byte(iter.readNumberAsString()))
}
}
func (codec *jsoniterNumberCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteRaw(string(*((*Number)(ptr))))
}
func (codec *jsoniterNumberCodec) EncodeInterface(val interface{}, stream *Stream) {
stream.WriteRaw(string(val.(Number)))
}
func (codec *jsoniterNumberCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*Number)(ptr))) == 0
}
type jsonRawMessageCodec struct {
}
func (codec *jsonRawMessageCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*((*json.RawMessage)(ptr)) = json.RawMessage(iter.SkipAndReturnBytes())
}
func (codec *jsonRawMessageCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteRaw(string(*((*json.RawMessage)(ptr))))
}
func (codec *jsonRawMessageCodec) EncodeInterface(val interface{}, stream *Stream) {
stream.WriteRaw(string(val.(json.RawMessage)))
}
func (codec *jsonRawMessageCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*json.RawMessage)(ptr))) == 0
}
type jsoniterRawMessageCodec struct {
}
func (codec *jsoniterRawMessageCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*((*RawMessage)(ptr)) = RawMessage(iter.SkipAndReturnBytes())
}
func (codec *jsoniterRawMessageCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteRaw(string(*((*RawMessage)(ptr))))
}
func (codec *jsoniterRawMessageCodec) EncodeInterface(val interface{}, stream *Stream) {
stream.WriteRaw(string(val.(RawMessage)))
}
func (codec *jsoniterRawMessageCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*RawMessage)(ptr))) == 0
}
type base64Codec struct {
sliceDecoder ValDecoder
}
func (codec *base64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if iter.ReadNil() {
ptrSlice := (*sliceHeader)(ptr)
ptrSlice.Len = 0
ptrSlice.Cap = 0
ptrSlice.Data = nil
return
}
switch iter.WhatIsNext() {
case StringValue:
encoding := base64.StdEncoding
src := iter.SkipAndReturnBytes()
src = src[1 : len(src)-1]
decodedLen := encoding.DecodedLen(len(src))
dst := make([]byte, decodedLen)
len, err := encoding.Decode(dst, src)
if err != nil {
iter.ReportError("decode base64", err.Error())
} else {
dst = dst[:len]
dstSlice := (*sliceHeader)(unsafe.Pointer(&dst))
ptrSlice := (*sliceHeader)(ptr)
ptrSlice.Data = dstSlice.Data
ptrSlice.Cap = dstSlice.Cap
ptrSlice.Len = dstSlice.Len
}
case ArrayValue:
codec.sliceDecoder.Decode(ptr, iter)
default:
iter.ReportError("base64Codec", "invalid input")
}
}
func (codec *base64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
src := *((*[]byte)(ptr))
if len(src) == 0 {
stream.WriteNil()
return
}
encoding := base64.StdEncoding
stream.writeByte('"')
toGrow := encoding.EncodedLen(len(src))
stream.ensure(toGrow)
encoding.Encode(stream.buf[stream.n:], src)
stream.n += toGrow
stream.writeByte('"')
}
func (codec *base64Codec) EncodeInterface(val interface{}, stream *Stream) {
ptr := extractInterface(val).word
src := *((*[]byte)(ptr))
if len(src) == 0 {
stream.WriteNil()
return
}
encoding := base64.StdEncoding
stream.writeByte('"')
toGrow := encoding.EncodedLen(len(src))
stream.ensure(toGrow)
encoding.Encode(stream.buf[stream.n:], src)
stream.n += toGrow
stream.writeByte('"')
}
func (codec *base64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*[]byte)(ptr))) == 0
}
type stringModeNumberDecoder struct {
elemDecoder ValDecoder
}
func (decoder *stringModeNumberDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
c := iter.nextToken()
if c != '"' {
iter.ReportError("stringModeNumberDecoder", `expect ", but found `+string([]byte{c}))
return
}
decoder.elemDecoder.Decode(ptr, iter)
if iter.Error != nil {
return
}
c = iter.readByte()
if c != '"' {
iter.ReportError("stringModeNumberDecoder", `expect ", but found `+string([]byte{c}))
return
}
}
type stringModeStringDecoder struct {
elemDecoder ValDecoder
cfg *frozenConfig
}
func (decoder *stringModeStringDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.elemDecoder.Decode(ptr, iter)
str := *((*string)(ptr))
tempIter := decoder.cfg.BorrowIterator([]byte(str))
defer decoder.cfg.ReturnIterator(tempIter)
*((*string)(ptr)) = tempIter.ReadString()
}
type stringModeNumberEncoder struct {
elemEncoder ValEncoder
}
func (encoder *stringModeNumberEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.writeByte('"')
encoder.elemEncoder.Encode(ptr, stream)
stream.writeByte('"')
}
func (encoder *stringModeNumberEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *stringModeNumberEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.elemEncoder.IsEmpty(ptr)
}
type stringModeStringEncoder struct {
elemEncoder ValEncoder
cfg *frozenConfig
}
func (encoder *stringModeStringEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
tempStream := encoder.cfg.BorrowStream(nil)
defer encoder.cfg.ReturnStream(tempStream)
encoder.elemEncoder.Encode(ptr, tempStream)
stream.WriteString(string(tempStream.Buffer()))
}
func (encoder *stringModeStringEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *stringModeStringEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.elemEncoder.IsEmpty(ptr)
}
type marshalerEncoder struct {
templateInterface emptyInterface
checkIsEmpty checkIsEmpty
}
func (encoder *marshalerEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
templateInterface := encoder.templateInterface
templateInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&templateInterface))
marshaler, ok := (*realInterface).(json.Marshaler)
if !ok {
stream.WriteVal(nil)
return
}
bytes, err := marshaler.MarshalJSON()
if err != nil {
stream.Error = err
} else {
stream.Write(bytes)
}
}
func (encoder *marshalerEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *marshalerEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.checkIsEmpty.IsEmpty(ptr)
}
type textMarshalerEncoder struct {
templateInterface emptyInterface
checkIsEmpty checkIsEmpty
}
func (encoder *textMarshalerEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
templateInterface := encoder.templateInterface
templateInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&templateInterface))
marshaler := (*realInterface).(encoding.TextMarshaler)
bytes, err := marshaler.MarshalText()
if err != nil {
stream.Error = err
} else {
stream.WriteString(string(bytes))
}
}
func (encoder *textMarshalerEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *textMarshalerEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.checkIsEmpty.IsEmpty(ptr)
}
type unmarshalerDecoder struct {
templateInterface emptyInterface
}
func (decoder *unmarshalerDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
templateInterface := decoder.templateInterface
templateInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&templateInterface))
unmarshaler := (*realInterface).(json.Unmarshaler)
iter.nextToken()
iter.unreadByte() // skip spaces
bytes := iter.SkipAndReturnBytes()
err := unmarshaler.UnmarshalJSON(bytes)
if err != nil {
iter.ReportError("unmarshalerDecoder", err.Error())
}
}
type textUnmarshalerDecoder struct {
templateInterface emptyInterface
}
func (decoder *textUnmarshalerDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
templateInterface := decoder.templateInterface
templateInterface.word = ptr
realInterface := (*interface{})(unsafe.Pointer(&templateInterface))
unmarshaler := (*realInterface).(encoding.TextUnmarshaler)
str := iter.ReadString()
err := unmarshaler.UnmarshalText([]byte(str))
if err != nil {
iter.ReportError("textUnmarshalerDecoder", err.Error())
}
}

147
vendor/github.com/json-iterator/go/feature_reflect_slice.go сгенерированный поставляемый
Просмотреть файл

@ -1,147 +0,0 @@
package jsoniter
import (
"fmt"
"io"
"reflect"
"unsafe"
)
func decoderOfSlice(cfg *frozenConfig, typ reflect.Type) (ValDecoder, error) {
decoder, err := decoderOfType(cfg, typ.Elem())
if err != nil {
return nil, err
}
return &sliceDecoder{typ, typ.Elem(), decoder}, nil
}
func encoderOfSlice(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
encoder, err := encoderOfType(cfg, typ.Elem())
if err != nil {
return nil, err
}
if typ.Elem().Kind() == reflect.Map {
encoder = &OptionalEncoder{encoder}
}
return &sliceEncoder{typ, typ.Elem(), encoder}, nil
}
type sliceEncoder struct {
sliceType reflect.Type
elemType reflect.Type
elemEncoder ValEncoder
}
func (encoder *sliceEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
slice := (*sliceHeader)(ptr)
if slice.Data == nil {
stream.WriteNil()
return
}
if slice.Len == 0 {
stream.WriteEmptyArray()
return
}
stream.WriteArrayStart()
elemPtr := unsafe.Pointer(slice.Data)
encoder.elemEncoder.Encode(unsafe.Pointer(elemPtr), stream)
for i := 1; i < slice.Len; i++ {
stream.WriteMore()
elemPtr = unsafe.Pointer(uintptr(elemPtr) + encoder.elemType.Size())
encoder.elemEncoder.Encode(unsafe.Pointer(elemPtr), stream)
}
stream.WriteArrayEnd()
if stream.Error != nil && stream.Error != io.EOF {
stream.Error = fmt.Errorf("%v: %s", encoder.sliceType, stream.Error.Error())
}
}
func (encoder *sliceEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *sliceEncoder) IsEmpty(ptr unsafe.Pointer) bool {
slice := (*sliceHeader)(ptr)
return slice.Len == 0
}
type sliceDecoder struct {
sliceType reflect.Type
elemType reflect.Type
elemDecoder ValDecoder
}
// sliceHeader is a safe version of SliceHeader used within this package.
type sliceHeader struct {
Data unsafe.Pointer
Len int
Cap int
}
func (decoder *sliceDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.doDecode(ptr, iter)
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.sliceType, iter.Error.Error())
}
}
func (decoder *sliceDecoder) doDecode(ptr unsafe.Pointer, iter *Iterator) {
slice := (*sliceHeader)(ptr)
if iter.ReadNil() {
slice.Len = 0
slice.Cap = 0
slice.Data = nil
return
}
reuseSlice(slice, decoder.sliceType, 4)
slice.Len = 0
offset := uintptr(0)
iter.ReadArrayCB(func(iter *Iterator) bool {
growOne(slice, decoder.sliceType, decoder.elemType)
decoder.elemDecoder.Decode(unsafe.Pointer(uintptr(slice.Data)+offset), iter)
offset += decoder.elemType.Size()
return true
})
}
// grow grows the slice s so that it can hold extra more values, allocating
// more capacity if needed. It also returns the old and new slice lengths.
func growOne(slice *sliceHeader, sliceType reflect.Type, elementType reflect.Type) {
newLen := slice.Len + 1
if newLen <= slice.Cap {
slice.Len = newLen
return
}
newCap := slice.Cap
if newCap == 0 {
newCap = 1
} else {
for newCap < newLen {
if slice.Len < 1024 {
newCap += newCap
} else {
newCap += newCap / 4
}
}
}
newVal := reflect.MakeSlice(sliceType, newLen, newCap)
dst := unsafe.Pointer(newVal.Pointer())
// copy old array into new array
originalBytesCount := slice.Len * int(elementType.Size())
srcSliceHeader := (unsafe.Pointer)(&sliceHeader{slice.Data, originalBytesCount, originalBytesCount})
dstSliceHeader := (unsafe.Pointer)(&sliceHeader{dst, originalBytesCount, originalBytesCount})
copy(*(*[]byte)(dstSliceHeader), *(*[]byte)(srcSliceHeader))
slice.Data = dst
slice.Len = newLen
slice.Cap = newCap
}
func reuseSlice(slice *sliceHeader, sliceType reflect.Type, expectedCap int) {
if expectedCap <= slice.Cap {
return
}
newVal := reflect.MakeSlice(sliceType, 0, expectedCap)
dst := unsafe.Pointer(newVal.Pointer())
slice.Data = dst
slice.Cap = expectedCap
}

320
vendor/github.com/json-iterator/go/feature_stream_int.go сгенерированный поставляемый
Просмотреть файл

@ -1,320 +0,0 @@
package jsoniter
var digits []uint32
func init() {
digits = make([]uint32, 1000)
for i := uint32(0); i < 1000; i++ {
digits[i] = (((i / 100) + '0') << 16) + ((((i / 10) % 10) + '0') << 8) + i%10 + '0'
if i < 10 {
digits[i] += 2 << 24
} else if i < 100 {
digits[i] += 1 << 24
}
}
}
func writeFirstBuf(buf []byte, v uint32, n int) int {
start := v >> 24
if start == 0 {
buf[n] = byte(v >> 16)
n++
buf[n] = byte(v >> 8)
n++
} else if start == 1 {
buf[n] = byte(v >> 8)
n++
}
buf[n] = byte(v)
n++
return n
}
func writeBuf(buf []byte, v uint32, n int) {
buf[n] = byte(v >> 16)
buf[n+1] = byte(v >> 8)
buf[n+2] = byte(v)
}
// WriteUint8 write uint8 to stream
func (stream *Stream) WriteUint8(val uint8) {
stream.ensure(3)
stream.n = writeFirstBuf(stream.buf, digits[val], stream.n)
}
// WriteInt8 write int8 to stream
func (stream *Stream) WriteInt8(nval int8) {
stream.ensure(4)
n := stream.n
var val uint8
if nval < 0 {
val = uint8(-nval)
stream.buf[n] = '-'
n++
} else {
val = uint8(nval)
}
stream.n = writeFirstBuf(stream.buf, digits[val], n)
}
// WriteUint16 write uint16 to stream
func (stream *Stream) WriteUint16(val uint16) {
stream.ensure(5)
q1 := val / 1000
if q1 == 0 {
stream.n = writeFirstBuf(stream.buf, digits[val], stream.n)
return
}
r1 := val - q1*1000
n := writeFirstBuf(stream.buf, digits[q1], stream.n)
writeBuf(stream.buf, digits[r1], n)
stream.n = n + 3
return
}
// WriteInt16 write int16 to stream
func (stream *Stream) WriteInt16(nval int16) {
stream.ensure(6)
n := stream.n
var val uint16
if nval < 0 {
val = uint16(-nval)
stream.buf[n] = '-'
n++
} else {
val = uint16(nval)
}
q1 := val / 1000
if q1 == 0 {
stream.n = writeFirstBuf(stream.buf, digits[val], n)
return
}
r1 := val - q1*1000
n = writeFirstBuf(stream.buf, digits[q1], n)
writeBuf(stream.buf, digits[r1], n)
stream.n = n + 3
return
}
// WriteUint32 write uint32 to stream
func (stream *Stream) WriteUint32(val uint32) {
stream.ensure(10)
n := stream.n
q1 := val / 1000
if q1 == 0 {
stream.n = writeFirstBuf(stream.buf, digits[val], n)
return
}
r1 := val - q1*1000
q2 := q1 / 1000
if q2 == 0 {
n := writeFirstBuf(stream.buf, digits[q1], n)
writeBuf(stream.buf, digits[r1], n)
stream.n = n + 3
return
}
r2 := q1 - q2*1000
q3 := q2 / 1000
if q3 == 0 {
n = writeFirstBuf(stream.buf, digits[q2], n)
} else {
r3 := q2 - q3*1000
stream.buf[n] = byte(q3 + '0')
n++
writeBuf(stream.buf, digits[r3], n)
n += 3
}
writeBuf(stream.buf, digits[r2], n)
writeBuf(stream.buf, digits[r1], n+3)
stream.n = n + 6
}
// WriteInt32 write int32 to stream
func (stream *Stream) WriteInt32(nval int32) {
stream.ensure(11)
n := stream.n
var val uint32
if nval < 0 {
val = uint32(-nval)
stream.buf[n] = '-'
n++
} else {
val = uint32(nval)
}
q1 := val / 1000
if q1 == 0 {
stream.n = writeFirstBuf(stream.buf, digits[val], n)
return
}
r1 := val - q1*1000
q2 := q1 / 1000
if q2 == 0 {
n := writeFirstBuf(stream.buf, digits[q1], n)
writeBuf(stream.buf, digits[r1], n)
stream.n = n + 3
return
}
r2 := q1 - q2*1000
q3 := q2 / 1000
if q3 == 0 {
n = writeFirstBuf(stream.buf, digits[q2], n)
} else {
r3 := q2 - q3*1000
stream.buf[n] = byte(q3 + '0')
n++
writeBuf(stream.buf, digits[r3], n)
n += 3
}
writeBuf(stream.buf, digits[r2], n)
writeBuf(stream.buf, digits[r1], n+3)
stream.n = n + 6
}
// WriteUint64 write uint64 to stream
func (stream *Stream) WriteUint64(val uint64) {
stream.ensure(20)
n := stream.n
q1 := val / 1000
if q1 == 0 {
stream.n = writeFirstBuf(stream.buf, digits[val], n)
return
}
r1 := val - q1*1000
q2 := q1 / 1000
if q2 == 0 {
n := writeFirstBuf(stream.buf, digits[q1], n)
writeBuf(stream.buf, digits[r1], n)
stream.n = n + 3
return
}
r2 := q1 - q2*1000
q3 := q2 / 1000
if q3 == 0 {
n = writeFirstBuf(stream.buf, digits[q2], n)
writeBuf(stream.buf, digits[r2], n)
writeBuf(stream.buf, digits[r1], n+3)
stream.n = n + 6
return
}
r3 := q2 - q3*1000
q4 := q3 / 1000
if q4 == 0 {
n = writeFirstBuf(stream.buf, digits[q3], n)
writeBuf(stream.buf, digits[r3], n)
writeBuf(stream.buf, digits[r2], n+3)
writeBuf(stream.buf, digits[r1], n+6)
stream.n = n + 9
return
}
r4 := q3 - q4*1000
q5 := q4 / 1000
if q5 == 0 {
n = writeFirstBuf(stream.buf, digits[q4], n)
writeBuf(stream.buf, digits[r4], n)
writeBuf(stream.buf, digits[r3], n+3)
writeBuf(stream.buf, digits[r2], n+6)
writeBuf(stream.buf, digits[r1], n+9)
stream.n = n + 12
return
}
r5 := q4 - q5*1000
q6 := q5 / 1000
if q6 == 0 {
n = writeFirstBuf(stream.buf, digits[q5], n)
} else {
n = writeFirstBuf(stream.buf, digits[q6], n)
r6 := q5 - q6*1000
writeBuf(stream.buf, digits[r6], n)
n += 3
}
writeBuf(stream.buf, digits[r5], n)
writeBuf(stream.buf, digits[r4], n+3)
writeBuf(stream.buf, digits[r3], n+6)
writeBuf(stream.buf, digits[r2], n+9)
writeBuf(stream.buf, digits[r1], n+12)
stream.n = n + 15
}
// WriteInt64 write int64 to stream
func (stream *Stream) WriteInt64(nval int64) {
stream.ensure(20)
n := stream.n
var val uint64
if nval < 0 {
val = uint64(-nval)
stream.buf[n] = '-'
n++
} else {
val = uint64(nval)
}
q1 := val / 1000
if q1 == 0 {
stream.n = writeFirstBuf(stream.buf, digits[val], n)
return
}
r1 := val - q1*1000
q2 := q1 / 1000
if q2 == 0 {
n := writeFirstBuf(stream.buf, digits[q1], n)
writeBuf(stream.buf, digits[r1], n)
stream.n = n + 3
return
}
r2 := q1 - q2*1000
q3 := q2 / 1000
if q3 == 0 {
n = writeFirstBuf(stream.buf, digits[q2], n)
writeBuf(stream.buf, digits[r2], n)
writeBuf(stream.buf, digits[r1], n+3)
stream.n = n + 6
return
}
r3 := q2 - q3*1000
q4 := q3 / 1000
if q4 == 0 {
n = writeFirstBuf(stream.buf, digits[q3], n)
writeBuf(stream.buf, digits[r3], n)
writeBuf(stream.buf, digits[r2], n+3)
writeBuf(stream.buf, digits[r1], n+6)
stream.n = n + 9
return
}
r4 := q3 - q4*1000
q5 := q4 / 1000
if q5 == 0 {
n = writeFirstBuf(stream.buf, digits[q4], n)
writeBuf(stream.buf, digits[r4], n)
writeBuf(stream.buf, digits[r3], n+3)
writeBuf(stream.buf, digits[r2], n+6)
writeBuf(stream.buf, digits[r1], n+9)
stream.n = n + 12
return
}
r5 := q4 - q5*1000
q6 := q5 / 1000
if q6 == 0 {
n = writeFirstBuf(stream.buf, digits[q5], n)
} else {
stream.buf[n] = byte(q6 + '0')
n++
r6 := q5 - q6*1000
writeBuf(stream.buf, digits[r6], n)
n += 3
}
writeBuf(stream.buf, digits[r5], n)
writeBuf(stream.buf, digits[r4], n+3)
writeBuf(stream.buf, digits[r3], n+6)
writeBuf(stream.buf, digits[r2], n+9)
writeBuf(stream.buf, digits[r1], n+12)
stream.n = n + 15
}
// WriteInt write int to stream
func (stream *Stream) WriteInt(val int) {
stream.WriteInt64(int64(val))
}
// WriteUint write uint to stream
func (stream *Stream) WriteUint(val uint) {
stream.WriteUint64(uint64(val))
}

0
vendor/github.com/json-iterator/go/feature_iter.go → vendor/github.com/json-iterator/go/iter.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_iter_array.go → vendor/github.com/json-iterator/go/iter_array.go сгенерированный поставляемый
Просмотреть файл

6
vendor/github.com/json-iterator/go/feature_iter_float.go → vendor/github.com/json-iterator/go/iter_float.go сгенерированный поставляемый
Просмотреть файл

@ -1,6 +1,7 @@
package jsoniter
import (
"encoding/json"
"io"
"math/big"
"strconv"
@ -339,3 +340,8 @@ func validateFloat(str string) string {
}
return ""
}
// ReadNumber read json.Number
func (iter *Iterator) ReadNumber() (ret json.Number) {
return json.Number(iter.readNumberAsString())
}

6
vendor/github.com/json-iterator/go/feature_iter_int.go → vendor/github.com/json-iterator/go/iter_int.go сгенерированный поставляемый
Просмотреть файл

@ -22,11 +22,17 @@ func init() {
// ReadUint read uint
func (iter *Iterator) ReadUint() uint {
if strconv.IntSize == 32 {
return uint(iter.ReadUint32())
}
return uint(iter.ReadUint64())
}
// ReadInt read int
func (iter *Iterator) ReadInt() int {
if strconv.IntSize == 32 {
return int(iter.ReadInt32())
}
return int(iter.ReadInt64())
}

150
vendor/github.com/json-iterator/go/feature_iter_object.go → vendor/github.com/json-iterator/go/iter_object.go сгенерированный поставляемый
Просмотреть файл

@ -2,8 +2,7 @@ package jsoniter
import (
"fmt"
"unicode"
"unsafe"
"strings"
)
// ReadObject read one field from object.
@ -19,26 +18,6 @@ func (iter *Iterator) ReadObject() (ret string) {
c = iter.nextToken()
if c == '"' {
iter.unreadByte()
if iter.cfg.objectFieldMustBeSimpleString {
return string(iter.readObjectFieldAsBytes())
} else {
field := iter.ReadString()
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
return field
}
}
if c == '}' {
return "" // end of object
}
iter.ReportError("ReadObject", `expect " after {, but found `+string([]byte{c}))
return
case ',':
if iter.cfg.objectFieldMustBeSimpleString {
return string(iter.readObjectFieldAsBytes())
} else {
field := iter.ReadString()
c = iter.nextToken()
if c != ':' {
@ -46,6 +25,18 @@ func (iter *Iterator) ReadObject() (ret string) {
}
return field
}
if c == '}' {
return "" // end of object
}
iter.ReportError("ReadObject", `expect " after {, but found `+string([]byte{c}))
return
case ',':
field := iter.ReadString()
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
return field
case '}':
return "" // end of object
default:
@ -54,97 +45,90 @@ func (iter *Iterator) ReadObject() (ret string) {
}
}
func (iter *Iterator) readFieldHash() int32 {
// CaseInsensitive
func (iter *Iterator) readFieldHash() int64 {
hash := int64(0x811c9dc5)
c := iter.nextToken()
if c == '"' {
for {
for i := iter.head; i < iter.tail; i++ {
// require ascii string and no escape
b := iter.buf[i]
if !iter.cfg.objectFieldMustBeSimpleString && b == '\\' {
iter.head = i
for _, b := range iter.readStringSlowPath() {
if 'A' <= b && b <= 'Z' {
b += 'a' - 'A'
}
hash ^= int64(b)
hash *= 0x1000193
if c != '"' {
iter.ReportError("readFieldHash", `expect ", but found `+string([]byte{c}))
return 0
}
for {
for i := iter.head; i < iter.tail; i++ {
// require ascii string and no escape
b := iter.buf[i]
if b == '\\' {
iter.head = i
for _, b := range iter.readStringSlowPath() {
if 'A' <= b && b <= 'Z' && !iter.cfg.caseSensitive {
b += 'a' - 'A'
}
c = iter.nextToken()
if c != ':' {
iter.ReportError("readFieldHash", `expect :, but found `+string([]byte{c}))
return 0
}
return int32(hash)
hash ^= int64(b)
hash *= 0x1000193
}
if b == '"' {
iter.head = i + 1
c = iter.nextToken()
if c != ':' {
iter.ReportError("readFieldHash", `expect :, but found `+string([]byte{c}))
return 0
}
return int32(hash)
c = iter.nextToken()
if c != ':' {
iter.ReportError("readFieldHash", `expect :, but found `+string([]byte{c}))
return 0
}
if 'A' <= b && b <= 'Z' {
b += 'a' - 'A'
}
hash ^= int64(b)
hash *= 0x1000193
return hash
}
if !iter.loadMore() {
iter.ReportError("readFieldHash", `incomplete field name`)
return 0
if b == '"' {
iter.head = i + 1
c = iter.nextToken()
if c != ':' {
iter.ReportError("readFieldHash", `expect :, but found `+string([]byte{c}))
return 0
}
return hash
}
if 'A' <= b && b <= 'Z' && !iter.cfg.caseSensitive {
b += 'a' - 'A'
}
hash ^= int64(b)
hash *= 0x1000193
}
if !iter.loadMore() {
iter.ReportError("readFieldHash", `incomplete field name`)
return 0
}
}
iter.ReportError("readFieldHash", `expect ", but found `+string([]byte{c}))
return 0
}
func calcHash(str string) int32 {
func calcHash(str string, caseSensitive bool) int64 {
if !caseSensitive {
str = strings.ToLower(str)
}
hash := int64(0x811c9dc5)
for _, b := range str {
hash ^= int64(unicode.ToLower(b))
for _, b := range []byte(str) {
hash ^= int64(b)
hash *= 0x1000193
}
return int32(hash)
return int64(hash)
}
// ReadObjectCB read object with callback, the key is ascii only and field name not copied
func (iter *Iterator) ReadObjectCB(callback func(*Iterator, string) bool) bool {
c := iter.nextToken()
var fieldBytes []byte
var field string
if c == '{' {
c = iter.nextToken()
if c == '"' {
iter.unreadByte()
if iter.cfg.objectFieldMustBeSimpleString {
fieldBytes = iter.readObjectFieldAsBytes()
field = *(*string)(unsafe.Pointer(&fieldBytes))
} else {
field = iter.ReadString()
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
field = iter.ReadString()
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
if !callback(iter, field) {
return false
}
c = iter.nextToken()
for c == ',' {
if iter.cfg.objectFieldMustBeSimpleString {
fieldBytes = iter.readObjectFieldAsBytes()
field = *(*string)(unsafe.Pointer(&fieldBytes))
} else {
field = iter.ReadString()
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
field = iter.ReadString()
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
if !callback(iter, field) {
return false

0
vendor/github.com/json-iterator/go/feature_iter_skip.go → vendor/github.com/json-iterator/go/iter_skip.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_iter_skip_sloppy.go → vendor/github.com/json-iterator/go/iter_skip_sloppy.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_iter_skip_strict.go → vendor/github.com/json-iterator/go/iter_skip_strict.go сгенерированный поставляемый
Просмотреть файл

0
vendor/github.com/json-iterator/go/feature_iter_string.go → vendor/github.com/json-iterator/go/iter_str.go сгенерированный поставляемый
Просмотреть файл

35
vendor/github.com/json-iterator/go/feature_pool.go → vendor/github.com/json-iterator/go/pool.go сгенерированный поставляемый
Просмотреть файл

@ -17,43 +17,26 @@ type StreamPool interface {
}
func (cfg *frozenConfig) BorrowStream(writer io.Writer) *Stream {
select {
case stream := <-cfg.streamPool:
stream.Reset(writer)
return stream
default:
return NewStream(cfg, writer, 512)
}
stream := cfg.streamPool.Get().(*Stream)
stream.Reset(writer)
return stream
}
func (cfg *frozenConfig) ReturnStream(stream *Stream) {
stream.out = nil
stream.Error = nil
stream.Attachment = nil
select {
case cfg.streamPool <- stream:
return
default:
return
}
cfg.streamPool.Put(stream)
}
func (cfg *frozenConfig) BorrowIterator(data []byte) *Iterator {
select {
case iter := <-cfg.iteratorPool:
iter.ResetBytes(data)
return iter
default:
return ParseBytes(cfg, data)
}
iter := cfg.iteratorPool.Get().(*Iterator)
iter.ResetBytes(data)
return iter
}
func (cfg *frozenConfig) ReturnIterator(iter *Iterator) {
iter.Error = nil
iter.Attachment = nil
select {
case cfg.iteratorPool <- iter:
return
default:
return
}
cfg.iteratorPool.Put(iter)
}

332
vendor/github.com/json-iterator/go/reflect.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,332 @@
package jsoniter
import (
"fmt"
"reflect"
"unsafe"
"github.com/modern-go/reflect2"
)
// ValDecoder is an internal type registered to cache as needed.
// Don't confuse jsoniter.ValDecoder with json.Decoder.
// For json.Decoder's adapter, refer to jsoniter.AdapterDecoder(todo link).
//
// Reflection on type to create decoders, which is then cached
// Reflection on value is avoided as we can, as the reflect.Value itself will allocate, with following exceptions
// 1. create instance of new value, for example *int will need a int to be allocated
// 2. append to slice, if the existing cap is not enough, allocate will be done using Reflect.New
// 3. assignment to map, both key and value will be reflect.Value
// For a simple struct binding, it will be reflect.Value free and allocation free
type ValDecoder interface {
Decode(ptr unsafe.Pointer, iter *Iterator)
}
// ValEncoder is an internal type registered to cache as needed.
// Don't confuse jsoniter.ValEncoder with json.Encoder.
// For json.Encoder's adapter, refer to jsoniter.AdapterEncoder(todo godoc link).
type ValEncoder interface {
IsEmpty(ptr unsafe.Pointer) bool
Encode(ptr unsafe.Pointer, stream *Stream)
}
type checkIsEmpty interface {
IsEmpty(ptr unsafe.Pointer) bool
}
type ctx struct {
*frozenConfig
prefix string
encoders map[reflect2.Type]ValEncoder
decoders map[reflect2.Type]ValDecoder
}
func (b *ctx) caseSensitive() bool {
if b.frozenConfig == nil {
// default is case-insensitive
return false
}
return b.frozenConfig.caseSensitive
}
func (b *ctx) append(prefix string) *ctx {
return &ctx{
frozenConfig: b.frozenConfig,
prefix: b.prefix + " " + prefix,
encoders: b.encoders,
decoders: b.decoders,
}
}
// ReadVal copy the underlying JSON into go interface, same as json.Unmarshal
func (iter *Iterator) ReadVal(obj interface{}) {
cacheKey := reflect2.RTypeOf(obj)
decoder := iter.cfg.getDecoderFromCache(cacheKey)
if decoder == nil {
typ := reflect2.TypeOf(obj)
if typ.Kind() != reflect.Ptr {
iter.ReportError("ReadVal", "can only unmarshal into pointer")
return
}
decoder = iter.cfg.DecoderOf(typ)
}
ptr := reflect2.PtrOf(obj)
if ptr == nil {
iter.ReportError("ReadVal", "can not read into nil pointer")
return
}
decoder.Decode(ptr, iter)
}
// WriteVal copy the go interface into underlying JSON, same as json.Marshal
func (stream *Stream) WriteVal(val interface{}) {
if nil == val {
stream.WriteNil()
return
}
cacheKey := reflect2.RTypeOf(val)
encoder := stream.cfg.getEncoderFromCache(cacheKey)
if encoder == nil {
typ := reflect2.TypeOf(val)
encoder = stream.cfg.EncoderOf(typ)
}
encoder.Encode(reflect2.PtrOf(val), stream)
}
func (cfg *frozenConfig) DecoderOf(typ reflect2.Type) ValDecoder {
cacheKey := typ.RType()
decoder := cfg.getDecoderFromCache(cacheKey)
if decoder != nil {
return decoder
}
ctx := &ctx{
frozenConfig: cfg,
prefix: "",
decoders: map[reflect2.Type]ValDecoder{},
encoders: map[reflect2.Type]ValEncoder{},
}
ptrType := typ.(*reflect2.UnsafePtrType)
decoder = decoderOfType(ctx, ptrType.Elem())
cfg.addDecoderToCache(cacheKey, decoder)
return decoder
}
func decoderOfType(ctx *ctx, typ reflect2.Type) ValDecoder {
decoder := getTypeDecoderFromExtension(ctx, typ)
if decoder != nil {
return decoder
}
decoder = createDecoderOfType(ctx, typ)
for _, extension := range extensions {
decoder = extension.DecorateDecoder(typ, decoder)
}
decoder = ctx.decoderExtension.DecorateDecoder(typ, decoder)
for _, extension := range ctx.extraExtensions {
decoder = extension.DecorateDecoder(typ, decoder)
}
return decoder
}
func createDecoderOfType(ctx *ctx, typ reflect2.Type) ValDecoder {
decoder := ctx.decoders[typ]
if decoder != nil {
return decoder
}
placeholder := &placeholderDecoder{}
ctx.decoders[typ] = placeholder
decoder = _createDecoderOfType(ctx, typ)
placeholder.decoder = decoder
return decoder
}
func _createDecoderOfType(ctx *ctx, typ reflect2.Type) ValDecoder {
decoder := createDecoderOfJsonRawMessage(ctx, typ)
if decoder != nil {
return decoder
}
decoder = createDecoderOfJsonNumber(ctx, typ)
if decoder != nil {
return decoder
}
decoder = createDecoderOfMarshaler(ctx, typ)
if decoder != nil {
return decoder
}
decoder = createDecoderOfAny(ctx, typ)
if decoder != nil {
return decoder
}
decoder = createDecoderOfNative(ctx, typ)
if decoder != nil {
return decoder
}
switch typ.Kind() {
case reflect.Interface:
ifaceType, isIFace := typ.(*reflect2.UnsafeIFaceType)
if isIFace {
return &ifaceDecoder{valType: ifaceType}
}
return &efaceDecoder{}
case reflect.Struct:
return decoderOfStruct(ctx, typ)
case reflect.Array:
return decoderOfArray(ctx, typ)
case reflect.Slice:
return decoderOfSlice(ctx, typ)
case reflect.Map:
return decoderOfMap(ctx, typ)
case reflect.Ptr:
return decoderOfOptional(ctx, typ)
default:
return &lazyErrorDecoder{err: fmt.Errorf("%s%s is unsupported type", ctx.prefix, typ.String())}
}
}
func (cfg *frozenConfig) EncoderOf(typ reflect2.Type) ValEncoder {
cacheKey := typ.RType()
encoder := cfg.getEncoderFromCache(cacheKey)
if encoder != nil {
return encoder
}
ctx := &ctx{
frozenConfig: cfg,
prefix: "",
decoders: map[reflect2.Type]ValDecoder{},
encoders: map[reflect2.Type]ValEncoder{},
}
encoder = encoderOfType(ctx, typ)
if typ.LikePtr() {
encoder = &onePtrEncoder{encoder}
}
cfg.addEncoderToCache(cacheKey, encoder)
return encoder
}
type onePtrEncoder struct {
encoder ValEncoder
}
func (encoder *onePtrEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.encoder.IsEmpty(unsafe.Pointer(&ptr))
}
func (encoder *onePtrEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
encoder.encoder.Encode(unsafe.Pointer(&ptr), stream)
}
func encoderOfType(ctx *ctx, typ reflect2.Type) ValEncoder {
encoder := getTypeEncoderFromExtension(ctx, typ)
if encoder != nil {
return encoder
}
encoder = createEncoderOfType(ctx, typ)
for _, extension := range extensions {
encoder = extension.DecorateEncoder(typ, encoder)
}
encoder = ctx.encoderExtension.DecorateEncoder(typ, encoder)
for _, extension := range ctx.extraExtensions {
encoder = extension.DecorateEncoder(typ, encoder)
}
return encoder
}
func createEncoderOfType(ctx *ctx, typ reflect2.Type) ValEncoder {
encoder := ctx.encoders[typ]
if encoder != nil {
return encoder
}
placeholder := &placeholderEncoder{}
ctx.encoders[typ] = placeholder
encoder = _createEncoderOfType(ctx, typ)
placeholder.encoder = encoder
return encoder
}
func _createEncoderOfType(ctx *ctx, typ reflect2.Type) ValEncoder {
encoder := createEncoderOfJsonRawMessage(ctx, typ)
if encoder != nil {
return encoder
}
encoder = createEncoderOfJsonNumber(ctx, typ)
if encoder != nil {
return encoder
}
encoder = createEncoderOfMarshaler(ctx, typ)
if encoder != nil {
return encoder
}
encoder = createEncoderOfAny(ctx, typ)
if encoder != nil {
return encoder
}
encoder = createEncoderOfNative(ctx, typ)
if encoder != nil {
return encoder
}
kind := typ.Kind()
switch kind {
case reflect.Interface:
return &dynamicEncoder{typ}
case reflect.Struct:
return encoderOfStruct(ctx, typ)
case reflect.Array:
return encoderOfArray(ctx, typ)
case reflect.Slice:
return encoderOfSlice(ctx, typ)
case reflect.Map:
return encoderOfMap(ctx, typ)
case reflect.Ptr:
return encoderOfOptional(ctx, typ)
default:
return &lazyErrorEncoder{err: fmt.Errorf("%s%s is unsupported type", ctx.prefix, typ.String())}
}
}
type lazyErrorDecoder struct {
err error
}
func (decoder *lazyErrorDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
if iter.WhatIsNext() != NilValue {
if iter.Error == nil {
iter.Error = decoder.err
}
} else {
iter.Skip()
}
}
type lazyErrorEncoder struct {
err error
}
func (encoder *lazyErrorEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if ptr == nil {
stream.WriteNil()
} else if stream.Error == nil {
stream.Error = encoder.err
}
}
func (encoder *lazyErrorEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return false
}
type placeholderDecoder struct {
decoder ValDecoder
}
func (decoder *placeholderDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.decoder.Decode(ptr, iter)
}
type placeholderEncoder struct {
encoder ValEncoder
}
func (encoder *placeholderEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
encoder.encoder.Encode(ptr, stream)
}
func (encoder *placeholderEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.encoder.IsEmpty(ptr)
}

104
vendor/github.com/json-iterator/go/reflect_array.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,104 @@
package jsoniter
import (
"fmt"
"github.com/modern-go/reflect2"
"io"
"unsafe"
)
func decoderOfArray(ctx *ctx, typ reflect2.Type) ValDecoder {
arrayType := typ.(*reflect2.UnsafeArrayType)
decoder := decoderOfType(ctx.append("[arrayElem]"), arrayType.Elem())
return &arrayDecoder{arrayType, decoder}
}
func encoderOfArray(ctx *ctx, typ reflect2.Type) ValEncoder {
arrayType := typ.(*reflect2.UnsafeArrayType)
if arrayType.Len() == 0 {
return emptyArrayEncoder{}
}
encoder := encoderOfType(ctx.append("[arrayElem]"), arrayType.Elem())
return &arrayEncoder{arrayType, encoder}
}
type emptyArrayEncoder struct{}
func (encoder emptyArrayEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteEmptyArray()
}
func (encoder emptyArrayEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return true
}
type arrayEncoder struct {
arrayType *reflect2.UnsafeArrayType
elemEncoder ValEncoder
}
func (encoder *arrayEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteArrayStart()
elemPtr := unsafe.Pointer(ptr)
encoder.elemEncoder.Encode(elemPtr, stream)
for i := 1; i < encoder.arrayType.Len(); i++ {
stream.WriteMore()
elemPtr = encoder.arrayType.UnsafeGetIndex(ptr, i)
encoder.elemEncoder.Encode(elemPtr, stream)
}
stream.WriteArrayEnd()
if stream.Error != nil && stream.Error != io.EOF {
stream.Error = fmt.Errorf("%v: %s", encoder.arrayType, stream.Error.Error())
}
}
func (encoder *arrayEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return false
}
type arrayDecoder struct {
arrayType *reflect2.UnsafeArrayType
elemDecoder ValDecoder
}
func (decoder *arrayDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.doDecode(ptr, iter)
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.arrayType, iter.Error.Error())
}
}
func (decoder *arrayDecoder) doDecode(ptr unsafe.Pointer, iter *Iterator) {
c := iter.nextToken()
arrayType := decoder.arrayType
if c == 'n' {
iter.skipThreeBytes('u', 'l', 'l')
return
}
if c != '[' {
iter.ReportError("decode array", "expect [ or n, but found "+string([]byte{c}))
return
}
c = iter.nextToken()
if c == ']' {
return
}
iter.unreadByte()
elemPtr := arrayType.UnsafeGetIndex(ptr, 0)
decoder.elemDecoder.Decode(elemPtr, iter)
length := 1
for c = iter.nextToken(); c == ','; c = iter.nextToken() {
if length >= arrayType.Len() {
iter.Skip()
continue
}
idx := length
length += 1
elemPtr = arrayType.UnsafeGetIndex(ptr, idx)
decoder.elemDecoder.Decode(elemPtr, iter)
}
if c != ']' {
iter.ReportError("decode array", "expect ], but found "+string([]byte{c}))
return
}
}

70
vendor/github.com/json-iterator/go/reflect_dynamic.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,70 @@
package jsoniter
import (
"github.com/modern-go/reflect2"
"reflect"
"unsafe"
)
type dynamicEncoder struct {
valType reflect2.Type
}
func (encoder *dynamicEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
obj := encoder.valType.UnsafeIndirect(ptr)
stream.WriteVal(obj)
}
func (encoder *dynamicEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.valType.UnsafeIndirect(ptr) == nil
}
type efaceDecoder struct {
}
func (decoder *efaceDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
pObj := (*interface{})(ptr)
obj := *pObj
if obj == nil {
*pObj = iter.Read()
return
}
typ := reflect2.TypeOf(obj)
if typ.Kind() != reflect.Ptr {
*pObj = iter.Read()
return
}
ptrType := typ.(*reflect2.UnsafePtrType)
ptrElemType := ptrType.Elem()
if iter.WhatIsNext() == NilValue {
if ptrElemType.Kind() != reflect.Ptr {
iter.skipFourBytes('n', 'u', 'l', 'l')
*pObj = nil
return
}
}
if reflect2.IsNil(obj) {
obj := ptrElemType.New()
iter.ReadVal(obj)
*pObj = obj
return
}
iter.ReadVal(obj)
}
type ifaceDecoder struct {
valType *reflect2.UnsafeIFaceType
}
func (decoder *ifaceDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
if iter.ReadNil() {
decoder.valType.UnsafeSet(ptr, decoder.valType.UnsafeNew())
return
}
obj := decoder.valType.UnsafeIndirect(ptr)
if reflect2.IsNil(obj) {
iter.ReportError("decode non empty interface", "can not unmarshal into nil")
return
}
iter.ReadVal(obj)
}

284
vendor/github.com/json-iterator/go/feature_reflect_extension.go → vendor/github.com/json-iterator/go/reflect_extension.go сгенерированный поставляемый
Просмотреть файл

@ -2,6 +2,7 @@ package jsoniter
import (
"fmt"
"github.com/modern-go/reflect2"
"reflect"
"sort"
"strings"
@ -17,17 +18,15 @@ var extensions = []Extension{}
// StructDescriptor describe how should we encode/decode the struct
type StructDescriptor struct {
onePtrEmbedded bool
onePtrOptimization bool
Type reflect.Type
Fields []*Binding
Type reflect2.Type
Fields []*Binding
}
// GetField get one field from the descriptor by its name.
// Can not use map here to keep field orders.
func (structDescriptor *StructDescriptor) GetField(fieldName string) *Binding {
for _, binding := range structDescriptor.Fields {
if binding.Field.Name == fieldName {
if binding.Field.Name() == fieldName {
return binding
}
}
@ -37,7 +36,7 @@ func (structDescriptor *StructDescriptor) GetField(fieldName string) *Binding {
// Binding describe how should we encode/decode the struct field
type Binding struct {
levels []int
Field *reflect.StructField
Field reflect2.StructField
FromNames []string
ToNames []string
Encoder ValEncoder
@ -48,10 +47,12 @@ type Binding struct {
// Can also rename fields by UpdateStructDescriptor.
type Extension interface {
UpdateStructDescriptor(structDescriptor *StructDescriptor)
CreateDecoder(typ reflect.Type) ValDecoder
CreateEncoder(typ reflect.Type) ValEncoder
DecorateDecoder(typ reflect.Type, decoder ValDecoder) ValDecoder
DecorateEncoder(typ reflect.Type, encoder ValEncoder) ValEncoder
CreateMapKeyDecoder(typ reflect2.Type) ValDecoder
CreateMapKeyEncoder(typ reflect2.Type) ValEncoder
CreateDecoder(typ reflect2.Type) ValDecoder
CreateEncoder(typ reflect2.Type) ValEncoder
DecorateDecoder(typ reflect2.Type, decoder ValDecoder) ValDecoder
DecorateEncoder(typ reflect2.Type, encoder ValEncoder) ValEncoder
}
// DummyExtension embed this type get dummy implementation for all methods of Extension
@ -62,23 +63,105 @@ type DummyExtension struct {
func (extension *DummyExtension) UpdateStructDescriptor(structDescriptor *StructDescriptor) {
}
// CreateMapKeyDecoder No-op
func (extension *DummyExtension) CreateMapKeyDecoder(typ reflect2.Type) ValDecoder {
return nil
}
// CreateMapKeyEncoder No-op
func (extension *DummyExtension) CreateMapKeyEncoder(typ reflect2.Type) ValEncoder {
return nil
}
// CreateDecoder No-op
func (extension *DummyExtension) CreateDecoder(typ reflect.Type) ValDecoder {
func (extension *DummyExtension) CreateDecoder(typ reflect2.Type) ValDecoder {
return nil
}
// CreateEncoder No-op
func (extension *DummyExtension) CreateEncoder(typ reflect.Type) ValEncoder {
func (extension *DummyExtension) CreateEncoder(typ reflect2.Type) ValEncoder {
return nil
}
// DecorateDecoder No-op
func (extension *DummyExtension) DecorateDecoder(typ reflect.Type, decoder ValDecoder) ValDecoder {
func (extension *DummyExtension) DecorateDecoder(typ reflect2.Type, decoder ValDecoder) ValDecoder {
return decoder
}
// DecorateEncoder No-op
func (extension *DummyExtension) DecorateEncoder(typ reflect.Type, encoder ValEncoder) ValEncoder {
func (extension *DummyExtension) DecorateEncoder(typ reflect2.Type, encoder ValEncoder) ValEncoder {
return encoder
}
type EncoderExtension map[reflect2.Type]ValEncoder
// UpdateStructDescriptor No-op
func (extension EncoderExtension) UpdateStructDescriptor(structDescriptor *StructDescriptor) {
}
// CreateDecoder No-op
func (extension EncoderExtension) CreateDecoder(typ reflect2.Type) ValDecoder {
return nil
}
// CreateEncoder get encoder from map
func (extension EncoderExtension) CreateEncoder(typ reflect2.Type) ValEncoder {
return extension[typ]
}
// CreateMapKeyDecoder No-op
func (extension EncoderExtension) CreateMapKeyDecoder(typ reflect2.Type) ValDecoder {
return nil
}
// CreateMapKeyEncoder No-op
func (extension EncoderExtension) CreateMapKeyEncoder(typ reflect2.Type) ValEncoder {
return nil
}
// DecorateDecoder No-op
func (extension EncoderExtension) DecorateDecoder(typ reflect2.Type, decoder ValDecoder) ValDecoder {
return decoder
}
// DecorateEncoder No-op
func (extension EncoderExtension) DecorateEncoder(typ reflect2.Type, encoder ValEncoder) ValEncoder {
return encoder
}
type DecoderExtension map[reflect2.Type]ValDecoder
// UpdateStructDescriptor No-op
func (extension DecoderExtension) UpdateStructDescriptor(structDescriptor *StructDescriptor) {
}
// CreateMapKeyDecoder No-op
func (extension DecoderExtension) CreateMapKeyDecoder(typ reflect2.Type) ValDecoder {
return nil
}
// CreateMapKeyEncoder No-op
func (extension DecoderExtension) CreateMapKeyEncoder(typ reflect2.Type) ValEncoder {
return nil
}
// CreateDecoder get decoder from map
func (extension DecoderExtension) CreateDecoder(typ reflect2.Type) ValDecoder {
return extension[typ]
}
// CreateEncoder No-op
func (extension DecoderExtension) CreateEncoder(typ reflect2.Type) ValEncoder {
return nil
}
// DecorateDecoder No-op
func (extension DecoderExtension) DecorateDecoder(typ reflect2.Type, decoder ValDecoder) ValDecoder {
return decoder
}
// DecorateEncoder No-op
func (extension DecoderExtension) DecorateEncoder(typ reflect2.Type, encoder ValEncoder) ValEncoder {
return encoder
}
@ -99,10 +182,6 @@ func (encoder *funcEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
encoder.fun(ptr, stream)
}
func (encoder *funcEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *funcEncoder) IsEmpty(ptr unsafe.Pointer) bool {
if encoder.isEmptyFunc == nil {
return false
@ -161,78 +240,90 @@ func RegisterExtension(extension Extension) {
extensions = append(extensions, extension)
}
func getTypeDecoderFromExtension(cfg *frozenConfig, typ reflect.Type) ValDecoder {
decoder := _getTypeDecoderFromExtension(cfg, typ)
func getTypeDecoderFromExtension(ctx *ctx, typ reflect2.Type) ValDecoder {
decoder := _getTypeDecoderFromExtension(ctx, typ)
if decoder != nil {
for _, extension := range extensions {
decoder = extension.DecorateDecoder(typ, decoder)
}
for _, extension := range cfg.extensions {
decoder = ctx.decoderExtension.DecorateDecoder(typ, decoder)
for _, extension := range ctx.extraExtensions {
decoder = extension.DecorateDecoder(typ, decoder)
}
}
return decoder
}
func _getTypeDecoderFromExtension(cfg *frozenConfig, typ reflect.Type) ValDecoder {
func _getTypeDecoderFromExtension(ctx *ctx, typ reflect2.Type) ValDecoder {
for _, extension := range extensions {
decoder := extension.CreateDecoder(typ)
if decoder != nil {
return decoder
}
}
for _, extension := range cfg.extensions {
decoder := ctx.decoderExtension.CreateDecoder(typ)
if decoder != nil {
return decoder
}
for _, extension := range ctx.extraExtensions {
decoder := extension.CreateDecoder(typ)
if decoder != nil {
return decoder
}
}
typeName := typ.String()
decoder := typeDecoders[typeName]
decoder = typeDecoders[typeName]
if decoder != nil {
return decoder
}
if typ.Kind() == reflect.Ptr {
decoder := typeDecoders[typ.Elem().String()]
ptrType := typ.(*reflect2.UnsafePtrType)
decoder := typeDecoders[ptrType.Elem().String()]
if decoder != nil {
return &OptionalDecoder{typ.Elem(), decoder}
return &OptionalDecoder{ptrType.Elem(), decoder}
}
}
return nil
}
func getTypeEncoderFromExtension(cfg *frozenConfig, typ reflect.Type) ValEncoder {
encoder := _getTypeEncoderFromExtension(cfg, typ)
func getTypeEncoderFromExtension(ctx *ctx, typ reflect2.Type) ValEncoder {
encoder := _getTypeEncoderFromExtension(ctx, typ)
if encoder != nil {
for _, extension := range extensions {
encoder = extension.DecorateEncoder(typ, encoder)
}
for _, extension := range cfg.extensions {
encoder = ctx.encoderExtension.DecorateEncoder(typ, encoder)
for _, extension := range ctx.extraExtensions {
encoder = extension.DecorateEncoder(typ, encoder)
}
}
return encoder
}
func _getTypeEncoderFromExtension(cfg *frozenConfig, typ reflect.Type) ValEncoder {
func _getTypeEncoderFromExtension(ctx *ctx, typ reflect2.Type) ValEncoder {
for _, extension := range extensions {
encoder := extension.CreateEncoder(typ)
if encoder != nil {
return encoder
}
}
for _, extension := range cfg.extensions {
encoder := ctx.encoderExtension.CreateEncoder(typ)
if encoder != nil {
return encoder
}
for _, extension := range ctx.extraExtensions {
encoder := extension.CreateEncoder(typ)
if encoder != nil {
return encoder
}
}
typeName := typ.String()
encoder := typeEncoders[typeName]
encoder = typeEncoders[typeName]
if encoder != nil {
return encoder
}
if typ.Kind() == reflect.Ptr {
encoder := typeEncoders[typ.Elem().String()]
typePtr := typ.(*reflect2.UnsafePtrType)
encoder := typeEncoders[typePtr.Elem().String()]
if encoder != nil {
return &OptionalEncoder{encoder}
}
@ -240,72 +331,60 @@ func _getTypeEncoderFromExtension(cfg *frozenConfig, typ reflect.Type) ValEncode
return nil
}
func describeStruct(cfg *frozenConfig, typ reflect.Type) (*StructDescriptor, error) {
func describeStruct(ctx *ctx, typ reflect2.Type) *StructDescriptor {
structType := typ.(*reflect2.UnsafeStructType)
embeddedBindings := []*Binding{}
bindings := []*Binding{}
for i := 0; i < typ.NumField(); i++ {
field := typ.Field(i)
tag := field.Tag.Get(cfg.getTagKey())
for i := 0; i < structType.NumField(); i++ {
field := structType.Field(i)
tag, hastag := field.Tag().Lookup(ctx.getTagKey())
if ctx.onlyTaggedField && !hastag {
continue
}
tagParts := strings.Split(tag, ",")
if tag == "-" {
continue
}
if field.Anonymous && (tag == "" || tagParts[0] == "") {
if field.Type.Kind() == reflect.Struct {
structDescriptor, err := describeStruct(cfg, field.Type)
if err != nil {
return nil, err
}
if field.Anonymous() && (tag == "" || tagParts[0] == "") {
if field.Type().Kind() == reflect.Struct {
structDescriptor := describeStruct(ctx, field.Type())
for _, binding := range structDescriptor.Fields {
binding.levels = append([]int{i}, binding.levels...)
omitempty := binding.Encoder.(*structFieldEncoder).omitempty
binding.Encoder = &structFieldEncoder{&field, binding.Encoder, omitempty}
binding.Decoder = &structFieldDecoder{&field, binding.Decoder}
binding.Encoder = &structFieldEncoder{field, binding.Encoder, omitempty}
binding.Decoder = &structFieldDecoder{field, binding.Decoder}
embeddedBindings = append(embeddedBindings, binding)
}
continue
} else if field.Type.Kind() == reflect.Ptr && field.Type.Elem().Kind() == reflect.Struct {
structDescriptor, err := describeStruct(cfg, field.Type.Elem())
if err != nil {
return nil, err
} else if field.Type().Kind() == reflect.Ptr {
ptrType := field.Type().(*reflect2.UnsafePtrType)
if ptrType.Elem().Kind() == reflect.Struct {
structDescriptor := describeStruct(ctx, ptrType.Elem())
for _, binding := range structDescriptor.Fields {
binding.levels = append([]int{i}, binding.levels...)
omitempty := binding.Encoder.(*structFieldEncoder).omitempty
binding.Encoder = &dereferenceEncoder{binding.Encoder}
binding.Encoder = &structFieldEncoder{field, binding.Encoder, omitempty}
binding.Decoder = &dereferenceDecoder{ptrType.Elem(), binding.Decoder}
binding.Decoder = &structFieldDecoder{field, binding.Decoder}
embeddedBindings = append(embeddedBindings, binding)
}
continue
}
for _, binding := range structDescriptor.Fields {
binding.levels = append([]int{i}, binding.levels...)
omitempty := binding.Encoder.(*structFieldEncoder).omitempty
binding.Encoder = &OptionalEncoder{binding.Encoder}
binding.Encoder = &structFieldEncoder{&field, binding.Encoder, omitempty}
binding.Decoder = &deferenceDecoder{field.Type.Elem(), binding.Decoder}
binding.Decoder = &structFieldDecoder{&field, binding.Decoder}
embeddedBindings = append(embeddedBindings, binding)
}
continue
}
}
fieldNames := calcFieldNames(field.Name, tagParts[0], tag)
fieldCacheKey := fmt.Sprintf("%s/%s", typ.String(), field.Name)
fieldNames := calcFieldNames(field.Name(), tagParts[0], tag)
fieldCacheKey := fmt.Sprintf("%s/%s", typ.String(), field.Name())
decoder := fieldDecoders[fieldCacheKey]
if decoder == nil {
var err error
decoder, err = decoderOfType(cfg, field.Type)
if len(fieldNames) > 0 && err != nil {
return nil, err
}
decoder = decoderOfType(ctx.append(field.Name()), field.Type())
}
encoder := fieldEncoders[fieldCacheKey]
if encoder == nil {
var err error
encoder, err = encoderOfType(cfg, field.Type)
if len(fieldNames) > 0 && err != nil {
return nil, err
}
// map is stored as pointer in the struct,
// and treat nil or empty map as empty field
if encoder != nil && field.Type.Kind() == reflect.Map {
encoder = &optionalMapEncoder{encoder}
}
encoder = encoderOfType(ctx.append(field.Name()), field.Type())
}
binding := &Binding{
Field: &field,
Field: field,
FromNames: fieldNames,
ToNames: fieldNames,
Decoder: decoder,
@ -314,38 +393,22 @@ func describeStruct(cfg *frozenConfig, typ reflect.Type) (*StructDescriptor, err
binding.levels = []int{i}
bindings = append(bindings, binding)
}
return createStructDescriptor(cfg, typ, bindings, embeddedBindings), nil
return createStructDescriptor(ctx, typ, bindings, embeddedBindings)
}
func createStructDescriptor(cfg *frozenConfig, typ reflect.Type, bindings []*Binding, embeddedBindings []*Binding) *StructDescriptor {
onePtrEmbedded := false
onePtrOptimization := false
if typ.NumField() == 1 {
firstField := typ.Field(0)
switch firstField.Type.Kind() {
case reflect.Ptr:
if firstField.Anonymous && firstField.Type.Elem().Kind() == reflect.Struct {
onePtrEmbedded = true
}
fallthrough
case reflect.Map:
onePtrOptimization = true
case reflect.Struct:
onePtrOptimization = isStructOnePtr(firstField.Type)
}
}
func createStructDescriptor(ctx *ctx, typ reflect2.Type, bindings []*Binding, embeddedBindings []*Binding) *StructDescriptor {
structDescriptor := &StructDescriptor{
onePtrEmbedded: onePtrEmbedded,
onePtrOptimization: onePtrOptimization,
Type: typ,
Fields: bindings,
Type: typ,
Fields: bindings,
}
for _, extension := range extensions {
extension.UpdateStructDescriptor(structDescriptor)
}
for _, extension := range cfg.extensions {
ctx.encoderExtension.UpdateStructDescriptor(structDescriptor)
ctx.decoderExtension.UpdateStructDescriptor(structDescriptor)
for _, extension := range ctx.extraExtensions {
extension.UpdateStructDescriptor(structDescriptor)
}
processTags(structDescriptor, cfg)
processTags(structDescriptor, ctx.frozenConfig)
// merge normal & embedded bindings & sort with original order
allBindings := sortableBindings(append(embeddedBindings, structDescriptor.Fields...))
sort.Sort(allBindings)
@ -353,21 +416,6 @@ func createStructDescriptor(cfg *frozenConfig, typ reflect.Type, bindings []*Bin
return structDescriptor
}
func isStructOnePtr(typ reflect.Type) bool {
if typ.NumField() == 1 {
firstField := typ.Field(0)
switch firstField.Type.Kind() {
case reflect.Ptr:
return true
case reflect.Map:
return true
case reflect.Struct:
return isStructOnePtr(firstField.Type)
}
}
return false
}
type sortableBindings []*Binding
func (bindings sortableBindings) Len() int {
@ -395,12 +443,12 @@ func (bindings sortableBindings) Swap(i, j int) {
func processTags(structDescriptor *StructDescriptor, cfg *frozenConfig) {
for _, binding := range structDescriptor.Fields {
shouldOmitEmpty := false
tagParts := strings.Split(binding.Field.Tag.Get(cfg.getTagKey()), ",")
tagParts := strings.Split(binding.Field.Tag().Get(cfg.getTagKey()), ",")
for _, tagPart := range tagParts[1:] {
if tagPart == "omitempty" {
shouldOmitEmpty = true
} else if tagPart == "string" {
if binding.Field.Type.Kind() == reflect.String {
if binding.Field.Type().Kind() == reflect.String {
binding.Decoder = &stringModeStringDecoder{binding.Decoder, cfg}
binding.Encoder = &stringModeStringEncoder{binding.Encoder, cfg}
} else {

112
vendor/github.com/json-iterator/go/reflect_json_number.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,112 @@
package jsoniter
import (
"encoding/json"
"github.com/modern-go/reflect2"
"strconv"
"unsafe"
)
type Number string
// String returns the literal text of the number.
func (n Number) String() string { return string(n) }
// Float64 returns the number as a float64.
func (n Number) Float64() (float64, error) {
return strconv.ParseFloat(string(n), 64)
}
// Int64 returns the number as an int64.
func (n Number) Int64() (int64, error) {
return strconv.ParseInt(string(n), 10, 64)
}
func CastJsonNumber(val interface{}) (string, bool) {
switch typedVal := val.(type) {
case json.Number:
return string(typedVal), true
case Number:
return string(typedVal), true
}
return "", false
}
var jsonNumberType = reflect2.TypeOfPtr((*json.Number)(nil)).Elem()
var jsoniterNumberType = reflect2.TypeOfPtr((*Number)(nil)).Elem()
func createDecoderOfJsonNumber(ctx *ctx, typ reflect2.Type) ValDecoder {
if typ.AssignableTo(jsonNumberType) {
return &jsonNumberCodec{}
}
if typ.AssignableTo(jsoniterNumberType) {
return &jsoniterNumberCodec{}
}
return nil
}
func createEncoderOfJsonNumber(ctx *ctx, typ reflect2.Type) ValEncoder {
if typ.AssignableTo(jsonNumberType) {
return &jsonNumberCodec{}
}
if typ.AssignableTo(jsoniterNumberType) {
return &jsoniterNumberCodec{}
}
return nil
}
type jsonNumberCodec struct {
}
func (codec *jsonNumberCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
switch iter.WhatIsNext() {
case StringValue:
*((*json.Number)(ptr)) = json.Number(iter.ReadString())
case NilValue:
iter.skipFourBytes('n', 'u', 'l', 'l')
*((*json.Number)(ptr)) = ""
default:
*((*json.Number)(ptr)) = json.Number([]byte(iter.readNumberAsString()))
}
}
func (codec *jsonNumberCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
number := *((*json.Number)(ptr))
if len(number) == 0 {
stream.writeByte('0')
} else {
stream.WriteRaw(string(number))
}
}
func (codec *jsonNumberCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*json.Number)(ptr))) == 0
}
type jsoniterNumberCodec struct {
}
func (codec *jsoniterNumberCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
switch iter.WhatIsNext() {
case StringValue:
*((*Number)(ptr)) = Number(iter.ReadString())
case NilValue:
iter.skipFourBytes('n', 'u', 'l', 'l')
*((*Number)(ptr)) = ""
default:
*((*Number)(ptr)) = Number([]byte(iter.readNumberAsString()))
}
}
func (codec *jsoniterNumberCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
number := *((*Number)(ptr))
if len(number) == 0 {
stream.writeByte('0')
} else {
stream.WriteRaw(string(number))
}
}
func (codec *jsoniterNumberCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*Number)(ptr))) == 0
}

60
vendor/github.com/json-iterator/go/reflect_json_raw_message.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,60 @@
package jsoniter
import (
"encoding/json"
"github.com/modern-go/reflect2"
"unsafe"
)
var jsonRawMessageType = reflect2.TypeOfPtr((*json.RawMessage)(nil)).Elem()
var jsoniterRawMessageType = reflect2.TypeOfPtr((*RawMessage)(nil)).Elem()
func createEncoderOfJsonRawMessage(ctx *ctx, typ reflect2.Type) ValEncoder {
if typ == jsonRawMessageType {
return &jsonRawMessageCodec{}
}
if typ == jsoniterRawMessageType {
return &jsoniterRawMessageCodec{}
}
return nil
}
func createDecoderOfJsonRawMessage(ctx *ctx, typ reflect2.Type) ValDecoder {
if typ == jsonRawMessageType {
return &jsonRawMessageCodec{}
}
if typ == jsoniterRawMessageType {
return &jsoniterRawMessageCodec{}
}
return nil
}
type jsonRawMessageCodec struct {
}
func (codec *jsonRawMessageCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*((*json.RawMessage)(ptr)) = json.RawMessage(iter.SkipAndReturnBytes())
}
func (codec *jsonRawMessageCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteRaw(string(*((*json.RawMessage)(ptr))))
}
func (codec *jsonRawMessageCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*json.RawMessage)(ptr))) == 0
}
type jsoniterRawMessageCodec struct {
}
func (codec *jsoniterRawMessageCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*((*RawMessage)(ptr)) = RawMessage(iter.SkipAndReturnBytes())
}
func (codec *jsoniterRawMessageCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteRaw(string(*((*RawMessage)(ptr))))
}
func (codec *jsoniterRawMessageCodec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*RawMessage)(ptr))) == 0
}

326
vendor/github.com/json-iterator/go/reflect_map.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,326 @@
package jsoniter
import (
"fmt"
"github.com/modern-go/reflect2"
"io"
"reflect"
"sort"
"unsafe"
)
func decoderOfMap(ctx *ctx, typ reflect2.Type) ValDecoder {
mapType := typ.(*reflect2.UnsafeMapType)
keyDecoder := decoderOfMapKey(ctx.append("[mapKey]"), mapType.Key())
elemDecoder := decoderOfType(ctx.append("[mapElem]"), mapType.Elem())
return &mapDecoder{
mapType: mapType,
keyType: mapType.Key(),
elemType: mapType.Elem(),
keyDecoder: keyDecoder,
elemDecoder: elemDecoder,
}
}
func encoderOfMap(ctx *ctx, typ reflect2.Type) ValEncoder {
mapType := typ.(*reflect2.UnsafeMapType)
if ctx.sortMapKeys {
return &sortKeysMapEncoder{
mapType: mapType,
keyEncoder: encoderOfMapKey(ctx.append("[mapKey]"), mapType.Key()),
elemEncoder: encoderOfType(ctx.append("[mapElem]"), mapType.Elem()),
}
}
return &mapEncoder{
mapType: mapType,
keyEncoder: encoderOfMapKey(ctx.append("[mapKey]"), mapType.Key()),
elemEncoder: encoderOfType(ctx.append("[mapElem]"), mapType.Elem()),
}
}
func decoderOfMapKey(ctx *ctx, typ reflect2.Type) ValDecoder {
decoder := ctx.decoderExtension.CreateMapKeyDecoder(typ)
if decoder != nil {
return decoder
}
for _, extension := range ctx.extraExtensions {
decoder := extension.CreateMapKeyDecoder(typ)
if decoder != nil {
return decoder
}
}
switch typ.Kind() {
case reflect.String:
return decoderOfType(ctx, reflect2.DefaultTypeOfKind(reflect.String))
case reflect.Bool,
reflect.Uint8, reflect.Int8,
reflect.Uint16, reflect.Int16,
reflect.Uint32, reflect.Int32,
reflect.Uint64, reflect.Int64,
reflect.Uint, reflect.Int,
reflect.Float32, reflect.Float64,
reflect.Uintptr:
typ = reflect2.DefaultTypeOfKind(typ.Kind())
return &numericMapKeyDecoder{decoderOfType(ctx, typ)}
default:
ptrType := reflect2.PtrTo(typ)
if ptrType.Implements(textMarshalerType) {
return &referenceDecoder{
&textUnmarshalerDecoder{
valType: ptrType,
},
}
}
if typ.Implements(textMarshalerType) {
return &textUnmarshalerDecoder{
valType: typ,
}
}
return &lazyErrorDecoder{err: fmt.Errorf("unsupported map key type: %v", typ)}
}
}
func encoderOfMapKey(ctx *ctx, typ reflect2.Type) ValEncoder {
encoder := ctx.encoderExtension.CreateMapKeyEncoder(typ)
if encoder != nil {
return encoder
}
for _, extension := range ctx.extraExtensions {
encoder := extension.CreateMapKeyEncoder(typ)
if encoder != nil {
return encoder
}
}
switch typ.Kind() {
case reflect.String:
return encoderOfType(ctx, reflect2.DefaultTypeOfKind(reflect.String))
case reflect.Bool,
reflect.Uint8, reflect.Int8,
reflect.Uint16, reflect.Int16,
reflect.Uint32, reflect.Int32,
reflect.Uint64, reflect.Int64,
reflect.Uint, reflect.Int,
reflect.Float32, reflect.Float64,
reflect.Uintptr:
typ = reflect2.DefaultTypeOfKind(typ.Kind())
return &numericMapKeyEncoder{encoderOfType(ctx, typ)}
default:
if typ == textMarshalerType {
return &directTextMarshalerEncoder{
stringEncoder: ctx.EncoderOf(reflect2.TypeOf("")),
}
}
if typ.Implements(textMarshalerType) {
return &textMarshalerEncoder{
valType: typ,
stringEncoder: ctx.EncoderOf(reflect2.TypeOf("")),
}
}
if typ.Kind() == reflect.Interface {
return &dynamicMapKeyEncoder{ctx, typ}
}
return &lazyErrorEncoder{err: fmt.Errorf("unsupported map key type: %v", typ)}
}
}
type mapDecoder struct {
mapType *reflect2.UnsafeMapType
keyType reflect2.Type
elemType reflect2.Type
keyDecoder ValDecoder
elemDecoder ValDecoder
}
func (decoder *mapDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
mapType := decoder.mapType
c := iter.nextToken()
if c == 'n' {
iter.skipThreeBytes('u', 'l', 'l')
*(*unsafe.Pointer)(ptr) = nil
mapType.UnsafeSet(ptr, mapType.UnsafeNew())
return
}
if mapType.UnsafeIsNil(ptr) {
mapType.UnsafeSet(ptr, mapType.UnsafeMakeMap(0))
}
if c != '{' {
iter.ReportError("ReadMapCB", `expect { or n, but found `+string([]byte{c}))
return
}
c = iter.nextToken()
if c == '}' {
return
}
if c != '"' {
iter.ReportError("ReadMapCB", `expect " after }, but found `+string([]byte{c}))
return
}
iter.unreadByte()
key := decoder.keyType.UnsafeNew()
decoder.keyDecoder.Decode(key, iter)
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadMapCB", "expect : after object field, but found "+string([]byte{c}))
return
}
elem := decoder.elemType.UnsafeNew()
decoder.elemDecoder.Decode(elem, iter)
decoder.mapType.UnsafeSetIndex(ptr, key, elem)
for c = iter.nextToken(); c == ','; c = iter.nextToken() {
key := decoder.keyType.UnsafeNew()
decoder.keyDecoder.Decode(key, iter)
c = iter.nextToken()
if c != ':' {
iter.ReportError("ReadMapCB", "expect : after object field, but found "+string([]byte{c}))
return
}
elem := decoder.elemType.UnsafeNew()
decoder.elemDecoder.Decode(elem, iter)
decoder.mapType.UnsafeSetIndex(ptr, key, elem)
}
if c != '}' {
iter.ReportError("ReadMapCB", `expect }, but found `+string([]byte{c}))
}
}
type numericMapKeyDecoder struct {
decoder ValDecoder
}
func (decoder *numericMapKeyDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
c := iter.nextToken()
if c != '"' {
iter.ReportError("ReadMapCB", `expect ", but found `+string([]byte{c}))
return
}
decoder.decoder.Decode(ptr, iter)
c = iter.nextToken()
if c != '"' {
iter.ReportError("ReadMapCB", `expect ", but found `+string([]byte{c}))
return
}
}
type numericMapKeyEncoder struct {
encoder ValEncoder
}
func (encoder *numericMapKeyEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.writeByte('"')
encoder.encoder.Encode(ptr, stream)
stream.writeByte('"')
}
func (encoder *numericMapKeyEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return false
}
type dynamicMapKeyEncoder struct {
ctx *ctx
valType reflect2.Type
}
func (encoder *dynamicMapKeyEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
obj := encoder.valType.UnsafeIndirect(ptr)
encoderOfMapKey(encoder.ctx, reflect2.TypeOf(obj)).Encode(reflect2.PtrOf(obj), stream)
}
func (encoder *dynamicMapKeyEncoder) IsEmpty(ptr unsafe.Pointer) bool {
obj := encoder.valType.UnsafeIndirect(ptr)
return encoderOfMapKey(encoder.ctx, reflect2.TypeOf(obj)).IsEmpty(reflect2.PtrOf(obj))
}
type mapEncoder struct {
mapType *reflect2.UnsafeMapType
keyEncoder ValEncoder
elemEncoder ValEncoder
}
func (encoder *mapEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteObjectStart()
iter := encoder.mapType.UnsafeIterate(ptr)
for i := 0; iter.HasNext(); i++ {
if i != 0 {
stream.WriteMore()
}
key, elem := iter.UnsafeNext()
encoder.keyEncoder.Encode(key, stream)
if stream.indention > 0 {
stream.writeTwoBytes(byte(':'), byte(' '))
} else {
stream.writeByte(':')
}
encoder.elemEncoder.Encode(elem, stream)
}
stream.WriteObjectEnd()
}
func (encoder *mapEncoder) IsEmpty(ptr unsafe.Pointer) bool {
iter := encoder.mapType.UnsafeIterate(ptr)
return !iter.HasNext()
}
type sortKeysMapEncoder struct {
mapType *reflect2.UnsafeMapType
keyEncoder ValEncoder
elemEncoder ValEncoder
}
func (encoder *sortKeysMapEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if *(*unsafe.Pointer)(ptr) == nil {
stream.WriteNil()
return
}
stream.WriteObjectStart()
mapIter := encoder.mapType.UnsafeIterate(ptr)
subStream := stream.cfg.BorrowStream(nil)
subIter := stream.cfg.BorrowIterator(nil)
keyValues := encodedKeyValues{}
for mapIter.HasNext() {
subStream.buf = make([]byte, 0, 64)
key, elem := mapIter.UnsafeNext()
encoder.keyEncoder.Encode(key, subStream)
if subStream.Error != nil && subStream.Error != io.EOF && stream.Error == nil {
stream.Error = subStream.Error
}
encodedKey := subStream.Buffer()
subIter.ResetBytes(encodedKey)
decodedKey := subIter.ReadString()
if stream.indention > 0 {
subStream.writeTwoBytes(byte(':'), byte(' '))
} else {
subStream.writeByte(':')
}
encoder.elemEncoder.Encode(elem, subStream)
keyValues = append(keyValues, encodedKV{
key: decodedKey,
keyValue: subStream.Buffer(),
})
}
sort.Sort(keyValues)
for i, keyValue := range keyValues {
if i != 0 {
stream.WriteMore()
}
stream.Write(keyValue.keyValue)
}
stream.WriteObjectEnd()
stream.cfg.ReturnStream(subStream)
stream.cfg.ReturnIterator(subIter)
}
func (encoder *sortKeysMapEncoder) IsEmpty(ptr unsafe.Pointer) bool {
iter := encoder.mapType.UnsafeIterate(ptr)
return !iter.HasNext()
}
type encodedKeyValues []encodedKV
type encodedKV struct {
key string
keyValue []byte
}
func (sv encodedKeyValues) Len() int { return len(sv) }
func (sv encodedKeyValues) Swap(i, j int) { sv[i], sv[j] = sv[j], sv[i] }
func (sv encodedKeyValues) Less(i, j int) bool { return sv[i].key < sv[j].key }

218
vendor/github.com/json-iterator/go/reflect_marshaler.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,218 @@
package jsoniter
import (
"encoding"
"encoding/json"
"github.com/modern-go/reflect2"
"unsafe"
)
var marshalerType = reflect2.TypeOfPtr((*json.Marshaler)(nil)).Elem()
var unmarshalerType = reflect2.TypeOfPtr((*json.Unmarshaler)(nil)).Elem()
var textMarshalerType = reflect2.TypeOfPtr((*encoding.TextMarshaler)(nil)).Elem()
var textUnmarshalerType = reflect2.TypeOfPtr((*encoding.TextUnmarshaler)(nil)).Elem()
func createDecoderOfMarshaler(ctx *ctx, typ reflect2.Type) ValDecoder {
ptrType := reflect2.PtrTo(typ)
if ptrType.Implements(unmarshalerType) {
return &referenceDecoder{
&unmarshalerDecoder{ptrType},
}
}
if ptrType.Implements(textUnmarshalerType) {
return &referenceDecoder{
&textUnmarshalerDecoder{ptrType},
}
}
return nil
}
func createEncoderOfMarshaler(ctx *ctx, typ reflect2.Type) ValEncoder {
if typ == marshalerType {
checkIsEmpty := createCheckIsEmpty(ctx, typ)
var encoder ValEncoder = &directMarshalerEncoder{
checkIsEmpty: checkIsEmpty,
}
return encoder
}
if typ.Implements(marshalerType) {
checkIsEmpty := createCheckIsEmpty(ctx, typ)
var encoder ValEncoder = &marshalerEncoder{
valType: typ,
checkIsEmpty: checkIsEmpty,
}
return encoder
}
ptrType := reflect2.PtrTo(typ)
if ctx.prefix != "" && ptrType.Implements(marshalerType) {
checkIsEmpty := createCheckIsEmpty(ctx, ptrType)
var encoder ValEncoder = &marshalerEncoder{
valType: ptrType,
checkIsEmpty: checkIsEmpty,
}
return &referenceEncoder{encoder}
}
if typ == textMarshalerType {
checkIsEmpty := createCheckIsEmpty(ctx, typ)
var encoder ValEncoder = &directTextMarshalerEncoder{
checkIsEmpty: checkIsEmpty,
stringEncoder: ctx.EncoderOf(reflect2.TypeOf("")),
}
return encoder
}
if typ.Implements(textMarshalerType) {
checkIsEmpty := createCheckIsEmpty(ctx, typ)
var encoder ValEncoder = &textMarshalerEncoder{
valType: typ,
stringEncoder: ctx.EncoderOf(reflect2.TypeOf("")),
checkIsEmpty: checkIsEmpty,
}
return encoder
}
// if prefix is empty, the type is the root type
if ctx.prefix != "" && ptrType.Implements(textMarshalerType) {
checkIsEmpty := createCheckIsEmpty(ctx, ptrType)
var encoder ValEncoder = &textMarshalerEncoder{
valType: ptrType,
stringEncoder: ctx.EncoderOf(reflect2.TypeOf("")),
checkIsEmpty: checkIsEmpty,
}
return &referenceEncoder{encoder}
}
return nil
}
type marshalerEncoder struct {
checkIsEmpty checkIsEmpty
valType reflect2.Type
}
func (encoder *marshalerEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
obj := encoder.valType.UnsafeIndirect(ptr)
if encoder.valType.IsNullable() && reflect2.IsNil(obj) {
stream.WriteNil()
return
}
marshaler := obj.(json.Marshaler)
bytes, err := marshaler.MarshalJSON()
if err != nil {
stream.Error = err
} else {
stream.Write(bytes)
}
}
func (encoder *marshalerEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.checkIsEmpty.IsEmpty(ptr)
}
type directMarshalerEncoder struct {
checkIsEmpty checkIsEmpty
}
func (encoder *directMarshalerEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
marshaler := *(*json.Marshaler)(ptr)
if marshaler == nil {
stream.WriteNil()
return
}
bytes, err := marshaler.MarshalJSON()
if err != nil {
stream.Error = err
} else {
stream.Write(bytes)
}
}
func (encoder *directMarshalerEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.checkIsEmpty.IsEmpty(ptr)
}
type textMarshalerEncoder struct {
valType reflect2.Type
stringEncoder ValEncoder
checkIsEmpty checkIsEmpty
}
func (encoder *textMarshalerEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
obj := encoder.valType.UnsafeIndirect(ptr)
if encoder.valType.IsNullable() && reflect2.IsNil(obj) {
stream.WriteNil()
return
}
marshaler := (obj).(encoding.TextMarshaler)
bytes, err := marshaler.MarshalText()
if err != nil {
stream.Error = err
} else {
str := string(bytes)
encoder.stringEncoder.Encode(unsafe.Pointer(&str), stream)
}
}
func (encoder *textMarshalerEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.checkIsEmpty.IsEmpty(ptr)
}
type directTextMarshalerEncoder struct {
stringEncoder ValEncoder
checkIsEmpty checkIsEmpty
}
func (encoder *directTextMarshalerEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
marshaler := *(*encoding.TextMarshaler)(ptr)
if marshaler == nil {
stream.WriteNil()
return
}
bytes, err := marshaler.MarshalText()
if err != nil {
stream.Error = err
} else {
str := string(bytes)
encoder.stringEncoder.Encode(unsafe.Pointer(&str), stream)
}
}
func (encoder *directTextMarshalerEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.checkIsEmpty.IsEmpty(ptr)
}
type unmarshalerDecoder struct {
valType reflect2.Type
}
func (decoder *unmarshalerDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
valType := decoder.valType
obj := valType.UnsafeIndirect(ptr)
unmarshaler := obj.(json.Unmarshaler)
iter.nextToken()
iter.unreadByte() // skip spaces
bytes := iter.SkipAndReturnBytes()
err := unmarshaler.UnmarshalJSON(bytes)
if err != nil {
iter.ReportError("unmarshalerDecoder", err.Error())
}
}
type textUnmarshalerDecoder struct {
valType reflect2.Type
}
func (decoder *textUnmarshalerDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
valType := decoder.valType
obj := valType.UnsafeIndirect(ptr)
if reflect2.IsNil(obj) {
ptrType := valType.(*reflect2.UnsafePtrType)
elemType := ptrType.Elem()
elem := elemType.UnsafeNew()
ptrType.UnsafeSet(ptr, unsafe.Pointer(&elem))
obj = valType.UnsafeIndirect(ptr)
}
unmarshaler := (obj).(encoding.TextUnmarshaler)
str := iter.ReadString()
err := unmarshaler.UnmarshalText([]byte(str))
if err != nil {
iter.ReportError("textUnmarshalerDecoder", err.Error())
}
}

451
vendor/github.com/json-iterator/go/reflect_native.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,451 @@
package jsoniter
import (
"encoding/base64"
"reflect"
"strconv"
"unsafe"
"github.com/modern-go/reflect2"
)
const ptrSize = 32 << uintptr(^uintptr(0)>>63)
func createEncoderOfNative(ctx *ctx, typ reflect2.Type) ValEncoder {
if typ.Kind() == reflect.Slice && typ.(reflect2.SliceType).Elem().Kind() == reflect.Uint8 {
sliceDecoder := decoderOfSlice(ctx, typ)
return &base64Codec{sliceDecoder: sliceDecoder}
}
typeName := typ.String()
kind := typ.Kind()
switch kind {
case reflect.String:
if typeName != "string" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*string)(nil)).Elem())
}
return &stringCodec{}
case reflect.Int:
if typeName != "int" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*int)(nil)).Elem())
}
if strconv.IntSize == 32 {
return &int32Codec{}
}
return &int64Codec{}
case reflect.Int8:
if typeName != "int8" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*int8)(nil)).Elem())
}
return &int8Codec{}
case reflect.Int16:
if typeName != "int16" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*int16)(nil)).Elem())
}
return &int16Codec{}
case reflect.Int32:
if typeName != "int32" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*int32)(nil)).Elem())
}
return &int32Codec{}
case reflect.Int64:
if typeName != "int64" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*int64)(nil)).Elem())
}
return &int64Codec{}
case reflect.Uint:
if typeName != "uint" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*uint)(nil)).Elem())
}
if strconv.IntSize == 32 {
return &uint32Codec{}
}
return &uint64Codec{}
case reflect.Uint8:
if typeName != "uint8" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*uint8)(nil)).Elem())
}
return &uint8Codec{}
case reflect.Uint16:
if typeName != "uint16" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*uint16)(nil)).Elem())
}
return &uint16Codec{}
case reflect.Uint32:
if typeName != "uint32" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*uint32)(nil)).Elem())
}
return &uint32Codec{}
case reflect.Uintptr:
if typeName != "uintptr" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*uintptr)(nil)).Elem())
}
if ptrSize == 32 {
return &uint32Codec{}
}
return &uint64Codec{}
case reflect.Uint64:
if typeName != "uint64" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*uint64)(nil)).Elem())
}
return &uint64Codec{}
case reflect.Float32:
if typeName != "float32" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*float32)(nil)).Elem())
}
return &float32Codec{}
case reflect.Float64:
if typeName != "float64" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*float64)(nil)).Elem())
}
return &float64Codec{}
case reflect.Bool:
if typeName != "bool" {
return encoderOfType(ctx, reflect2.TypeOfPtr((*bool)(nil)).Elem())
}
return &boolCodec{}
}
return nil
}
func createDecoderOfNative(ctx *ctx, typ reflect2.Type) ValDecoder {
if typ.Kind() == reflect.Slice && typ.(reflect2.SliceType).Elem().Kind() == reflect.Uint8 {
sliceDecoder := decoderOfSlice(ctx, typ)
return &base64Codec{sliceDecoder: sliceDecoder}
}
typeName := typ.String()
switch typ.Kind() {
case reflect.String:
if typeName != "string" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*string)(nil)).Elem())
}
return &stringCodec{}
case reflect.Int:
if typeName != "int" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*int)(nil)).Elem())
}
if strconv.IntSize == 32 {
return &int32Codec{}
}
return &int64Codec{}
case reflect.Int8:
if typeName != "int8" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*int8)(nil)).Elem())
}
return &int8Codec{}
case reflect.Int16:
if typeName != "int16" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*int16)(nil)).Elem())
}
return &int16Codec{}
case reflect.Int32:
if typeName != "int32" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*int32)(nil)).Elem())
}
return &int32Codec{}
case reflect.Int64:
if typeName != "int64" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*int64)(nil)).Elem())
}
return &int64Codec{}
case reflect.Uint:
if typeName != "uint" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*uint)(nil)).Elem())
}
if strconv.IntSize == 32 {
return &uint32Codec{}
}
return &uint64Codec{}
case reflect.Uint8:
if typeName != "uint8" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*uint8)(nil)).Elem())
}
return &uint8Codec{}
case reflect.Uint16:
if typeName != "uint16" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*uint16)(nil)).Elem())
}
return &uint16Codec{}
case reflect.Uint32:
if typeName != "uint32" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*uint32)(nil)).Elem())
}
return &uint32Codec{}
case reflect.Uintptr:
if typeName != "uintptr" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*uintptr)(nil)).Elem())
}
if ptrSize == 32 {
return &uint32Codec{}
}
return &uint64Codec{}
case reflect.Uint64:
if typeName != "uint64" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*uint64)(nil)).Elem())
}
return &uint64Codec{}
case reflect.Float32:
if typeName != "float32" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*float32)(nil)).Elem())
}
return &float32Codec{}
case reflect.Float64:
if typeName != "float64" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*float64)(nil)).Elem())
}
return &float64Codec{}
case reflect.Bool:
if typeName != "bool" {
return decoderOfType(ctx, reflect2.TypeOfPtr((*bool)(nil)).Elem())
}
return &boolCodec{}
}
return nil
}
type stringCodec struct {
}
func (codec *stringCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
*((*string)(ptr)) = iter.ReadString()
}
func (codec *stringCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
str := *((*string)(ptr))
stream.WriteString(str)
}
func (codec *stringCodec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*string)(ptr)) == ""
}
type int8Codec struct {
}
func (codec *int8Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int8)(ptr)) = iter.ReadInt8()
}
}
func (codec *int8Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt8(*((*int8)(ptr)))
}
func (codec *int8Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int8)(ptr)) == 0
}
type int16Codec struct {
}
func (codec *int16Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int16)(ptr)) = iter.ReadInt16()
}
}
func (codec *int16Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt16(*((*int16)(ptr)))
}
func (codec *int16Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int16)(ptr)) == 0
}
type int32Codec struct {
}
func (codec *int32Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int32)(ptr)) = iter.ReadInt32()
}
}
func (codec *int32Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt32(*((*int32)(ptr)))
}
func (codec *int32Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int32)(ptr)) == 0
}
type int64Codec struct {
}
func (codec *int64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*int64)(ptr)) = iter.ReadInt64()
}
}
func (codec *int64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteInt64(*((*int64)(ptr)))
}
func (codec *int64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*int64)(ptr)) == 0
}
type uint8Codec struct {
}
func (codec *uint8Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint8)(ptr)) = iter.ReadUint8()
}
}
func (codec *uint8Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint8(*((*uint8)(ptr)))
}
func (codec *uint8Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint8)(ptr)) == 0
}
type uint16Codec struct {
}
func (codec *uint16Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint16)(ptr)) = iter.ReadUint16()
}
}
func (codec *uint16Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint16(*((*uint16)(ptr)))
}
func (codec *uint16Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint16)(ptr)) == 0
}
type uint32Codec struct {
}
func (codec *uint32Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint32)(ptr)) = iter.ReadUint32()
}
}
func (codec *uint32Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint32(*((*uint32)(ptr)))
}
func (codec *uint32Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint32)(ptr)) == 0
}
type uint64Codec struct {
}
func (codec *uint64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*uint64)(ptr)) = iter.ReadUint64()
}
}
func (codec *uint64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteUint64(*((*uint64)(ptr)))
}
func (codec *uint64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*uint64)(ptr)) == 0
}
type float32Codec struct {
}
func (codec *float32Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*float32)(ptr)) = iter.ReadFloat32()
}
}
func (codec *float32Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteFloat32(*((*float32)(ptr)))
}
func (codec *float32Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*float32)(ptr)) == 0
}
type float64Codec struct {
}
func (codec *float64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*float64)(ptr)) = iter.ReadFloat64()
}
}
func (codec *float64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteFloat64(*((*float64)(ptr)))
}
func (codec *float64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return *((*float64)(ptr)) == 0
}
type boolCodec struct {
}
func (codec *boolCodec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.ReadNil() {
*((*bool)(ptr)) = iter.ReadBool()
}
}
func (codec *boolCodec) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteBool(*((*bool)(ptr)))
}
func (codec *boolCodec) IsEmpty(ptr unsafe.Pointer) bool {
return !(*((*bool)(ptr)))
}
type base64Codec struct {
sliceType *reflect2.UnsafeSliceType
sliceDecoder ValDecoder
}
func (codec *base64Codec) Decode(ptr unsafe.Pointer, iter *Iterator) {
if iter.ReadNil() {
codec.sliceType.UnsafeSetNil(ptr)
return
}
switch iter.WhatIsNext() {
case StringValue:
src := iter.ReadString()
dst, err := base64.StdEncoding.DecodeString(src)
if err != nil {
iter.ReportError("decode base64", err.Error())
} else {
codec.sliceType.UnsafeSet(ptr, unsafe.Pointer(&dst))
}
case ArrayValue:
codec.sliceDecoder.Decode(ptr, iter)
default:
iter.ReportError("base64Codec", "invalid input")
}
}
func (codec *base64Codec) Encode(ptr unsafe.Pointer, stream *Stream) {
src := *((*[]byte)(ptr))
if len(src) == 0 {
stream.WriteNil()
return
}
encoding := base64.StdEncoding
stream.writeByte('"')
size := encoding.EncodedLen(len(src))
buf := make([]byte, size)
encoding.Encode(buf, src)
stream.buf = append(stream.buf, buf...)
stream.writeByte('"')
}
func (codec *base64Codec) IsEmpty(ptr unsafe.Pointer) bool {
return len(*((*[]byte)(ptr))) == 0
}

133
vendor/github.com/json-iterator/go/reflect_optional.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,133 @@
package jsoniter
import (
"github.com/modern-go/reflect2"
"reflect"
"unsafe"
)
func decoderOfOptional(ctx *ctx, typ reflect2.Type) ValDecoder {
ptrType := typ.(*reflect2.UnsafePtrType)
elemType := ptrType.Elem()
decoder := decoderOfType(ctx, elemType)
if ctx.prefix == "" && elemType.Kind() == reflect.Ptr {
return &dereferenceDecoder{elemType, decoder}
}
return &OptionalDecoder{elemType, decoder}
}
func encoderOfOptional(ctx *ctx, typ reflect2.Type) ValEncoder {
ptrType := typ.(*reflect2.UnsafePtrType)
elemType := ptrType.Elem()
elemEncoder := encoderOfType(ctx, elemType)
encoder := &OptionalEncoder{elemEncoder}
return encoder
}
type OptionalDecoder struct {
ValueType reflect2.Type
ValueDecoder ValDecoder
}
func (decoder *OptionalDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
if iter.ReadNil() {
*((*unsafe.Pointer)(ptr)) = nil
} else {
if *((*unsafe.Pointer)(ptr)) == nil {
//pointer to null, we have to allocate memory to hold the value
newPtr := decoder.ValueType.UnsafeNew()
decoder.ValueDecoder.Decode(newPtr, iter)
*((*unsafe.Pointer)(ptr)) = newPtr
} else {
//reuse existing instance
decoder.ValueDecoder.Decode(*((*unsafe.Pointer)(ptr)), iter)
}
}
}
type dereferenceDecoder struct {
// only to deference a pointer
valueType reflect2.Type
valueDecoder ValDecoder
}
func (decoder *dereferenceDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
if *((*unsafe.Pointer)(ptr)) == nil {
//pointer to null, we have to allocate memory to hold the value
newPtr := decoder.valueType.UnsafeNew()
decoder.valueDecoder.Decode(newPtr, iter)
*((*unsafe.Pointer)(ptr)) = newPtr
} else {
//reuse existing instance
decoder.valueDecoder.Decode(*((*unsafe.Pointer)(ptr)), iter)
}
}
type OptionalEncoder struct {
ValueEncoder ValEncoder
}
func (encoder *OptionalEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if *((*unsafe.Pointer)(ptr)) == nil {
stream.WriteNil()
} else {
encoder.ValueEncoder.Encode(*((*unsafe.Pointer)(ptr)), stream)
}
}
func (encoder *OptionalEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return *((*unsafe.Pointer)(ptr)) == nil
}
type dereferenceEncoder struct {
ValueEncoder ValEncoder
}
func (encoder *dereferenceEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if *((*unsafe.Pointer)(ptr)) == nil {
stream.WriteNil()
} else {
encoder.ValueEncoder.Encode(*((*unsafe.Pointer)(ptr)), stream)
}
}
func (encoder *dereferenceEncoder) IsEmpty(ptr unsafe.Pointer) bool {
dePtr := *((*unsafe.Pointer)(ptr))
if dePtr == nil {
return true
}
return encoder.ValueEncoder.IsEmpty(dePtr)
}
func (encoder *dereferenceEncoder) IsEmbeddedPtrNil(ptr unsafe.Pointer) bool {
deReferenced := *((*unsafe.Pointer)(ptr))
if deReferenced == nil {
return true
}
isEmbeddedPtrNil, converted := encoder.ValueEncoder.(IsEmbeddedPtrNil)
if !converted {
return false
}
fieldPtr := unsafe.Pointer(deReferenced)
return isEmbeddedPtrNil.IsEmbeddedPtrNil(fieldPtr)
}
type referenceEncoder struct {
encoder ValEncoder
}
func (encoder *referenceEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
encoder.encoder.Encode(unsafe.Pointer(&ptr), stream)
}
func (encoder *referenceEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.encoder.IsEmpty(unsafe.Pointer(&ptr))
}
type referenceDecoder struct {
decoder ValDecoder
}
func (decoder *referenceDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.decoder.Decode(unsafe.Pointer(&ptr), iter)
}

99
vendor/github.com/json-iterator/go/reflect_slice.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,99 @@
package jsoniter
import (
"fmt"
"github.com/modern-go/reflect2"
"io"
"unsafe"
)
func decoderOfSlice(ctx *ctx, typ reflect2.Type) ValDecoder {
sliceType := typ.(*reflect2.UnsafeSliceType)
decoder := decoderOfType(ctx.append("[sliceElem]"), sliceType.Elem())
return &sliceDecoder{sliceType, decoder}
}
func encoderOfSlice(ctx *ctx, typ reflect2.Type) ValEncoder {
sliceType := typ.(*reflect2.UnsafeSliceType)
encoder := encoderOfType(ctx.append("[sliceElem]"), sliceType.Elem())
return &sliceEncoder{sliceType, encoder}
}
type sliceEncoder struct {
sliceType *reflect2.UnsafeSliceType
elemEncoder ValEncoder
}
func (encoder *sliceEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if encoder.sliceType.UnsafeIsNil(ptr) {
stream.WriteNil()
return
}
length := encoder.sliceType.UnsafeLengthOf(ptr)
if length == 0 {
stream.WriteEmptyArray()
return
}
stream.WriteArrayStart()
encoder.elemEncoder.Encode(encoder.sliceType.UnsafeGetIndex(ptr, 0), stream)
for i := 1; i < length; i++ {
stream.WriteMore()
elemPtr := encoder.sliceType.UnsafeGetIndex(ptr, i)
encoder.elemEncoder.Encode(elemPtr, stream)
}
stream.WriteArrayEnd()
if stream.Error != nil && stream.Error != io.EOF {
stream.Error = fmt.Errorf("%v: %s", encoder.sliceType, stream.Error.Error())
}
}
func (encoder *sliceEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.sliceType.UnsafeLengthOf(ptr) == 0
}
type sliceDecoder struct {
sliceType *reflect2.UnsafeSliceType
elemDecoder ValDecoder
}
func (decoder *sliceDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.doDecode(ptr, iter)
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.sliceType, iter.Error.Error())
}
}
func (decoder *sliceDecoder) doDecode(ptr unsafe.Pointer, iter *Iterator) {
c := iter.nextToken()
sliceType := decoder.sliceType
if c == 'n' {
iter.skipThreeBytes('u', 'l', 'l')
sliceType.UnsafeSetNil(ptr)
return
}
if c != '[' {
iter.ReportError("decode slice", "expect [ or n, but found "+string([]byte{c}))
return
}
c = iter.nextToken()
if c == ']' {
sliceType.UnsafeSet(ptr, sliceType.UnsafeMakeSlice(0, 0))
return
}
iter.unreadByte()
sliceType.UnsafeGrow(ptr, 1)
elemPtr := sliceType.UnsafeGetIndex(ptr, 0)
decoder.elemDecoder.Decode(elemPtr, iter)
length := 1
for c = iter.nextToken(); c == ','; c = iter.nextToken() {
idx := length
length += 1
sliceType.UnsafeGrow(ptr, length)
elemPtr = sliceType.UnsafeGetIndex(ptr, idx)
decoder.elemDecoder.Decode(elemPtr, iter)
}
if c != ']' {
iter.ReportError("decode slice", "expect ], but found "+string([]byte{c}))
return
}
}

532
vendor/github.com/json-iterator/go/feature_reflect_struct_decoder.go → vendor/github.com/json-iterator/go/reflect_struct_decoder.go сгенерированный поставляемый
Просмотреть файл

@ -3,38 +3,78 @@ package jsoniter
import (
"fmt"
"io"
"reflect"
"strings"
"unsafe"
"github.com/modern-go/reflect2"
)
func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder) (ValDecoder, error) {
knownHash := map[int32]struct{}{
func decoderOfStruct(ctx *ctx, typ reflect2.Type) ValDecoder {
bindings := map[string]*Binding{}
structDescriptor := describeStruct(ctx, typ)
for _, binding := range structDescriptor.Fields {
for _, fromName := range binding.FromNames {
old := bindings[fromName]
if old == nil {
bindings[fromName] = binding
continue
}
ignoreOld, ignoreNew := resolveConflictBinding(ctx.frozenConfig, old, binding)
if ignoreOld {
delete(bindings, fromName)
}
if !ignoreNew {
bindings[fromName] = binding
}
}
}
fields := map[string]*structFieldDecoder{}
for k, binding := range bindings {
fields[k] = binding.Decoder.(*structFieldDecoder)
}
if !ctx.caseSensitive() {
for k, binding := range bindings {
if _, found := fields[strings.ToLower(k)]; !found {
fields[strings.ToLower(k)] = binding.Decoder.(*structFieldDecoder)
}
}
}
return createStructDecoder(ctx, typ, fields)
}
func createStructDecoder(ctx *ctx, typ reflect2.Type, fields map[string]*structFieldDecoder) ValDecoder {
if ctx.disallowUnknownFields {
return &generalStructDecoder{typ: typ, fields: fields, disallowUnknownFields: true}
}
knownHash := map[int64]struct{}{
0: {},
}
switch len(fields) {
case 0:
return &skipObjectDecoder{typ}, nil
return &skipObjectDecoder{typ}
case 1:
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
return &oneFieldStructDecoder{typ, fieldHash, fieldDecoder}, nil
return &oneFieldStructDecoder{typ, fieldHash, fieldDecoder}
}
case 2:
var fieldHash1 int32
var fieldHash2 int32
var fieldHash1 int64
var fieldHash2 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldHash1 == 0 {
@ -45,19 +85,19 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
fieldDecoder2 = fieldDecoder
}
}
return &twoFieldsStructDecoder{typ, fieldHash1, fieldDecoder1, fieldHash2, fieldDecoder2}, nil
return &twoFieldsStructDecoder{typ, fieldHash1, fieldDecoder1, fieldHash2, fieldDecoder2}
case 3:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -72,21 +112,23 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &threeFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3}
case 4:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName4 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldName4 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
var fieldDecoder4 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -104,24 +146,26 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &fourFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4}
case 5:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName4 int32
var fieldName5 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldName4 int64
var fieldName5 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
var fieldDecoder4 *structFieldDecoder
var fieldDecoder5 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -142,15 +186,18 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &fiveFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4, fieldName5, fieldDecoder5}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4,
fieldName5, fieldDecoder5}
case 6:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName4 int32
var fieldName5 int32
var fieldName6 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldName4 int64
var fieldName5 int64
var fieldName6 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
@ -158,10 +205,10 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
var fieldDecoder5 *structFieldDecoder
var fieldDecoder6 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -185,16 +232,20 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &sixFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4, fieldName5, fieldDecoder5, fieldName6, fieldDecoder6}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4,
fieldName5, fieldDecoder5,
fieldName6, fieldDecoder6}
case 7:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName4 int32
var fieldName5 int32
var fieldName6 int32
var fieldName7 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldName4 int64
var fieldName5 int64
var fieldName6 int64
var fieldName7 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
@ -203,10 +254,10 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
var fieldDecoder6 *structFieldDecoder
var fieldDecoder7 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -233,18 +284,22 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &sevenFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4, fieldName5, fieldDecoder5, fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4,
fieldName5, fieldDecoder5,
fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7}
case 8:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName4 int32
var fieldName5 int32
var fieldName6 int32
var fieldName7 int32
var fieldName8 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldName4 int64
var fieldName5 int64
var fieldName6 int64
var fieldName7 int64
var fieldName8 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
@ -254,10 +309,10 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
var fieldDecoder7 *structFieldDecoder
var fieldDecoder8 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -287,19 +342,24 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &eightFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4, fieldName5, fieldDecoder5, fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7, fieldName8, fieldDecoder8}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4,
fieldName5, fieldDecoder5,
fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7,
fieldName8, fieldDecoder8}
case 9:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName4 int32
var fieldName5 int32
var fieldName6 int32
var fieldName7 int32
var fieldName8 int32
var fieldName9 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldName4 int64
var fieldName5 int64
var fieldName6 int64
var fieldName7 int64
var fieldName8 int64
var fieldName9 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
@ -310,10 +370,10 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
var fieldDecoder8 *structFieldDecoder
var fieldDecoder9 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -346,20 +406,26 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &nineFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4, fieldName5, fieldDecoder5, fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7, fieldName8, fieldDecoder8, fieldName9, fieldDecoder9}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4,
fieldName5, fieldDecoder5,
fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7,
fieldName8, fieldDecoder8,
fieldName9, fieldDecoder9}
case 10:
var fieldName1 int32
var fieldName2 int32
var fieldName3 int32
var fieldName4 int32
var fieldName5 int32
var fieldName6 int32
var fieldName7 int32
var fieldName8 int32
var fieldName9 int32
var fieldName10 int32
var fieldName1 int64
var fieldName2 int64
var fieldName3 int64
var fieldName4 int64
var fieldName5 int64
var fieldName6 int64
var fieldName7 int64
var fieldName8 int64
var fieldName9 int64
var fieldName10 int64
var fieldDecoder1 *structFieldDecoder
var fieldDecoder2 *structFieldDecoder
var fieldDecoder3 *structFieldDecoder
@ -371,10 +437,10 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
var fieldDecoder9 *structFieldDecoder
var fieldDecoder10 *structFieldDecoder
for fieldName, fieldDecoder := range fields {
fieldHash := calcHash(fieldName)
fieldHash := calcHash(fieldName, ctx.caseSensitive())
_, known := knownHash[fieldHash]
if known {
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
knownHash[fieldHash] = struct{}{}
if fieldName1 == 0 {
@ -410,66 +476,80 @@ func createStructDecoder(typ reflect.Type, fields map[string]*structFieldDecoder
}
}
return &tenFieldsStructDecoder{typ,
fieldName1, fieldDecoder1, fieldName2, fieldDecoder2, fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4, fieldName5, fieldDecoder5, fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7, fieldName8, fieldDecoder8, fieldName9, fieldDecoder9,
fieldName10, fieldDecoder10}, nil
fieldName1, fieldDecoder1,
fieldName2, fieldDecoder2,
fieldName3, fieldDecoder3,
fieldName4, fieldDecoder4,
fieldName5, fieldDecoder5,
fieldName6, fieldDecoder6,
fieldName7, fieldDecoder7,
fieldName8, fieldDecoder8,
fieldName9, fieldDecoder9,
fieldName10, fieldDecoder10}
}
return &generalStructDecoder{typ, fields}, nil
return &generalStructDecoder{typ, fields, false}
}
type generalStructDecoder struct {
typ reflect.Type
fields map[string]*structFieldDecoder
typ reflect2.Type
fields map[string]*structFieldDecoder
disallowUnknownFields bool
}
func (decoder *generalStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
if !iter.readObjectStart() {
return
}
var fieldBytes []byte
var c byte
for c = ','; c == ','; c = iter.nextToken() {
decoder.decodeOneField(ptr, iter)
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
if c != '}' {
iter.ReportError("struct Decode", `expect }, but found `+string([]byte{c}))
}
}
func (decoder *generalStructDecoder) decodeOneField(ptr unsafe.Pointer, iter *Iterator) {
var field string
var fieldDecoder *structFieldDecoder
if iter.cfg.objectFieldMustBeSimpleString {
fieldBytes = iter.readObjectFieldAsBytes()
fieldBytes := iter.ReadStringAsSlice()
field = *(*string)(unsafe.Pointer(&fieldBytes))
fieldDecoder = decoder.fields[field]
if fieldDecoder == nil && !iter.cfg.caseSensitive {
fieldDecoder = decoder.fields[strings.ToLower(field)]
}
} else {
field = iter.ReadString()
fieldDecoder = decoder.fields[field]
if fieldDecoder == nil && !iter.cfg.caseSensitive {
fieldDecoder = decoder.fields[strings.ToLower(field)]
}
}
if fieldDecoder == nil {
msg := "found unknown field: " + field
if decoder.disallowUnknownFields {
iter.ReportError("ReadObject", msg)
}
c := iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
}
fieldDecoder := decoder.fields[strings.ToLower(field)]
if fieldDecoder == nil {
iter.Skip()
} else {
fieldDecoder.Decode(ptr, iter)
return
}
for iter.nextToken() == ',' {
if iter.cfg.objectFieldMustBeSimpleString {
fieldBytes := iter.readObjectFieldAsBytes()
field = *(*string)(unsafe.Pointer(&fieldBytes))
} else {
field = iter.ReadString()
c := iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
}
fieldDecoder = decoder.fields[strings.ToLower(field)]
if fieldDecoder == nil {
iter.Skip()
} else {
fieldDecoder.Decode(ptr, iter)
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
c := iter.nextToken()
if c != ':' {
iter.ReportError("ReadObject", "expect : after object field, but found "+string([]byte{c}))
}
fieldDecoder.Decode(ptr, iter)
}
type skipObjectDecoder struct {
typ reflect.Type
typ reflect2.Type
}
func (decoder *skipObjectDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
@ -482,8 +562,8 @@ func (decoder *skipObjectDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
}
type oneFieldStructDecoder struct {
typ reflect.Type
fieldHash int32
typ reflect2.Type
fieldHash int64
fieldDecoder *structFieldDecoder
}
@ -502,15 +582,15 @@ func (decoder *oneFieldStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterator)
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type twoFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
}
@ -532,17 +612,17 @@ func (decoder *twoFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterator
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type threeFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
}
@ -566,19 +646,19 @@ func (decoder *threeFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterat
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type fourFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
fieldHash4 int32
fieldHash4 int64
fieldDecoder4 *structFieldDecoder
}
@ -604,21 +684,21 @@ func (decoder *fourFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterato
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type fiveFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
fieldHash4 int32
fieldHash4 int64
fieldDecoder4 *structFieldDecoder
fieldHash5 int32
fieldHash5 int64
fieldDecoder5 *structFieldDecoder
}
@ -646,23 +726,23 @@ func (decoder *fiveFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterato
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type sixFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
fieldHash4 int32
fieldHash4 int64
fieldDecoder4 *structFieldDecoder
fieldHash5 int32
fieldHash5 int64
fieldDecoder5 *structFieldDecoder
fieldHash6 int32
fieldHash6 int64
fieldDecoder6 *structFieldDecoder
}
@ -692,25 +772,25 @@ func (decoder *sixFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterator
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type sevenFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
fieldHash4 int32
fieldHash4 int64
fieldDecoder4 *structFieldDecoder
fieldHash5 int32
fieldHash5 int64
fieldDecoder5 *structFieldDecoder
fieldHash6 int32
fieldHash6 int64
fieldDecoder6 *structFieldDecoder
fieldHash7 int32
fieldHash7 int64
fieldDecoder7 *structFieldDecoder
}
@ -742,27 +822,27 @@ func (decoder *sevenFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterat
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type eightFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
fieldHash4 int32
fieldHash4 int64
fieldDecoder4 *structFieldDecoder
fieldHash5 int32
fieldHash5 int64
fieldDecoder5 *structFieldDecoder
fieldHash6 int32
fieldHash6 int64
fieldDecoder6 *structFieldDecoder
fieldHash7 int32
fieldHash7 int64
fieldDecoder7 *structFieldDecoder
fieldHash8 int32
fieldHash8 int64
fieldDecoder8 *structFieldDecoder
}
@ -796,29 +876,29 @@ func (decoder *eightFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterat
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type nineFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
fieldHash4 int32
fieldHash4 int64
fieldDecoder4 *structFieldDecoder
fieldHash5 int32
fieldHash5 int64
fieldDecoder5 *structFieldDecoder
fieldHash6 int32
fieldHash6 int64
fieldDecoder6 *structFieldDecoder
fieldHash7 int32
fieldHash7 int64
fieldDecoder7 *structFieldDecoder
fieldHash8 int32
fieldHash8 int64
fieldDecoder8 *structFieldDecoder
fieldHash9 int32
fieldHash9 int64
fieldDecoder9 *structFieldDecoder
}
@ -854,31 +934,31 @@ func (decoder *nineFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterato
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type tenFieldsStructDecoder struct {
typ reflect.Type
fieldHash1 int32
typ reflect2.Type
fieldHash1 int64
fieldDecoder1 *structFieldDecoder
fieldHash2 int32
fieldHash2 int64
fieldDecoder2 *structFieldDecoder
fieldHash3 int32
fieldHash3 int64
fieldDecoder3 *structFieldDecoder
fieldHash4 int32
fieldHash4 int64
fieldDecoder4 *structFieldDecoder
fieldHash5 int32
fieldHash5 int64
fieldDecoder5 *structFieldDecoder
fieldHash6 int32
fieldHash6 int64
fieldDecoder6 *structFieldDecoder
fieldHash7 int32
fieldHash7 int64
fieldDecoder7 *structFieldDecoder
fieldHash8 int32
fieldHash8 int64
fieldDecoder8 *structFieldDecoder
fieldHash9 int32
fieldHash9 int64
fieldDecoder9 *structFieldDecoder
fieldHash10 int32
fieldHash10 int64
fieldDecoder10 *structFieldDecoder
}
@ -916,19 +996,53 @@ func (decoder *tenFieldsStructDecoder) Decode(ptr unsafe.Pointer, iter *Iterator
}
}
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%v: %s", decoder.typ, iter.Error.Error())
iter.Error = fmt.Errorf("%v.%s", decoder.typ, iter.Error.Error())
}
}
type structFieldDecoder struct {
field *reflect.StructField
field reflect2.StructField
fieldDecoder ValDecoder
}
func (decoder *structFieldDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
fieldPtr := unsafe.Pointer(uintptr(ptr) + decoder.field.Offset)
fieldPtr := decoder.field.UnsafeGet(ptr)
decoder.fieldDecoder.Decode(fieldPtr, iter)
if iter.Error != nil && iter.Error != io.EOF {
iter.Error = fmt.Errorf("%s: %s", decoder.field.Name, iter.Error.Error())
iter.Error = fmt.Errorf("%s: %s", decoder.field.Name(), iter.Error.Error())
}
}
type stringModeStringDecoder struct {
elemDecoder ValDecoder
cfg *frozenConfig
}
func (decoder *stringModeStringDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
decoder.elemDecoder.Decode(ptr, iter)
str := *((*string)(ptr))
tempIter := decoder.cfg.BorrowIterator([]byte(str))
defer decoder.cfg.ReturnIterator(tempIter)
*((*string)(ptr)) = tempIter.ReadString()
}
type stringModeNumberDecoder struct {
elemDecoder ValDecoder
}
func (decoder *stringModeNumberDecoder) Decode(ptr unsafe.Pointer, iter *Iterator) {
c := iter.nextToken()
if c != '"' {
iter.ReportError("stringModeNumberDecoder", `expect ", but found `+string([]byte{c}))
return
}
decoder.elemDecoder.Decode(ptr, iter)
if iter.Error != nil {
return
}
c = iter.readByte()
if c != '"' {
iter.ReportError("stringModeNumberDecoder", `expect ", but found `+string([]byte{c}))
return
}
}

158
vendor/github.com/json-iterator/go/feature_reflect_object.go → vendor/github.com/json-iterator/go/reflect_struct_encoder.go сгенерированный поставляемый
Просмотреть файл

@ -2,23 +2,20 @@ package jsoniter
import (
"fmt"
"github.com/modern-go/reflect2"
"io"
"reflect"
"strings"
"unsafe"
)
func encoderOfStruct(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
func encoderOfStruct(ctx *ctx, typ reflect2.Type) ValEncoder {
type bindingTo struct {
binding *Binding
toName string
ignored bool
}
orderedBindings := []*bindingTo{}
structDescriptor, err := describeStruct(cfg, typ)
if err != nil {
return nil, err
}
structDescriptor := describeStruct(ctx, typ)
for _, binding := range structDescriptor.Fields {
for _, toName := range binding.ToNames {
new := &bindingTo{
@ -29,13 +26,13 @@ func encoderOfStruct(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
if old.toName != toName {
continue
}
old.ignored, new.ignored = resolveConflictBinding(cfg, old.binding, new.binding)
old.ignored, new.ignored = resolveConflictBinding(ctx.frozenConfig, old.binding, new.binding)
}
orderedBindings = append(orderedBindings, new)
}
}
if len(orderedBindings) == 0 {
return &emptyStructEncoder{}, nil
return &emptyStructEncoder{}
}
finalOrderedFields := []structFieldTo{}
for _, bindingTo := range orderedBindings {
@ -46,12 +43,36 @@ func encoderOfStruct(cfg *frozenConfig, typ reflect.Type) (ValEncoder, error) {
})
}
}
return &structEncoder{structDescriptor.onePtrEmbedded, structDescriptor.onePtrOptimization, finalOrderedFields}, nil
return &structEncoder{typ, finalOrderedFields}
}
func createCheckIsEmpty(ctx *ctx, typ reflect2.Type) checkIsEmpty {
encoder := createEncoderOfNative(ctx, typ)
if encoder != nil {
return encoder
}
kind := typ.Kind()
switch kind {
case reflect.Interface:
return &dynamicEncoder{typ}
case reflect.Struct:
return &structEncoder{typ: typ}
case reflect.Array:
return &arrayEncoder{}
case reflect.Slice:
return &sliceEncoder{}
case reflect.Map:
return encoderOfMap(ctx, typ)
case reflect.Ptr:
return &OptionalEncoder{}
default:
return &lazyErrorEncoder{err: fmt.Errorf("unsupported type: %v", typ)}
}
}
func resolveConflictBinding(cfg *frozenConfig, old, new *Binding) (ignoreOld, ignoreNew bool) {
newTagged := new.Field.Tag.Get(cfg.getTagKey()) != ""
oldTagged := old.Field.Tag.Get(cfg.getTagKey()) != ""
newTagged := new.Field.Tag().Get(cfg.getTagKey()) != ""
oldTagged := old.Field.Tag().Get(cfg.getTagKey()) != ""
if newTagged {
if oldTagged {
if len(old.levels) > len(new.levels) {
@ -78,62 +99,41 @@ func resolveConflictBinding(cfg *frozenConfig, old, new *Binding) (ignoreOld, ig
}
}
func decoderOfStruct(cfg *frozenConfig, typ reflect.Type) (ValDecoder, error) {
bindings := map[string]*Binding{}
structDescriptor, err := describeStruct(cfg, typ)
if err != nil {
return nil, err
}
for _, binding := range structDescriptor.Fields {
for _, fromName := range binding.FromNames {
old := bindings[fromName]
if old == nil {
bindings[fromName] = binding
continue
}
ignoreOld, ignoreNew := resolveConflictBinding(cfg, old, binding)
if ignoreOld {
delete(bindings, fromName)
}
if !ignoreNew {
bindings[fromName] = binding
}
}
}
fields := map[string]*structFieldDecoder{}
for k, binding := range bindings {
fields[strings.ToLower(k)] = binding.Decoder.(*structFieldDecoder)
}
return createStructDecoder(typ, fields)
}
type structFieldEncoder struct {
field *reflect.StructField
field reflect2.StructField
fieldEncoder ValEncoder
omitempty bool
}
func (encoder *structFieldEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
fieldPtr := unsafe.Pointer(uintptr(ptr) + encoder.field.Offset)
fieldPtr := encoder.field.UnsafeGet(ptr)
encoder.fieldEncoder.Encode(fieldPtr, stream)
if stream.Error != nil && stream.Error != io.EOF {
stream.Error = fmt.Errorf("%s: %s", encoder.field.Name, stream.Error.Error())
stream.Error = fmt.Errorf("%s: %s", encoder.field.Name(), stream.Error.Error())
}
}
func (encoder *structFieldEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *structFieldEncoder) IsEmpty(ptr unsafe.Pointer) bool {
fieldPtr := unsafe.Pointer(uintptr(ptr) + encoder.field.Offset)
fieldPtr := encoder.field.UnsafeGet(ptr)
return encoder.fieldEncoder.IsEmpty(fieldPtr)
}
func (encoder *structFieldEncoder) IsEmbeddedPtrNil(ptr unsafe.Pointer) bool {
isEmbeddedPtrNil, converted := encoder.fieldEncoder.(IsEmbeddedPtrNil)
if !converted {
return false
}
fieldPtr := encoder.field.UnsafeGet(ptr)
return isEmbeddedPtrNil.IsEmbeddedPtrNil(fieldPtr)
}
type IsEmbeddedPtrNil interface {
IsEmbeddedPtrNil(ptr unsafe.Pointer) bool
}
type structEncoder struct {
onePtrEmbedded bool
onePtrOptimization bool
fields []structFieldTo
typ reflect2.Type
fields []structFieldTo
}
type structFieldTo struct {
@ -148,6 +148,9 @@ func (encoder *structEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
if field.encoder.omitempty && field.encoder.IsEmpty(ptr) {
continue
}
if field.encoder.IsEmbeddedPtrNil(ptr) {
continue
}
if isNotFirst {
stream.WriteMore()
}
@ -156,23 +159,8 @@ func (encoder *structEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
isNotFirst = true
}
stream.WriteObjectEnd()
}
func (encoder *structEncoder) EncodeInterface(val interface{}, stream *Stream) {
e := (*emptyInterface)(unsafe.Pointer(&val))
if encoder.onePtrOptimization {
if e.word == nil && encoder.onePtrEmbedded {
stream.WriteObjectStart()
stream.WriteObjectEnd()
return
}
ptr := uintptr(e.word)
e.word = unsafe.Pointer(&ptr)
}
if reflect.TypeOf(val).Kind() == reflect.Ptr {
encoder.Encode(unsafe.Pointer(&e.word), stream)
} else {
encoder.Encode(e.word, stream)
if stream.Error != nil && stream.Error != io.EOF {
stream.Error = fmt.Errorf("%v.%s", encoder.typ, stream.Error.Error())
}
}
@ -187,10 +175,36 @@ func (encoder *emptyStructEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.WriteEmptyObject()
}
func (encoder *emptyStructEncoder) EncodeInterface(val interface{}, stream *Stream) {
WriteToStream(val, stream, encoder)
}
func (encoder *emptyStructEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return false
}
type stringModeNumberEncoder struct {
elemEncoder ValEncoder
}
func (encoder *stringModeNumberEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
stream.writeByte('"')
encoder.elemEncoder.Encode(ptr, stream)
stream.writeByte('"')
}
func (encoder *stringModeNumberEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.elemEncoder.IsEmpty(ptr)
}
type stringModeStringEncoder struct {
elemEncoder ValEncoder
cfg *frozenConfig
}
func (encoder *stringModeStringEncoder) Encode(ptr unsafe.Pointer, stream *Stream) {
tempStream := encoder.cfg.BorrowStream(nil)
defer encoder.cfg.ReturnStream(tempStream)
encoder.elemEncoder.Encode(ptr, tempStream)
stream.WriteString(string(tempStream.Buffer()))
}
func (encoder *stringModeStringEncoder) IsEmpty(ptr unsafe.Pointer) bool {
return encoder.elemEncoder.IsEmpty(ptr)
}

155
vendor/github.com/json-iterator/go/feature_stream.go → vendor/github.com/json-iterator/go/stream.go сгенерированный поставляемый
Просмотреть файл

@ -10,7 +10,6 @@ type Stream struct {
cfg *frozenConfig
out io.Writer
buf []byte
n int
Error error
indention int
Attachment interface{} // open for customized encoder
@ -24,8 +23,7 @@ func NewStream(cfg API, out io.Writer, bufSize int) *Stream {
return &Stream{
cfg: cfg.(*frozenConfig),
out: out,
buf: make([]byte, bufSize),
n: 0,
buf: make([]byte, 0, bufSize),
Error: nil,
indention: 0,
}
@ -39,22 +37,27 @@ func (stream *Stream) Pool() StreamPool {
// Reset reuse this stream instance by assign a new writer
func (stream *Stream) Reset(out io.Writer) {
stream.out = out
stream.n = 0
stream.buf = stream.buf[:0]
}
// Available returns how many bytes are unused in the buffer.
func (stream *Stream) Available() int {
return len(stream.buf) - stream.n
return cap(stream.buf) - len(stream.buf)
}
// Buffered returns the number of bytes that have been written into the current buffer.
func (stream *Stream) Buffered() int {
return stream.n
return len(stream.buf)
}
// Buffer if writer is nil, use this method to take the result
func (stream *Stream) Buffer() []byte {
return stream.buf[:stream.n]
return stream.buf
}
// SetBuffer allows to append to the internal buffer directly
func (stream *Stream) SetBuffer(buf []byte) {
stream.buf = buf
}
// Write writes the contents of p into the buffer.
@ -62,97 +65,34 @@ func (stream *Stream) Buffer() []byte {
// If nn < len(p), it also returns an error explaining
// why the write is short.
func (stream *Stream) Write(p []byte) (nn int, err error) {
for len(p) > stream.Available() && stream.Error == nil {
if stream.out == nil {
stream.growAtLeast(len(p))
} else {
var n int
if stream.Buffered() == 0 {
// Large write, empty buffer.
// Write directly from p to avoid copy.
n, stream.Error = stream.out.Write(p)
} else {
n = copy(stream.buf[stream.n:], p)
stream.n += n
stream.Flush()
}
nn += n
p = p[n:]
}
stream.buf = append(stream.buf, p...)
if stream.out != nil {
nn, err = stream.out.Write(stream.buf)
stream.buf = stream.buf[nn:]
return
}
if stream.Error != nil {
return nn, stream.Error
}
n := copy(stream.buf[stream.n:], p)
stream.n += n
nn += n
return nn, nil
return len(p), nil
}
// WriteByte writes a single byte.
func (stream *Stream) writeByte(c byte) {
if stream.Error != nil {
return
}
if stream.Available() < 1 {
stream.growAtLeast(1)
}
stream.buf[stream.n] = c
stream.n++
stream.buf = append(stream.buf, c)
}
func (stream *Stream) writeTwoBytes(c1 byte, c2 byte) {
if stream.Error != nil {
return
}
if stream.Available() < 2 {
stream.growAtLeast(2)
}
stream.buf[stream.n] = c1
stream.buf[stream.n+1] = c2
stream.n += 2
stream.buf = append(stream.buf, c1, c2)
}
func (stream *Stream) writeThreeBytes(c1 byte, c2 byte, c3 byte) {
if stream.Error != nil {
return
}
if stream.Available() < 3 {
stream.growAtLeast(3)
}
stream.buf[stream.n] = c1
stream.buf[stream.n+1] = c2
stream.buf[stream.n+2] = c3
stream.n += 3
stream.buf = append(stream.buf, c1, c2, c3)
}
func (stream *Stream) writeFourBytes(c1 byte, c2 byte, c3 byte, c4 byte) {
if stream.Error != nil {
return
}
if stream.Available() < 4 {
stream.growAtLeast(4)
}
stream.buf[stream.n] = c1
stream.buf[stream.n+1] = c2
stream.buf[stream.n+2] = c3
stream.buf[stream.n+3] = c4
stream.n += 4
stream.buf = append(stream.buf, c1, c2, c3, c4)
}
func (stream *Stream) writeFiveBytes(c1 byte, c2 byte, c3 byte, c4 byte, c5 byte) {
if stream.Error != nil {
return
}
if stream.Available() < 5 {
stream.growAtLeast(5)
}
stream.buf[stream.n] = c1
stream.buf[stream.n+1] = c2
stream.buf[stream.n+2] = c3
stream.buf[stream.n+3] = c4
stream.buf[stream.n+4] = c5
stream.n += 5
stream.buf = append(stream.buf, c1, c2, c3, c4, c5)
}
// Flush writes any buffered data to the underlying io.Writer.
@ -163,56 +103,20 @@ func (stream *Stream) Flush() error {
if stream.Error != nil {
return stream.Error
}
if stream.n == 0 {
return nil
}
n, err := stream.out.Write(stream.buf[0:stream.n])
if n < stream.n && err == nil {
err = io.ErrShortWrite
}
n, err := stream.out.Write(stream.buf)
if err != nil {
if n > 0 && n < stream.n {
copy(stream.buf[0:stream.n-n], stream.buf[n:stream.n])
if stream.Error == nil {
stream.Error = err
}
stream.n -= n
stream.Error = err
return err
}
stream.n = 0
stream.buf = stream.buf[n:]
return nil
}
func (stream *Stream) ensure(minimal int) {
available := stream.Available()
if available < minimal {
stream.growAtLeast(minimal)
}
}
func (stream *Stream) growAtLeast(minimal int) {
if stream.out != nil {
stream.Flush()
if stream.Available() >= minimal {
return
}
}
toGrow := len(stream.buf)
if toGrow < minimal {
toGrow = minimal
}
newBuf := make([]byte, len(stream.buf)+toGrow)
copy(newBuf, stream.Buffer())
stream.buf = newBuf
}
// WriteRaw write string out without quotes, just like []byte
func (stream *Stream) WriteRaw(s string) {
stream.ensure(len(s))
if stream.Error != nil {
return
}
n := copy(stream.buf[stream.n:], s)
stream.n += n
stream.buf = append(stream.buf, s...)
}
// WriteNil write null to stream
@ -273,6 +177,7 @@ func (stream *Stream) WriteEmptyObject() {
func (stream *Stream) WriteMore() {
stream.writeByte(',')
stream.writeIndention(0)
stream.Flush()
}
// WriteArrayStart write [ with possible indention
@ -300,9 +205,7 @@ func (stream *Stream) writeIndention(delta int) {
}
stream.writeByte('\n')
toWrite := stream.indention - delta
stream.ensure(toWrite)
for i := 0; i < toWrite && stream.n < len(stream.buf); i++ {
stream.buf[stream.n] = ' '
stream.n++
for i := 0; i < toWrite; i++ {
stream.buf = append(stream.buf, ' ')
}
}

14
vendor/github.com/json-iterator/go/feature_stream_float.go → vendor/github.com/json-iterator/go/stream_float.go сгенерированный поставляемый
Просмотреть файл

@ -21,7 +21,7 @@ func (stream *Stream) WriteFloat32(val float32) {
fmt = 'e'
}
}
stream.WriteRaw(strconv.FormatFloat(float64(val), fmt, -1, 32))
stream.buf = strconv.AppendFloat(stream.buf, float64(val), fmt, -1, 32)
}
// WriteFloat32Lossy write float32 to stream with ONLY 6 digits precision although much much faster
@ -43,13 +43,12 @@ func (stream *Stream) WriteFloat32Lossy(val float32) {
return
}
stream.writeByte('.')
stream.ensure(10)
for p := precision - 1; p > 0 && fval < pow10[p]; p-- {
stream.writeByte('0')
}
stream.WriteUint64(fval)
for stream.buf[stream.n-1] == '0' {
stream.n--
for stream.buf[len(stream.buf)-1] == '0' {
stream.buf = stream.buf[:len(stream.buf)-1]
}
}
@ -63,7 +62,7 @@ func (stream *Stream) WriteFloat64(val float64) {
fmt = 'e'
}
}
stream.WriteRaw(strconv.FormatFloat(float64(val), fmt, -1, 64))
stream.buf = strconv.AppendFloat(stream.buf, float64(val), fmt, -1, 64)
}
// WriteFloat64Lossy write float64 to stream with ONLY 6 digits precision although much much faster
@ -85,12 +84,11 @@ func (stream *Stream) WriteFloat64Lossy(val float64) {
return
}
stream.writeByte('.')
stream.ensure(10)
for p := precision - 1; p > 0 && fval < pow10[p]; p-- {
stream.writeByte('0')
}
stream.WriteUint64(fval)
for stream.buf[stream.n-1] == '0' {
stream.n--
for stream.buf[len(stream.buf)-1] == '0' {
stream.buf = stream.buf[:len(stream.buf)-1]
}
}

190
vendor/github.com/json-iterator/go/stream_int.go сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,190 @@
package jsoniter
var digits []uint32
func init() {
digits = make([]uint32, 1000)
for i := uint32(0); i < 1000; i++ {
digits[i] = (((i / 100) + '0') << 16) + ((((i / 10) % 10) + '0') << 8) + i%10 + '0'
if i < 10 {
digits[i] += 2 << 24
} else if i < 100 {
digits[i] += 1 << 24
}
}
}
func writeFirstBuf(space []byte, v uint32) []byte {
start := v >> 24
if start == 0 {
space = append(space, byte(v>>16), byte(v>>8))
} else if start == 1 {
space = append(space, byte(v>>8))
}
space = append(space, byte(v))
return space
}
func writeBuf(buf []byte, v uint32) []byte {
return append(buf, byte(v>>16), byte(v>>8), byte(v))
}
// WriteUint8 write uint8 to stream
func (stream *Stream) WriteUint8(val uint8) {
stream.buf = writeFirstBuf(stream.buf, digits[val])
}
// WriteInt8 write int8 to stream
func (stream *Stream) WriteInt8(nval int8) {
var val uint8
if nval < 0 {
val = uint8(-nval)
stream.buf = append(stream.buf, '-')
} else {
val = uint8(nval)
}
stream.buf = writeFirstBuf(stream.buf, digits[val])
}
// WriteUint16 write uint16 to stream
func (stream *Stream) WriteUint16(val uint16) {
q1 := val / 1000
if q1 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[val])
return
}
r1 := val - q1*1000
stream.buf = writeFirstBuf(stream.buf, digits[q1])
stream.buf = writeBuf(stream.buf, digits[r1])
return
}
// WriteInt16 write int16 to stream
func (stream *Stream) WriteInt16(nval int16) {
var val uint16
if nval < 0 {
val = uint16(-nval)
stream.buf = append(stream.buf, '-')
} else {
val = uint16(nval)
}
stream.WriteUint16(val)
}
// WriteUint32 write uint32 to stream
func (stream *Stream) WriteUint32(val uint32) {
q1 := val / 1000
if q1 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[val])
return
}
r1 := val - q1*1000
q2 := q1 / 1000
if q2 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[q1])
stream.buf = writeBuf(stream.buf, digits[r1])
return
}
r2 := q1 - q2*1000
q3 := q2 / 1000
if q3 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[q2])
} else {
r3 := q2 - q3*1000
stream.buf = append(stream.buf, byte(q3+'0'))
stream.buf = writeBuf(stream.buf, digits[r3])
}
stream.buf = writeBuf(stream.buf, digits[r2])
stream.buf = writeBuf(stream.buf, digits[r1])
}
// WriteInt32 write int32 to stream
func (stream *Stream) WriteInt32(nval int32) {
var val uint32
if nval < 0 {
val = uint32(-nval)
stream.buf = append(stream.buf, '-')
} else {
val = uint32(nval)
}
stream.WriteUint32(val)
}
// WriteUint64 write uint64 to stream
func (stream *Stream) WriteUint64(val uint64) {
q1 := val / 1000
if q1 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[val])
return
}
r1 := val - q1*1000
q2 := q1 / 1000
if q2 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[q1])
stream.buf = writeBuf(stream.buf, digits[r1])
return
}
r2 := q1 - q2*1000
q3 := q2 / 1000
if q3 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[q2])
stream.buf = writeBuf(stream.buf, digits[r2])
stream.buf = writeBuf(stream.buf, digits[r1])
return
}
r3 := q2 - q3*1000
q4 := q3 / 1000
if q4 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[q3])
stream.buf = writeBuf(stream.buf, digits[r3])
stream.buf = writeBuf(stream.buf, digits[r2])
stream.buf = writeBuf(stream.buf, digits[r1])
return
}
r4 := q3 - q4*1000
q5 := q4 / 1000
if q5 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[q4])
stream.buf = writeBuf(stream.buf, digits[r4])
stream.buf = writeBuf(stream.buf, digits[r3])
stream.buf = writeBuf(stream.buf, digits[r2])
stream.buf = writeBuf(stream.buf, digits[r1])
return
}
r5 := q4 - q5*1000
q6 := q5 / 1000
if q6 == 0 {
stream.buf = writeFirstBuf(stream.buf, digits[q5])
} else {
stream.buf = writeFirstBuf(stream.buf, digits[q6])
r6 := q5 - q6*1000
stream.buf = writeBuf(stream.buf, digits[r6])
}
stream.buf = writeBuf(stream.buf, digits[r5])
stream.buf = writeBuf(stream.buf, digits[r4])
stream.buf = writeBuf(stream.buf, digits[r3])
stream.buf = writeBuf(stream.buf, digits[r2])
stream.buf = writeBuf(stream.buf, digits[r1])
}
// WriteInt64 write int64 to stream
func (stream *Stream) WriteInt64(nval int64) {
var val uint64
if nval < 0 {
val = uint64(-nval)
stream.buf = append(stream.buf, '-')
} else {
val = uint64(nval)
}
stream.WriteUint64(val)
}
// WriteInt write int to stream
func (stream *Stream) WriteInt(val int) {
stream.WriteInt64(int64(val))
}
// WriteUint write uint to stream
func (stream *Stream) WriteUint(val uint) {
stream.WriteUint64(uint64(val))
}

40
vendor/github.com/json-iterator/go/feature_stream_string.go → vendor/github.com/json-iterator/go/stream_str.go сгенерированный поставляемый
Просмотреть файл

@ -219,34 +219,22 @@ var hex = "0123456789abcdef"
// WriteStringWithHTMLEscaped write string to stream with html special characters escaped
func (stream *Stream) WriteStringWithHTMLEscaped(s string) {
stream.ensure(32)
valLen := len(s)
toWriteLen := valLen
bufLengthMinusTwo := len(stream.buf) - 2 // make room for the quotes
if stream.n+toWriteLen > bufLengthMinusTwo {
toWriteLen = bufLengthMinusTwo - stream.n
}
n := stream.n
stream.buf[n] = '"'
n++
stream.buf = append(stream.buf, '"')
// write string, the fast path, without utf8 and escape support
i := 0
for ; i < toWriteLen; i++ {
for ; i < valLen; i++ {
c := s[i]
if c < utf8.RuneSelf && htmlSafeSet[c] {
stream.buf[n] = c
n++
stream.buf = append(stream.buf, c)
} else {
break
}
}
if i == valLen {
stream.buf[n] = '"'
n++
stream.n = n
stream.buf = append(stream.buf, '"')
return
}
stream.n = n
writeStringSlowPathWithHTMLEscaped(stream, i, s, valLen)
}
@ -321,34 +309,22 @@ func writeStringSlowPathWithHTMLEscaped(stream *Stream, i int, s string, valLen
// WriteString write string to stream without html escape
func (stream *Stream) WriteString(s string) {
stream.ensure(32)
valLen := len(s)
toWriteLen := valLen
bufLengthMinusTwo := len(stream.buf) - 2 // make room for the quotes
if stream.n+toWriteLen > bufLengthMinusTwo {
toWriteLen = bufLengthMinusTwo - stream.n
}
n := stream.n
stream.buf[n] = '"'
n++
stream.buf = append(stream.buf, '"')
// write string, the fast path, without utf8 and escape support
i := 0
for ; i < toWriteLen; i++ {
for ; i < valLen; i++ {
c := s[i]
if c > 31 && c != '"' && c != '\\' {
stream.buf[n] = c
n++
stream.buf = append(stream.buf, c)
} else {
break
}
}
if i == valLen {
stream.buf[n] = '"'
n++
stream.n = n
stream.buf = append(stream.buf, '"')
return
}
stream.n = n
writeStringSlowPath(stream, i, s, valLen)
}

2
vendor/github.com/json-iterator/go/test.sh сгенерированный поставляемый
Просмотреть файл

@ -4,7 +4,7 @@ set -e
echo "" > coverage.txt
for d in $(go list ./... | grep -v vendor); do
go test -coverprofile=profile.out $d
go test -coverprofile=profile.out -coverpkg=github.com/json-iterator/go $d
if [ -f profile.out ]; then
cat profile.out >> coverage.txt
rm profile.out

1
vendor/github.com/modern-go/concurrent/.gitignore сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1 @@
/coverage.txt

14
vendor/github.com/modern-go/concurrent/.travis.yml сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,14 @@
language: go
go:
- 1.8.x
- 1.x
before_install:
- go get -t -v ./...
script:
- ./test.sh
after_success:
- bash <(curl -s https://codecov.io/bash)

201
vendor/github.com/modern-go/concurrent/LICENSE сгенерированный поставляемый Normal file
Просмотреть файл

@ -0,0 +1,201 @@
Apache License
Version 2.0, January 2004
http://www.apache.org/licenses/
TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION
1. Definitions.
"License" shall mean the terms and conditions for use, reproduction,
and distribution as defined by Sections 1 through 9 of this document.
"Licensor" shall mean the copyright owner or entity authorized by
the copyright owner that is granting the License.
"Legal Entity" shall mean the union of the acting entity and all
other entities that control, are controlled by, or are under common
control with that entity. For the purposes of this definition,
"control" means (i) the power, direct or indirect, to cause the
direction or management of such entity, whether by contract or
otherwise, or (ii) ownership of fifty percent (50%) or more of the
outstanding shares, or (iii) beneficial ownership of such entity.
"You" (or "Your") shall mean an individual or Legal Entity
exercising permissions granted by this License.
"Source" form shall mean the preferred form for making modifications,
including but not limited to software source code, documentation
source, and configuration files.
"Object" form shall mean any form resulting from mechanical
transformation or translation of a Source form, including but
not limited to compiled object code, generated documentation,
and conversions to other media types.
"Work" shall mean the work of authorship, whether in Source or
Object form, made available under the License, as indicated by a
copyright notice that is included in or attached to the work
(an example is provided in the Appendix below).
"Derivative Works" shall mean any work, whether in Source or Object
form, that is based on (or derived from) the Work and for which the
editorial revisions, annotations, elaborations, or other modifications
represent, as a whole, an original work of authorship. For the purposes
of this License, Derivative Works shall not include works that remain
separable from, or merely link (or bind by name) to the interfaces of,
the Work and Derivative Works thereof.
"Contribution" shall mean any work of authorship, including
the original version of the Work and any modifications or additions
to that Work or Derivative Works thereof, that is intentionally
submitted to Licensor for inclusion in the Work by the copyright owner
or by an individual or Legal Entity authorized to submit on behalf of
the copyright owner. For the purposes of this definition, "submitted"
means any form of electronic, verbal, or written communication sent
to the Licensor or its representatives, including but not limited to
communication on electronic mailing lists, source code control systems,
and issue tracking systems that are managed by, or on behalf of, the
Licensor for the purpose of discussing and improving the Work, but
excluding communication that is conspicuously marked or otherwise
designated in writing by the copyright owner as "Not a Contribution."
"Contributor" shall mean Licensor and any individual or Legal Entity
on behalf of whom a Contribution has been received by Licensor and
subsequently incorporated within the Work.
2. Grant of Copyright License. Subject to the terms and conditions of
this License, each Contributor hereby grants to You a perpetual,
worldwide, non-exclusive, no-charge, royalty-free, irrevocable
copyright license to reproduce, prepare Derivative Works of,
publicly display, publicly perform, sublicense, and distribute the
Work and such Derivative Works in Source or Object form.
3. Grant of Patent License. Subject to the terms and conditions of
this License, each Contributor hereby grants to You a perpetual,
worldwide, non-exclusive, no-charge, royalty-free, irrevocable
(except as stated in this section) patent license to make, have made,
use, offer to sell, sell, import, and otherwise transfer the Work,
where such license applies only to those patent claims licensable
by such Contributor that are necessarily infringed by their
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as of the date such litigation is filed.
4. Redistribution. You may reproduce and distribute copies of the
Work or Derivative Works thereof in any medium, with or without
modifications, and in Source or Object form, provided that You
meet the following conditions:
(a) You must give any other recipients of the Work or
Derivative Works a copy of this License; and
(b) You must cause any modified files to carry prominent notices
stating that You changed the files; and
(c) You must retain, in the Source form of any Derivative Works
that You distribute, all copyright, patent, trademark, and
attribution notices from the Source form of the Work,
excluding those notices that do not pertain to any part of
the Derivative Works; and
(d) If the Work includes a "NOTICE" text file as part of its
distribution, then any Derivative Works that You distribute must
include a readable copy of the attribution notices contained
within such NOTICE file, excluding those notices that do not
pertain to any part of the Derivative Works, in at least one
of the following places: within a NOTICE text file distributed
as part of the Derivative Works; within the Source form or
documentation, if provided along with the Derivative Works; or,
within a display generated by the Derivative Works, if and
wherever such third-party notices normally appear. The contents
of the NOTICE file are for informational purposes only and
do not modify the License. You may add Your own attribution
notices within Derivative Works that You distribute, alongside
or as an addendum to the NOTICE text from the Work, provided
that such additional attribution notices cannot be construed
as modifying the License.
You may add Your own copyright statement to Your modifications and
may provide additional or different license terms and conditions
for use, reproduction, or distribution of Your modifications, or
for any such Derivative Works as a whole, provided Your use,
reproduction, and distribution of the Work otherwise complies with
the conditions stated in this License.
5. Submission of Contributions. Unless You explicitly state otherwise,
any Contribution intentionally submitted for inclusion in the Work
by You to the Licensor shall be under the terms and conditions of
this License, without any additional terms or conditions.
Notwithstanding the above, nothing herein shall supersede or modify
the terms of any separate license agreement you may have executed
with Licensor regarding such Contributions.
6. Trademarks. This License does not grant permission to use the trade
names, trademarks, service marks, or product names of the Licensor,
except as required for reasonable and customary use in describing the
origin of the Work and reproducing the content of the NOTICE file.
7. Disclaimer of Warranty. Unless required by applicable law or
agreed to in writing, Licensor provides the Work (and each
Contributor provides its Contributions) on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
implied, including, without limitation, any warranties or conditions
of TITLE, NON-INFRINGEMENT, MERCHANTABILITY, or FITNESS FOR A
PARTICULAR PURPOSE. You are solely responsible for determining the
appropriateness of using or redistributing the Work and assume any
risks associated with Your exercise of permissions under this License.
8. Limitation of Liability. In no event and under no legal theory,
whether in tort (including negligence), contract, or otherwise,
unless required by applicable law (such as deliberate and grossly
negligent acts) or agreed to in writing, shall any Contributor be
liable to You for damages, including any direct, indirect, special,
incidental, or consequential damages of any character arising as a
result of this License or out of the use or inability to use the
Work (including but not limited to damages for loss of goodwill,
work stoppage, computer failure or malfunction, or any and all
other commercial damages or losses), even if such Contributor
has been advised of the possibility of such damages.
9. Accepting Warranty or Additional Liability. While redistributing
the Work or Derivative Works thereof, You may choose to offer,
and charge a fee for, acceptance of support, warranty, indemnity,
or other liability obligations and/or rights consistent with this
License. However, in accepting such obligations, You may act only
on Your own behalf and on Your sole responsibility, not on behalf
of any other Contributor, and only if You agree to indemnify,
defend, and hold each Contributor harmless for any liability
incurred by, or claims asserted against, such Contributor by reason
of your accepting any such warranty or additional liability.
END OF TERMS AND CONDITIONS
APPENDIX: How to apply the Apache License to your work.
To apply the Apache License to your work, attach the following
boilerplate notice, with the fields enclosed by brackets "[]"
replaced with your own identifying information. (Don't include
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same "printed page" as the copyright notice for easier
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Copyright [yyyy] [name of copyright owner]
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
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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.

49
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# concurrent
[![Sourcegraph](https://sourcegraph.com/github.com/modern-go/concurrent/-/badge.svg)](https://sourcegraph.com/github.com/modern-go/concurrent?badge)
[![GoDoc](http://img.shields.io/badge/go-documentation-blue.svg?style=flat-square)](http://godoc.org/github.com/modern-go/concurrent)
[![Build Status](https://travis-ci.org/modern-go/concurrent.svg?branch=master)](https://travis-ci.org/modern-go/concurrent)
[![codecov](https://codecov.io/gh/modern-go/concurrent/branch/master/graph/badge.svg)](https://codecov.io/gh/modern-go/concurrent)
[![rcard](https://goreportcard.com/badge/github.com/modern-go/concurrent)](https://goreportcard.com/report/github.com/modern-go/concurrent)
[![License](https://img.shields.io/badge/License-Apache%202.0-blue.svg)](https://raw.githubusercontent.com/modern-go/concurrent/master/LICENSE)
* concurrent.Map: backport sync.Map for go below 1.9
* concurrent.Executor: goroutine with explicit ownership and cancellable
# concurrent.Map
because sync.Map is only available in go 1.9, we can use concurrent.Map to make code portable
```go
m := concurrent.NewMap()
m.Store("hello", "world")
elem, found := m.Load("hello")
// elem will be "world"
// found will be true
```
# concurrent.Executor
```go
executor := concurrent.NewUnboundedExecutor()
executor.Go(func(ctx context.Context) {
everyMillisecond := time.NewTicker(time.Millisecond)
for {
select {
case <-ctx.Done():
fmt.Println("goroutine exited")
return
case <-everyMillisecond.C:
// do something
}
}
})
time.Sleep(time.Second)
executor.StopAndWaitForever()
fmt.Println("executor stopped")
```
attach goroutine to executor instance, so that we can
* cancel it by stop the executor with Stop/StopAndWait/StopAndWaitForever
* handle panic by callback: the default behavior will no longer crash your application

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package concurrent
import "context"
// Executor replace go keyword to start a new goroutine
// the goroutine should cancel itself if the context passed in has been cancelled
// the goroutine started by the executor, is owned by the executor
// we can cancel all executors owned by the executor just by stop the executor itself
// however Executor interface does not Stop method, the one starting and owning executor
// should use the concrete type of executor, instead of this interface.
type Executor interface {
// Go starts a new goroutine controlled by the context
Go(handler func(ctx context.Context))
}

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//+build go1.9
package concurrent
import "sync"
// Map is a wrapper for sync.Map introduced in go1.9
type Map struct {
sync.Map
}
// NewMap creates a thread safe Map
func NewMap() *Map {
return &Map{}
}

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//+build !go1.9
package concurrent
import "sync"
// Map implements a thread safe map for go version below 1.9 using mutex
type Map struct {
lock sync.RWMutex
data map[interface{}]interface{}
}
// NewMap creates a thread safe map
func NewMap() *Map {
return &Map{
data: make(map[interface{}]interface{}, 32),
}
}
// Load is same as sync.Map Load
func (m *Map) Load(key interface{}) (elem interface{}, found bool) {
m.lock.RLock()
elem, found = m.data[key]
m.lock.RUnlock()
return
}
// Load is same as sync.Map Store
func (m *Map) Store(key interface{}, elem interface{}) {
m.lock.Lock()
m.data[key] = elem
m.lock.Unlock()
}

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package concurrent
import (
"os"
"log"
"io/ioutil"
)
// ErrorLogger is used to print out error, can be set to writer other than stderr
var ErrorLogger = log.New(os.Stderr, "", 0)
// InfoLogger is used to print informational message, default to off
var InfoLogger = log.New(ioutil.Discard, "", 0)

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vendor/github.com/modern-go/concurrent/test.sh сгенерированный поставляемый Executable file
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#!/usr/bin/env bash
set -e
echo "" > coverage.txt
for d in $(go list ./... | grep -v vendor); do
go test -coverprofile=profile.out -coverpkg=github.com/modern-go/concurrent $d
if [ -f profile.out ]; then
cat profile.out >> coverage.txt
rm profile.out
fi
done

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package concurrent
import (
"context"
"fmt"
"runtime"
"runtime/debug"
"sync"
"time"
"reflect"
)
// HandlePanic logs goroutine panic by default
var HandlePanic = func(recovered interface{}, funcName string) {
ErrorLogger.Println(fmt.Sprintf("%s panic: %v", funcName, recovered))
ErrorLogger.Println(string(debug.Stack()))
}
// UnboundedExecutor is a executor without limits on counts of alive goroutines
// it tracks the goroutine started by it, and can cancel them when shutdown
type UnboundedExecutor struct {
ctx context.Context
cancel context.CancelFunc
activeGoroutinesMutex *sync.Mutex
activeGoroutines map[string]int
HandlePanic func(recovered interface{}, funcName string)
}
// GlobalUnboundedExecutor has the life cycle of the program itself
// any goroutine want to be shutdown before main exit can be started from this executor
// GlobalUnboundedExecutor expects the main function to call stop
// it does not magically knows the main function exits
var GlobalUnboundedExecutor = NewUnboundedExecutor()
// NewUnboundedExecutor creates a new UnboundedExecutor,
// UnboundedExecutor can not be created by &UnboundedExecutor{}
// HandlePanic can be set with a callback to override global HandlePanic
func NewUnboundedExecutor() *UnboundedExecutor {
ctx, cancel := context.WithCancel(context.TODO())
return &UnboundedExecutor{
ctx: ctx,
cancel: cancel,
activeGoroutinesMutex: &sync.Mutex{},
activeGoroutines: map[string]int{},
}
}
// Go starts a new goroutine and tracks its lifecycle.
// Panic will be recovered and logged automatically, except for StopSignal
func (executor *UnboundedExecutor) Go(handler func(ctx context.Context)) {
pc := reflect.ValueOf(handler).Pointer()
f := runtime.FuncForPC(pc)
funcName := f.Name()
file, line := f.FileLine(pc)
executor.activeGoroutinesMutex.Lock()
defer executor.activeGoroutinesMutex.Unlock()
startFrom := fmt.Sprintf("%s:%d", file, line)
executor.activeGoroutines[startFrom] += 1
go func() {
defer func() {
recovered := recover()
// if you want to quit a goroutine without trigger HandlePanic
// use runtime.Goexit() to quit
if recovered != nil {
if executor.HandlePanic == nil {
HandlePanic(recovered, funcName)
} else {
executor.HandlePanic(recovered, funcName)
}
}
executor.activeGoroutinesMutex.Lock()
executor.activeGoroutines[startFrom] -= 1
executor.activeGoroutinesMutex.Unlock()
}()
handler(executor.ctx)
}()
}
// Stop cancel all goroutines started by this executor without wait
func (executor *UnboundedExecutor) Stop() {
executor.cancel()
}
// StopAndWaitForever cancel all goroutines started by this executor and
// wait until all goroutines exited
func (executor *UnboundedExecutor) StopAndWaitForever() {
executor.StopAndWait(context.Background())
}
// StopAndWait cancel all goroutines started by this executor and wait.
// Wait can be cancelled by the context passed in.
func (executor *UnboundedExecutor) StopAndWait(ctx context.Context) {
executor.cancel()
for {
oneHundredMilliseconds := time.NewTimer(time.Millisecond * 100)
select {
case <-oneHundredMilliseconds.C:
if executor.checkNoActiveGoroutines() {
return
}
case <-ctx.Done():
return
}
}
}
func (executor *UnboundedExecutor) checkNoActiveGoroutines() bool {
executor.activeGoroutinesMutex.Lock()
defer executor.activeGoroutinesMutex.Unlock()
for startFrom, count := range executor.activeGoroutines {
if count > 0 {
InfoLogger.Println("UnboundedExecutor is still waiting goroutines to quit",
"startFrom", startFrom,
"count", count)
return false
}
}
return true
}

2
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/vendor
/coverage.txt

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language: go
go:
- 1.8.x
- 1.x
before_install:
- go get -t -v ./...
- go get -t -v github.com/modern-go/reflect2-tests/...
script:
- ./test.sh
after_success:
- bash <(curl -s https://codecov.io/bash)

15
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# This file is autogenerated, do not edit; changes may be undone by the next 'dep ensure'.
[[projects]]
name = "github.com/modern-go/concurrent"
packages = ["."]
revision = "e0a39a4cb4216ea8db28e22a69f4ec25610d513a"
version = "1.0.0"
[solve-meta]
analyzer-name = "dep"
analyzer-version = 1
inputs-digest = "daee8a88b3498b61c5640056665b8b9eea062006f5e596bbb6a3ed9119a11ec7"
solver-name = "gps-cdcl"
solver-version = 1

35
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# Gopkg.toml example
#
# Refer to https://golang.github.io/dep/docs/Gopkg.toml.html
# for detailed Gopkg.toml documentation.
#
# required = ["github.com/user/thing/cmd/thing"]
# ignored = ["github.com/user/project/pkgX", "bitbucket.org/user/project/pkgA/pkgY"]
#
# [[constraint]]
# name = "github.com/user/project"
# version = "1.0.0"
#
# [[constraint]]
# name = "github.com/user/project2"
# branch = "dev"
# source = "github.com/myfork/project2"
#
# [[override]]
# name = "github.com/x/y"
# version = "2.4.0"
#
# [prune]
# non-go = false
# go-tests = true
# unused-packages = true
ignored = []
[[constraint]]
name = "github.com/modern-go/concurrent"
version = "1.0.0"
[prune]
go-tests = true
unused-packages = true

201
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Apache License
Version 2.0, January 2004
http://www.apache.org/licenses/
TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION
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"License" shall mean the terms and conditions for use, reproduction,
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(c) You must retain, in the Source form of any Derivative Works
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(d) If the Work includes a "NOTICE" text file as part of its
distribution, then any Derivative Works that You distribute must
include a readable copy of the attribution notices contained
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of the following places: within a NOTICE text file distributed
as part of the Derivative Works; within the Source form or
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of the NOTICE file are for informational purposes only and
do not modify the License. You may add Your own attribution
notices within Derivative Works that You distribute, alongside
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that such additional attribution notices cannot be construed
as modifying the License.
You may add Your own copyright statement to Your modifications and
may provide additional or different license terms and conditions
for use, reproduction, or distribution of Your modifications, or
for any such Derivative Works as a whole, provided Your use,
reproduction, and distribution of the Work otherwise complies with
the conditions stated in this License.
5. Submission of Contributions. Unless You explicitly state otherwise,
any Contribution intentionally submitted for inclusion in the Work
by You to the Licensor shall be under the terms and conditions of
this License, without any additional terms or conditions.
Notwithstanding the above, nothing herein shall supersede or modify
the terms of any separate license agreement you may have executed
with Licensor regarding such Contributions.
6. Trademarks. This License does not grant permission to use the trade
names, trademarks, service marks, or product names of the Licensor,
except as required for reasonable and customary use in describing the
origin of the Work and reproducing the content of the NOTICE file.
7. Disclaimer of Warranty. Unless required by applicable law or
agreed to in writing, Licensor provides the Work (and each
Contributor provides its Contributions) on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
implied, including, without limitation, any warranties or conditions
of TITLE, NON-INFRINGEMENT, MERCHANTABILITY, or FITNESS FOR A
PARTICULAR PURPOSE. You are solely responsible for determining the
appropriateness of using or redistributing the Work and assume any
risks associated with Your exercise of permissions under this License.
8. Limitation of Liability. In no event and under no legal theory,
whether in tort (including negligence), contract, or otherwise,
unless required by applicable law (such as deliberate and grossly
negligent acts) or agreed to in writing, shall any Contributor be
liable to You for damages, including any direct, indirect, special,
incidental, or consequential damages of any character arising as a
result of this License or out of the use or inability to use the
Work (including but not limited to damages for loss of goodwill,
work stoppage, computer failure or malfunction, or any and all
other commercial damages or losses), even if such Contributor
has been advised of the possibility of such damages.
9. Accepting Warranty or Additional Liability. While redistributing
the Work or Derivative Works thereof, You may choose to offer,
and charge a fee for, acceptance of support, warranty, indemnity,
or other liability obligations and/or rights consistent with this
License. However, in accepting such obligations, You may act only
on Your own behalf and on Your sole responsibility, not on behalf
of any other Contributor, and only if You agree to indemnify,
defend, and hold each Contributor harmless for any liability
incurred by, or claims asserted against, such Contributor by reason
of your accepting any such warranty or additional liability.
END OF TERMS AND CONDITIONS
APPENDIX: How to apply the Apache License to your work.
To apply the Apache License to your work, attach the following
boilerplate notice, with the fields enclosed by brackets "[]"
replaced with your own identifying information. (Don't include
the brackets!) The text should be enclosed in the appropriate
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Copyright [yyyy] [name of copyright owner]
Licensed under the Apache License, Version 2.0 (the "License");
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71
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# reflect2
[![Sourcegraph](https://sourcegraph.com/github.com/modern-go/reflect2/-/badge.svg)](https://sourcegraph.com/github.com/modern-go/reflect2?badge)
[![GoDoc](http://img.shields.io/badge/go-documentation-blue.svg?style=flat-square)](http://godoc.org/github.com/modern-go/reflect2)
[![Build Status](https://travis-ci.org/modern-go/reflect2.svg?branch=master)](https://travis-ci.org/modern-go/reflect2)
[![codecov](https://codecov.io/gh/modern-go/reflect2/branch/master/graph/badge.svg)](https://codecov.io/gh/modern-go/reflect2)
[![rcard](https://goreportcard.com/badge/github.com/modern-go/reflect2)](https://goreportcard.com/report/github.com/modern-go/reflect2)
[![License](https://img.shields.io/badge/License-Apache%202.0-blue.svg)](https://raw.githubusercontent.com/modern-go/reflect2/master/LICENSE)
reflect api that avoids runtime reflect.Value cost
* reflect get/set interface{}, with type checking
* reflect get/set unsafe.Pointer, without type checking
* `reflect2.TypeByName` works like `Class.forName` found in java
[json-iterator](https://github.com/json-iterator/go) use this package to save runtime dispatching cost.
This package is designed for low level libraries to optimize reflection performance.
General application should still use reflect standard library.
# reflect2.TypeByName
```go
// given package is github.com/your/awesome-package
type MyStruct struct {
// ...
}
// will return the type
reflect2.TypeByName("awesome-package.MyStruct")
// however, if the type has not been used
// it will be eliminated by compiler, so we can not get it in runtime
```
# reflect2 get/set interface{}
```go
valType := reflect2.TypeOf(1)
i := 1
j := 10
valType.Set(&i, &j)
// i will be 10
```
to get set `type`, always use its pointer `*type`
# reflect2 get/set unsafe.Pointer
```go
valType := reflect2.TypeOf(1)
i := 1
j := 10
valType.UnsafeSet(unsafe.Pointer(&i), unsafe.Pointer(&j))
// i will be 10
```
to get set `type`, always use its pointer `*type`
# benchmark
Benchmark is not necessary for this package. It does nothing actually.
As it is just a thin wrapper to make go runtime public.
Both `reflect2` and `reflect` call same function
provided by `runtime` package exposed by go language.
# unsafe safety
Instead of casting `[]byte` to `sliceHeader` in your application using unsafe.
We can use reflect2 instead. This way, if `sliceHeader` changes in the future,
only reflect2 need to be upgraded.
reflect2 tries its best to keep the implementation same as reflect (by testing).

8
vendor/github.com/modern-go/reflect2/go_above_17.go сгенерированный поставляемый Normal file
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//+build go1.7
package reflect2
import "unsafe"
//go:linkname resolveTypeOff reflect.resolveTypeOff
func resolveTypeOff(rtype unsafe.Pointer, off int32) unsafe.Pointer

14
vendor/github.com/modern-go/reflect2/go_above_19.go сгенерированный поставляемый Normal file
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@ -0,0 +1,14 @@
//+build go1.9
package reflect2
import (
"unsafe"
)
//go:linkname makemap reflect.makemap
func makemap(rtype unsafe.Pointer, cap int) (m unsafe.Pointer)
func makeMapWithSize(rtype unsafe.Pointer, cap int) unsafe.Pointer {
return makemap(rtype, cap)
}

9
vendor/github.com/modern-go/reflect2/go_below_17.go сгенерированный поставляемый Normal file
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@ -0,0 +1,9 @@
//+build !go1.7
package reflect2
import "unsafe"
func resolveTypeOff(rtype unsafe.Pointer, off int32) unsafe.Pointer {
return nil
}

14
vendor/github.com/modern-go/reflect2/go_below_19.go сгенерированный поставляемый Normal file
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@ -0,0 +1,14 @@
//+build !go1.9
package reflect2
import (
"unsafe"
)
//go:linkname makemap reflect.makemap
func makemap(rtype unsafe.Pointer) (m unsafe.Pointer)
func makeMapWithSize(rtype unsafe.Pointer, cap int) unsafe.Pointer {
return makemap(rtype)
}

298
vendor/github.com/modern-go/reflect2/reflect2.go сгенерированный поставляемый Normal file
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package reflect2
import (
"github.com/modern-go/concurrent"
"reflect"
"unsafe"
)
type Type interface {
Kind() reflect.Kind
// New return pointer to data of this type
New() interface{}
// UnsafeNew return the allocated space pointed by unsafe.Pointer
UnsafeNew() unsafe.Pointer
// PackEFace cast a unsafe pointer to object represented pointer
PackEFace(ptr unsafe.Pointer) interface{}
// Indirect dereference object represented pointer to this type
Indirect(obj interface{}) interface{}
// UnsafeIndirect dereference pointer to this type
UnsafeIndirect(ptr unsafe.Pointer) interface{}
// Type1 returns reflect.Type
Type1() reflect.Type
Implements(thatType Type) bool
String() string
RType() uintptr
// interface{} of this type has pointer like behavior
LikePtr() bool
IsNullable() bool
IsNil(obj interface{}) bool
UnsafeIsNil(ptr unsafe.Pointer) bool
Set(obj interface{}, val interface{})
UnsafeSet(ptr unsafe.Pointer, val unsafe.Pointer)
AssignableTo(anotherType Type) bool
}
type ListType interface {
Type
Elem() Type
SetIndex(obj interface{}, index int, elem interface{})
UnsafeSetIndex(obj unsafe.Pointer, index int, elem unsafe.Pointer)
GetIndex(obj interface{}, index int) interface{}
UnsafeGetIndex(obj unsafe.Pointer, index int) unsafe.Pointer
}
type ArrayType interface {
ListType
Len() int
}
type SliceType interface {
ListType
MakeSlice(length int, cap int) interface{}
UnsafeMakeSlice(length int, cap int) unsafe.Pointer
Grow(obj interface{}, newLength int)
UnsafeGrow(ptr unsafe.Pointer, newLength int)
Append(obj interface{}, elem interface{})
UnsafeAppend(obj unsafe.Pointer, elem unsafe.Pointer)
LengthOf(obj interface{}) int
UnsafeLengthOf(ptr unsafe.Pointer) int
SetNil(obj interface{})
UnsafeSetNil(ptr unsafe.Pointer)
Cap(obj interface{}) int
UnsafeCap(ptr unsafe.Pointer) int
}
type StructType interface {
Type
NumField() int
Field(i int) StructField
FieldByName(name string) StructField
FieldByIndex(index []int) StructField
FieldByNameFunc(match func(string) bool) StructField
}
type StructField interface {
Offset() uintptr
Name() string
PkgPath() string
Type() Type
Tag() reflect.StructTag
Index() []int
Anonymous() bool
Set(obj interface{}, value interface{})
UnsafeSet(obj unsafe.Pointer, value unsafe.Pointer)
Get(obj interface{}) interface{}
UnsafeGet(obj unsafe.Pointer) unsafe.Pointer
}
type MapType interface {
Type
Key() Type
Elem() Type
MakeMap(cap int) interface{}
UnsafeMakeMap(cap int) unsafe.Pointer
SetIndex(obj interface{}, key interface{}, elem interface{})
UnsafeSetIndex(obj unsafe.Pointer, key unsafe.Pointer, elem unsafe.Pointer)
TryGetIndex(obj interface{}, key interface{}) (interface{}, bool)
GetIndex(obj interface{}, key interface{}) interface{}
UnsafeGetIndex(obj unsafe.Pointer, key unsafe.Pointer) unsafe.Pointer
Iterate(obj interface{}) MapIterator
UnsafeIterate(obj unsafe.Pointer) MapIterator
}
type MapIterator interface {
HasNext() bool
Next() (key interface{}, elem interface{})
UnsafeNext() (key unsafe.Pointer, elem unsafe.Pointer)
}
type PtrType interface {
Type
Elem() Type
}
type InterfaceType interface {
NumMethod() int
}
type Config struct {
UseSafeImplementation bool
}
type API interface {
TypeOf(obj interface{}) Type
Type2(type1 reflect.Type) Type
}
var ConfigUnsafe = Config{UseSafeImplementation: false}.Froze()
var ConfigSafe = Config{UseSafeImplementation: true}.Froze()
type frozenConfig struct {
useSafeImplementation bool
cache *concurrent.Map
}
func (cfg Config) Froze() *frozenConfig {
return &frozenConfig{
useSafeImplementation: cfg.UseSafeImplementation,
cache: concurrent.NewMap(),
}
}
func (cfg *frozenConfig) TypeOf(obj interface{}) Type {
cacheKey := uintptr(unpackEFace(obj).rtype)
typeObj, found := cfg.cache.Load(cacheKey)
if found {
return typeObj.(Type)
}
return cfg.Type2(reflect.TypeOf(obj))
}
func (cfg *frozenConfig) Type2(type1 reflect.Type) Type {
if type1 == nil {
return nil
}
cacheKey := uintptr(unpackEFace(type1).data)
typeObj, found := cfg.cache.Load(cacheKey)
if found {
return typeObj.(Type)
}
type2 := cfg.wrapType(type1)
cfg.cache.Store(cacheKey, type2)
return type2
}
func (cfg *frozenConfig) wrapType(type1 reflect.Type) Type {
safeType := safeType{Type: type1, cfg: cfg}
switch type1.Kind() {
case reflect.Struct:
if cfg.useSafeImplementation {
return &safeStructType{safeType}
}
return newUnsafeStructType(cfg, type1)
case reflect.Array:
if cfg.useSafeImplementation {
return &safeSliceType{safeType}
}
return newUnsafeArrayType(cfg, type1)
case reflect.Slice:
if cfg.useSafeImplementation {
return &safeSliceType{safeType}
}
return newUnsafeSliceType(cfg, type1)
case reflect.Map:
if cfg.useSafeImplementation {
return &safeMapType{safeType}
}
return newUnsafeMapType(cfg, type1)
case reflect.Ptr, reflect.Chan, reflect.Func:
if cfg.useSafeImplementation {
return &safeMapType{safeType}
}
return newUnsafePtrType(cfg, type1)
case reflect.Interface:
if cfg.useSafeImplementation {
return &safeMapType{safeType}
}
if type1.NumMethod() == 0 {
return newUnsafeEFaceType(cfg, type1)
}
return newUnsafeIFaceType(cfg, type1)
default:
if cfg.useSafeImplementation {
return &safeType
}
return newUnsafeType(cfg, type1)
}
}
func TypeOf(obj interface{}) Type {
return ConfigUnsafe.TypeOf(obj)
}
func TypeOfPtr(obj interface{}) PtrType {
return TypeOf(obj).(PtrType)
}
func Type2(type1 reflect.Type) Type {
if type1 == nil {
return nil
}
return ConfigUnsafe.Type2(type1)
}
func PtrTo(typ Type) Type {
return Type2(reflect.PtrTo(typ.Type1()))
}
func PtrOf(obj interface{}) unsafe.Pointer {
return unpackEFace(obj).data
}
func RTypeOf(obj interface{}) uintptr {
return uintptr(unpackEFace(obj).rtype)
}
func IsNil(obj interface{}) bool {
if obj == nil {
return true
}
return unpackEFace(obj).data == nil
}
func IsNullable(kind reflect.Kind) bool {
switch kind {
case reflect.Ptr, reflect.Map, reflect.Chan, reflect.Func, reflect.Slice, reflect.Interface:
return true
}
return false
}
func likePtrKind(kind reflect.Kind) bool {
switch kind {
case reflect.Ptr, reflect.Map, reflect.Chan, reflect.Func:
return true
}
return false
}
func likePtrType(typ reflect.Type) bool {
if likePtrKind(typ.Kind()) {
return true
}
if typ.Kind() == reflect.Struct {
if typ.NumField() != 1 {
return false
}
return likePtrType(typ.Field(0).Type)
}
if typ.Kind() == reflect.Array {
if typ.Len() != 1 {
return false
}
return likePtrType(typ.Elem())
}
return false
}
// NoEscape hides a pointer from escape analysis. noescape is
// the identity function but escape analysis doesn't think the
// output depends on the input. noescape is inlined and currently
// compiles down to zero instructions.
// USE CAREFULLY!
//go:nosplit
func NoEscape(p unsafe.Pointer) unsafe.Pointer {
x := uintptr(p)
return unsafe.Pointer(x ^ 0)
}
func UnsafeCastString(str string) []byte {
stringHeader := (*reflect.StringHeader)(unsafe.Pointer(&str))
sliceHeader := &reflect.SliceHeader{
Data: stringHeader.Data,
Cap: stringHeader.Len,
Len: stringHeader.Len,
}
return *(*[]byte)(unsafe.Pointer(sliceHeader))
}

0
vendor/github.com/modern-go/reflect2/reflect2_amd64.s сгенерированный поставляемый Normal file
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30
vendor/github.com/modern-go/reflect2/reflect2_kind.go сгенерированный поставляемый Normal file
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package reflect2
import (
"reflect"
"unsafe"
)
// DefaultTypeOfKind return the non aliased default type for the kind
func DefaultTypeOfKind(kind reflect.Kind) Type {
return kindTypes[kind]
}
var kindTypes = map[reflect.Kind]Type{
reflect.Bool: TypeOf(true),
reflect.Uint8: TypeOf(uint8(0)),
reflect.Int8: TypeOf(int8(0)),
reflect.Uint16: TypeOf(uint16(0)),
reflect.Int16: TypeOf(int16(0)),
reflect.Uint32: TypeOf(uint32(0)),
reflect.Int32: TypeOf(int32(0)),
reflect.Uint64: TypeOf(uint64(0)),
reflect.Int64: TypeOf(int64(0)),
reflect.Uint: TypeOf(uint(0)),
reflect.Int: TypeOf(int(0)),
reflect.Float32: TypeOf(float32(0)),
reflect.Float64: TypeOf(float64(0)),
reflect.Uintptr: TypeOf(uintptr(0)),
reflect.String: TypeOf(""),
reflect.UnsafePointer: TypeOf(unsafe.Pointer(nil)),
}

0
vendor/github.com/modern-go/reflect2/relfect2_386.s сгенерированный поставляемый Normal file
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0
vendor/github.com/modern-go/reflect2/relfect2_amd64p32.s сгенерированный поставляемый Normal file
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0
vendor/github.com/modern-go/reflect2/relfect2_arm.s сгенерированный поставляемый Normal file
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0
vendor/github.com/modern-go/reflect2/relfect2_arm64.s сгенерированный поставляемый Normal file
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0
vendor/github.com/modern-go/reflect2/relfect2_mips64x.s сгенерированный поставляемый Normal file
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