prometheus/postgres_exporter
1
0
Fork 0
mirror of https://github.com/prometheus-community/postgres_exporter.git synced 2025-08-08 04:42:07 +03:00
Code Activity

Refactor repository layout and convert build system to Mage.

Browse Source 
This commit implements a massive refactor of the repository, and
moves the build system over to use Mage (magefile.org) which should
allow seamless building across multiple platforms.
This commit is contained in:
Will Rouesnel
2018-02-23 01:55:49 +11:00
parent 3e6cf08dc5
commit 989489096e
269 changed files with 35309 additions and 2017 deletions
Download Patch File Download Diff File Expand all files Collapse all files

15
tools/vendor/golang.org/x/lint/CONTRIBUTING.md generated vendored Normal file
View File

@@ -0,0 +1,15 @@
# Contributing to Golint
## Before filing an issue:
### Are you having trouble building golint?
Check you have the latest version of its dependencies. Run
```
go get -u github.com/golang/lint
```
If you still have problems, consider searching for existing issues before filing a new issue.
## Before sending a pull request:
Have you understood the purpose of golint? Make sure to carefully read `README`.

27
tools/vendor/golang.org/x/lint/LICENSE generated vendored Normal file
View File

@@ -0,0 +1,27 @@
Copyright (c) 2013 The Go Authors. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above
copyright notice, this list of conditions and the following disclaimer
in the documentation and/or other materials provided with the
distribution.
* Neither the name of Google Inc. nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

85
tools/vendor/golang.org/x/lint/README.md generated vendored Normal file
View File

@@ -0,0 +1,85 @@
Golint is a linter for Go source code.
[![Build Status](https://travis-ci.org/golang/lint.svg?branch=master)](https://travis-ci.org/golang/lint)
## Installation
Golint requires Go 1.6 or later.
go get -u golang.org/x/lint/golint
## Usage
Invoke `golint` with one or more filenames, directories, or packages named
by its import path. Golint uses the same
[import path syntax](https://golang.org/cmd/go/#hdr-Import_path_syntax) as
the `go` command and therefore
also supports relative import paths like `./...`. Additionally the `...`
wildcard can be used as suffix on relative and absolute file paths to recurse
into them.
The output of this tool is a list of suggestions in Vim quickfix format,
which is accepted by lots of different editors.
## Purpose
Golint differs from gofmt. Gofmt reformats Go source code, whereas
golint prints out style mistakes.
Golint differs from govet. Govet is concerned with correctness, whereas
golint is concerned with coding style. Golint is in use at Google, and it
seeks to match the accepted style of the open source Go project.
The suggestions made by golint are exactly that: suggestions.
Golint is not perfect, and has both false positives and false negatives.
Do not treat its output as a gold standard. We will not be adding pragmas
or other knobs to suppress specific warnings, so do not expect or require
code to be completely "lint-free".
In short, this tool is not, and will never be, trustworthy enough for its
suggestions to be enforced automatically, for example as part of a build process.
Golint makes suggestions for many of the mechanically checkable items listed in
[Effective Go](https://golang.org/doc/effective_go.html) and the
[CodeReviewComments wiki page](https://golang.org/wiki/CodeReviewComments).
## Scope
Golint is meant to carry out the stylistic conventions put forth in
[Effective Go](https://golang.org/doc/effective_go.html) and
[CodeReviewComments](https://golang.org/wiki/CodeReviewComments).
Changes that are not aligned with those documents will not be considered.
## Contributions
Contributions to this project are welcome provided they are [in scope](#scope),
though please send mail before starting work on anything major.
Contributors retain their copyright, so we need you to fill out
[a short form](https://developers.google.com/open-source/cla/individual)
before we can accept your contribution.
## Vim
Add this to your ~/.vimrc:
set rtp+=$GOPATH/src/github.com/golang/lint/misc/vim
If you have multiple entries in your GOPATH, replace `$GOPATH` with the right value.
Running `:Lint` will run golint on the current file and populate the quickfix list.
Optionally, add this to your `~/.vimrc` to automatically run `golint` on `:w`
autocmd BufWritePost,FileWritePost *.go execute 'Lint' | cwindow
## Emacs
Add this to your `.emacs` file:
(add-to-list 'load-path (concat (getenv "GOPATH") "/src/github.com/golang/lint/misc/emacs"))
(require 'golint)
If you have multiple entries in your GOPATH, replace `$GOPATH` with the right value.
Running M-x golint will run golint on the current file.
For more usage, see [Compilation-Mode](http://www.gnu.org/software/emacs/manual/html_node/emacs/Compilation-Mode.html).

1708
tools/vendor/golang.org/x/lint/lint.go generated vendored Normal file
View File

File diff suppressed because it is too large Load Diff

459
tools/vendor/golang.org/x/tools/go/callgraph/rta/rta.go generated vendored Normal file
View File

@@ -0,0 +1,459 @@
// Copyright 2013 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// This package provides Rapid Type Analysis (RTA) for Go, a fast
// algorithm for call graph construction and discovery of reachable code
// (and hence dead code) and runtime types. The algorithm was first
// described in:
//
// David F. Bacon and Peter F. Sweeney. 1996.
// Fast static analysis of C++ virtual function calls. (OOPSLA '96)
// http://doi.acm.org/10.1145/236337.236371
//
// The algorithm uses dynamic programming to tabulate the cross-product
// of the set of known "address taken" functions with the set of known
// dynamic calls of the same type. As each new address-taken function
// is discovered, call graph edges are added from each known callsite,
// and as each new call site is discovered, call graph edges are added
// from it to each known address-taken function.
//
// A similar approach is used for dynamic calls via interfaces: it
// tabulates the cross-product of the set of known "runtime types",
// i.e. types that may appear in an interface value, or be derived from
// one via reflection, with the set of known "invoke"-mode dynamic
// calls. As each new "runtime type" is discovered, call edges are
// added from the known call sites, and as each new call site is
// discovered, call graph edges are added to each compatible
// method.
//
// In addition, we must consider all exported methods of any runtime type
// as reachable, since they may be called via reflection.
//
// Each time a newly added call edge causes a new function to become
// reachable, the code of that function is analyzed for more call sites,
// address-taken functions, and runtime types. The process continues
// until a fixed point is achieved.
//
// The resulting call graph is less precise than one produced by pointer
// analysis, but the algorithm is much faster. For example, running the
// cmd/callgraph tool on its own source takes ~2.1s for RTA and ~5.4s
// for points-to analysis.
//
package rta // import "golang.org/x/tools/go/callgraph/rta"
// TODO(adonovan): test it by connecting it to the interpreter and
// replacing all "unreachable" functions by a special intrinsic, and
// ensure that that intrinsic is never called.
import (
"fmt"
"go/types"
"golang.org/x/tools/go/callgraph"
"golang.org/x/tools/go/ssa"
"golang.org/x/tools/go/types/typeutil"
)
// A Result holds the results of Rapid Type Analysis, which includes the
// set of reachable functions/methods, runtime types, and the call graph.
//
type Result struct {
// CallGraph is the discovered callgraph.
// It does not include edges for calls made via reflection.
CallGraph *callgraph.Graph
// Reachable contains the set of reachable functions and methods.
// This includes exported methods of runtime types, since
// they may be accessed via reflection.
// The value indicates whether the function is address-taken.
//
// (We wrap the bool in a struct to avoid inadvertent use of
// "if Reachable[f] {" to test for set membership.)
Reachable map[*ssa.Function]struct{ AddrTaken bool }
// RuntimeTypes contains the set of types that are needed at
// runtime, for interfaces or reflection.
//
// The value indicates whether the type is inaccessible to reflection.
// Consider:
// type A struct{B}
// fmt.Println(new(A))
// Types *A, A and B are accessible to reflection, but the unnamed
// type struct{B} is not.
RuntimeTypes typeutil.Map
}
// Working state of the RTA algorithm.
type rta struct {
result *Result
prog *ssa.Program
worklist []*ssa.Function // list of functions to visit
// addrTakenFuncsBySig contains all address-taken *Functions, grouped by signature.
// Keys are *types.Signature, values are map[*ssa.Function]bool sets.
addrTakenFuncsBySig typeutil.Map
// dynCallSites contains all dynamic "call"-mode call sites, grouped by signature.
// Keys are *types.Signature, values are unordered []ssa.CallInstruction.
dynCallSites typeutil.Map
// invokeSites contains all "invoke"-mode call sites, grouped by interface.
// Keys are *types.Interface (never *types.Named),
// Values are unordered []ssa.CallInstruction sets.
invokeSites typeutil.Map
// The following two maps together define the subset of the
// m:n "implements" relation needed by the algorithm.
// concreteTypes maps each concrete type to the set of interfaces that it implements.
// Keys are types.Type, values are unordered []*types.Interface.
// Only concrete types used as MakeInterface operands are included.
concreteTypes typeutil.Map
// interfaceTypes maps each interface type to
// the set of concrete types that implement it.
// Keys are *types.Interface, values are unordered []types.Type.
// Only interfaces used in "invoke"-mode CallInstructions are included.
interfaceTypes typeutil.Map
}
// addReachable marks a function as potentially callable at run-time,
// and ensures that it gets processed.
func (r *rta) addReachable(f *ssa.Function, addrTaken bool) {
reachable := r.result.Reachable
n := len(reachable)
v := reachable[f]
if addrTaken {
v.AddrTaken = true
}
reachable[f] = v
if len(reachable) > n {
// First time seeing f. Add it to the worklist.
r.worklist = append(r.worklist, f)
}
}
// addEdge adds the specified call graph edge, and marks it reachable.
// addrTaken indicates whether to mark the callee as "address-taken".
func (r *rta) addEdge(site ssa.CallInstruction, callee *ssa.Function, addrTaken bool) {
r.addReachable(callee, addrTaken)
if g := r.result.CallGraph; g != nil {
if site.Parent() == nil {
panic(site)
}
from := g.CreateNode(site.Parent())
to := g.CreateNode(callee)
callgraph.AddEdge(from, site, to)
}
}
// ---------- addrTakenFuncs × dynCallSites ----------
// visitAddrTakenFunc is called each time we encounter an address-taken function f.
func (r *rta) visitAddrTakenFunc(f *ssa.Function) {
// Create two-level map (Signature -> Function -> bool).
S := f.Signature
funcs, _ := r.addrTakenFuncsBySig.At(S).(map[*ssa.Function]bool)
if funcs == nil {
funcs = make(map[*ssa.Function]bool)
r.addrTakenFuncsBySig.Set(S, funcs)
}
if !funcs[f] {
// First time seeing f.
funcs[f] = true
// If we've seen any dyncalls of this type, mark it reachable,
// and add call graph edges.
sites, _ := r.dynCallSites.At(S).([]ssa.CallInstruction)
for _, site := range sites {
r.addEdge(site, f, true)
}
}
}
// visitDynCall is called each time we encounter a dynamic "call"-mode call.
func (r *rta) visitDynCall(site ssa.CallInstruction) {
S := site.Common().Signature()
// Record the call site.
sites, _ := r.dynCallSites.At(S).([]ssa.CallInstruction)
r.dynCallSites.Set(S, append(sites, site))
// For each function of signature S that we know is address-taken,
// mark it reachable. We'll add the callgraph edges later.
funcs, _ := r.addrTakenFuncsBySig.At(S).(map[*ssa.Function]bool)
for g := range funcs {
r.addEdge(site, g, true)
}
}
// ---------- concrete types × invoke sites ----------
// addInvokeEdge is called for each new pair (site, C) in the matrix.
func (r *rta) addInvokeEdge(site ssa.CallInstruction, C types.Type) {
// Ascertain the concrete method of C to be called.
imethod := site.Common().Method
cmethod := r.prog.MethodValue(r.prog.MethodSets.MethodSet(C).Lookup(imethod.Pkg(), imethod.Name()))
r.addEdge(site, cmethod, true)
}
// visitInvoke is called each time the algorithm encounters an "invoke"-mode call.
func (r *rta) visitInvoke(site ssa.CallInstruction) {
I := site.Common().Value.Type().Underlying().(*types.Interface)
// Record the invoke site.
sites, _ := r.invokeSites.At(I).([]ssa.CallInstruction)
r.invokeSites.Set(I, append(sites, site))
// Add callgraph edge for each existing
// address-taken concrete type implementing I.
for _, C := range r.implementations(I) {
r.addInvokeEdge(site, C)
}
}
// ---------- main algorithm ----------
// visitFunc processes function f.
func (r *rta) visitFunc(f *ssa.Function) {
var space [32]*ssa.Value // preallocate space for common case
for _, b := range f.Blocks {
for _, instr := range b.Instrs {
rands := instr.Operands(space[:0])
switch instr := instr.(type) {
case ssa.CallInstruction:
call := instr.Common()
if call.IsInvoke() {
r.visitInvoke(instr)
} else if g := call.StaticCallee(); g != nil {
r.addEdge(instr, g, false)
} else if _, ok := call.Value.(*ssa.Builtin); !ok {
r.visitDynCall(instr)
}
// Ignore the call-position operand when
// looking for address-taken Functions.
// Hack: assume this is rands[0].
rands = rands[1:]
case *ssa.MakeInterface:
r.addRuntimeType(instr.X.Type(), false)
}
// Process all address-taken functions.
for _, op := range rands {
if g, ok := (*op).(*ssa.Function); ok {
r.visitAddrTakenFunc(g)
}
}
}
}
}
// Analyze performs Rapid Type Analysis, starting at the specified root
// functions. It returns nil if no roots were specified.
//
// If buildCallGraph is true, Result.CallGraph will contain a call
// graph; otherwise, only the other fields (reachable functions) are
// populated.
//
func Analyze(roots []*ssa.Function, buildCallGraph bool) *Result {
if len(roots) == 0 {
return nil
}
r := &rta{
result: &Result{Reachable: make(map[*ssa.Function]struct{ AddrTaken bool })},
prog: roots[0].Prog,
}
if buildCallGraph {
// TODO(adonovan): change callgraph API to eliminate the
// notion of a distinguished root node. Some callgraphs
// have many roots, or none.
r.result.CallGraph = callgraph.New(roots[0])
}
hasher := typeutil.MakeHasher()
r.result.RuntimeTypes.SetHasher(hasher)
r.addrTakenFuncsBySig.SetHasher(hasher)
r.dynCallSites.SetHasher(hasher)
r.invokeSites.SetHasher(hasher)
r.concreteTypes.SetHasher(hasher)
r.interfaceTypes.SetHasher(hasher)
// Visit functions, processing their instructions, and adding
// new functions to the worklist, until a fixed point is
// reached.
var shadow []*ssa.Function // for efficiency, we double-buffer the worklist
r.worklist = append(r.worklist, roots...)
for len(r.worklist) > 0 {
shadow, r.worklist = r.worklist, shadow[:0]
for _, f := range shadow {
r.visitFunc(f)
}
}
return r.result
}
// interfaces(C) returns all currently known interfaces implemented by C.
func (r *rta) interfaces(C types.Type) []*types.Interface {
// Ascertain set of interfaces C implements
// and update 'implements' relation.
var ifaces []*types.Interface
r.interfaceTypes.Iterate(func(I types.Type, concs interface{}) {
if I := I.(*types.Interface); types.Implements(C, I) {
concs, _ := concs.([]types.Type)
r.interfaceTypes.Set(I, append(concs, C))
ifaces = append(ifaces, I)
}
})
r.concreteTypes.Set(C, ifaces)
return ifaces
}
// implementations(I) returns all currently known concrete types that implement I.
func (r *rta) implementations(I *types.Interface) []types.Type {
var concs []types.Type
if v := r.interfaceTypes.At(I); v != nil {
concs = v.([]types.Type)
} else {
// First time seeing this interface.
// Update the 'implements' relation.
r.concreteTypes.Iterate(func(C types.Type, ifaces interface{}) {
if types.Implements(C, I) {
ifaces, _ := ifaces.([]*types.Interface)
r.concreteTypes.Set(C, append(ifaces, I))
concs = append(concs, C)
}
})
r.interfaceTypes.Set(I, concs)
}
return concs
}
// addRuntimeType is called for each concrete type that can be the
// dynamic type of some interface or reflect.Value.
// Adapted from needMethods in go/ssa/builder.go
//
func (r *rta) addRuntimeType(T types.Type, skip bool) {
if prev, ok := r.result.RuntimeTypes.At(T).(bool); ok {
if skip && !prev {
r.result.RuntimeTypes.Set(T, skip)
}
return
}
r.result.RuntimeTypes.Set(T, skip)
mset := r.prog.MethodSets.MethodSet(T)
if _, ok := T.Underlying().(*types.Interface); !ok {
// T is a new concrete type.
for i, n := 0, mset.Len(); i < n; i++ {
sel := mset.At(i)
m := sel.Obj()
if m.Exported() {
// Exported methods are always potentially callable via reflection.
r.addReachable(r.prog.MethodValue(sel), true)
}
}
// Add callgraph edge for each existing dynamic
// "invoke"-mode call via that interface.
for _, I := range r.interfaces(T) {
sites, _ := r.invokeSites.At(I).([]ssa.CallInstruction)
for _, site := range sites {
r.addInvokeEdge(site, T)
}
}
}
// Precondition: T is not a method signature (*Signature with Recv()!=nil).
// Recursive case: skip => don't call makeMethods(T).
// Each package maintains its own set of types it has visited.
var n *types.Named
switch T := T.(type) {
case *types.Named:
n = T
case *types.Pointer:
n, _ = T.Elem().(*types.Named)
}
if n != nil {
owner := n.Obj().Pkg()
if owner == nil {
return // built-in error type
}
}
// Recursion over signatures of each exported method.
for i := 0; i < mset.Len(); i++ {
if mset.At(i).Obj().Exported() {
sig := mset.At(i).Type().(*types.Signature)
r.addRuntimeType(sig.Params(), true) // skip the Tuple itself
r.addRuntimeType(sig.Results(), true) // skip the Tuple itself
}
}
switch t := T.(type) {
case *types.Basic:
// nop
case *types.Interface:
// nop---handled by recursion over method set.
case *types.Pointer:
r.addRuntimeType(t.Elem(), false)
case *types.Slice:
r.addRuntimeType(t.Elem(), false)
case *types.Chan:
r.addRuntimeType(t.Elem(), false)
case *types.Map:
r.addRuntimeType(t.Key(), false)
r.addRuntimeType(t.Elem(), false)
case *types.Signature:
if t.Recv() != nil {
panic(fmt.Sprintf("Signature %s has Recv %s", t, t.Recv()))
}
r.addRuntimeType(t.Params(), true) // skip the Tuple itself
r.addRuntimeType(t.Results(), true) // skip the Tuple itself
case *types.Named:
// A pointer-to-named type can be derived from a named
// type via reflection. It may have methods too.
r.addRuntimeType(types.NewPointer(T), false)
// Consider 'type T struct{S}' where S has methods.
// Reflection provides no way to get from T to struct{S},
// only to S, so the method set of struct{S} is unwanted,
// so set 'skip' flag during recursion.
r.addRuntimeType(t.Underlying(), true)
case *types.Array:
r.addRuntimeType(t.Elem(), false)
case *types.Struct:
for i, n := 0, t.NumFields(); i < n; i++ {
r.addRuntimeType(t.Field(i).Type(), false)
}
case *types.Tuple:
for i, n := 0, t.Len(); i < n; i++ {
r.addRuntimeType(t.At(i).Type(), false)
}
default:
panic(T)
}
}