Multiline Marshal tag (#221 )

The new multiline tag works just like the existing 'commented' tag (i.e. `multiline:"true"`), and tells go-toml to marshal the value as a multi-line string. The tag currently has no impact on any non-string fields.
Go 1.10 support (#223 )
2018-06-05 13:47:19 -07:00 · 2018-03-23 11:52:43 -07:00 · 2018-02-28 15:36:31 -08:00 · 2018-01-18 14:54:55 -08:00 · 2018-01-18 14:10:55 -08:00 · 2018-01-18 14:08:34 -08:00
49 changed files with 8970 additions and 986 deletions
@@ -1 +1,2 @@
 test_program/test_program_bin
 fuzz/
@@ -1,6 +1,23 @@
 sudo: false
 language: go
 script: "./test.sh"
 go:
-    - 1.1
+  - 1.8.x
-    - 1.2
+  - 1.9.x
  - 1.10.x
  - tip
 matrix:
  allow_failures:
    - go: tip
  fast_finish: true
 script:
  - if [ -n "$(go fmt ./...)" ]; then exit 1; fi
  - ./test.sh
  - ./benchmark.sh $TRAVIS_BRANCH https://github.com/$TRAVIS_REPO_SLUG.git
 before_install:
  - go get github.com/axw/gocov/gocov
  - go get github.com/mattn/goveralls
  - if ! go get code.google.com/p/go.tools/cmd/cover; then go get golang.org/x/tools/cmd/cover; fi
 branches:
  only: [master]
 after_success:
  - $HOME/gopath/bin/goveralls -service=travis-ci -coverprofile=coverage.out -repotoken $COVERALLS_TOKEN
@@ -0,0 +1,21 @@
 The MIT License (MIT)
 Copyright (c) 2013 - 2017 Thomas Pelletier, Eric Anderton
 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.
@@ -3,53 +3,102 @@
 Go library for the [TOML](https://github.com/mojombo/toml) format.
 This library supports TOML version
-[v0.1.0](https://github.com/mojombo/toml/blob/master/versions/toml-v0.1.0.md)
+[v0.4.0](https://github.com/toml-lang/toml/blob/master/versions/en/toml-v0.4.0.md)
-[![Build Status](https://travis-ci.org/pelletier/go-toml.png?branch=master)](https://travis-ci.org/pelletier/go-toml)
+[![GoDoc](https://godoc.org/github.com/pelletier/go-toml?status.svg)](http://godoc.org/github.com/pelletier/go-toml)
 [![license](https://img.shields.io/github/license/pelletier/go-toml.svg)](https://github.com/pelletier/go-toml/blob/master/LICENSE)
 [![Build Status](https://travis-ci.org/pelletier/go-toml.svg?branch=master)](https://travis-ci.org/pelletier/go-toml)
 [![Coverage Status](https://coveralls.io/repos/github/pelletier/go-toml/badge.svg?branch=master)](https://coveralls.io/github/pelletier/go-toml?branch=master)
 [![Go Report Card](https://goreportcard.com/badge/github.com/pelletier/go-toml)](https://goreportcard.com/report/github.com/pelletier/go-toml)
 ## Features
 Go-toml provides the following features for using data parsed from TOML documents:
 * Load TOML documents from files and string data
 * Easily navigate TOML structure using Tree
 * Mashaling and unmarshaling to and from data structures
 * Line & column position data for all parsed elements
 * [Query support similar to JSON-Path](query/)
 * Syntax errors contain line and column numbers
 ## Import
 ```go
 import "github.com/pelletier/go-toml"
 ## Usage
 Say you have a TOML file that looks like this:
 ```toml
 [postgres]
 user = "pelletier"
 password = "mypassword"
 ```
-Read the username and password like this:
+## Usage example
 Read a TOML document:
 ```go
-import (
+config, _ := toml.Load(`
-    "fmt"
+[postgres]
-    "github.com/pelletier/go-toml"
+user = "pelletier"
-)
+password = "mypassword"`)
 config, err := toml.LoadFile("config.toml")
 if err != nil {
    fmt.Println("Error ", err.Error())
 } else {
 // retrieve data directly
 user := config.Get("postgres.user").(string)
    password := config.Get("postgres.password").(string)
 // or using an intermediate object
-    configTree := config.Get("postgres").(*toml.TomlTree)
+postgresConfig := config.Get("postgres").(*toml.Tree)
-    user = configTree.Get("user").(string)
+password := postgresConfig.Get("password").(string)
-    password = configTree.Get("password").(string)
+```
-    fmt.Println("User is ", user, ". Password is ", password)
+
 Or use Unmarshal:
 ```go
 type Postgres struct {
    User     string
    Password string
 }
 type Config struct {
    Postgres Postgres
 }
 doc := []byte(`
 [Postgres]
 User = "pelletier"
 Password = "mypassword"`)
 config := Config{}
 toml.Unmarshal(doc, &config)
 fmt.Println("user=", config.Postgres.User)
 ```
 Or use a query:
 ```go
 // use a query to gather elements without walking the tree
 q, _ := query.Compile("$..[user,password]")
 results := q.Execute(config)
 for ii, item := range results.Values() {
    fmt.Println("Query result %d: %v", ii, item)
 }
 ```
 ## Documentation
-The documentation is available at
+The documentation and additional examples are available at
 [godoc.org](http://godoc.org/github.com/pelletier/go-toml).
 ## Tools
 Go-toml provides two handy command line tools:
 * `tomll`: Reads TOML files and lint them.
    ```
    go install github.com/pelletier/go-toml/cmd/tomll
    tomll --help
    ```
 * `tomljson`: Reads a TOML file and outputs its JSON representation.
    ```
    go install github.com/pelletier/go-toml/cmd/tomljson
    tomljson --help
    ```
 ## Contribute
 Feel free to report bugs and patches using GitHub's pull requests system on
@@ -60,29 +109,23 @@ much appreciated!
 You have to make sure two kind of tests run:
-1. The Go unit tests: `go test`
+1. The Go unit tests
-2. The TOML examples base: `./test_program/go-test.sh`
+2. The TOML examples base
 You can run both of them using `./test.sh`.
 ### Fuzzing
 The script `./fuzz.sh` is available to
 run [go-fuzz](https://github.com/dvyukov/go-fuzz) on go-toml.
 ## Versioning
 Go-toml follows [Semantic Versioning](http://semver.org/). The supported version
 of [TOML](https://github.com/toml-lang/toml) is indicated at the beginning of
 this document. The last two major versions of Go are supported
 (see [Go Release Policy](https://golang.org/doc/devel/release.html#policy)).
 ## License
-Copyright (c) 2013, 2014 Thomas Pelletier, Eric Anderton
+The MIT License (MIT). Read [LICENSE](LICENSE).
 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.
@@ -0,0 +1,164 @@
 {
    "array": {
        "key1": [
            1,
            2,
            3
        ],
        "key2": [
            "red",
            "yellow",
            "green"
        ],
        "key3": [
            [
                1,
                2
            ],
            [
                3,
                4,
                5
            ]
        ],
        "key4": [
            [
                1,
                2
            ],
            [
                "a",
                "b",
                "c"
            ]
        ],
        "key5": [
            1,
            2,
            3
        ],
        "key6": [
            1,
            2
        ]
    },
    "boolean": {
        "False": false,
        "True": true
    },
    "datetime": {
        "key1": "1979-05-27T07:32:00Z",
        "key2": "1979-05-27T00:32:00-07:00",
        "key3": "1979-05-27T00:32:00.999999-07:00"
    },
    "float": {
        "both": {
            "key": 6.626e-34
        },
        "exponent": {
            "key1": 5e+22,
            "key2": 1000000,
            "key3": -0.02
        },
        "fractional": {
            "key1": 1,
            "key2": 3.1415,
            "key3": -0.01
        },
        "underscores": {
            "key1": 9224617.445991227,
            "key2": 1e+100
        }
    },
    "fruit": [{
            "name": "apple",
            "physical": {
                "color": "red",
                "shape": "round"
            },
            "variety": [{
                    "name": "red delicious"
                },
                {
                    "name": "granny smith"
                }
            ]
        },
        {
            "name": "banana",
            "variety": [{
                "name": "plantain"
            }]
        }
    ],
    "integer": {
        "key1": 99,
        "key2": 42,
        "key3": 0,
        "key4": -17,
        "underscores": {
            "key1": 1000,
            "key2": 5349221,
            "key3": 12345
        }
    },
    "products": [{
            "name": "Hammer",
            "sku": 738594937
        },
        {},
        {
            "color": "gray",
            "name": "Nail",
            "sku": 284758393
        }
    ],
    "string": {
        "basic": {
            "basic": "I'm a string. \"You can quote me\". Name\tJosé\nLocation\tSF."
        },
        "literal": {
            "multiline": {
                "lines": "The first newline is\ntrimmed in raw strings.\n   All other whitespace\n   is preserved.\n",
                "regex2": "I [dw]on't need \\d{2} apples"
            },
            "quoted": "Tom \"Dubs\" Preston-Werner",
            "regex": "\u003c\\i\\c*\\s*\u003e",
            "winpath": "C:\\Users\\nodejs\\templates",
            "winpath2": "\\\\ServerX\\admin$\\system32\\"
        },
        "multiline": {
            "continued": {
                "key1": "The quick brown fox jumps over the lazy dog.",
                "key2": "The quick brown fox jumps over the lazy dog.",
                "key3": "The quick brown fox jumps over the lazy dog."
            },
            "key1": "One\nTwo",
            "key2": "One\nTwo",
            "key3": "One\nTwo"
        }
    },
    "table": {
        "inline": {
            "name": {
                "first": "Tom",
                "last": "Preston-Werner"
            },
            "point": {
                "x": 1,
                "y": 2
            }
        },
        "key": "value",
        "subtable": {
            "key": "another value"
        }
    },
    "x": {
        "y": {
            "z": {
                "w": {}
            }
        }
    }
 }
@@ -0,0 +1,32 @@
 #!/bin/bash
 set -e
 reference_ref=${1:-master}
 reference_git=${2:-.}
 if ! `hash benchstat 2>/dev/null`; then
    echo "Installing benchstat"
    go get golang.org/x/perf/cmd/benchstat
    go install golang.org/x/perf/cmd/benchstat
 fi
 tempdir=`mktemp -d /tmp/go-toml-benchmark-XXXXXX`
 ref_tempdir="${tempdir}/ref"
 ref_benchmark="${ref_tempdir}/benchmark-`echo -n ${reference_ref}|tr -s '/' '-'`.txt"
 local_benchmark="`pwd`/benchmark-local.txt"
 echo "=== ${reference_ref} (${ref_tempdir})"
 git clone ${reference_git} ${ref_tempdir} >/dev/null 2>/dev/null
 pushd ${ref_tempdir} >/dev/null
 git checkout ${reference_ref} >/dev/null 2>/dev/null
 go test -bench=. -benchmem | tee ${ref_benchmark}
 popd >/dev/null
 echo ""
 echo "=== local"
 go test -bench=. -benchmem  | tee ${local_benchmark}
 echo ""
 echo "=== diff"
 benchstat -delta-test=none ${ref_benchmark} ${local_benchmark}
@@ -0,0 +1,244 @@
 ################################################################################
 ## Comment
 # Speak your mind with the hash symbol. They go from the symbol to the end of
 # the line.
 ################################################################################
 ## Table
 # Tables (also known as hash tables or dictionaries) are collections of
 # key/value pairs. They appear in square brackets on a line by themselves.
 [table]
 key = "value" # Yeah, you can do this.
 # Nested tables are denoted by table names with dots in them. Name your tables
 # whatever crap you please, just don't use #, ., [ or ].
 [table.subtable]
 key = "another value"
 # You don't need to specify all the super-tables if you don't want to. TOML
 # knows how to do it for you.
 # [x] you
 # [x.y] don't
 # [x.y.z] need these
 [x.y.z.w] # for this to work
 ################################################################################
 ## Inline Table
 # Inline tables provide a more compact syntax for expressing tables. They are
 # especially useful for grouped data that can otherwise quickly become verbose.
 # Inline tables are enclosed in curly braces `{` and `}`. No newlines are
 # allowed between the curly braces unless they are valid within a value.
 [table.inline]
 name = { first = "Tom", last = "Preston-Werner" }
 point = { x = 1, y = 2 }
 ################################################################################
 ## String
 # There are four ways to express strings: basic, multi-line basic, literal, and
 # multi-line literal. All strings must contain only valid UTF-8 characters.
 [string.basic]
 basic = "I'm a string. \"You can quote me\". Name\tJos\u00E9\nLocation\tSF."
 [string.multiline]
 # The following strings are byte-for-byte equivalent:
 key1 = "One\nTwo"
 key2 = """One\nTwo"""
 key3 = """
 One
 Two"""
 [string.multiline.continued]
 # The following strings are byte-for-byte equivalent:
 key1 = "The quick brown fox jumps over the lazy dog."
 key2 = """
 The quick brown \
  fox jumps over \
    the lazy dog."""
 key3 = """\
       The quick brown \
       fox jumps over \
       the lazy dog.\
       """
 [string.literal]
 # What you see is what you get.
 winpath  = 'C:\Users\nodejs\templates'
 winpath2 = '\\ServerX\admin$\system32\'
 quoted   = 'Tom "Dubs" Preston-Werner'
 regex    = '<\i\c*\s*>'
 [string.literal.multiline]
 regex2 = '''I [dw]on't need \d{2} apples'''
 lines  = '''
 The first newline is
 trimmed in raw strings.
   All other whitespace
   is preserved.
 '''
 ################################################################################
 ## Integer
 # Integers are whole numbers. Positive numbers may be prefixed with a plus sign.
 # Negative numbers are prefixed with a minus sign.
 [integer]
 key1 = +99
 key2 = 42
 key3 = 0
 key4 = -17
 [integer.underscores]
 # For large numbers, you may use underscores to enhance readability. Each
 # underscore must be surrounded by at least one digit.
 key1 = 1_000
 key2 = 5_349_221
 key3 = 1_2_3_4_5     # valid but inadvisable
 ################################################################################
 ## Float
 # A float consists of an integer part (which may be prefixed with a plus or
 # minus sign) followed by a fractional part and/or an exponent part.
 [float.fractional]
 key1 = +1.0
 key2 = 3.1415
 key3 = -0.01
 [float.exponent]
 key1 = 5e+22
 key2 = 1e6
 key3 = -2E-2
 [float.both]
 key = 6.626e-34
 [float.underscores]
 key1 = 9_224_617.445_991_228_313
 key2 = 1e1_00
 ################################################################################
 ## Boolean
 # Booleans are just the tokens you're used to. Always lowercase.
 [boolean]
 True = true
 False = false
 ################################################################################
 ## Datetime
 # Datetimes are RFC 3339 dates.
 [datetime]
 key1 = 1979-05-27T07:32:00Z
 key2 = 1979-05-27T00:32:00-07:00
 key3 = 1979-05-27T00:32:00.999999-07:00
 ################################################################################
 ## Array
 # Arrays are square brackets with other primitives inside. Whitespace is
 # ignored. Elements are separated by commas. Data types may not be mixed.
 [array]
 key1 = [ 1, 2, 3 ]
 key2 = [ "red", "yellow", "green" ]
 key3 = [ [ 1, 2 ], [3, 4, 5] ]
 #key4 = [ [ 1, 2 ], ["a", "b", "c"] ] # this is ok
 # Arrays can also be multiline. So in addition to ignoring whitespace, arrays
 # also ignore newlines between the brackets.  Terminating commas are ok before
 # the closing bracket.
 key5 = [
  1, 2, 3
 ]
 key6 = [
  1,
  2, # this is ok
 ]
 ################################################################################
 ## Array of Tables
 # These can be expressed by using a table name in double brackets. Each table
 # with the same double bracketed name will be an element in the array. The
 # tables are inserted in the order encountered.
 [[products]]
 name = "Hammer"
 sku = 738594937
 [[products]]
 [[products]]
 name = "Nail"
 sku = 284758393
 color = "gray"
 # You can create nested arrays of tables as well.
 [[fruit]]
  name = "apple"
  [fruit.physical]
    color = "red"
    shape = "round"
  [[fruit.variety]]
    name = "red delicious"
  [[fruit.variety]]
    name = "granny smith"
 [[fruit]]
  name = "banana"
  [[fruit.variety]]
    name = "plantain"
@@ -0,0 +1,121 @@
 ---
 array:
  key1:
  - 1
  - 2
  - 3
  key2:
  - red
  - yellow
  - green
  key3:
  - - 1
    - 2
  - - 3
    - 4
    - 5
  key4:
  - - 1
    - 2
  - - a
    - b
    - c
  key5:
  - 1
  - 2
  - 3
  key6:
  - 1
  - 2
 boolean:
  'False': false
  'True': true
 datetime:
  key1: '1979-05-27T07:32:00Z'
  key2: '1979-05-27T00:32:00-07:00'
  key3: '1979-05-27T00:32:00.999999-07:00'
 float:
  both:
    key: 6.626e-34
  exponent:
    key1: 5.0e+22
    key2: 1000000
    key3: -0.02
  fractional:
    key1: 1
    key2: 3.1415
    key3: -0.01
  underscores:
    key1: 9224617.445991227
    key2: 1.0e+100
 fruit:
 - name: apple
  physical:
    color: red
    shape: round
  variety:
  - name: red delicious
  - name: granny smith
 - name: banana
  variety:
  - name: plantain
 integer:
  key1: 99
  key2: 42
  key3: 0
  key4: -17
  underscores:
    key1: 1000
    key2: 5349221
    key3: 12345
 products:
 - name: Hammer
  sku: 738594937
 - {}
 - color: gray
  name: Nail
  sku: 284758393
 string:
  basic:
    basic: "I'm a string. \"You can quote me\". Name\tJosé\nLocation\tSF."
  literal:
    multiline:
      lines: |
        The first newline is
        trimmed in raw strings.
           All other whitespace
           is preserved.
      regex2: I [dw]on't need \d{2} apples
    quoted: Tom "Dubs" Preston-Werner
    regex: "<\\i\\c*\\s*>"
    winpath: C:\Users\nodejs\templates
    winpath2: "\\\\ServerX\\admin$\\system32\\"
  multiline:
    continued:
      key1: The quick brown fox jumps over the lazy dog.
      key2: The quick brown fox jumps over the lazy dog.
      key3: The quick brown fox jumps over the lazy dog.
    key1: |-
      One
      Two
    key2: |-
      One
      Two
    key3: |-
      One
      Two
 table:
  inline:
    name:
      first: Tom
      last: Preston-Werner
    point:
      x: 1
      y: 2
  key: value
  subtable:
    key: another value
 x:
  y:
    z:
      w: {}
@@ -0,0 +1,192 @@
 package toml
 import (
 	"bytes"
 	"encoding/json"
 	"io/ioutil"
 	"testing"
 	"time"
 	burntsushi "github.com/BurntSushi/toml"
 	yaml "gopkg.in/yaml.v2"
 )
 type benchmarkDoc struct {
 	Table struct {
 		Key      string
 		Subtable struct {
 			Key string
 		}
 		Inline struct {
 			Name struct {
 				First string
 				Last  string
 			}
 			Point struct {
 				X int64
 				U int64
 			}
 		}
 	}
 	String struct {
 		Basic struct {
 			Basic string
 		}
 		Multiline struct {
 			Key1      string
 			Key2      string
 			Key3      string
 			Continued struct {
 				Key1 string
 				Key2 string
 				Key3 string
 			}
 		}
 		Literal struct {
 			Winpath   string
 			Winpath2  string
 			Quoted    string
 			Regex     string
 			Multiline struct {
 				Regex2 string
 				Lines  string
 			}
 		}
 	}
 	Integer struct {
 		Key1        int64
 		Key2        int64
 		Key3        int64
 		Key4        int64
 		Underscores struct {
 			Key1 int64
 			Key2 int64
 			Key3 int64
 		}
 	}
 	Float struct {
 		Fractional struct {
 			Key1 float64
 			Key2 float64
 			Key3 float64
 		}
 		Exponent struct {
 			Key1 float64
 			Key2 float64
 			Key3 float64
 		}
 		Both struct {
 			Key float64
 		}
 		Underscores struct {
 			Key1 float64
 			Key2 float64
 		}
 	}
 	Boolean struct {
 		True  bool
 		False bool
 	}
 	Datetime struct {
 		Key1 time.Time
 		Key2 time.Time
 		Key3 time.Time
 	}
 	Array struct {
 		Key1 []int64
 		Key2 []string
 		Key3 [][]int64
 		// TODO: Key4 not supported by go-toml's Unmarshal
 		Key5 []int64
 		Key6 []int64
 	}
 	Products []struct {
 		Name  string
 		Sku   int64
 		Color string
 	}
 	Fruit []struct {
 		Name     string
 		Physical struct {
 			Color   string
 			Shape   string
 			Variety []struct {
 				Name string
 			}
 		}
 	}
 }
 func BenchmarkParseToml(b *testing.B) {
 	fileBytes, err := ioutil.ReadFile("benchmark.toml")
 	if err != nil {
 		b.Fatal(err)
 	}
 	b.ResetTimer()
 	for i := 0; i < b.N; i++ {
 		_, err := LoadReader(bytes.NewReader(fileBytes))
 		if err != nil {
 			b.Fatal(err)
 		}
 	}
 }
 func BenchmarkUnmarshalToml(b *testing.B) {
 	bytes, err := ioutil.ReadFile("benchmark.toml")
 	if err != nil {
 		b.Fatal(err)
 	}
 	b.ResetTimer()
 	for i := 0; i < b.N; i++ {
 		target := benchmarkDoc{}
 		err := Unmarshal(bytes, &target)
 		if err != nil {
 			b.Fatal(err)
 		}
 	}
 }
 func BenchmarkUnmarshalBurntSushiToml(b *testing.B) {
 	bytes, err := ioutil.ReadFile("benchmark.toml")
 	if err != nil {
 		b.Fatal(err)
 	}
 	b.ResetTimer()
 	for i := 0; i < b.N; i++ {
 		target := benchmarkDoc{}
 		err := burntsushi.Unmarshal(bytes, &target)
 		if err != nil {
 			b.Fatal(err)
 		}
 	}
 }
 func BenchmarkUnmarshalJson(b *testing.B) {
 	bytes, err := ioutil.ReadFile("benchmark.json")
 	if err != nil {
 		b.Fatal(err)
 	}
 	b.ResetTimer()
 	for i := 0; i < b.N; i++ {
 		target := benchmarkDoc{}
 		err := json.Unmarshal(bytes, &target)
 		if err != nil {
 			b.Fatal(err)
 		}
 	}
 }
 func BenchmarkUnmarshalYaml(b *testing.B) {
 	bytes, err := ioutil.ReadFile("benchmark.yml")
 	if err != nil {
 		b.Fatal(err)
 	}
 	b.ResetTimer()
 	for i := 0; i < b.N; i++ {
 		target := benchmarkDoc{}
 		err := yaml.Unmarshal(bytes, &target)
 		if err != nil {
 			b.Fatal(err)
 		}
 	}
 }
@@ -1,6 +0,0 @@
 #!/bin/bash
 # fail out of the script if anything here fails
 set -e
 # clear out stuff generated by test.sh
 rm -rf src test_program_bin toml-test
@@ -3,34 +3,37 @@ package main
 import (
 	"encoding/json"
 	"fmt"
 	"github.com/pelletier/go-toml"
 	"io/ioutil"
 	"log"
 	"os"
 	"time"
 	"github.com/pelletier/go-toml"
 )
 func main() {
 	bytes, err := ioutil.ReadAll(os.Stdin)
 	if err != nil {
 		log.Fatalf("Error during TOML read: %s", err)
 		os.Exit(2)
 	}
 	tree, err := toml.Load(string(bytes))
 	if err != nil {
 		log.Fatalf("Error during TOML load: %s", err)
 		os.Exit(1)
 	}
-	typedTree := translate((map[string]interface{})(*tree))
+	typedTree := translate(*tree)
 	if err := json.NewEncoder(os.Stdout).Encode(typedTree); err != nil {
 		log.Fatalf("Error encoding JSON: %s", err)
 		os.Exit(3)
 	}
 	os.Exit(0)
 }
 func translate(tomlData interface{}) interface{} {
 	switch orig := tomlData.(type) {
 	case map[string]interface{}:
 		typed := make(map[string]interface{}, len(orig))
@@ -38,9 +41,16 @@ func translate(tomlData interface{}) interface{} {
 			typed[k] = translate(v)
 		}
 		return typed
-	case *toml.TomlTree:
+	case *toml.Tree:
-		return translate((map[string]interface{})(*orig))
+		return translate(*orig)
-	case []*toml.TomlTree:
+	case toml.Tree:
 		keys := orig.Keys()
 		typed := make(map[string]interface{}, len(keys))
 		for _, k := range keys {
 			typed[k] = translate(orig.GetPath([]string{k}))
 		}
 		return typed
 	case []*toml.Tree:
 		typed := make([]map[string]interface{}, len(orig))
 		for i, v := range orig {
 			typed[i] = translate(v).(map[string]interface{})
@@ -0,0 +1,71 @@
 // Tomljson reads TOML and converts to JSON.
 //
 // Usage:
 //   cat file.toml | tomljson > file.json
 //   tomljson file1.toml > file.json
 package main
 import (
 	"encoding/json"
 	"flag"
 	"fmt"
 	"io"
 	"os"
 	"github.com/pelletier/go-toml"
 )
 func main() {
 	flag.Usage = func() {
 		fmt.Fprintln(os.Stderr, "tomljson can be used in two ways:")
 		fmt.Fprintln(os.Stderr, "Writing to STDIN and reading from STDOUT:")
 		fmt.Fprintln(os.Stderr, "  cat file.toml | tomljson > file.json")
 		fmt.Fprintln(os.Stderr, "")
 		fmt.Fprintln(os.Stderr, "Reading from a file name:")
 		fmt.Fprintln(os.Stderr, "  tomljson file.toml")
 	}
 	flag.Parse()
 	os.Exit(processMain(flag.Args(), os.Stdin, os.Stdout, os.Stderr))
 }
 func processMain(files []string, defaultInput io.Reader, output io.Writer, errorOutput io.Writer) int {
 	// read from stdin and print to stdout
 	inputReader := defaultInput
 	if len(files) > 0 {
 		var err error
 		inputReader, err = os.Open(files[0])
 		if err != nil {
 			printError(err, errorOutput)
 			return -1
 		}
 	}
 	s, err := reader(inputReader)
 	if err != nil {
 		printError(err, errorOutput)
 		return -1
 	}
 	io.WriteString(output, s+"\n")
 	return 0
 }
 func printError(err error, output io.Writer) {
 	io.WriteString(output, err.Error()+"\n")
 }
 func reader(r io.Reader) (string, error) {
 	tree, err := toml.LoadReader(r)
 	if err != nil {
 		return "", err
 	}
 	return mapToJSON(tree)
 }
 func mapToJSON(tree *toml.Tree) (string, error) {
 	treeMap := tree.ToMap()
 	bytes, err := json.MarshalIndent(treeMap, "", "  ")
 	if err != nil {
 		return "", err
 	}
 	return string(bytes[:]), nil
 }
@@ -0,0 +1,82 @@
 package main
 import (
 	"bytes"
 	"io/ioutil"
 	"os"
 	"strings"
 	"testing"
 )
 func expectBufferEquality(t *testing.T, name string, buffer *bytes.Buffer, expected string) {
 	output := buffer.String()
 	if output != expected {
 		t.Errorf("incorrect %s:\n%s\n\nexpected %s:\n%s", name, output, name, expected)
 		t.Log([]rune(output))
 		t.Log([]rune(expected))
 	}
 }
 func expectProcessMainResults(t *testing.T, input string, args []string, exitCode int, expectedOutput string, expectedError string) {
 	inputReader := strings.NewReader(input)
 	outputBuffer := new(bytes.Buffer)
 	errorBuffer := new(bytes.Buffer)
 	returnCode := processMain(args, inputReader, outputBuffer, errorBuffer)
 	expectBufferEquality(t, "output", outputBuffer, expectedOutput)
 	expectBufferEquality(t, "error", errorBuffer, expectedError)
 	if returnCode != exitCode {
 		t.Error("incorrect return code:", returnCode, "expected", exitCode)
 	}
 }
 func TestProcessMainReadFromStdin(t *testing.T) {
 	input := `
 		[mytoml]
 		a = 42`
 	expectedOutput := `{
  "mytoml": {
    "a": 42
  }
 }
 `
 	expectedError := ``
 	expectedExitCode := 0
 	expectProcessMainResults(t, input, []string{}, expectedExitCode, expectedOutput, expectedError)
 }
 func TestProcessMainReadFromFile(t *testing.T) {
 	input := `
 		[mytoml]
 		a = 42`
 	tmpfile, err := ioutil.TempFile("", "example.toml")
 	if err != nil {
 		t.Fatal(err)
 	}
 	if _, err := tmpfile.Write([]byte(input)); err != nil {
 		t.Fatal(err)
 	}
 	defer os.Remove(tmpfile.Name())
 	expectedOutput := `{
  "mytoml": {
    "a": 42
  }
 }
 `
 	expectedError := ``
 	expectedExitCode := 0
 	expectProcessMainResults(t, ``, []string{tmpfile.Name()}, expectedExitCode, expectedOutput, expectedError)
 }
 func TestProcessMainReadFromMissingFile(t *testing.T) {
 	expectedError := `open /this/file/does/not/exist: no such file or directory
 `
 	expectProcessMainResults(t, ``, []string{"/this/file/does/not/exist"}, -1, ``, expectedError)
 }
@@ -0,0 +1,65 @@
 // Tomll is a linter for TOML
 //
 // Usage:
 //   cat file.toml | tomll > file_linted.toml
 //   tomll file1.toml file2.toml # lint the two files in place
 package main
 import (
 	"flag"
 	"fmt"
 	"io"
 	"io/ioutil"
 	"os"
 	"github.com/pelletier/go-toml"
 )
 func main() {
 	flag.Usage = func() {
 		fmt.Fprintln(os.Stderr, "tomll can be used in two ways:")
 		fmt.Fprintln(os.Stderr, "Writing to STDIN and reading from STDOUT:")
 		fmt.Fprintln(os.Stderr, "  cat file.toml | tomll > file.toml")
 		fmt.Fprintln(os.Stderr, "")
 		fmt.Fprintln(os.Stderr, "Reading and updating a list of files:")
 		fmt.Fprintln(os.Stderr, "  tomll a.toml b.toml c.toml")
 		fmt.Fprintln(os.Stderr, "")
 		fmt.Fprintln(os.Stderr, "When given a list of files, tomll will modify all files in place without asking.")
 	}
 	flag.Parse()
 	// read from stdin and print to stdout
 	if flag.NArg() == 0 {
 		s, err := lintReader(os.Stdin)
 		if err != nil {
 			io.WriteString(os.Stderr, err.Error())
 			os.Exit(-1)
 		}
 		io.WriteString(os.Stdout, s)
 	} else {
 		// otherwise modify a list of files
 		for _, filename := range flag.Args() {
 			s, err := lintFile(filename)
 			if err != nil {
 				io.WriteString(os.Stderr, err.Error())
 				os.Exit(-1)
 			}
 			ioutil.WriteFile(filename, []byte(s), 0644)
 		}
 	}
 }
 func lintFile(filename string) (string, error) {
 	tree, err := toml.LoadFile(filename)
 	if err != nil {
 		return "", err
 	}
 	return tree.String(), nil
 }
 func lintReader(r io.Reader) (string, error) {
 	tree, err := toml.LoadReader(r)
 	if err != nil {
 		return "", err
 	}
 	return tree.String(), nil
 }
@@ -0,0 +1,23 @@
 // Package toml is a TOML parser and manipulation library.
 //
 // This version supports the specification as described in
 // https://github.com/toml-lang/toml/blob/master/versions/en/toml-v0.4.0.md
 //
 // Marshaling
 //
 // Go-toml can marshal and unmarshal TOML documents from and to data
 // structures.
 //
 // TOML document as a tree
 //
 // Go-toml can operate on a TOML document as a tree. Use one of the Load*
 // functions to parse TOML data and obtain a Tree instance, then one of its
 // methods to manipulate the tree.
 //
 // JSONPath-like queries
 //
 // The package github.com/pelletier/go-toml/query implements a system
 // similar to JSONPath to quickly retrieve elements of a TOML document using a
 // single expression. See the package documentation for more information.
 //
 package toml
@@ -0,0 +1,105 @@
 // code examples for godoc
 package toml_test
 import (
 	"fmt"
 	"log"
 	toml "github.com/pelletier/go-toml"
 )
 func Example_tree() {
 	config, err := toml.LoadFile("config.toml")
 	if err != nil {
 		fmt.Println("Error ", err.Error())
 	} else {
 		// retrieve data directly
 		user := config.Get("postgres.user").(string)
 		password := config.Get("postgres.password").(string)
 		// or using an intermediate object
 		configTree := config.Get("postgres").(*toml.Tree)
 		user = configTree.Get("user").(string)
 		password = configTree.Get("password").(string)
 		fmt.Println("User is", user, " and password is", password)
 		// show where elements are in the file
 		fmt.Printf("User position: %v\n", configTree.GetPosition("user"))
 		fmt.Printf("Password position: %v\n", configTree.GetPosition("password"))
 	}
 }
 func Example_unmarshal() {
 	type Employer struct {
 		Name  string
 		Phone string
 	}
 	type Person struct {
 		Name     string
 		Age      int64
 		Employer Employer
 	}
 	document := []byte(`
 	name = "John"
 	age = 30
 	[employer]
 		name = "Company Inc."
 		phone = "+1 234 567 89012"
 	`)
 	person := Person{}
 	toml.Unmarshal(document, &person)
 	fmt.Println(person.Name, "is", person.Age, "and works at", person.Employer.Name)
 	// Output:
 	// John is 30 and works at Company Inc.
 }
 func ExampleMarshal() {
 	type Postgres struct {
 		User     string `toml:"user"`
 		Password string `toml:"password"`
 		Database string `toml:"db" commented:"true" comment:"not used anymore"`
 	}
 	type Config struct {
 		Postgres Postgres `toml:"postgres" comment:"Postgres configuration"`
 	}
 	config := Config{Postgres{User: "pelletier", Password: "mypassword", Database: "old_database"}}
 	b, err := toml.Marshal(config)
 	if err != nil {
 		log.Fatal(err)
 	}
 	fmt.Println(string(b))
 	// Output:
 	// # Postgres configuration
 	// [postgres]
 	//
 	//   # not used anymore
 	//   # db = "old_database"
 	//   password = "mypassword"
 	//   user = "pelletier"
 }
 func ExampleUnmarshal() {
 	type Postgres struct {
 		User     string
 		Password string
 	}
 	type Config struct {
 		Postgres Postgres
 	}
 	doc := []byte(`
 	[postgres]
 	user = "pelletier"
 	password = "mypassword"`)
 	config := Config{}
 	toml.Unmarshal(doc, &config)
 	fmt.Println("user=", config.Postgres.User)
 	// Output:
 	// user= pelletier
 }
@@ -0,0 +1,29 @@
 # This is a TOML document. Boom.
 title = "TOML Example"
 [owner]
 name = "Tom Preston-Werner"
 organization = "GitHub"
 bio = "GitHub Cofounder & CEO\nLikes tater tots and beer."
 dob = 1979-05-27T07:32:00Z # First class dates? Why not?
 [database]
 server = "192.168.1.1"
 ports = [ 8001, 8001, 8002 ]
 connection_max = 5000
 enabled = true
 [servers]
  # You can indent as you please. Tabs or spaces. TOML don't care.
  [servers.alpha]
  ip = "10.0.0.1"
  dc = "eqdc10"
  [servers.beta]
  ip = "10.0.0.2"
  dc = "eqdc10"
 [clients]
 data = [ ["gamma", "delta"], [1, 2] ] # just an update to make sure parsers support it
@@ -0,0 +1,31 @@
 // +build gofuzz
 package toml
 func Fuzz(data []byte) int {
 	tree, err := LoadBytes(data)
 	if err != nil {
 		if tree != nil {
 			panic("tree must be nil if there is an error")
 		}
 		return 0
 	}
 	str, err := tree.ToTomlString()
 	if err != nil {
 		if str != "" {
 			panic(`str must be "" if there is an error`)
 		}
 		panic(err)
 	}
 	tree, err = Load(str)
 	if err != nil {
 		if tree != nil {
 			panic("tree must be nil if there is an error")
 		}
 		return 0
 	}
 	return 1
 }
@@ -0,0 +1,15 @@
 #! /bin/sh
 set -eu
 go get github.com/dvyukov/go-fuzz/go-fuzz
 go get github.com/dvyukov/go-fuzz/go-fuzz-build
 if [ ! -e toml-fuzz.zip ]; then
    go-fuzz-build github.com/pelletier/go-toml
 fi
 rm -fr fuzz
 mkdir -p fuzz/corpus
 cp *.toml fuzz/corpus
 go-fuzz -bin=toml-fuzz.zip -workdir=fuzz
@@ -0,0 +1,85 @@
 // Parsing keys handling both bare and quoted keys.
 package toml
 import (
 	"bytes"
 	"errors"
 	"fmt"
 	"unicode"
 )
 // Convert the bare key group string to an array.
 // The input supports double quotation to allow "." inside the key name,
 // but escape sequences are not supported. Lexers must unescape them beforehand.
 func parseKey(key string) ([]string, error) {
 	groups := []string{}
 	var buffer bytes.Buffer
 	inQuotes := false
 	wasInQuotes := false
 	ignoreSpace := true
 	expectDot := false
 	for _, char := range key {
 		if ignoreSpace {
 			if char == ' ' {
 				continue
 			}
 			ignoreSpace = false
 		}
 		switch char {
 		case '"':
 			if inQuotes {
 				groups = append(groups, buffer.String())
 				buffer.Reset()
 				wasInQuotes = true
 			}
 			inQuotes = !inQuotes
 			expectDot = false
 		case '.':
 			if inQuotes {
 				buffer.WriteRune(char)
 			} else {
 				if !wasInQuotes {
 					if buffer.Len() == 0 {
 						return nil, errors.New("empty table key")
 					}
 					groups = append(groups, buffer.String())
 					buffer.Reset()
 				}
 				ignoreSpace = true
 				expectDot = false
 				wasInQuotes = false
 			}
 		case ' ':
 			if inQuotes {
 				buffer.WriteRune(char)
 			} else {
 				expectDot = true
 			}
 		default:
 			if !inQuotes && !isValidBareChar(char) {
 				return nil, fmt.Errorf("invalid bare character: %c", char)
 			}
 			if !inQuotes && expectDot {
 				return nil, errors.New("what?")
 			}
 			buffer.WriteRune(char)
 			expectDot = false
 		}
 	}
 	if inQuotes {
 		return nil, errors.New("mismatched quotes")
 	}
 	if buffer.Len() > 0 {
 		groups = append(groups, buffer.String())
 	}
 	if len(groups) == 0 {
 		return nil, errors.New("empty key")
 	}
 	return groups, nil
 }
 func isValidBareChar(r rune) bool {
 	return isAlphanumeric(r) || r == '-' || unicode.IsNumber(r)
 }
@@ -0,0 +1,63 @@
 package toml
 import (
 	"fmt"
 	"testing"
 )
 func testResult(t *testing.T, key string, expected []string) {
 	parsed, err := parseKey(key)
 	t.Logf("key=%s expected=%s parsed=%s", key, expected, parsed)
 	if err != nil {
 		t.Fatal("Unexpected error:", err)
 	}
 	if len(expected) != len(parsed) {
 		t.Fatal("Expected length", len(expected), "but", len(parsed), "parsed")
 	}
 	for index, expectedKey := range expected {
 		if expectedKey != parsed[index] {
 			t.Fatal("Expected", expectedKey, "at index", index, "but found", parsed[index])
 		}
 	}
 }
 func testError(t *testing.T, key string, expectedError string) {
 	res, err := parseKey(key)
 	if err == nil {
 		t.Fatalf("Expected error, but succesfully parsed key %s", res)
 	}
 	if fmt.Sprintf("%s", err) != expectedError {
 		t.Fatalf("Expected error \"%s\", but got \"%s\".", expectedError, err)
 	}
 }
 func TestBareKeyBasic(t *testing.T) {
 	testResult(t, "test", []string{"test"})
 }
 func TestBareKeyDotted(t *testing.T) {
 	testResult(t, "this.is.a.key", []string{"this", "is", "a", "key"})
 }
 func TestDottedKeyBasic(t *testing.T) {
 	testResult(t, "\"a.dotted.key\"", []string{"a.dotted.key"})
 }
 func TestBaseKeyPound(t *testing.T) {
 	testError(t, "hello#world", "invalid bare character: #")
 }
 func TestQuotedKeys(t *testing.T) {
 	testResult(t, `hello."foo".bar`, []string{"hello", "foo", "bar"})
 	testResult(t, `"hello!"`, []string{"hello!"})
 	testResult(t, `foo."ba.r".baz`, []string{"foo", "ba.r", "baz"})
 	// escape sequences must not be converted
 	testResult(t, `"hello\tworld"`, []string{`hello\tworld`})
 }
 func TestEmptyKey(t *testing.T) {
 	testError(t, "", "empty key")
 	testError(t, " ", "empty key")
 	testResult(t, `""`, []string{""})
 }
@@ -1,415 +1,750 @@
 package toml
-import "testing"
+import (
 	"reflect"
 	"testing"
 )
 func testFlow(t *testing.T, input string, expectedFlow []token) {
-	_, ch := lex(input)
+	tokens := lexToml([]byte(input))
-	for _, expected := range expectedFlow {
+	if !reflect.DeepEqual(tokens, expectedFlow) {
-		token := <-ch
+		t.Fatal("Different flows. Expected\n", expectedFlow, "\nGot:\n", tokens)
 		if token != expected {
 			t.Log("compared", token, "to", expected)
 			t.Log(token.val, "<->", expected.val)
 			t.Log(token.typ, "<->", expected.typ)
 			t.FailNow()
 		}
 	}
 	tok, ok := <-ch
 	if ok {
 		t.Log("channel is not closed!")
 		t.Log(len(ch)+1, "tokens remaining:")
 		t.Log("token ->", tok)
 		for token := range ch {
 			t.Log("token ->", token)
 		}
 		t.FailNow()
 	}
 }
 func TestValidKeyGroup(t *testing.T) {
 	testFlow(t, "[hello world]", []token{
-		token{tokenLeftBracket, "["},
+		{Position{1, 1}, tokenLeftBracket, "["},
-		token{tokenKeyGroup, "hello world"},
+		{Position{1, 2}, tokenKeyGroup, "hello world"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 13}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 14}, tokenEOF, ""},
 	})
 }
 func TestNestedQuotedUnicodeKeyGroup(t *testing.T) {
 	testFlow(t, `[ j . "ʞ" . l ]`, []token{
 		{Position{1, 1}, tokenLeftBracket, "["},
 		{Position{1, 2}, tokenKeyGroup, ` j . "ʞ" . l `},
 		{Position{1, 15}, tokenRightBracket, "]"},
 		{Position{1, 16}, tokenEOF, ""},
 	})
 }
 func TestUnclosedKeyGroup(t *testing.T) {
 	testFlow(t, "[hello world", []token{
-		token{tokenLeftBracket, "["},
+		{Position{1, 1}, tokenLeftBracket, "["},
-		token{tokenError, "unclosed key group"},
+		{Position{1, 2}, tokenError, "unclosed table key"},
 	})
 }
 func TestComment(t *testing.T) {
 	testFlow(t, "# blahblah", []token{
-		token{tokenEOF, ""},
+		{Position{1, 11}, tokenEOF, ""},
 	})
 }
 func TestKeyGroupComment(t *testing.T) {
 	testFlow(t, "[hello world] # blahblah", []token{
-		token{tokenLeftBracket, "["},
+		{Position{1, 1}, tokenLeftBracket, "["},
-		token{tokenKeyGroup, "hello world"},
+		{Position{1, 2}, tokenKeyGroup, "hello world"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 13}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 25}, tokenEOF, ""},
 	})
 }
 func TestMultipleKeyGroupsComment(t *testing.T) {
 	testFlow(t, "[hello world] # blahblah\n[test]", []token{
-		token{tokenLeftBracket, "["},
+		{Position{1, 1}, tokenLeftBracket, "["},
-		token{tokenKeyGroup, "hello world"},
+		{Position{1, 2}, tokenKeyGroup, "hello world"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 13}, tokenRightBracket, "]"},
-		token{tokenLeftBracket, "["},
+		{Position{2, 1}, tokenLeftBracket, "["},
-		token{tokenKeyGroup, "test"},
+		{Position{2, 2}, tokenKeyGroup, "test"},
-		token{tokenRightBracket, "]"},
+		{Position{2, 6}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{2, 7}, tokenEOF, ""},
 	})
 }
 func TestSimpleWindowsCRLF(t *testing.T) {
 	testFlow(t, "a=4\r\nb=2", []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 2}, tokenEqual, "="},
 		{Position{1, 3}, tokenInteger, "4"},
 		{Position{2, 1}, tokenKey, "b"},
 		{Position{2, 2}, tokenEqual, "="},
 		{Position{2, 3}, tokenInteger, "2"},
 		{Position{2, 4}, tokenEOF, ""},
 	})
 }
 func TestBasicKey(t *testing.T) {
 	testFlow(t, "hello", []token{
-		token{tokenKey, "hello"},
+		{Position{1, 1}, tokenKey, "hello"},
-		token{tokenEOF, ""},
+		{Position{1, 6}, tokenEOF, ""},
 	})
 }
 func TestBasicKeyWithUnderscore(t *testing.T) {
 	testFlow(t, "hello_hello", []token{
-		token{tokenKey, "hello_hello"},
+		{Position{1, 1}, tokenKey, "hello_hello"},
-		token{tokenEOF, ""},
+		{Position{1, 12}, tokenEOF, ""},
 	})
 }
 func TestBasicKeyWithDash(t *testing.T) {
 	testFlow(t, "hello-world", []token{
-		token{tokenKey, "hello-world"},
+		{Position{1, 1}, tokenKey, "hello-world"},
-		token{tokenEOF, ""},
+		{Position{1, 12}, tokenEOF, ""},
 	})
 }
 func TestBasicKeyWithUppercaseMix(t *testing.T) {
 	testFlow(t, "helloHELLOHello", []token{
-		token{tokenKey, "helloHELLOHello"},
+		{Position{1, 1}, tokenKey, "helloHELLOHello"},
-		token{tokenEOF, ""},
+		{Position{1, 16}, tokenEOF, ""},
 	})
 }
 func TestBasicKeyWithInternationalCharacters(t *testing.T) {
 	testFlow(t, "héllÖ", []token{
-		token{tokenKey, "héllÖ"},
+		{Position{1, 1}, tokenKey, "héllÖ"},
-		token{tokenEOF, ""},
+		{Position{1, 6}, tokenEOF, ""},
 	})
 }
 func TestBasicKeyAndEqual(t *testing.T) {
 	testFlow(t, "hello =", []token{
-		token{tokenKey, "hello"},
+		{Position{1, 1}, tokenKey, "hello"},
-		token{tokenEqual, "="},
+		{Position{1, 7}, tokenEqual, "="},
-		token{tokenEOF, ""},
+		{Position{1, 8}, tokenEOF, ""},
 	})
 }
 func TestKeyWithSharpAndEqual(t *testing.T) {
 	testFlow(t, "key#name = 5", []token{
-		token{tokenKey, "key#name"},
+		{Position{1, 1}, tokenError, "keys cannot contain # character"},
 		token{tokenEqual, "="},
 		token{tokenInteger, "5"},
 		token{tokenEOF, ""},
 	})
 }
 func TestKeyWithSymbolsAndEqual(t *testing.T) {
-	testFlow(t, "~!@#$^&*()_+-`1234567890[]\\|/?><.,;:' = 5", []token{
+	testFlow(t, "~!@$^&*()_+-`1234567890[]\\|/?><.,;:' = 5", []token{
-		token{tokenKey, "~!@#$^&*()_+-`1234567890[]\\|/?><.,;:'"},
+		{Position{1, 1}, tokenError, "keys cannot contain ~ character"},
 		token{tokenEqual, "="},
 		token{tokenInteger, "5"},
 		token{tokenEOF, ""},
 	})
 }
 func TestKeyEqualStringEscape(t *testing.T) {
-	testFlow(t, "foo = \"hello\\\"\"", []token{
+	testFlow(t, `foo = "hello\""`, []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenString, "hello\""},
+		{Position{1, 8}, tokenString, "hello\""},
-		token{tokenEOF, ""},
+		{Position{1, 16}, tokenEOF, ""},
 	})
 }
 func TestKeyEqualStringUnfinished(t *testing.T) {
-	testFlow(t, "foo = \"bar", []token{
+	testFlow(t, `foo = "bar`, []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenError, "unclosed string"},
+		{Position{1, 8}, tokenError, "unclosed string"},
 	})
 }
 func TestKeyEqualString(t *testing.T) {
-	testFlow(t, "foo = \"bar\"", []token{
+	testFlow(t, `foo = "bar"`, []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenString, "bar"},
+		{Position{1, 8}, tokenString, "bar"},
-		token{tokenEOF, ""},
+		{Position{1, 12}, tokenEOF, ""},
 	})
 }
 func TestKeyEqualTrue(t *testing.T) {
 	testFlow(t, "foo = true", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenTrue, "true"},
+		{Position{1, 7}, tokenTrue, "true"},
-		token{tokenEOF, ""},
+		{Position{1, 11}, tokenEOF, ""},
 	})
 }
 func TestKeyEqualFalse(t *testing.T) {
 	testFlow(t, "foo = false", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenFalse, "false"},
+		{Position{1, 7}, tokenFalse, "false"},
-		token{tokenEOF, ""},
+		{Position{1, 12}, tokenEOF, ""},
 	})
 }
 func TestArrayNestedString(t *testing.T) {
-	testFlow(t, "a = [ [\"hello\", \"world\"] ]", []token{
+	testFlow(t, `a = [ ["hello", "world"] ]`, []token{
-		token{tokenKey, "a"},
+		{Position{1, 1}, tokenKey, "a"},
-		token{tokenEqual, "="},
+		{Position{1, 3}, tokenEqual, "="},
-		token{tokenLeftBracket, "["},
+		{Position{1, 5}, tokenLeftBracket, "["},
-		token{tokenLeftBracket, "["},
+		{Position{1, 7}, tokenLeftBracket, "["},
-		token{tokenString, "hello"},
+		{Position{1, 9}, tokenString, "hello"},
-		token{tokenComma, ","},
+		{Position{1, 15}, tokenComma, ","},
-		token{tokenString, "world"},
+		{Position{1, 18}, tokenString, "world"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 24}, tokenRightBracket, "]"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 26}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 27}, tokenEOF, ""},
 	})
 }
 func TestArrayNestedInts(t *testing.T) {
 	testFlow(t, "a = [ [42, 21], [10] ]", []token{
-		token{tokenKey, "a"},
+		{Position{1, 1}, tokenKey, "a"},
-		token{tokenEqual, "="},
+		{Position{1, 3}, tokenEqual, "="},
-		token{tokenLeftBracket, "["},
+		{Position{1, 5}, tokenLeftBracket, "["},
-		token{tokenLeftBracket, "["},
+		{Position{1, 7}, tokenLeftBracket, "["},
-		token{tokenInteger, "42"},
+		{Position{1, 8}, tokenInteger, "42"},
-		token{tokenComma, ","},
+		{Position{1, 10}, tokenComma, ","},
-		token{tokenInteger, "21"},
+		{Position{1, 12}, tokenInteger, "21"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 14}, tokenRightBracket, "]"},
-		token{tokenComma, ","},
+		{Position{1, 15}, tokenComma, ","},
-		token{tokenLeftBracket, "["},
+		{Position{1, 17}, tokenLeftBracket, "["},
-		token{tokenInteger, "10"},
+		{Position{1, 18}, tokenInteger, "10"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 20}, tokenRightBracket, "]"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 22}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 23}, tokenEOF, ""},
 	})
 }
 func TestArrayInts(t *testing.T) {
 	testFlow(t, "a = [ 42, 21, 10, ]", []token{
-		token{tokenKey, "a"},
+		{Position{1, 1}, tokenKey, "a"},
-		token{tokenEqual, "="},
+		{Position{1, 3}, tokenEqual, "="},
-		token{tokenLeftBracket, "["},
+		{Position{1, 5}, tokenLeftBracket, "["},
-		token{tokenInteger, "42"},
+		{Position{1, 7}, tokenInteger, "42"},
-		token{tokenComma, ","},
+		{Position{1, 9}, tokenComma, ","},
-		token{tokenInteger, "21"},
+		{Position{1, 11}, tokenInteger, "21"},
-		token{tokenComma, ","},
+		{Position{1, 13}, tokenComma, ","},
-		token{tokenInteger, "10"},
+		{Position{1, 15}, tokenInteger, "10"},
-		token{tokenComma, ","},
+		{Position{1, 17}, tokenComma, ","},
-		token{tokenRightBracket, "]"},
+		{Position{1, 19}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 20}, tokenEOF, ""},
 	})
 }
 func TestMultilineArrayComments(t *testing.T) {
 	testFlow(t, "a = [1, # wow\n2, # such items\n3, # so array\n]", []token{
-		token{tokenKey, "a"},
+		{Position{1, 1}, tokenKey, "a"},
-		token{tokenEqual, "="},
+		{Position{1, 3}, tokenEqual, "="},
-		token{tokenLeftBracket, "["},
+		{Position{1, 5}, tokenLeftBracket, "["},
-		token{tokenInteger, "1"},
+		{Position{1, 6}, tokenInteger, "1"},
-		token{tokenComma, ","},
+		{Position{1, 7}, tokenComma, ","},
-		token{tokenInteger, "2"},
+		{Position{2, 1}, tokenInteger, "2"},
-		token{tokenComma, ","},
+		{Position{2, 2}, tokenComma, ","},
-		token{tokenInteger, "3"},
+		{Position{3, 1}, tokenInteger, "3"},
-		token{tokenComma, ","},
+		{Position{3, 2}, tokenComma, ","},
-		token{tokenRightBracket, "]"},
+		{Position{4, 1}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{4, 2}, tokenEOF, ""},
 	})
 }
 func TestNestedArraysComment(t *testing.T) {
 	toml := `
 someArray = [
 # does not work
 ["entry1"]
 ]`
 	testFlow(t, toml, []token{
 		{Position{2, 1}, tokenKey, "someArray"},
 		{Position{2, 11}, tokenEqual, "="},
 		{Position{2, 13}, tokenLeftBracket, "["},
 		{Position{4, 1}, tokenLeftBracket, "["},
 		{Position{4, 3}, tokenString, "entry1"},
 		{Position{4, 10}, tokenRightBracket, "]"},
 		{Position{5, 1}, tokenRightBracket, "]"},
 		{Position{5, 2}, tokenEOF, ""},
 	})
 }
 func TestKeyEqualArrayBools(t *testing.T) {
 	testFlow(t, "foo = [true, false, true]", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenLeftBracket, "["},
+		{Position{1, 7}, tokenLeftBracket, "["},
-		token{tokenTrue, "true"},
+		{Position{1, 8}, tokenTrue, "true"},
-		token{tokenComma, ","},
+		{Position{1, 12}, tokenComma, ","},
-		token{tokenFalse, "false"},
+		{Position{1, 14}, tokenFalse, "false"},
-		token{tokenComma, ","},
+		{Position{1, 19}, tokenComma, ","},
-		token{tokenTrue, "true"},
+		{Position{1, 21}, tokenTrue, "true"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 25}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 26}, tokenEOF, ""},
 	})
 }
 func TestKeyEqualArrayBoolsWithComments(t *testing.T) {
 	testFlow(t, "foo = [true, false, true] # YEAH", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenLeftBracket, "["},
+		{Position{1, 7}, tokenLeftBracket, "["},
-		token{tokenTrue, "true"},
+		{Position{1, 8}, tokenTrue, "true"},
-		token{tokenComma, ","},
+		{Position{1, 12}, tokenComma, ","},
-		token{tokenFalse, "false"},
+		{Position{1, 14}, tokenFalse, "false"},
-		token{tokenComma, ","},
+		{Position{1, 19}, tokenComma, ","},
-		token{tokenTrue, "true"},
+		{Position{1, 21}, tokenTrue, "true"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 25}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 33}, tokenEOF, ""},
 	})
 }
 func TestDateRegexp(t *testing.T) {
 	if dateRegexp.FindString("1979-05-27T07:32:00Z") == "" {
-		t.Fail()
+		t.Error("basic lexing")
 	}
 	if dateRegexp.FindString("1979-05-27T00:32:00-07:00") == "" {
 		t.Error("offset lexing")
 	}
 	if dateRegexp.FindString("1979-05-27T00:32:00.999999-07:00") == "" {
 		t.Error("nano precision lexing")
 	}
 }
 func TestKeyEqualDate(t *testing.T) {
 	testFlow(t, "foo = 1979-05-27T07:32:00Z", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenDate, "1979-05-27T07:32:00Z"},
+		{Position{1, 7}, tokenDate, "1979-05-27T07:32:00Z"},
-		token{tokenEOF, ""},
+		{Position{1, 27}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = 1979-05-27T00:32:00-07:00", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 7}, tokenDate, "1979-05-27T00:32:00-07:00"},
 		{Position{1, 32}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = 1979-05-27T00:32:00.999999-07:00", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 7}, tokenDate, "1979-05-27T00:32:00.999999-07:00"},
 		{Position{1, 39}, tokenEOF, ""},
 	})
 }
 func TestFloatEndingWithDot(t *testing.T) {
 	testFlow(t, "foo = 42.", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenError, "float cannot end with a dot"},
+		{Position{1, 7}, tokenError, "float cannot end with a dot"},
 	})
 }
 func TestFloatWithTwoDots(t *testing.T) {
 	testFlow(t, "foo = 4.2.", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenError, "cannot have two dots in one float"},
+		{Position{1, 7}, tokenError, "cannot have two dots in one float"},
 	})
 }
-func TestDoubleEqualKey(t *testing.T) {
+func TestFloatWithExponent1(t *testing.T) {
-	testFlow(t, "foo= = 2", []token{
+	testFlow(t, "a = 5e+22", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "a"},
-		token{tokenEqual, "="},
+		{Position{1, 3}, tokenEqual, "="},
-		token{tokenError, "cannot have multiple equals for the same key"},
+		{Position{1, 5}, tokenFloat, "5e+22"},
 		{Position{1, 10}, tokenEOF, ""},
 	})
 }
 func TestFloatWithExponent2(t *testing.T) {
 	testFlow(t, "a = 5E+22", []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 3}, tokenEqual, "="},
 		{Position{1, 5}, tokenFloat, "5E+22"},
 		{Position{1, 10}, tokenEOF, ""},
 	})
 }
 func TestFloatWithExponent3(t *testing.T) {
 	testFlow(t, "a = -5e+22", []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 3}, tokenEqual, "="},
 		{Position{1, 5}, tokenFloat, "-5e+22"},
 		{Position{1, 11}, tokenEOF, ""},
 	})
 }
 func TestFloatWithExponent4(t *testing.T) {
 	testFlow(t, "a = -5e-22", []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 3}, tokenEqual, "="},
 		{Position{1, 5}, tokenFloat, "-5e-22"},
 		{Position{1, 11}, tokenEOF, ""},
 	})
 }
 func TestFloatWithExponent5(t *testing.T) {
 	testFlow(t, "a = 6.626e-34", []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 3}, tokenEqual, "="},
 		{Position{1, 5}, tokenFloat, "6.626e-34"},
 		{Position{1, 14}, tokenEOF, ""},
 	})
 }
 func TestInvalidEsquapeSequence(t *testing.T) {
-	testFlow(t, "foo = \"\\x\"", []token{
+	testFlow(t, `foo = "\x"`, []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenError, "invalid escape sequence: \\x"},
+		{Position{1, 8}, tokenError, "invalid escape sequence: \\x"},
 	})
 }
 func TestNestedArrays(t *testing.T) {
 	testFlow(t, "foo = [[[]]]", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenLeftBracket, "["},
+		{Position{1, 7}, tokenLeftBracket, "["},
-		token{tokenLeftBracket, "["},
+		{Position{1, 8}, tokenLeftBracket, "["},
-		token{tokenLeftBracket, "["},
+		{Position{1, 9}, tokenLeftBracket, "["},
-		token{tokenRightBracket, "]"},
+		{Position{1, 10}, tokenRightBracket, "]"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 11}, tokenRightBracket, "]"},
-		token{tokenRightBracket, "]"},
+		{Position{1, 12}, tokenRightBracket, "]"},
-		token{tokenEOF, ""},
+		{Position{1, 13}, tokenEOF, ""},
 	})
 }
 func TestKeyEqualNumber(t *testing.T) {
 	testFlow(t, "foo = 42", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenInteger, "42"},
+		{Position{1, 7}, tokenInteger, "42"},
-		token{tokenEOF, ""},
+		{Position{1, 9}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = +42", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenInteger, "+42"},
+		{Position{1, 7}, tokenInteger, "+42"},
-		token{tokenEOF, ""},
+		{Position{1, 10}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = -42", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenInteger, "-42"},
+		{Position{1, 7}, tokenInteger, "-42"},
-		token{tokenEOF, ""},
+		{Position{1, 10}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = 4.2", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenFloat, "4.2"},
+		{Position{1, 7}, tokenFloat, "4.2"},
-		token{tokenEOF, ""},
+		{Position{1, 10}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = +4.2", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenFloat, "+4.2"},
+		{Position{1, 7}, tokenFloat, "+4.2"},
-		token{tokenEOF, ""},
+		{Position{1, 11}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = -4.2", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenFloat, "-4.2"},
+		{Position{1, 7}, tokenFloat, "-4.2"},
-		token{tokenEOF, ""},
+		{Position{1, 11}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = 1_000", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 7}, tokenInteger, "1_000"},
 		{Position{1, 12}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = 5_349_221", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 7}, tokenInteger, "5_349_221"},
 		{Position{1, 16}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = 1_2_3_4_5", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 7}, tokenInteger, "1_2_3_4_5"},
 		{Position{1, 16}, tokenEOF, ""},
 	})
 	testFlow(t, "flt8 = 9_224_617.445_991_228_313", []token{
 		{Position{1, 1}, tokenKey, "flt8"},
 		{Position{1, 6}, tokenEqual, "="},
 		{Position{1, 8}, tokenFloat, "9_224_617.445_991_228_313"},
 		{Position{1, 33}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = +", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 7}, tokenError, "no digit in that number"},
 	})
 }
 func TestMultiline(t *testing.T) {
 	testFlow(t, "foo = 42\nbar=21", []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenInteger, "42"},
+		{Position{1, 7}, tokenInteger, "42"},
-		token{tokenKey, "bar"},
+		{Position{2, 1}, tokenKey, "bar"},
-		token{tokenEqual, "="},
+		{Position{2, 4}, tokenEqual, "="},
-		token{tokenInteger, "21"},
+		{Position{2, 5}, tokenInteger, "21"},
-		token{tokenEOF, ""},
+		{Position{2, 7}, tokenEOF, ""},
 	})
 }
 func TestKeyEqualStringUnicodeEscape(t *testing.T) {
-	testFlow(t, "foo = \"hello \\u2665\"", []token{
+	testFlow(t, `foo = "hello \u2665"`, []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenString, "hello ♥"},
+		{Position{1, 8}, tokenString, "hello ♥"},
-		token{tokenEOF, ""},
+		{Position{1, 21}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = "hello \U000003B4"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, "hello δ"},
 		{Position{1, 25}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = "\uabcd"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, "\uabcd"},
 		{Position{1, 15}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = "\uABCD"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, "\uABCD"},
 		{Position{1, 15}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = "\U000bcdef"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, "\U000bcdef"},
 		{Position{1, 19}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = "\U000BCDEF"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, "\U000BCDEF"},
 		{Position{1, 19}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = "\u2"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenError, "unfinished unicode escape"},
 	})
 	testFlow(t, `foo = "\U2"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenError, "unfinished unicode escape"},
 	})
 }
 func TestKeyEqualStringNoEscape(t *testing.T) {
 	testFlow(t, "foo = \"hello \u0002\"", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenError, "unescaped control character U+0002"},
 	})
 	testFlow(t, "foo = \"hello \u001F\"", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenError, "unescaped control character U+001F"},
 	})
 }
 func TestLiteralString(t *testing.T) {
 	testFlow(t, `foo = 'C:\Users\nodejs\templates'`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, `C:\Users\nodejs\templates`},
 		{Position{1, 34}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = '\\ServerX\admin$\system32\'`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, `\\ServerX\admin$\system32\`},
 		{Position{1, 35}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = 'Tom "Dubs" Preston-Werner'`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, `Tom "Dubs" Preston-Werner`},
 		{Position{1, 34}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = '<\i\c*\s*>'`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, `<\i\c*\s*>`},
 		{Position{1, 19}, tokenEOF, ""},
 	})
 	testFlow(t, `foo = 'C:\Users\nodejs\unfinis`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenError, "unclosed string"},
 	})
 }
 func TestMultilineLiteralString(t *testing.T) {
 	testFlow(t, `foo = '''hello 'literal' world'''`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 10}, tokenString, `hello 'literal' world`},
 		{Position{1, 34}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = '''\nhello\n'literal'\nworld'''", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{2, 1}, tokenString, "hello\n'literal'\nworld"},
 		{Position{4, 9}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = '''\r\nhello\r\n'literal'\r\nworld'''", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{2, 1}, tokenString, "hello\r\n'literal'\r\nworld"},
 		{Position{4, 9}, tokenEOF, ""},
 	})
 }
 func TestMultilineString(t *testing.T) {
 	testFlow(t, `foo = """hello "literal" world"""`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 10}, tokenString, `hello "literal" world`},
 		{Position{1, 34}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = \"\"\"\r\nhello\\\r\n\"literal\"\\\nworld\"\"\"", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{2, 1}, tokenString, "hello\"literal\"world"},
 		{Position{4, 9}, tokenEOF, ""},
 	})
 	testFlow(t, "foo = \"\"\"\\\n    \\\n    \\\n    hello\\\nmultiline\\\nworld\"\"\"", []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 10}, tokenString, "hellomultilineworld"},
 		{Position{6, 9}, tokenEOF, ""},
 	})
 	testFlow(t, "key2 = \"\"\"\nThe quick brown \\\n\n\n  fox jumps over \\\n    the lazy dog.\"\"\"", []token{
 		{Position{1, 1}, tokenKey, "key2"},
 		{Position{1, 6}, tokenEqual, "="},
 		{Position{2, 1}, tokenString, "The quick brown fox jumps over the lazy dog."},
 		{Position{6, 21}, tokenEOF, ""},
 	})
 	testFlow(t, "key2 = \"\"\"\\\n       The quick brown \\\n       fox jumps over \\\n       the lazy dog.\\\n       \"\"\"", []token{
 		{Position{1, 1}, tokenKey, "key2"},
 		{Position{1, 6}, tokenEqual, "="},
 		{Position{1, 11}, tokenString, "The quick brown fox jumps over the lazy dog."},
 		{Position{5, 11}, tokenEOF, ""},
 	})
 	testFlow(t, `key2 = "Roses are red\nViolets are blue"`, []token{
 		{Position{1, 1}, tokenKey, "key2"},
 		{Position{1, 6}, tokenEqual, "="},
 		{Position{1, 9}, tokenString, "Roses are red\nViolets are blue"},
 		{Position{1, 41}, tokenEOF, ""},
 	})
 	testFlow(t, "key2 = \"\"\"\nRoses are red\nViolets are blue\"\"\"", []token{
 		{Position{1, 1}, tokenKey, "key2"},
 		{Position{1, 6}, tokenEqual, "="},
 		{Position{2, 1}, tokenString, "Roses are red\nViolets are blue"},
 		{Position{3, 20}, tokenEOF, ""},
 	})
 }
 func TestUnicodeString(t *testing.T) {
-	testFlow(t, "foo = \"hello ♥ world\"", []token{
+	testFlow(t, `foo = "hello ♥ world"`, []token{
-		token{tokenKey, "foo"},
+		{Position{1, 1}, tokenKey, "foo"},
-		token{tokenEqual, "="},
+		{Position{1, 5}, tokenEqual, "="},
-		token{tokenString, "hello ♥ world"},
+		{Position{1, 8}, tokenString, "hello ♥ world"},
-		token{tokenEOF, ""},
+		{Position{1, 22}, tokenEOF, ""},
 	})
 }
 func TestEscapeInString(t *testing.T) {
 	testFlow(t, `foo = "\b\f\/"`, []token{
 		{Position{1, 1}, tokenKey, "foo"},
 		{Position{1, 5}, tokenEqual, "="},
 		{Position{1, 8}, tokenString, "\b\f/"},
 		{Position{1, 15}, tokenEOF, ""},
 	})
 }
 func TestKeyGroupArray(t *testing.T) {
 	testFlow(t, "[[foo]]", []token{
-		token{tokenDoubleLeftBracket, "[["},
+		{Position{1, 1}, tokenDoubleLeftBracket, "[["},
-		token{tokenKeyGroupArray, "foo"},
+		{Position{1, 3}, tokenKeyGroupArray, "foo"},
-		token{tokenDoubleRightBracket, "]]"},
+		{Position{1, 6}, tokenDoubleRightBracket, "]]"},
-		token{tokenEOF, ""},
+		{Position{1, 8}, tokenEOF, ""},
 	})
 }
 func TestQuotedKey(t *testing.T) {
 	testFlow(t, "\"a b\" = 42", []token{
 		{Position{1, 1}, tokenKey, "a b"},
 		{Position{1, 7}, tokenEqual, "="},
 		{Position{1, 9}, tokenInteger, "42"},
 		{Position{1, 11}, tokenEOF, ""},
 	})
 }
 func TestKeyNewline(t *testing.T) {
 	testFlow(t, "a\n= 4", []token{
 		{Position{1, 1}, tokenError, "keys cannot contain new lines"},
 	})
 }
 func TestInvalidFloat(t *testing.T) {
 	testFlow(t, "a=7e1_", []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 2}, tokenEqual, "="},
 		{Position{1, 3}, tokenFloat, "7e1_"},
 		{Position{1, 7}, tokenEOF, ""},
 	})
 }
 func TestLexUnknownRvalue(t *testing.T) {
 	testFlow(t, `a = !b`, []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 3}, tokenEqual, "="},
 		{Position{1, 5}, tokenError, "no value can start with !"},
 	})
 	testFlow(t, `a = \b`, []token{
 		{Position{1, 1}, tokenKey, "a"},
 		{Position{1, 3}, tokenEqual, "="},
 		{Position{1, 5}, tokenError, `no value can start with \`},
 	})
 }
 func BenchmarkLexer(b *testing.B) {
 	sample := `title = "Hugo: A Fast and Flexible Website Generator"
 baseurl = "http://gohugo.io/"
 MetaDataFormat = "yaml"
 pluralizeListTitles = false
 [params]
  description = "Documentation of Hugo, a fast and flexible static site generator built with love by spf13, bep and friends in Go"
  author = "Steve Francia (spf13) and friends"
  release = "0.22-DEV"
 [[menu.main]]
 	name = "Download Hugo"
 	pre = "<i class='fa fa-download'></i>"
 	url = "https://github.com/spf13/hugo/releases"
 	weight = -200
 `
 	b.ResetTimer()
 	for i := 0; i < b.N; i++ {
 		lexToml([]byte(sample))
 	}
 }
@@ -0,0 +1,609 @@
 package toml
 import (
 	"bytes"
 	"errors"
 	"fmt"
 	"io"
 	"reflect"
 	"strconv"
 	"strings"
 	"time"
 )
 const tagKeyMultiline = "multiline"
 type tomlOpts struct {
 	name      string
 	comment   string
 	commented bool
 	multiline bool
 	include   bool
 	omitempty bool
 }
 type encOpts struct {
 	quoteMapKeys            bool
 	arraysOneElementPerLine bool
 }
 var encOptsDefaults = encOpts{
 	quoteMapKeys: false,
 }
 var timeType = reflect.TypeOf(time.Time{})
 var marshalerType = reflect.TypeOf(new(Marshaler)).Elem()
 // Check if the given marshall type maps to a Tree primitive
 func isPrimitive(mtype reflect.Type) bool {
 	switch mtype.Kind() {
 	case reflect.Ptr:
 		return isPrimitive(mtype.Elem())
 	case reflect.Bool:
 		return true
 	case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
 		return true
 	case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
 		return true
 	case reflect.Float32, reflect.Float64:
 		return true
 	case reflect.String:
 		return true
 	case reflect.Struct:
 		return mtype == timeType || isCustomMarshaler(mtype)
 	default:
 		return false
 	}
 }
 // Check if the given marshall type maps to a Tree slice
 func isTreeSlice(mtype reflect.Type) bool {
 	switch mtype.Kind() {
 	case reflect.Slice:
 		return !isOtherSlice(mtype)
 	default:
 		return false
 	}
 }
 // Check if the given marshall type maps to a non-Tree slice
 func isOtherSlice(mtype reflect.Type) bool {
 	switch mtype.Kind() {
 	case reflect.Ptr:
 		return isOtherSlice(mtype.Elem())
 	case reflect.Slice:
 		return isPrimitive(mtype.Elem()) || isOtherSlice(mtype.Elem())
 	default:
 		return false
 	}
 }
 // Check if the given marshall type maps to a Tree
 func isTree(mtype reflect.Type) bool {
 	switch mtype.Kind() {
 	case reflect.Map:
 		return true
 	case reflect.Struct:
 		return !isPrimitive(mtype)
 	default:
 		return false
 	}
 }
 func isCustomMarshaler(mtype reflect.Type) bool {
 	return mtype.Implements(marshalerType)
 }
 func callCustomMarshaler(mval reflect.Value) ([]byte, error) {
 	return mval.Interface().(Marshaler).MarshalTOML()
 }
 // Marshaler is the interface implemented by types that
 // can marshal themselves into valid TOML.
 type Marshaler interface {
 	MarshalTOML() ([]byte, error)
 }
 /*
 Marshal returns the TOML encoding of v.  Behavior is similar to the Go json
 encoder, except that there is no concept of a Marshaler interface or MarshalTOML
 function for sub-structs, and currently only definite types can be marshaled
 (i.e. no `interface{}`).
 The following struct annotations are supported:
  toml:"Field"      Overrides the field's name to output.
  omitempty         When set, empty values and groups are not emitted.
  comment:"comment" Emits a # comment on the same line. This supports new lines.
  commented:"true"  Emits the value as commented.
 Note that pointers are automatically assigned the "omitempty" option, as TOML
 explicitly does not handle null values (saying instead the label should be
 dropped).
 Tree structural types and corresponding marshal types:
  *Tree                            (*)struct, (*)map[string]interface{}
  []*Tree                          (*)[](*)struct, (*)[](*)map[string]interface{}
  []interface{} (as interface{})   (*)[]primitive, (*)[]([]interface{})
  interface{}                      (*)primitive
 Tree primitive types and corresponding marshal types:
  uint64     uint, uint8-uint64, pointers to same
  int64      int, int8-uint64, pointers to same
  float64    float32, float64, pointers to same
  string     string, pointers to same
  bool       bool, pointers to same
  time.Time  time.Time{}, pointers to same
 */
 func Marshal(v interface{}) ([]byte, error) {
 	return NewEncoder(nil).marshal(v)
 }
 // Encoder writes TOML values to an output stream.
 type Encoder struct {
 	w io.Writer
 	encOpts
 }
 // NewEncoder returns a new encoder that writes to w.
 func NewEncoder(w io.Writer) *Encoder {
 	return &Encoder{
 		w:       w,
 		encOpts: encOptsDefaults,
 	}
 }
 // Encode writes the TOML encoding of v to the stream.
 //
 // See the documentation for Marshal for details.
 func (e *Encoder) Encode(v interface{}) error {
 	b, err := e.marshal(v)
 	if err != nil {
 		return err
 	}
 	if _, err := e.w.Write(b); err != nil {
 		return err
 	}
 	return nil
 }
 // QuoteMapKeys sets up the encoder to encode
 // maps with string type keys with quoted TOML keys.
 //
 // This relieves the character limitations on map keys.
 func (e *Encoder) QuoteMapKeys(v bool) *Encoder {
 	e.quoteMapKeys = v
 	return e
 }
 // ArraysWithOneElementPerLine sets up the encoder to encode arrays
 // with more than one element on multiple lines instead of one.
 //
 // For example:
 //
 //   A = [1,2,3]
 //
 // Becomes
 //
 //   A = [
 //     1,
 //     2,
 //     3,
 //   ]
 func (e *Encoder) ArraysWithOneElementPerLine(v bool) *Encoder {
 	e.arraysOneElementPerLine = v
 	return e
 }
 func (e *Encoder) marshal(v interface{}) ([]byte, error) {
 	mtype := reflect.TypeOf(v)
 	if mtype.Kind() != reflect.Struct {
 		return []byte{}, errors.New("Only a struct can be marshaled to TOML")
 	}
 	sval := reflect.ValueOf(v)
 	if isCustomMarshaler(mtype) {
 		return callCustomMarshaler(sval)
 	}
 	t, err := e.valueToTree(mtype, sval)
 	if err != nil {
 		return []byte{}, err
 	}
 	var buf bytes.Buffer
 	_, err = t.writeTo(&buf, "", "", 0, e.arraysOneElementPerLine)
 	return buf.Bytes(), err
 }
 // Convert given marshal struct or map value to toml tree
 func (e *Encoder) valueToTree(mtype reflect.Type, mval reflect.Value) (*Tree, error) {
 	if mtype.Kind() == reflect.Ptr {
 		return e.valueToTree(mtype.Elem(), mval.Elem())
 	}
 	tval := newTree()
 	switch mtype.Kind() {
 	case reflect.Struct:
 		for i := 0; i < mtype.NumField(); i++ {
 			mtypef, mvalf := mtype.Field(i), mval.Field(i)
 			opts := tomlOptions(mtypef)
 			if opts.include && (!opts.omitempty || !isZero(mvalf)) {
 				val, err := e.valueToToml(mtypef.Type, mvalf)
 				if err != nil {
 					return nil, err
 				}
 				tval.SetWithOptions(opts.name, SetOptions{
 					Comment:   opts.comment,
 					Commented: opts.commented,
 					Multiline: opts.multiline,
 				}, val)
 			}
 		}
 	case reflect.Map:
 		for _, key := range mval.MapKeys() {
 			mvalf := mval.MapIndex(key)
 			val, err := e.valueToToml(mtype.Elem(), mvalf)
 			if err != nil {
 				return nil, err
 			}
 			if e.quoteMapKeys {
 				keyStr, err := tomlValueStringRepresentation(key.String(), "", e.arraysOneElementPerLine)
 				if err != nil {
 					return nil, err
 				}
 				tval.SetPath([]string{keyStr}, val)
 			} else {
 				tval.Set(key.String(), val)
 			}
 		}
 	}
 	return tval, nil
 }
 // Convert given marshal slice to slice of Toml trees
 func (e *Encoder) valueToTreeSlice(mtype reflect.Type, mval reflect.Value) ([]*Tree, error) {
 	tval := make([]*Tree, mval.Len(), mval.Len())
 	for i := 0; i < mval.Len(); i++ {
 		val, err := e.valueToTree(mtype.Elem(), mval.Index(i))
 		if err != nil {
 			return nil, err
 		}
 		tval[i] = val
 	}
 	return tval, nil
 }
 // Convert given marshal slice to slice of toml values
 func (e *Encoder) valueToOtherSlice(mtype reflect.Type, mval reflect.Value) (interface{}, error) {
 	tval := make([]interface{}, mval.Len(), mval.Len())
 	for i := 0; i < mval.Len(); i++ {
 		val, err := e.valueToToml(mtype.Elem(), mval.Index(i))
 		if err != nil {
 			return nil, err
 		}
 		tval[i] = val
 	}
 	return tval, nil
 }
 // Convert given marshal value to toml value
 func (e *Encoder) valueToToml(mtype reflect.Type, mval reflect.Value) (interface{}, error) {
 	if mtype.Kind() == reflect.Ptr {
 		return e.valueToToml(mtype.Elem(), mval.Elem())
 	}
 	switch {
 	case isCustomMarshaler(mtype):
 		return callCustomMarshaler(mval)
 	case isTree(mtype):
 		return e.valueToTree(mtype, mval)
 	case isTreeSlice(mtype):
 		return e.valueToTreeSlice(mtype, mval)
 	case isOtherSlice(mtype):
 		return e.valueToOtherSlice(mtype, mval)
 	default:
 		switch mtype.Kind() {
 		case reflect.Bool:
 			return mval.Bool(), nil
 		case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
 			return mval.Int(), nil
 		case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64:
 			return mval.Uint(), nil
 		case reflect.Float32, reflect.Float64:
 			return mval.Float(), nil
 		case reflect.String:
 			return mval.String(), nil
 		case reflect.Struct:
 			return mval.Interface().(time.Time), nil
 		default:
 			return nil, fmt.Errorf("Marshal can't handle %v(%v)", mtype, mtype.Kind())
 		}
 	}
 }
 // Unmarshal attempts to unmarshal the Tree into a Go struct pointed by v.
 // Neither Unmarshaler interfaces nor UnmarshalTOML functions are supported for
 // sub-structs, and only definite types can be unmarshaled.
 func (t *Tree) Unmarshal(v interface{}) error {
 	d := Decoder{tval: t}
 	return d.unmarshal(v)
 }
 // Marshal returns the TOML encoding of Tree.
 // See Marshal() documentation for types mapping table.
 func (t *Tree) Marshal() ([]byte, error) {
 	var buf bytes.Buffer
 	err := NewEncoder(&buf).Encode(t)
 	return buf.Bytes(), err
 }
 // Unmarshal parses the TOML-encoded data and stores the result in the value
 // pointed to by v. Behavior is similar to the Go json encoder, except that there
 // is no concept of an Unmarshaler interface or UnmarshalTOML function for
 // sub-structs, and currently only definite types can be unmarshaled to (i.e. no
 // `interface{}`).
 //
 // The following struct annotations are supported:
 //
 //   toml:"Field" Overrides the field's name to map to.
 //
 // See Marshal() documentation for types mapping table.
 func Unmarshal(data []byte, v interface{}) error {
 	t, err := LoadReader(bytes.NewReader(data))
 	if err != nil {
 		return err
 	}
 	return t.Unmarshal(v)
 }
 // Decoder reads and decodes TOML values from an input stream.
 type Decoder struct {
 	r    io.Reader
 	tval *Tree
 	encOpts
 }
 // NewDecoder returns a new decoder that reads from r.
 func NewDecoder(r io.Reader) *Decoder {
 	return &Decoder{
 		r:       r,
 		encOpts: encOptsDefaults,
 	}
 }
 // Decode reads a TOML-encoded value from it's input
 // and unmarshals it in the value pointed at by v.
 //
 // See the documentation for Marshal for details.
 func (d *Decoder) Decode(v interface{}) error {
 	var err error
 	d.tval, err = LoadReader(d.r)
 	if err != nil {
 		return err
 	}
 	return d.unmarshal(v)
 }
 func (d *Decoder) unmarshal(v interface{}) error {
 	mtype := reflect.TypeOf(v)
 	if mtype.Kind() != reflect.Ptr || mtype.Elem().Kind() != reflect.Struct {
 		return errors.New("Only a pointer to struct can be unmarshaled from TOML")
 	}
 	sval, err := d.valueFromTree(mtype.Elem(), d.tval)
 	if err != nil {
 		return err
 	}
 	reflect.ValueOf(v).Elem().Set(sval)
 	return nil
 }
 // Convert toml tree to marshal struct or map, using marshal type
 func (d *Decoder) valueFromTree(mtype reflect.Type, tval *Tree) (reflect.Value, error) {
 	if mtype.Kind() == reflect.Ptr {
 		return d.unwrapPointer(mtype, tval)
 	}
 	var mval reflect.Value
 	switch mtype.Kind() {
 	case reflect.Struct:
 		mval = reflect.New(mtype).Elem()
 		for i := 0; i < mtype.NumField(); i++ {
 			mtypef := mtype.Field(i)
 			opts := tomlOptions(mtypef)
 			if opts.include {
 				baseKey := opts.name
 				keysToTry := []string{baseKey, strings.ToLower(baseKey), strings.ToTitle(baseKey)}
 				for _, key := range keysToTry {
 					exists := tval.Has(key)
 					if !exists {
 						continue
 					}
 					val := tval.Get(key)
 					mvalf, err := d.valueFromToml(mtypef.Type, val)
 					if err != nil {
 						return mval, formatError(err, tval.GetPosition(key))
 					}
 					mval.Field(i).Set(mvalf)
 					break
 				}
 			}
 		}
 	case reflect.Map:
 		mval = reflect.MakeMap(mtype)
 		for _, key := range tval.Keys() {
 			// TODO: path splits key
 			val := tval.GetPath([]string{key})
 			mvalf, err := d.valueFromToml(mtype.Elem(), val)
 			if err != nil {
 				return mval, formatError(err, tval.GetPosition(key))
 			}
 			mval.SetMapIndex(reflect.ValueOf(key), mvalf)
 		}
 	}
 	return mval, nil
 }
 // Convert toml value to marshal struct/map slice, using marshal type
 func (d *Decoder) valueFromTreeSlice(mtype reflect.Type, tval []*Tree) (reflect.Value, error) {
 	mval := reflect.MakeSlice(mtype, len(tval), len(tval))
 	for i := 0; i < len(tval); i++ {
 		val, err := d.valueFromTree(mtype.Elem(), tval[i])
 		if err != nil {
 			return mval, err
 		}
 		mval.Index(i).Set(val)
 	}
 	return mval, nil
 }
 // Convert toml value to marshal primitive slice, using marshal type
 func (d *Decoder) valueFromOtherSlice(mtype reflect.Type, tval []interface{}) (reflect.Value, error) {
 	mval := reflect.MakeSlice(mtype, len(tval), len(tval))
 	for i := 0; i < len(tval); i++ {
 		val, err := d.valueFromToml(mtype.Elem(), tval[i])
 		if err != nil {
 			return mval, err
 		}
 		mval.Index(i).Set(val)
 	}
 	return mval, nil
 }
 // Convert toml value to marshal value, using marshal type
 func (d *Decoder) valueFromToml(mtype reflect.Type, tval interface{}) (reflect.Value, error) {
 	if mtype.Kind() == reflect.Ptr {
 		return d.unwrapPointer(mtype, tval)
 	}
 	switch tval.(type) {
 	case *Tree:
 		if isTree(mtype) {
 			return d.valueFromTree(mtype, tval.(*Tree))
 		}
 		return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to a tree", tval, tval)
 	case []*Tree:
 		if isTreeSlice(mtype) {
 			return d.valueFromTreeSlice(mtype, tval.([]*Tree))
 		}
 		return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to trees", tval, tval)
 	case []interface{}:
 		if isOtherSlice(mtype) {
 			return d.valueFromOtherSlice(mtype, tval.([]interface{}))
 		}
 		return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to a slice", tval, tval)
 	default:
 		switch mtype.Kind() {
 		case reflect.Bool, reflect.Struct:
 			val := reflect.ValueOf(tval)
 			// if this passes for when mtype is reflect.Struct, tval is a time.Time
 			if !val.Type().ConvertibleTo(mtype) {
 				return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to %v", tval, tval, mtype.String())
 			}
 			return val.Convert(mtype), nil
 		case reflect.String:
 			val := reflect.ValueOf(tval)
 			// stupidly, int64 is convertible to string. So special case this.
 			if !val.Type().ConvertibleTo(mtype) || val.Kind() == reflect.Int64 {
 				return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to %v", tval, tval, mtype.String())
 			}
 			return val.Convert(mtype), nil
 		case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
 			val := reflect.ValueOf(tval)
 			if !val.Type().ConvertibleTo(mtype) {
 				return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to %v", tval, tval, mtype.String())
 			}
 			if reflect.Indirect(reflect.New(mtype)).OverflowInt(val.Int()) {
 				return reflect.ValueOf(nil), fmt.Errorf("%v(%T) would overflow %v", tval, tval, mtype.String())
 			}
 			return val.Convert(mtype), nil
 		case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
 			val := reflect.ValueOf(tval)
 			if !val.Type().ConvertibleTo(mtype) {
 				return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to %v", tval, tval, mtype.String())
 			}
 			if val.Int() < 0 {
 				return reflect.ValueOf(nil), fmt.Errorf("%v(%T) is negative so does not fit in %v", tval, tval, mtype.String())
 			}
 			if reflect.Indirect(reflect.New(mtype)).OverflowUint(uint64(val.Int())) {
 				return reflect.ValueOf(nil), fmt.Errorf("%v(%T) would overflow %v", tval, tval, mtype.String())
 			}
 			return val.Convert(mtype), nil
 		case reflect.Float32, reflect.Float64:
 			val := reflect.ValueOf(tval)
 			if !val.Type().ConvertibleTo(mtype) {
 				return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to %v", tval, tval, mtype.String())
 			}
 			if reflect.Indirect(reflect.New(mtype)).OverflowFloat(val.Float()) {
 				return reflect.ValueOf(nil), fmt.Errorf("%v(%T) would overflow %v", tval, tval, mtype.String())
 			}
 			return val.Convert(mtype), nil
 		default:
 			return reflect.ValueOf(nil), fmt.Errorf("Can't convert %v(%T) to %v(%v)", tval, tval, mtype, mtype.Kind())
 		}
 	}
 }
 func (d *Decoder) unwrapPointer(mtype reflect.Type, tval interface{}) (reflect.Value, error) {
 	val, err := d.valueFromToml(mtype.Elem(), tval)
 	if err != nil {
 		return reflect.ValueOf(nil), err
 	}
 	mval := reflect.New(mtype.Elem())
 	mval.Elem().Set(val)
 	return mval, nil
 }
 func tomlOptions(vf reflect.StructField) tomlOpts {
 	tag := vf.Tag.Get("toml")
 	parse := strings.Split(tag, ",")
 	var comment string
 	if c := vf.Tag.Get("comment"); c != "" {
 		comment = c
 	}
 	commented, _ := strconv.ParseBool(vf.Tag.Get("commented"))
 	multiline, _ := strconv.ParseBool(vf.Tag.Get(tagKeyMultiline))
 	result := tomlOpts{name: vf.Name, comment: comment, commented: commented, multiline: multiline, include: true, omitempty: false}
 	if parse[0] != "" {
 		if parse[0] == "-" && len(parse) == 1 {
 			result.include = false
 		} else {
 			result.name = strings.Trim(parse[0], " ")
 		}
 	}
 	if vf.PkgPath != "" {
 		result.include = false
 	}
 	if len(parse) > 1 && strings.Trim(parse[1], " ") == "omitempty" {
 		result.omitempty = true
 	}
 	if vf.Type.Kind() == reflect.Ptr {
 		result.omitempty = true
 	}
 	return result
 }
 func isZero(val reflect.Value) bool {
 	switch val.Type().Kind() {
 	case reflect.Map:
 		fallthrough
 	case reflect.Array:
 		fallthrough
 	case reflect.Slice:
 		return val.Len() == 0
 	default:
 		return reflect.DeepEqual(val.Interface(), reflect.Zero(val.Type()).Interface())
 	}
 }
 func formatError(err error, pos Position) error {
 	if err.Error()[0] == '(' { // Error already contains position information
 		return err
 	}
 	return fmt.Errorf("%s: %s", pos, err)
 }
@@ -0,0 +1,806 @@
 package toml
 import (
 	"bytes"
 	"encoding/json"
 	"fmt"
 	"io/ioutil"
 	"reflect"
 	"strings"
 	"testing"
 	"time"
 )
 type basicMarshalTestStruct struct {
 	String     string                      `toml:"string"`
 	StringList []string                    `toml:"strlist"`
 	Sub        basicMarshalTestSubStruct   `toml:"subdoc"`
 	SubList    []basicMarshalTestSubStruct `toml:"sublist"`
 }
 type basicMarshalTestSubStruct struct {
 	String2 string
 }
 var basicTestData = basicMarshalTestStruct{
 	String:     "Hello",
 	StringList: []string{"Howdy", "Hey There"},
 	Sub:        basicMarshalTestSubStruct{"One"},
 	SubList:    []basicMarshalTestSubStruct{{"Two"}, {"Three"}},
 }
 var basicTestToml = []byte(`string = "Hello"
 strlist = ["Howdy","Hey There"]
 [subdoc]
  String2 = "One"
 [[sublist]]
  String2 = "Two"
 [[sublist]]
  String2 = "Three"
 `)
 func TestBasicMarshal(t *testing.T) {
 	result, err := Marshal(basicTestData)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := basicTestToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestBasicUnmarshal(t *testing.T) {
 	result := basicMarshalTestStruct{}
 	err := Unmarshal(basicTestToml, &result)
 	expected := basicTestData
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		t.Errorf("Bad unmarshal: expected %v, got %v", expected, result)
 	}
 }
 type testDoc struct {
 	Title       string            `toml:"title"`
 	Basics      testDocBasics     `toml:"basic"`
 	BasicLists  testDocBasicLists `toml:"basic_lists"`
 	BasicMap    map[string]string `toml:"basic_map"`
 	Subdocs     testDocSubs       `toml:"subdoc"`
 	SubDocList  []testSubDoc      `toml:"subdoclist"`
 	SubDocPtrs  []*testSubDoc     `toml:"subdocptrs"`
 	err         int               `toml:"shouldntBeHere"`
 	unexported  int               `toml:"shouldntBeHere"`
 	Unexported2 int               `toml:"-"`
 }
 type testDocBasics struct {
 	Bool       bool      `toml:"bool"`
 	Date       time.Time `toml:"date"`
 	Float      float32   `toml:"float"`
 	Int        int       `toml:"int"`
 	Uint       uint      `toml:"uint"`
 	String     *string   `toml:"string"`
 	unexported int       `toml:"shouldntBeHere"`
 }
 type testDocBasicLists struct {
 	Bools   []bool      `toml:"bools"`
 	Dates   []time.Time `toml:"dates"`
 	Floats  []*float32  `toml:"floats"`
 	Ints    []int       `toml:"ints"`
 	Strings []string    `toml:"strings"`
 	UInts   []uint      `toml:"uints"`
 }
 type testDocSubs struct {
 	First  testSubDoc  `toml:"first"`
 	Second *testSubDoc `toml:"second"`
 }
 type testSubDoc struct {
 	Name       string `toml:"name"`
 	unexported int    `toml:"shouldntBeHere"`
 }
 var biteMe = "Bite me"
 var float1 float32 = 12.3
 var float2 float32 = 45.6
 var float3 float32 = 78.9
 var subdoc = testSubDoc{"Second", 0}
 var docData = testDoc{
 	Title:       "TOML Marshal Testing",
 	unexported:  0,
 	Unexported2: 0,
 	Basics: testDocBasics{
 		Bool:       true,
 		Date:       time.Date(1979, 5, 27, 7, 32, 0, 0, time.UTC),
 		Float:      123.4,
 		Int:        5000,
 		Uint:       5001,
 		String:     &biteMe,
 		unexported: 0,
 	},
 	BasicLists: testDocBasicLists{
 		Bools: []bool{true, false, true},
 		Dates: []time.Time{
 			time.Date(1979, 5, 27, 7, 32, 0, 0, time.UTC),
 			time.Date(1980, 5, 27, 7, 32, 0, 0, time.UTC),
 		},
 		Floats:  []*float32{&float1, &float2, &float3},
 		Ints:    []int{8001, 8001, 8002},
 		Strings: []string{"One", "Two", "Three"},
 		UInts:   []uint{5002, 5003},
 	},
 	BasicMap: map[string]string{
 		"one": "one",
 		"two": "two",
 	},
 	Subdocs: testDocSubs{
 		First:  testSubDoc{"First", 0},
 		Second: &subdoc,
 	},
 	SubDocList: []testSubDoc{
 		{"List.First", 0},
 		{"List.Second", 0},
 	},
 	SubDocPtrs: []*testSubDoc{&subdoc},
 }
 func TestDocMarshal(t *testing.T) {
 	result, err := Marshal(docData)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected, _ := ioutil.ReadFile("marshal_test.toml")
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestDocUnmarshal(t *testing.T) {
 	result := testDoc{}
 	tomlData, _ := ioutil.ReadFile("marshal_test.toml")
 	err := Unmarshal(tomlData, &result)
 	expected := docData
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		resStr, _ := json.MarshalIndent(result, "", "  ")
 		expStr, _ := json.MarshalIndent(expected, "", "  ")
 		t.Errorf("Bad unmarshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expStr, resStr)
 	}
 }
 func TestDocPartialUnmarshal(t *testing.T) {
 	result := testDocSubs{}
 	tree, _ := LoadFile("marshal_test.toml")
 	subTree := tree.Get("subdoc").(*Tree)
 	err := subTree.Unmarshal(&result)
 	expected := docData.Subdocs
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		resStr, _ := json.MarshalIndent(result, "", "  ")
 		expStr, _ := json.MarshalIndent(expected, "", "  ")
 		t.Errorf("Bad partial unmartial: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expStr, resStr)
 	}
 }
 type tomlTypeCheckTest struct {
 	name string
 	item interface{}
 	typ  int //0=primitive, 1=otherslice, 2=treeslice, 3=tree
 }
 func TestTypeChecks(t *testing.T) {
 	tests := []tomlTypeCheckTest{
 		{"integer", 2, 0},
 		{"time", time.Date(2015, 1, 1, 0, 0, 0, 0, time.UTC), 0},
 		{"stringlist", []string{"hello", "hi"}, 1},
 		{"timelist", []time.Time{time.Date(2015, 1, 1, 0, 0, 0, 0, time.UTC)}, 1},
 		{"objectlist", []tomlTypeCheckTest{}, 2},
 		{"object", tomlTypeCheckTest{}, 3},
 	}
 	for _, test := range tests {
 		expected := []bool{false, false, false, false}
 		expected[test.typ] = true
 		result := []bool{
 			isPrimitive(reflect.TypeOf(test.item)),
 			isOtherSlice(reflect.TypeOf(test.item)),
 			isTreeSlice(reflect.TypeOf(test.item)),
 			isTree(reflect.TypeOf(test.item)),
 		}
 		if !reflect.DeepEqual(expected, result) {
 			t.Errorf("Bad type check on %q: expected %v, got %v", test.name, expected, result)
 		}
 	}
 }
 type unexportedMarshalTestStruct struct {
 	String      string                      `toml:"string"`
 	StringList  []string                    `toml:"strlist"`
 	Sub         basicMarshalTestSubStruct   `toml:"subdoc"`
 	SubList     []basicMarshalTestSubStruct `toml:"sublist"`
 	unexported  int                         `toml:"shouldntBeHere"`
 	Unexported2 int                         `toml:"-"`
 }
 var unexportedTestData = unexportedMarshalTestStruct{
 	String:      "Hello",
 	StringList:  []string{"Howdy", "Hey There"},
 	Sub:         basicMarshalTestSubStruct{"One"},
 	SubList:     []basicMarshalTestSubStruct{{"Two"}, {"Three"}},
 	unexported:  0,
 	Unexported2: 0,
 }
 var unexportedTestToml = []byte(`string = "Hello"
 strlist = ["Howdy","Hey There"]
 unexported = 1
 shouldntBeHere = 2
 [subdoc]
  String2 = "One"
 [[sublist]]
  String2 = "Two"
 [[sublist]]
  String2 = "Three"
 `)
 func TestUnexportedUnmarshal(t *testing.T) {
 	result := unexportedMarshalTestStruct{}
 	err := Unmarshal(unexportedTestToml, &result)
 	expected := unexportedTestData
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		t.Errorf("Bad unexported unmarshal: expected %v, got %v", expected, result)
 	}
 }
 type errStruct struct {
 	Bool   bool      `toml:"bool"`
 	Date   time.Time `toml:"date"`
 	Float  float64   `toml:"float"`
 	Int    int16     `toml:"int"`
 	String *string   `toml:"string"`
 }
 var errTomls = []string{
 	"bool = truly\ndate = 1979-05-27T07:32:00Z\nfloat = 123.4\nint = 5000\nstring = \"Bite me\"",
 	"bool = true\ndate = 1979-05-27T07:3200Z\nfloat = 123.4\nint = 5000\nstring = \"Bite me\"",
 	"bool = true\ndate = 1979-05-27T07:32:00Z\nfloat = 123a4\nint = 5000\nstring = \"Bite me\"",
 	"bool = true\ndate = 1979-05-27T07:32:00Z\nfloat = 123.4\nint = j000\nstring = \"Bite me\"",
 	"bool = true\ndate = 1979-05-27T07:32:00Z\nfloat = 123.4\nint = 5000\nstring = Bite me",
 	"bool = true\ndate = 1979-05-27T07:32:00Z\nfloat = 123.4\nint = 5000\nstring = Bite me",
 	"bool = 1\ndate = 1979-05-27T07:32:00Z\nfloat = 123.4\nint = 5000\nstring = \"Bite me\"",
 	"bool = true\ndate = 1\nfloat = 123.4\nint = 5000\nstring = \"Bite me\"",
 	"bool = true\ndate = 1979-05-27T07:32:00Z\n\"sorry\"\nint = 5000\nstring = \"Bite me\"",
 	"bool = true\ndate = 1979-05-27T07:32:00Z\nfloat = 123.4\nint = \"sorry\"\nstring = \"Bite me\"",
 	"bool = true\ndate = 1979-05-27T07:32:00Z\nfloat = 123.4\nint = 5000\nstring = 1",
 }
 type mapErr struct {
 	Vals map[string]float64
 }
 type intErr struct {
 	Int1  int
 	Int2  int8
 	Int3  int16
 	Int4  int32
 	Int5  int64
 	UInt1 uint
 	UInt2 uint8
 	UInt3 uint16
 	UInt4 uint32
 	UInt5 uint64
 	Flt1  float32
 	Flt2  float64
 }
 var intErrTomls = []string{
 	"Int1 = []\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = []\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = []\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = []\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = []\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = []\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = []\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = []\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = []\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = []\nFlt1 = 1.0\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = []\nFlt2 = 2.0",
 	"Int1 = 1\nInt2 = 2\nInt3 = 3\nInt4 = 4\nInt5 = 5\nUInt1 = 1\nUInt2 = 2\nUInt3 = 3\nUInt4 = 4\nUInt5 = 5\nFlt1 = 1.0\nFlt2 = []",
 }
 func TestErrUnmarshal(t *testing.T) {
 	for ind, toml := range errTomls {
 		result := errStruct{}
 		err := Unmarshal([]byte(toml), &result)
 		if err == nil {
 			t.Errorf("Expected err from case %d\n", ind)
 		}
 	}
 	result2 := mapErr{}
 	err := Unmarshal([]byte("[Vals]\nfred=\"1.2\""), &result2)
 	if err == nil {
 		t.Errorf("Expected err from map")
 	}
 	for ind, toml := range intErrTomls {
 		result3 := intErr{}
 		err := Unmarshal([]byte(toml), &result3)
 		if err == nil {
 			t.Errorf("Expected int err from case %d\n", ind)
 		}
 	}
 }
 type emptyMarshalTestStruct struct {
 	Title      string                  `toml:"title"`
 	Bool       bool                    `toml:"bool"`
 	Int        int                     `toml:"int"`
 	String     string                  `toml:"string"`
 	StringList []string                `toml:"stringlist"`
 	Ptr        *basicMarshalTestStruct `toml:"ptr"`
 	Map        map[string]string       `toml:"map"`
 }
 var emptyTestData = emptyMarshalTestStruct{
 	Title:      "Placeholder",
 	Bool:       false,
 	Int:        0,
 	String:     "",
 	StringList: []string{},
 	Ptr:        nil,
 	Map:        map[string]string{},
 }
 var emptyTestToml = []byte(`bool = false
 int = 0
 string = ""
 stringlist = []
 title = "Placeholder"
 [map]
 `)
 type emptyMarshalTestStruct2 struct {
 	Title      string                  `toml:"title"`
 	Bool       bool                    `toml:"bool,omitempty"`
 	Int        int                     `toml:"int, omitempty"`
 	String     string                  `toml:"string,omitempty "`
 	StringList []string                `toml:"stringlist,omitempty"`
 	Ptr        *basicMarshalTestStruct `toml:"ptr,omitempty"`
 	Map        map[string]string       `toml:"map,omitempty"`
 }
 var emptyTestData2 = emptyMarshalTestStruct2{
 	Title:      "Placeholder",
 	Bool:       false,
 	Int:        0,
 	String:     "",
 	StringList: []string{},
 	Ptr:        nil,
 	Map:        map[string]string{},
 }
 var emptyTestToml2 = []byte(`title = "Placeholder"
 `)
 func TestEmptyMarshal(t *testing.T) {
 	result, err := Marshal(emptyTestData)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := emptyTestToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad empty marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestEmptyMarshalOmit(t *testing.T) {
 	result, err := Marshal(emptyTestData2)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := emptyTestToml2
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad empty omit marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestEmptyUnmarshal(t *testing.T) {
 	result := emptyMarshalTestStruct{}
 	err := Unmarshal(emptyTestToml, &result)
 	expected := emptyTestData
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		t.Errorf("Bad empty unmarshal: expected %v, got %v", expected, result)
 	}
 }
 func TestEmptyUnmarshalOmit(t *testing.T) {
 	result := emptyMarshalTestStruct2{}
 	err := Unmarshal(emptyTestToml, &result)
 	expected := emptyTestData2
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		t.Errorf("Bad empty omit unmarshal: expected %v, got %v", expected, result)
 	}
 }
 type pointerMarshalTestStruct struct {
 	Str       *string
 	List      *[]string
 	ListPtr   *[]*string
 	Map       *map[string]string
 	MapPtr    *map[string]*string
 	EmptyStr  *string
 	EmptyList *[]string
 	EmptyMap  *map[string]string
 	DblPtr    *[]*[]*string
 }
 var pointerStr = "Hello"
 var pointerList = []string{"Hello back"}
 var pointerListPtr = []*string{&pointerStr}
 var pointerMap = map[string]string{"response": "Goodbye"}
 var pointerMapPtr = map[string]*string{"alternate": &pointerStr}
 var pointerTestData = pointerMarshalTestStruct{
 	Str:       &pointerStr,
 	List:      &pointerList,
 	ListPtr:   &pointerListPtr,
 	Map:       &pointerMap,
 	MapPtr:    &pointerMapPtr,
 	EmptyStr:  nil,
 	EmptyList: nil,
 	EmptyMap:  nil,
 }
 var pointerTestToml = []byte(`List = ["Hello back"]
 ListPtr = ["Hello"]
 Str = "Hello"
 [Map]
  response = "Goodbye"
 [MapPtr]
  alternate = "Hello"
 `)
 func TestPointerMarshal(t *testing.T) {
 	result, err := Marshal(pointerTestData)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := pointerTestToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad pointer marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestPointerUnmarshal(t *testing.T) {
 	result := pointerMarshalTestStruct{}
 	err := Unmarshal(pointerTestToml, &result)
 	expected := pointerTestData
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		t.Errorf("Bad pointer unmarshal: expected %v, got %v", expected, result)
 	}
 }
 func TestUnmarshalTypeMismatch(t *testing.T) {
 	result := pointerMarshalTestStruct{}
 	err := Unmarshal([]byte("List = 123"), &result)
 	if !strings.HasPrefix(err.Error(), "(1, 1): Can't convert 123(int64) to []string(slice)") {
 		t.Errorf("Type mismatch must be reported: got %v", err.Error())
 	}
 }
 type nestedMarshalTestStruct struct {
 	String [][]string
 	//Struct [][]basicMarshalTestSubStruct
 	StringPtr *[]*[]*string
 	// StructPtr *[]*[]*basicMarshalTestSubStruct
 }
 var str1 = "Three"
 var str2 = "Four"
 var strPtr = []*string{&str1, &str2}
 var strPtr2 = []*[]*string{&strPtr}
 var nestedTestData = nestedMarshalTestStruct{
 	String:    [][]string{{"Five", "Six"}, {"One", "Two"}},
 	StringPtr: &strPtr2,
 }
 var nestedTestToml = []byte(`String = [["Five","Six"],["One","Two"]]
 StringPtr = [["Three","Four"]]
 `)
 func TestNestedMarshal(t *testing.T) {
 	result, err := Marshal(nestedTestData)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := nestedTestToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad nested marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestNestedUnmarshal(t *testing.T) {
 	result := nestedMarshalTestStruct{}
 	err := Unmarshal(nestedTestToml, &result)
 	expected := nestedTestData
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		t.Errorf("Bad nested unmarshal: expected %v, got %v", expected, result)
 	}
 }
 type customMarshalerParent struct {
 	Self    customMarshaler   `toml:"me"`
 	Friends []customMarshaler `toml:"friends"`
 }
 type customMarshaler struct {
 	FirsName string
 	LastName string
 }
 func (c customMarshaler) MarshalTOML() ([]byte, error) {
 	fullName := fmt.Sprintf("%s %s", c.FirsName, c.LastName)
 	return []byte(fullName), nil
 }
 var customMarshalerData = customMarshaler{FirsName: "Sally", LastName: "Fields"}
 var customMarshalerToml = []byte(`Sally Fields`)
 var nestedCustomMarshalerData = customMarshalerParent{
 	Self:    customMarshaler{FirsName: "Maiku", LastName: "Suteda"},
 	Friends: []customMarshaler{customMarshalerData},
 }
 var nestedCustomMarshalerToml = []byte(`friends = ["Sally Fields"]
 me = "Maiku Suteda"
 `)
 func TestCustomMarshaler(t *testing.T) {
 	result, err := Marshal(customMarshalerData)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := customMarshalerToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad custom marshaler: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestNestedCustomMarshaler(t *testing.T) {
 	result, err := Marshal(nestedCustomMarshalerData)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := nestedCustomMarshalerToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad nested custom marshaler: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 var commentTestToml = []byte(`
 # it's a comment on type
 [postgres]
  # isCommented = "dvalue"
  noComment = "cvalue"
  # A comment on AttrB with a
  # break line
  password = "bvalue"
  # A comment on AttrA
  user = "avalue"
  [[postgres.My]]
    # a comment on my on typeC
    My = "Foo"
  [[postgres.My]]
    # a comment on my on typeC
    My = "Baar"
 `)
 func TestMarshalComment(t *testing.T) {
 	type TypeC struct {
 		My string `comment:"a comment on my on typeC"`
 	}
 	type TypeB struct {
 		AttrA string `toml:"user" comment:"A comment on AttrA"`
 		AttrB string `toml:"password" comment:"A comment on AttrB with a\n break line"`
 		AttrC string `toml:"noComment"`
 		AttrD string `toml:"isCommented" commented:"true"`
 		My    []TypeC
 	}
 	type TypeA struct {
 		TypeB TypeB `toml:"postgres" comment:"it's a comment on type"`
 	}
 	ta := []TypeC{{My: "Foo"}, {My: "Baar"}}
 	config := TypeA{TypeB{AttrA: "avalue", AttrB: "bvalue", AttrC: "cvalue", AttrD: "dvalue", My: ta}}
 	result, err := Marshal(config)
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := commentTestToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 type mapsTestStruct struct {
 	Simple map[string]string
 	Paths  map[string]string
 	Other  map[string]float64
 	X      struct {
 		Y struct {
 			Z map[string]bool
 		}
 	}
 }
 var mapsTestData = mapsTestStruct{
 	Simple: map[string]string{
 		"one plus one": "two",
 		"next":         "three",
 	},
 	Paths: map[string]string{
 		"/this/is/a/path": "/this/is/also/a/path",
 		"/heloo.txt":      "/tmp/lololo.txt",
 	},
 	Other: map[string]float64{
 		"testing": 3.9999,
 	},
 	X: struct{ Y struct{ Z map[string]bool } }{
 		Y: struct{ Z map[string]bool }{
 			Z: map[string]bool{
 				"is.Nested": true,
 			},
 		},
 	},
 }
 var mapsTestToml = []byte(`
 [Other]
  "testing" = 3.9999
 [Paths]
  "/heloo.txt" = "/tmp/lololo.txt"
  "/this/is/a/path" = "/this/is/also/a/path"
 [Simple]
  "next" = "three"
  "one plus one" = "two"
 [X]
  [X.Y]
    [X.Y.Z]
      "is.Nested" = true
 `)
 func TestEncodeQuotedMapKeys(t *testing.T) {
 	var buf bytes.Buffer
 	if err := NewEncoder(&buf).QuoteMapKeys(true).Encode(mapsTestData); err != nil {
 		t.Fatal(err)
 	}
 	result := buf.Bytes()
 	expected := mapsTestToml
 	if !bytes.Equal(result, expected) {
 		t.Errorf("Bad maps marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, result)
 	}
 }
 func TestDecodeQuotedMapKeys(t *testing.T) {
 	result := mapsTestStruct{}
 	err := NewDecoder(bytes.NewBuffer(mapsTestToml)).Decode(&result)
 	expected := mapsTestData
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !reflect.DeepEqual(result, expected) {
 		t.Errorf("Bad maps unmarshal: expected %v, got %v", expected, result)
 	}
 }
 type structArrayNoTag struct {
 	A struct {
 		B []int64
 		C []int64
 	}
 }
 func TestMarshalArray(t *testing.T) {
 	expected := []byte(`
 [A]
  B = [1,2,3]
  C = [1]
 `)
 	m := structArrayNoTag{
 		A: struct {
 			B []int64
 			C []int64
 		}{
 			B: []int64{1, 2, 3},
 			C: []int64{1},
 		},
 	}
 	b, err := Marshal(m)
 	if err != nil {
 		t.Fatal(err)
 	}
 	if !bytes.Equal(b, expected) {
 		t.Errorf("Bad arrays marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, b)
 	}
 }
 func TestMarshalArrayOnePerLine(t *testing.T) {
 	expected := []byte(`
 [A]
  B = [
    1,
    2,
    3,
  ]
  C = [1]
 `)
 	m := structArrayNoTag{
 		A: struct {
 			B []int64
 			C []int64
 		}{
 			B: []int64{1, 2, 3},
 			C: []int64{1},
 		},
 	}
 	var buf bytes.Buffer
 	encoder := NewEncoder(&buf).ArraysWithOneElementPerLine(true)
 	err := encoder.Encode(m)
 	if err != nil {
 		t.Fatal(err)
 	}
 	b := buf.Bytes()
 	if !bytes.Equal(b, expected) {
 		t.Errorf("Bad arrays marshal: expected\n-----\n%s\n-----\ngot\n-----\n%s\n-----\n", expected, b)
 	}
 }
@@ -0,0 +1,38 @@
 title = "TOML Marshal Testing"
 [basic]
  bool = true
  date = 1979-05-27T07:32:00Z
  float = 123.4
  int = 5000
  string = "Bite me"
  uint = 5001
 [basic_lists]
  bools = [true,false,true]
  dates = [1979-05-27T07:32:00Z,1980-05-27T07:32:00Z]
  floats = [12.3,45.6,78.9]
  ints = [8001,8001,8002]
  strings = ["One","Two","Three"]
  uints = [5002,5003]
 [basic_map]
  one = "one"
  two = "two"
 [subdoc]
  [subdoc.first]
    name = "First"
  [subdoc.second]
    name = "Second"
 [[subdoclist]]
  name = "List.First"
 [[subdoclist]]
  name = "List.Second"
 [[subdocptrs]]
  name = "Second"
@@ -3,66 +3,64 @@
 package toml
 import (
 	"errors"
 	"fmt"
 	"math"
 	"reflect"
 	"regexp"
 	"strconv"
 	"strings"
 	"time"
 )
-type parser struct {
+type tomlParser struct {
-	flow          chan token
+	flowIdx       int
-	tree          *TomlTree
+	flow          []token
-	tokensBuffer  []token
+	tree          *Tree
-	currentGroup  []string
+	currentTable  []string
-	seenGroupKeys []string
+	seenTableKeys []string
 }
-type parserStateFn func(*parser) parserStateFn
+type tomlParserStateFn func() tomlParserStateFn
-func (p *parser) run() {
+// Formats and panics an error message based on a token
-	for state := parseStart; state != nil; {
+func (p *tomlParser) raiseError(tok *token, msg string, args ...interface{}) {
-		state = state(p)
+	panic(tok.Position.String() + ": " + fmt.Sprintf(msg, args...))
 }
 func (p *tomlParser) run() {
 	for state := p.parseStart; state != nil; {
 		state = state()
 	}
 }
-func (p *parser) peek() *token {
+func (p *tomlParser) peek() *token {
-	if len(p.tokensBuffer) != 0 {
+	if p.flowIdx >= len(p.flow) {
 		return &(p.tokensBuffer[0])
 	}
 	tok, ok := <-p.flow
 	if !ok {
 		return nil
 	}
-	p.tokensBuffer = append(p.tokensBuffer, tok)
+	return &p.flow[p.flowIdx]
 	return &tok
 }
-func (p *parser) assume(typ tokenType) {
+func (p *tomlParser) assume(typ tokenType) {
 	tok := p.getToken()
 	if tok == nil {
-		panic(fmt.Sprintf("was expecting token %s, but token stream is empty", typ))
+		p.raiseError(tok, "was expecting token %s, but token stream is empty", tok)
 	}
 	if tok.typ != typ {
-		panic(fmt.Sprintf("was expecting token %s, but got %s", typ, tok.typ))
+		p.raiseError(tok, "was expecting token %s, but got %s instead", typ, tok)
 	}
 }
-func (p *parser) getToken() *token {
+func (p *tomlParser) getToken() *token {
-	if len(p.tokensBuffer) != 0 {
+	tok := p.peek()
-		tok := p.tokensBuffer[0]
+	if tok == nil {
 		p.tokensBuffer = p.tokensBuffer[1:]
 		return &tok
 	}
 	tok, ok := <-p.flow
 	if !ok {
 		return nil
 	}
-	return &tok
+	p.flowIdx++
 	return tok
 }
-func parseStart(p *parser) parserStateFn {
+func (p *tomlParser) parseStart() tomlParserStateFn {
 	tok := p.peek()
 	// end of stream, parsing is finished
@@ -72,105 +70,171 @@ func parseStart(p *parser) parserStateFn {
 	switch tok.typ {
 	case tokenDoubleLeftBracket:
-		return parseGroupArray
+		return p.parseGroupArray
 	case tokenLeftBracket:
-		return parseGroup
+		return p.parseGroup
 	case tokenKey:
-		return parseAssign
+		return p.parseAssign
 	case tokenEOF:
 		return nil
 	default:
-		panic("unexpected token")
+		p.raiseError(tok, "unexpected token")
 	}
 	return nil
 }
-func parseGroupArray(p *parser) parserStateFn {
+func (p *tomlParser) parseGroupArray() tomlParserStateFn {
-	p.getToken() // discard the [[
+	startToken := p.getToken() // discard the [[
 	key := p.getToken()
 	if key.typ != tokenKeyGroupArray {
-		panic(fmt.Sprintf("unexpected token %s, was expecting a key group array", key))
+		p.raiseError(key, "unexpected token %s, was expecting a table array key", key)
 	}
-	// get or create group array element at the indicated part in the path
+	// get or create table array element at the indicated part in the path
-	p.currentGroup = strings.Split(key.val, ".")
+	keys, err := parseKey(key.val)
-	dest_tree := p.tree.GetPath(p.currentGroup)
+	if err != nil {
-	var array []*TomlTree
+		p.raiseError(key, "invalid table array key: %s", err)
-	if dest_tree == nil {
+	}
-		array = make([]*TomlTree, 0)
+	p.tree.createSubTree(keys[:len(keys)-1], startToken.Position) // create parent entries
-	} else if dest_tree.([]*TomlTree) != nil {
+	destTree := p.tree.GetPath(keys)
-		array = dest_tree.([]*TomlTree)
+	var array []*Tree
 	if destTree == nil {
 		array = make([]*Tree, 0)
 	} else if target, ok := destTree.([]*Tree); ok && target != nil {
 		array = destTree.([]*Tree)
 	} else {
-		panic(fmt.Sprintf("key %s is already assigned and not of type group array", key))
+		p.raiseError(key, "key %s is already assigned and not of type table array", key)
 	}
 	p.currentTable = keys
-	// add a new tree to the end of the group array
+	// add a new tree to the end of the table array
-	new_tree := make(TomlTree)
+	newTree := newTree()
-	array = append(array, &new_tree)
+	newTree.position = startToken.Position
-	p.tree.SetPath(p.currentGroup, array)
+	array = append(array, newTree)
 	p.tree.SetPath(p.currentTable, array)
 	// remove all keys that were children of this table array
 	prefix := key.val + "."
 	found := false
 	for ii := 0; ii < len(p.seenTableKeys); {
 		tableKey := p.seenTableKeys[ii]
 		if strings.HasPrefix(tableKey, prefix) {
 			p.seenTableKeys = append(p.seenTableKeys[:ii], p.seenTableKeys[ii+1:]...)
 		} else {
 			found = (tableKey == key.val)
 			ii++
 		}
 	}
 	// keep this key name from use by other kinds of assignments
-	p.seenGroupKeys = append(p.seenGroupKeys, key.val)
+	if !found {
 		p.seenTableKeys = append(p.seenTableKeys, key.val)
 	}
 	// move to next parser state
 	p.assume(tokenDoubleRightBracket)
-	return parseStart(p)
+	return p.parseStart
 }
-func parseGroup(p *parser) parserStateFn {
+func (p *tomlParser) parseGroup() tomlParserStateFn {
-	p.getToken() // discard the [
+	startToken := p.getToken() // discard the [
 	key := p.getToken()
 	if key.typ != tokenKeyGroup {
-		panic(fmt.Sprintf("unexpected token %s, was expecting a key group", key))
+		p.raiseError(key, "unexpected token %s, was expecting a table key", key)
 	}
-	for _, item := range p.seenGroupKeys {
+	for _, item := range p.seenTableKeys {
 		if item == key.val {
-			panic("duplicated tables")
+			p.raiseError(key, "duplicated tables")
 		}
 	}
 	p.seenGroupKeys = append(p.seenGroupKeys, key.val)
 	p.tree.createSubTree(key.val)
 	p.assume(tokenRightBracket)
 	p.currentGroup = strings.Split(key.val, ".")
 	return parseStart(p)
 }
-func parseAssign(p *parser) parserStateFn {
+	p.seenTableKeys = append(p.seenTableKeys, key.val)
 	keys, err := parseKey(key.val)
 	if err != nil {
 		p.raiseError(key, "invalid table array key: %s", err)
 	}
 	if err := p.tree.createSubTree(keys, startToken.Position); err != nil {
 		p.raiseError(key, "%s", err)
 	}
 	p.assume(tokenRightBracket)
 	p.currentTable = keys
 	return p.parseStart
 }
 func (p *tomlParser) parseAssign() tomlParserStateFn {
 	key := p.getToken()
 	p.assume(tokenEqual)
-	value := parseRvalue(p)
+
-	var group_key []string
+	value := p.parseRvalue()
-	if len(p.currentGroup) > 0 {
+	var tableKey []string
-		group_key = p.currentGroup
+	if len(p.currentTable) > 0 {
 		tableKey = p.currentTable
 	} else {
-		group_key = make([]string, 0)
+		tableKey = []string{}
 	}
-	// find the group to assign, looking out for arrays of groups
+	// find the table to assign, looking out for arrays of tables
-	var target_node *TomlTree
+	var targetNode *Tree
-	switch node := p.tree.GetPath(group_key).(type) {
+	switch node := p.tree.GetPath(tableKey).(type) {
-	case []*TomlTree:
+	case []*Tree:
-		target_node = node[len(node)-1]
+		targetNode = node[len(node)-1]
-	case *TomlTree:
+	case *Tree:
-		target_node = node
+		targetNode = node
 	default:
-		panic(fmt.Sprintf("Unknown group type for path %v", group_key))
+		p.raiseError(key, "Unknown table type for path: %s",
 			strings.Join(tableKey, "."))
 	}
-	// assign value to the found group
+	// assign value to the found table
-	local_key := []string{key.val}
+	keyVals := []string{key.val}
-	final_key := append(group_key, key.val)
+	if len(keyVals) != 1 {
-	if target_node.GetPath(local_key) != nil {
+		p.raiseError(key, "Invalid key")
 		panic(fmt.Sprintf("the following key was defined twice: %s", strings.Join(final_key, ".")))
 	}
-	target_node.SetPath(local_key, value)
+	keyVal := keyVals[0]
-	return parseStart(p)
+	localKey := []string{keyVal}
 	finalKey := append(tableKey, keyVal)
 	if targetNode.GetPath(localKey) != nil {
 		p.raiseError(key, "The following key was defined twice: %s",
 			strings.Join(finalKey, "."))
 	}
 	var toInsert interface{}
 	switch value.(type) {
 	case *Tree, []*Tree:
 		toInsert = value
 	default:
 		toInsert = &tomlValue{value: value, position: key.Position}
 	}
 	targetNode.values[keyVal] = toInsert
 	return p.parseStart
 }
-func parseRvalue(p *parser) interface{} {
+var numberUnderscoreInvalidRegexp *regexp.Regexp
 var hexNumberUnderscoreInvalidRegexp *regexp.Regexp
 func numberContainsInvalidUnderscore(value string) error {
 	if numberUnderscoreInvalidRegexp.MatchString(value) {
 		return errors.New("invalid use of _ in number")
 	}
 	return nil
 }
 func hexNumberContainsInvalidUnderscore(value string) error {
 	if hexNumberUnderscoreInvalidRegexp.MatchString(value) {
 		return errors.New("invalid use of _ in hex number")
 	}
 	return nil
 }
 func cleanupNumberToken(value string) string {
 	cleanedVal := strings.Replace(value, "_", "", -1)
 	return cleanedVal
 }
 func (p *tomlParser) parseRvalue() interface{} {
 	tok := p.getToken()
 	if tok == nil || tok.typ == tokenEOF {
-		panic("expecting a value")
+		p.raiseError(tok, "expecting a value")
 	}
 	switch tok.typ {
@@ -180,78 +244,187 @@ func parseRvalue(p *parser) interface{} {
 		return true
 	case tokenFalse:
 		return false
 	case tokenInf:
 		if tok.val[0] == '-' {
 			return math.Inf(-1)
 		}
 		return math.Inf(1)
 	case tokenNan:
 		return math.NaN()
 	case tokenInteger:
-		val, err := strconv.ParseInt(tok.val, 10, 64)
+		cleanedVal := cleanupNumberToken(tok.val)
 		var err error
 		var val int64
 		if len(cleanedVal) >= 3 && cleanedVal[0] == '0' {
 			switch cleanedVal[1] {
 			case 'x':
 				err = hexNumberContainsInvalidUnderscore(tok.val)
 				if err != nil {
-			panic(err)
+					p.raiseError(tok, "%s", err)
 				}
 				val, err = strconv.ParseInt(cleanedVal[2:], 16, 64)
 			case 'o':
 				err = numberContainsInvalidUnderscore(tok.val)
 				if err != nil {
 					p.raiseError(tok, "%s", err)
 				}
 				val, err = strconv.ParseInt(cleanedVal[2:], 8, 64)
 			case 'b':
 				err = numberContainsInvalidUnderscore(tok.val)
 				if err != nil {
 					p.raiseError(tok, "%s", err)
 				}
 				val, err = strconv.ParseInt(cleanedVal[2:], 2, 64)
 			default:
 				panic("invalid base") // the lexer should catch this first
 			}
 		} else {
 			err = numberContainsInvalidUnderscore(tok.val)
 			if err != nil {
 				p.raiseError(tok, "%s", err)
 			}
 			val, err = strconv.ParseInt(cleanedVal, 10, 64)
 		}
 		if err != nil {
 			p.raiseError(tok, "%s", err)
 		}
 		return val
 	case tokenFloat:
-		val, err := strconv.ParseFloat(tok.val, 64)
+		err := numberContainsInvalidUnderscore(tok.val)
 		if err != nil {
-			panic(err)
+			p.raiseError(tok, "%s", err)
 		}
 		cleanedVal := cleanupNumberToken(tok.val)
 		val, err := strconv.ParseFloat(cleanedVal, 64)
 		if err != nil {
 			p.raiseError(tok, "%s", err)
 		}
 		return val
 	case tokenDate:
-		val, err := time.Parse(time.RFC3339, tok.val)
+		val, err := time.ParseInLocation(time.RFC3339Nano, tok.val, time.UTC)
 		if err != nil {
-			panic(err)
+			p.raiseError(tok, "%s", err)
 		}
 		return val
 	case tokenLeftBracket:
-		return parseArray(p)
+		return p.parseArray()
 	case tokenLeftCurlyBrace:
 		return p.parseInlineTable()
 	case tokenEqual:
 		p.raiseError(tok, "cannot have multiple equals for the same key")
 	case tokenError:
-		panic(tok.val)
+		p.raiseError(tok, "%s", tok)
 	}
-	panic("never reached")
+	p.raiseError(tok, "never reached")
 	return nil
 }
-func parseArray(p *parser) []interface{} {
+func tokenIsComma(t *token) bool {
-	array := make([]interface{}, 0)
+	return t != nil && t.typ == tokenComma
 }
 func (p *tomlParser) parseInlineTable() *Tree {
 	tree := newTree()
 	var previous *token
 Loop:
 	for {
 		follow := p.peek()
 		if follow == nil || follow.typ == tokenEOF {
 			p.raiseError(follow, "unterminated inline table")
 		}
 		switch follow.typ {
 		case tokenRightCurlyBrace:
 			p.getToken()
 			break Loop
 		case tokenKey:
 			if !tokenIsComma(previous) && previous != nil {
 				p.raiseError(follow, "comma expected between fields in inline table")
 			}
 			key := p.getToken()
 			p.assume(tokenEqual)
 			value := p.parseRvalue()
 			tree.Set(key.val, value)
 		case tokenComma:
 			if previous == nil {
 				p.raiseError(follow, "inline table cannot start with a comma")
 			}
 			if tokenIsComma(previous) {
 				p.raiseError(follow, "need field between two commas in inline table")
 			}
 			p.getToken()
 		default:
 			p.raiseError(follow, "unexpected token type in inline table: %s", follow.String())
 		}
 		previous = follow
 	}
 	if tokenIsComma(previous) {
 		p.raiseError(previous, "trailing comma at the end of inline table")
 	}
 	return tree
 }
 func (p *tomlParser) parseArray() interface{} {
 	var array []interface{}
 	arrayType := reflect.TypeOf(nil)
 	for {
 		follow := p.peek()
 		if follow == nil || follow.typ == tokenEOF {
-			panic("unterminated array")
+			p.raiseError(follow, "unterminated array")
 		}
 		if follow.typ == tokenRightBracket {
 			p.getToken()
-			return array
+			break
 		}
-		val := parseRvalue(p)
+		val := p.parseRvalue()
 		if arrayType == nil {
 			arrayType = reflect.TypeOf(val)
 		}
 		if reflect.TypeOf(val) != arrayType {
-			panic("mixed types in array")
+			p.raiseError(follow, "mixed types in array")
 		}
 		array = append(array, val)
 		follow = p.peek()
-		if follow == nil {
+		if follow == nil || follow.typ == tokenEOF {
-			panic("unterminated array")
+			p.raiseError(follow, "unterminated array")
 		}
 		if follow.typ != tokenRightBracket && follow.typ != tokenComma {
-			panic("missing comma")
+			p.raiseError(follow, "missing comma")
 		}
 		if follow.typ == tokenComma {
 			p.getToken()
 		}
 	}
 	// An array of Trees is actually an array of inline
 	// tables, which is a shorthand for a table array. If the
 	// array was not converted from []interface{} to []*Tree,
 	// the two notations would not be equivalent.
 	if arrayType == reflect.TypeOf(newTree()) {
 		tomlArray := make([]*Tree, len(array))
 		for i, v := range array {
 			tomlArray[i] = v.(*Tree)
 		}
 		return tomlArray
 	}
 	return array
 }
-func parse(flow chan token) *TomlTree {
+func parseToml(flow []token) *Tree {
-	result := make(TomlTree)
+	result := newTree()
-	parser := &parser{
+	result.position = Position{1, 1}
 	parser := &tomlParser{
 		flowIdx:       0,
 		flow:          flow,
-		tree:          &result,
+		tree:          result,
-		tokensBuffer:  make([]token, 0),
+		currentTable:  make([]string, 0),
-		currentGroup:  make([]string, 0),
+		seenTableKeys: make([]string, 0),
 		seenGroupKeys: make([]string, 0),
 	}
 	parser.run()
-	return parser.tree
+	return result
 }
 func init() {
 	numberUnderscoreInvalidRegexp = regexp.MustCompile(`([^\d]_|_[^\d])|_$|^_`)
 	hexNumberUnderscoreInvalidRegexp = regexp.MustCompile(`(^0x_)|([^\da-f]_|_[^\da-f])|_$|^_`)
 }
@@ -2,25 +2,35 @@ package toml
 import (
 	"fmt"
 	"math"
 	"reflect"
 	"testing"
 	"time"
 	"github.com/davecgh/go-spew/spew"
 )
-func assertTree(t *testing.T, tree *TomlTree, err error, ref map[string]interface{}) {
+func assertSubTree(t *testing.T, path []string, tree *Tree, err error, ref map[string]interface{}) {
 	if err != nil {
 		t.Error("Non-nil error:", err.Error())
 		return
 	}
 	for k, v := range ref {
-		node := tree.Get(k)
+		nextPath := append(path, k)
-		switch cast_node := node.(type) {
+		t.Log("asserting path", nextPath)
-		case []*TomlTree:
+		// NOTE: directly access key instead of resolve by path
-			for idx, item := range cast_node {
+		// NOTE: see TestSpecialKV
-				assertTree(t, item, err, v.([]map[string]interface{})[idx])
+		switch node := tree.GetPath([]string{k}).(type) {
 		case []*Tree:
 			t.Log("\tcomparing key", nextPath, "by array iteration")
 			for idx, item := range node {
 				assertSubTree(t, nextPath, item, err, v.([]map[string]interface{})[idx])
 			}
-		case *TomlTree:
+		case *Tree:
-			assertTree(t, cast_node, err, v.(map[string]interface{}))
+			t.Log("\tcomparing key", nextPath, "by subtree assestion")
 			assertSubTree(t, nextPath, node, err, v.(map[string]interface{}))
 		default:
 			t.Log("\tcomparing key", nextPath, "by string representation because it's of type", reflect.TypeOf(node))
 			if fmt.Sprintf("%v", node) != fmt.Sprintf("%v", v) {
 				t.Errorf("was expecting %v at %v but got %v", v, k, node)
 			}
@@ -28,9 +38,15 @@ func assertTree(t *testing.T, tree *TomlTree, err error, ref map[string]interfac
 	}
 }
 func assertTree(t *testing.T, tree *Tree, err error, ref map[string]interface{}) {
 	t.Log("Asserting tree:\n", spew.Sdump(tree))
 	assertSubTree(t, []string{}, tree, err, ref)
 	t.Log("Finished tree assertion.")
 }
 func TestCreateSubTree(t *testing.T) {
-	tree := make(TomlTree)
+	tree := newTree()
-	tree.createSubTree("a.b.c")
+	tree.createSubTree([]string{"a", "b", "c"}, Position{})
 	tree.Set("a.b.c", 42)
 	if tree.Get("a.b.c") != 42 {
 		t.Fail()
@@ -50,6 +66,24 @@ func TestSimpleKV(t *testing.T) {
 	})
 }
 func TestNumberInKey(t *testing.T) {
 	tree, err := Load("hello2 = 42")
 	assertTree(t, tree, err, map[string]interface{}{
 		"hello2": int64(42),
 	})
 }
 func TestIncorrectKeyExtraSquareBracket(t *testing.T) {
 	_, err := Load(`[a]b]
 zyx = 42`)
 	if err == nil {
 		t.Error("Error should have been returned.")
 	}
 	if err.Error() != "(1, 4): unexpected token" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestSimpleNumbers(t *testing.T) {
 	tree, err := Load("a = +42\nb = -21\nc = +4.2\nd = -2.1")
 	assertTree(t, tree, err, map[string]interface{}{
@@ -60,6 +94,116 @@ func TestSimpleNumbers(t *testing.T) {
 	})
 }
 func TestSpecialFloats(t *testing.T) {
 	tree, err := Load(`
 normalinf = inf
 plusinf = +inf
 minusinf = -inf
 normalnan = nan
 plusnan = +nan
 minusnan = -nan
 `)
 	assertTree(t, tree, err, map[string]interface{}{
 		"normalinf": math.Inf(1),
 		"plusinf":   math.Inf(1),
 		"minusinf":  math.Inf(-1),
 		"normalnan": math.NaN(),
 		"plusnan":   math.NaN(),
 		"minusnan":  math.NaN(),
 	})
 }
 func TestHexIntegers(t *testing.T) {
 	tree, err := Load(`a = 0xDEADBEEF`)
 	assertTree(t, tree, err, map[string]interface{}{"a": int64(3735928559)})
 	tree, err = Load(`a = 0xdeadbeef`)
 	assertTree(t, tree, err, map[string]interface{}{"a": int64(3735928559)})
 	tree, err = Load(`a = 0xdead_beef`)
 	assertTree(t, tree, err, map[string]interface{}{"a": int64(3735928559)})
 	_, err = Load(`a = 0x_1`)
 	if err.Error() != "(1, 5): invalid use of _ in hex number" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestOctIntegers(t *testing.T) {
 	tree, err := Load(`a = 0o01234567`)
 	assertTree(t, tree, err, map[string]interface{}{"a": int64(342391)})
 	tree, err = Load(`a = 0o755`)
 	assertTree(t, tree, err, map[string]interface{}{"a": int64(493)})
 	_, err = Load(`a = 0o_1`)
 	if err.Error() != "(1, 5): invalid use of _ in number" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestBinIntegers(t *testing.T) {
 	tree, err := Load(`a = 0b11010110`)
 	assertTree(t, tree, err, map[string]interface{}{"a": int64(214)})
 	_, err = Load(`a = 0b_1`)
 	if err.Error() != "(1, 5): invalid use of _ in number" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestBadIntegerBase(t *testing.T) {
 	_, err := Load(`a = 0k1`)
 	if err.Error() != "(1, 5): unknown number base: k. possible options are x (hex) o (octal) b (binary)" {
 		t.Error("Error should have been returned.")
 	}
 }
 func TestIntegerNoDigit(t *testing.T) {
 	_, err := Load(`a = 0b`)
 	if err.Error() != "(1, 5): number needs at least one digit" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestNumbersWithUnderscores(t *testing.T) {
 	tree, err := Load("a = 1_000")
 	assertTree(t, tree, err, map[string]interface{}{
 		"a": int64(1000),
 	})
 	tree, err = Load("a = 5_349_221")
 	assertTree(t, tree, err, map[string]interface{}{
 		"a": int64(5349221),
 	})
 	tree, err = Load("a = 1_2_3_4_5")
 	assertTree(t, tree, err, map[string]interface{}{
 		"a": int64(12345),
 	})
 	tree, err = Load("flt8 = 9_224_617.445_991_228_313")
 	assertTree(t, tree, err, map[string]interface{}{
 		"flt8": float64(9224617.445991228313),
 	})
 	tree, err = Load("flt9 = 1e1_00")
 	assertTree(t, tree, err, map[string]interface{}{
 		"flt9": float64(1e100),
 	})
 }
 func TestFloatsWithExponents(t *testing.T) {
 	tree, err := Load("a = 5e+22\nb = 5E+22\nc = -5e+22\nd = -5e-22\ne = 6.626e-34")
 	assertTree(t, tree, err, map[string]interface{}{
 		"a": float64(5e+22),
 		"b": float64(5E+22),
 		"c": float64(-5e+22),
 		"d": float64(-5e-22),
 		"e": float64(6.626e-34),
 	})
 }
 func TestSimpleDate(t *testing.T) {
 	tree, err := Load("a = 1979-05-27T07:32:00Z")
 	assertTree(t, tree, err, map[string]interface{}{
@@ -67,6 +211,20 @@ func TestSimpleDate(t *testing.T) {
 	})
 }
 func TestDateOffset(t *testing.T) {
 	tree, err := Load("a = 1979-05-27T00:32:00-07:00")
 	assertTree(t, tree, err, map[string]interface{}{
 		"a": time.Date(1979, time.May, 27, 0, 32, 0, 0, time.FixedZone("", -7*60*60)),
 	})
 }
 func TestDateNano(t *testing.T) {
 	tree, err := Load("a = 1979-05-27T00:32:00.999999999-07:00")
 	assertTree(t, tree, err, map[string]interface{}{
 		"a": time.Date(1979, time.May, 27, 0, 32, 0, 999999999, time.FixedZone("", -7*60*60)),
 	})
 }
 func TestSimpleString(t *testing.T) {
 	tree, err := Load("a = \"hello world\"")
 	assertTree(t, tree, err, map[string]interface{}{
@@ -74,6 +232,43 @@ func TestSimpleString(t *testing.T) {
 	})
 }
 func TestSpaceKey(t *testing.T) {
 	tree, err := Load("\"a b\" = \"hello world\"")
 	assertTree(t, tree, err, map[string]interface{}{
 		"a b": "hello world",
 	})
 }
 func TestDoubleQuotedKey(t *testing.T) {
 	tree, err := Load(`
 	"key"        = "a"
 	"\t"         = "b"
 	"\U0001F914" = "c"
 	"\u2764"     = "d"
 	`)
 	assertTree(t, tree, err, map[string]interface{}{
 		"key":        "a",
 		"\t":         "b",
 		"\U0001F914": "c",
 		"\u2764":     "d",
 	})
 }
 func TestSingleQuotedKey(t *testing.T) {
 	tree, err := Load(`
 	'key'        = "a"
 	'\t'         = "b"
 	'\U0001F914' = "c"
 	'\u2764'     = "d"
 	`)
 	assertTree(t, tree, err, map[string]interface{}{
 		`key`:        "a",
 		`\t`:         "b",
 		`\U0001F914`: "c",
 		`\u2764`:     "d",
 	})
 }
 func TestStringEscapables(t *testing.T) {
 	tree, err := Load("a = \"a \\n b\"")
 	assertTree(t, tree, err, map[string]interface{}{
@@ -96,6 +291,16 @@ func TestStringEscapables(t *testing.T) {
 	})
 }
 func TestEmptyQuotedString(t *testing.T) {
 	tree, err := Load(`[""]
 "" = 1`)
 	assertTree(t, tree, err, map[string]interface{}{
 		"": map[string]interface{}{
 			"": int64(1),
 		},
 	})
 }
 func TestBools(t *testing.T) {
 	tree, err := Load("a = true\nb = false")
 	assertTree(t, tree, err, map[string]interface{}{
@@ -107,7 +312,48 @@ func TestBools(t *testing.T) {
 func TestNestedKeys(t *testing.T) {
 	tree, err := Load("[a.b.c]\nd = 42")
 	assertTree(t, tree, err, map[string]interface{}{
-		"a.b.c.d": int64(42),
+		"a": map[string]interface{}{
 			"b": map[string]interface{}{
 				"c": map[string]interface{}{
 					"d": int64(42),
 				},
 			},
 		},
 	})
 }
 func TestNestedQuotedUnicodeKeys(t *testing.T) {
 	tree, err := Load("[ j . \"ʞ\" . l ]\nd = 42")
 	assertTree(t, tree, err, map[string]interface{}{
 		"j": map[string]interface{}{
 			"ʞ": map[string]interface{}{
 				"l": map[string]interface{}{
 					"d": int64(42),
 				},
 			},
 		},
 	})
 	tree, err = Load("[ g . h . i ]\nd = 42")
 	assertTree(t, tree, err, map[string]interface{}{
 		"g": map[string]interface{}{
 			"h": map[string]interface{}{
 				"i": map[string]interface{}{
 					"d": int64(42),
 				},
 			},
 		},
 	})
 	tree, err = Load("[ d.e.f ]\nk = 42")
 	assertTree(t, tree, err, map[string]interface{}{
 		"d": map[string]interface{}{
 			"e": map[string]interface{}{
 				"f": map[string]interface{}{
 					"k": int64(42),
 				},
 			},
 		},
 	})
 }
@@ -147,25 +393,36 @@ func TestArrayMultiline(t *testing.T) {
 func TestArrayNested(t *testing.T) {
 	tree, err := Load("a = [[42, 21], [10]]")
 	assertTree(t, tree, err, map[string]interface{}{
-		"a": [][]int64{[]int64{int64(42), int64(21)}, []int64{int64(10)}},
+		"a": [][]int64{{int64(42), int64(21)}, {int64(10)}},
 	})
 }
 func TestNestedArrayComment(t *testing.T) {
 	tree, err := Load(`
 someArray = [
 # does not work
 ["entry1"]
 ]`)
 	assertTree(t, tree, err, map[string]interface{}{
 		"someArray": [][]string{{"entry1"}},
 	})
 }
 func TestNestedEmptyArrays(t *testing.T) {
 	tree, err := Load("a = [[[]]]")
 	assertTree(t, tree, err, map[string]interface{}{
-		"a": [][][]interface{}{[][]interface{}{[]interface{}{}}},
+		"a": [][][]interface{}{{{}}},
 	})
 }
 func TestArrayMixedTypes(t *testing.T) {
 	_, err := Load("a = [42, 16.0]")
-	if err.Error() != "mixed types in array" {
+	if err.Error() != "(1, 10): mixed types in array" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("a = [42, \"hello\"]")
-	if err.Error() != "mixed types in array" {
+	if err.Error() != "(1, 11): mixed types in array" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
@@ -173,20 +430,42 @@ func TestArrayMixedTypes(t *testing.T) {
 func TestArrayNestedStrings(t *testing.T) {
 	tree, err := Load("data = [ [\"gamma\", \"delta\"], [\"Foo\"] ]")
 	assertTree(t, tree, err, map[string]interface{}{
-		"data": [][]string{[]string{"gamma", "delta"}, []string{"Foo"}},
+		"data": [][]string{{"gamma", "delta"}, {"Foo"}},
 	})
 }
 func TestParseUnknownRvalue(t *testing.T) {
 	_, err := Load("a = !bssss")
 	if err == nil {
 		t.Error("Expecting a parse error")
 	}
 	_, err = Load("a = /b")
 	if err == nil {
 		t.Error("Expecting a parse error")
 	}
 }
 func TestMissingValue(t *testing.T) {
 	_, err := Load("a = ")
-	if err.Error() != "expecting a value" {
+	if err.Error() != "(1, 5): expecting a value" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestUnterminatedArray(t *testing.T) {
 	_, err := Load("a = [1,")
-	if err.Error() != "unterminated array" {
+	if err.Error() != "(1, 8): unterminated array" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("a = [1")
 	if err.Error() != "(1, 7): unterminated array" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("a = [1 2")
 	if err.Error() != "(1, 8): missing comma" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
@@ -212,23 +491,97 @@ func TestArrayWithExtraCommaComment(t *testing.T) {
 	})
 }
 func TestSimpleInlineGroup(t *testing.T) {
 	tree, err := Load("key = {a = 42}")
 	assertTree(t, tree, err, map[string]interface{}{
 		"key": map[string]interface{}{
 			"a": int64(42),
 		},
 	})
 }
 func TestDoubleInlineGroup(t *testing.T) {
 	tree, err := Load("key = {a = 42, b = \"foo\"}")
 	assertTree(t, tree, err, map[string]interface{}{
 		"key": map[string]interface{}{
 			"a": int64(42),
 			"b": "foo",
 		},
 	})
 }
 func TestExampleInlineGroup(t *testing.T) {
 	tree, err := Load(`name = { first = "Tom", last = "Preston-Werner" }
 point = { x = 1, y = 2 }`)
 	assertTree(t, tree, err, map[string]interface{}{
 		"name": map[string]interface{}{
 			"first": "Tom",
 			"last":  "Preston-Werner",
 		},
 		"point": map[string]interface{}{
 			"x": int64(1),
 			"y": int64(2),
 		},
 	})
 }
 func TestExampleInlineGroupInArray(t *testing.T) {
 	tree, err := Load(`points = [{ x = 1, y = 2 }]`)
 	assertTree(t, tree, err, map[string]interface{}{
 		"points": []map[string]interface{}{
 			{
 				"x": int64(1),
 				"y": int64(2),
 			},
 		},
 	})
 }
 func TestInlineTableUnterminated(t *testing.T) {
 	_, err := Load("foo = {")
 	if err.Error() != "(1, 8): unterminated inline table" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestInlineTableCommaExpected(t *testing.T) {
 	_, err := Load("foo = {hello = 53 test = foo}")
 	if err.Error() != "(1, 19): comma expected between fields in inline table" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestInlineTableCommaStart(t *testing.T) {
 	_, err := Load("foo = {, hello = 53}")
 	if err.Error() != "(1, 8): inline table cannot start with a comma" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestInlineTableDoubleComma(t *testing.T) {
 	_, err := Load("foo = {hello = 53,, foo = 17}")
 	if err.Error() != "(1, 19): need field between two commas in inline table" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestDuplicateGroups(t *testing.T) {
 	_, err := Load("[foo]\na=2\n[foo]b=3")
-	if err.Error() != "duplicated tables" {
+	if err.Error() != "(3, 2): duplicated tables" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestDuplicateKeys(t *testing.T) {
 	_, err := Load("foo = 2\nfoo = 3")
-	if err.Error() != "the following key was defined twice: foo" {
+	if err.Error() != "(2, 1): The following key was defined twice: foo" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestEmptyIntermediateTable(t *testing.T) {
 	_, err := Load("[foo..bar]")
-	if err.Error() != "empty intermediate table" {
+	if err.Error() != "(1, 2): invalid table array key: empty table key" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
@@ -249,19 +602,20 @@ func TestImplicitDeclarationBefore(t *testing.T) {
 func TestFloatsWithoutLeadingZeros(t *testing.T) {
 	_, err := Load("a = .42")
-	if err.Error() != "cannot start float with a dot" {
+	if err.Error() != "(1, 5): cannot start float with a dot" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("a = -.42")
-	if err.Error() != "cannot start float with a dot" {
+	if err.Error() != "(1, 5): cannot start float with a dot" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestMissingFile(t *testing.T) {
 	_, err := LoadFile("foo.toml")
-	if err.Error() != "open foo.toml: no such file or directory" {
+	if err.Error() != "open foo.toml: no such file or directory" &&
 		err.Error() != "open foo.toml: The system cannot find the file specified." {
 		t.Error("Bad error message:", err.Error())
 	}
 }
@@ -271,19 +625,70 @@ func TestParseFile(t *testing.T) {
 	assertTree(t, tree, err, map[string]interface{}{
 		"title": "TOML Example",
-		"owner.name":              "Tom Preston-Werner",
+		"owner": map[string]interface{}{
-		"owner.organization":      "GitHub",
+			"name":         "Tom Preston-Werner",
-		"owner.bio":               "GitHub Cofounder & CEO\nLikes tater tots and beer.",
+			"organization": "GitHub",
-		"owner.dob":               time.Date(1979, time.May, 27, 7, 32, 0, 0, time.UTC),
+			"bio":          "GitHub Cofounder & CEO\nLikes tater tots and beer.",
-		"database.server":         "192.168.1.1",
+			"dob":          time.Date(1979, time.May, 27, 7, 32, 0, 0, time.UTC),
-		"database.ports":          []int64{8001, 8001, 8002},
+		},
-		"database.connection_max": 5000,
+		"database": map[string]interface{}{
-		"database.enabled":        true,
+			"server":         "192.168.1.1",
-		"servers.alpha.ip":        "10.0.0.1",
+			"ports":          []int64{8001, 8001, 8002},
-		"servers.alpha.dc":        "eqdc10",
+			"connection_max": 5000,
-		"servers.beta.ip":         "10.0.0.2",
+			"enabled":        true,
-		"servers.beta.dc":         "eqdc10",
+		},
-		"clients.data":            []interface{}{[]string{"gamma", "delta"}, []int64{1, 2}},
+		"servers": map[string]interface{}{
 			"alpha": map[string]interface{}{
 				"ip": "10.0.0.1",
 				"dc": "eqdc10",
 			},
 			"beta": map[string]interface{}{
 				"ip": "10.0.0.2",
 				"dc": "eqdc10",
 			},
 		},
 		"clients": map[string]interface{}{
 			"data": []interface{}{
 				[]string{"gamma", "delta"},
 				[]int64{1, 2},
 			},
 		},
 	})
 }
 func TestParseFileCRLF(t *testing.T) {
 	tree, err := LoadFile("example-crlf.toml")
 	assertTree(t, tree, err, map[string]interface{}{
 		"title": "TOML Example",
 		"owner": map[string]interface{}{
 			"name":         "Tom Preston-Werner",
 			"organization": "GitHub",
 			"bio":          "GitHub Cofounder & CEO\nLikes tater tots and beer.",
 			"dob":          time.Date(1979, time.May, 27, 7, 32, 0, 0, time.UTC),
 		},
 		"database": map[string]interface{}{
 			"server":         "192.168.1.1",
 			"ports":          []int64{8001, 8001, 8002},
 			"connection_max": 5000,
 			"enabled":        true,
 		},
 		"servers": map[string]interface{}{
 			"alpha": map[string]interface{}{
 				"ip": "10.0.0.1",
 				"dc": "eqdc10",
 			},
 			"beta": map[string]interface{}{
 				"ip": "10.0.0.2",
 				"dc": "eqdc10",
 			},
 		},
 		"clients": map[string]interface{}{
 			"data": []interface{}{
 				[]string{"gamma", "delta"},
 				[]int64{1, 2},
 			},
 		},
 	})
 }
@@ -299,41 +704,196 @@ func TestParseKeyGroupArray(t *testing.T) {
 	})
 }
-func TestToTomlValue(t *testing.T) {
+func TestParseKeyGroupArrayUnfinished(t *testing.T) {
 	_, err := Load("[[foo.bar]\na = 42")
 	if err.Error() != "(1, 10): was expecting token [[, but got unclosed table array key instead" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("[[foo.[bar]\na = 42")
 	if err.Error() != "(1, 3): unexpected token table array key cannot contain ']', was expecting a table array key" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestParseKeyGroupArrayQueryExample(t *testing.T) {
 	tree, err := Load(`
      [[book]]
      title = "The Stand"
      author = "Stephen King"
      [[book]]
      title = "For Whom the Bell Tolls"
      author = "Ernest Hemmingway"
      [[book]]
      title = "Neuromancer"
      author = "William Gibson"
    `)
 	assertTree(t, tree, err, map[string]interface{}{
 		"book": []map[string]interface{}{
 			{"title": "The Stand", "author": "Stephen King"},
 			{"title": "For Whom the Bell Tolls", "author": "Ernest Hemmingway"},
 			{"title": "Neuromancer", "author": "William Gibson"},
 		},
 	})
 }
 func TestParseKeyGroupArraySpec(t *testing.T) {
 	tree, err := Load("[[fruit]]\n name=\"apple\"\n [fruit.physical]\n color=\"red\"\n shape=\"round\"\n [[fruit]]\n name=\"banana\"")
 	assertTree(t, tree, err, map[string]interface{}{
 		"fruit": []map[string]interface{}{
 			{"name": "apple", "physical": map[string]interface{}{"color": "red", "shape": "round"}},
 			{"name": "banana"},
 		},
 	})
 }
 func TestTomlValueStringRepresentation(t *testing.T) {
 	for idx, item := range []struct {
 		Value  interface{}
 		Expect string
 	}{
 		{int64(12345), "12345"},
 		{uint64(50), "50"},
 		{float64(123.45), "123.45"},
-		{bool(true), "true"},
+		{true, "true"},
 		{"hello world", "\"hello world\""},
 		{"\b\t\n\f\r\"\\", "\"\\b\\t\\n\\f\\r\\\"\\\\\""},
 		{"\x05", "\"\\u0005\""},
 		{time.Date(1979, time.May, 27, 7, 32, 0, 0, time.UTC),
 			"1979-05-27T07:32:00Z"},
 		{[]interface{}{"gamma", "delta"},
-			"[\n  \"gamma\",\n  \"delta\",\n]"},
+			"[\"gamma\",\"delta\"]"},
 		{nil, ""},
 	} {
-		result := toTomlValue(item.Value, 0)
+		result, err := tomlValueStringRepresentation(item.Value, "", false)
 		if err != nil {
 			t.Errorf("Test %d - unexpected error: %s", idx, err)
 		}
 		if result != item.Expect {
 			t.Errorf("Test %d - got '%s', expected '%s'", idx, result, item.Expect)
 		}
 	}
 }
-func TestToString(t *testing.T) {
+func TestToStringMapStringString(t *testing.T) {
-	tree := &TomlTree{
+	tree, err := TreeFromMap(map[string]interface{}{"m": map[string]interface{}{"v": "abc"}})
-		"foo": &TomlTree{
+	if err != nil {
-			"bar": []*TomlTree{
+		t.Fatalf("unexpected error: %s", err)
 				{"a": int64(42)},
 				{"a": int64(69)},
 			},
 		},
 	}
-	result := tree.ToString()
+	want := "\n[m]\n  v = \"abc\"\n"
-	expected := "\n[foo]\n\n[[foo.bar]]\na = 42\n\n[[foo.bar]]\na = 69\n"
+	got := tree.String()
-	if result != expected {
+
-		t.Errorf("Expected got '%s', expected '%s'", result, expected)
+	if got != want {
 		t.Errorf("want:\n%q\ngot:\n%q", want, got)
 	}
 }
 func assertPosition(t *testing.T, text string, ref map[string]Position) {
 	tree, err := Load(text)
 	if err != nil {
 		t.Errorf("Error loading document text: `%v`", text)
 		t.Errorf("Error: %v", err)
 	}
 	for path, pos := range ref {
 		testPos := tree.GetPosition(path)
 		if testPos.Invalid() {
 			t.Errorf("Failed to query tree path or path has invalid position: %s", path)
 		} else if pos != testPos {
 			t.Errorf("Expected position %v, got %v instead", pos, testPos)
 		}
 	}
 }
 func TestDocumentPositions(t *testing.T) {
 	assertPosition(t,
 		"[foo]\nbar=42\nbaz=69",
 		map[string]Position{
 			"":        {1, 1},
 			"foo":     {1, 1},
 			"foo.bar": {2, 1},
 			"foo.baz": {3, 1},
 		})
 }
 func TestDocumentPositionsWithSpaces(t *testing.T) {
 	assertPosition(t,
 		"  [foo]\n  bar=42\n  baz=69",
 		map[string]Position{
 			"":        {1, 1},
 			"foo":     {1, 3},
 			"foo.bar": {2, 3},
 			"foo.baz": {3, 3},
 		})
 }
 func TestDocumentPositionsWithGroupArray(t *testing.T) {
 	assertPosition(t,
 		"[[foo]]\nbar=42\nbaz=69",
 		map[string]Position{
 			"":        {1, 1},
 			"foo":     {1, 1},
 			"foo.bar": {2, 1},
 			"foo.baz": {3, 1},
 		})
 }
 func TestNestedTreePosition(t *testing.T) {
 	assertPosition(t,
 		"[foo.bar]\na=42\nb=69",
 		map[string]Position{
 			"":          {1, 1},
 			"foo":       {1, 1},
 			"foo.bar":   {1, 1},
 			"foo.bar.a": {2, 1},
 			"foo.bar.b": {3, 1},
 		})
 }
 func TestInvalidGroupArray(t *testing.T) {
 	_, err := Load("[table#key]\nanswer = 42")
 	if err == nil {
 		t.Error("Should error")
 	}
 	_, err = Load("[foo.[bar]\na = 42")
 	if err.Error() != "(1, 2): unexpected token table key cannot contain ']', was expecting a table key" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestDoubleEqual(t *testing.T) {
 	_, err := Load("foo= = 2")
 	if err.Error() != "(1, 6): cannot have multiple equals for the same key" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestGroupArrayReassign(t *testing.T) {
 	_, err := Load("[hello]\n[[hello]]")
 	if err.Error() != "(2, 3): key \"hello\" is already assigned and not of type table array" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
 func TestInvalidFloatParsing(t *testing.T) {
 	_, err := Load("a=1e_2")
 	if err.Error() != "(1, 3): invalid use of _ in number" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("a=1e2_")
 	if err.Error() != "(1, 3): invalid use of _ in number" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("a=1__2")
 	if err.Error() != "(1, 3): invalid use of _ in number" {
 		t.Error("Bad error message:", err.Error())
 	}
 	_, err = Load("a=_1_2")
 	if err.Error() != "(1, 3): cannot start number with underscore" {
 		t.Error("Bad error message:", err.Error())
 	}
 }
@@ -0,0 +1,29 @@
 // Position support for go-toml
 package toml
 import (
 	"fmt"
 )
 // Position of a document element within a TOML document.
 //
 // Line and Col are both 1-indexed positions for the element's line number and
 // column number, respectively.  Values of zero or less will cause Invalid(),
 // to return true.
 type Position struct {
 	Line int // line within the document
 	Col  int // column within the line
 }
 // String representation of the position.
 // Displays 1-indexed line and column numbers.
 func (p Position) String() string {
 	return fmt.Sprintf("(%d, %d)", p.Line, p.Col)
 }
 // Invalid returns whether or not the position is valid (i.e. with negative or
 // null values)
 func (p Position) Invalid() bool {
 	return p.Line <= 0 || p.Col <= 0
 }
@@ -0,0 +1,29 @@
 // Testing support for go-toml
 package toml
 import (
 	"testing"
 )
 func TestPositionString(t *testing.T) {
 	p := Position{123, 456}
 	expected := "(123, 456)"
 	value := p.String()
 	if value != expected {
 		t.Errorf("Expected %v, got %v instead", expected, value)
 	}
 }
 func TestInvalid(t *testing.T) {
 	for i, v := range []Position{
 		{0, 1234},
 		{1234, 0},
 		{0, 0},
 	} {
 		if !v.Invalid() {
 			t.Errorf("Position at %v is valid: %v", i, v)
 		}
 	}
 }
@@ -0,0 +1,175 @@
 // Package query performs JSONPath-like queries on a TOML document.
 //
 // The query path implementation is based loosely on the JSONPath specification:
 // http://goessner.net/articles/JsonPath/.
 //
 // The idea behind a query path is to allow quick access to any element, or set
 // of elements within TOML document, with a single expression.
 //
 //   result, err := query.CompileAndExecute("$.foo.bar.baz", tree)
 //
 // This is roughly equivalent to:
 //
 //   next := tree.Get("foo")
 //   if next != nil {
 //     next = next.Get("bar")
 //     if next != nil {
 //       next = next.Get("baz")
 //     }
 //   }
 //   result := next
 //
 // err is nil if any parsing exception occurs.
 //
 // If no node in the tree matches the query, result will simply contain an empty list of
 // items.
 //
 // As illustrated above, the query path is much more efficient, especially since
 // the structure of the TOML file can vary.  Rather than making assumptions about
 // a document's structure, a query allows the programmer to make structured
 // requests into the document, and get zero or more values as a result.
 //
 // Query syntax
 //
 // The syntax of a query begins with a root token, followed by any number
 // sub-expressions:
 //
 //   $
 //                    Root of the TOML tree.  This must always come first.
 //   .name
 //                    Selects child of this node, where 'name' is a TOML key
 //                    name.
 //   ['name']
 //                    Selects child of this node, where 'name' is a string
 //                    containing a TOML key name.
 //   [index]
 //                    Selcts child array element at 'index'.
 //   ..expr
 //                    Recursively selects all children, filtered by an a union,
 //                    index, or slice expression.
 //   ..*
 //                    Recursive selection of all nodes at this point in the
 //                    tree.
 //   .*
 //                    Selects all children of the current node.
 //   [expr,expr]
 //                    Union operator - a logical 'or' grouping of two or more
 //                    sub-expressions: index, key name, or filter.
 //   [start:end:step]
 //                    Slice operator - selects array elements from start to
 //                    end-1, at the given step.  All three arguments are
 //                    optional.
 //   [?(filter)]
 //                    Named filter expression - the function 'filter' is
 //                    used to filter children at this node.
 //
 // Query Indexes And Slices
 //
 // Index expressions perform no bounds checking, and will contribute no
 // values to the result set if the provided index or index range is invalid.
 // Negative indexes represent values from the end of the array, counting backwards.
 //
 //   // select the last index of the array named 'foo'
 //   query.CompileAndExecute("$.foo[-1]", tree)
 //
 // Slice expressions are supported, by using ':' to separate a start/end index pair.
 //
 //   // select up to the first five elements in the array
 //   query.CompileAndExecute("$.foo[0:5]", tree)
 //
 // Slice expressions also allow negative indexes for the start and stop
 // arguments.
 //
 //   // select all array elements.
 //   query.CompileAndExecute("$.foo[0:-1]", tree)
 //
 // Slice expressions may have an optional stride/step parameter:
 //
 //   // select every other element
 //   query.CompileAndExecute("$.foo[0:-1:2]", tree)
 //
 // Slice start and end parameters are also optional:
 //
 //   // these are all equivalent and select all the values in the array
 //   query.CompileAndExecute("$.foo[:]", tree)
 //   query.CompileAndExecute("$.foo[0:]", tree)
 //   query.CompileAndExecute("$.foo[:-1]", tree)
 //   query.CompileAndExecute("$.foo[0:-1:]", tree)
 //   query.CompileAndExecute("$.foo[::1]", tree)
 //   query.CompileAndExecute("$.foo[0::1]", tree)
 //   query.CompileAndExecute("$.foo[:-1:1]", tree)
 //   query.CompileAndExecute("$.foo[0:-1:1]", tree)
 //
 // Query Filters
 //
 // Query filters are used within a Union [,] or single Filter [] expression.
 // A filter only allows nodes that qualify through to the next expression,
 // and/or into the result set.
 //
 //   // returns children of foo that are permitted by the 'bar' filter.
 //   query.CompileAndExecute("$.foo[?(bar)]", tree)
 //
 // There are several filters provided with the library:
 //
 //   tree
 //          Allows nodes of type Tree.
 //   int
 //          Allows nodes of type int64.
 //   float
 //          Allows nodes of type float64.
 //   string
 //          Allows nodes of type string.
 //   time
 //          Allows nodes of type time.Time.
 //   bool
 //          Allows nodes of type bool.
 //
 // Query Results
 //
 // An executed query returns a Result object.  This contains the nodes
 // in the TOML tree that qualify the query expression.  Position information
 // is also available for each value in the set.
 //
 //   // display the results of a query
 //   results := query.CompileAndExecute("$.foo.bar.baz", tree)
 //   for idx, value := results.Values() {
 //       fmt.Println("%v: %v", results.Positions()[idx], value)
 //   }
 //
 // Compiled Queries
 //
 // Queries may be executed directly on a Tree object, or compiled ahead
 // of time and executed discretely.  The former is more convenient, but has the
 // penalty of having to recompile the query expression each time.
 //
 //   // basic query
 //   results := query.CompileAndExecute("$.foo.bar.baz", tree)
 //
 //   // compiled query
 //   query, err := toml.Compile("$.foo.bar.baz")
 //   results := query.Execute(tree)
 //
 //   // run the compiled query again on a different tree
 //   moreResults := query.Execute(anotherTree)
 //
 // User Defined Query Filters
 //
 // Filter expressions may also be user defined by using the SetFilter()
 // function on the Query object.  The function must return true/false, which
 // signifies if the passed node is kept or discarded, respectively.
 //
 //   // create a query that references a user-defined filter
 //   query, _ := query.Compile("$[?(bazOnly)]")
 //
 //   // define the filter, and assign it to the query
 //   query.SetFilter("bazOnly", func(node interface{}) bool{
 //       if tree, ok := node.(*Tree); ok {
 //           return tree.Has("baz")
 //       }
 //       return false  // reject all other node types
 //   })
 //
 //   // run the query
 //   query.Execute(tree)
 //
 package query
@@ -0,0 +1,357 @@
 // TOML JSONPath lexer.
 //
 // Written using the principles developed by Rob Pike in
 // http://www.youtube.com/watch?v=HxaD_trXwRE
 package query
 import (
 	"fmt"
 	"github.com/pelletier/go-toml"
 	"strconv"
 	"strings"
 	"unicode/utf8"
 )
 // Lexer state function
 type queryLexStateFn func() queryLexStateFn
 // Lexer definition
 type queryLexer struct {
 	input      string
 	start      int
 	pos        int
 	width      int
 	tokens     chan token
 	depth      int
 	line       int
 	col        int
 	stringTerm string
 }
 func (l *queryLexer) run() {
 	for state := l.lexVoid; state != nil; {
 		state = state()
 	}
 	close(l.tokens)
 }
 func (l *queryLexer) nextStart() {
 	// iterate by runes (utf8 characters)
 	// search for newlines and advance line/col counts
 	for i := l.start; i < l.pos; {
 		r, width := utf8.DecodeRuneInString(l.input[i:])
 		if r == '\n' {
 			l.line++
 			l.col = 1
 		} else {
 			l.col++
 		}
 		i += width
 	}
 	// advance start position to next token
 	l.start = l.pos
 }
 func (l *queryLexer) emit(t tokenType) {
 	l.tokens <- token{
 		Position: toml.Position{Line: l.line, Col: l.col},
 		typ:      t,
 		val:      l.input[l.start:l.pos],
 	}
 	l.nextStart()
 }
 func (l *queryLexer) emitWithValue(t tokenType, value string) {
 	l.tokens <- token{
 		Position: toml.Position{Line: l.line, Col: l.col},
 		typ:      t,
 		val:      value,
 	}
 	l.nextStart()
 }
 func (l *queryLexer) next() rune {
 	if l.pos >= len(l.input) {
 		l.width = 0
 		return eof
 	}
 	var r rune
 	r, l.width = utf8.DecodeRuneInString(l.input[l.pos:])
 	l.pos += l.width
 	return r
 }
 func (l *queryLexer) ignore() {
 	l.nextStart()
 }
 func (l *queryLexer) backup() {
 	l.pos -= l.width
 }
 func (l *queryLexer) errorf(format string, args ...interface{}) queryLexStateFn {
 	l.tokens <- token{
 		Position: toml.Position{Line: l.line, Col: l.col},
 		typ:      tokenError,
 		val:      fmt.Sprintf(format, args...),
 	}
 	return nil
 }
 func (l *queryLexer) peek() rune {
 	r := l.next()
 	l.backup()
 	return r
 }
 func (l *queryLexer) accept(valid string) bool {
 	if strings.ContainsRune(valid, l.next()) {
 		return true
 	}
 	l.backup()
 	return false
 }
 func (l *queryLexer) follow(next string) bool {
 	return strings.HasPrefix(l.input[l.pos:], next)
 }
 func (l *queryLexer) lexVoid() queryLexStateFn {
 	for {
 		next := l.peek()
 		switch next {
 		case '$':
 			l.pos++
 			l.emit(tokenDollar)
 			continue
 		case '.':
 			if l.follow("..") {
 				l.pos += 2
 				l.emit(tokenDotDot)
 			} else {
 				l.pos++
 				l.emit(tokenDot)
 			}
 			continue
 		case '[':
 			l.pos++
 			l.emit(tokenLeftBracket)
 			continue
 		case ']':
 			l.pos++
 			l.emit(tokenRightBracket)
 			continue
 		case ',':
 			l.pos++
 			l.emit(tokenComma)
 			continue
 		case '*':
 			l.pos++
 			l.emit(tokenStar)
 			continue
 		case '(':
 			l.pos++
 			l.emit(tokenLeftParen)
 			continue
 		case ')':
 			l.pos++
 			l.emit(tokenRightParen)
 			continue
 		case '?':
 			l.pos++
 			l.emit(tokenQuestion)
 			continue
 		case ':':
 			l.pos++
 			l.emit(tokenColon)
 			continue
 		case '\'':
 			l.ignore()
 			l.stringTerm = string(next)
 			return l.lexString
 		case '"':
 			l.ignore()
 			l.stringTerm = string(next)
 			return l.lexString
 		}
 		if isSpace(next) {
 			l.next()
 			l.ignore()
 			continue
 		}
 		if isAlphanumeric(next) {
 			return l.lexKey
 		}
 		if next == '+' || next == '-' || isDigit(next) {
 			return l.lexNumber
 		}
 		if l.next() == eof {
 			break
 		}
 		return l.errorf("unexpected char: '%v'", next)
 	}
 	l.emit(tokenEOF)
 	return nil
 }
 func (l *queryLexer) lexKey() queryLexStateFn {
 	for {
 		next := l.peek()
 		if !isAlphanumeric(next) {
 			l.emit(tokenKey)
 			return l.lexVoid
 		}
 		if l.next() == eof {
 			break
 		}
 	}
 	l.emit(tokenEOF)
 	return nil
 }
 func (l *queryLexer) lexString() queryLexStateFn {
 	l.pos++
 	l.ignore()
 	growingString := ""
 	for {
 		if l.follow(l.stringTerm) {
 			l.emitWithValue(tokenString, growingString)
 			l.pos++
 			l.ignore()
 			return l.lexVoid
 		}
 		if l.follow("\\\"") {
 			l.pos++
 			growingString += "\""
 		} else if l.follow("\\'") {
 			l.pos++
 			growingString += "'"
 		} else if l.follow("\\n") {
 			l.pos++
 			growingString += "\n"
 		} else if l.follow("\\b") {
 			l.pos++
 			growingString += "\b"
 		} else if l.follow("\\f") {
 			l.pos++
 			growingString += "\f"
 		} else if l.follow("\\/") {
 			l.pos++
 			growingString += "/"
 		} else if l.follow("\\t") {
 			l.pos++
 			growingString += "\t"
 		} else if l.follow("\\r") {
 			l.pos++
 			growingString += "\r"
 		} else if l.follow("\\\\") {
 			l.pos++
 			growingString += "\\"
 		} else if l.follow("\\u") {
 			l.pos += 2
 			code := ""
 			for i := 0; i < 4; i++ {
 				c := l.peek()
 				l.pos++
 				if !isHexDigit(c) {
 					return l.errorf("unfinished unicode escape")
 				}
 				code = code + string(c)
 			}
 			l.pos--
 			intcode, err := strconv.ParseInt(code, 16, 32)
 			if err != nil {
 				return l.errorf("invalid unicode escape: \\u" + code)
 			}
 			growingString += string(rune(intcode))
 		} else if l.follow("\\U") {
 			l.pos += 2
 			code := ""
 			for i := 0; i < 8; i++ {
 				c := l.peek()
 				l.pos++
 				if !isHexDigit(c) {
 					return l.errorf("unfinished unicode escape")
 				}
 				code = code + string(c)
 			}
 			l.pos--
 			intcode, err := strconv.ParseInt(code, 16, 32)
 			if err != nil {
 				return l.errorf("invalid unicode escape: \\u" + code)
 			}
 			growingString += string(rune(intcode))
 		} else if l.follow("\\") {
 			l.pos++
 			return l.errorf("invalid escape sequence: \\" + string(l.peek()))
 		} else {
 			growingString += string(l.peek())
 		}
 		if l.next() == eof {
 			break
 		}
 	}
 	return l.errorf("unclosed string")
 }
 func (l *queryLexer) lexNumber() queryLexStateFn {
 	l.ignore()
 	if !l.accept("+") {
 		l.accept("-")
 	}
 	pointSeen := false
 	digitSeen := false
 	for {
 		next := l.next()
 		if next == '.' {
 			if pointSeen {
 				return l.errorf("cannot have two dots in one float")
 			}
 			if !isDigit(l.peek()) {
 				return l.errorf("float cannot end with a dot")
 			}
 			pointSeen = true
 		} else if isDigit(next) {
 			digitSeen = true
 		} else {
 			l.backup()
 			break
 		}
 		if pointSeen && !digitSeen {
 			return l.errorf("cannot start float with a dot")
 		}
 	}
 	if !digitSeen {
 		return l.errorf("no digit in that number")
 	}
 	if pointSeen {
 		l.emit(tokenFloat)
 	} else {
 		l.emit(tokenInteger)
 	}
 	return l.lexVoid
 }
 // Entry point
 func lexQuery(input string) chan token {
 	l := &queryLexer{
 		input:  input,
 		tokens: make(chan token),
 		line:   1,
 		col:    1,
 	}
 	go l.run()
 	return l.tokens
 }
@@ -0,0 +1,179 @@
 package query
 import (
 	"github.com/pelletier/go-toml"
 	"testing"
 )
 func testQLFlow(t *testing.T, input string, expectedFlow []token) {
 	ch := lexQuery(input)
 	for idx, expected := range expectedFlow {
 		token := <-ch
 		if token != expected {
 			t.Log("While testing #", idx, ":", input)
 			t.Log("compared (got)", token, "to (expected)", expected)
 			t.Log("\tvalue:", token.val, "<->", expected.val)
 			t.Log("\tvalue as bytes:", []byte(token.val), "<->", []byte(expected.val))
 			t.Log("\ttype:", token.typ.String(), "<->", expected.typ.String())
 			t.Log("\tline:", token.Line, "<->", expected.Line)
 			t.Log("\tcolumn:", token.Col, "<->", expected.Col)
 			t.Log("compared", token, "to", expected)
 			t.FailNow()
 		}
 	}
 	tok, ok := <-ch
 	if ok {
 		t.Log("channel is not closed!")
 		t.Log(len(ch)+1, "tokens remaining:")
 		t.Log("token ->", tok)
 		for token := range ch {
 			t.Log("token ->", token)
 		}
 		t.FailNow()
 	}
 }
 func TestLexSpecialChars(t *testing.T) {
 	testQLFlow(t, " .$[]..()?*", []token{
 		{toml.Position{1, 2}, tokenDot, "."},
 		{toml.Position{1, 3}, tokenDollar, "$"},
 		{toml.Position{1, 4}, tokenLeftBracket, "["},
 		{toml.Position{1, 5}, tokenRightBracket, "]"},
 		{toml.Position{1, 6}, tokenDotDot, ".."},
 		{toml.Position{1, 8}, tokenLeftParen, "("},
 		{toml.Position{1, 9}, tokenRightParen, ")"},
 		{toml.Position{1, 10}, tokenQuestion, "?"},
 		{toml.Position{1, 11}, tokenStar, "*"},
 		{toml.Position{1, 12}, tokenEOF, ""},
 	})
 }
 func TestLexString(t *testing.T) {
 	testQLFlow(t, "'foo\n'", []token{
 		{toml.Position{1, 2}, tokenString, "foo\n"},
 		{toml.Position{2, 2}, tokenEOF, ""},
 	})
 }
 func TestLexDoubleString(t *testing.T) {
 	testQLFlow(t, `"bar"`, []token{
 		{toml.Position{1, 2}, tokenString, "bar"},
 		{toml.Position{1, 6}, tokenEOF, ""},
 	})
 }
 func TestLexStringEscapes(t *testing.T) {
 	testQLFlow(t, `"foo \" \' \b \f \/ \t \r \\ \u03A9 \U00012345 \n bar"`, []token{
 		{toml.Position{1, 2}, tokenString, "foo \" ' \b \f / \t \r \\ \u03A9 \U00012345 \n bar"},
 		{toml.Position{1, 55}, tokenEOF, ""},
 	})
 }
 func TestLexStringUnfinishedUnicode4(t *testing.T) {
 	testQLFlow(t, `"\u000"`, []token{
 		{toml.Position{1, 2}, tokenError, "unfinished unicode escape"},
 	})
 }
 func TestLexStringUnfinishedUnicode8(t *testing.T) {
 	testQLFlow(t, `"\U0000"`, []token{
 		{toml.Position{1, 2}, tokenError, "unfinished unicode escape"},
 	})
 }
 func TestLexStringInvalidEscape(t *testing.T) {
 	testQLFlow(t, `"\x"`, []token{
 		{toml.Position{1, 2}, tokenError, "invalid escape sequence: \\x"},
 	})
 }
 func TestLexStringUnfinished(t *testing.T) {
 	testQLFlow(t, `"bar`, []token{
 		{toml.Position{1, 2}, tokenError, "unclosed string"},
 	})
 }
 func TestLexKey(t *testing.T) {
 	testQLFlow(t, "foo", []token{
 		{toml.Position{1, 1}, tokenKey, "foo"},
 		{toml.Position{1, 4}, tokenEOF, ""},
 	})
 }
 func TestLexRecurse(t *testing.T) {
 	testQLFlow(t, "$..*", []token{
 		{toml.Position{1, 1}, tokenDollar, "$"},
 		{toml.Position{1, 2}, tokenDotDot, ".."},
 		{toml.Position{1, 4}, tokenStar, "*"},
 		{toml.Position{1, 5}, tokenEOF, ""},
 	})
 }
 func TestLexBracketKey(t *testing.T) {
 	testQLFlow(t, "$[foo]", []token{
 		{toml.Position{1, 1}, tokenDollar, "$"},
 		{toml.Position{1, 2}, tokenLeftBracket, "["},
 		{toml.Position{1, 3}, tokenKey, "foo"},
 		{toml.Position{1, 6}, tokenRightBracket, "]"},
 		{toml.Position{1, 7}, tokenEOF, ""},
 	})
 }
 func TestLexSpace(t *testing.T) {
 	testQLFlow(t, "foo bar baz", []token{
 		{toml.Position{1, 1}, tokenKey, "foo"},
 		{toml.Position{1, 5}, tokenKey, "bar"},
 		{toml.Position{1, 9}, tokenKey, "baz"},
 		{toml.Position{1, 12}, tokenEOF, ""},
 	})
 }
 func TestLexInteger(t *testing.T) {
 	testQLFlow(t, "100 +200 -300", []token{
 		{toml.Position{1, 1}, tokenInteger, "100"},
 		{toml.Position{1, 5}, tokenInteger, "+200"},
 		{toml.Position{1, 10}, tokenInteger, "-300"},
 		{toml.Position{1, 14}, tokenEOF, ""},
 	})
 }
 func TestLexFloat(t *testing.T) {
 	testQLFlow(t, "100.0 +200.0 -300.0", []token{
 		{toml.Position{1, 1}, tokenFloat, "100.0"},
 		{toml.Position{1, 7}, tokenFloat, "+200.0"},
 		{toml.Position{1, 14}, tokenFloat, "-300.0"},
 		{toml.Position{1, 20}, tokenEOF, ""},
 	})
 }
 func TestLexFloatWithMultipleDots(t *testing.T) {
 	testQLFlow(t, "4.2.", []token{
 		{toml.Position{1, 1}, tokenError, "cannot have two dots in one float"},
 	})
 }
 func TestLexFloatLeadingDot(t *testing.T) {
 	testQLFlow(t, "+.1", []token{
 		{toml.Position{1, 1}, tokenError, "cannot start float with a dot"},
 	})
 }
 func TestLexFloatWithTrailingDot(t *testing.T) {
 	testQLFlow(t, "42.", []token{
 		{toml.Position{1, 1}, tokenError, "float cannot end with a dot"},
 	})
 }
 func TestLexNumberWithoutDigit(t *testing.T) {
 	testQLFlow(t, "+", []token{
 		{toml.Position{1, 1}, tokenError, "no digit in that number"},
 	})
 }
 func TestLexUnknown(t *testing.T) {
 	testQLFlow(t, "^", []token{
 		{toml.Position{1, 1}, tokenError, "unexpected char: '94'"},
 	})
 }
@@ -0,0 +1,232 @@
 package query
 import (
 	"fmt"
 	"github.com/pelletier/go-toml"
 )
 // base match
 type matchBase struct {
 	next pathFn
 }
 func (f *matchBase) setNext(next pathFn) {
 	f.next = next
 }
 // terminating functor - gathers results
 type terminatingFn struct {
 	// empty
 }
 func newTerminatingFn() *terminatingFn {
 	return &terminatingFn{}
 }
 func (f *terminatingFn) setNext(next pathFn) {
 	// do nothing
 }
 func (f *terminatingFn) call(node interface{}, ctx *queryContext) {
 	ctx.result.appendResult(node, ctx.lastPosition)
 }
 // match single key
 type matchKeyFn struct {
 	matchBase
 	Name string
 }
 func newMatchKeyFn(name string) *matchKeyFn {
 	return &matchKeyFn{Name: name}
 }
 func (f *matchKeyFn) call(node interface{}, ctx *queryContext) {
 	if array, ok := node.([]*toml.Tree); ok {
 		for _, tree := range array {
 			item := tree.Get(f.Name)
 			if item != nil {
 				ctx.lastPosition = tree.GetPosition(f.Name)
 				f.next.call(item, ctx)
 			}
 		}
 	} else if tree, ok := node.(*toml.Tree); ok {
 		item := tree.Get(f.Name)
 		if item != nil {
 			ctx.lastPosition = tree.GetPosition(f.Name)
 			f.next.call(item, ctx)
 		}
 	}
 }
 // match single index
 type matchIndexFn struct {
 	matchBase
 	Idx int
 }
 func newMatchIndexFn(idx int) *matchIndexFn {
 	return &matchIndexFn{Idx: idx}
 }
 func (f *matchIndexFn) call(node interface{}, ctx *queryContext) {
 	if arr, ok := node.([]interface{}); ok {
 		if f.Idx < len(arr) && f.Idx >= 0 {
 			if treesArray, ok := node.([]*toml.Tree); ok {
 				if len(treesArray) > 0 {
 					ctx.lastPosition = treesArray[0].Position()
 				}
 			}
 			f.next.call(arr[f.Idx], ctx)
 		}
 	}
 }
 // filter by slicing
 type matchSliceFn struct {
 	matchBase
 	Start, End, Step int
 }
 func newMatchSliceFn(start, end, step int) *matchSliceFn {
 	return &matchSliceFn{Start: start, End: end, Step: step}
 }
 func (f *matchSliceFn) call(node interface{}, ctx *queryContext) {
 	if arr, ok := node.([]interface{}); ok {
 		// adjust indexes for negative values, reverse ordering
 		realStart, realEnd := f.Start, f.End
 		if realStart < 0 {
 			realStart = len(arr) + realStart
 		}
 		if realEnd < 0 {
 			realEnd = len(arr) + realEnd
 		}
 		if realEnd < realStart {
 			realEnd, realStart = realStart, realEnd // swap
 		}
 		// loop and gather
 		for idx := realStart; idx < realEnd; idx += f.Step {
 			if treesArray, ok := node.([]*toml.Tree); ok {
 				if len(treesArray) > 0 {
 					ctx.lastPosition = treesArray[0].Position()
 				}
 			}
 			f.next.call(arr[idx], ctx)
 		}
 	}
 }
 // match anything
 type matchAnyFn struct {
 	matchBase
 }
 func newMatchAnyFn() *matchAnyFn {
 	return &matchAnyFn{}
 }
 func (f *matchAnyFn) call(node interface{}, ctx *queryContext) {
 	if tree, ok := node.(*toml.Tree); ok {
 		for _, k := range tree.Keys() {
 			v := tree.Get(k)
 			ctx.lastPosition = tree.GetPosition(k)
 			f.next.call(v, ctx)
 		}
 	}
 }
 // filter through union
 type matchUnionFn struct {
 	Union []pathFn
 }
 func (f *matchUnionFn) setNext(next pathFn) {
 	for _, fn := range f.Union {
 		fn.setNext(next)
 	}
 }
 func (f *matchUnionFn) call(node interface{}, ctx *queryContext) {
 	for _, fn := range f.Union {
 		fn.call(node, ctx)
 	}
 }
 // match every single last node in the tree
 type matchRecursiveFn struct {
 	matchBase
 }
 func newMatchRecursiveFn() *matchRecursiveFn {
 	return &matchRecursiveFn{}
 }
 func (f *matchRecursiveFn) call(node interface{}, ctx *queryContext) {
 	originalPosition := ctx.lastPosition
 	if tree, ok := node.(*toml.Tree); ok {
 		var visit func(tree *toml.Tree)
 		visit = func(tree *toml.Tree) {
 			for _, k := range tree.Keys() {
 				v := tree.Get(k)
 				ctx.lastPosition = tree.GetPosition(k)
 				f.next.call(v, ctx)
 				switch node := v.(type) {
 				case *toml.Tree:
 					visit(node)
 				case []*toml.Tree:
 					for _, subtree := range node {
 						visit(subtree)
 					}
 				}
 			}
 		}
 		ctx.lastPosition = originalPosition
 		f.next.call(tree, ctx)
 		visit(tree)
 	}
 }
 // match based on an externally provided functional filter
 type matchFilterFn struct {
 	matchBase
 	Pos  toml.Position
 	Name string
 }
 func newMatchFilterFn(name string, pos toml.Position) *matchFilterFn {
 	return &matchFilterFn{Name: name, Pos: pos}
 }
 func (f *matchFilterFn) call(node interface{}, ctx *queryContext) {
 	fn, ok := (*ctx.filters)[f.Name]
 	if !ok {
 		panic(fmt.Sprintf("%s: query context does not have filter '%s'",
 			f.Pos.String(), f.Name))
 	}
 	switch castNode := node.(type) {
 	case *toml.Tree:
 		for _, k := range castNode.Keys() {
 			v := castNode.Get(k)
 			if fn(v) {
 				ctx.lastPosition = castNode.GetPosition(k)
 				f.next.call(v, ctx)
 			}
 		}
 	case []*toml.Tree:
 		for _, v := range castNode {
 			if fn(v) {
 				if len(castNode) > 0 {
 					ctx.lastPosition = castNode[0].Position()
 				}
 				f.next.call(v, ctx)
 			}
 		}
 	case []interface{}:
 		for _, v := range castNode {
 			if fn(v) {
 				f.next.call(v, ctx)
 			}
 		}
 	}
 }
@@ -0,0 +1,202 @@
 package query
 import (
 	"fmt"
 	"github.com/pelletier/go-toml"
 	"testing"
 )
 // dump path tree to a string
 func pathString(root pathFn) string {
 	result := fmt.Sprintf("%T:", root)
 	switch fn := root.(type) {
 	case *terminatingFn:
 		result += "{}"
 	case *matchKeyFn:
 		result += fmt.Sprintf("{%s}", fn.Name)
 		result += pathString(fn.next)
 	case *matchIndexFn:
 		result += fmt.Sprintf("{%d}", fn.Idx)
 		result += pathString(fn.next)
 	case *matchSliceFn:
 		result += fmt.Sprintf("{%d:%d:%d}",
 			fn.Start, fn.End, fn.Step)
 		result += pathString(fn.next)
 	case *matchAnyFn:
 		result += "{}"
 		result += pathString(fn.next)
 	case *matchUnionFn:
 		result += "{["
 		for _, v := range fn.Union {
 			result += pathString(v) + ", "
 		}
 		result += "]}"
 	case *matchRecursiveFn:
 		result += "{}"
 		result += pathString(fn.next)
 	case *matchFilterFn:
 		result += fmt.Sprintf("{%s}", fn.Name)
 		result += pathString(fn.next)
 	}
 	return result
 }
 func assertPathMatch(t *testing.T, path, ref *Query) bool {
 	pathStr := pathString(path.root)
 	refStr := pathString(ref.root)
 	if pathStr != refStr {
 		t.Errorf("paths do not match")
 		t.Log("test:", pathStr)
 		t.Log("ref: ", refStr)
 		return false
 	}
 	return true
 }
 func assertPath(t *testing.T, query string, ref *Query) {
 	path, _ := parseQuery(lexQuery(query))
 	assertPathMatch(t, path, ref)
 }
 func buildPath(parts ...pathFn) *Query {
 	query := newQuery()
 	for _, v := range parts {
 		query.appendPath(v)
 	}
 	return query
 }
 func TestPathRoot(t *testing.T) {
 	assertPath(t,
 		"$",
 		buildPath(
 		// empty
 		))
 }
 func TestPathKey(t *testing.T) {
 	assertPath(t,
 		"$.foo",
 		buildPath(
 			newMatchKeyFn("foo"),
 		))
 }
 func TestPathBracketKey(t *testing.T) {
 	assertPath(t,
 		"$[foo]",
 		buildPath(
 			newMatchKeyFn("foo"),
 		))
 }
 func TestPathBracketStringKey(t *testing.T) {
 	assertPath(t,
 		"$['foo']",
 		buildPath(
 			newMatchKeyFn("foo"),
 		))
 }
 func TestPathIndex(t *testing.T) {
 	assertPath(t,
 		"$[123]",
 		buildPath(
 			newMatchIndexFn(123),
 		))
 }
 func TestPathSliceStart(t *testing.T) {
 	assertPath(t,
 		"$[123:]",
 		buildPath(
 			newMatchSliceFn(123, maxInt, 1),
 		))
 }
 func TestPathSliceStartEnd(t *testing.T) {
 	assertPath(t,
 		"$[123:456]",
 		buildPath(
 			newMatchSliceFn(123, 456, 1),
 		))
 }
 func TestPathSliceStartEndColon(t *testing.T) {
 	assertPath(t,
 		"$[123:456:]",
 		buildPath(
 			newMatchSliceFn(123, 456, 1),
 		))
 }
 func TestPathSliceStartStep(t *testing.T) {
 	assertPath(t,
 		"$[123::7]",
 		buildPath(
 			newMatchSliceFn(123, maxInt, 7),
 		))
 }
 func TestPathSliceEndStep(t *testing.T) {
 	assertPath(t,
 		"$[:456:7]",
 		buildPath(
 			newMatchSliceFn(0, 456, 7),
 		))
 }
 func TestPathSliceStep(t *testing.T) {
 	assertPath(t,
 		"$[::7]",
 		buildPath(
 			newMatchSliceFn(0, maxInt, 7),
 		))
 }
 func TestPathSliceAll(t *testing.T) {
 	assertPath(t,
 		"$[123:456:7]",
 		buildPath(
 			newMatchSliceFn(123, 456, 7),
 		))
 }
 func TestPathAny(t *testing.T) {
 	assertPath(t,
 		"$.*",
 		buildPath(
 			newMatchAnyFn(),
 		))
 }
 func TestPathUnion(t *testing.T) {
 	assertPath(t,
 		"$[foo, bar, baz]",
 		buildPath(
 			&matchUnionFn{[]pathFn{
 				newMatchKeyFn("foo"),
 				newMatchKeyFn("bar"),
 				newMatchKeyFn("baz"),
 			}},
 		))
 }
 func TestPathRecurse(t *testing.T) {
 	assertPath(t,
 		"$..*",
 		buildPath(
 			newMatchRecursiveFn(),
 		))
 }
 func TestPathFilterExpr(t *testing.T) {
 	assertPath(t,
 		"$[?('foo'),?(bar)]",
 		buildPath(
 			&matchUnionFn{[]pathFn{
 				newMatchFilterFn("foo", toml.Position{}),
 				newMatchFilterFn("bar", toml.Position{}),
 			}},
 		))
 }
@@ -0,0 +1,275 @@
 /*
  Based on the "jsonpath" spec/concept.
  http://goessner.net/articles/JsonPath/
  https://code.google.com/p/json-path/
 */
 package query
 import (
 	"fmt"
 )
 const maxInt = int(^uint(0) >> 1)
 type queryParser struct {
 	flow         chan token
 	tokensBuffer []token
 	query        *Query
 	union        []pathFn
 	err          error
 }
 type queryParserStateFn func() queryParserStateFn
 // Formats and panics an error message based on a token
 func (p *queryParser) parseError(tok *token, msg string, args ...interface{}) queryParserStateFn {
 	p.err = fmt.Errorf(tok.Position.String()+": "+msg, args...)
 	return nil // trigger parse to end
 }
 func (p *queryParser) run() {
 	for state := p.parseStart; state != nil; {
 		state = state()
 	}
 }
 func (p *queryParser) backup(tok *token) {
 	p.tokensBuffer = append(p.tokensBuffer, *tok)
 }
 func (p *queryParser) peek() *token {
 	if len(p.tokensBuffer) != 0 {
 		return &(p.tokensBuffer[0])
 	}
 	tok, ok := <-p.flow
 	if !ok {
 		return nil
 	}
 	p.backup(&tok)
 	return &tok
 }
 func (p *queryParser) lookahead(types ...tokenType) bool {
 	result := true
 	buffer := []token{}
 	for _, typ := range types {
 		tok := p.getToken()
 		if tok == nil {
 			result = false
 			break
 		}
 		buffer = append(buffer, *tok)
 		if tok.typ != typ {
 			result = false
 			break
 		}
 	}
 	// add the tokens back to the buffer, and return
 	p.tokensBuffer = append(p.tokensBuffer, buffer...)
 	return result
 }
 func (p *queryParser) getToken() *token {
 	if len(p.tokensBuffer) != 0 {
 		tok := p.tokensBuffer[0]
 		p.tokensBuffer = p.tokensBuffer[1:]
 		return &tok
 	}
 	tok, ok := <-p.flow
 	if !ok {
 		return nil
 	}
 	return &tok
 }
 func (p *queryParser) parseStart() queryParserStateFn {
 	tok := p.getToken()
 	if tok == nil || tok.typ == tokenEOF {
 		return nil
 	}
 	if tok.typ != tokenDollar {
 		return p.parseError(tok, "Expected '$' at start of expression")
 	}
 	return p.parseMatchExpr
 }
 // handle '.' prefix, '[]', and '..'
 func (p *queryParser) parseMatchExpr() queryParserStateFn {
 	tok := p.getToken()
 	switch tok.typ {
 	case tokenDotDot:
 		p.query.appendPath(&matchRecursiveFn{})
 		// nested parse for '..'
 		tok := p.getToken()
 		switch tok.typ {
 		case tokenKey:
 			p.query.appendPath(newMatchKeyFn(tok.val))
 			return p.parseMatchExpr
 		case tokenLeftBracket:
 			return p.parseBracketExpr
 		case tokenStar:
 			// do nothing - the recursive predicate is enough
 			return p.parseMatchExpr
 		}
 	case tokenDot:
 		// nested parse for '.'
 		tok := p.getToken()
 		switch tok.typ {
 		case tokenKey:
 			p.query.appendPath(newMatchKeyFn(tok.val))
 			return p.parseMatchExpr
 		case tokenStar:
 			p.query.appendPath(&matchAnyFn{})
 			return p.parseMatchExpr
 		}
 	case tokenLeftBracket:
 		return p.parseBracketExpr
 	case tokenEOF:
 		return nil // allow EOF at this stage
 	}
 	return p.parseError(tok, "expected match expression")
 }
 func (p *queryParser) parseBracketExpr() queryParserStateFn {
 	if p.lookahead(tokenInteger, tokenColon) {
 		return p.parseSliceExpr
 	}
 	if p.peek().typ == tokenColon {
 		return p.parseSliceExpr
 	}
 	return p.parseUnionExpr
 }
 func (p *queryParser) parseUnionExpr() queryParserStateFn {
 	var tok *token
 	// this state can be traversed after some sub-expressions
 	// so be careful when setting up state in the parser
 	if p.union == nil {
 		p.union = []pathFn{}
 	}
 loop: // labeled loop for easy breaking
 	for {
 		if len(p.union) > 0 {
 			// parse delimiter or terminator
 			tok = p.getToken()
 			switch tok.typ {
 			case tokenComma:
 				// do nothing
 			case tokenRightBracket:
 				break loop
 			default:
 				return p.parseError(tok, "expected ',' or ']', not '%s'", tok.val)
 			}
 		}
 		// parse sub expression
 		tok = p.getToken()
 		switch tok.typ {
 		case tokenInteger:
 			p.union = append(p.union, newMatchIndexFn(tok.Int()))
 		case tokenKey:
 			p.union = append(p.union, newMatchKeyFn(tok.val))
 		case tokenString:
 			p.union = append(p.union, newMatchKeyFn(tok.val))
 		case tokenQuestion:
 			return p.parseFilterExpr
 		default:
 			return p.parseError(tok, "expected union sub expression, not '%s', %d", tok.val, len(p.union))
 		}
 	}
 	// if there is only one sub-expression, use that instead
 	if len(p.union) == 1 {
 		p.query.appendPath(p.union[0])
 	} else {
 		p.query.appendPath(&matchUnionFn{p.union})
 	}
 	p.union = nil // clear out state
 	return p.parseMatchExpr
 }
 func (p *queryParser) parseSliceExpr() queryParserStateFn {
 	// init slice to grab all elements
 	start, end, step := 0, maxInt, 1
 	// parse optional start
 	tok := p.getToken()
 	if tok.typ == tokenInteger {
 		start = tok.Int()
 		tok = p.getToken()
 	}
 	if tok.typ != tokenColon {
 		return p.parseError(tok, "expected ':'")
 	}
 	// parse optional end
 	tok = p.getToken()
 	if tok.typ == tokenInteger {
 		end = tok.Int()
 		tok = p.getToken()
 	}
 	if tok.typ == tokenRightBracket {
 		p.query.appendPath(newMatchSliceFn(start, end, step))
 		return p.parseMatchExpr
 	}
 	if tok.typ != tokenColon {
 		return p.parseError(tok, "expected ']' or ':'")
 	}
 	// parse optional step
 	tok = p.getToken()
 	if tok.typ == tokenInteger {
 		step = tok.Int()
 		if step < 0 {
 			return p.parseError(tok, "step must be a positive value")
 		}
 		tok = p.getToken()
 	}
 	if tok.typ != tokenRightBracket {
 		return p.parseError(tok, "expected ']'")
 	}
 	p.query.appendPath(newMatchSliceFn(start, end, step))
 	return p.parseMatchExpr
 }
 func (p *queryParser) parseFilterExpr() queryParserStateFn {
 	tok := p.getToken()
 	if tok.typ != tokenLeftParen {
 		return p.parseError(tok, "expected left-parenthesis for filter expression")
 	}
 	tok = p.getToken()
 	if tok.typ != tokenKey && tok.typ != tokenString {
 		return p.parseError(tok, "expected key or string for filter function name")
 	}
 	name := tok.val
 	tok = p.getToken()
 	if tok.typ != tokenRightParen {
 		return p.parseError(tok, "expected right-parenthesis for filter expression")
 	}
 	p.union = append(p.union, newMatchFilterFn(name, tok.Position))
 	return p.parseUnionExpr
 }
 func parseQuery(flow chan token) (*Query, error) {
 	parser := &queryParser{
 		flow:         flow,
 		tokensBuffer: []token{},
 		query:        newQuery(),
 	}
 	parser.run()
 	return parser.query, parser.err
 }
@@ -0,0 +1,482 @@
 package query
 import (
 	"fmt"
 	"io/ioutil"
 	"sort"
 	"strings"
 	"testing"
 	"time"
 	"github.com/pelletier/go-toml"
 )
 type queryTestNode struct {
 	value    interface{}
 	position toml.Position
 }
 func valueString(root interface{}) string {
 	result := "" //fmt.Sprintf("%T:", root)
 	switch node := root.(type) {
 	case *Result:
 		items := []string{}
 		for i, v := range node.Values() {
 			items = append(items, fmt.Sprintf("%s:%s",
 				node.Positions()[i].String(), valueString(v)))
 		}
 		sort.Strings(items)
 		result = "[" + strings.Join(items, ", ") + "]"
 	case queryTestNode:
 		result = fmt.Sprintf("%s:%s",
 			node.position.String(), valueString(node.value))
 	case []interface{}:
 		items := []string{}
 		for _, v := range node {
 			items = append(items, valueString(v))
 		}
 		sort.Strings(items)
 		result = "[" + strings.Join(items, ", ") + "]"
 	case *toml.Tree:
 		// workaround for unreliable map key ordering
 		items := []string{}
 		for _, k := range node.Keys() {
 			v := node.GetPath([]string{k})
 			items = append(items, k+":"+valueString(v))
 		}
 		sort.Strings(items)
 		result = "{" + strings.Join(items, ", ") + "}"
 	case map[string]interface{}:
 		// workaround for unreliable map key ordering
 		items := []string{}
 		for k, v := range node {
 			items = append(items, k+":"+valueString(v))
 		}
 		sort.Strings(items)
 		result = "{" + strings.Join(items, ", ") + "}"
 	case int64:
 		result += fmt.Sprintf("%d", node)
 	case string:
 		result += "'" + node + "'"
 	case float64:
 		result += fmt.Sprintf("%f", node)
 	case bool:
 		result += fmt.Sprintf("%t", node)
 	case time.Time:
 		result += fmt.Sprintf("'%v'", node)
 	}
 	return result
 }
 func assertValue(t *testing.T, result, ref interface{}) {
 	pathStr := valueString(result)
 	refStr := valueString(ref)
 	if pathStr != refStr {
 		t.Errorf("values do not match")
 		t.Log("test:", pathStr)
 		t.Log("ref: ", refStr)
 	}
 }
 func assertQueryPositions(t *testing.T, tomlDoc string, query string, ref []interface{}) {
 	tree, err := toml.Load(tomlDoc)
 	if err != nil {
 		t.Errorf("Non-nil toml parse error: %v", err)
 		return
 	}
 	q, err := Compile(query)
 	if err != nil {
 		t.Error(err)
 		return
 	}
 	results := q.Execute(tree)
 	assertValue(t, results, ref)
 }
 func TestQueryRoot(t *testing.T) {
 	assertQueryPositions(t,
 		"a = 42",
 		"$",
 		[]interface{}{
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(42),
 				}, toml.Position{1, 1},
 			},
 		})
 }
 func TestQueryKey(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo]\na = 42",
 		"$.foo.a",
 		[]interface{}{
 			queryTestNode{
 				int64(42), toml.Position{2, 1},
 			},
 		})
 }
 func TestQueryKeyString(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo]\na = 42",
 		"$.foo['a']",
 		[]interface{}{
 			queryTestNode{
 				int64(42), toml.Position{2, 1},
 			},
 		})
 }
 func TestQueryIndex(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo]\na = [1,2,3,4,5,6,7,8,9,0]",
 		"$.foo.a[5]",
 		[]interface{}{
 			queryTestNode{
 				int64(6), toml.Position{2, 1},
 			},
 		})
 }
 func TestQuerySliceRange(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo]\na = [1,2,3,4,5,6,7,8,9,0]",
 		"$.foo.a[0:5]",
 		[]interface{}{
 			queryTestNode{
 				int64(1), toml.Position{2, 1},
 			},
 			queryTestNode{
 				int64(2), toml.Position{2, 1},
 			},
 			queryTestNode{
 				int64(3), toml.Position{2, 1},
 			},
 			queryTestNode{
 				int64(4), toml.Position{2, 1},
 			},
 			queryTestNode{
 				int64(5), toml.Position{2, 1},
 			},
 		})
 }
 func TestQuerySliceStep(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo]\na = [1,2,3,4,5,6,7,8,9,0]",
 		"$.foo.a[0:5:2]",
 		[]interface{}{
 			queryTestNode{
 				int64(1), toml.Position{2, 1},
 			},
 			queryTestNode{
 				int64(3), toml.Position{2, 1},
 			},
 			queryTestNode{
 				int64(5), toml.Position{2, 1},
 			},
 		})
 }
 func TestQueryAny(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo.bar]\na=1\nb=2\n[foo.baz]\na=3\nb=4",
 		"$.foo.*",
 		[]interface{}{
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(1),
 					"b": int64(2),
 				}, toml.Position{1, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(3),
 					"b": int64(4),
 				}, toml.Position{4, 1},
 			},
 		})
 }
 func TestQueryUnionSimple(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo.bar]\na=1\nb=2\n[baz.foo]\na=3\nb=4\n[gorf.foo]\na=5\nb=6",
 		"$.*[bar,foo]",
 		[]interface{}{
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(1),
 					"b": int64(2),
 				}, toml.Position{1, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(3),
 					"b": int64(4),
 				}, toml.Position{4, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(5),
 					"b": int64(6),
 				}, toml.Position{7, 1},
 			},
 		})
 }
 func TestQueryRecursionAll(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo.bar]\na=1\nb=2\n[baz.foo]\na=3\nb=4\n[gorf.foo]\na=5\nb=6",
 		"$..*",
 		[]interface{}{
 			queryTestNode{
 				map[string]interface{}{
 					"foo": map[string]interface{}{
 						"bar": map[string]interface{}{
 							"a": int64(1),
 							"b": int64(2),
 						},
 					},
 					"baz": map[string]interface{}{
 						"foo": map[string]interface{}{
 							"a": int64(3),
 							"b": int64(4),
 						},
 					},
 					"gorf": map[string]interface{}{
 						"foo": map[string]interface{}{
 							"a": int64(5),
 							"b": int64(6),
 						},
 					},
 				}, toml.Position{1, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"bar": map[string]interface{}{
 						"a": int64(1),
 						"b": int64(2),
 					},
 				}, toml.Position{1, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(1),
 					"b": int64(2),
 				}, toml.Position{1, 1},
 			},
 			queryTestNode{
 				int64(1), toml.Position{2, 1},
 			},
 			queryTestNode{
 				int64(2), toml.Position{3, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"foo": map[string]interface{}{
 						"a": int64(3),
 						"b": int64(4),
 					},
 				}, toml.Position{4, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(3),
 					"b": int64(4),
 				}, toml.Position{4, 1},
 			},
 			queryTestNode{
 				int64(3), toml.Position{5, 1},
 			},
 			queryTestNode{
 				int64(4), toml.Position{6, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"foo": map[string]interface{}{
 						"a": int64(5),
 						"b": int64(6),
 					},
 				}, toml.Position{7, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(5),
 					"b": int64(6),
 				}, toml.Position{7, 1},
 			},
 			queryTestNode{
 				int64(5), toml.Position{8, 1},
 			},
 			queryTestNode{
 				int64(6), toml.Position{9, 1},
 			},
 		})
 }
 func TestQueryRecursionUnionSimple(t *testing.T) {
 	assertQueryPositions(t,
 		"[foo.bar]\na=1\nb=2\n[baz.foo]\na=3\nb=4\n[gorf.foo]\na=5\nb=6",
 		"$..['foo','bar']",
 		[]interface{}{
 			queryTestNode{
 				map[string]interface{}{
 					"bar": map[string]interface{}{
 						"a": int64(1),
 						"b": int64(2),
 					},
 				}, toml.Position{1, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(3),
 					"b": int64(4),
 				}, toml.Position{4, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(1),
 					"b": int64(2),
 				}, toml.Position{1, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"a": int64(5),
 					"b": int64(6),
 				}, toml.Position{7, 1},
 			},
 		})
 }
 func TestQueryFilterFn(t *testing.T) {
 	buff, err := ioutil.ReadFile("../example.toml")
 	if err != nil {
 		t.Error(err)
 		return
 	}
 	assertQueryPositions(t, string(buff),
 		"$..[?(int)]",
 		[]interface{}{
 			queryTestNode{
 				int64(8001), toml.Position{13, 1},
 			},
 			queryTestNode{
 				int64(8001), toml.Position{13, 1},
 			},
 			queryTestNode{
 				int64(8002), toml.Position{13, 1},
 			},
 			queryTestNode{
 				int64(5000), toml.Position{14, 1},
 			},
 		})
 	assertQueryPositions(t, string(buff),
 		"$..[?(string)]",
 		[]interface{}{
 			queryTestNode{
 				"TOML Example", toml.Position{3, 1},
 			},
 			queryTestNode{
 				"Tom Preston-Werner", toml.Position{6, 1},
 			},
 			queryTestNode{
 				"GitHub", toml.Position{7, 1},
 			},
 			queryTestNode{
 				"GitHub Cofounder & CEO\nLikes tater tots and beer.",
 				toml.Position{8, 1},
 			},
 			queryTestNode{
 				"192.168.1.1", toml.Position{12, 1},
 			},
 			queryTestNode{
 				"10.0.0.1", toml.Position{21, 3},
 			},
 			queryTestNode{
 				"eqdc10", toml.Position{22, 3},
 			},
 			queryTestNode{
 				"10.0.0.2", toml.Position{25, 3},
 			},
 			queryTestNode{
 				"eqdc10", toml.Position{26, 3},
 			},
 		})
 	assertQueryPositions(t, string(buff),
 		"$..[?(float)]",
 		[]interface{}{ // no float values in document
 		})
 	tv, _ := time.Parse(time.RFC3339, "1979-05-27T07:32:00Z")
 	assertQueryPositions(t, string(buff),
 		"$..[?(tree)]",
 		[]interface{}{
 			queryTestNode{
 				map[string]interface{}{
 					"name":         "Tom Preston-Werner",
 					"organization": "GitHub",
 					"bio":          "GitHub Cofounder & CEO\nLikes tater tots and beer.",
 					"dob":          tv,
 				}, toml.Position{5, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"server":         "192.168.1.1",
 					"ports":          []interface{}{int64(8001), int64(8001), int64(8002)},
 					"connection_max": int64(5000),
 					"enabled":        true,
 				}, toml.Position{11, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"alpha": map[string]interface{}{
 						"ip": "10.0.0.1",
 						"dc": "eqdc10",
 					},
 					"beta": map[string]interface{}{
 						"ip": "10.0.0.2",
 						"dc": "eqdc10",
 					},
 				}, toml.Position{17, 1},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"ip": "10.0.0.1",
 					"dc": "eqdc10",
 				}, toml.Position{20, 3},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"ip": "10.0.0.2",
 					"dc": "eqdc10",
 				}, toml.Position{24, 3},
 			},
 			queryTestNode{
 				map[string]interface{}{
 					"data": []interface{}{
 						[]interface{}{"gamma", "delta"},
 						[]interface{}{int64(1), int64(2)},
 					},
 				}, toml.Position{28, 1},
 			},
 		})
 	assertQueryPositions(t, string(buff),
 		"$..[?(time)]",
 		[]interface{}{
 			queryTestNode{
 				tv, toml.Position{9, 1},
 			},
 		})
 	assertQueryPositions(t, string(buff),
 		"$..[?(bool)]",
 		[]interface{}{
 			queryTestNode{
 				true, toml.Position{15, 1},
 			},
 		})
 }
@@ -0,0 +1,158 @@
 package query
 import (
 	"time"
 	"github.com/pelletier/go-toml"
 )
 // NodeFilterFn represents a user-defined filter function, for use with
 // Query.SetFilter().
 //
 // The return value of the function must indicate if 'node' is to be included
 // at this stage of the TOML path.  Returning true will include the node, and
 // returning false will exclude it.
 //
 // NOTE: Care should be taken to write script callbacks such that they are safe
 // to use from multiple goroutines.
 type NodeFilterFn func(node interface{}) bool
 // Result is the result of Executing a Query.
 type Result struct {
 	items     []interface{}
 	positions []toml.Position
 }
 // appends a value/position pair to the result set.
 func (r *Result) appendResult(node interface{}, pos toml.Position) {
 	r.items = append(r.items, node)
 	r.positions = append(r.positions, pos)
 }
 // Values is a set of values within a Result.  The order of values is not
 // guaranteed to be in document order, and may be different each time a query is
 // executed.
 func (r Result) Values() []interface{} {
 	return r.items
 }
 // Positions is a set of positions for values within a Result.  Each index
 // in Positions() corresponds to the entry in Value() of the same index.
 func (r Result) Positions() []toml.Position {
 	return r.positions
 }
 // runtime context for executing query paths
 type queryContext struct {
 	result       *Result
 	filters      *map[string]NodeFilterFn
 	lastPosition toml.Position
 }
 // generic path functor interface
 type pathFn interface {
 	setNext(next pathFn)
 	// it is the caller's responsibility to set the ctx.lastPosition before invoking call()
 	// node can be one of: *toml.Tree, []*toml.Tree, or a scalar
 	call(node interface{}, ctx *queryContext)
 }
 // A Query is the representation of a compiled TOML path.  A Query is safe
 // for concurrent use by multiple goroutines.
 type Query struct {
 	root    pathFn
 	tail    pathFn
 	filters *map[string]NodeFilterFn
 }
 func newQuery() *Query {
 	return &Query{
 		root:    nil,
 		tail:    nil,
 		filters: &defaultFilterFunctions,
 	}
 }
 func (q *Query) appendPath(next pathFn) {
 	if q.root == nil {
 		q.root = next
 	} else {
 		q.tail.setNext(next)
 	}
 	q.tail = next
 	next.setNext(newTerminatingFn()) // init the next functor
 }
 // Compile compiles a TOML path expression. The returned Query can be used
 // to match elements within a Tree and its descendants. See Execute.
 func Compile(path string) (*Query, error) {
 	return parseQuery(lexQuery(path))
 }
 // Execute executes a query against a Tree, and returns the result of the query.
 func (q *Query) Execute(tree *toml.Tree) *Result {
 	result := &Result{
 		items:     []interface{}{},
 		positions: []toml.Position{},
 	}
 	if q.root == nil {
 		result.appendResult(tree, tree.GetPosition(""))
 	} else {
 		ctx := &queryContext{
 			result:  result,
 			filters: q.filters,
 		}
 		ctx.lastPosition = tree.Position()
 		q.root.call(tree, ctx)
 	}
 	return result
 }
 // CompileAndExecute is a shorthand for Compile(path) followed by Execute(tree).
 func CompileAndExecute(path string, tree *toml.Tree) (*Result, error) {
 	query, err := Compile(path)
 	if err != nil {
 		return nil, err
 	}
 	return query.Execute(tree), nil
 }
 // SetFilter sets a user-defined filter function.  These may be used inside
 // "?(..)" query expressions to filter TOML document elements within a query.
 func (q *Query) SetFilter(name string, fn NodeFilterFn) {
 	if q.filters == &defaultFilterFunctions {
 		// clone the static table
 		q.filters = &map[string]NodeFilterFn{}
 		for k, v := range defaultFilterFunctions {
 			(*q.filters)[k] = v
 		}
 	}
 	(*q.filters)[name] = fn
 }
 var defaultFilterFunctions = map[string]NodeFilterFn{
 	"tree": func(node interface{}) bool {
 		_, ok := node.(*toml.Tree)
 		return ok
 	},
 	"int": func(node interface{}) bool {
 		_, ok := node.(int64)
 		return ok
 	},
 	"float": func(node interface{}) bool {
 		_, ok := node.(float64)
 		return ok
 	},
 	"string": func(node interface{}) bool {
 		_, ok := node.(string)
 		return ok
 	},
 	"time": func(node interface{}) bool {
 		_, ok := node.(time.Time)
 		return ok
 	},
 	"bool": func(node interface{}) bool {
 		_, ok := node.(bool)
 		return ok
 	},
 }
@@ -0,0 +1,157 @@
 package query
 import (
 	"fmt"
 	"testing"
 	"github.com/pelletier/go-toml"
 )
 func assertArrayContainsInAnyOrder(t *testing.T, array []interface{}, objects ...interface{}) {
 	if len(array) != len(objects) {
 		t.Fatalf("array contains %d objects but %d are expected", len(array), len(objects))
 	}
 	for _, o := range objects {
 		found := false
 		for _, a := range array {
 			if a == o {
 				found = true
 				break
 			}
 		}
 		if !found {
 			t.Fatal(o, "not found in array", array)
 		}
 	}
 }
 func TestQueryExample(t *testing.T) {
 	config, _ := toml.Load(`
      [[book]]
      title = "The Stand"
      author = "Stephen King"
      [[book]]
      title = "For Whom the Bell Tolls"
      author = "Ernest Hemmingway"
      [[book]]
      title = "Neuromancer"
      author = "William Gibson"
    `)
 	authors, err := CompileAndExecute("$.book.author", config)
 	if err != nil {
 		t.Fatal("unexpected error:", err)
 	}
 	names := authors.Values()
 	if len(names) != 3 {
 		t.Fatalf("query should return 3 names but returned %d", len(names))
 	}
 	assertArrayContainsInAnyOrder(t, names, "Stephen King", "Ernest Hemmingway", "William Gibson")
 }
 func TestQueryReadmeExample(t *testing.T) {
 	config, _ := toml.Load(`
 [postgres]
 user = "pelletier"
 password = "mypassword"
 `)
 	query, err := Compile("$..[user,password]")
 	if err != nil {
 		t.Fatal("unexpected error:", err)
 	}
 	results := query.Execute(config)
 	values := results.Values()
 	if len(values) != 2 {
 		t.Fatalf("query should return 2 values but returned %d", len(values))
 	}
 	assertArrayContainsInAnyOrder(t, values, "pelletier", "mypassword")
 }
 func TestQueryPathNotPresent(t *testing.T) {
 	config, _ := toml.Load(`a = "hello"`)
 	query, err := Compile("$.foo.bar")
 	if err != nil {
 		t.Fatal("unexpected error:", err)
 	}
 	results := query.Execute(config)
 	if err != nil {
 		t.Fatalf("err should be nil. got %s instead", err)
 	}
 	if len(results.items) != 0 {
 		t.Fatalf("no items should be matched. %d matched instead", len(results.items))
 	}
 }
 func ExampleNodeFilterFn_filterExample() {
 	tree, _ := toml.Load(`
      [struct_one]
      foo = "foo"
      bar = "bar"
      [struct_two]
      baz = "baz"
      gorf = "gorf"
    `)
 	// create a query that references a user-defined-filter
 	query, _ := Compile("$[?(bazOnly)]")
 	// define the filter, and assign it to the query
 	query.SetFilter("bazOnly", func(node interface{}) bool {
 		if tree, ok := node.(*toml.Tree); ok {
 			return tree.Has("baz")
 		}
 		return false // reject all other node types
 	})
 	// results contain only the 'struct_two' Tree
 	query.Execute(tree)
 }
 func ExampleQuery_queryExample() {
 	config, _ := toml.Load(`
      [[book]]
      title = "The Stand"
      author = "Stephen King"
      [[book]]
      title = "For Whom the Bell Tolls"
      author = "Ernest Hemmingway"
      [[book]]
      title = "Neuromancer"
      author = "William Gibson"
    `)
 	// find and print all the authors in the document
 	query, _ := Compile("$.book.author")
 	authors := query.Execute(config)
 	for _, name := range authors.Values() {
 		fmt.Println(name)
 	}
 }
 func TestTomlQuery(t *testing.T) {
 	tree, err := toml.Load("[foo.bar]\na=1\nb=2\n[baz.foo]\na=3\nb=4\n[gorf.foo]\na=5\nb=6")
 	if err != nil {
 		t.Error(err)
 		return
 	}
 	query, err := Compile("$.foo.bar")
 	if err != nil {
 		t.Error(err)
 		return
 	}
 	result := query.Execute(tree)
 	values := result.Values()
 	if len(values) != 1 {
 		t.Errorf("Expected resultset of 1, got %d instead: %v", len(values), values)
 	}
 	if tt, ok := values[0].(*toml.Tree); !ok {
 		t.Errorf("Expected type of Tree: %T", values[0])
 	} else if tt.Get("a") != int64(1) {
 		t.Errorf("Expected 'a' with a value 1: %v", tt.Get("a"))
 	} else if tt.Get("b") != int64(2) {
 		t.Errorf("Expected 'b' with a value 2: %v", tt.Get("b"))
 	}
 }
@@ -0,0 +1,106 @@
 package query
 import (
 	"fmt"
 	"github.com/pelletier/go-toml"
 	"strconv"
 	"unicode"
 )
 // Define tokens
 type tokenType int
 const (
 	eof = -(iota + 1)
 )
 const (
 	tokenError tokenType = iota
 	tokenEOF
 	tokenKey
 	tokenString
 	tokenInteger
 	tokenFloat
 	tokenLeftBracket
 	tokenRightBracket
 	tokenLeftParen
 	tokenRightParen
 	tokenComma
 	tokenColon
 	tokenDollar
 	tokenStar
 	tokenQuestion
 	tokenDot
 	tokenDotDot
 )
 var tokenTypeNames = []string{
 	"Error",
 	"EOF",
 	"Key",
 	"String",
 	"Integer",
 	"Float",
 	"[",
 	"]",
 	"(",
 	")",
 	",",
 	":",
 	"$",
 	"*",
 	"?",
 	".",
 	"..",
 }
 type token struct {
 	toml.Position
 	typ tokenType
 	val string
 }
 func (tt tokenType) String() string {
 	idx := int(tt)
 	if idx < len(tokenTypeNames) {
 		return tokenTypeNames[idx]
 	}
 	return "Unknown"
 }
 func (t token) Int() int {
 	if result, err := strconv.Atoi(t.val); err != nil {
 		panic(err)
 	} else {
 		return result
 	}
 }
 func (t token) String() string {
 	switch t.typ {
 	case tokenEOF:
 		return "EOF"
 	case tokenError:
 		return t.val
 	}
 	return fmt.Sprintf("%q", t.val)
 }
 func isSpace(r rune) bool {
 	return r == ' ' || r == '\t'
 }
 func isAlphanumeric(r rune) bool {
 	return unicode.IsLetter(r) || r == '_'
 }
 func isDigit(r rune) bool {
 	return unicode.IsNumber(r)
 }
 func isHexDigit(r rune) bool {
 	return isDigit(r) ||
 		(r >= 'a' && r <= 'f') ||
 		(r >= 'A' && r <= 'F')
 }
@@ -1,28 +1,88 @@
 #!/bin/bash
 # fail out of the script if anything here fails
 set -e
 set -o pipefail
 # set the path to the present working directory
 export GOPATH=`pwd`
-# Vendorize the BurntSushi test suite
+function git_clone() {
-# NOTE: this gets a specific release to avoid versioning issues
+  path=$1
-if [ ! -d 'src/github.com/BurntSushi/toml-test' ]; then
+  branch=$2
-  mkdir -p src/github.com/BurntSushi
+  version=$3
-  git clone https://github.com/BurntSushi/toml-test.git src/github.com/BurntSushi/toml-test
+  if [ ! -d "src/$path" ]; then
    mkdir -p src/$path
    git clone https://$path.git src/$path
  fi
-pushd src/github.com/BurntSushi/toml-test
+  pushd src/$path
-git reset --hard '0.2.0'  # use the released version, NOT tip
+  git checkout "$branch"
  git reset --hard "$version"
  popd
 }
 # Remove potential previous runs
 rm -rf src test_program_bin toml-test
 go get github.com/pelletier/go-buffruneio
 go get github.com/davecgh/go-spew/spew
 go get gopkg.in/yaml.v2
 go get github.com/BurntSushi/toml
 # get code for BurntSushi TOML validation
 # pinning all to 'HEAD' for version 0.3.x work (TODO: pin to commit hash when tests stabilize)
 git_clone github.com/BurntSushi/toml master HEAD
 git_clone github.com/BurntSushi/toml-test master HEAD #was: 0.2.0 HEAD
 # build the BurntSushi test application
 go build -o toml-test github.com/BurntSushi/toml-test
 # vendorize the current lib for testing
 # NOTE: this basically mocks an install without having to go back out to github for code
 mkdir -p src/github.com/pelletier/go-toml/cmd
 mkdir -p src/github.com/pelletier/go-toml/query
 cp *.go *.toml src/github.com/pelletier/go-toml
-cp cmd/*.go src/github.com/pelletier/go-toml/cmd
+cp -R cmd/* src/github.com/pelletier/go-toml/cmd
 cp -R query/* src/github.com/pelletier/go-toml/query
 go build -o test_program_bin src/github.com/pelletier/go-toml/cmd/test_program.go
-# Run basic unit tests and then the BurntSushi test suite
+# Run basic unit tests
-go test -v github.com/pelletier/go-toml
+go test github.com/pelletier/go-toml -covermode=count -coverprofile=coverage.out
 go test github.com/pelletier/go-toml/cmd/tomljson
 go test github.com/pelletier/go-toml/query
 # run the entire BurntSushi test suite
 if [[ $# -eq 0 ]] ; then
  echo "Running all BurntSushi tests"
  ./toml-test ./test_program_bin | tee test_out
 else
  # run a specific test
  test=$1
  test_path='src/github.com/BurntSushi/toml-test/tests'
  valid_test="$test_path/valid/$test"
  invalid_test="$test_path/invalid/$test"
  if [ -e "$valid_test.toml" ]; then
    echo "Valid Test TOML for $test:"
    echo "===="
    cat "$valid_test.toml"
    echo "Valid Test JSON for $test:"
    echo "===="
    cat "$valid_test.json"
    echo "Go-TOML Output for $test:"
    echo "===="
    cat "$valid_test.toml" | ./test_program_bin
  fi
  if [ -e "$invalid_test.toml" ]; then
    echo "Invalid Test TOML for $test:"
    echo "===="
    cat "$invalid_test.toml"
    echo "Go-TOML Output for $test:"
    echo "===="
    echo "go-toml Output:"
    cat "$invalid_test.toml" | ./test_program_bin
  fi
 fi
@@ -0,0 +1,144 @@
 package toml
 import (
 	"fmt"
 	"strconv"
 	"unicode"
 )
 // Define tokens
 type tokenType int
 const (
 	eof = -(iota + 1)
 )
 const (
 	tokenError tokenType = iota
 	tokenEOF
 	tokenComment
 	tokenKey
 	tokenString
 	tokenInteger
 	tokenTrue
 	tokenFalse
 	tokenFloat
 	tokenInf
 	tokenNan
 	tokenEqual
 	tokenLeftBracket
 	tokenRightBracket
 	tokenLeftCurlyBrace
 	tokenRightCurlyBrace
 	tokenLeftParen
 	tokenRightParen
 	tokenDoubleLeftBracket
 	tokenDoubleRightBracket
 	tokenDate
 	tokenKeyGroup
 	tokenKeyGroupArray
 	tokenComma
 	tokenColon
 	tokenDollar
 	tokenStar
 	tokenQuestion
 	tokenDot
 	tokenDotDot
 	tokenEOL
 )
 var tokenTypeNames = []string{
 	"Error",
 	"EOF",
 	"Comment",
 	"Key",
 	"String",
 	"Integer",
 	"True",
 	"False",
 	"Float",
 	"Inf",
 	"NaN",
 	"=",
 	"[",
 	"]",
 	"{",
 	"}",
 	"(",
 	")",
 	"]]",
 	"[[",
 	"Date",
 	"KeyGroup",
 	"KeyGroupArray",
 	",",
 	":",
 	"$",
 	"*",
 	"?",
 	".",
 	"..",
 	"EOL",
 }
 type token struct {
 	Position
 	typ tokenType
 	val string
 }
 func (tt tokenType) String() string {
 	idx := int(tt)
 	if idx < len(tokenTypeNames) {
 		return tokenTypeNames[idx]
 	}
 	return "Unknown"
 }
 func (t token) Int() int {
 	if result, err := strconv.Atoi(t.val); err != nil {
 		panic(err)
 	} else {
 		return result
 	}
 }
 func (t token) String() string {
 	switch t.typ {
 	case tokenEOF:
 		return "EOF"
 	case tokenError:
 		return t.val
 	}
 	return fmt.Sprintf("%q", t.val)
 }
 func isSpace(r rune) bool {
 	return r == ' ' || r == '\t'
 }
 func isAlphanumeric(r rune) bool {
 	return unicode.IsLetter(r) || r == '_'
 }
 func isKeyChar(r rune) bool {
 	// Keys start with the first character that isn't whitespace or [ and end
 	// with the last non-whitespace character before the equals sign. Keys
 	// cannot contain a # character."
 	return !(r == '\r' || r == '\n' || r == eof || r == '=')
 }
 func isKeyStartChar(r rune) bool {
 	return !(isSpace(r) || r == '\r' || r == '\n' || r == eof || r == '[')
 }
 func isDigit(r rune) bool {
 	return unicode.IsNumber(r)
 }
 func isHexDigit(r rune) bool {
 	return isDigit(r) ||
 		(r >= 'a' && r <= 'f') ||
 		(r >= 'A' && r <= 'F')
 }
@@ -0,0 +1,67 @@
 package toml
 import "testing"
 func TestTokenStringer(t *testing.T) {
 	var tests = []struct {
 		tt     tokenType
 		expect string
 	}{
 		{tokenError, "Error"},
 		{tokenEOF, "EOF"},
 		{tokenComment, "Comment"},
 		{tokenKey, "Key"},
 		{tokenString, "String"},
 		{tokenInteger, "Integer"},
 		{tokenTrue, "True"},
 		{tokenFalse, "False"},
 		{tokenFloat, "Float"},
 		{tokenEqual, "="},
 		{tokenLeftBracket, "["},
 		{tokenRightBracket, "]"},
 		{tokenLeftCurlyBrace, "{"},
 		{tokenRightCurlyBrace, "}"},
 		{tokenLeftParen, "("},
 		{tokenRightParen, ")"},
 		{tokenDoubleLeftBracket, "]]"},
 		{tokenDoubleRightBracket, "[["},
 		{tokenDate, "Date"},
 		{tokenKeyGroup, "KeyGroup"},
 		{tokenKeyGroupArray, "KeyGroupArray"},
 		{tokenComma, ","},
 		{tokenColon, ":"},
 		{tokenDollar, "$"},
 		{tokenStar, "*"},
 		{tokenQuestion, "?"},
 		{tokenDot, "."},
 		{tokenDotDot, ".."},
 		{tokenEOL, "EOL"},
 		{tokenEOL + 1, "Unknown"},
 	}
 	for i, test := range tests {
 		got := test.tt.String()
 		if got != test.expect {
 			t.Errorf("[%d] invalid string of token type; got %q, expected %q", i, got, test.expect)
 		}
 	}
 }
 func TestTokenString(t *testing.T) {
 	var tests = []struct {
 		tok    token
 		expect string
 	}{
 		{token{Position{1, 1}, tokenEOF, ""}, "EOF"},
 		{token{Position{1, 1}, tokenError, "Δt"}, "Δt"},
 		{token{Position{1, 1}, tokenString, "bar"}, `"bar"`},
 		{token{Position{1, 1}, tokenString, "123456789012345"}, `"123456789012345"`},
 	}
 	for i, test := range tests {
 		got := test.tok.String()
 		if got != test.expect {
 			t.Errorf("[%d] invalid of string token; got %q, expected %q", i, got, test.expect)
 		}
 	}
 }
@@ -1,85 +1,174 @@
 // TOML markup language parser.
 //
 // This version supports the specification as described in
 // https://github.com/toml-lang/toml/blob/master/versions/toml-v0.2.0.md
 package toml
 import (
 	"errors"
 	"fmt"
 	"io"
 	"io/ioutil"
 	"os"
 	"runtime"
 	"strconv"
 	"strings"
 	"time"
 )
-// Definition of a TomlTree.
+type tomlValue struct {
-// This is the result of the parsing of a TOML file.
+	value     interface{} // string, int64, uint64, float64, bool, time.Time, [] of any of this list
-type TomlTree map[string]interface{}
+	comment   string
 	commented bool
 	multiline bool
 	position  Position
 }
-// Has returns a boolean indicating if the toplevel tree contains the given
+// Tree is the result of the parsing of a TOML file.
-// key.
+type Tree struct {
-func (t *TomlTree) Has(key string) bool {
+	values    map[string]interface{} // string -> *tomlValue, *Tree, []*Tree
-	mp := (map[string]interface{})(*t)
+	comment   string
-	for k, _ := range mp {
+	commented bool
-		if k == key {
+	position  Position
-			return true
+}
 func newTree() *Tree {
 	return &Tree{
 		values:   make(map[string]interface{}),
 		position: Position{},
 	}
 }
 // TreeFromMap initializes a new Tree object using the given map.
 func TreeFromMap(m map[string]interface{}) (*Tree, error) {
 	result, err := toTree(m)
 	if err != nil {
 		return nil, err
 	}
 	return result.(*Tree), nil
 }
 // Position returns the position of the tree.
 func (t *Tree) Position() Position {
 	return t.position
 }
 // Has returns a boolean indicating if the given key exists.
 func (t *Tree) Has(key string) bool {
 	if key == "" {
 		return false
 	}
 	return t.HasPath(strings.Split(key, "."))
 }
-// Keys returns the keys of the toplevel tree.
+// HasPath returns true if the given path of keys exists, false otherwise.
-// Warning: this is a costly operation.
+func (t *Tree) HasPath(keys []string) bool {
-func (t *TomlTree) Keys() []string {
+	return t.GetPath(keys) != nil
-	keys := make([]string, 0)
+}
-	mp := (map[string]interface{})(*t)
+
-	for k, _ := range mp {
+// Keys returns the keys of the toplevel tree (does not recurse).
-		keys = append(keys, k)
+func (t *Tree) Keys() []string {
 	keys := make([]string, len(t.values))
 	i := 0
 	for k := range t.values {
 		keys[i] = k
 		i++
 	}
 	return keys
 }
-// Get the value at key in the TomlTree.
+// Get the value at key in the Tree.
-// Key is a dot-separated path (e.g. a.b.c).
+// Key is a dot-separated path (e.g. a.b.c) without single/double quoted strings.
 // If you need to retrieve non-bare keys, use GetPath.
 // Returns nil if the path does not exist in the tree.
 // If keys is of length zero, the current tree is returned.
-func (t *TomlTree) Get(key string) interface{} {
+func (t *Tree) Get(key string) interface{} {
 	if key == "" {
 		return t
 	}
 	return t.GetPath(strings.Split(key, "."))
 }
-// Returns the element in the tree indicated by 'keys'.
+// GetPath returns the element in the tree indicated by 'keys'.
 // If keys is of length zero, the current tree is returned.
-func (t *TomlTree) GetPath(keys []string) interface{} {
+func (t *Tree) GetPath(keys []string) interface{} {
 	if len(keys) == 0 {
 		return t
 	}
 	subtree := t
-	for _, intermediate_key := range keys[:len(keys)-1] {
+	for _, intermediateKey := range keys[:len(keys)-1] {
-		_, exists := (*subtree)[intermediate_key]
+		value, exists := subtree.values[intermediateKey]
 		if !exists {
 			return nil
 		}
-		switch node := (*subtree)[intermediate_key].(type) {
+		switch node := value.(type) {
-		case *TomlTree:
+		case *Tree:
 			subtree = node
-		case []*TomlTree:
+		case []*Tree:
 			// go to most recent element
 			if len(node) == 0 {
-				return nil //(*subtree)[intermediate_key] = append(node, &TomlTree{})
+				return nil
 			}
 			subtree = node[len(node)-1]
 		default:
 			return nil // cannot navigate through other node types
 		}
 	}
-	return (*subtree)[keys[len(keys)-1]]
+	// branch based on final node type
 	switch node := subtree.values[keys[len(keys)-1]].(type) {
 	case *tomlValue:
 		return node.value
 	default:
 		return node
 	}
 }
-// Same as Get but with a default value
+// GetPosition returns the position of the given key.
-func (t *TomlTree) GetDefault(key string, def interface{}) interface{} {
+func (t *Tree) GetPosition(key string) Position {
 	if key == "" {
 		return t.position
 	}
 	return t.GetPositionPath(strings.Split(key, "."))
 }
 // GetPositionPath returns the element in the tree indicated by 'keys'.
 // If keys is of length zero, the current tree is returned.
 func (t *Tree) GetPositionPath(keys []string) Position {
 	if len(keys) == 0 {
 		return t.position
 	}
 	subtree := t
 	for _, intermediateKey := range keys[:len(keys)-1] {
 		value, exists := subtree.values[intermediateKey]
 		if !exists {
 			return Position{0, 0}
 		}
 		switch node := value.(type) {
 		case *Tree:
 			subtree = node
 		case []*Tree:
 			// go to most recent element
 			if len(node) == 0 {
 				return Position{0, 0}
 			}
 			subtree = node[len(node)-1]
 		default:
 			return Position{0, 0}
 		}
 	}
 	// branch based on final node type
 	switch node := subtree.values[keys[len(keys)-1]].(type) {
 	case *tomlValue:
 		return node.position
 	case *Tree:
 		return node.position
 	case []*Tree:
 		// go to most recent element
 		if len(node) == 0 {
 			return Position{0, 0}
 		}
 		return node[len(node)-1].position
 	default:
 		return Position{0, 0}
 	}
 }
 // GetDefault works like Get but with a default value
 func (t *Tree) GetDefault(key string, def interface{}) interface{} {
 	val := t.Get(key)
 	if val == nil {
 		return def
@@ -87,33 +176,124 @@ func (t *TomlTree) GetDefault(key string, def interface{}) interface{} {
 	return val
 }
-// Set an element in the tree.
+// SetOptions arguments are supplied to the SetWithOptions and SetPathWithOptions functions to modify marshalling behaviour.
-// Key is a dot-separated path (e.g. a.b.c).
+// The default values within the struct are valid default options.
-// Creates all necessary intermediates trees, if needed.
+type SetOptions struct {
-func (t *TomlTree) Set(key string, value interface{}) {
+	Comment   string
-	t.SetPath(strings.Split(key, "."), value)
+	Commented bool
 	Multiline bool
 }
-func (t *TomlTree) SetPath(keys []string, value interface{}) {
+// SetWithOptions is the same as Set, but allows you to provide formatting
-	subtree := t
+// instructions to the key, that will be used by Marshal().
-	for _, intermediate_key := range keys[:len(keys)-1] {
+func (t *Tree) SetWithOptions(key string, opts SetOptions, value interface{}) {
-		_, exists := (*subtree)[intermediate_key]
+	t.SetPathWithOptions(strings.Split(key, "."), opts, value)
 		if !exists {
 			var new_tree TomlTree = make(TomlTree)
 			(*subtree)[intermediate_key] = &new_tree
 }
-		switch node := (*subtree)[intermediate_key].(type) {
+
-		case *TomlTree:
+// SetPathWithOptions is the same as SetPath, but allows you to provide
 // formatting instructions to the key, that will be reused by Marshal().
 func (t *Tree) SetPathWithOptions(keys []string, opts SetOptions, value interface{}) {
 	subtree := t
 	for _, intermediateKey := range keys[:len(keys)-1] {
 		nextTree, exists := subtree.values[intermediateKey]
 		if !exists {
 			nextTree = newTree()
 			subtree.values[intermediateKey] = nextTree // add new element here
 		}
 		switch node := nextTree.(type) {
 		case *Tree:
 			subtree = node
-		case []*TomlTree:
+		case []*Tree:
 			// go to most recent element
 			if len(node) == 0 {
-				(*subtree)[intermediate_key] = append(node, &TomlTree{})
+				// create element if it does not exist
 				subtree.values[intermediateKey] = append(node, newTree())
 			}
 			subtree = node[len(node)-1]
 		}
 	}
-	(*subtree)[keys[len(keys)-1]] = value
+
 	var toInsert interface{}
 	switch value.(type) {
 	case *Tree:
 		tt := value.(*Tree)
 		tt.comment = opts.Comment
 		toInsert = value
 	case []*Tree:
 		toInsert = value
 	case *tomlValue:
 		tt := value.(*tomlValue)
 		tt.comment = opts.Comment
 		toInsert = tt
 	default:
 		toInsert = &tomlValue{value: value, comment: opts.Comment, commented: opts.Commented, multiline: opts.Multiline}
 	}
 	subtree.values[keys[len(keys)-1]] = toInsert
 }
 // Set an element in the tree.
 // Key is a dot-separated path (e.g. a.b.c).
 // Creates all necessary intermediate trees, if needed.
 func (t *Tree) Set(key string, value interface{}) {
 	t.SetWithComment(key, "", false, value)
 }
 // SetWithComment is the same as Set, but allows you to provide comment
 // information to the key, that will be reused by Marshal().
 func (t *Tree) SetWithComment(key string, comment string, commented bool, value interface{}) {
 	t.SetPathWithComment(strings.Split(key, "."), comment, commented, value)
 }
 // SetPath sets an element in the tree.
 // Keys is an array of path elements (e.g. {"a","b","c"}).
 // Creates all necessary intermediate trees, if needed.
 func (t *Tree) SetPath(keys []string, value interface{}) {
 	t.SetPathWithComment(keys, "", false, value)
 }
 // SetPathWithComment is the same as SetPath, but allows you to provide comment
 // information to the key, that will be reused by Marshal().
 func (t *Tree) SetPathWithComment(keys []string, comment string, commented bool, value interface{}) {
 	subtree := t
 	for _, intermediateKey := range keys[:len(keys)-1] {
 		nextTree, exists := subtree.values[intermediateKey]
 		if !exists {
 			nextTree = newTree()
 			subtree.values[intermediateKey] = nextTree // add new element here
 		}
 		switch node := nextTree.(type) {
 		case *Tree:
 			subtree = node
 		case []*Tree:
 			// go to most recent element
 			if len(node) == 0 {
 				// create element if it does not exist
 				subtree.values[intermediateKey] = append(node, newTree())
 			}
 			subtree = node[len(node)-1]
 		}
 	}
 	var toInsert interface{}
 	switch value.(type) {
 	case *Tree:
 		tt := value.(*Tree)
 		tt.comment = comment
 		toInsert = value
 	case []*Tree:
 		toInsert = value
 	case *tomlValue:
 		tt := value.(*tomlValue)
 		tt.comment = comment
 		toInsert = tt
 	default:
 		toInsert = &tomlValue{value: value, comment: comment, commented: commented}
 	}
 	subtree.values[keys[len(keys)-1]] = toInsert
 }
 // createSubTree takes a tree and a key and create the necessary intermediate
@@ -121,121 +301,34 @@ func (t *TomlTree) SetPath(keys []string, value interface{}) {
 //
 // e.g. passing a.b.c will create (assuming tree is empty) tree[a], tree[a][b]
 // and tree[a][b][c]
-func (t *TomlTree) createSubTree(key string) {
+//
 // Returns nil on success, error object on failure
 func (t *Tree) createSubTree(keys []string, pos Position) error {
 	subtree := t
-	for _, intermediate_key := range strings.Split(key, ".") {
+	for _, intermediateKey := range keys {
-		if intermediate_key == "" {
+		nextTree, exists := subtree.values[intermediateKey]
 			panic("empty intermediate table")
 		}
 		_, exists := (*subtree)[intermediate_key]
 		if !exists {
-			var new_tree TomlTree = make(TomlTree)
+			tree := newTree()
-			(*subtree)[intermediate_key] = &new_tree
+			tree.position = pos
-		}
+			subtree.values[intermediateKey] = tree
-		subtree = ((*subtree)[intermediate_key]).(*TomlTree)
+			nextTree = tree
 	}
 		}
-// encodes a string to a TOML-compliant string value
+		switch node := nextTree.(type) {
-func encodeTomlString(value string) string {
+		case []*Tree:
-	result := ""
+			subtree = node[len(node)-1]
-	for _, rr := range value {
+		case *Tree:
-		int_rr := uint16(rr)
+			subtree = node
 		switch rr {
 		case '\b':
 			result += "\\b"
 		case '\t':
 			result += "\\t"
 		case '\n':
 			result += "\\n"
 		case '\f':
 			result += "\\f"
 		case '\r':
 			result += "\\r"
 		case '"':
 			result += "\\\""
 		case '\\':
 			result += "\\\\"
 		default:
-			if int_rr < 0x001F {
+			return fmt.Errorf("unknown type for path %s (%s): %T (%#v)",
-				result += fmt.Sprintf("\\u%0.4X", int_rr)
+				strings.Join(keys, "."), intermediateKey, nextTree, nextTree)
 			} else {
 				result += string(rr)
 		}
 	}
-	}
+	return nil
 	return result
 }
-// Value print support function for ToString()
+// LoadBytes creates a Tree from a []byte.
-// Outputs the TOML compliant string representation of a value
+func LoadBytes(b []byte) (tree *Tree, err error) {
 func toTomlValue(item interface{}, indent int) string {
 	tab := strings.Repeat(" ", indent)
 	switch value := item.(type) {
 	case int64:
 		return tab + strconv.FormatInt(value, 10)
 	case float64:
 		return tab + strconv.FormatFloat(value, 'f', -1, 64)
 	case string:
 		return tab + "\"" + encodeTomlString(value) + "\""
 	case bool:
 		if value {
 			return "true"
 		} else {
 			return "false"
 		}
 	case time.Time:
 		return tab + value.Format(time.RFC3339)
 	case []interface{}:
 		result := tab + "[\n"
 		for _, item := range value {
 			result += toTomlValue(item, indent+2) + ",\n"
 		}
 		return result + tab + "]"
 	default:
 		panic(fmt.Sprintf("unsupported value type: %v", value))
 	}
 }
 // Recursive support function for ToString()
 // Outputs a tree, using the provided keyspace to prefix group names
 func (t *TomlTree) toToml(keyspace string) string {
 	result := ""
 	for k, v := range (map[string]interface{})(*t) {
 		// figure out the keyspace
 		combined_key := k
 		if keyspace != "" {
 			combined_key = keyspace + "." + combined_key
 		}
 		// output based on type
 		switch node := v.(type) {
 		case []*TomlTree:
 			for _, item := range node {
 				if len(item.Keys()) > 0 {
 					result += fmt.Sprintf("\n[[%s]]\n", combined_key)
 				}
 				result += item.toToml(combined_key)
 			}
 		case *TomlTree:
 			if len(node.Keys()) > 0 {
 				result += fmt.Sprintf("\n[%s]\n", combined_key)
 			}
 			result += node.toToml(combined_key)
 		default:
 			result += fmt.Sprintf("%s = %s\n", k, toTomlValue(node, 0))
 		}
 	}
 	return result
 }
 // Generates a human-readable representation of the current tree.
 // Output spans multiple lines, and is suitable for ingest by a TOML parser
 func (t *TomlTree) ToString() string {
 	return t.toToml("")
 }
 // Create a TomlTree from a string.
 func Load(content string) (tree *TomlTree, err error) {
 	defer func() {
 		if r := recover(); r != nil {
 			if _, ok := r.(runtime.Error); ok {
@@ -244,19 +337,31 @@ func Load(content string) (tree *TomlTree, err error) {
 			err = errors.New(r.(string))
 		}
 	}()
-	_, flow := lex(content)
+	tree = parseToml(lexToml(b))
 	tree = parse(flow)
 	return
 }
-// Create a TomlTree from a file.
+// LoadReader creates a Tree from any io.Reader.
-func LoadFile(path string) (tree *TomlTree, err error) {
+func LoadReader(reader io.Reader) (tree *Tree, err error) {
-	buff, ferr := ioutil.ReadFile(path)
+	inputBytes, err := ioutil.ReadAll(reader)
-	if ferr != nil {
+	if err != nil {
 		err = ferr
 	} else {
 		s := string(buff)
 		tree, err = Load(s)
 	}
 		return
 	}
 	tree, err = LoadBytes(inputBytes)
 	return
 }
 // Load creates a Tree from a string.
 func Load(content string) (tree *Tree, err error) {
 	return LoadBytes([]byte(content))
 }
 // LoadFile creates a Tree from a file.
 func LoadFile(path string) (tree *Tree, err error) {
 	file, err := os.Open(path)
 	if err != nil {
 		return nil, err
 	}
 	defer file.Close()
 	return LoadReader(file)
 }
@@ -1,20 +1,85 @@
 // Testing support for go-toml
 package toml
 import (
 	"testing"
 )
 func TestTomlHas(t *testing.T) {
 	tree, _ := Load(`
 		[test]
 		key = "value"
 	`)
 	if !tree.Has("test.key") {
 		t.Errorf("Has - expected test.key to exists")
 	}
 	if tree.Has("") {
 		t.Errorf("Should return false if the key is not provided")
 	}
 }
 func TestTomlGet(t *testing.T) {
 	tree, _ := Load(`
 		[test]
 		key = "value"
 	`)
 	if tree.Get("") != tree {
 		t.Errorf("Get should return the tree itself when given an empty path")
 	}
 	if tree.Get("test.key") != "value" {
 		t.Errorf("Get should return the value")
 	}
 	if tree.Get(`\`) != nil {
 		t.Errorf("should return nil when the key is malformed")
 	}
 }
 func TestTomlGetDefault(t *testing.T) {
 	tree, _ := Load(`
 		[test]
 		key = "value"
 	`)
 	if tree.GetDefault("", "hello") != tree {
 		t.Error("GetDefault should return the tree itself when given an empty path")
 	}
 	if tree.GetDefault("test.key", "hello") != "value" {
 		t.Error("Get should return the value")
 	}
 	if tree.GetDefault("whatever", "hello") != "hello" {
 		t.Error("GetDefault should return the default value if the key does not exist")
 	}
 }
 func TestTomlHasPath(t *testing.T) {
 	tree, _ := Load(`
 		[test]
 		key = "value"
 	`)
 	if !tree.HasPath([]string{"test", "key"}) {
 		t.Errorf("HasPath - expected test.key to exists")
 	}
 }
 func TestTomlGetPath(t *testing.T) {
-	node := make(TomlTree)
+	node := newTree()
 	//TODO: set other node data
 	for idx, item := range []struct {
 		Path     []string
-		Expected interface{}
+		Expected *Tree
 	}{
 		{ // empty path test
 			[]string{},
-			&node,
+			node,
 		},
 	} {
 		result := node.GetPath(item.Path)
@@ -22,4 +87,20 @@ func TestTomlGetPath(t *testing.T) {
 			t.Errorf("GetPath[%d] %v - expected %v, got %v instead.", idx, item.Path, item.Expected, result)
 		}
 	}
 	tree, _ := Load("[foo.bar]\na=1\nb=2\n[baz.foo]\na=3\nb=4\n[gorf.foo]\na=5\nb=6")
 	if tree.GetPath([]string{"whatever"}) != nil {
 		t.Error("GetPath should return nil when the key does not exist")
 	}
 }
 func TestTomlFromMap(t *testing.T) {
 	simpleMap := map[string]interface{}{"hello": 42}
 	tree, err := TreeFromMap(simpleMap)
 	if err != nil {
 		t.Fatal("unexpected error:", err)
 	}
 	if tree.Get("hello") != int64(42) {
 		t.Fatal("hello should be 42, not", tree.Get("hello"))
 	}
 }
@@ -0,0 +1,142 @@
 package toml
 import (
 	"fmt"
 	"reflect"
 	"time"
 )
 var kindToType = [reflect.String + 1]reflect.Type{
 	reflect.Bool:    reflect.TypeOf(true),
 	reflect.String:  reflect.TypeOf(""),
 	reflect.Float32: reflect.TypeOf(float64(1)),
 	reflect.Float64: reflect.TypeOf(float64(1)),
 	reflect.Int:     reflect.TypeOf(int64(1)),
 	reflect.Int8:    reflect.TypeOf(int64(1)),
 	reflect.Int16:   reflect.TypeOf(int64(1)),
 	reflect.Int32:   reflect.TypeOf(int64(1)),
 	reflect.Int64:   reflect.TypeOf(int64(1)),
 	reflect.Uint:    reflect.TypeOf(uint64(1)),
 	reflect.Uint8:   reflect.TypeOf(uint64(1)),
 	reflect.Uint16:  reflect.TypeOf(uint64(1)),
 	reflect.Uint32:  reflect.TypeOf(uint64(1)),
 	reflect.Uint64:  reflect.TypeOf(uint64(1)),
 }
 // typeFor returns a reflect.Type for a reflect.Kind, or nil if none is found.
 // supported values:
 // string, bool, int64, uint64, float64, time.Time, int, int8, int16, int32, uint, uint8, uint16, uint32, float32
 func typeFor(k reflect.Kind) reflect.Type {
 	if k > 0 && int(k) < len(kindToType) {
 		return kindToType[k]
 	}
 	return nil
 }
 func simpleValueCoercion(object interface{}) (interface{}, error) {
 	switch original := object.(type) {
 	case string, bool, int64, uint64, float64, time.Time:
 		return original, nil
 	case int:
 		return int64(original), nil
 	case int8:
 		return int64(original), nil
 	case int16:
 		return int64(original), nil
 	case int32:
 		return int64(original), nil
 	case uint:
 		return uint64(original), nil
 	case uint8:
 		return uint64(original), nil
 	case uint16:
 		return uint64(original), nil
 	case uint32:
 		return uint64(original), nil
 	case float32:
 		return float64(original), nil
 	case fmt.Stringer:
 		return original.String(), nil
 	default:
 		return nil, fmt.Errorf("cannot convert type %T to Tree", object)
 	}
 }
 func sliceToTree(object interface{}) (interface{}, error) {
 	// arrays are a bit tricky, since they can represent either a
 	// collection of simple values, which is represented by one
 	// *tomlValue, or an array of tables, which is represented by an
 	// array of *Tree.
 	// holding the assumption that this function is called from toTree only when value.Kind() is Array or Slice
 	value := reflect.ValueOf(object)
 	insideType := value.Type().Elem()
 	length := value.Len()
 	if length > 0 {
 		insideType = reflect.ValueOf(value.Index(0).Interface()).Type()
 	}
 	if insideType.Kind() == reflect.Map {
 		// this is considered as an array of tables
 		tablesArray := make([]*Tree, 0, length)
 		for i := 0; i < length; i++ {
 			table := value.Index(i)
 			tree, err := toTree(table.Interface())
 			if err != nil {
 				return nil, err
 			}
 			tablesArray = append(tablesArray, tree.(*Tree))
 		}
 		return tablesArray, nil
 	}
 	sliceType := typeFor(insideType.Kind())
 	if sliceType == nil {
 		sliceType = insideType
 	}
 	arrayValue := reflect.MakeSlice(reflect.SliceOf(sliceType), 0, length)
 	for i := 0; i < length; i++ {
 		val := value.Index(i).Interface()
 		simpleValue, err := simpleValueCoercion(val)
 		if err != nil {
 			return nil, err
 		}
 		arrayValue = reflect.Append(arrayValue, reflect.ValueOf(simpleValue))
 	}
 	return &tomlValue{value: arrayValue.Interface(), position: Position{}}, nil
 }
 func toTree(object interface{}) (interface{}, error) {
 	value := reflect.ValueOf(object)
 	if value.Kind() == reflect.Map {
 		values := map[string]interface{}{}
 		keys := value.MapKeys()
 		for _, key := range keys {
 			if key.Kind() != reflect.String {
 				if _, ok := key.Interface().(string); !ok {
 					return nil, fmt.Errorf("map key needs to be a string, not %T (%v)", key.Interface(), key.Kind())
 				}
 			}
 			v := value.MapIndex(key)
 			newValue, err := toTree(v.Interface())
 			if err != nil {
 				return nil, err
 			}
 			values[key.String()] = newValue
 		}
 		return &Tree{values: values, position: Position{}}, nil
 	}
 	if value.Kind() == reflect.Array || value.Kind() == reflect.Slice {
 		return sliceToTree(object)
 	}
 	simpleValue, err := simpleValueCoercion(object)
 	if err != nil {
 		return nil, err
 	}
 	return &tomlValue{value: simpleValue, position: Position{}}, nil
 }
@@ -0,0 +1,126 @@
 package toml
 import (
 	"strconv"
 	"testing"
 	"time"
 )
 type customString string
 type stringer struct{}
 func (s stringer) String() string {
 	return "stringer"
 }
 func validate(t *testing.T, path string, object interface{}) {
 	switch o := object.(type) {
 	case *Tree:
 		for key, tree := range o.values {
 			validate(t, path+"."+key, tree)
 		}
 	case []*Tree:
 		for index, tree := range o {
 			validate(t, path+"."+strconv.Itoa(index), tree)
 		}
 	case *tomlValue:
 		switch o.value.(type) {
 		case int64, uint64, bool, string, float64, time.Time,
 			[]int64, []uint64, []bool, []string, []float64, []time.Time:
 		default:
 			t.Fatalf("tomlValue at key %s containing incorrect type %T", path, o.value)
 		}
 	default:
 		t.Fatalf("value at key %s is of incorrect type %T", path, object)
 	}
 	t.Logf("validation ok %s as %T", path, object)
 }
 func validateTree(t *testing.T, tree *Tree) {
 	validate(t, "", tree)
 }
 func TestTreeCreateToTree(t *testing.T) {
 	data := map[string]interface{}{
 		"a_string": "bar",
 		"an_int":   42,
 		"time":     time.Now(),
 		"int8":     int8(2),
 		"int16":    int16(2),
 		"int32":    int32(2),
 		"uint8":    uint8(2),
 		"uint16":   uint16(2),
 		"uint32":   uint32(2),
 		"float32":  float32(2),
 		"a_bool":   false,
 		"stringer": stringer{},
 		"nested": map[string]interface{}{
 			"foo": "bar",
 		},
 		"array":                 []string{"a", "b", "c"},
 		"array_uint":            []uint{uint(1), uint(2)},
 		"array_table":           []map[string]interface{}{{"sub_map": 52}},
 		"array_times":           []time.Time{time.Now(), time.Now()},
 		"map_times":             map[string]time.Time{"now": time.Now()},
 		"custom_string_map_key": map[customString]interface{}{customString("custom"): "custom"},
 	}
 	tree, err := TreeFromMap(data)
 	if err != nil {
 		t.Fatal("unexpected error:", err)
 	}
 	validateTree(t, tree)
 }
 func TestTreeCreateToTreeInvalidLeafType(t *testing.T) {
 	_, err := TreeFromMap(map[string]interface{}{"foo": t})
 	expected := "cannot convert type *testing.T to Tree"
 	if err.Error() != expected {
 		t.Fatalf("expected error %s, got %s", expected, err.Error())
 	}
 }
 func TestTreeCreateToTreeInvalidMapKeyType(t *testing.T) {
 	_, err := TreeFromMap(map[string]interface{}{"foo": map[int]interface{}{2: 1}})
 	expected := "map key needs to be a string, not int (int)"
 	if err.Error() != expected {
 		t.Fatalf("expected error %s, got %s", expected, err.Error())
 	}
 }
 func TestTreeCreateToTreeInvalidArrayMemberType(t *testing.T) {
 	_, err := TreeFromMap(map[string]interface{}{"foo": []*testing.T{t}})
 	expected := "cannot convert type *testing.T to Tree"
 	if err.Error() != expected {
 		t.Fatalf("expected error %s, got %s", expected, err.Error())
 	}
 }
 func TestTreeCreateToTreeInvalidTableGroupType(t *testing.T) {
 	_, err := TreeFromMap(map[string]interface{}{"foo": []map[string]interface{}{{"hello": t}}})
 	expected := "cannot convert type *testing.T to Tree"
 	if err.Error() != expected {
 		t.Fatalf("expected error %s, got %s", expected, err.Error())
 	}
 }
 func TestRoundTripArrayOfTables(t *testing.T) {
 	orig := "\n[[stuff]]\n  name = \"foo\"\n  things = [\"a\",\"b\"]\n"
 	tree, err := Load(orig)
 	if err != nil {
 		t.Fatalf("unexpected error: %s", err)
 	}
 	m := tree.ToMap()
 	tree, err = TreeFromMap(m)
 	if err != nil {
 		t.Fatalf("unexpected error: %s", err)
 	}
 	want := orig
 	got := tree.String()
 	if got != want {
 		t.Errorf("want:\n%s\ngot:\n%s", want, got)
 	}
 }
@@ -0,0 +1,333 @@
 package toml
 import (
 	"bytes"
 	"fmt"
 	"io"
 	"math"
 	"reflect"
 	"sort"
 	"strconv"
 	"strings"
 	"time"
 )
 // Encodes a string to a TOML-compliant multi-line string value
 // This function is a clone of the existing encodeTomlString function, except that whitespace characters
 // are preserved. Quotation marks and backslashes are also not escaped.
 func encodeMultilineTomlString(value string) string {
 	var b bytes.Buffer
 	for _, rr := range value {
 		switch rr {
 		case '\b':
 			b.WriteString(`\b`)
 		case '\t':
 			b.WriteString("\t")
 		case '\n':
 			b.WriteString("\n")
 		case '\f':
 			b.WriteString(`\f`)
 		case '\r':
 			b.WriteString("\r")
 		case '"':
 			b.WriteString(`"`)
 		case '\\':
 			b.WriteString(`\`)
 		default:
 			intRr := uint16(rr)
 			if intRr < 0x001F {
 				b.WriteString(fmt.Sprintf("\\u%0.4X", intRr))
 			} else {
 				b.WriteRune(rr)
 			}
 		}
 	}
 	return b.String()
 }
 // Encodes a string to a TOML-compliant string value
 func encodeTomlString(value string) string {
 	var b bytes.Buffer
 	for _, rr := range value {
 		switch rr {
 		case '\b':
 			b.WriteString(`\b`)
 		case '\t':
 			b.WriteString(`\t`)
 		case '\n':
 			b.WriteString(`\n`)
 		case '\f':
 			b.WriteString(`\f`)
 		case '\r':
 			b.WriteString(`\r`)
 		case '"':
 			b.WriteString(`\"`)
 		case '\\':
 			b.WriteString(`\\`)
 		default:
 			intRr := uint16(rr)
 			if intRr < 0x001F {
 				b.WriteString(fmt.Sprintf("\\u%0.4X", intRr))
 			} else {
 				b.WriteRune(rr)
 			}
 		}
 	}
 	return b.String()
 }
 func tomlValueStringRepresentation(v interface{}, indent string, arraysOneElementPerLine bool) (string, error) {
 	// this interface check is added to dereference the change made in the writeTo function.
 	// That change was made to allow this function to see formatting options.
 	tv, ok := v.(*tomlValue)
 	if ok {
 		v = tv.value
 	} else {
 		tv = &tomlValue{}
 	}
 	switch value := v.(type) {
 	case uint64:
 		return strconv.FormatUint(value, 10), nil
 	case int64:
 		return strconv.FormatInt(value, 10), nil
 	case float64:
 		// Ensure a round float does contain a decimal point. Otherwise feeding
 		// the output back to the parser would convert to an integer.
 		if math.Trunc(value) == value {
 			return strings.ToLower(strconv.FormatFloat(value, 'f', 1, 32)), nil
 		}
 		return strings.ToLower(strconv.FormatFloat(value, 'f', -1, 32)), nil
 	case string:
 		if tv.multiline {
 			return "\"\"\"\n" + encodeMultilineTomlString(value) + "\"\"\"", nil
 		}
 		return "\"" + encodeTomlString(value) + "\"", nil
 	case []byte:
 		b, _ := v.([]byte)
 		return tomlValueStringRepresentation(string(b), indent, arraysOneElementPerLine)
 	case bool:
 		if value {
 			return "true", nil
 		}
 		return "false", nil
 	case time.Time:
 		return value.Format(time.RFC3339), nil
 	case nil:
 		return "", nil
 	}
 	rv := reflect.ValueOf(v)
 	if rv.Kind() == reflect.Slice {
 		var values []string
 		for i := 0; i < rv.Len(); i++ {
 			item := rv.Index(i).Interface()
 			itemRepr, err := tomlValueStringRepresentation(item, indent, arraysOneElementPerLine)
 			if err != nil {
 				return "", err
 			}
 			values = append(values, itemRepr)
 		}
 		if arraysOneElementPerLine && len(values) > 1 {
 			stringBuffer := bytes.Buffer{}
 			valueIndent := indent + `  ` // TODO: move that to a shared encoder state
 			stringBuffer.WriteString("[\n")
 			for _, value := range values {
 				stringBuffer.WriteString(valueIndent)
 				stringBuffer.WriteString(value)
 				stringBuffer.WriteString(`,`)
 				stringBuffer.WriteString("\n")
 			}
 			stringBuffer.WriteString(indent + "]")
 			return stringBuffer.String(), nil
 		}
 		return "[" + strings.Join(values, ",") + "]", nil
 	}
 	return "", fmt.Errorf("unsupported value type %T: %v", v, v)
 }
 func (t *Tree) writeTo(w io.Writer, indent, keyspace string, bytesCount int64, arraysOneElementPerLine bool) (int64, error) {
 	simpleValuesKeys := make([]string, 0)
 	complexValuesKeys := make([]string, 0)
 	for k := range t.values {
 		v := t.values[k]
 		switch v.(type) {
 		case *Tree, []*Tree:
 			complexValuesKeys = append(complexValuesKeys, k)
 		default:
 			simpleValuesKeys = append(simpleValuesKeys, k)
 		}
 	}
 	sort.Strings(simpleValuesKeys)
 	sort.Strings(complexValuesKeys)
 	for _, k := range simpleValuesKeys {
 		v, ok := t.values[k].(*tomlValue)
 		if !ok {
 			return bytesCount, fmt.Errorf("invalid value type at %s: %T", k, t.values[k])
 		}
 		repr, err := tomlValueStringRepresentation(v, indent, arraysOneElementPerLine)
 		if err != nil {
 			return bytesCount, err
 		}
 		if v.comment != "" {
 			comment := strings.Replace(v.comment, "\n", "\n"+indent+"#", -1)
 			start := "# "
 			if strings.HasPrefix(comment, "#") {
 				start = ""
 			}
 			writtenBytesCountComment, errc := writeStrings(w, "\n", indent, start, comment, "\n")
 			bytesCount += int64(writtenBytesCountComment)
 			if errc != nil {
 				return bytesCount, errc
 			}
 		}
 		var commented string
 		if v.commented {
 			commented = "# "
 		}
 		writtenBytesCount, err := writeStrings(w, indent, commented, k, " = ", repr, "\n")
 		bytesCount += int64(writtenBytesCount)
 		if err != nil {
 			return bytesCount, err
 		}
 	}
 	for _, k := range complexValuesKeys {
 		v := t.values[k]
 		combinedKey := k
 		if keyspace != "" {
 			combinedKey = keyspace + "." + combinedKey
 		}
 		var commented string
 		if t.commented {
 			commented = "# "
 		}
 		switch node := v.(type) {
 		// node has to be of those two types given how keys are sorted above
 		case *Tree:
 			tv, ok := t.values[k].(*Tree)
 			if !ok {
 				return bytesCount, fmt.Errorf("invalid value type at %s: %T", k, t.values[k])
 			}
 			if tv.comment != "" {
 				comment := strings.Replace(tv.comment, "\n", "\n"+indent+"#", -1)
 				start := "# "
 				if strings.HasPrefix(comment, "#") {
 					start = ""
 				}
 				writtenBytesCountComment, errc := writeStrings(w, "\n", indent, start, comment)
 				bytesCount += int64(writtenBytesCountComment)
 				if errc != nil {
 					return bytesCount, errc
 				}
 			}
 			writtenBytesCount, err := writeStrings(w, "\n", indent, commented, "[", combinedKey, "]\n")
 			bytesCount += int64(writtenBytesCount)
 			if err != nil {
 				return bytesCount, err
 			}
 			bytesCount, err = node.writeTo(w, indent+"  ", combinedKey, bytesCount, arraysOneElementPerLine)
 			if err != nil {
 				return bytesCount, err
 			}
 		case []*Tree:
 			for _, subTree := range node {
 				writtenBytesCount, err := writeStrings(w, "\n", indent, commented, "[[", combinedKey, "]]\n")
 				bytesCount += int64(writtenBytesCount)
 				if err != nil {
 					return bytesCount, err
 				}
 				bytesCount, err = subTree.writeTo(w, indent+"  ", combinedKey, bytesCount, arraysOneElementPerLine)
 				if err != nil {
 					return bytesCount, err
 				}
 			}
 		}
 	}
 	return bytesCount, nil
 }
 func writeStrings(w io.Writer, s ...string) (int, error) {
 	var n int
 	for i := range s {
 		b, err := io.WriteString(w, s[i])
 		n += b
 		if err != nil {
 			return n, err
 		}
 	}
 	return n, nil
 }
 // WriteTo encode the Tree as Toml and writes it to the writer w.
 // Returns the number of bytes written in case of success, or an error if anything happened.
 func (t *Tree) WriteTo(w io.Writer) (int64, error) {
 	return t.writeTo(w, "", "", 0, false)
 }
 // ToTomlString generates a human-readable representation of the current tree.
 // Output spans multiple lines, and is suitable for ingest by a TOML parser.
 // If the conversion cannot be performed, ToString returns a non-nil error.
 func (t *Tree) ToTomlString() (string, error) {
 	var buf bytes.Buffer
 	_, err := t.WriteTo(&buf)
 	if err != nil {
 		return "", err
 	}
 	return buf.String(), nil
 }
 // String generates a human-readable representation of the current tree.
 // Alias of ToString. Present to implement the fmt.Stringer interface.
 func (t *Tree) String() string {
 	result, _ := t.ToTomlString()
 	return result
 }
 // ToMap recursively generates a representation of the tree using Go built-in structures.
 // The following types are used:
 //
 //	* bool
 //	* float64
 //	* int64
 //	* string
 //	* uint64
 //	* time.Time
 //	* map[string]interface{} (where interface{} is any of this list)
 //	* []interface{} (where interface{} is any of this list)
 func (t *Tree) ToMap() map[string]interface{} {
 	result := map[string]interface{}{}
 	for k, v := range t.values {
 		switch node := v.(type) {
 		case []*Tree:
 			var array []interface{}
 			for _, item := range node {
 				array = append(array, item.ToMap())
 			}
 			result[k] = array
 		case *Tree:
 			result[k] = node.ToMap()
 		case *tomlValue:
 			result[k] = node.value
 		}
 	}
 	return result
 }
@@ -0,0 +1,376 @@
 package toml
 import (
 	"bytes"
 	"errors"
 	"fmt"
 	"reflect"
 	"strings"
 	"testing"
 	"time"
 )
 type failingWriter struct {
 	failAt  int
 	written int
 	buffer  bytes.Buffer
 }
 func (f *failingWriter) Write(p []byte) (n int, err error) {
 	count := len(p)
 	toWrite := f.failAt - (count + f.written)
 	if toWrite < 0 {
 		toWrite = 0
 	}
 	if toWrite > count {
 		f.written += count
 		f.buffer.Write(p)
 		return count, nil
 	}
 	f.buffer.Write(p[:toWrite])
 	f.written = f.failAt
 	return toWrite, fmt.Errorf("failingWriter failed after writing %d bytes", f.written)
 }
 func assertErrorString(t *testing.T, expected string, err error) {
 	expectedErr := errors.New(expected)
 	if err == nil || err.Error() != expectedErr.Error() {
 		t.Errorf("expecting error %s, but got %s instead", expected, err)
 	}
 }
 func TestTreeWriteToEmptyTable(t *testing.T) {
 	doc := `[[empty-tables]]
 [[empty-tables]]`
 	toml, err := Load(doc)
 	if err != nil {
 		t.Fatal("Unexpected Load error:", err)
 	}
 	tomlString, err := toml.ToTomlString()
 	if err != nil {
 		t.Fatal("Unexpected ToTomlString error:", err)
 	}
 	expected := `
 [[empty-tables]]
 [[empty-tables]]
 `
 	if tomlString != expected {
 		t.Fatalf("Expected:\n%s\nGot:\n%s", expected, tomlString)
 	}
 }
 func TestTreeWriteToTomlString(t *testing.T) {
 	toml, err := Load(`name = { first = "Tom", last = "Preston-Werner" }
 points = { x = 1, y = 2 }`)
 	if err != nil {
 		t.Fatal("Unexpected error:", err)
 	}
 	tomlString, _ := toml.ToTomlString()
 	reparsedTree, err := Load(tomlString)
 	assertTree(t, reparsedTree, err, map[string]interface{}{
 		"name": map[string]interface{}{
 			"first": "Tom",
 			"last":  "Preston-Werner",
 		},
 		"points": map[string]interface{}{
 			"x": int64(1),
 			"y": int64(2),
 		},
 	})
 }
 func TestTreeWriteToTomlStringSimple(t *testing.T) {
 	tree, err := Load("[foo]\n\n[[foo.bar]]\na = 42\n\n[[foo.bar]]\na = 69\n")
 	if err != nil {
 		t.Errorf("Test failed to parse: %v", err)
 		return
 	}
 	result, err := tree.ToTomlString()
 	if err != nil {
 		t.Errorf("Unexpected error: %s", err)
 	}
 	expected := "\n[foo]\n\n  [[foo.bar]]\n    a = 42\n\n  [[foo.bar]]\n    a = 69\n"
 	if result != expected {
 		t.Errorf("Expected got '%s', expected '%s'", result, expected)
 	}
 }
 func TestTreeWriteToTomlStringKeysOrders(t *testing.T) {
 	for i := 0; i < 100; i++ {
 		tree, _ := Load(`
 		foobar = true
 		bar = "baz"
 		foo = 1
 		[qux]
 		  foo = 1
 		  bar = "baz2"`)
 		stringRepr, _ := tree.ToTomlString()
 		t.Log("Intermediate string representation:")
 		t.Log(stringRepr)
 		r := strings.NewReader(stringRepr)
 		toml, err := LoadReader(r)
 		if err != nil {
 			t.Fatal("Unexpected error:", err)
 		}
 		assertTree(t, toml, err, map[string]interface{}{
 			"foobar": true,
 			"bar":    "baz",
 			"foo":    1,
 			"qux": map[string]interface{}{
 				"foo": 1,
 				"bar": "baz2",
 			},
 		})
 	}
 }
 func testMaps(t *testing.T, actual, expected map[string]interface{}) {
 	if !reflect.DeepEqual(actual, expected) {
 		t.Fatal("trees aren't equal.\n", "Expected:\n", expected, "\nActual:\n", actual)
 	}
 }
 func TestTreeWriteToMapSimple(t *testing.T) {
 	tree, _ := Load("a = 42\nb = 17")
 	expected := map[string]interface{}{
 		"a": int64(42),
 		"b": int64(17),
 	}
 	testMaps(t, tree.ToMap(), expected)
 }
 func TestTreeWriteToInvalidTreeSimpleValue(t *testing.T) {
 	tree := Tree{values: map[string]interface{}{"foo": int8(1)}}
 	_, err := tree.ToTomlString()
 	assertErrorString(t, "invalid value type at foo: int8", err)
 }
 func TestTreeWriteToInvalidTreeTomlValue(t *testing.T) {
 	tree := Tree{values: map[string]interface{}{"foo": &tomlValue{value: int8(1), comment: "", position: Position{}}}}
 	_, err := tree.ToTomlString()
 	assertErrorString(t, "unsupported value type int8: 1", err)
 }
 func TestTreeWriteToInvalidTreeTomlValueArray(t *testing.T) {
 	tree := Tree{values: map[string]interface{}{"foo": &tomlValue{value: int8(1), comment: "", position: Position{}}}}
 	_, err := tree.ToTomlString()
 	assertErrorString(t, "unsupported value type int8: 1", err)
 }
 func TestTreeWriteToFailingWriterInSimpleValue(t *testing.T) {
 	toml, _ := Load(`a = 2`)
 	writer := failingWriter{failAt: 0, written: 0}
 	_, err := toml.WriteTo(&writer)
 	assertErrorString(t, "failingWriter failed after writing 0 bytes", err)
 }
 func TestTreeWriteToFailingWriterInTable(t *testing.T) {
 	toml, _ := Load(`
 [b]
 a = 2`)
 	writer := failingWriter{failAt: 2, written: 0}
 	_, err := toml.WriteTo(&writer)
 	assertErrorString(t, "failingWriter failed after writing 2 bytes", err)
 	writer = failingWriter{failAt: 13, written: 0}
 	_, err = toml.WriteTo(&writer)
 	assertErrorString(t, "failingWriter failed after writing 13 bytes", err)
 }
 func TestTreeWriteToFailingWriterInArray(t *testing.T) {
 	toml, _ := Load(`
 [[b]]
 a = 2`)
 	writer := failingWriter{failAt: 2, written: 0}
 	_, err := toml.WriteTo(&writer)
 	assertErrorString(t, "failingWriter failed after writing 2 bytes", err)
 	writer = failingWriter{failAt: 15, written: 0}
 	_, err = toml.WriteTo(&writer)
 	assertErrorString(t, "failingWriter failed after writing 15 bytes", err)
 }
 func TestTreeWriteToMapExampleFile(t *testing.T) {
 	tree, _ := LoadFile("example.toml")
 	expected := map[string]interface{}{
 		"title": "TOML Example",
 		"owner": map[string]interface{}{
 			"name":         "Tom Preston-Werner",
 			"organization": "GitHub",
 			"bio":          "GitHub Cofounder & CEO\nLikes tater tots and beer.",
 			"dob":          time.Date(1979, time.May, 27, 7, 32, 0, 0, time.UTC),
 		},
 		"database": map[string]interface{}{
 			"server":         "192.168.1.1",
 			"ports":          []interface{}{int64(8001), int64(8001), int64(8002)},
 			"connection_max": int64(5000),
 			"enabled":        true,
 		},
 		"servers": map[string]interface{}{
 			"alpha": map[string]interface{}{
 				"ip": "10.0.0.1",
 				"dc": "eqdc10",
 			},
 			"beta": map[string]interface{}{
 				"ip": "10.0.0.2",
 				"dc": "eqdc10",
 			},
 		},
 		"clients": map[string]interface{}{
 			"data": []interface{}{
 				[]interface{}{"gamma", "delta"},
 				[]interface{}{int64(1), int64(2)},
 			},
 		},
 	}
 	testMaps(t, tree.ToMap(), expected)
 }
 func TestTreeWriteToMapWithTablesInMultipleChunks(t *testing.T) {
 	tree, _ := Load(`
 	[[menu.main]]
        a = "menu 1"
        b = "menu 2"
        [[menu.main]]
        c = "menu 3"
        d = "menu 4"`)
 	expected := map[string]interface{}{
 		"menu": map[string]interface{}{
 			"main": []interface{}{
 				map[string]interface{}{"a": "menu 1", "b": "menu 2"},
 				map[string]interface{}{"c": "menu 3", "d": "menu 4"},
 			},
 		},
 	}
 	treeMap := tree.ToMap()
 	testMaps(t, treeMap, expected)
 }
 func TestTreeWriteToMapWithArrayOfInlineTables(t *testing.T) {
 	tree, _ := Load(`
    	[params]
 	language_tabs = [
    		{ key = "shell", name = "Shell" },
    		{ key = "ruby", name = "Ruby" },
    		{ key = "python", name = "Python" }
 	]`)
 	expected := map[string]interface{}{
 		"params": map[string]interface{}{
 			"language_tabs": []interface{}{
 				map[string]interface{}{
 					"key":  "shell",
 					"name": "Shell",
 				},
 				map[string]interface{}{
 					"key":  "ruby",
 					"name": "Ruby",
 				},
 				map[string]interface{}{
 					"key":  "python",
 					"name": "Python",
 				},
 			},
 		},
 	}
 	treeMap := tree.ToMap()
 	testMaps(t, treeMap, expected)
 }
 func TestTreeWriteToFloat(t *testing.T) {
 	tree, err := Load(`a = 3.0`)
 	if err != nil {
 		t.Fatal(err)
 	}
 	str, err := tree.ToTomlString()
 	if err != nil {
 		t.Fatal(err)
 	}
 	expected := `a = 3.0`
 	if strings.TrimSpace(str) != strings.TrimSpace(expected) {
 		t.Fatalf("Expected:\n%s\nGot:\n%s", expected, str)
 	}
 }
 func TestTreeWriteToSpecialFloat(t *testing.T) {
 	expected := `a = +inf
 b = -inf
 c = nan`
 	tree, err := Load(expected)
 	if err != nil {
 		t.Fatal(err)
 	}
 	str, err := tree.ToTomlString()
 	if err != nil {
 		t.Fatal(err)
 	}
 	if strings.TrimSpace(str) != strings.TrimSpace(expected) {
 		t.Fatalf("Expected:\n%s\nGot:\n%s", expected, str)
 	}
 }
 func BenchmarkTreeToTomlString(b *testing.B) {
 	toml, err := Load(sampleHard)
 	if err != nil {
 		b.Fatal("Unexpected error:", err)
 	}
 	for i := 0; i < b.N; i++ {
 		_, err := toml.ToTomlString()
 		if err != nil {
 			b.Fatal(err)
 		}
 	}
 }
 var sampleHard = `# Test file for TOML
 # Only this one tries to emulate a TOML file written by a user of the kind of parser writers probably hate
 # This part you'll really hate
 [the]
 test_string = "You'll hate me after this - #"          # " Annoying, isn't it?
    [the.hard]
    test_array = [ "] ", " # "]      # ] There you go, parse this!
    test_array2 = [ "Test #11 ]proved that", "Experiment #9 was a success" ]
    # You didn't think it'd as easy as chucking out the last #, did you?
    another_test_string = " Same thing, but with a string #"
    harder_test_string = " And when \"'s are in the string, along with # \""   # "and comments are there too"
    # Things will get harder
        [the.hard."bit#"]
        "what?" = "You don't think some user won't do that?"
        multi_line_array = [
            "]",
            # ] Oh yes I did
            ]
 # Each of the following keygroups/key value pairs should produce an error. Uncomment to them to test
 #[error]   if you didn't catch this, your parser is broken
 #string = "Anything other than tabs, spaces and newline after a keygroup or key value pair has ended should produce an error unless it is a comment"   like this
 #array = [
 #         "This might most likely happen in multiline arrays",
 #         Like here,
 #         "or here,
 #         and here"
 #         ]     End of array comment, forgot the #
 #number = 3.14  pi <--again forgot the #         `
`@@ -1 +1,2 @@`
	`test_program/test_program_bin`	`test_program/test_program_bin`
		`fuzz/`