grafana/vendor/github.com/jung-kurt/gofpdf/util.go
Oleg Gaidarenko 1a4be4af8c
Enterprise: add dependencies for upcoming features (#18793)
* Enterprise: add dependencies for upcoming features

See enterprise issues
2019-08-30 18:14:32 +02:00

455 lines
11 KiB
Go

/*
* Copyright (c) 2013 Kurt Jung (Gmail: kurt.w.jung)
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
package gofpdf
import (
"bufio"
"bytes"
"compress/zlib"
"fmt"
"io"
"math"
"os"
"path/filepath"
"strings"
)
func round(f float64) int {
if f < 0 {
return -int(math.Floor(-f + 0.5))
}
return int(math.Floor(f + 0.5))
}
func sprintf(fmtStr string, args ...interface{}) string {
return fmt.Sprintf(fmtStr, args...)
}
// fileExist returns true if the specified normal file exists
func fileExist(filename string) (ok bool) {
info, err := os.Stat(filename)
if err == nil {
if ^os.ModePerm&info.Mode() == 0 {
ok = true
}
}
return ok
}
// fileSize returns the size of the specified file; ok will be false
// if the file does not exist or is not an ordinary file
func fileSize(filename string) (size int64, ok bool) {
info, err := os.Stat(filename)
ok = err == nil
if ok {
size = info.Size()
}
return
}
// bufferFromReader returns a new buffer populated with the contents of the specified Reader
func bufferFromReader(r io.Reader) (b *bytes.Buffer, err error) {
b = new(bytes.Buffer)
_, err = b.ReadFrom(r)
return
}
// slicesEqual returns true if the two specified float slices are equal
func slicesEqual(a, b []float64) bool {
if len(a) != len(b) {
return false
}
for i := range a {
if a[i] != b[i] {
return false
}
}
return true
}
// sliceCompress returns a zlib-compressed copy of the specified byte array
func sliceCompress(data []byte) []byte {
var buf bytes.Buffer
cmp, _ := zlib.NewWriterLevel(&buf, zlib.BestSpeed)
cmp.Write(data)
cmp.Close()
return buf.Bytes()
}
// sliceUncompress returns an uncompressed copy of the specified zlib-compressed byte array
func sliceUncompress(data []byte) (outData []byte, err error) {
inBuf := bytes.NewReader(data)
r, err := zlib.NewReader(inBuf)
defer r.Close()
if err == nil {
var outBuf bytes.Buffer
_, err = outBuf.ReadFrom(r)
if err == nil {
outData = outBuf.Bytes()
}
}
return
}
// utf8toutf16 converts UTF-8 to UTF-16BE; from http://www.fpdf.org/
func utf8toutf16(s string, withBOM ...bool) string {
bom := true
if len(withBOM) > 0 {
bom = withBOM[0]
}
res := make([]byte, 0, 8)
if bom {
res = append(res, 0xFE, 0xFF)
}
nb := len(s)
i := 0
for i < nb {
c1 := byte(s[i])
i++
switch {
case c1 >= 224:
// 3-byte character
c2 := byte(s[i])
i++
c3 := byte(s[i])
i++
res = append(res, ((c1&0x0F)<<4)+((c2&0x3C)>>2),
((c2&0x03)<<6)+(c3&0x3F))
case c1 >= 192:
// 2-byte character
c2 := byte(s[i])
i++
res = append(res, ((c1 & 0x1C) >> 2),
((c1&0x03)<<6)+(c2&0x3F))
default:
// Single-byte character
res = append(res, 0, c1)
}
}
return string(res)
}
// intIf returns a if cnd is true, otherwise b
func intIf(cnd bool, a, b int) int {
if cnd {
return a
}
return b
}
// strIf returns aStr if cnd is true, otherwise bStr
func strIf(cnd bool, aStr, bStr string) string {
if cnd {
return aStr
}
return bStr
}
// doNothing returns the passed string with no translation.
func doNothing(s string) string {
return s
}
// Dump the internals of the specified values
// func dump(fileStr string, a ...interface{}) {
// fl, err := os.OpenFile(fileStr, os.O_CREATE|os.O_APPEND|os.O_WRONLY, 0600)
// if err == nil {
// fmt.Fprintf(fl, "----------------\n")
// spew.Fdump(fl, a...)
// fl.Close()
// }
// }
func repClosure(m map[rune]byte) func(string) string {
var buf bytes.Buffer
return func(str string) string {
var ch byte
var ok bool
buf.Truncate(0)
for _, r := range str {
if r < 0x80 {
ch = byte(r)
} else {
ch, ok = m[r]
if !ok {
ch = byte('.')
}
}
buf.WriteByte(ch)
}
return buf.String()
}
}
// UnicodeTranslator returns a function that can be used to translate, where
// possible, utf-8 strings to a form that is compatible with the specified code
// page. The returned function accepts a string and returns a string.
//
// r is a reader that should read a buffer made up of content lines that
// pertain to the code page of interest. Each line is made up of three
// whitespace separated fields. The first begins with "!" and is followed by
// two hexadecimal digits that identify the glyph position in the code page of
// interest. The second field begins with "U+" and is followed by the unicode
// code point value. The third is the glyph name. A number of these code page
// map files are packaged with the gfpdf library in the font directory.
//
// An error occurs only if a line is read that does not conform to the expected
// format. In this case, the returned function is valid but does not perform
// any rune translation.
func UnicodeTranslator(r io.Reader) (f func(string) string, err error) {
m := make(map[rune]byte)
var uPos, cPos uint32
var lineStr, nameStr string
sc := bufio.NewScanner(r)
for sc.Scan() {
lineStr = sc.Text()
lineStr = strings.TrimSpace(lineStr)
if len(lineStr) > 0 {
_, err = fmt.Sscanf(lineStr, "!%2X U+%4X %s", &cPos, &uPos, &nameStr)
if err == nil {
if cPos >= 0x80 {
m[rune(uPos)] = byte(cPos)
}
}
}
}
if err == nil {
f = repClosure(m)
} else {
f = doNothing
}
return
}
// UnicodeTranslatorFromFile returns a function that can be used to translate,
// where possible, utf-8 strings to a form that is compatible with the
// specified code page. See UnicodeTranslator for more details.
//
// fileStr identifies a font descriptor file that maps glyph positions to names.
//
// If an error occurs reading the file, the returned function is valid but does
// not perform any rune translation.
func UnicodeTranslatorFromFile(fileStr string) (f func(string) string, err error) {
var fl *os.File
fl, err = os.Open(fileStr)
if err == nil {
f, err = UnicodeTranslator(fl)
fl.Close()
} else {
f = doNothing
}
return
}
// UnicodeTranslatorFromDescriptor returns a function that can be used to
// translate, where possible, utf-8 strings to a form that is compatible with
// the specified code page. See UnicodeTranslator for more details.
//
// cpStr identifies a code page. A descriptor file in the font directory, set
// with the fontDirStr argument in the call to New(), should have this name
// plus the extension ".map". If cpStr is empty, it will be replaced with
// "cp1252", the gofpdf code page default.
//
// If an error occurs reading the descriptor, the returned function is valid
// but does not perform any rune translation.
//
// The CellFormat_codepage example demonstrates this method.
func (f *Fpdf) UnicodeTranslatorFromDescriptor(cpStr string) (rep func(string) string) {
var str string
var ok bool
if f.err == nil {
if len(cpStr) == 0 {
cpStr = "cp1252"
}
str, ok = embeddedMapList[cpStr]
if ok {
rep, f.err = UnicodeTranslator(strings.NewReader(str))
} else {
rep, f.err = UnicodeTranslatorFromFile(filepath.Join(f.fontpath, cpStr) + ".map")
}
} else {
rep = doNothing
}
return
}
// Transform moves a point by given X, Y offset
func (p *PointType) Transform(x, y float64) PointType {
return PointType{p.X + x, p.Y + y}
}
// Orientation returns the orientation of a given size:
// "P" for portrait, "L" for landscape
func (s *SizeType) Orientation() string {
if s == nil || s.Ht == s.Wd {
return ""
}
if s.Wd > s.Ht {
return "L"
}
return "P"
}
// ScaleBy expands a size by a certain factor
func (s *SizeType) ScaleBy(factor float64) SizeType {
return SizeType{s.Wd * factor, s.Ht * factor}
}
// ScaleToWidth adjusts the height of a size to match the given width
func (s *SizeType) ScaleToWidth(width float64) SizeType {
height := s.Ht * width / s.Wd
return SizeType{width, height}
}
// ScaleToHeight adjusts the width of a size to match the given height
func (s *SizeType) ScaleToHeight(height float64) SizeType {
width := s.Wd * height / s.Ht
return SizeType{width, height}
}
//The untypedKeyMap structure and its methods are copyrighted 2019 by Arteom Korotkiy (Gmail: arteomkorotkiy).
//Imitation of untyped Map Array
type untypedKeyMap struct {
keySet []interface{}
valueSet []int
}
//Get position of key=>value in PHP Array
func (pa *untypedKeyMap) getIndex(key interface{}) int {
if key != nil {
for i, mKey := range pa.keySet {
if mKey == key {
return i
}
}
return -1
}
return -1
}
//Put key=>value in PHP Array
func (pa *untypedKeyMap) put(key interface{}, value int) {
if key == nil {
var i int
for n := 0; ; n++ {
i = pa.getIndex(n)
if i < 0 {
key = n
break
}
}
pa.keySet = append(pa.keySet, key)
pa.valueSet = append(pa.valueSet, value)
} else {
i := pa.getIndex(key)
if i < 0 {
pa.keySet = append(pa.keySet, key)
pa.valueSet = append(pa.valueSet, value)
} else {
pa.valueSet[i] = value
}
}
}
//Delete value in PHP Array
func (pa *untypedKeyMap) delete(key interface{}) {
if pa == nil || pa.keySet == nil || pa.valueSet == nil {
return
}
i := pa.getIndex(key)
if i >= 0 {
if i == 0 {
pa.keySet = pa.keySet[1:]
pa.valueSet = pa.valueSet[1:]
} else if i == len(pa.keySet)-1 {
pa.keySet = pa.keySet[:len(pa.keySet)-1]
pa.valueSet = pa.valueSet[:len(pa.valueSet)-1]
} else {
pa.keySet = append(pa.keySet[:i], pa.keySet[i+1:]...)
pa.valueSet = append(pa.valueSet[:i], pa.valueSet[i+1:]...)
}
}
}
//Get value from PHP Array
func (pa *untypedKeyMap) get(key interface{}) int {
i := pa.getIndex(key)
if i >= 0 {
return pa.valueSet[i]
}
return 0
}
//Imitation of PHP function pop()
func (pa *untypedKeyMap) pop() {
pa.keySet = pa.keySet[:len(pa.keySet)-1]
pa.valueSet = pa.valueSet[:len(pa.valueSet)-1]
}
//Imitation of PHP function array_merge()
func arrayMerge(arr1, arr2 *untypedKeyMap) *untypedKeyMap {
answer := untypedKeyMap{}
if arr1 == nil && arr2 == nil {
answer = untypedKeyMap{
make([]interface{}, 0),
make([]int, 0),
}
} else if arr2 == nil {
answer.keySet = arr1.keySet[:]
answer.valueSet = arr1.valueSet[:]
} else if arr1 == nil {
answer.keySet = arr2.keySet[:]
answer.valueSet = arr2.valueSet[:]
} else {
answer.keySet = arr1.keySet[:]
answer.valueSet = arr1.valueSet[:]
for i := 0; i < len(arr2.keySet); i++ {
if arr2.keySet[i] == "interval" {
if arr1.getIndex("interval") < 0 {
answer.put("interval", arr2.valueSet[i])
}
} else {
answer.put(nil, arr2.valueSet[i])
}
}
}
return &answer
}
func remove(arr []int, key int) []int {
n := 0
for i, mKey := range arr {
if mKey == key {
n = i
}
}
if n == 0 {
return arr[1:]
} else if n == len(arr)-1 {
return arr[:len(arr)-1]
}
return append(arr[:n], arr[n+1:]...)
}
func isChinese(rune2 rune) bool {
// chinese unicode: 4e00-9fa5
if rune2 >= rune(0x4e00) && rune2 <= rune(0x9fa5) {
return true
}
return false
}