com.fasterxml.jackson.core.io.NumberOutput Maven / Gradle / Ivy
Go to download
Show more of this group Show more artifacts with this name
Show all versions of jackson-core Show documentation
Show all versions of jackson-core Show documentation
Core Jackson abstractions, basic JSON streaming API implementation
package com.fasterxml.jackson.core.io;
public final class NumberOutput
{
private final static char NC = (char) 0;
private static int MILLION = 1000000;
private static int BILLION = 1000000000;
private static long TEN_BILLION_L = 10000000000L;
private static long THOUSAND_L = 1000L;
private static long MIN_INT_AS_LONG = (long) Integer.MIN_VALUE;
private static long MAX_INT_AS_LONG = (long) Integer.MAX_VALUE;
final static String SMALLEST_LONG = String.valueOf(Long.MIN_VALUE);
final static char[] LEAD_3 = new char[4000];
final static char[] FULL_3 = new char[4000];
static {
/* Let's fill it with NULLs for ignorable leading digits,
* and digit chars for others
*/
int ix = 0;
for (int i1 = 0; i1 < 10; ++i1) {
char f1 = (char) ('0' + i1);
char l1 = (i1 == 0) ? NC : f1;
for (int i2 = 0; i2 < 10; ++i2) {
char f2 = (char) ('0' + i2);
char l2 = (i1 == 0 && i2 == 0) ? NC : f2;
for (int i3 = 0; i3 < 10; ++i3) {
// Last is never to be empty
char f3 = (char) ('0' + i3);
LEAD_3[ix] = l1;
LEAD_3[ix+1] = l2;
LEAD_3[ix+2] = f3;
FULL_3[ix] = f1;
FULL_3[ix+1] = f2;
FULL_3[ix+2] = f3;
ix += 4;
}
}
}
}
final static byte[] FULL_TRIPLETS_B = new byte[4000];
static {
for (int i = 0; i < 4000; ++i) {
FULL_TRIPLETS_B[i] = (byte) FULL_3[i];
}
}
final static String[] sSmallIntStrs = new String[] {
"0","1","2","3","4","5","6","7","8","9","10"
};
final static String[] sSmallIntStrs2 = new String[] {
"-1","-2","-3","-4","-5","-6","-7","-8","-9","-10"
};
/*
/**********************************************************
/* Efficient serialization methods using raw buffers
/**********************************************************
*/
/**
* @return Offset within buffer after outputting int
*/
public static int outputInt(int v, char[] b, int off)
{
if (v < 0) {
if (v == Integer.MIN_VALUE) {
/* Special case: no matching positive value within range;
* let's then "upgrade" to long and output as such.
*/
return outputLong((long) v, b, off);
}
b[off++] = '-';
v = -v;
}
if (v < MILLION) { // at most 2 triplets...
if (v < 1000) {
if (v < 10) {
b[off++] = (char) ('0' + v);
} else {
off = leading3(v, b, off);
}
} else {
int thousands = v / 1000;
v -= (thousands * 1000); // == value % 1000
off = leading3(thousands, b, off);
off = full3(v, b, off);
}
return off;
}
// ok, all 3 triplets included
/* Let's first hand possible billions separately before
* handling 3 triplets. This is possible since we know we
* can have at most '2' as billion count.
*/
boolean hasBillions = (v >= BILLION);
if (hasBillions) {
v -= BILLION;
if (v >= BILLION) {
v -= BILLION;
b[off++] = '2';
} else {
b[off++] = '1';
}
}
int newValue = v / 1000;
int ones = (v - (newValue * 1000)); // == value % 1000
v = newValue;
newValue /= 1000;
int thousands = (v - (newValue * 1000));
// value now has millions, which have 1, 2 or 3 digits
if (hasBillions) {
off = full3(newValue, b, off);
} else {
off = leading3(newValue, b, off);
}
off = full3(thousands, b, off);
off = full3(ones, b, off);
return off;
}
public static int outputInt(int v, byte[] b, int off)
{
if (v < 0) {
if (v == Integer.MIN_VALUE) {
return outputLong((long) v, b, off);
}
b[off++] = '-';
v = -v;
}
if (v < MILLION) { // at most 2 triplets...
if (v < 1000) {
if (v < 10) {
b[off++] = (byte) ('0' + v);
} else {
off = leading3(v, b, off);
}
} else {
int thousands = v / 1000;
v -= (thousands * 1000); // == value % 1000
off = leading3(thousands, b, off);
off = full3(v, b, off);
}
return off;
}
boolean hasB = (v >= BILLION);
if (hasB) {
v -= BILLION;
if (v >= BILLION) {
v -= BILLION;
b[off++] = '2';
} else {
b[off++] = '1';
}
}
int newValue = v / 1000;
int ones = (v - (newValue * 1000)); // == value % 1000
v = newValue;
newValue /= 1000;
int thousands = (v - (newValue * 1000));
if (hasB) {
off = full3(newValue, b, off);
} else {
off = leading3(newValue, b, off);
}
off = full3(thousands, b, off);
off = full3(ones, b, off);
return off;
}
/**
* @return Offset within buffer after outputting int
*/
public static int outputLong(long v, char[] b, int off)
{
// First: does it actually fit in an int?
if (v < 0L) {
/* MIN_INT is actually printed as long, just because its
* negation is not an int but long
*/
if (v > MIN_INT_AS_LONG) {
return outputInt((int) v, b, off);
}
if (v == Long.MIN_VALUE) {
// Special case: no matching positive value within range
int len = SMALLEST_LONG.length();
SMALLEST_LONG.getChars(0, len, b, off);
return (off + len);
}
b[off++] = '-';
v = -v;
} else {
if (v <= MAX_INT_AS_LONG) {
return outputInt((int) v, b, off);
}
}
/* Ok: real long print. Need to first figure out length
* in characters, and then print in from end to beginning
*/
int origOffset = off;
off += calcLongStrLength(v);
int ptr = off;
// First, with long arithmetics:
while (v > MAX_INT_AS_LONG) { // full triplet
ptr -= 3;
long newValue = v / THOUSAND_L;
int triplet = (int) (v - newValue * THOUSAND_L);
full3(triplet, b, ptr);
v = newValue;
}
// Then with int arithmetics:
int ivalue = (int) v;
while (ivalue >= 1000) { // still full triplet
ptr -= 3;
int newValue = ivalue / 1000;
int triplet = ivalue - (newValue * 1000);
full3(triplet, b, ptr);
ivalue = newValue;
}
// And finally, if anything remains, partial triplet
leading3(ivalue, b, origOffset);
return off;
}
public static int outputLong(long v, byte[] b, int off)
{
if (v < 0L) {
if (v > MIN_INT_AS_LONG) {
return outputInt((int) v, b, off);
}
if (v == Long.MIN_VALUE) {
// Special case: no matching positive value within range
int len = SMALLEST_LONG.length();
for (int i = 0; i < len; ++i) {
b[off++] = (byte) SMALLEST_LONG.charAt(i);
}
return off;
}
b[off++] = '-';
v = -v;
} else {
if (v <= MAX_INT_AS_LONG) {
return outputInt((int) v, b, off);
}
}
int origOff = off;
off += calcLongStrLength(v);
int ptr = off;
// First, with long arithmetics:
while (v > MAX_INT_AS_LONG) { // full triplet
ptr -= 3;
long newV = v / THOUSAND_L;
int t = (int) (v - newV * THOUSAND_L);
full3(t, b, ptr);
v = newV;
}
// Then with int arithmetics:
int ivalue = (int) v;
while (ivalue >= 1000) { // still full triplet
ptr -= 3;
int newV = ivalue / 1000;
int t = ivalue - (newV * 1000);
full3(t, b, ptr);
ivalue = newV;
}
leading3(ivalue, b, origOff);
return off;
}
/*
/**********************************************************
/* Secondary convenience serialization methods
/**********************************************************
*/
/* !!! 05-Aug-2008, tatus: Any ways to further optimize
* these? (or need: only called by diagnostics methods?)
*/
public static String toString(int v)
{
// Lookup table for small values
if (v < sSmallIntStrs.length) {
if (v >= 0) {
return sSmallIntStrs[v];
}
int v2 = -v - 1;
if (v2 < sSmallIntStrs2.length) {
return sSmallIntStrs2[v2];
}
}
return Integer.toString(v);
}
public static String toString(long v) {
if (v <= Integer.MAX_VALUE && v >= Integer.MIN_VALUE) {
return toString((int) v);
}
return Long.toString(v);
}
public static String toString(double v) {
return Double.toString(v);
}
/**
* @since 2.6.0
*/
public static String toString(float v) {
return Float.toString(v);
}
/*
/**********************************************************
/* Internal methods
/**********************************************************
*/
private static int leading3(int t, char[] b, int off)
{
int digitOffset = (t << 2);
char c = LEAD_3[digitOffset++];
if (c != NC) {
b[off++] = c;
}
c = LEAD_3[digitOffset++];
if (c != NC) {
b[off++] = c;
}
// Last is required to be non-empty
b[off++] = LEAD_3[digitOffset];
return off;
}
private static int leading3(int t, byte[] b, int off)
{
int digitOffset = (t << 2);
char c = LEAD_3[digitOffset++];
if (c != NC) {
b[off++] = (byte) c;
}
c = LEAD_3[digitOffset++];
if (c != NC) {
b[off++] = (byte) c;
}
// Last is required to be non-empty
b[off++] = (byte) LEAD_3[digitOffset];
return off;
}
private static int full3(int t, char[] b, int off)
{
int digitOffset = (t << 2);
b[off++] = FULL_3[digitOffset++];
b[off++] = FULL_3[digitOffset++];
b[off++] = FULL_3[digitOffset];
return off;
}
private static int full3(int t, byte[] b, int off)
{
int digitOffset = (t << 2);
b[off++] = FULL_TRIPLETS_B[digitOffset++];
b[off++] = FULL_TRIPLETS_B[digitOffset++];
b[off++] = FULL_TRIPLETS_B[digitOffset];
return off;
}
/**
*
* Pre-conditions: c is positive, and larger than
* Integer.MAX_VALUE (about 2 billions).
*/
private static int calcLongStrLength(long v)
{
int len = 10;
long cmp = TEN_BILLION_L;
// 19 is longest, need to worry about overflow
while (v >= cmp) {
if (len == 19) {
break;
}
++len;
cmp = (cmp << 3) + (cmp << 1); // 10x
}
return len;
}
}