This program does not use the GD library to generate PNG images of the current time. it is very helpful and useful for reference. teaman sorting & lt ;? Php & nbsp; functionset_4pixel ($ r, $ g, $ B, $ x, $ y) & nbsp ;{& nbsp; global $ sx, $ sy, $ pixels; & nbsp; $ ofs this program does not use the GD library to generate PNG format images of the current time. it is very informative and useful for reference. teaman sorting
Function set_4pixel ($ r, $ g, $ B, $ x, $ y)
{
Global $ sx, $ sy, $ pixels;
$ Ofs = 3 * ($ sx * $ y + $ x );
$ Pixels [$ ofs] = chr ($ r );
$ Pixels [$ ofs + 1] = chr ($ g );
$ Pixels [$ ofs + 2] = chr ($ B );
$ Pixels [$ ofs + 3] = chr ($ r );
$ Pixels [$ ofs + 4] = chr ($ g );
$ Pixels [$ ofs + 5] = chr ($ B );
$ Ofs + = 3 * $ sx;
$ Pixels [$ ofs] = chr ($ r );
$ Pixels [$ ofs + 1] = chr ($ g );
$ Pixels [$ ofs + 2] = chr ($ B );
$ Pixels [$ ofs + 3] = chr ($ r );
$ Pixels [$ ofs + 4] = chr ($ g );
$ Pixels [$ ofs + 5] = chr ($ B );
}
// Function for generating digital images
Function draw2digits ($ x, $ y, $ number)
{
Draw_digit ($ x, $ y, (int) ($ number/10 ));
Draw_digit ($ x + 11, $ y, $ number % 10 );
}
Function draw_digit ($ x, $ y, $ digit)
{
Global $ sx, $ sy, $ pixels, $ digits, $ lines;
$ Digit = $ digits [$ digit];
$ M = 8;
For ($ B = 1, $ I = 0; $ I <7; $ I ++, $ B * = 2 ){
If ($ B & $ digit) ==$ B ){
$ J = $ I * 4;
$ X0 = $ lines [$ j] * $ m + $ x;
$ Y0 = $ lines [$ j + 1] * $ m + $ y;
$ X1 = $ lines [$ j + 2] * $ m + $ x;
$ Y1 = $ lines [$ j + 3] * $ m + $ y;
If ($ x0 = $ x1 ){
$ Ofs = 3 * ($ sx * $ y0 + $ x0 );
For ($ h = $ y0; $ h <= $ y1; $ h ++, $ ofs + = 3 * $ sx ){
$ Pixels [$ ofs] = chr (0 );
$ Pixels [$ ofs + 1] = chr (0 );
$ Pixels [$ ofs + 2] = chr (0 );
}
} Else {
$ Ofs = 3 * ($ sx * $ y0 + $ x0 );
For ($ w = $ x0; $ w <= $ x1; $ w ++ ){
$ Pixels [$ ofs ++] = chr (0 );
$ Pixels [$ ofs ++] = chr (0 );
$ Pixels [$ ofs ++] = chr (0 );
}
}
}
}
}
// Add text to the image
Function add_chunk ($ type)
{
Global $ result, $ data, $ chunk, $ crc_table;
// Chunk: Layer
// Length: 4 bytes: used to calculate chunk
// Chunk type: 4 bytes
// Chunk data: length bytes
// CRC: 4 bytes: cyclic verification
// Copy data and create CRC checksum
$ Len = strlen ($ data );
$ Chunk = pack ("c *", ($ len> 24) & 255,
($ Len> 16) & 255,
($ Len> 8) & 255,
$ Len & 255 );
$ Chunk. = $ type;
$ Chunk. = $ data;
// Calculate a CRC checksum with the bytes chunk [4 .. len-1]
$ Z = 16777215;
$ Z | = 255 <24;
$ C = $ z;
For ($ n = 4; $ n <strlen ($ chunk); $ n ++ ){
$ C8 = ($ c> 8) & 0 xffffff;
$ C = $ crc_table [($ c ^ ord ($ chunk] [$ n]) & 0xff] ^ $ c8;
}
$ Crc = $ c ^ $ z;
$ Chunk. = chr ($ crc> 24) & 255 );
$ Chunk. = chr ($ crc> 16) & 255 );
$ Chunk. = chr ($ crc> 8) & 255 );
$ Chunk. = chr ($ crc & 255 );
// Add the result to $ result
$ Result. = $ chunk;
}
// Main program
$ Sx = 80;
$ Sy = 21;
$ Pixels = "";
// Fill
For ($ h = 0; $ h <$ sy; $ h ++ ){
For ($ w = 0; $ w <$ sx; $ w ++ ){
$ R = 100/$ sx * $ w + 155;
$ G = 100/$ sy * $ h + 155;
$ B = 255-(100/($ sx + $ sy) * ($ w + $ h ));
$ Pixels. = chr ($ r );
$ Pixels. = chr ($ g );
$ Pixels. = chr ($ B );
}
}
$ Date = getdate ();
$ S = $ date ["seconds"];
$ M = $ date ["minutes"];
$ H = $ date ["hours"];
$ Digits = array (95, 5,118,117, 45,121,123, 69,127,125 );
$ Lines = array (1, 1, 1, 2, 0, 1, 0, 2, 1, 0, 1, 1, 0, 0, 0, 1, 0, 2, 1, 2, 0, 1, 1, 1, 0, 0, 1, 0 );
Draw2digits (4, 2, $ h );
Draw2digits (30, 2, $ m );
Draw2digits (56, 2, $ s );
Set_4pixel (0, 0, 0, 26, 7 );
Set_4pixel (0, 0, 0, 26, 13 );
Set_4pixel (0, 0, 0, 52, 7 );
Set_4pixel (0, 0, 0, 52, 13 );
// Create a cyclic verification table
$ Z =-306674912; // = 0xedb88320
For ($ n = 0; $ n <256; $ n ++ ){
$ C = $ n;
For ($ k = 0; $ k <8; $ k ++ ){
$ C2 = ($ c> 1) & 0x7fffffff;
If ($ c & 1) $ c = $ z ^ ($ c2); else $ c = $ c2;
}
$ Crc_table [$ n] = $ c;
}
// PNG file signature
$ Result = pack ("c );
// IHDR chunk data:
// Width: 4 bytes
// Height: 4 bytes
// Bit depth: 1 byte (8 bits per RGB value)
// Color type: 1 byte (2 = RGB)
// ComPRession method: 1 byte (0 = deflate/inflate)
// Filter method: 1 byte (0 = adaptive filtering)
// Interlace method: 1 byte (0 = no interlace)
$ Data = pack ("c *", ($ sx> 24) & 255,
($ Sx> 16) & 255,
($ Sx> 8) & 255,
$ Sx & 255,
($ Sy> 24) & 255,
($ Sy> 16) & 255,
($ Sy> 8) & 255,
$ Sy & 255,
8,
2,
0,
0,
0 );
Add_chunk ("IHDR ");
// Do not translate the text below. please refer to it yourself
// Scanline:
// Filter byte: 0 = none
// RGB bytes for the line
// The scanline is compressed with "zlib", method 8 (RFC-1950 ):
// Compression method/flags code: 1 byte ($78 = method 8, 32 k window)
// Additional flags/check bits: 1 byte ($01: FCHECK = 1, FDICT = 0, FLEVEL = 0)
// Compressed data blocks: n bytes
// One block (RFC-1951 ):
// Bit 0: BFINAL: 1 for the last block
// Bit 1 and 2: BTYPE: 0 for no compression
// Next 2 bytes: LEN (LSB first)
// Next 2 bytes: one's complement of LEN
// LEN bytes uncompressed data
// Check value: 4 bytes (Adler-32 checksum of the uncompressed data)
//
$ Len = ($ sx * 3 + 1) * $ sy;
$ Data = pack ("c *", 0x78, 0x01,
1,
$ Len & 255,
($ Len> 8) & 255,
255-($ len & 255 ),
255-($ len> 8) & 255 ));
$ Start = strlen ($ data );
$ I2 = 0;
For ($ h = 0; $ h <$ sy; $ h ++ ){
$ Data. = chr (0 );
For ($ w = 0; $ w <$ sx * 3; $ w ++ ){
$ Data. = $ pixels [$ i2 ++];
}
}
// Calculate a Adler32 checksum with the bytes data [start .. len-1]
$ S1 = 1;
$ S2 = 0;
For ($ n = $ start; $ n <strlen ($ data); $ n ++ ){
$ S1 = ($ s1 + ord ($ data [$ n]) % 65521;
$ S2 = ($ s2 + $ S1.) % 65521;
}
$ Adler = ($ s2 <16) | $ s1;
$ Data. = chr ($ adler> 24) & 255 );
$ Data. = chr ($ adler> 16) & 255 );
$ Data. = chr ($ adler> 8) & 255 );
$ Data. = chr ($ adler & 255 );
Add_chunk ("IDAT ");
// IEND: marks the end of the PNG-file
$ Data = "";
Add_chunk ("IEND ");
// Print the image
Echo ($ result );
?>
// How to call it is actually very simple. Save the above as Timeimg. php
// Create a new page as follows:
Test
// Call the php file through image connection