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/**************************** printf_light.as ********************************
* Author: Agner Fog
* date created: 2021-05-24
* Last modified: 2021-05-25
* Version: 1.11
* Project: ForwardCom library libc_light.li
* Description: printf, sprintf, snprintf: Print formatted output
* This version is for small CPUs with limited capabilities
* The following instructions are avoided: mul, div, push, pop, sys_call.
* Output to stdout goes directly to output port 10. It does not wait if
* the output buffer is full.
*
* C declarations:
* int printf (const char * format, ... );
* int sprintf (char * string, const char * format, ... );
* int snprintf (char * string, size_t max_length, const char * format, ... );
*
* printf: print to stdout
* sprintf: print to string
* snprintf: print to string with length limit
* fprintf: print to file. not implemented yet
*
* These functions are following the definitions in the C standard.
* All standard features are supported, except the following:
* - cannot print floating point numbers
* - cannot print octal
* - cannot print decimal integers with more than 32 bits
*
* Copyright 2021 GNU General Public License http://www.gnu.org/licenses
*****************************************************************************/
const section read ip
// call table for dispatching format string specifiers
call_table: int8 (specif_space-def)/4 // ' ': print space or minus
int8 0 // !
int8 0 // "
int8 (specif_hash-def)/4 // #: prepend 0x
int8 0 // $
int8 (specif_percent-def)/4 // %: print percent sign
int8 0 // &
int8 0 // '
int8 0 // (
int8 0 // )
int8 (specif_star-def)/4 // *: width specified by parameter
int8 (specif_plus-def)/4 // +: print sign
int8 0 // ,
int8 (specif_minus-def)/4 // -: left justified
int8 0 // .
int8 0 // /
int8 (specif_number-def)/4 // 0
int8 (specif_number-def)/4 // 1
int8 (specif_number-def)/4 // 2
int8 (specif_number-def)/4 // 3
int8 (specif_number-def)/4 // 4
int8 (specif_number-def)/4 // 5
int8 (specif_number-def)/4 // 6
int8 (specif_number-def)/4 // 7
int8 (specif_number-def)/4 // 8
int8 (specif_number-def)/4 // 9
int8 0 // :
int8 0 // ;
int8 0 // <
int8 0 // =
int8 0 // >
int8 0 // ?
int8 0 // @
int8 (specif_hex-def)/4 // A: hexadecimal float
int8 0 // B
int8 0 // C
int8 0 // D
int8 (specif_float-def)/4 // E: float
int8 (specif_float-def)/4 // F: float
int8 (specif_float-def)/4 // G: float
int8 0 // H
int8 0 // I
int8 0 // J
int8 0 // K
int8 (specif_l-def)/4 // L: long (long double)
int8 0 // M
int8 0 // N
int8 0 // O
int8 0 // P
int8 0 // Q
int8 0 // R
int8 0 // S
int8 0 // T
int8 0 // U
int8 0 // V
int8 0 // W
int8 (specif_hex-def)/4 // X: hexadecimal
int8 0 // Y
int8 0 // Z
int8 0 // [
int8 0 // \
int8 0 // ]
int8 0 // ^
int8 0 // _
int8 0 // `
int8 (specif_hex-def)/4 // a: hexadecimal float
int8 0 // b
int8 (specif_char-def)/4 // c: character
int8 (specif_dec-def)/4 // d: signed decimal
int8 (specif_float-def)/4 // e: float
int8 (specif_float-def)/4 // f: float
int8 (specif_float-def)/4 // g: float
int8 (specif_h-def)/4 // h: short
int8 (specif_dec-def)/4 // i: signed decimal
int8 (specif_l-def)/4 // j: intmax_t
int8 0 // k
int8 (specif_l-def)/4 // l: long
int8 0 // m
int8 (specif_num-def)/4 // n: read number of characters printed so far
int8 0 // o
int8 (specif_hex-def)/4 // p: pointer, print as hexadecimal
int8 0 // q
int8 0 // r
int8 (specif_string-def)/4 // s: string
int8 (specif_l-def)/4 // t: ptrdiff_t
int8 (specif_uns-def)/4 // u: unsigned decimal
int8 0 // v
int8 0 // w
int8 (specif_hex-def)/4 // x: hexadecimal
int8 0 // y
int8 (specif_l-def)/4 // z: size_t
const end
code section execute align = 4 // code section
// _printf: print formatted string to stdout
// parameters: r0: format string, r1: parameter list
_printf function public reguse = 0xF, 0
int64 r2 = r0 // format string
int64 r3 = r1 // parameter list
int64 sp -= 10*8 // start saving registers
int64 [sp+0x30] = r10 // save r10. The rest are saved under printf_generic
int64 r10 = address ([char_to_stdout])
jump printf_generic
// _sprintf: print formatted string to string buffer
// parameters: r0: destination string, r1: format string, r2: parameter list
_sprintf function public reguse = 0xF, 0
int64 r3 = r2 // parameter list
int64 r2 = r1 // format string
int64 r1 = -1 // character count limit = UINT_MAX
int64 sp -= 10*8 // start saving registers
int64 [sp+0x30] = r10 // save r10. The rest are saved under printf_generic
int64 r10 = address ([char_to_string])
jump printf_generic
// _snprintf: print formatted string to string buffer with limit
// parameters: r0: destination string, r1: length limit, r2: format string, r3: parameter list
_snprintf function public reguse = 0xF, 0
int64 r1-- // character count limit. make space for terminating zero
int64 sp -= 10*8 // start saving registers
int64 [sp+0x30] = r10 // save r10. The rest are saved under printf_generic
int64 r10 = address ([char_to_string])
// continue in printf_generic
printf_generic: // common procedure for all printf variants
// save r4 - r13
//int64 sp -= 10*8 // this is done above
int64 [sp+0x00] = r4
int64 [sp+0x08] = r5
int64 [sp+0x10] = r6
int64 [sp+0x18] = r7
int64 [sp+0x20] = r8
int64 [sp+0x28] = r9
// int64 [sp+0x30] = r10 // r10 saved above
int64 [sp+0x38] = r11
int64 [sp+0x40] = r12
int64 [sp+0x48] = r13
if (int64 r2 == 0) {jump finish} // format string pointer is null
int r13 = 0 // reset field width
int r11 = 0 // reset modifiers
int r12 = 0 // state start
// loop through format string
while (true) {
int8 r8 = [r2] // read character from format string
if (int8+ r8 == 0) {break} // end of format string
int64 r2++ // increment format string pointer
if (int r12 == 0) { // state start
if (int8+ r8 == '%') {
int r12 = 1 // state after '%'
}
else {
call (r10) // print character from format string
}
nop
}
else { // after '%' or modifier
int r6 = r8 - ' ' // table index
int64 r4 = address ([unknown_character])
if (uint r6 > 91) {
call (r4) // call unknown_character
}
else {
int64 r5 = address ([call_table])
int8 call_relative (r4, [r5 + r6*1]) // dispatch format specifier or modifier
}
}
}
finish:
// if printing to string, insert terminating zero
int64 r4 = address ([char_to_string])
if (uint64 r10 >= r4) {
int r4 = 0
int8 [r0] = r4
}
int64 r0 = r9 // return number of characters written
// restore r4 - r13
int64 r4 = [sp+0x00]
int64 r5 = [sp+0x08]
int64 r6 = [sp+0x10]
int64 r7 = [sp+0x18]
int64 r8 = [sp+0x20]
int64 r9 = [sp+0x28]
int64 r10 = [sp+0x30]
int64 r11 = [sp+0x38]
int64 r12 = [sp+0x40]
int64 r13 = [sp+0x48]
int64 sp += 10*8
return // return from _printf, etc.
/////////////////////////////////////////////////////////////
// subfunctions for different characters in format string
/////////////////////////////////////////////////////////////
specif_space: // ' ': print space or minus
if (int r12 != 1) {jump unknown_character}
int r11 |= 8 // set modifier flag
return
specif_plus: // +: print sign
if (int r12 != 1) {jump unknown_character}
int r11 |= 4 // set modifier flag
return
specif_minus: // -: left justified
if (int r12 != 1) {jump unknown_character}
int r11 |= 1 // set modifier flag
return
specif_hash: // hash sign: print prefix 0x
if (int r12 != 1) {jump unknown_character}
int r11 |= 0x10 // set modifier flag
return
specif_h: // h: short
int r4 = test_bits_or(r11, 0x40) // is there a preceding h?
int r11 |= 0x40 // set modifier flag h
int r11 |= 0x80, mask = r4 // set modifier flag hh
int r12 = 3 // state after sub_specifier
return
specif_l: // l: long
int r11 |= 0x20 // set modifier flag l
int r12 = 3 // state after sub_specifier
return
specif_percent: // %: print percent sign
jump unknown_character // just print % sign and reset state
specif_star: // *: width specified by parameter
if (int r12 != 1) {jump unknown_character}
int r13 = [r3] // read width from paramter
int64 r3 += 8
int r12 = 2 // state after width
int r11 |= 0x100 // set modifier flag
return
specif_number: // 0-9
if (int r12 == 1) {
if (int r8 == '0') { // leading '0' means print leading zeroes
int r11 |= 2 // set modifier flag 2
return
}
}
// number specifies width
// width = previous_width * 10 + new_digit
int r4 = r13 << 3 // multiply width by 10
int r13 <<= 1
int r13 += r4
int r8 -= '0' // convert from ASCII
int r13 += r8 // new width
int r12 = 2 // state after width
int r11 |= 0x100 // set modifier flag
return
// subfunction for writing to stdout
char_to_stdout:
int8 output(r8, r8, 10) // write to stdout
int64 r9++ // count characters written
return
// subfunction for writing to string
char_to_string:
int64 r9++ // count characters written or potentially written
if (uint64 r9 > r1) { // compare with string length limit
jump char_to_string9 // stop printing
}
int8 [r0] = r8 // write to string
int64 r0++ // increment string pointer
char_to_string9:
return
// %n: read number of characters printed so far
specif_num: // n: read number of characters printed so far
int64 r4 = [r3] // read pointer from parameter list
int64 r3 += 8 // increment parameter list
int32 [r4] = r9 // save number of characters written
jump reset_state
// %c: Print character
specif_char: // c: print character
int r13-- // number of leading or trailing spaces to pring
if (int !(r11 & 1)) { // field is right justified. print leading spaces
int r8 = ' ' // leading spaces
for (int; r13 > 0; r13--) {
call (r10) // print space
}
}
int8 r8 = [r3] // read character from parameter list
int64 r3 += 8 // increment parameter list
call (r10) // print character
int r8 = ' ' // print any trailing spaces
for (int; r13 > 0; r13--) {
call (r10) // print space
}
jump reset_state
// %s: Print string
specif_string: // s: string
int64 r6 = [r3] // read string pointer from parameter list
int64 r3 += 8 // increment parameter list
if (int64 r6 == 0) {jump unknown_character} // null string
int r4 = r11 ^ 1 // check if right justified
int16+ test_bits_and(r4, 0x101), jump_false specif_string2
// string is right justified with specified width. check if leading spaces are needed
for (int r5 = 0; r5 < r13; r5++) {
int8 r8 = [r6+r5] // read string character
if (int8+ r8 == 0) {break} // string is shorter. leading spaces needed
}
// print leading spaces
int r8 = ' '
for (int ; r5 < r13; r5++) {
call (r10) // print space
}
int r13 = 0 // avoid printing trailing spaces also
specif_string2:
while (true) {
int8 r8 = [r6] // read character from string
if (int8+ r8 == 0) {break} // end of string
int64 r6++ // increment string pointer
call (r10) // print character
int r13-- // count down field width
}
// print any trailing space
int r8 = ' '
while (int r13 > 0) {
call (r10) // print character
int r13-- // count down field width
}
jump reset_state
// %e, %f, %g: Print floating point number
specif_float:
//jump specif_float1 // (intermediate jump target specif_float placed here to avoid overflow in call table)
// float not implemented. print as %#LX
int r11 |= 0x30 // print 0x prefix, 64 bits
jump specif_hex
// reference point, default in call table, print unknown character:
def: // default, reference point in call table
unknown_character: // unknown character after '%'
call r10 // print character
//jump reset_state
reset_state: // reset state after '%' command
int r11 = 0 // reset modifiers
int r12 = 0 // state start
int r13 = 0 // reset field width
return
// %x: Print hexadecimal
specif_hex: // X: hexadecimal
int r7 = r8 & 0x20 // is lower case
int64 r4 = [r3] // read integer from parameter list
int64 r3 += 8 // increment parameter list
if (int !(r11 & 0x20)) { // check if long int
int32 r4 = r4 // not long. truncate to 32 bits
}
specif_hex2: // entry from %i (decimal) if number too big
int64 r5 = bitscan(r4, 1) // find number of bits
uint32 r5 >>= 2
int32 r5++ // number of digits to print
int r13 -= r5 // number of leading or trailing spaces to print
int r6 = test_bit(r11, 4) // '#' option
int r13 -= 2, mask = r6 // make space of 0x prefix
if (int !(r11 & 1)) { // field is right justified. print leading spaces
int r8 = ' ' // leading spaces
int r6 = test_bit(r11, 1) // get bit 1: leading zeroes
int r8 = '0', mask=r6, fallback=r8 // leading zeroes instead of leading spaces
while (int r13 > 0) { // print r13 leading spaces or zeroes
call r10
int r13--
}
}
if (int r11 & 0x10) { // '#' flag. Print 0x prefix
int r8 = '0'
call r10
int r8 = 'X' | r7 // 'x' or 'X'
call r10
}
// convert to hexadecimal
if (int r5 > 8) { // must use 64 bits
int r6 = 16 - r5 // number of digits to skip
int r6 <<= 2 // number of bits to skip
uint64 r4 <<= r6 // remove leading zero bits
for (int ; r5 > 0; r5--) { // loop for r5 digits
uint64 r4 = rotate(r4, 4) // get digit into low position
int r8 = r4 & 0xF // get digit
int r8 += '0' // convert to ASCII
int r6 = r8 > '9' // digit is A - F
int r8 += 7, mask = r6 // add 7 to get letter A - F
int r8 |= r7 // lower case
call r10 // print character
}
}
else { // use 32 bits. CPU may not support 64 bits
int r6 = 8 - r5 // number of digits to skip
int r6 <<= 2 // number of bits to skip
uint32 r4 <<= r6 // remove leading zero bits
for (int ; r5 > 0; r5--) { // loop for r5 digits
uint32 r4 = rotate(r4, 4) // get digit into low position
int r8 = r4 & 0xF // get digit
int r8 += '0' // convert to ASCII
int r6 = r8 > '9' // digit is A - F
int r8 += 7, mask = r6 // add 7 to get letter A - F
int r8 |= r7 // lower case
call r10 // print character
}
}
// print any trailing spaces
int r8 = ' ' // trailing spaces
while (int r13 > 0) { // print r13 trailing spaces
call r10
int r13--
}
jump reset_state
// %i, %d: Print signed decimal integer
specif_dec: // i: signed decimal
int64 r4 = [r3] // read integer from parameter list
int64 r3 += 8 // increment parameter list
if (int r11 & 0x20) { // %li: 64-bit integer
int64 r5 = test_bit(r4, 63) // get sign bit
int64 r4 = -r4, mask = r5 // change sign if negative
int r11 |= 0x200, mask = r5 // set bit to remember negative
int64 r6 = bitscan(r4, 1) // find number of bits
if (int r6 > 31) { // cannot handle 64 bits decimal. Do hexadecimal instead
int r11 |= 0x11 // prepare for hexadecimal escape. get 0x prefix and left justify
int r7 = 0 // use upper case for hexadecimal escape
if (int8+ r5 & 1) {
int r8 = '-' // print '-'
call r10
}
jump specif_hex2 // print as hexadecimal
}
}
else {
if (int r11 & 0x80) { // %hhi: int8
int32 r5 = test_bit(r4, 7) // get sign bit
int8 r4 = -r4, mask = r5 // change sign if negative. truncate to 8 bits
int r11 |= 0x200, mask = r5 // set bit to remember negative
}
else {
if (int r11 & 0x40) { // %hhi: int16
int32 r5 = test_bit(r4, 15) // get sign bit
int16 r4 = -r4, mask = r5 // change sign if negative. truncate to 16 bits
int r11 |= 0x200, mask = r5 // set bit to remember negative
}
else {
// %i: int32
int32 r5 = test_bit(r4, 31) // get sign bit
int32 r4 = -r4, mask = r5 // change sign if negative. truncate to 16 bits
int r11 |= 0x200, mask = r5 // set bit to remember negative
}
}
}
jump specif_uns2 // sign has been stored in r11. continue in unsigned
// %u: Print unsigned decimal integer
specif_uns: // u: unsigned decimal
int64 r4 = [r3] // read integer from parameter list
int64 r3 += 8 // increment parameter list
if (int r11 & 0x20) { // %li: 64-bit integer
int64 r6 = bitscan(r4, 1) // find number of bits
int r8 |= 0x10 // prepare for hexadecimal escape. get 0x prefix
int r7 = 0 // use upper case for hexadecimal escape
if (int r6 > 31) {jump specif_hex2}// cannot handle 64 bits decimal. Do hexadecimal instead
}
specif_uns2:
int64 sp -= 8 // save r14
int64 [sp] = r14
// 32 bit decimal signed or unsigned
// First two BCD digits are made with simple subtraction to avoid the need for a larger bit field
int r5 = 0 // upper two BCD digits
while (uint32 r4 >= 1000000000) {
nop
uint32 r4 -= 1000000000
uint32 r5 += 0x10
nop
}
while (uint32 r4 >= 100000000) {
uint32 r4 -= 100000000
uint32 r5 += 0x01
}
// Generate 8 BCD digits using double dabble algorithm
int32 r14 = 0 // generate BCD in r14
for (int r6 = 0; r6 < 32; r6++) { // loop for 32 bits
int32 r7 = r14 + 0x33333333 // digit values 5-9 will set bit 3 in each 4-bit nibble
int32 r7 &= 0x88888888 // isolate bit 3 in each nibble
int32 r8 = r7 >> 3 // generate value 3 in nibbles with value 5-9
int32 r7 >>= 2
int32 r7 |= r8 // this will have 3 for each nibble with a value 5-9
int32 r14 += r7 // add 3 to nibble values 5-9 to generate 8-12
int32 r14 = funnel_shift(r4, r14, 31) // shift most significant bit of r4 into r14
int32 r4 <<= 1
}
// r5:r14 = BCD value
// determine width
int r6 = bitscan(r14, 1) // number of significant bits
uint r6 >>= 2 // number of significant digits in low part
int r6++ // number of digits in low part
if (int r5 != 0) { // high part is nonzero
int r6 = bitscan(r5, 1) // find number of digits in high part
uint r6 >>= 2
int r6 += 9 // number of digits total
}
int r7 = test_bits_or(r11, 0x20C) // leading sign needed
int r6 += r7 // number of characters needed
int r13 -= r6 // number of leading or trailing spaces needed
if (int !(r11 & 1)) { // right justified
int r6 = r13 > 0 && r7 // leading sign && leading spaces
int r4 = test_bit(r11, 1), options=1, fallback=r6 // leading zeroes and leading sign. sign must come first
int r8 = ' ' // leading sign to print
int r6 = test_bit(r11, 2) // flag for '+' prefix
int r8 = '+', mask=r6, fallback=r8 // leading + required if not negative
int r6 = test_bit(r11, 9) // flag for negative
int r8 = '-', mask=r6, fallback=r8 // leading -. value is negative
if (int r4 & 1) { // sign must come before leading zeroes
call r10 // print leading sign
int r7 = 0 // remember leading sign has been written
}
// print leading spaces or zeroes
int r8 = ' ' // space
int r6 = test_bit(r11, 1) // flag for leading zeroes
int r8 = '0', mask=r6, fallback=r8
while (int r13 > 0) { // write leading spaces or zeroes
call r10
int r13--
}
}
if (int r7 & 1) { // sign after leading spaces
int r8 = ' ' // space
int r6 = test_bit(r11, 2) // flag for '+' prefix
int r8 = '+', mask=r6, fallback=r8 // leading + required if not negative
int r6 = test_bit(r11, 9) // flag for negative
int r8 = '-', mask=r6, fallback=r8 // leading -. value is negative
call r10 // write sign
}
int r4 = 0 // remember if first digit has been printed
// print high two digits
uint32 r5 <<= 24 // left justify high part
for (int r6 = 2; r6 > 0; r6--) { // print two high digits if any
int32 r5 = rotate(r5, 4) // get most significant digit first
int8 r8 = r5 & 0x0F
int r4 = (r8 != 0) || r4 // digit has been printed
int8 r8 += '0' // convert to ASCII
if (int r4 != 0) {
call r10 // print character to stdout
}
}
// print low 8 decimal digits
for (int r6 = 8; r6 > 0; r6--) {
int32 r14 = rotate(r14, 4) // get most significant digit first
int8 r8 = r14 & 0x0F
int r4 = (r8 != 0) || r4 // digit has been printed
int r4 = (r6 == 1) || r4 // last digit must be printed
int8 r8 += '0' // convert to ASCII
if (int r4 != 0) {
call r10 // print character to stdout
}
}
// print trailing spaces
int r8 = ' ' // space
while (int r13 > 0) { // write trailing spaces
call r10
int r13--
}
int64 r14 = [sp] // restore r14
int64 sp += 8
jump reset_state // finished
// %e, %f, %g: Print floating point number. not implemented
specif_float1:
nop
jump reset_state // finished
code end
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