* */*: cl_istream -> std::istream, cl_ostream -> std::ostream.

[cln.git] / src / complex / input / cl_N_read.cc

// read_complex().

// General includes.
#include "cl_sysdep.h"

// Specification.
#include "cln/complex_io.h"


// Implementation.

#include <string.h>
#include "cln/input.h"
#include "cln/real_io.h"
#include "cln/float_io.h"
#include "cln/rational_io.h"
#include "cln/integer_io.h"
#include "cln/integer.h"
#include "cl_I.h"
#include "cl_F.h"
#include "cl_C.h"
#include "cln/abort.h"

#undef floor
#include <cmath>
#define floor cln_floor


namespace cln {

// Step forward over all digits, to the end of string or to the next non-digit.
static const char * skip_digits (const char * ptr, const char * string_limit, unsigned int base)
{
        for ( ; ptr != string_limit; ptr++) {
                var char ch = *ptr;
                if ((ch >= '0') && (ch <= '9'))
                        if (ch < '0' + (int)base)
                                continue;
                        else
                                break;
                else {
                        if (base <= 10)
                                break;
                        if (((ch >= 'A') && (ch < 'A'-10+(int)base))
                            || ((ch >= 'a') && (ch < 'a'-10+(int)base))
                           )
                                continue;
                        else
                                break;
                }
        }
        return ptr;
}

// Finish reading the "+yi" part of "x+yi" when "x" has already been read.
static const cl_N read_complex_number_rest (const cl_read_flags& flags, const char * string_rest, const char * string, const char * string_limit, const char * * end_of_parse, const cl_R& x);

#define at_end_of_parse(ptr)  \
  if (end_of_parse)                                                     \
    { *end_of_parse = (ptr); }                                          \
  else                                                                  \
    { if ((ptr) != string_limit) { read_number_junk((ptr),string,string_limit); } }

const cl_N read_complex (const cl_read_flags& flags, const char * string, const char * string_limit, const char * * end_of_parse)
{
        // If no string_limit is given, it defaults to the end of the string.
        if (!string_limit)
                string_limit = string + ::strlen(string);
        if (flags.syntax & syntax_rational) {
                // Check for rational number syntax.
                var unsigned int rational_base = flags.rational_base;
                var const char * ptr = string;
                if (flags.lsyntax & lsyntax_commonlisp) {
                        if (ptr == string_limit) goto not_rational_syntax;
                        if (*ptr == '#') {
                                // Check for #b, #o, #x, #nR syntax.
                                ptr++;
                                if (ptr == string_limit) goto not_rational_syntax;
                                switch (*ptr) {
                                case 'b': case 'B':
                                        rational_base = 2; break;
                                case 'o': case 'O':
                                        rational_base = 8; break;
                                case 'x': case 'X':
                                        rational_base = 16; break;
                                default:
                                        var const char * base_end_ptr =
                                                skip_digits(ptr,string_limit,10);
                                        if (base_end_ptr == ptr) goto not_rational_syntax;
                                        if (base_end_ptr == string_limit) goto not_rational_syntax;
                                        if (!((*base_end_ptr == 'r') || (*base_end_ptr == 'R')))
                                                goto not_rational_syntax;
                                        var cl_I base = read_integer(10,0,ptr,0,base_end_ptr-ptr);
                                        if (!((base >= 2) && (base <= 36))) {
                                                fprint(std::cerr, "Base must be an integer in the range from 2 to 36, not ");
                                                fprint(std::cerr, base);
                                                fprint(std::cerr, "\n");
                                                cl_abort();
                                        }
                                        rational_base = FN_to_UL(base); ptr = base_end_ptr;
                                        break;
                                }
                                ptr++;
                        }
                }
                var const char * ptr_after_prefix = ptr;
                var cl_signean sign = 0;
                if (ptr == string_limit) goto not_rational_syntax;
                switch (*ptr) {
                        case '-': sign = ~sign;
                        case '+': ptr++;
                        default: break;
                }
                var const char * ptr_after_sign = ptr;
                if (flags.syntax & syntax_integer) {
                        // Check for integer syntax:  {'+'|'-'|} {digit}+ {'.'|}
                        // Allow final dot only in Common Lisp syntax if there was no #<base> prefix.
                        if ((flags.lsyntax & lsyntax_commonlisp) && (ptr_after_prefix == string)) {
                                ptr = skip_digits(ptr_after_sign,string_limit,10);
                                if (ptr != ptr_after_sign)
                                  if (ptr != string_limit)
                                    if (*ptr == '.') {
                                        ptr++;
                                        if ((ptr == string_limit) || !(((*ptr >= '0') && (*ptr <= '9')) || ((*ptr >= 'A') && (*ptr <= 'Z') && (*ptr != 'I')) || ((*ptr >= 'a') && (*ptr <= 'z') && (*ptr != 'i')) || (*ptr == '.') || (*ptr == '_') || (*ptr == '/')))
                                                return read_complex_number_rest(flags,ptr,string,string_limit,end_of_parse,
                                                        read_integer(10,sign,ptr_after_sign,0,ptr-ptr_after_sign));
                                }
                        }
                        ptr = skip_digits(ptr_after_sign,string_limit,rational_base);
                        if ((ptr == string_limit) || !(((*ptr >= '0') && (*ptr <= '9')) || ((*ptr >= 'A') && (*ptr <= 'Z') && (*ptr != 'I')) || ((*ptr >= 'a') && (*ptr <= 'z') && (*ptr != 'i')) || (*ptr == '.') || (*ptr == '_') || (*ptr == '/')))
                                return read_complex_number_rest(flags,ptr,string,string_limit,end_of_parse,
                                        read_integer(rational_base,sign,ptr_after_sign,0,ptr-ptr_after_sign));
                }
                if (flags.syntax & syntax_ratio) {
                        // Check for ratio syntax: {'+'|'-'|} {digit}+ '/' {digit}+
                        ptr = skip_digits(ptr_after_sign,string_limit,rational_base);
                        if (ptr != ptr_after_sign)
                          if (ptr != string_limit)
                            if (*ptr == '/') {
                                var const char * ptr_at_slash = ptr;
                                ptr = skip_digits(ptr_at_slash+1,string_limit,rational_base);
                                if (ptr != ptr_at_slash+1)
                                  if ((ptr == string_limit) || !(((*ptr >= '0') && (*ptr <= '9')) || ((*ptr >= 'A') && (*ptr <= 'Z') && (*ptr != 'I')) || ((*ptr >= 'a') && (*ptr <= 'z') && (*ptr != 'i')) || (*ptr == '.') || (*ptr == '_') || (*ptr == '/')))
                                        return read_complex_number_rest(flags,ptr,string,string_limit,end_of_parse,
                                                read_rational(rational_base,sign,ptr_after_sign,0,ptr_at_slash-ptr_after_sign,ptr-ptr_after_sign));
                        }
                }
        }
not_rational_syntax:
        if (flags.syntax & syntax_float) {
                // Check for floating-point number syntax:
                // {'+'|'-'|} {digit}+ {'.' {digit}* | } expo {'+'|'-'|} {digit}+
                // {'+'|'-'|} {digit}* '.' {digit}+ expo {'+'|'-'|} {digit}+
                // {'+'|'-'|} {digit}* '.' {digit}+
                var const char * ptr = string;
                var const unsigned int float_base = 10;
                var cl_signean sign = 0;
                if (ptr == string_limit) goto not_float_syntax;
                switch (*ptr) {
                        case '-': sign = ~sign;
                        case '+': ptr++;
                        default: break;
                }
                var const char * ptr_after_sign = ptr;
                var const char * ptr_after_intpart = skip_digits(ptr_after_sign,string_limit,float_base);
                var cl_boolean have_dot = cl_false;
                var const char * ptr_before_fracpart = ptr_after_intpart;
                var const char * ptr_after_fracpart = ptr_after_intpart;
                ptr = ptr_after_intpart;
                if (ptr != string_limit)
                  if (*ptr == '.') {
                        have_dot = cl_true;
                        ptr_before_fracpart = ptr+1;
                        ptr_after_fracpart = skip_digits(ptr_before_fracpart,string_limit,float_base);
                }
                ptr = ptr_after_fracpart;
                var char exponent_marker;
                var cl_boolean have_exponent;
                var const char * ptr_in_exponent = ptr;
                var const char * ptr_after_exponent = ptr;
                if ((ptr == string_limit) || !(((*ptr >= '0') && (*ptr <= '9')) || ((*ptr >= 'A') && (*ptr <= 'Z') && (*ptr != 'I')) || ((*ptr >= 'a') && (*ptr <= 'z') && (*ptr != 'i')) || (*ptr == '.') || (*ptr == '/'))) {
                        // No exponent.
                        have_exponent = cl_false;
                        // Must have at least one fractional part digit.
                        if (ptr_after_fracpart == ptr_before_fracpart) goto not_float_syntax;
                        exponent_marker = 'E';
                } else {
                        have_exponent = cl_true;
                        // Must have at least one digit.
                        if (ptr_after_sign == ptr_after_intpart)
                                if (ptr_after_fracpart == ptr_before_fracpart)
                                        goto not_float_syntax;
                        exponent_marker = ((*ptr >= 'a') && (*ptr <= 'z') ? *ptr - 'a' + 'A' : *ptr);
                        switch (exponent_marker) {
                                case 'E':
                                case 'S': case 'F': case 'D': case 'L':
                                        break;
                                default:
                                        goto not_float_syntax;
                        }
                }
                if (have_exponent) {
                        ptr++;
                        if (ptr == string_limit) goto not_float_syntax;
                        switch (*ptr) {
                                case '-':
                                case '+': ptr++;
                                default: break;
                        }
                        ptr_in_exponent = ptr;
                        ptr_after_exponent = skip_digits(ptr_in_exponent,string_limit,10);
                        if (ptr_after_exponent == ptr_in_exponent) goto not_float_syntax;
                }
                ptr = ptr_after_exponent;
                var const char * ptr_after_prec = ptr;
                var float_format_t prec;
                if ((ptr != string_limit) && (*ptr == '_')) {
                        ptr++;
                        ptr_after_prec = skip_digits(ptr,string_limit,10);
                        if (ptr_after_prec == ptr) goto not_float_syntax;
                        var cl_I prec1 = digits_to_I(ptr,ptr_after_prec-ptr,10);
                        var uintL prec2 = cl_I_to_UL(prec1);
                        prec = (float_base==10 ? float_format(prec2)
                                               : (float_format_t)((uintL)((1+prec2)*::log((double)float_base)*1.442695041)+1)
                               );
                } else {
                        switch (exponent_marker) {
                                case 'S': prec = float_format_sfloat; break;
                                case 'F': prec = float_format_ffloat; break;
                                case 'D': prec = float_format_dfloat; break;
                                case 'L': prec = flags.float_flags.default_lfloat_format; break;
                                case 'E': prec = flags.float_flags.default_float_format; break;
                                default: NOTREACHED
                        }
                        if (flags.float_flags.mantissa_dependent_float_format) {
                                // Count the number of significant digits.
                                ptr = ptr_after_sign;
                                while (ptr < ptr_after_fracpart && (*ptr == '0' || *ptr == '.')) ptr++;
                                var uintL num_significant_digits =
                                  (ptr_after_fracpart - ptr) - (ptr_before_fracpart > ptr ? 1 : 0);
                                var uintL prec2 = (num_significant_digits>=2 ? num_significant_digits-2 : 0);
                                var float_format_t precx =
                                  (float_base==10 ? float_format(prec2)
                                                  : (float_format_t)((uintL)((1+prec2)*::log((double)float_base)*1.442695041)+1)
                                  );
                                if ((uintL)precx > (uintL)prec)
                                        prec = precx;
                        }
                }
                floatformatcase(prec
                ,       if (!(flags.syntax & syntax_sfloat)) goto not_float_syntax;
                ,       if (!(flags.syntax & syntax_ffloat)) goto not_float_syntax;
                ,       if (!(flags.syntax & syntax_dfloat)) goto not_float_syntax;
                ,       unused len;
                        if (!(flags.syntax & syntax_lfloat)) goto not_float_syntax;
                );
                return read_complex_number_rest(flags,ptr_after_prec,string,string_limit,end_of_parse,
                        read_float(float_base,prec,sign,ptr_after_sign,0,ptr_after_fracpart-ptr_after_sign,ptr_after_exponent-ptr_after_sign,ptr_before_fracpart-ptr_after_sign));
        }
not_float_syntax:
        if ((flags.syntax & syntax_complex) && (flags.lsyntax & lsyntax_commonlisp)) {
                // Check for complex number syntax:
                // '#' {'C'|'c'} '(' realpart {' '}+ imagpart ')'
                var const char * ptr = string;
                if (ptr == string_limit) goto not_complex_syntax;
                if (!(*ptr == '#')) goto not_complex_syntax;
                ptr++;
                if (ptr == string_limit) goto not_complex_syntax;
                if (!((*ptr == 'C') || (*ptr == 'c'))) goto not_complex_syntax;
                ptr++;
                // Modified flags for parsing the realpart and imagpart:
                var cl_read_flags flags_for_parts = flags;
                flags_for_parts.syntax = (cl_read_syntax_t)((flags_for_parts.syntax & ~syntax_complex) | syntax_maybe_bad);
                var const char * end_of_part;
                if (ptr == string_limit) goto not_complex_syntax;
                if (!(*ptr == '(')) goto not_complex_syntax;
                ptr++;
                var cl_R realpart = read_real(flags_for_parts,ptr,string_limit,&end_of_part);
                if (end_of_part == ptr) goto not_complex_syntax;
                ptr = end_of_part;
                if (ptr == string_limit) goto not_complex_syntax;
                if (!(*ptr == ' ')) goto not_complex_syntax;
                ptr++;
                while ((ptr != string_limit) && (*ptr == ' ')) { ptr++; }
                var cl_R imagpart = read_real(flags_for_parts,ptr,string_limit,&end_of_part);
                if (end_of_part == ptr) goto not_complex_syntax;
                ptr = end_of_part;
                if (ptr == string_limit) goto not_complex_syntax;
                if (!(*ptr == ')')) goto not_complex_syntax;
                ptr++;
                at_end_of_parse(ptr);
                return complex(realpart,imagpart);
        }
not_complex_syntax:
bad_syntax:
        if (flags.syntax & syntax_maybe_bad) {
                ASSERT(end_of_parse);
                *end_of_parse = string;
                return 0; // dummy return
        }
        read_number_bad_syntax(string,string_limit);
}

static const cl_N read_complex_number_rest (const cl_read_flags& flags, const char * string_rest, const char * string, const char * string_limit, const char * * end_of_parse, const cl_R& x)
{
        unused string;
        if ((flags.syntax & syntax_complex) && (flags.lsyntax & lsyntax_algebraic)) {
                // Finish reading the "+yi" part of "x+yi".
                // We allow "y" to begin with a '-'.
                // We also allow the '+' to be replaced by '-', but in this case
                // "y" may not begin with a '-'.
                // We also allow the syntax "xi" (implicit realpart = 0).
                var const char * ptr = string_rest;
                if (ptr == string_limit) goto not_complex_syntax;
                if ((*ptr == 'i') || (*ptr == 'I')) {
                        ptr++;
                        at_end_of_parse(ptr);
                        return complex(0,x);
                }
                switch (*ptr) {
                        case '+': ptr++;
                        case '-': break;
                        default: goto not_complex_syntax;
                }
                // Modified flags for parsing the imagpart:
                var cl_read_flags flags_for_part = flags;
                flags_for_part.syntax = (cl_read_syntax_t)((flags_for_part.syntax & ~syntax_complex) | syntax_maybe_bad);
                var const char * end_of_part;
                var const cl_R& realpart = x;
                var cl_R imagpart = read_real(flags_for_part,ptr,string_limit,&end_of_part);
                if (end_of_part == ptr) goto not_complex_syntax;
                ptr = end_of_part;
                if (ptr == string_limit) goto not_complex_syntax;
                if (!((*ptr == 'i') || (*ptr == 'I'))) goto not_complex_syntax;
                ptr++;
                at_end_of_parse(ptr);
                return complex(realpart,imagpart);
        }
not_complex_syntax:
        at_end_of_parse(string_rest);
        return x;
}

}  // namespace cln