/* * Copyright (c) 2013, Kelvin W Sherlock * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ #include "qd.h" #include "toolbox.h" #include "sane.h" #include #include #include #include #include #include #include #include #include "stackframe.h" #include "complex.h" #include "fpinfo.h" using ToolBox::Log; namespace SANE { using std::to_string; using std::fpclassify; using std::signbit; using std::abs; using its_complicated::to_string; using its_complicated::fpclassify; using its_complicated::signbit; namespace { // default environment is: // rounding direction: to nearest // rounding precision: extended // exception flags: clear // halts: clear /* * Environment: x d d e e e e e x p p h h h h h * x - reserved * d d - rounding direction * e - exception flags * p - rounding precision * h - halt flags */ enum { kExceptionInexact = 1 << 12, kExceptionDivideByZero = 1 << 11, kExceptionOverflow = 1 << 10, kExceptionUnderflow = 1 << 9, kExceptionInvalid = 1 << 8, kHaltInexact = 1 << 4, kHaltDivideByZero = 1 << 3, kHaltOverflow = 1 << 2, kHaltUnderflow = 1 << 1, kHaltInvalid = 1 << 0, kRoundingDirectionMask = 0x6000, kRoundingDirectionToNearest = 0x0000, kRoundingDirectionUpward = 0x2000, kRoundingDirectionDownward = 0x4000, kRoundingDirectionTowardZero = 0x6000, kRoundingPrecisionMask = 0x0060, kRoundingPrecisionExtended = 0x0000, kRoundingPrecisionDouble = 0x0020, kRoundingPrecisionSingle = 0x0040, kRoundingPrecisionUndefined = 0x0060, }; const uint16_t DefaultEnvironment = 0; uint16_t Environment = DefaultEnvironment; } // long double is an 80-bit extended with an extra 48-bits of 0 padding. typedef long double extended; template T readnum(uint32_t address); template<> int16_t readnum(uint32_t address) { return memoryReadWord(address); } template<> int32_t readnum(uint32_t address) { return memoryReadLong(address); } template<> int64_t readnum(uint32_t address) { return memoryReadLongLong(address); } template<> complex readnum(uint32_t address) { return complex(memoryReadLongLong(address)); } template<> float readnum(uint32_t address) { static_assert(sizeof(float) == 4, "unexpected float size"); uint32_t x = memoryReadLong(address); return *((float *)&x); } template<> double readnum(uint32_t address) { static_assert(sizeof(double) == 8, "unexpected double size"); uint64_t x = memoryReadLongLong(address); return *((double *)&x); } template<> long double readnum(uint32_t address) { char buffer[16]; static_assert(sizeof(long double) == 16, "unexpected long double size"); // read and swap 10 bytes // this is very much little endian. for (unsigned i = 0; i < 10; ++i) { buffer[9 - i] = memoryReadByte(address + i); } // remainder are 0-filled. for (unsigned i = 10; i < 16; ++i) buffer[i] = 0; // now cast... return *((long double *)buffer); } template void writenum(T value, uint32_t address); template<> void writenum(int16_t value, uint32_t address) { memoryWriteWord(value, address); } template<> void writenum(int32_t value, uint32_t address) { memoryWriteLong(value, address); } template<> void writenum(int64_t value, uint32_t address) { memoryWriteLongLong(value, address); } template<> void writenum(complex value, uint32_t address) { memoryWriteLongLong(value, address); } template<> void writenum(float value, uint32_t address) { static_assert(sizeof(value) == 4, "unexpected float size"); memoryWriteLong(*((uint32_t *)&value), address); } template<> void writenum(double value, uint32_t address) { static_assert(sizeof(value) == 8, "unexpected double size"); memoryWriteLongLong(*((uint64_t *)&value), address); } template<> void writenum(long double value, uint32_t address) { static_assert(sizeof(value) == 16, "unexpected long double size"); char buffer[16]; std::memcpy(buffer, &value, sizeof(value)); // copy 10 bytes over // little-endian specific. for(unsigned i = 0; i < 10; ++i) memoryWriteByte(buffer[9 - i], address + i); } decform decform::read(uint32_t address) { enum { _style = 0, _unused = 1, _digits = 2, }; decform d; if (!address) return d; d.style = memoryReadByte(address + _style); d.digits = memoryReadWord(address + _digits); return d; } void decform::write(uint32_t address) { enum { _style = 0, _unused = 1, _digits = 2, }; if (!address) return; memoryWriteByte(style, address + _style); memoryWriteWord(digits, address + _digits); } decimal decimal::read(uint32_t address) { enum { _sgn = 0, _exp = 2, _sig = 4, SIGDIGLEN = 20, }; decimal d; if (!address) return d; d.sgn = memoryReadByte(address + _sgn); d.exp = memoryReadWord(address + _exp); //unsigned length = memoryReadByte(address + _sig); //length = std::min(length, (unsigned)SIGDIGLEN); d.sig = ToolBox::ReadPString(address + _sig, false); return d; } void decimal::write(uint32_t address) { enum { _sgn = 0, _exp = 2, _sig = 4, SIGDIGLEN = 20, }; memoryWriteByte(sgn, address + _sgn); memoryWriteByte(0, address + _sgn + 1); // unused. memoryWriteWord(exp, address + _exp); // check if <= SIGDIGLEN? ToolBox::WritePString(address + _sig, sig); } void format_f(extended x, int precision, std::string &mm, std::string &nn) { char *buffer = nullptr; mm.clear(); nn.clear(); if (precision < 0) precision = 0; int length = asprintf(&buffer, "%.*Lf", precision, x); std::string tmp(buffer, length); free(buffer); auto dot = tmp.find('.'); if (dot == tmp.npos) { mm = std::move(tmp); } else { mm = tmp.substr(0, dot); nn = tmp.substr(dot + 1); } // skip mm if it's 0 if (mm.length() == 1 && mm.front() == '0') mm.clear(); // skip nn if it's 0000... if (std::all_of(nn.begin(), nn.end(), [](char c){ return c == '0'; })) nn.clear(); } void format_e(extended x, int precision, std::string &mm, std::string &nn, int &exp) { char *buffer = nullptr; exp = 0; mm.clear(); nn.clear(); if (precision < 0) precision = 0; if (precision > 19) precision = 19; int length = asprintf(&buffer, "%.*Le", precision, x); // output mm . nn e[+-]exp // mm e[+-]exp std::string tmp(buffer, length); free(buffer); auto dot = tmp.find('.'); auto e = tmp.find('e'); if (dot == tmp.npos) { mm = tmp.substr(0, e); } else { mm = tmp.substr(0, dot); nn = tmp.substr(dot + 1, e - dot - 1); } char sign = tmp[e+1]; tmp = tmp.substr(e + 2); exp = std::stoi(tmp); if (sign == '-') exp = -exp; } uint16_t fx2dec() { // extended (80-bit fp) to decimal // convert a to d based on decform f // used by printf %g, %f, %e, etc uint16_t op; uint32_t f_adr; uint32_t a_adr; uint32_t d_adr; decform df; decimal d; StackFrame<14>(f_adr, a_adr, d_adr, op); Log(" FX2DEC(%08x, %08x, %08x, %04x)\n", f_adr, a_adr, d_adr, op); extended s = readnum(a_adr); df = decform::read(f_adr); if (ToolBox::Trace) { std::string tmp1 = std::to_string(s); Log(" %s (style: %d digits: %d)\n", tmp1.c_str(), df.style, df.digits); } /* * SANE pp 30, 31 * * Floating style: * [-| ]m[.nnn]e[+|-]dddd * * Fixed style: * [-]mmm[.nnn] */ if (df.digits < 0) df.digits = 0; if (df.digits > 19) df.digits = 19; fpinfo fpi(s); //fprintf(stderr, "%02x %02x %d %016llx\n", fpi.sign, fpi.one, fpi.exp, fpi.sig); d.sgn = signbit(s); // handle infinity, nan as a special case. switch (fpclassify(s)) { case FP_ZERO: d.sig = "0"; d.write(d_adr); return 0; case FP_NAN: // NAN type encoded in the sig. { char buffer[20]; // 16 + 2 needed snprintf(buffer, 20, "N%016llx", fpi.sig); d.sig = buffer; d.write(d_adr); } return 0; case FP_INFINITE: d.sig = "I"; d.write(d_adr); return 0; default: break; } // normal and subnormal handled here.... // float decimal: df.digits refers to the total length // fixed decimal: df.digits refers to the fractional part only. s = abs(s); if (s < 1.0 && df.style == decform::FLOATDECIMAL) { std::string mm; std::string nn; format_e(s, df.digits - 1, mm, nn, d.exp); d.sig = mm + nn; // better be < 0... if (d.exp < 0) d.exp -= nn.length(); d.write(d_adr); return 0; } else // s > 1 { std::string mm; std::string nn; format_f(s, df.digits, mm, nn); if (mm.empty() && nn.empty()) { // very large 0. d.sig = "0"; d.write(d_adr); return 0; } // if nn is empty (or 0s), this is a large number, // and we don't have to worry about the fraction. if (nn.empty()) { d.exp = 0; if (df.style == decform::FIXEDDECIMAL) df.digits = 19; // limit the length. if (mm.length() > df.digits) { d.exp = mm.length() - df.digits; mm.resize(df.digits); } d.sig = std::move(mm); } else { if (df.style == decform::FIXEDDECIMAL) { // digits is the total size, mm + nn // re-format with new precision. // this is getting repetitive... if (mm.length()) { int precision = df.digits - mm.length(); if (precision < 0) precision = 1; format_f(s, precision, mm, nn); } } // todo -- if mm is empty and nn has leading 0s, // drop the leading 0s and adjust the exponent // accordingly. d.sig = mm + nn; d.exp = -nn.length(); if (d.sig.length() > 19) { d.exp += (d.sig.length() - 19); d.sig.resize(19); } } d.write(d_adr); return 0; } } template uint16_t fadd(const char *name) { // faddi, etc. // destination is always extended. uint16_t op; uint32_t dest; uint32_t src; StackFrame<10>(src, dest, op); Log(" %s(%08x, %08x, %04x)\n", name, src, dest, op); SrcType s = readnum(src); DestType d = readnum(dest); if (ToolBox::Trace) { std::string tmp1 = std::to_string(d); std::string tmp2 = std::to_string(s); Log(" %s + %s\n", tmp1.c_str(), tmp2.c_str()); } d = d + s; writenum(d, dest); return 0; } template uint16_t fsub(const char *name) { // fsub, etc. // destination is always extended. uint16_t op; uint32_t dest; uint32_t src; StackFrame<10>(src, dest, op); Log(" %s(%08x, %08x, %04x)\n", name, src, dest, op); SrcType s = readnum(src); DestType d = readnum(dest); if (ToolBox::Trace) { std::string tmp1 = std::to_string(d); std::string tmp2 = std::to_string(s); Log(" %s - %s\n", tmp1.c_str(), tmp2.c_str()); } d = d - s; writenum(d, dest); return 0; } template uint16_t fmul(const char *name) { // multiply extended (80-bit fp) uint16_t op; uint32_t dest; uint32_t src; StackFrame<10>(src, dest, op); Log(" %s(%08x, %08x, %04x)\n", name, src, dest, op); SrcType s = readnum(src); DestType d = readnum(dest); if (ToolBox::Trace) { std::string tmp1 = std::to_string(d); std::string tmp2 = std::to_string(s); Log(" %s * %s\n", tmp1.c_str(), tmp2.c_str()); } d = d * s; writenum((extended)d, dest); return 0; } template uint16_t fdiv(const char *name) { // div extended (80-bit fp) uint16_t op; uint32_t dest; uint32_t src; StackFrame<10>(src, dest, op); Log(" %s(%08x, %08x, %04x)\n", name, src, dest, op); SrcType s = readnum(src); DestType d = readnum(dest); if (ToolBox::Trace) { std::string tmp1 = std::to_string(d); std::string tmp2 = std::to_string(s); Log(" %s / %s\n", tmp1.c_str(), tmp2.c_str()); } // dest = dest / src d = d / s; writenum(d, dest); return 0; } template uint16_t fconvert(const char *name) { // type conversion. uint16_t op; uint32_t dest; uint32_t src; StackFrame<10>(src, dest, op); Log(" %s(%08x, %08x, %04x)\n", name, src, dest, op); SrcType s = readnum(src); if (ToolBox::Trace) { std::string tmp1 = to_string(s); Log(" %s\n", tmp1.c_str()); } writenum((DestType)s, dest); return 0; } extern "C" void cpuSetFlagsShift(BOOLE z, BOOLE n, BOOLE c, BOOLE v); template uint16_t fcmp(const char *name) { uint16_t op; uint32_t dest; uint32_t src; // TODO op & 0x0f == 0x08 vs 0x0a // for signaling unordered & NaN StackFrame<10>(src, dest, op); Log(" %s(%08x, %08x, %04x)\n", name, src, dest, op); SrcType s = readnum(src); DestType d = readnum(dest); if (ToolBox::Trace) { std::string tmp1 = std::to_string(d); std::string tmp2 = std::to_string(s); Log(" %s <> %s\n", tmp1.c_str(), tmp2.c_str()); } // TODO -- verify if src/dest are backwards here // // // check if ordered... if (d > s) { cpuSetFlagsShift(false, false, false, false); return 0; } if (d < s) { cpuSetFlagsShift(false, true, true, false); return 0; } if (d == s) { cpuSetFlagsShift(true, false, false, false); return 0; } // unorderable? // signal? cpuSetFlagsShift(false, false, false, true); return 0; } template uint16_t fdecimal(const char *name) { uint16_t op; uint32_t decimalPtr; uint32_t dest; StackFrame<10>(decimalPtr, dest, op); uint16_t sgn = memoryReadByte(decimalPtr); int16_t exp = memoryReadWord(decimalPtr + 2); std::string sig; sig = ToolBox::ReadPString(decimalPtr + 4, false); Log(" %s({%c %s e%d}, %08x)\n", name, sgn ? '-' : ' ', sig.c_str(), exp, dest ); extended tmp = 0; if (sig.length()) { if (sig[0] == 'I') { tmp = INFINITY; } else if (sig[0] == 'N') { tmp = NAN; // todo -- nan type } else { tmp = stold(sig); while (exp > 0) { tmp = tmp * 10.0; exp--; } while (exp < 0) { tmp = tmp / 10.0; exp++; } } } if (sgn) tmp = -tmp; writenum((DestType)tmp, dest); return 0; } template uint16_t fclassify(const char *name) { /* * The classify operations set the sign of the destination to * the sign of the source and the value of the destination * according to the class of the source, as shown in Table E-18. * The destination is an integer variable. (pg 273) * * * Table E-18 * Class Information * ---------------------- * Class of SRC Value * ---------------------- * Signaling NaN 1 * Quiet NaN 2 * Infinity 3 * Zero 4 * Normalized 5 * Denormalized 6 * * Table E-19 * --------------------------- * Sign of SRC Sign of DST * --------------------------- * Positive Positive * Negative Negative */ // N.B. - Sane.h uses 0-5, but how can you have integer -0? uint16_t op; uint32_t dest; uint32_t src; StackFrame<10>(src, dest, op); Log(" %s(%08x, %08x, %04x)\n", name, src, dest, op); SrcType s = readnum(src); if (ToolBox::Trace) { std::string tmp1 = to_string(s); Log(" %s\n", tmp1.c_str()); } int16_t klass = 0; switch(fpclassify(s)) { case FP_INFINITE: klass = 3; break; case FP_NAN: // todo -- signaling NaN is indicated // by the MSB of the fraction field f // 1 is quiet, 0 is signaling. klass = 1; break; case FP_NORMAL: klass = 5; break; case FP_SUBNORMAL: klass = 6; break; case FP_ZERO: klass = 4; break; } if (signbit(s)) klass = -klass; if (dest) { memoryWriteWord(klass, dest); } return 0; } #pragma mark - environment /* * environment is a uint16_t *. * void setenvironment(environment e); * void getenvironment(environment *e); * void procentry(environment *e); * void procexit(environment e); */ uint16_t fgetenv(void) { uint32_t address; uint16_t op; StackFrame<6>(address, op); Log(" FGETENV(%08x)\n", address); memoryWriteWord(Environment, address); return 0; } uint16_t fsetenv(void) { uint32_t address; uint16_t value; uint16_t op; StackFrame<6>(address, op); value = address ? memoryReadWord(address) : DefaultEnvironment; Log(" FSETENV(%08x (%04x))\n", address, value); Environment = value; return 0; } uint16_t fprocentry(void) { uint32_t address; uint16_t op; StackFrame<6>(address, op); Log(" FPROCENTRY(%08x)\n", address); if (address) memoryWriteWord(Environment, address); Environment = DefaultEnvironment; return 0; } uint16_t fprocexit(void) { uint32_t address; uint16_t value; uint16_t op; StackFrame<6>(address, op); value = address ? memoryReadWord(address) : DefaultEnvironment; Log(" FPROCEXIT(%08x (%04x))\n", address, value); // todo -- also should signal exceptions/halts at this point. Environment = value; return 0; } uint16_t ftintx() { // truncate (round towards 0 regardless of rounding settings) uint32_t address; uint16_t op; StackFrame<6>(address, op); Log(" FTINTX(%08x)\n", address); extended s = readnum(address); if (ToolBox::Trace) { std::string tmp1 = to_string(s); Log(" %s\n", tmp1.c_str()); } s = std::trunc(s); writenum(s, address); return 0; } extern "C" void cpuSetFlagsAbs(UWO f); uint16_t fp68k(uint16_t trap) { uint16_t op; uint32_t sp; sp = cpuGetAReg(7); op = memoryReadWord(sp); Log("%04x FP68K(%04x)\n", trap, op); cpuSetFlagsAbs(0x4); if (op == 0x000b) return fx2dec(); switch(op) { // addition case 0x0000: return fadd("FADDX"); case 0x0800: return fadd("FADDD"); case 0x1000: return fadd("FADDS"); //case 0x3000: return fadd("FADDC"); case 0x2000: return fadd("FADDI"); case 0x2800: return fadd("FADDL"); // subtraction case 0x0002: return fsub("FSUBX"); case 0x0802: return fsub("FSUBD"); case 0x1002: return fsub("FSUBS"); //case 0x3002: return fsub("FSUBC"); case 0x2002: return fsub("FSUBI"); case 0x2802: return fsub("FSUBL"); // multiplication case 0x0004: return fmul("FMULX"); case 0x0804: return fmul("FMULD"); case 0x1004: return fmul("FMULS"); //case 0x3004: return fmul("FMUlC"); case 0x2004: return fmul("FMULI"); case 0x2804: return fmul("FMULL"); // division case 0x0006: return fdiv("FDIVX"); case 0x0806: return fdiv("FDIVD"); case 0x1006: return fdiv("FDIVS"); //case 0x3006: return fdiv("FDIVC"); case 0x2006: return fdiv("FDIVI"); case 0x2806: return fdiv("FDIVL"); // comparison case 0x0008: return fcmp("FCMPX"); case 0x0808: return fcmp("FCMPD"); case 0x1008: return fcmp("FCMPS"); //case 0x3008: return fcmp("FCMPC"); case 0x2008: return fcmp("FCMPI"); case 0x2808: return fcmp("FCMPL"); case 0x000a: return fcmp("FCPXX"); case 0x080a: return fcmp("FCPXD"); case 0x100a: return fcmp("FCPXS"); //case 0x300a: return fcmp("FCPXC"); case 0x200a: return fcmp("FCPXI"); case 0x280a: return fcmp("FCPXL"); // conversion (extended -> ???) case 0x0010: return fconvert("FX2X"); case 0x0810: return fconvert("FX2D"); case 0x1010: return fconvert("FX2S"); case 0x3010: return fconvert("FX2C"); case 0x2010: return fconvert("FX2I"); case 0x2810: return fconvert("FX2L"); // conversion (??? -> extended) case 0x000e: return fconvert("FX2X"); case 0x080e: return fconvert("FD2X"); case 0x100e: return fconvert("FS2X"); case 0x300e: return fconvert("FC2X"); case 0x200e: return fconvert("FI2X"); case 0x280e: return fconvert("FL2X"); case 0x001c: return fclassify("FCLASSX"); case 0x081c: return fclassify("FCLASSD"); case 0x101c: return fclassify("FCLASSS"); case 0x301c: return fclassify("FCLASSC"); case 0x0009: // fdec2x return fdecimal("FDEC2X"); break; case 0x0016: return ftintx(); case 0x0017: return fprocentry(); case 0x0019: return fprocexit(); case 0x0003: return fgetenv(); case 0x0001: return fsetenv(); } fprintf(stderr, "fp68k -- op %04x is not yet supported\n", op); exit(1); return 0; } uint16_t NumToString(void) { /* * on entry: * A0 Pointer to pascal string * D0 The number * * on exit: * A0 Pointer to pascal string * D0 Result code * */ int32_t theNum = cpuGetDReg(0); uint32_t theString = cpuGetAReg(0); //std::string s = ToolBox::ReadPString(theString, false); Log(" NumToString(%08x, %08x)\n", theNum, theString); std::string s = std::to_string(theNum); ToolBox::WritePString(theString, s); return 0; } uint32_t StringToNum(void) { /* * on entry: * A0 Pointer to pascal string * * on exit: * D0 the number * */ uint32_t theString = cpuGetAReg(0); std::string s = ToolBox::ReadPString(theString, false); Log(" StringToNum(%s)\n", s.c_str()); bool negative = false; uint32_t tmp = 0; if (!s.length()) return 0; auto iter = s.begin(); // check for leading +- if (*iter == '-') { negative = true; ++iter; } else if (*iter == '+') { negative = false; ++iter; } for ( ; iter != s.end(); ++iter) { // doesn't actually check if it's a number. int value = *iter & 0x0f; tmp = tmp * 10 + value; } if (negative) tmp = -tmp; return tmp; } uint32_t fstr2dec(char type) { // void str2dec(const char *s,short *ix,decimal *d,short *vp); #if 0 #define SIGDIGLEN 20 /* significant decimal digits */ #define DECSTROUTLEN 80 /* max length for dec2str output */ struct decimal { char sgn; /*sign 0 for +, 1 for -*/ char unused; short exp; /*decimal exponent*/ struct{ unsigned char length; unsigned char text[SIGDIGLEN]; /*significant digits */ unsigned char unused; }sig; }; #endif uint32_t stringPtr; uint32_t indexPtr; uint32_t decimalPtr; uint32_t validPtr; uint16_t valid; uint16_t index; decimal d; StackFrame<16>(stringPtr, indexPtr, decimalPtr, validPtr); index = memoryReadWord(indexPtr); std::string str; if (type == 'P') str = ToolBox::ReadPString(stringPtr, false); if (type == 'C') str = ToolBox::ReadCString(stringPtr, false); Log(" F%cSTR2DEC(%s, %04x, %08x, %08x)\n", type, str.c_str(), index, decimalPtr, validPtr); if (type == 'P') index--; str2dec(str, index, d, valid); if (type == 'P') index++; memoryWriteWord(index, indexPtr); memoryWriteWord(valid, validPtr); if (d.sig.length() > 20) { // truncate and adjust the exponent // 1234e0 -> 123e1 -> 12e2 -> 1e3 // 1234e-1 -> 123e-0 -> 12e1 int over = d.sig.length() - 20; d.sig.resize(20); d.exp += over; } memoryWriteByte(d.sgn, decimalPtr); memoryWriteByte(0, decimalPtr + 1); memoryWriteWord(d.exp, decimalPtr + 2); ToolBox::WritePString(decimalPtr + 4, d.sig); return 0; } uint32_t decstr68k(uint16_t trap) { // this is a strange one since it may be sane or it may be the binary/decimal package. uint16_t op; StackFrame<2>(op); Log("%04x DECSTR68K(%04x)\n", trap, op); switch (op) { case 0x00: return NumToString(); break; case 0x01: return StringToNum(); break; case 0x02: // fpstr2dec return fstr2dec('P'); break; case 0x04: // fcstr2dec return fstr2dec('C'); break; default: fprintf(stderr, "decstr68k -- op %04x is not yet supported\n", op); exit(1); } return 0; } }