// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package fmt /* f := fmt.New(); print f.d(1234).s("\n").str(); // create string, print it f.d(-1234).s("\n").put(); // print string f.ud(^0).putnl(); // print string with automatic newline */ // import sys "sys" export Fmt, New; const NByte = 64; const NPows10 = 160; var ldigits string = "0123456789abcdef"; // BUG: Should be const var udigits string = "0123456789ABCDEF"; // BUG: Should be const var pows10 [NPows10] double; func init() { pows10[0] = 1.0e0; pows10[1] = 1.0e1; for i:=2; i 0) or right (w < 0) // padding is in bytes, not characters (agrees with ANSIC C, not Plan 9 C) func (f *Fmt) pad(s string) { if f.wid_present && f.wid != 0 { left := true; w := f.wid; if w < 0 { left = false; w = -w; } w -= len(s); if w > 0 { if w > NByte { w = NByte; } var buf[NByte] byte; // BUG: should be able to allocate variable size for i := 0; i < w; i++ { buf[i] = ' '; } if left { s = string(buf)[0:w] + s; } else { s = s + string(buf)[0:w]; } } } f.buf += s; } // format val into buf, ending at buf[i]. (printing is easier right-to-left; // that's why the bidi languages are right-to-left except for numbers. wait, // never mind.) val is known to be unsigned. we could make things maybe // marginally faster by splitting the 32-bit case out into a separate function // but it's not worth the duplication, so val has 64 bits. func putint(buf *[NByte]byte, i int, base, val uint64, digits *string) int { for val >= base { buf[i] = digits[val%base]; i--; val /= base; } buf[i] = digits[val]; return i-1; } // boolean func (f *Fmt) boolean(a bool) *Fmt { if a { f.pad("true"); } else { f.pad("false"); } f.clearflags(); return f; } // integer; interprets prec but not wid. func (f *Fmt) integer(a int64, base uint, is_signed bool, digits *string) string { var buf [NByte]byte; negative := is_signed && a < 0; if negative { a = -a; } i := putint(&buf, NByte-1, uint64(base), uint64(a), digits); if f.prec_present { for i > 0 && f.prec > (NByte-1-i) { buf[i] = '0'; i--; } } if negative { buf[i] = '-'; i--; } return string(buf)[i+1:NByte]; } // decimal func (f *Fmt) d(a int32) *Fmt { f.pad(f.integer(int64(a), 10, true, &ldigits)); f.clearflags(); return f; } func (f *Fmt) D(a int64) *Fmt { f.pad(f.integer(a, 10, true, &ldigits)); f.clearflags(); return f; } // unsigned decimal func (f *Fmt) ud(a int32) *Fmt { f.pad(f.integer(int64(uint32(a)), 10, false, &ldigits)); f.clearflags(); return f; } func (f *Fmt) uD(a int64) *Fmt { f.pad(f.integer(a, 10, false, &ldigits)); f.clearflags(); return f; } // hexdecimal func (f *Fmt) x(a int32) *Fmt { f.pad(f.integer(int64(a), 16, true, &ldigits)); f.clearflags(); return f; } func (f *Fmt) X(a int64) *Fmt { f.pad(f.integer(a, 16, true, &ldigits)); f.clearflags(); return f; } // unsigned hexdecimal func (f *Fmt) ux(a int32) *Fmt { f.pad(f.integer(int64(uint32(a)), 16, false, &ldigits)); f.clearflags(); return f; } func (f *Fmt) uX(a int64) *Fmt { f.pad(f.integer(a, 16, false, &ldigits)); f.clearflags(); return f; } // HEXADECIMAL func (f *Fmt) Ux(a int32) *Fmt { f.pad(f.integer(int64(a), 16, true, &udigits)); f.clearflags(); return f; } func (f *Fmt) UX(a int64) *Fmt { f.pad(f.integer(a, 16, true, &udigits)); f.clearflags(); return f; } // unsigned HEXADECIMAL func (f *Fmt) uUx(a int32) *Fmt { f.pad(f.integer(int64(uint32(a)), 16, false, &udigits)); f.clearflags(); return f; } func (f *Fmt) uUX(a int64) *Fmt { f.pad(f.integer(a, 16, false, &udigits)); f.clearflags(); return f; } // octal func (f *Fmt) o(a int32) *Fmt { f.pad(f.integer(int64(a), 8, true, &ldigits)); f.clearflags(); return f; } func (f *Fmt) O(a int64) *Fmt { f.pad(f.integer(a, 8, true, &ldigits)); f.clearflags(); return f; } // unsigned octal func (f *Fmt) uo(a int32) *Fmt { f.pad(f.integer(int64(uint32(a)), 8, false, &ldigits)); f.clearflags(); return f; } func (f *Fmt) uO(a int64) *Fmt { f.pad(f.integer(a, 8, false, &ldigits)); f.clearflags(); return f; } // binary func (f *Fmt) b(a int32) *Fmt { f.pad(f.integer(int64(uint32(a)), 2, false, &ldigits)); f.clearflags(); return f; } func (f *Fmt) B(a int64) *Fmt { f.pad(f.integer(a, 2, false, &ldigits)); f.clearflags(); return f; } // character func (f *Fmt) c(a int) *Fmt { f.pad(string(a)); f.clearflags(); return f; } // string func (f *Fmt) s(s string) *Fmt { if f.prec_present { if f.prec < len(s) { s = s[0:f.prec]; } } f.pad(s); f.clearflags(); return f; } func pow10(n int) double { var d double; neg := false; if n < 0 { if n < -307 { // DBL_MIN_10_EXP return 0.; } neg = true; n = -n; }else if n > 308 { // DBL_MAX_10_EXP return 1.79769e+308; // HUGE_VAL } if n < NPows10 { d = pows10[n]; } else { d = pows10[NPows10-1]; for { n -= NPows10 - 1; if n < NPows10 { d *= pows10[n]; break; } d *= pows10[NPows10 - 1]; } } if neg { return 1/d; } return d; } func unpack(a double) (negative bool, exp int, num double) { if a == 0 { return false, 0, 0.0 } neg := a < 0; if neg { a = -a; } // find g,e such that a = g*10^e. // guess 10-exponent using 2-exponent, then fine tune. g, e2 := sys.frexp(a); e := int(e2 * .301029995663981); g = a * pow10(-e); for g < 1 { e--; g = a * pow10(-e); } for g >= 10 { e++; g = a * pow10(-e); } return neg, e, g; } // double func (f *Fmt) E(a double) *Fmt { var negative bool; var g double; var exp int; negative, exp, g = unpack(a); prec := 6; if f.prec_present { prec = f.prec; } prec++; // one digit left of decimal var s string; // multiply by 10^prec to get decimal places; put decimal after first digit if g == 0 { // doesn't work for zero - fake it s = "000000000000000000000000000000000000000000000000000000000000"; if prec < len(s) { s = s[0:prec]; } else { prec = len(s); } } else { g *= pow10(prec); s = f.integer(int64(g + .5), 10, true, &ldigits); // get the digits into a string } s = s[0:1] + "." + s[1:prec]; // insert a decimal point // print exponent with leading 0 if appropriate. es := New().p(2).integer(int64(exp), 10, true, &ldigits); if exp > 0 { es = "+" + es; // TODO: should do this with a fmt flag } s = s + "e" + es; if negative { s = "-" + s; } f.pad(s); f.clearflags(); return f; } // double func (f *Fmt) F(a double) *Fmt { var negative bool; var g double; var exp int; negative, exp, g = unpack(a); if exp > 19 || exp < -19 { // too big for this sloppy code return f.E(a); } prec := 6; if f.prec_present { prec = f.prec; } // prec is number of digits after decimal point s := "NO"; if exp >= 0 { g *= pow10(exp); gi := int64(g); s = New().integer(gi, 10, true, &ldigits); s = s + "."; g -= double(gi); s = s + New().p(prec).integer(int64(g*pow10(prec) + .5), 10, true, &ldigits); } else { g *= pow10(prec + exp); s = "0." + New().p(prec).integer(int64(g + .5), 10, true, &ldigits); } if negative { s = "-" + s; } f.pad(s); f.clearflags(); return f; } // double func (f *Fmt) G(a double) *Fmt { f1 := New(); f2 := New(); if f.wid_present { f1.w(f.wid); f2.w(f.wid); } if f.prec_present { f1.p(f.prec); f2.p(f.prec); } efmt := f1.E(a).str(); ffmt := f2.F(a).str(); // ffmt can return e in my bogus world; don't trim trailing 0s if so. f_is_e := false; for i := 0; i < len(ffmt); i++ { if ffmt[i] == 'e' { f_is_e = true; break; } } if !f_is_e { // strip trailing zeros l := len(ffmt); for ffmt[l-1]=='0' { l--; } ffmt = ffmt[0:l]; } if len(efmt) < len(ffmt) { f.pad(efmt); } else { f.pad(ffmt); } f.clearflags(); return f; } // float func (x *Fmt) f(a float) *Fmt { return x.F(double(a)) } // float func (x *Fmt) e(a float) *Fmt { return x.E(double(a)) } // float func (x *Fmt) g(a float) *Fmt { return x.G(double(a)) }