func main() {
	fmt.Printf("System colours:\n")
	fmt.Printf("%s   %s\n", tc.Black("Black"), tc.Bblack("Bright Black"))
	fmt.Printf("%s    %s\n", tc.Blue("Blue"), tc.Bblue("Bright Blue"))
	fmt.Printf("%s   %s\n", tc.Green("Green"), tc.Bgreen("Bright Green"))
	fmt.Printf("%s    %s\n", tc.Cyan("Cyan"), tc.Bcyan("Bright Cyan"))
	fmt.Printf("%s     %s\n", tc.Red("Red"), tc.Bred("Bright Red"))
	fmt.Printf("%s  %s\n", tc.Purple("Purple"), tc.Bpurple("Bright Purple"))
	fmt.Printf("%s  %s\n", tc.Yellow("Yellow"), tc.Byellow("Bright Yellow"))
	fmt.Printf("%s   %s\n", tc.White("White"), tc.Bwhite("Bright White"))

	fmt.Printf("\n 256ish colour cube\n")
	fmt.Print("4-bit palette: ")
	for i := 0; i < 16; i++ {
		fmt.Print(tc.Foreground8(tc.C256(i), "::"))
	}
	fmt.Print("\n               ")
	for i := 0; i < 16; i++ {
		fmt.Print(tc.Background8(tc.C256(i), "  "))
	}
	fmt.Print("\n")
	for r0 := 0; r0 < 6; r0 += 3 {
		for g := 0; g < 6; g++ {
			for r := 0; r < 3; r++ {
				for b := 0; b < 6; b++ {
					c := tc.Colour256(r+r0, g, b)
					fmt.Print(tc.Foreground8(c, "::"))
				}
				fmt.Print("   ")
			}
			fmt.Print("     ")
			for r := 0; r < 3; r++ {
				for b := 0; b < 6; b++ {
					c := tc.Colour256(r+r0, g, b)
					fmt.Print(tc.Background8(c, "  "))
				}
				fmt.Print("   ")
			}
			fmt.Print("\n")
		}
		fmt.Print("\n")
	}
	fmt.Print("4.5-bit greyscale ramp: ")
	for i := 232; i < 256; i++ {
		fmt.Print(tc.Foreground8(tc.C256(i), "::"))
	}
	fmt.Print("\n                        ")
	for i := 232; i < 256; i++ {
		fmt.Print(tc.Background8(tc.C256(i), "  "))
	}
	fmt.Print("\n")
}
Exemple #2
0
func prettyCertificate(cert *x509.Certificate) (string, string) {
	key := "unknown"
	if cert.PublicKeyAlgorithm == x509.RSA {
		pk, ok := cert.PublicKey.(*rsa.PublicKey)
		if !ok {
			key = tc.Bred("RSA - error")
		} else {
			col := cStrength(pk.N.BitLen())
			key = col(fmt.Sprintf("RSA-%d", pk.N.BitLen()))
		}
	} else if cert.PublicKeyAlgorithm == x509.DSA {
		pk, ok := cert.PublicKey.(*dsa.PublicKey)
		if !ok {
			key = tc.Bred("DSA - error")
		} else {
			bl := pk.P.BitLen()
			col := tc.Red
			if bl < 1536 {
				col = tc.Bred
			}
			key = col(fmt.Sprintf("DSA-%d", bl))
		}
	} else if cert.PublicKeyAlgorithm == x509.ECDSA {
		pk, ok := cert.PublicKey.(*ecdsa.PublicKey)
		if !ok {
			key = tc.Bred("ECDSA - error")
		} else {
			bl := pk.Params().P.BitLen()
			col := tc.Green
			if bl < 224 {
				col = tc.Red
			} else if bl < 256 {
				col = tc.Yellow
			}
			key = col(fmt.Sprintf("ECDSA-%d", bl))
		}
	}

	sig := strSigAlg(cert.SignatureAlgorithm)
	if cert.SignatureAlgorithm == x509.UnknownSignatureAlgorithm ||
		cert.SignatureAlgorithm == x509.MD2WithRSA ||
		cert.SignatureAlgorithm == x509.MD5WithRSA {
		sig = tc.Bred(sig)
	} else if cert.SignatureAlgorithm == x509.SHA1WithRSA ||
		cert.SignatureAlgorithm == x509.DSAWithSHA1 ||
		cert.SignatureAlgorithm == x509.DSAWithSHA256 ||
		cert.SignatureAlgorithm == x509.ECDSAWithSHA1 {
		sig = tc.Red(sig)
	} else {
		sig = tc.Green(sig)
	}

	subject := cert.Subject.CommonName
	if len(subject) > 45 {
		subject = subject[0:45]
	}
	issuer := cert.Issuer.CommonName
	if len(issuer) > 45 {
		issuer = issuer[0:45]
	}

	fpr := tc.Bblack(fmt.Sprintf("%x", sha1.Sum(cert.Raw)))

	subject = fmt.Sprintf("subject: %-45s  key type: %s / sig: %s", subject, key, sig)
	issuer = fmt.Sprintf("issuer:  %-45s  fingerprint: %s", issuer, fpr)

	return subject, issuer
}