1,通信双方的证书生成
1.1生成根节点证书
openssl genrsa -out cakey.pem 2048 openssl req -new -key cakey.pem -subj "/CN=rootca.bitbaba.com" -out cacsr.pem openssl x509 -req -in cacsr.pem -days 999 -signkey cakey.pem -out cacert.pem
1.2生成alice的证书
openssl genrsa -out alicekey.pem 2048 openssl req -new -key cakey.pem -subj "/emailAddress=imalice.freemail@gmail.com" -out alicecsr.pem openssl x509 -req -in alicecsr.pem -days 999 -CA cacert.pem -CAKey cakey.pem -set_serial 01 -name "alice" -out alicecert.pem openssl pkcs12 -export -in alicecert.pem -inkey alicekey.pem -certfile cacert.pem -out alice.p12
1.3生成bob的证书
openssl genrsa -out bobkey.pem 2048 openssl req -new -key bobkey.pem -subj "/emailAddress=iambob.freemail@gmail.com" -out bobcsr.pem openssl x509 -req -in bobcsr.pem -days 999 -CA cacert.pem -CAkey cakey.pem -set_serial 02 -name "bob" -out bobcert.pem openssl pkcs12 -export -in bobcert.pem -inkey bobkey.pem -certfile cacert.pem -out bob.p12
2,邮件签名
openssl smime -sign -in /tmp/msg.txt -signer alicecert.pem -inkey alicekey.pem -nocerts -nodetach -text -out /tmp/alicesigned.eml
提醒:
-nodetach 把信息原文也包含到base64块里面,而不是用mime格式的分隔符单独放置,比较容易保证信息不被邮件收发服务器重构,导致验证失败。
-nocerts 是一个可选选项,如果设置的话,alice的证书(公钥等)不会被包含到签名信息里面(base64块)
-signer 在签发邮件的时候,指定发送人的证书位置,这里指定alice的证书
3,签名验证
openssl smime -verify -in /tmp/alicesigned.eml -certfile alicecert.pem -CAfile cacert.pem
注意:
-signer 参数这个时候的意思:导出签发邮件的证书保存。所以要小心覆盖原有证书
-CAfile 设置信任的ca位置,否则验证不通过
-certfile 是一个可选选项,如果签名的时候指定了-nocerts,这里可以指定验证证书(alice),这样网络传输经济。
4,邮件加密
smime -encrypt -in /tmp/msg.txt -from imalice.freemail@gmail.com -to iambob.freemail@gmail.com -des3 -out /tmp/msg.eml bobcert.pem
5,邮件解密
openssl smime -decrypt -in /tmp/msg.eml -recip bobcert.pem -inkey bobkey.pem
6, 签名并加密
openssl smime -sign -in msg.txt -signer alicecert.pem -inkey alicekey.pem -nocerts -nodetach -text | openssl smime -encrypt -des3 -from imalice.freemail@gmail.com -to iambob.freemail@gmail.com -subject HiBob bobcert.pem
To: iambob.freemail@gmail.com From: imalice.freemail@gmail.com Subject: HiBob MIME-Version: 1.0 Content-Disposition: attachment; filename="smime.p7m" Content-Type: application/x-pkcs7-mime; smime-type=enveloped-data; name="smime.p7m" Content-Transfer-Encoding: base64 MIIGKQYJKoZIhvcNAQcDoIIGGjCCBhYCAQAxggFmMIIBYgIBADBKMEUxCzAJBgNV BAYTAkFVMRMwEQYDVQQIDApTb21lLVN0YXRlMSEwHwYDVQQKDBhJbnRlcm5ldCBX aWRnaXRzIFB0eSBMdGQCAQMwDQYJKoZIhvcNAQEBBQAEggEAdmR6L5KWIhmIFBwj UV2wxBb8S20+TH+ZsQ7NtHN/FucV+LMkRWsif03ExRqnsLwigQSXinigsOrgpovn X8JpfiOQp3cg6KEyhX0+q2Ziiu4qRNZLCKoWXZ4oxyYORe8PT1R9NwSfnfVcHvec duyOMYdp3T50844CXQ0NMv/FjEv5bdhN5TdPvEhyOcaQ4g/Fhsh0kPPFVNWnLFIw 6p+2K5sZr749RvGuzmZuwd4WvAtPO/bgBks7sbR8mR7jXLZaq8Q/NHN913Jq5Pf2 VATbIDUbvbD2Znv22NJOt600Et+yi4xHT/TG5TXVYZSuayOPhVkX032Gycgp3c35 UaYHozCCBKUGCSqGSIb3DQEHATAUBggqhkiG9w0DBwQI525g7nh7tU6AggSAxAL5 yGDcR3M+xZZELlG1/JcUKWLUmZQoqKyKtT5gk61lMJ6Si4LcQSlYP+IySeAYB9fw RY+uKepW0snNHMO/IrT+EtKn/qJgm/OJSEf5YrCwmJx/k1Pv2BZu4GeTmnB5cfKx xTus0bhiGR7tqWRv9XrexhdeUKumyJMzr9Vxzfnz+ahTk510npW3Ei+4rKkQOO3z mrwRUril/J9onvInkvjAOwMceKTyjrCzEJv3f5JMreqwSjeTnxQcihJHdqPo1NpZ RSNIsG83Hz2/mMNuRgVQi7DVWqJlcsv4OG9J6Dw6Xp7bnskppoMYMsZzOon0X4o+ JTjb9lyhxcXPE8htbd3qg1EroMByoWD/HcKLYv00vo1Gd5mgHCEqp0a6/WrpLlGQ JDJDFqJ2TEJCbgAiTejxns+t/zQyC9iOVSP+S1/rkzuZV28O7zCDjJwxGK1rUFa1 Epa4jlciFyppuzzxYICxSDNVAfFsGLW3heuxFqew3aUufDcjzhkDYGrZpWd91C0/ WYqVQM5VYtpqTZHUfNAkFvyuB2jqi265/rvsgpIb1mlC3ee4DbAqAz9a8HMMajkN rRWGuGm9S/Zz4QskAaNYdQXqmv2UT2NmDhcv+zGqH0vzlGs0k9Ae0My1cucBPmFO NjbM11yHTSKN1sqlRtzQiCi7IbM5B4Q2O8/jhvO07ezRz5Fj4o4PxpElQ/7mtusg Fz97HA4guZ+8Ig/NoG7HkdJh5Ju0fTGnqDosG3jXJWtJlXrsA3qHwdbk1Z8ux7xf L6fVmO2dEBUkc6ihMvDgyZByUbyauEfyCwSb0UfJeJbbfY9UmsBWbU635rLn5Fcx MTY9JwoD/SgEYRm3XhxphO+xy2LAVal4GULlcqtXeGKLUzuRavn/MCP7V5xLEX8Z 3hih/eJ/OFOUL/Hndr5py3oLavhV+mFwNTJrQ2Jrk9DwnsnUS70Z8nEKbe9O41Xl rcll6nLMnY6qXmA47tz5NM7uPGBpus5cInRnI2ndGnGJt0pW30ubn1gH/sYA6iwR aWTz4gxo1h9pVfJ6z8P6guXJaS5X6NLGVfl6EPs1EwEEbc0zd3r9iphcARtnI4U6 fOa5QeRWd8KI/XpSS9KXM90Jdphxz1E1iD9VGkFPhxRq0HMaEZu2ggD2HUTHibyZ 9fV9f6wf2Hx4Wng1Eh1PDiffnIYkrEYdfu2Uqt7HaYxz1T0qbrkHNJOjT8eZ3aZW yLn/bEDeyxeLcsGDOt6hdW0C0PaoLzv6okKbprLgx4Dfxfh0ytu1m/M6WoVO3/QB ELvxshSBc77P4+UAAlDjRhpQRuDOa0xU5DHeb3DDogRGw8nWpleyqQsTlgQmzYWJ w8ps+VbrGTn3hNkGcLgkqXWy5uLocuj+61RB8HZAdNMhjAKHvr9pGhac1hbLW7aP uehFCfCo4P0vDNJpjV7JDG8y+j89guGbC8ew3Hd7LYGucdGYWgnKxBRpmG5dJ7Vi swGNTSOWATI+Lz+sySCVHyrKbsf3IfFsjdMZxQrZttnm63q5rRam/F0VMbEE
7,解密并验证
openssl smime -decrypt -in enc.eml -recip bobcert.pem -inkey bobkey.pem | openssl smime -verify -certfile alicecert.pem -CAfile cacert.pem
Content-Type: text/plain Hello, World ! Verification successful
管道命令
openssl smime -sign -in msg.txt -signer alicecert.pem -inkey alicekey.pem -nocerts -nodetach -text | \ openssl smime -encrypt -des3 -from imalice.freemail@gmail.com -to iambob.freemail@gmail.com -subject HiBob bobcert.pem | \ openssl smime -decrypt -recip bobcert.pem -inkey bobkey.pem | \ openssl smime -verify -certfile alicecert.pem -CAfile cacert.pem
8,邮件发送
9,邮件接收
备注:
1)关于cms的一些数据结构定义
子结构的详细定义可以参考:https://github.com/openssl/openssl/blob/master/crypto/cms/cms_lcl.h
struct CMS_ContentInfo_st {
ASN1_OBJECT *contentType;
union {
ASN1_OCTET_STRING *data;
CMS_SignedData *signedData;
CMS_EnvelopedData *envelopedData;
CMS_DigestedData *digestedData;
CMS_EncryptedData *encryptedData;
CMS_AuthenticatedData *authenticatedData;
CMS_CompressedData *compressedData;
ASN1_TYPE *other;
/* Other types ... */
void *otherData;
} d;
};
PKCS7的递推定义
/*-
Encryption_ID DES-CBC
Digest_ID MD5
Digest_Encryption_ID rsaEncryption
Key_Encryption_ID rsaEncryption
*/
typedef struct pkcs7_issuer_and_serial_st {
X509_NAME *issuer;
ASN1_INTEGER *serial;
} PKCS7_ISSUER_AND_SERIAL;
typedef struct pkcs7_signer_info_st {
ASN1_INTEGER *version; /* version 1 */
PKCS7_ISSUER_AND_SERIAL *issuer_and_serial;
X509_ALGOR *digest_alg;
STACK_OF(X509_ATTRIBUTE) *auth_attr; /* [ 0 ] */
X509_ALGOR *digest_enc_alg;
ASN1_OCTET_STRING *enc_digest;
STACK_OF(X509_ATTRIBUTE) *unauth_attr; /* [ 1 ] */
/* The private key to sign with */
EVP_PKEY *pkey;
} PKCS7_SIGNER_INFO;
DECLARE_STACK_OF(PKCS7_SIGNER_INFO)
DECLARE_ASN1_SET_OF(PKCS7_SIGNER_INFO)
typedef struct pkcs7_recip_info_st {
ASN1_INTEGER *version; /* version 0 */
PKCS7_ISSUER_AND_SERIAL *issuer_and_serial;
X509_ALGOR *key_enc_algor;
ASN1_OCTET_STRING *enc_key;
X509 *cert; /* get the pub-key from this */
} PKCS7_RECIP_INFO;
DECLARE_STACK_OF(PKCS7_RECIP_INFO)
DECLARE_ASN1_SET_OF(PKCS7_RECIP_INFO)
typedef struct pkcs7_signed_st {
ASN1_INTEGER *version; /* version 1 */
STACK_OF(X509_ALGOR) *md_algs; /* md used */
STACK_OF(X509) *cert; /* [ 0 ] */
STACK_OF(X509_CRL) *crl; /* [ 1 ] */
STACK_OF(PKCS7_SIGNER_INFO) *signer_info;
struct pkcs7_st *contents;
} PKCS7_SIGNED;
/*
* The above structure is very very similar to PKCS7_SIGN_ENVELOPE. How about
* merging the two
*/
typedef struct pkcs7_enc_content_st {
ASN1_OBJECT *content_type;
X509_ALGOR *algorithm;
ASN1_OCTET_STRING *enc_data; /* [ 0 ] */
const EVP_CIPHER *cipher;
} PKCS7_ENC_CONTENT;
typedef struct pkcs7_enveloped_st {
ASN1_INTEGER *version; /* version 0 */
STACK_OF(PKCS7_RECIP_INFO) *recipientinfo;
PKCS7_ENC_CONTENT *enc_data;
} PKCS7_ENVELOPE;
typedef struct pkcs7_signedandenveloped_st {
ASN1_INTEGER *version; /* version 1 */
STACK_OF(X509_ALGOR) *md_algs; /* md used */
STACK_OF(X509) *cert; /* [ 0 ] */
STACK_OF(X509_CRL) *crl; /* [ 1 ] */
STACK_OF(PKCS7_SIGNER_INFO) *signer_info;
PKCS7_ENC_CONTENT *enc_data;
STACK_OF(PKCS7_RECIP_INFO) *recipientinfo;
} PKCS7_SIGN_ENVELOPE;
typedef struct pkcs7_digest_st {
ASN1_INTEGER *version; /* version 0 */
X509_ALGOR *md; /* md used */
struct pkcs7_st *contents;
ASN1_OCTET_STRING *digest;
} PKCS7_DIGEST;
typedef struct pkcs7_encrypted_st {
ASN1_INTEGER *version; /* version 0 */
PKCS7_ENC_CONTENT *enc_data;
} PKCS7_ENCRYPT;
typedef struct pkcs7_st {
/*
* The following is non NULL if it contains ASN1 encoding of this
* structure
*/
unsigned char *asn1;
long length;
# define PKCS7_S_HEADER 0
# define PKCS7_S_BODY 1
# define PKCS7_S_TAIL 2
int state; /* used during processing */
int detached;
ASN1_OBJECT *type;
/* content as defined by the type */
/*
* all encryption/message digests are applied to the 'contents', leaving
* out the 'type' field.
*/
union {
char *ptr;
/* NID_pkcs7_data */
ASN1_OCTET_STRING *data;
/* NID_pkcs7_signed */
PKCS7_SIGNED *sign;
/* NID_pkcs7_enveloped */
PKCS7_ENVELOPE *enveloped;
/* NID_pkcs7_signedAndEnveloped */
PKCS7_SIGN_ENVELOPE *signed_and_enveloped;
/* NID_pkcs7_digest */
PKCS7_DIGEST *digest;
/* NID_pkcs7_encrypted */
PKCS7_ENCRYPT *encrypted;
/* Anything else */
ASN1_TYPE *other;
} d;
} PKCS7;
PKCS#7 is an old standard from RSA Labs, published later on as an "informational RFC". Then, a new versions was produced, as an "Internet standard", i.e. with the seal of approval from the powers-that-be at IETF; a new name was invented for that: CMS. Newer versions were subsequently defined: RFC 3369, RFC 3852, RFC 5652. You can consider CMS and PKCS#7 to both designate the same standard, which has several versions. CMS (PKCS#7) is a format for applying encryption, signatures and/or integrity checks on arbitrary binary messages (which can be large). It can be nested. It is the basis for some protocols such as time stamping. It is also frequently (ab)used as a container for X.509 certificates: the SignedData type includes a field for a set of signatures (and that set can be empty), and also a field to store arbitrary X.509 certificates which are considered as "potentially useful" for whoever processes the object. CMS is nominally backward compatible: there are version fields at various places, and a library which understands a version of CMS should be able to process messages from older versions; moreover, such a library should also produce messages which are compatible with other versions, inasmuch as it is feasible given the message contents. See section 5.1 for an example: the "version" fields are set to the minimal values which still make sense given what else is in the structure.
if (noout) {
if (print)
CMS_ContentInfo_print_ctx(out, cms, 0, NULL);
} else if (outformat == FORMAT_SMIME) {
if (to)
BIO_printf(out, "To: %s\n", to);
if (from)
BIO_printf(out, "From: %s\n", from);
if (subject)
BIO_printf(out, "Subject: %s\n", subject);
if (operation == SMIME_RESIGN)
ret = SMIME_write_CMS(out, cms, indata, flags);
else
ret = SMIME_write_CMS(out, cms, in, flags);
} else if (outformat == FORMAT_PEM)
ret = PEM_write_bio_CMS_stream(out, cms, in, flags);
else if (outformat == FORMAT_ASN1)
ret = i2d_CMS_bio_stream(out, cms, in, flags);
else {
BIO_printf(bio_err, "Bad output format for CMS file\n");
goto end;
}
else {
if (to)
BIO_printf(out, "To: %s\n", to);
if (from)
BIO_printf(out, "From: %s\n", from);
if (subject)
BIO_printf(out, "Subject: %s\n", subject);
if (outformat == FORMAT_SMIME) {
if (operation == SMIME_RESIGN)
SMIME_write_PKCS7(out, p7, indata, flags);
else
SMIME_write_PKCS7(out, p7, in, flags);
} else if (outformat == FORMAT_PEM)
PEM_write_bio_PKCS7_stream(out, p7, in, flags);
else if (outformat == FORMAT_ASN1)
i2d_PKCS7_bio_stream(out, p7, in, flags);
else {
BIO_printf(bio_err, "Bad output format for PKCS#7 file\n");
goto end;
}
2) smtp如何发送邮件
https://technet.microsoft.com/en-us/library/dd441082.aspx
https://tools.ietf.org/html/rfc821
https://tools.ietf.org/html/rfc2554
https://tools.ietf.org/html/rfc2821
http://tools.ietf.org/html/rfc5321
邮件如何在smtp服务器之间路由 http://en.wikipedia.org/wiki/MX_record
如何通过邮件地址后缀的domain来查询邮件服务器(smtp)的地址:nslookup -type=mx sina.com