Google Git
Sign in
apache / cloudberry / refs/heads/cbdb-postgres-merge / . / src / interfaces / libpq / fe-auth.c
blob: 3b2fb19532516557ba118d3b4950cfa27ed3ebc0 [file] [log] [blame]
/*-------------------------------------------------------------------------
*
* fe-auth.c
* The front-end (client) authorization routines
*
* Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
* IDENTIFICATION
* src/interfaces/libpq/fe-auth.c
*
*-------------------------------------------------------------------------
*/
/*
* INTERFACE ROUTINES
* frontend (client) routines:
* pg_fe_sendauth send authentication information
* pg_fe_getauthname get user's name according to the client side
* of the authentication system
*/
/*
* This file is compiled with both frontend and backend codes, symlinked by
* src/backend/Makefile, and use macro FRONTEND to switch.
*
* Include "c.h" to adopt Cloudberry C types. Don't include "postgres_fe.h",
* which only defines FRONTEND besides including "c.h"
*/
#include "c.h"
#ifdef WIN32
#include "win32.h"
#else
#include <unistd.h>
#include <fcntl.h>
#include <limits.h>
#include <sys/param.h> /* for MAXHOSTNAMELEN on most */
#include <sys/socket.h>
#ifdef HAVE_SYS_UCRED_H
#include <sys/ucred.h>
#endif
#ifndef MAXHOSTNAMELEN
#include <netdb.h> /* for MAXHOSTNAMELEN on some */
#endif
#endif
#include "common/md5.h"
#include "common/scram-common.h"
#include "fe-auth.h"
#include "fe-auth-sasl.h"
#include "libpq-fe.h"
#ifdef ENABLE_GSS
/*
* GSSAPI authentication system.
*/
#include "fe-gssapi-common.h"
/*
* Continue GSS authentication with next token as needed.
*/
static int
pg_GSS_continue(PGconn *conn, int payloadlen)
{
OM_uint32 maj_stat,
min_stat,
lmin_s,
gss_flags = GSS_C_MUTUAL_FLAG;
gss_buffer_desc ginbuf;
gss_buffer_desc goutbuf;
/*
* On first call, there's no input token. On subsequent calls, read the
* input token into a GSS buffer.
*/
if (conn->gctx != GSS_C_NO_CONTEXT)
{
ginbuf.length = payloadlen;
ginbuf.value = malloc(payloadlen);
if (!ginbuf.value)
{
libpq_append_conn_error(conn, "out of memory allocating GSSAPI buffer (%d)",
payloadlen);
return STATUS_ERROR;
}
if (pqGetnchar(ginbuf.value, payloadlen, conn))
{
/*
* Shouldn't happen, because the caller should've ensured that the
* whole message is already in the input buffer.
*/
free(ginbuf.value);
return STATUS_ERROR;
}
}
else
{
ginbuf.length = 0;
ginbuf.value = NULL;
}
/* Only try to acquire credentials if GSS delegation isn't disabled. */
if (!pg_GSS_have_cred_cache(&conn->gcred))
conn->gcred = GSS_C_NO_CREDENTIAL;
if (conn->gssdelegation && conn->gssdelegation[0] == '1')
gss_flags |= GSS_C_DELEG_FLAG;
maj_stat = gss_init_sec_context(&min_stat,
conn->gcred,
&conn->gctx,
conn->gtarg_nam,
GSS_C_NO_OID,
gss_flags,
0,
GSS_C_NO_CHANNEL_BINDINGS,
(ginbuf.value == NULL) ? GSS_C_NO_BUFFER : &ginbuf,
NULL,
&goutbuf,
NULL,
NULL);
free(ginbuf.value);
if (goutbuf.length != 0)
{
/*
* GSS generated data to send to the server. We don't care if it's the
* first or subsequent packet, just send the same kind of password
* packet.
*/
if (pqPacketSend(conn, 'p',
goutbuf.value, goutbuf.length) != STATUS_OK)
{
gss_release_buffer(&lmin_s, &goutbuf);
return STATUS_ERROR;
}
}
gss_release_buffer(&lmin_s, &goutbuf);
if (maj_stat != GSS_S_COMPLETE && maj_stat != GSS_S_CONTINUE_NEEDED)
{
pg_GSS_error(libpq_gettext("GSSAPI continuation error"),
conn,
maj_stat, min_stat);
gss_release_name(&lmin_s, &conn->gtarg_nam);
if (conn->gctx)
gss_delete_sec_context(&lmin_s, &conn->gctx, GSS_C_NO_BUFFER);
return STATUS_ERROR;
}
if (maj_stat == GSS_S_COMPLETE)
{
conn->client_finished_auth = true;
gss_release_name(&lmin_s, &conn->gtarg_nam);
conn->gssapi_used = true;
}
return STATUS_OK;
}
/*
* Send initial GSS authentication token
*/
static int
pg_GSS_startup(PGconn *conn, int payloadlen)
{
int ret;
char *host = conn->connhost[conn->whichhost].host;
if (!(host && host[0] != '\0'))
{
libpq_append_conn_error(conn, "host name must be specified");
return STATUS_ERROR;
}
if (conn->gctx)
{
libpq_append_conn_error(conn, "duplicate GSS authentication request");
return STATUS_ERROR;
}
ret = pg_GSS_load_servicename(conn);
if (ret != STATUS_OK)
return ret;
/*
* Initial packet is the same as a continuation packet with no initial
* context.
*/
conn->gctx = GSS_C_NO_CONTEXT;
return pg_GSS_continue(conn, payloadlen);
}
#endif /* ENABLE_GSS */
#ifdef ENABLE_SSPI
/*
* SSPI authentication system (Windows only)
*/
static void
pg_SSPI_error(PGconn *conn, const char *mprefix, SECURITY_STATUS r)
{
char sysmsg[256];
if (FormatMessage(FORMAT_MESSAGE_IGNORE_INSERTS |
FORMAT_MESSAGE_FROM_SYSTEM,
NULL, r, 0,
sysmsg, sizeof(sysmsg), NULL) == 0)
appendPQExpBuffer(&conn->errorMessage, "%s: SSPI error %x\n",
mprefix, (unsigned int) r);
else
appendPQExpBuffer(&conn->errorMessage, "%s: %s (%x)\n",
mprefix, sysmsg, (unsigned int) r);
}
/*
* Continue SSPI authentication with next token as needed.
*/
static int
pg_SSPI_continue(PGconn *conn, int payloadlen)
{
SECURITY_STATUS r;
CtxtHandle newContext;
ULONG contextAttr;
SecBufferDesc inbuf;
SecBufferDesc outbuf;
SecBuffer OutBuffers[1];
SecBuffer InBuffers[1];
char *inputbuf = NULL;
if (conn->sspictx != NULL)
{
/*
* On runs other than the first we have some data to send. Put this
* data in a SecBuffer type structure.
*/
inputbuf = malloc(payloadlen);
if (!inputbuf)
{
libpq_append_conn_error(conn, "out of memory allocating SSPI buffer (%d)",
payloadlen);
return STATUS_ERROR;
}
if (pqGetnchar(inputbuf, payloadlen, conn))
{
/*
* Shouldn't happen, because the caller should've ensured that the
* whole message is already in the input buffer.
*/
free(inputbuf);
return STATUS_ERROR;
}
inbuf.ulVersion = SECBUFFER_VERSION;
inbuf.cBuffers = 1;
inbuf.pBuffers = InBuffers;
InBuffers[0].pvBuffer = inputbuf;
InBuffers[0].cbBuffer = payloadlen;
InBuffers[0].BufferType = SECBUFFER_TOKEN;
}
OutBuffers[0].pvBuffer = NULL;
OutBuffers[0].BufferType = SECBUFFER_TOKEN;
OutBuffers[0].cbBuffer = 0;
outbuf.cBuffers = 1;
outbuf.pBuffers = OutBuffers;
outbuf.ulVersion = SECBUFFER_VERSION;
r = InitializeSecurityContext(conn->sspicred,
conn->sspictx,
conn->sspitarget,
ISC_REQ_ALLOCATE_MEMORY,
0,
SECURITY_NETWORK_DREP,
(conn->sspictx == NULL) ? NULL : &inbuf,
0,
&newContext,
&outbuf,
&contextAttr,
NULL);
/* we don't need the input anymore */
free(inputbuf);
if (r != SEC_E_OK && r != SEC_I_CONTINUE_NEEDED)
{
pg_SSPI_error(conn, libpq_gettext("SSPI continuation error"), r);
return STATUS_ERROR;
}
if (conn->sspictx == NULL)
{
/* On first run, transfer retrieved context handle */
conn->sspictx = malloc(sizeof(CtxtHandle));
if (conn->sspictx == NULL)
{
libpq_append_conn_error(conn, "out of memory");
return STATUS_ERROR;
}
memcpy(conn->sspictx, &newContext, sizeof(CtxtHandle));
}
/*
* If SSPI returned any data to be sent to the server (as it normally
* would), send this data as a password packet.
*/
if (outbuf.cBuffers > 0)
{
if (outbuf.cBuffers != 1)
{
/*
* This should never happen, at least not for Kerberos
* authentication. Keep check in case it shows up with other
* authentication methods later.
*/
appendPQExpBufferStr(&conn->errorMessage,
"SSPI returned invalid number of output buffers\n");
return STATUS_ERROR;
}
/*
* If the negotiation is complete, there may be zero bytes to send.
* The server is at this point not expecting any more data, so don't
* send it.
*/
if (outbuf.pBuffers[0].cbBuffer > 0)
{
if (pqPacketSend(conn, 'p',
outbuf.pBuffers[0].pvBuffer, outbuf.pBuffers[0].cbBuffer))
{
FreeContextBuffer(outbuf.pBuffers[0].pvBuffer);
return STATUS_ERROR;
}
}
FreeContextBuffer(outbuf.pBuffers[0].pvBuffer);
}
if (r == SEC_E_OK)
conn->client_finished_auth = true;
/* Cleanup is handled by the code in freePGconn() */
return STATUS_OK;
}
/*
* Send initial SSPI authentication token.
* If use_negotiate is 0, use kerberos authentication package which is
* compatible with Unix. If use_negotiate is 1, use the negotiate package
* which supports both kerberos and NTLM, but is not compatible with Unix.
*/
static int
pg_SSPI_startup(PGconn *conn, int use_negotiate, int payloadlen)
{
SECURITY_STATUS r;
TimeStamp expire;
char *host = conn->connhost[conn->whichhost].host;
if (conn->sspictx)
{
libpq_append_conn_error(conn, "duplicate SSPI authentication request");
return STATUS_ERROR;
}
/*
* Retrieve credentials handle
*/
conn->sspicred = malloc(sizeof(CredHandle));
if (conn->sspicred == NULL)
{
libpq_append_conn_error(conn, "out of memory");
return STATUS_ERROR;
}
r = AcquireCredentialsHandle(NULL,
use_negotiate ? "negotiate" : "kerberos",
SECPKG_CRED_OUTBOUND,
NULL,
NULL,
NULL,
NULL,
conn->sspicred,
&expire);
if (r != SEC_E_OK)
{
pg_SSPI_error(conn, libpq_gettext("could not acquire SSPI credentials"), r);
free(conn->sspicred);
conn->sspicred = NULL;
return STATUS_ERROR;
}
/*
* Compute target principal name. SSPI has a different format from GSSAPI,
* but not more complex. We can skip the @REALM part, because Windows will
* fill that in for us automatically.
*/
if (!(host && host[0] != '\0'))
{
libpq_append_conn_error(conn, "host name must be specified");
return STATUS_ERROR;
}
conn->sspitarget = malloc(strlen(conn->krbsrvname) + strlen(host) + 2);
if (!conn->sspitarget)
{
libpq_append_conn_error(conn, "out of memory");
return STATUS_ERROR;
}
sprintf(conn->sspitarget, "%s/%s", conn->krbsrvname, host);
/*
* Indicate that we're in SSPI authentication mode to make sure that
* pg_SSPI_continue is called next time in the negotiation.
*/
conn->usesspi = 1;
return pg_SSPI_continue(conn, payloadlen);
}
#endif /* ENABLE_SSPI */
/*
* Initialize SASL authentication exchange.
*/
static int
pg_SASL_init(PGconn *conn, int payloadlen)
{
char *initialresponse = NULL;
int initialresponselen;
bool done;
bool success;
const char *selected_mechanism;
PQExpBufferData mechanism_buf;
char *password;
initPQExpBuffer(&mechanism_buf);
if (conn->channel_binding[0] == 'r' && /* require */
!conn->ssl_in_use)
{
libpq_append_conn_error(conn, "channel binding required, but SSL not in use");
goto error;
}
if (conn->sasl_state)
{
libpq_append_conn_error(conn, "duplicate SASL authentication request");
goto error;
}
/*
* Parse the list of SASL authentication mechanisms in the
* AuthenticationSASL message, and select the best mechanism that we
* support. SCRAM-SHA-256-PLUS and SCRAM-SHA-256 are the only ones
* supported at the moment, listed by order of decreasing importance.
*/
selected_mechanism = NULL;
for (;;)
{
if (pqGets(&mechanism_buf, conn))
{
appendPQExpBufferStr(&conn->errorMessage,
"fe_sendauth: invalid authentication request from server: invalid list of authentication mechanisms\n");
goto error;
}
if (PQExpBufferDataBroken(mechanism_buf))
goto oom_error;
/* An empty string indicates end of list */
if (mechanism_buf.data[0] == '\0')
break;
/*
* Select the mechanism to use. Pick SCRAM-SHA-256-PLUS over anything
* else if a channel binding type is set and if the client supports it
* (and did not set channel_binding=disable). Pick SCRAM-SHA-256 if
* nothing else has already been picked. If we add more mechanisms, a
* more refined priority mechanism might become necessary.
*/
if (strcmp(mechanism_buf.data, SCRAM_SHA_256_PLUS_NAME) == 0)
{
if (conn->ssl_in_use)
{
/* The server has offered SCRAM-SHA-256-PLUS. */
#ifdef HAVE_PGTLS_GET_PEER_CERTIFICATE_HASH
/*
* The client supports channel binding, which is chosen if
* channel_binding is not disabled.
*/
if (conn->channel_binding[0] != 'd') /* disable */
{
selected_mechanism = SCRAM_SHA_256_PLUS_NAME;
conn->sasl = &pg_scram_mech;
}
#else
/*
* The client does not support channel binding. If it is
* required, complain immediately instead of the error below
* which would be confusing as the server is publishing
* SCRAM-SHA-256-PLUS.
*/
if (conn->channel_binding[0] == 'r') /* require */
{
libpq_append_conn_error(conn, "channel binding is required, but client does not support it");
goto error;
}
#endif
}
else
{
/*
* The server offered SCRAM-SHA-256-PLUS, but the connection
* is not SSL-encrypted. That's not sane. Perhaps SSL was
* stripped by a proxy? There's no point in continuing,
* because the server will reject the connection anyway if we
* try authenticate without channel binding even though both
* the client and server supported it. The SCRAM exchange
* checks for that, to prevent downgrade attacks.
*/
libpq_append_conn_error(conn, "server offered SCRAM-SHA-256-PLUS authentication over a non-SSL connection");
goto error;
}
}
else if (strcmp(mechanism_buf.data, SCRAM_SHA_256_NAME) == 0 &&
!selected_mechanism)
{
selected_mechanism = SCRAM_SHA_256_NAME;
conn->sasl = &pg_scram_mech;
}
}
if (!selected_mechanism)
{
libpq_append_conn_error(conn, "none of the server's SASL authentication mechanisms are supported");
goto error;
}
if (conn->channel_binding[0] == 'r' && /* require */
strcmp(selected_mechanism, SCRAM_SHA_256_PLUS_NAME) != 0)
{
libpq_append_conn_error(conn, "channel binding is required, but server did not offer an authentication method that supports channel binding");
goto error;
}
/*
* Now that the SASL mechanism has been chosen for the exchange,
* initialize its state information.
*/
/*
* First, select the password to use for the exchange, complaining if
* there isn't one. Currently, all supported SASL mechanisms require a
* password, so we can just go ahead here without further distinction.
*/
conn->password_needed = true;
password = conn->connhost[conn->whichhost].password;
if (password == NULL)
password = conn->pgpass;
if (password == NULL || password[0] == '\0')
{
appendPQExpBufferStr(&conn->errorMessage,
PQnoPasswordSupplied);
goto error;
}
Assert(conn->sasl);
/*
* Initialize the SASL state information with all the information gathered
* during the initial exchange.
*
* Note: Only tls-unique is supported for the moment.
*/
conn->sasl_state = conn->sasl->init(conn,
password,
selected_mechanism);
if (!conn->sasl_state)
goto oom_error;
/* Get the mechanism-specific Initial Client Response, if any */
conn->sasl->exchange(conn->sasl_state,
NULL, -1,
&initialresponse, &initialresponselen,
&done, &success);
if (done && !success)
goto error;
/*
* Build a SASLInitialResponse message, and send it.
*/
if (pqPutMsgStart('p', conn))
goto error;
if (pqPuts(selected_mechanism, conn))
goto error;
if (initialresponse)
{
if (pqPutInt(initialresponselen, 4, conn))
goto error;
if (pqPutnchar(initialresponse, initialresponselen, conn))
goto error;
}
if (pqPutMsgEnd(conn))
goto error;
if (pqFlush(conn))
goto error;
termPQExpBuffer(&mechanism_buf);
free(initialresponse);
return STATUS_OK;
error:
termPQExpBuffer(&mechanism_buf);
free(initialresponse);
return STATUS_ERROR;
oom_error:
termPQExpBuffer(&mechanism_buf);
free(initialresponse);
libpq_append_conn_error(conn, "out of memory");
return STATUS_ERROR;
}
/*
* Exchange a message for SASL communication protocol with the backend.
* This should be used after calling pg_SASL_init to set up the status of
* the protocol.
*/
static int
pg_SASL_continue(PGconn *conn, int payloadlen, bool final)
{
char *output;
int outputlen;
bool done;
bool success;
int res;
char *challenge;
/* Read the SASL challenge from the AuthenticationSASLContinue message. */
challenge = malloc(payloadlen + 1);
if (!challenge)
{
libpq_append_conn_error(conn, "out of memory allocating SASL buffer (%d)",
payloadlen);
return STATUS_ERROR;
}
if (pqGetnchar(challenge, payloadlen, conn))
{
free(challenge);
return STATUS_ERROR;
}
/* For safety and convenience, ensure the buffer is NULL-terminated. */
challenge[payloadlen] = '\0';
conn->sasl->exchange(conn->sasl_state,
challenge, payloadlen,
&output, &outputlen,
&done, &success);
free(challenge); /* don't need the input anymore */
if (final && !done)
{
if (outputlen != 0)
free(output);
libpq_append_conn_error(conn, "AuthenticationSASLFinal received from server, but SASL authentication was not completed");
return STATUS_ERROR;
}
/*
* If the exchange is not completed yet, we need to make sure that the
* SASL mechanism has generated a message to send back.
*/
if (output == NULL && !done)
{
libpq_append_conn_error(conn, "no client response found after SASL exchange success");
return STATUS_ERROR;
}
/*
* SASL allows zero-length responses, so this check uses "output" and not
* "outputlen" to allow the case of an empty message.
*/
if (output)
{
/*
* Send the SASL response to the server.
*/
res = pqPacketSend(conn, 'p', output, outputlen);
free(output);
if (res != STATUS_OK)
return STATUS_ERROR;
}
if (done && !success)
return STATUS_ERROR;
return STATUS_OK;
}
static int
pg_password_sendauth(PGconn *conn, const char *password, AuthRequest areq)
{
int ret;
char *crypt_pwd = NULL;
const char *pwd_to_send;
char md5Salt[4];
/* Read the salt from the AuthenticationMD5Password message. */
if (areq == AUTH_REQ_MD5)
{
if (pqGetnchar(md5Salt, 4, conn))
return STATUS_ERROR; /* shouldn't happen */
}
/* Encrypt the password if needed. */
switch (areq)
{
case AUTH_REQ_MD5:
{
char *crypt_pwd2;
const char *errstr = NULL;
/* Allocate enough space for two MD5 hashes */
crypt_pwd = malloc(2 * (MD5_PASSWD_LEN + 1));
if (!crypt_pwd)
{
libpq_append_conn_error(conn, "out of memory");
return STATUS_ERROR;
}
crypt_pwd2 = crypt_pwd + MD5_PASSWD_LEN + 1;
if (!pg_md5_encrypt(password, conn->pguser,
strlen(conn->pguser), crypt_pwd2,
&errstr))
{
libpq_append_conn_error(conn, "could not encrypt password: %s", errstr);
free(crypt_pwd);
return STATUS_ERROR;
}
if (!pg_md5_encrypt(crypt_pwd2 + strlen("md5"), md5Salt,
4, crypt_pwd, &errstr))
{
libpq_append_conn_error(conn, "could not encrypt password: %s", errstr);
free(crypt_pwd);
return STATUS_ERROR;
}
pwd_to_send = crypt_pwd;
break;
}
case AUTH_REQ_PASSWORD:
pwd_to_send = password;
break;
default:
return STATUS_ERROR;
}
ret = pqPacketSend(conn, 'p', pwd_to_send, strlen(pwd_to_send) + 1);
free(crypt_pwd);
return ret;
}
/*
* Translate a disallowed AuthRequest code into an error message.
*/
static const char *
auth_method_description(AuthRequest areq)
{
switch (areq)
{
case AUTH_REQ_PASSWORD:
return libpq_gettext("server requested a cleartext password");
case AUTH_REQ_MD5:
return libpq_gettext("server requested a hashed password");
case AUTH_REQ_GSS:
case AUTH_REQ_GSS_CONT:
return libpq_gettext("server requested GSSAPI authentication");
case AUTH_REQ_SSPI:
return libpq_gettext("server requested SSPI authentication");
case AUTH_REQ_SASL:
case AUTH_REQ_SASL_CONT:
case AUTH_REQ_SASL_FIN:
return libpq_gettext("server requested SASL authentication");
}
return libpq_gettext("server requested an unknown authentication type");
}
/*
* Convenience macro for checking the allowed_auth_methods bitmask. Caller
* must ensure that type is not greater than 31 (high bit of the bitmask).
*/
#define auth_method_allowed(conn, type) \
(((conn)->allowed_auth_methods & (1 << (type))) != 0)
/*
* Verify that the authentication request is expected, given the connection
* parameters. This is especially important when the client wishes to
* authenticate the server before any sensitive information is exchanged.
*/
static bool
check_expected_areq(AuthRequest areq, PGconn *conn)
{
bool result = true;
const char *reason = NULL;
StaticAssertDecl((sizeof(conn->allowed_auth_methods) * CHAR_BIT) > AUTH_REQ_MAX,
"AUTH_REQ_MAX overflows the allowed_auth_methods bitmask");
if (conn->sslcertmode[0] == 'r' /* require */
&& areq == AUTH_REQ_OK)
{
/*
* Trade off a little bit of complexity to try to get these error
* messages as precise as possible.
*/
if (!conn->ssl_cert_requested)
{
libpq_append_conn_error(conn, "server did not request an SSL certificate");
return false;
}
else if (!conn->ssl_cert_sent)
{
libpq_append_conn_error(conn, "server accepted connection without a valid SSL certificate");
return false;
}
}
/*
* If the user required a specific auth method, or specified an allowed
* set, then reject all others here, and make sure the server actually
* completes an authentication exchange.
*/
if (conn->require_auth)
{
switch (areq)
{
case AUTH_REQ_OK:
/*
* Check to make sure we've actually finished our exchange (or
* else that the user has allowed an authentication-less
* connection).
*
* If the user has allowed both SCRAM and unauthenticated
* (trust) connections, then this check will silently accept
* partial SCRAM exchanges, where a misbehaving server does
* not provide its verifier before sending an OK. This is
* consistent with historical behavior, but it may be a point
* to revisit in the future, since it could allow a server
* that doesn't know the user's password to silently harvest
* material for a brute force attack.
*/
if (!conn->auth_required || conn->client_finished_auth)
break;
/*
* No explicit authentication request was made by the server
* -- or perhaps it was made and not completed, in the case of
* SCRAM -- but there is one special case to check. If the
* user allowed "gss", then a GSS-encrypted channel also
* satisfies the check.
*/
#ifdef ENABLE_GSS
if (auth_method_allowed(conn, AUTH_REQ_GSS) && conn->gssenc)
{
/*
* If implicit GSS auth has already been performed via GSS
* encryption, we don't need to have performed an
* AUTH_REQ_GSS exchange. This allows require_auth=gss to
* be combined with gssencmode, since there won't be an
* explicit authentication request in that case.
*/
}
else
#endif
{
reason = libpq_gettext("server did not complete authentication");
result = false;
}
break;
case AUTH_REQ_PASSWORD:
case AUTH_REQ_MD5:
case AUTH_REQ_GSS:
case AUTH_REQ_GSS_CONT:
case AUTH_REQ_SSPI:
case AUTH_REQ_SASL:
case AUTH_REQ_SASL_CONT:
case AUTH_REQ_SASL_FIN:
/*
* We don't handle these with the default case, to avoid
* bit-shifting past the end of the allowed_auth_methods mask
* if the server sends an unexpected AuthRequest.
*/
result = auth_method_allowed(conn, areq);
break;
default:
result = false;
break;
}
}
if (!result)
{
if (!reason)
reason = auth_method_description(areq);
libpq_append_conn_error(conn, "authentication method requirement \"%s\" failed: %s",
conn->require_auth, reason);
return result;
}
/*
* When channel_binding=require, we must protect against two cases: (1) we
* must not respond to non-SASL authentication requests, which might leak
* information such as the client's password; and (2) even if we receive
* AUTH_REQ_OK, we still must ensure that channel binding has happened in
* order to authenticate the server.
*/
if (conn->channel_binding[0] == 'r' /* require */ )
{
switch (areq)
{
case AUTH_REQ_SASL:
case AUTH_REQ_SASL_CONT:
case AUTH_REQ_SASL_FIN:
break;
case AUTH_REQ_OK:
if (!conn->sasl || !conn->sasl->channel_bound(conn->sasl_state))
{
libpq_append_conn_error(conn, "channel binding required, but server authenticated client without channel binding");
result = false;
}
break;
default:
libpq_append_conn_error(conn, "channel binding required but not supported by server's authentication request");
result = false;
break;
}
}
return result;
}
/*
* pg_fe_sendauth
* client demux routine for processing an authentication request
*
* The server has sent us an authentication challenge (or OK). Send an
* appropriate response. The caller has ensured that the whole message is
* now in the input buffer, and has already read the type and length of
* it. We are responsible for reading any remaining extra data, specific
* to the authentication method. 'payloadlen' is the remaining length in
* the message.
*/
int
pg_fe_sendauth(AuthRequest areq, int payloadlen, PGconn *conn)
{
int oldmsglen;
if (!check_expected_areq(areq, conn))
return STATUS_ERROR;
switch (areq)
{
case AUTH_REQ_OK:
break;
case AUTH_REQ_KRB4:
libpq_append_conn_error(conn, "Kerberos 4 authentication not supported");
return STATUS_ERROR;
case AUTH_REQ_KRB5:
libpq_append_conn_error(conn, "Kerberos 5 authentication not supported");
return STATUS_ERROR;
#if defined(ENABLE_GSS) || defined(ENABLE_SSPI)
case AUTH_REQ_GSS:
#if !defined(ENABLE_SSPI)
/* no native SSPI, so use GSSAPI library for it */
case AUTH_REQ_SSPI:
#endif
{
int r;
pglock_thread();
/*
* If we have both GSS and SSPI support compiled in, use SSPI
* support by default. This is overridable by a connection
* string parameter. Note that when using SSPI we still leave
* the negotiate parameter off, since we want SSPI to use the
* GSSAPI kerberos protocol. For actual SSPI negotiate
* protocol, we use AUTH_REQ_SSPI.
*/
#if defined(ENABLE_GSS) && defined(ENABLE_SSPI)
if (conn->gsslib && (pg_strcasecmp(conn->gsslib, "gssapi") == 0))
r = pg_GSS_startup(conn, payloadlen);
else
r = pg_SSPI_startup(conn, 0, payloadlen);
#elif defined(ENABLE_GSS) && !defined(ENABLE_SSPI)
r = pg_GSS_startup(conn, payloadlen);
#elif !defined(ENABLE_GSS) && defined(ENABLE_SSPI)
r = pg_SSPI_startup(conn, 0, payloadlen);
#endif
if (r != STATUS_OK)
{
/* Error message already filled in. */
pgunlock_thread();
return STATUS_ERROR;
}
pgunlock_thread();
}
break;
case AUTH_REQ_GSS_CONT:
{
int r;
pglock_thread();
#if defined(ENABLE_GSS) && defined(ENABLE_SSPI)
if (conn->usesspi)
r = pg_SSPI_continue(conn, payloadlen);
else
r = pg_GSS_continue(conn, payloadlen);
#elif defined(ENABLE_GSS) && !defined(ENABLE_SSPI)
r = pg_GSS_continue(conn, payloadlen);
#elif !defined(ENABLE_GSS) && defined(ENABLE_SSPI)
r = pg_SSPI_continue(conn, payloadlen);
#endif
if (r != STATUS_OK)
{
/* Error message already filled in. */
pgunlock_thread();
return STATUS_ERROR;
}
pgunlock_thread();
}
break;
#else /* defined(ENABLE_GSS) || defined(ENABLE_SSPI) */
/* No GSSAPI *or* SSPI support */
case AUTH_REQ_GSS:
case AUTH_REQ_GSS_CONT:
libpq_append_conn_error(conn, "GSSAPI authentication not supported");
return STATUS_ERROR;
#endif /* defined(ENABLE_GSS) || defined(ENABLE_SSPI) */
#ifdef ENABLE_SSPI
case AUTH_REQ_SSPI:
/*
* SSPI has its own startup message so libpq can decide which
* method to use. Indicate to pg_SSPI_startup that we want SSPI
* negotiation instead of Kerberos.
*/
pglock_thread();
if (pg_SSPI_startup(conn, 1, payloadlen) != STATUS_OK)
{
/* Error message already filled in. */
pgunlock_thread();
return STATUS_ERROR;
}
pgunlock_thread();
break;
#else
/*
* No SSPI support. However, if we have GSSAPI but not SSPI
* support, AUTH_REQ_SSPI will have been handled in the codepath
* for AUTH_REQ_GSS above, so don't duplicate the case label in
* that case.
*/
#if !defined(ENABLE_GSS)
case AUTH_REQ_SSPI:
libpq_append_conn_error(conn, "SSPI authentication not supported");
return STATUS_ERROR;
#endif /* !define(ENABLE_GSS) */
#endif /* ENABLE_SSPI */
case AUTH_REQ_CRYPT:
libpq_append_conn_error(conn, "Crypt authentication not supported");
return STATUS_ERROR;
case AUTH_REQ_MD5:
case AUTH_REQ_PASSWORD:
{
char *password;
conn->password_needed = true;
password = conn->connhost[conn->whichhost].password;
if (password == NULL)
password = conn->pgpass;
if (password == NULL || password[0] == '\0')
{
appendPQExpBufferStr(&conn->errorMessage,
PQnoPasswordSupplied);
return STATUS_ERROR;
}
if (pg_password_sendauth(conn, password, areq) != STATUS_OK)
{
appendPQExpBufferStr(&conn->errorMessage,
"fe_sendauth: error sending password authentication\n");
return STATUS_ERROR;
}
/* We expect no further authentication requests. */
conn->client_finished_auth = true;
break;
}
case AUTH_REQ_SASL:
/*
* The request contains the name (as assigned by IANA) of the
* authentication mechanism.
*/
if (pg_SASL_init(conn, payloadlen) != STATUS_OK)
{
/* pg_SASL_init already set the error message */
return STATUS_ERROR;
}
break;
case AUTH_REQ_SASL_CONT:
case AUTH_REQ_SASL_FIN:
if (conn->sasl_state == NULL)
{
appendPQExpBufferStr(&conn->errorMessage,
"fe_sendauth: invalid authentication request from server: AUTH_REQ_SASL_CONT without AUTH_REQ_SASL\n");
return STATUS_ERROR;
}
oldmsglen = conn->errorMessage.len;
if (pg_SASL_continue(conn, payloadlen,
(areq == AUTH_REQ_SASL_FIN)) != STATUS_OK)
{
/* Use this message if pg_SASL_continue didn't supply one */
if (conn->errorMessage.len == oldmsglen)
appendPQExpBufferStr(&conn->errorMessage,
"fe_sendauth: error in SASL authentication\n");
return STATUS_ERROR;
}
break;
default:
libpq_append_conn_error(conn, "authentication method %u not supported", areq);
return STATUS_ERROR;
}
return STATUS_OK;
}
/*
* pg_fe_getusername
*
* Returns a pointer to malloc'd space containing the name of the
* specified user_id. If there is an error, return NULL, and append
* a suitable error message to *errorMessage if that's not NULL.
*
* Caution: on Windows, the user_id argument is ignored, and we always
* fetch the current user's name.
*/
char *
pg_fe_getusername(uid_t user_id, PQExpBuffer errorMessage)
{
char *result = NULL;
const char *name = NULL;
#ifdef WIN32
/* Microsoft recommends buffer size of UNLEN+1, where UNLEN = 256 */
char username[256 + 1];
DWORD namesize = sizeof(username);
#else
char pwdbuf[BUFSIZ];
#endif
/*
* Some users are using configure --enable-thread-safety-force, so we
* might as well do the locking within our library to protect getpwuid().
* In fact, application developers can use getpwuid() in their application
* if they use the locking call we provide, or install their own locking
* function using PQregisterThreadLock().
*/
pglock_thread();
#ifdef WIN32
if (GetUserName(username, &namesize))
name = username;
else if (errorMessage)
libpq_append_error(errorMessage,
"user name lookup failure: error code %lu",
GetLastError());
#else
if (pg_get_user_name(user_id, pwdbuf, sizeof(pwdbuf)))
name = pwdbuf;
else if (errorMessage)
appendPQExpBuffer(errorMessage, "%s\n", pwdbuf);
#endif
if (name)
{
result = strdup(name);
if (result == NULL && errorMessage)
libpq_append_error(errorMessage, "out of memory");
}
pgunlock_thread();
return result;
}
/*
* pg_fe_getauthname
*
* Returns a pointer to malloc'd space containing whatever name the user
* has authenticated to the system. If there is an error, return NULL,
* and append a suitable error message to *errorMessage if that's not NULL.
*/
char *
pg_fe_getauthname(PQExpBuffer errorMessage)
{
#ifdef WIN32
return pg_fe_getusername(0, errorMessage);
#else
return pg_fe_getusername(geteuid(), errorMessage);
#endif
}
/*
* PQencryptPassword -- exported routine to encrypt a password with MD5
*
* This function is equivalent to calling PQencryptPasswordConn with
* "md5" as the encryption method, except that this doesn't require
* a connection object. This function is deprecated, use
* PQencryptPasswordConn instead.
*/
char *
PQencryptPassword(const char *passwd, const char *user)
{
char *crypt_pwd;
const char *errstr = NULL;
crypt_pwd = malloc(MD5_PASSWD_LEN + 1);
if (!crypt_pwd)
return NULL;
if (!pg_md5_encrypt(passwd, user, strlen(user), crypt_pwd, &errstr))
{
free(crypt_pwd);
return NULL;
}
return crypt_pwd;
}
/*
* PQencryptPasswordConn -- exported routine to encrypt a password
*
* This is intended to be used by client applications that wish to send
* commands like ALTER USER joe PASSWORD 'pwd'. The password need not
* be sent in cleartext if it is encrypted on the client side. This is
* good because it ensures the cleartext password won't end up in logs,
* pg_stat displays, etc. We export the function so that clients won't
* be dependent on low-level details like whether the encryption is MD5
* or something else.
*
* Arguments are a connection object, the cleartext password, the SQL
* name of the user it is for, and a string indicating the algorithm to
* use for encrypting the password. If algorithm is NULL, this queries
* the server for the current 'password_encryption' value. If you wish
* to avoid that, e.g. to avoid blocking, you can execute
* 'show password_encryption' yourself before calling this function, and
* pass it as the algorithm.
*
* Return value is a malloc'd string. The client may assume the string
* doesn't contain any special characters that would require escaping.
* On error, an error message is stored in the connection object, and
* returns NULL.
*/
char *
PQencryptPasswordConn(PGconn *conn, const char *passwd, const char *user,
const char *algorithm)
{
#define MAX_ALGORITHM_NAME_LEN 50
char algobuf[MAX_ALGORITHM_NAME_LEN + 1];
char *crypt_pwd = NULL;
if (!conn)
return NULL;
pqClearConnErrorState(conn);
/* If no algorithm was given, ask the server. */
if (algorithm == NULL)
{
PGresult *res;
char *val;
res = PQexec(conn, "show password_encryption");
if (res == NULL)
{
/* PQexec() should've set conn->errorMessage already */
return NULL;
}
if (PQresultStatus(res) != PGRES_TUPLES_OK)
{
/* PQexec() should've set conn->errorMessage already */
PQclear(res);
return NULL;
}
if (PQntuples(res) != 1 || PQnfields(res) != 1)
{
PQclear(res);
libpq_append_conn_error(conn, "unexpected shape of result set returned for SHOW");
return NULL;
}
val = PQgetvalue(res, 0, 0);
if (strlen(val) > MAX_ALGORITHM_NAME_LEN)
{
PQclear(res);
libpq_append_conn_error(conn, "password_encryption value too long");
return NULL;
}
strcpy(algobuf, val);
PQclear(res);
algorithm = algobuf;
}
/*
* Also accept "on" and "off" as aliases for "md5", because
* password_encryption was a boolean before PostgreSQL 10. We refuse to
* send the password in plaintext even if it was "off".
*/
if (strcmp(algorithm, "on") == 0 ||
strcmp(algorithm, "off") == 0)
algorithm = "md5";
/*
* Ok, now we know what algorithm to use
*/
if (strcmp(algorithm, "scram-sha-256") == 0)
{
const char *errstr = NULL;
crypt_pwd = pg_fe_scram_build_secret(passwd,
conn->scram_sha_256_iterations,
&errstr);
if (!crypt_pwd)
libpq_append_conn_error(conn, "could not encrypt password: %s", errstr);
}
else if (strcmp(algorithm, "md5") == 0)
{
crypt_pwd = malloc(MD5_PASSWD_LEN + 1);
if (crypt_pwd)
{
const char *errstr = NULL;
if (!pg_md5_encrypt(passwd, user, strlen(user), crypt_pwd, &errstr))
{
libpq_append_conn_error(conn, "could not encrypt password: %s", errstr);
free(crypt_pwd);
crypt_pwd = NULL;
}
}
else
libpq_append_conn_error(conn, "out of memory");
}
else
{
libpq_append_conn_error(conn, "unrecognized password encryption algorithm \"%s\"",
algorithm);
return NULL;
}
return crypt_pwd;
}