/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Server side RPC handler. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Fragment size (5680: NT style). */ #define MLRPC_FRAG_SZ 5680 static unsigned long mlrpc_frag_size = MLRPC_FRAG_SZ; /* * Context table. */ #define CTXT_PIPE_SZ 65536 #define CTXT_TABLE_ENTRIES 128 static struct mlsvc_rpc_context context_table[CTXT_TABLE_ENTRIES]; static mutex_t mlrpc_context_lock; static int mlrpc_s_process(struct mlrpc_xaction *); static int mlrpc_s_bind(struct mlrpc_xaction *); static int mlrpc_s_request(struct mlrpc_xaction *); static void mlrpc_reply_prepare_hdr(struct mlrpc_xaction *); static int mlrpc_s_alter_context(struct mlrpc_xaction *); static void mlrpc_reply_bind_ack(struct mlrpc_xaction *); static void mlrpc_reply_fault(struct mlrpc_xaction *, unsigned long); static int mlrpc_build_reply(struct mlrpc_xaction *); /* * This is the RPC service server-side entry point. All MSRPC encoded * messages should be passed through here. We use the same context * structure as the client side but we don't need to set up the client * side info. */ struct mlsvc_rpc_context * mlrpc_process(int fid, smb_dr_user_ctx_t *user_ctx) { struct mlsvc_rpc_context *context; struct mlrpc_xaction *mxa; struct mlndr_stream *recv_mlnds; struct mlndr_stream *send_mlnds; unsigned char *pdu_base_addr; char *data; int datalen; if ((context = mlrpc_lookup(fid)) == NULL) return (NULL); context->user_ctx = user_ctx; data = context->inpipe->sp_data; datalen = context->inpipe->sp_datalen; mxa = (struct mlrpc_xaction *)malloc(sizeof (struct mlrpc_xaction)); if (mxa == NULL) return (NULL); bzero(mxa, sizeof (struct mlrpc_xaction)); mxa->fid = fid; mxa->context = context; mxa->binding_list = context->binding; if ((mxa->heap = mlrpc_heap_create()) == NULL) { free(mxa); return (NULL); } recv_mlnds = &mxa->recv_mlnds; (void) mlnds_initialize(recv_mlnds, datalen, NDR_MODE_CALL_RECV, mxa->heap); bcopy(data, recv_mlnds->pdu_base_addr, datalen); send_mlnds = &mxa->send_mlnds; (void) mlnds_initialize(send_mlnds, 0, NDR_MODE_RETURN_SEND, mxa->heap); (void) mlrpc_s_process(mxa); /* * Different pointers for single frag vs multi frag responses. */ if (send_mlnds->pdu_base_addr_with_rpc_hdrs) pdu_base_addr = send_mlnds->pdu_base_addr_with_rpc_hdrs; else pdu_base_addr = send_mlnds->pdu_base_addr; datalen = send_mlnds->pdu_size_with_rpc_hdrs; context->outpipe->sp_datalen = datalen; bcopy(pdu_base_addr, context->outpipe->sp_data, datalen); mlnds_destruct(&mxa->recv_mlnds); mlnds_destruct(&mxa->send_mlnds); mlrpc_heap_destroy(mxa->heap); free(mxa); return (context); } /* * Lookup the context for pipeid. If one exists, return a pointer to it. * Otherwise attempt to allocate a new context and return it. If the * context table is full, return a null pointer. */ struct mlsvc_rpc_context * mlrpc_lookup(int fid) { struct mlsvc_rpc_context *context; struct mlsvc_rpc_context *available = NULL; int i; (void) mutex_lock(&mlrpc_context_lock); for (i = 0; i < CTXT_TABLE_ENTRIES; ++i) { context = &context_table[i]; if (available == NULL && context->fid == 0) { available = context; continue; } if (context->fid == fid) { (void) mutex_unlock(&mlrpc_context_lock); return (context); } } if (available) { bzero(available, sizeof (struct mlsvc_rpc_context)); available->inpipe = malloc(CTXT_PIPE_SZ); available->outpipe = malloc(CTXT_PIPE_SZ); if (available->inpipe == NULL || available->outpipe == NULL) { free(available->inpipe); free(available->outpipe); bzero(available, sizeof (struct mlsvc_rpc_context)); (void) mutex_unlock(&mlrpc_context_lock); return (NULL); } bzero(available->inpipe, sizeof (smb_pipe_t)); bzero(available->outpipe, sizeof (smb_pipe_t)); available->fid = fid; available->inpipe->sp_pipeid = fid; available->outpipe->sp_pipeid = fid; mlrpc_binding_pool_initialize(&available->binding, available->binding_pool, CTXT_N_BINDING_POOL); } (void) mutex_unlock(&mlrpc_context_lock); return (available); } /* * This function should be called to release the context associated * with a fid when the client performs a close file. */ void mlrpc_release(int fid) { struct mlsvc_rpc_context *context; int i; (void) mutex_lock(&mlrpc_context_lock); for (i = 0; i < CTXT_TABLE_ENTRIES; ++i) { context = &context_table[i]; if (context->fid == fid) { ndr_hdclose(fid); free(context->inpipe); free(context->outpipe); bzero(context, sizeof (struct mlsvc_rpc_context)); break; } } (void) mutex_unlock(&mlrpc_context_lock); } /* * This is the entry point for all server-side RPC processing. * It is assumed that the PDU has already been received. */ static int mlrpc_s_process(struct mlrpc_xaction *mxa) { int rc; rc = mlrpc_decode_pdu_hdr(mxa); if (!MLRPC_DRC_IS_OK(rc)) return (-1); (void) mlrpc_reply_prepare_hdr(mxa); switch (mxa->ptype) { case MLRPC_PTYPE_BIND: rc = mlrpc_s_bind(mxa); break; case MLRPC_PTYPE_REQUEST: rc = mlrpc_s_request(mxa); break; case MLRPC_PTYPE_ALTER_CONTEXT: rc = mlrpc_s_alter_context(mxa); break; default: rc = MLRPC_DRC_FAULT_RPCHDR_PTYPE_INVALID; break; } if (MLRPC_DRC_IS_FAULT(rc)) mlrpc_reply_fault(mxa, rc); (void) mlrpc_build_reply(mxa); return (rc); } /* * Multiple p_cont_elem[]s, multiple transfer_syntaxes[] and multiple * p_results[] not supported. */ static int mlrpc_s_bind(struct mlrpc_xaction *mxa) { mlrpc_p_cont_list_t *cont_list; mlrpc_p_result_list_t *result_list; mlrpc_p_result_t *result; unsigned p_cont_id; struct mlrpc_binding *mbind; ndr_uuid_t *as_uuid; ndr_uuid_t *ts_uuid; char as_buf[64]; char ts_buf[64]; int as_vers; int ts_vers; struct mlndr_stream *send_mlnds; struct mlrpc_service *msvc; int rc; mlrpc_port_any_t *sec_addr; /* acquire targets */ cont_list = &mxa->recv_hdr.bind_hdr.p_context_elem; result_list = &mxa->send_hdr.bind_ack_hdr.p_result_list; result = &result_list->p_results[0]; /* * Set up temporary secondary address port. * We will correct this later (below). */ send_mlnds = &mxa->send_mlnds; sec_addr = &mxa->send_hdr.bind_ack_hdr.sec_addr; sec_addr->length = 13; (void) strcpy((char *)sec_addr->port_spec, "\\PIPE\\ntsvcs"); result_list->n_results = 1; result_list->reserved = 0; result_list->reserved2 = 0; result->result = MLRPC_PCDR_ACCEPTANCE; result->reason = 0; bzero(&result->transfer_syntax, sizeof (result->transfer_syntax)); /* sanity check */ if (cont_list->n_context_elem != 1 || cont_list->p_cont_elem[0].n_transfer_syn != 1) { mlndo_trace("mlrpc_s_bind: warning: multiple p_cont_elem"); } p_cont_id = cont_list->p_cont_elem[0].p_cont_id; if ((mbind = mlrpc_find_binding(mxa, p_cont_id)) != NULL) { /* * Duplicate p_cont_id. * Send a bind_ack with a better error. */ mlndo_trace("mlrpc_s_bind: duplicate binding"); return (MLRPC_DRC_FAULT_BIND_PCONT_BUSY); } if ((mbind = mlrpc_new_binding(mxa)) == NULL) { /* * No free binding slot */ result->result = MLRPC_PCDR_PROVIDER_REJECTION; result->reason = MLRPC_PPR_LOCAL_LIMIT_EXCEEDED; mlndo_trace("mlrpc_s_bind: no resources"); return (MLRPC_DRC_OK); } as_uuid = &cont_list->p_cont_elem[0].abstract_syntax.if_uuid; as_vers = cont_list->p_cont_elem[0].abstract_syntax.if_version; ts_uuid = &cont_list->p_cont_elem[0].transfer_syntaxes[0].if_uuid; ts_vers = cont_list->p_cont_elem[0].transfer_syntaxes[0].if_version; msvc = mlrpc_find_service_by_uuids(as_uuid, as_vers, ts_uuid, ts_vers); if (!msvc) { mlrpc_uuid_to_str(as_uuid, as_buf); mlrpc_uuid_to_str(ts_uuid, ts_buf); mlndo_printf(send_mlnds, 0, "mlrpc_s_bind: unknown service"); mlndo_printf(send_mlnds, 0, "abs=%s v%d, xfer=%s v%d", as_buf, as_vers, ts_buf, ts_vers); result->result = MLRPC_PCDR_PROVIDER_REJECTION; result->reason = MLRPC_PPR_ABSTRACT_SYNTAX_NOT_SUPPORTED; return (MLRPC_DRC_OK); } /* * We can now use the correct secondary address port. */ sec_addr = &mxa->send_hdr.bind_ack_hdr.sec_addr; sec_addr->length = strlen(msvc->sec_addr_port) + 1; (void) strlcpy((char *)sec_addr->port_spec, msvc->sec_addr_port, MLRPC_PORT_ANY_MAX_PORT_SPEC); mbind->p_cont_id = p_cont_id; mbind->which_side = MLRPC_BIND_SIDE_SERVER; /* mbind->context set by app */ mbind->service = msvc; mbind->instance_specific = 0; mxa->binding = mbind; if (msvc->bind_req) { /* * Call the service-specific bind() handler. If * this fails, we shouild send a specific error * on the bind ack. */ rc = (msvc->bind_req)(mxa); if (MLRPC_DRC_IS_FAULT(rc)) { mbind->service = 0; /* free binding slot */ mbind->which_side = 0; mbind->p_cont_id = 0; mbind->instance_specific = 0; return (rc); } } result->transfer_syntax = cont_list->p_cont_elem[0].transfer_syntaxes[0]; /* * Special rejection of Windows 2000 DSSETUP interface. * This interface was introduced in Windows 2000 but has * been subsequently deprecated due to problems. */ if (strcmp(msvc->name, "DSSETUP") == 0) { result->result = MLRPC_PCDR_PROVIDER_REJECTION; result->reason = MLRPC_PPR_ABSTRACT_SYNTAX_NOT_SUPPORTED; } return (MLRPC_DRC_BINDING_MADE); } /* * mlrpc_s_alter_context * * The alter context request is used to request additional presentation * context for another interface and/or version. It's very similar to a * bind request. * * We don't fully support multiple contexts so, for now, we reject this * request. Windows 2000 clients attempt to use an alternate LSA context * when ACLs are modified. */ static int mlrpc_s_alter_context(struct mlrpc_xaction *mxa) { mlrpc_p_result_list_t *result_list; mlrpc_p_result_t *result; mlrpc_p_cont_list_t *cont_list; struct mlrpc_binding *mbind; struct mlrpc_service *msvc; unsigned p_cont_id; ndr_uuid_t *as_uuid; ndr_uuid_t *ts_uuid; int as_vers; int ts_vers; mlrpc_port_any_t *sec_addr; result_list = &mxa->send_hdr.bind_ack_hdr.p_result_list; result_list->n_results = 1; result_list->reserved = 0; result_list->reserved2 = 0; result = &result_list->p_results[0]; result->result = MLRPC_PCDR_ACCEPTANCE; result->reason = 0; bzero(&result->transfer_syntax, sizeof (result->transfer_syntax)); if (mxa != NULL) { result->result = MLRPC_PCDR_PROVIDER_REJECTION; result->reason = MLRPC_PPR_ABSTRACT_SYNTAX_NOT_SUPPORTED; return (MLRPC_DRC_OK); } cont_list = &mxa->recv_hdr.bind_hdr.p_context_elem; p_cont_id = cont_list->p_cont_elem[0].p_cont_id; if ((mbind = mlrpc_find_binding(mxa, p_cont_id)) != NULL) return (MLRPC_DRC_FAULT_BIND_PCONT_BUSY); if ((mbind = mlrpc_new_binding(mxa)) == NULL) { result->result = MLRPC_PCDR_PROVIDER_REJECTION; result->reason = MLRPC_PPR_LOCAL_LIMIT_EXCEEDED; return (MLRPC_DRC_OK); } as_uuid = &cont_list->p_cont_elem[0].abstract_syntax.if_uuid; as_vers = cont_list->p_cont_elem[0].abstract_syntax.if_version; ts_uuid = &cont_list->p_cont_elem[0].transfer_syntaxes[0].if_uuid; ts_vers = cont_list->p_cont_elem[0].transfer_syntaxes[0].if_version; msvc = mlrpc_find_service_by_uuids(as_uuid, as_vers, ts_uuid, ts_vers); if (msvc == 0) { result->result = MLRPC_PCDR_PROVIDER_REJECTION; result->reason = MLRPC_PPR_ABSTRACT_SYNTAX_NOT_SUPPORTED; return (MLRPC_DRC_OK); } mbind->p_cont_id = p_cont_id; mbind->which_side = MLRPC_BIND_SIDE_SERVER; /* mbind->context set by app */ mbind->service = msvc; mbind->instance_specific = 0; mxa->binding = mbind; sec_addr = &mxa->send_hdr.bind_ack_hdr.sec_addr; sec_addr->length = 0; bzero(sec_addr->port_spec, MLRPC_PORT_ANY_MAX_PORT_SPEC); result->transfer_syntax = cont_list->p_cont_elem[0].transfer_syntaxes[0]; return (MLRPC_DRC_BINDING_MADE); } static int mlrpc_s_request(struct mlrpc_xaction *mxa) { struct mlrpc_binding *mbind; struct mlrpc_service *msvc; unsigned p_cont_id; int rc; mxa->opnum = mxa->recv_hdr.request_hdr.opnum; p_cont_id = mxa->recv_hdr.request_hdr.p_cont_id; if ((mbind = mlrpc_find_binding(mxa, p_cont_id)) == NULL) return (MLRPC_DRC_FAULT_REQUEST_PCONT_INVALID); mxa->binding = mbind; msvc = mbind->service; /* * Make room for the response hdr. */ mxa->send_mlnds.pdu_scan_offset = MLRPC_RSP_HDR_SIZE; if (msvc->call_stub) rc = (*msvc->call_stub)(mxa); else rc = mlrpc_generic_call_stub(mxa); if (MLRPC_DRC_IS_FAULT(rc)) { mlndo_printf(0, 0, "%s[0x%02x]: 0x%04x", msvc->name, mxa->opnum, rc); } return (rc); } /* * The transaction and the two mlnds streams use the same heap, which * should already exist at this point. The heap will also be available * to the stub. */ int mlrpc_generic_call_stub(struct mlrpc_xaction *mxa) { struct mlrpc_binding *mbind = mxa->binding; struct mlrpc_service *msvc = mbind->service; struct ndr_typeinfo *intf_ti = msvc->interface_ti; struct mlrpc_stub_table *ste; int opnum = mxa->opnum; unsigned p_len = intf_ti->c_size_fixed_part; char *param; int rc; if (mxa->heap == NULL) { mlndo_printf(0, 0, "%s[0x%02x]: no heap", msvc->name, opnum); return (MLRPC_DRC_FAULT_OUT_OF_MEMORY); } if ((ste = mlrpc_find_stub_in_svc(msvc, opnum)) == NULL) { mlndo_printf(0, 0, "%s[0x%02x]: invalid opnum", msvc->name, opnum); return (MLRPC_DRC_FAULT_REQUEST_OPNUM_INVALID); } if ((param = mlrpc_heap_malloc(mxa->heap, p_len)) == NULL) return (MLRPC_DRC_FAULT_OUT_OF_MEMORY); bzero(param, p_len); rc = mlrpc_decode_call(mxa, param); if (!MLRPC_DRC_IS_OK(rc)) return (rc); rc = (*ste->func)(param, mxa); if (rc == MLRPC_DRC_OK) rc = mlrpc_encode_return(mxa, param); return (rc); } /* * We can perform some initial setup of the response header here. * We also need to cache some of the information from the bind * negotiation for use during subsequent RPC calls. */ static void mlrpc_reply_prepare_hdr(struct mlrpc_xaction *mxa) { mlrpcconn_common_header_t *rhdr = &mxa->recv_hdr.common_hdr; mlrpcconn_common_header_t *hdr = &mxa->send_hdr.common_hdr; hdr->rpc_vers = 5; hdr->rpc_vers_minor = 0; hdr->pfc_flags = MLRPC_PFC_FIRST_FRAG + MLRPC_PFC_LAST_FRAG; hdr->packed_drep = rhdr->packed_drep; hdr->frag_length = 0; hdr->auth_length = 0; hdr->call_id = rhdr->call_id; #ifdef _BIG_ENDIAN hdr->packed_drep.intg_char_rep = MLRPC_REPLAB_CHAR_ASCII | MLRPC_REPLAB_INTG_BIG_ENDIAN; #else hdr->packed_drep.intg_char_rep = MLRPC_REPLAB_CHAR_ASCII | MLRPC_REPLAB_INTG_LITTLE_ENDIAN; #endif switch (mxa->ptype) { case MLRPC_PTYPE_BIND: hdr->ptype = MLRPC_PTYPE_BIND_ACK; mxa->send_hdr.bind_ack_hdr.max_xmit_frag = mxa->recv_hdr.bind_hdr.max_xmit_frag; mxa->send_hdr.bind_ack_hdr.max_recv_frag = mxa->recv_hdr.bind_hdr.max_recv_frag; mxa->send_hdr.bind_ack_hdr.assoc_group_id = mxa->recv_hdr.bind_hdr.assoc_group_id; if (mxa->send_hdr.bind_ack_hdr.assoc_group_id == 0) mxa->send_hdr.bind_ack_hdr.assoc_group_id = time(0); /* * Save the maximum fragment sizes * for use with subsequent requests. */ mxa->context->max_xmit_frag = mxa->recv_hdr.bind_hdr.max_xmit_frag; mxa->context->max_recv_frag = mxa->recv_hdr.bind_hdr.max_recv_frag; break; case MLRPC_PTYPE_REQUEST: hdr->ptype = MLRPC_PTYPE_RESPONSE; /* mxa->send_hdr.response_hdr.alloc_hint */ mxa->send_hdr.response_hdr.p_cont_id = mxa->recv_hdr.request_hdr.p_cont_id; mxa->send_hdr.response_hdr.cancel_count = 0; mxa->send_hdr.response_hdr.reserved = 0; break; case MLRPC_PTYPE_ALTER_CONTEXT: hdr->ptype = MLRPC_PTYPE_ALTER_CONTEXT_RESP; /* * The max_xmit_frag, max_recv_frag * and assoc_group_id are ignored. */ break; default: hdr->ptype = 0xFF; } } /* * Finish and encode the bind acknowledge (MLRPC_PTYPE_BIND_ACK) header. * The frag_length is different from a regular RPC response. */ static void mlrpc_reply_bind_ack(struct mlrpc_xaction *mxa) { mlrpcconn_common_header_t *hdr; mlrpcconn_bind_ack_hdr_t *bahdr; hdr = &mxa->send_hdr.common_hdr; bahdr = &mxa->send_hdr.bind_ack_hdr; hdr->frag_length = mlrpc_bind_ack_hdr_size(bahdr); } /* * Signal an RPC fault. The stream is reset and we overwrite whatever * was in the response header with the fault information. */ static void mlrpc_reply_fault(struct mlrpc_xaction *mxa, unsigned long drc) { mlrpcconn_common_header_t *rhdr = &mxa->recv_hdr.common_hdr; mlrpcconn_common_header_t *hdr = &mxa->send_hdr.common_hdr; struct mlndr_stream *mlnds = &mxa->send_mlnds; unsigned long fault_status; MLNDS_RESET(mlnds); hdr->rpc_vers = 5; hdr->rpc_vers_minor = 0; hdr->pfc_flags = MLRPC_PFC_FIRST_FRAG + MLRPC_PFC_LAST_FRAG; hdr->packed_drep = rhdr->packed_drep; hdr->frag_length = sizeof (mxa->send_hdr.fault_hdr); hdr->auth_length = 0; hdr->call_id = rhdr->call_id; #ifdef _BIG_ENDIAN hdr->packed_drep.intg_char_rep = MLRPC_REPLAB_CHAR_ASCII | MLRPC_REPLAB_INTG_BIG_ENDIAN; #else hdr->packed_drep.intg_char_rep = MLRPC_REPLAB_CHAR_ASCII | MLRPC_REPLAB_INTG_LITTLE_ENDIAN; #endif switch (drc & MLRPC_DRC_MASK_SPECIFIER) { case MLRPC_DRC_FAULT_OUT_OF_MEMORY: case MLRPC_DRC_FAULT_ENCODE_TOO_BIG: fault_status = MLRPC_FAULT_NCA_OUT_ARGS_TOO_BIG; break; case MLRPC_DRC_FAULT_REQUEST_PCONT_INVALID: fault_status = MLRPC_FAULT_NCA_INVALID_PRES_CONTEXT_ID; break; case MLRPC_DRC_FAULT_REQUEST_OPNUM_INVALID: fault_status = MLRPC_FAULT_NCA_OP_RNG_ERROR; break; case MLRPC_DRC_FAULT_DECODE_FAILED: case MLRPC_DRC_FAULT_ENCODE_FAILED: fault_status = MLRPC_FAULT_NCA_PROTO_ERROR; break; default: fault_status = MLRPC_FAULT_NCA_UNSPEC_REJECT; break; } mxa->send_hdr.fault_hdr.common_hdr.ptype = MLRPC_PTYPE_FAULT; mxa->send_hdr.fault_hdr.status = fault_status; mxa->send_hdr.response_hdr.alloc_hint = hdr->frag_length; } static int mlrpc_build_reply(struct mlrpc_xaction *mxa) { mlrpcconn_common_header_t *hdr = &mxa->send_hdr.common_hdr; struct mlndr_stream *mlnds = &mxa->send_mlnds; unsigned long pdu_size; unsigned long frag_size; unsigned long pdu_data_size; unsigned long frag_data_size; uint32_t rem_dlen; uint32_t save_rem_dlen; uint32_t bytesoff; uint32_t cnt; uint32_t obytes; uint32_t num_ext_frags; uint16_t last_frag = 0; uchar_t *frag_startp; mlrpcconn_common_header_t *rpc_hdr; hdr = &mxa->send_hdr.common_hdr; frag_size = mlrpc_frag_size; pdu_size = mlnds->pdu_size; if (pdu_size <= frag_size) { /* * Single fragment response. The PDU size may be zero * here (i.e. bind or fault response). So don't make * any assumptions about it until after the header is * encoded. */ switch (hdr->ptype) { case MLRPC_PTYPE_BIND_ACK: mlrpc_reply_bind_ack(mxa); break; case MLRPC_PTYPE_FAULT: /* already setup */ break; case MLRPC_PTYPE_RESPONSE: hdr->frag_length = pdu_size; mxa->send_hdr.response_hdr.alloc_hint = hdr->frag_length; break; default: hdr->frag_length = pdu_size; break; } mlnds->pdu_scan_offset = 0; (void) mlrpc_encode_pdu_hdr(mxa); mlnds->pdu_size_with_rpc_hdrs = mlnds->pdu_size; mlnds->pdu_base_addr_with_rpc_hdrs = 0; return (0); } /* * Multiple fragment response. */ hdr->pfc_flags = MLRPC_PFC_FIRST_FRAG; hdr->frag_length = frag_size; mxa->send_hdr.response_hdr.alloc_hint = pdu_size - MLRPC_RSP_HDR_SIZE; mlnds->pdu_scan_offset = 0; (void) mlrpc_encode_pdu_hdr(mxa); /* * We need to update the 24-byte header in subsequent fragments. * * pdu_data_size: total data remaining to be handled * frag_size: total fragment size including header * frag_data_size: data in fragment * (i.e. frag_size - MLRPC_RSP_HDR_SIZE) */ pdu_data_size = pdu_size - MLRPC_RSP_HDR_SIZE; frag_data_size = frag_size - MLRPC_RSP_HDR_SIZE; num_ext_frags = pdu_data_size / frag_data_size; /* * We may need to stretch the pipe and insert an RPC header * at each frag boundary. The response will get chunked into * xdrlen sizes for each trans request. */ mlnds->pdu_base_addr_with_rpc_hdrs = malloc(pdu_size + (num_ext_frags * MLRPC_RSP_HDR_SIZE)); mlnds->pdu_size_with_rpc_hdrs = mlnds->pdu_size + (num_ext_frags * MLRPC_RSP_HDR_SIZE); /* * Start stretching loop. */ bcopy(mlnds->pdu_base_addr, mlnds->pdu_base_addr_with_rpc_hdrs, frag_size); /*LINTED E_BAD_PTR_CAST_ALIGN*/ rpc_hdr = (mlrpcconn_common_header_t *) mlnds->pdu_base_addr_with_rpc_hdrs; rpc_hdr->pfc_flags = MLRPC_PFC_FIRST_FRAG; rem_dlen = pdu_data_size - frag_size; bytesoff = frag_size; cnt = 1; while (num_ext_frags--) { /* first copy the RPC header to the front of the frag */ bcopy(mlnds->pdu_base_addr, mlnds->pdu_base_addr_with_rpc_hdrs + (cnt * frag_size), MLRPC_RSP_HDR_SIZE); /* then copy the data portion of the frag */ save_rem_dlen = rem_dlen; if (rem_dlen >= (frag_size - MLRPC_RSP_HDR_SIZE)) { rem_dlen = rem_dlen - frag_size + MLRPC_RSP_HDR_SIZE; obytes = frag_size - MLRPC_RSP_HDR_SIZE; } else { last_frag = 1; /* this is the last one */ obytes = rem_dlen; } frag_startp = mlnds->pdu_base_addr_with_rpc_hdrs + (cnt * frag_size); bcopy(mlnds->pdu_base_addr + bytesoff, frag_startp + MLRPC_RSP_HDR_SIZE, obytes); /* set the FRAG FLAGS in the frag header spot */ /*LINTED E_BAD_PTR_CAST_ALIGN*/ rpc_hdr = (mlrpcconn_common_header_t *)frag_startp; if (last_frag) { rpc_hdr->frag_length = save_rem_dlen; rpc_hdr->pfc_flags = MLRPC_PFC_LAST_FRAG; } else { rpc_hdr->pfc_flags = 0; } bytesoff += (frag_size - MLRPC_RSP_HDR_SIZE); cnt++; } return (0); }