FreeCalypso > hg > fc-magnetite
view src/g23m-gprs/sm/sm_tft.c @ 258:13bcc2ed7e44
configure.sh & targets/*.conf: emit FLASH_BASE_ADDR & FLASH_SECTOR_SIZE
into the generated Makefile
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Fri, 04 Aug 2017 07:14:16 +0000 |
parents | 219afcfc6250 |
children |
line wrap: on
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/*---------------------------------------------------------------------------- | Project : 3G PS | Module : SM +----------------------------------------------------------------------------- | Copyright 2003 Texas Instruments. | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments . | The receipt of or possession of this file does not convey | any rights to reproduce or disclose its contents or to | manufacture, use, or sell anything it may describe, in | whole, or in part, without the specific written consent of | Texas Instruments. +----------------------------------------------------------------------------- | Purpose: 3G TFT utility functions implementation in the SM entity. | For design details, see: | 8010.908 SM Detailed Specification +---------------------------------------------------------------------------*/ /*==== DECLARATION CONTROL =================================================*/ /*==== INCLUDES ============================================================*/ #include "sm.h" #include "sm_tft.h" /*==== CONST ===============================================================*/ /*==== LOCAL VARS ===========================================================*/ /*==== PRIVATE FUNCTIONS ====================================================*/ /* +------------------------------------------------------------------------------ | Function : sm_tft_count_tfts_in_mask +------------------------------------------------------------------------------ | Description : Returns the number of filters (set bits) in a TFT mask. | | Parameters : tft_mask - TFT mask +------------------------------------------------------------------------------ */ static U8 sm_tft_count_tfts_in_mask(U8 tft_mask) /*@*/ { U8 count_array[16] = { (U8)0 /* 0000 */, (U8)1 /* 0001 */, (U8)1 /* 0010 */, (U8)2 /* 0011 */, (U8)1 /* 0100 */, (U8)2 /* 0101 */, (U8)2 /* 0110 */, (U8)3 /* 0111 */, (U8)1 /* 1000 */, (U8)2 /* 1001 */, (U8)2 /* 1010 */, (U8)3 /* 1011 */, (U8)2 /* 1100 */, (U8)3 /* 1101 */, (U8)3 /* 1110 */, (U8)4 /* 1111 */ }; return (count_array[(U16)tft_mask >> 4] + count_array[(U16)tft_mask & 15]); } /* +------------------------------------------------------------------------------ | Function : sm_tft_is_tft_in_mask +------------------------------------------------------------------------------ | Description : Returns TRUE if the TFT with the specified ID (bit) is | set in the specified TFT mask. | | Parameters : id - TFT identifier | tft_mask - TFT mask +------------------------------------------------------------------------------ */ static BOOL sm_tft_is_tft_in_mask(U8 id, U8 tft_mask) /*@*/ { return ((tft_mask & (1UL << id)) != 0); } /* +------------------------------------------------------------------------------ | Function : sm_tft_is_port_range +------------------------------------------------------------------------------ | Description : Query function returning TRUE if high_limit is not zero, and | high_limit is greater than (but not equal) to low_limit. | | Parameters : low_limit - lower port limit | high_limit - upper port limit +------------------------------------------------------------------------------ */ static BOOL sm_tft_is_port_range(U16 low_limit, U16 high_limit) { return (high_limit != 0 && low_limit < high_limit); } static /*@exposed@*/T_NAS_tft_pf * sm_tft_get_active_tft_by_id(/*@returned@*/ /*@partial@*/struct T_SM_CONTEXT_DATA *context, U8 id) { TRACE_ASSERT(id < (U8)NAS_SIZE_TFT_FILTER); TRACE_ASSERT(context->active_tft.ptr_tft_pf != NULL); return (&context->active_tft.ptr_tft_pf[id]); } /* +------------------------------------------------------------------------------ | Function : sm_tft_pf_size +------------------------------------------------------------------------------ | Description : Query function returning the packed size of a packet filter. | | Parameters : tft_pf - packet filter +------------------------------------------------------------------------------ */ static U16 sm_tft_pf_size(T_NAS_tft_pf *tft_pf) { U16 tft_pf_size = (U16)3; /* Filter ID, precedence and length octet mandatory */ U16 lower3bits[8] = { (U16) 0, /* 0x00: None */ (U16) 9, /* 0x01: IPv4_SRC_ADDR_MASK */ (U16) 33, /* 0x02: IPv6_SRC_ADDR_MASK */ (U16) 0, /* 0x03: IPv4_SRC_ADDR_MASK + IPv6_SRC_ADDR_MASK -- INVALID! */ (U16) 3, /* 0x04: PROTOCOL_OR_NEXT_HDR */ (U16) 12, /* 0x05: IPv4_SRC_ADDR_MASK + PROTOCOL_OR_NEXT_HDR */ (U16) 36, /* 0x06: IPv6_SRC_ADDR_MASK + PROTOCOL_OR_NEXT_HDR */ (U16) 0 /* 0x07: IPv4_SRC_ADDR_MASK + IPv6_SRC_ADDR_MASK + PROTOCOL_OR_NEXT_HDR -- INVALID! */ }; U16 upper3bits[8] = { (U16) 0, /* 0x00: None */ (U16) 5, /* 0x20: IPSEC_SPI */ (U16) 3, /* 0x40: TOS_AND_MASK */ (U16) 5, /* 0x60: IPSEC_SPI + TOS_AND_MASK */ (U16) 4, /* 0x80: FLOW_LABEL */ (U16) 0, /* 0xa0: IPSEC_SPI + FLOW_LABEL - INVALID! */ (U16) 7, /* 0xc0: TOS_AND_MASK + FLOW_LABEL */ (U16) 0 /* 0xe0: IPSEC_SPI + TOS_AND_MASK + FLOW_LABEL - INVALID! */ }; if ((tft_pf->tft_pf_valid_bits & (U8)0x07) != (U8)0) { tft_pf_size += lower3bits[(U16)tft_pf->tft_pf_valid_bits & 0x07]; } if ((tft_pf->tft_pf_valid_bits & (U8)0xe0) != (U8)0) { tft_pf_size += upper3bits[(U16)tft_pf->tft_pf_valid_bits >> 5]; } if ((tft_pf->tft_pf_valid_bits & (U8)NAS_TFT_ID_DEST_PORT_RANGE) != (U8)0) { T_NAS_tft_dest_port_range *range = &tft_pf->tft_pf_entry.tft_pf_ipv4.tft_dest_port_range; if (sm_tft_is_port_range(range->low_limit, range->high_limit)) { tft_pf_size += (U16)5; /* Destination port range */ } else { tft_pf_size += (U16)3; /* Single destination port */ } } if ((tft_pf->tft_pf_valid_bits & (U8)NAS_TFT_ID_SRC_PORT_RANGE) != (U8)0) { T_NAS_tft_src_port_range *range = &tft_pf->tft_pf_entry.tft_pf_ipv4.tft_src_port_range; if (sm_tft_is_port_range(range->low_limit, range->high_limit)) { tft_pf_size += (U16)5; /* Source port range */ } else { tft_pf_size += (U16)3; /* Single source port */ } } return tft_pf_size; } /* +------------------------------------------------------------------------------ | Function : sm_tft_are_equal +------------------------------------------------------------------------------ | Description : Query function returning TRUE if the two input packet filters | are equal (same parameters). | | Parameters : tft1 - packet filter 1 | tft2 - packet filter 2 +------------------------------------------------------------------------------ */ static BOOL sm_tft_are_equal(T_NAS_tft_pf *tft1, T_NAS_tft_pf *tft2) { U8 valid_bits; /* Compare outer-level parameters */ if (tft1->tft_pf_id != tft2->tft_pf_id || tft1->tft_pf_precedence != tft2->tft_pf_precedence || tft1->tft_pf_valid_bits != tft2->tft_pf_valid_bits || tft1->ctrl_tft_pf_entry != tft2->ctrl_tft_pf_entry) { return FALSE; } valid_bits = tft1->tft_pf_valid_bits; if (tft1->ctrl_tft_pf_entry == NAS_is_tft_pf_ipv4) { T_NAS_tft_pf_ipv4 *v4_pf_1 = &tft1->tft_pf_entry.tft_pf_ipv4; T_NAS_tft_pf_ipv4 *v4_pf_2 = &tft2->tft_pf_entry.tft_pf_ipv4; if (((valid_bits & (U8)NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR) != (U8)0 && v4_pf_1->tft_protocol != v4_pf_2->tft_protocol) || ((valid_bits & (U8)NAS_TFT_ID_TOS_AND_MASK) != (U8)0 && v4_pf_1->tft_tos_and_mask.tos_value != v4_pf_2->tft_tos_and_mask.tos_value && v4_pf_1->tft_tos_and_mask.tos_mask != v4_pf_2->tft_tos_and_mask.tos_mask) || ((valid_bits & (U8)NAS_TFT_ID_DEST_PORT_RANGE) != (U8)0 && memcmp(&v4_pf_1->tft_dest_port_range, &v4_pf_2->tft_dest_port_range, sizeof(T_NAS_tft_dest_port_range)) != 0) || ((valid_bits & (U8)NAS_TFT_ID_SRC_PORT_RANGE) != (U8)0 && memcmp(&v4_pf_1->tft_src_port_range, &v4_pf_2->tft_src_port_range, sizeof(T_NAS_tft_src_port_range)) != 0) || ((valid_bits & (U8)NAS_TFT_ID_IPSEC_SPI) != (U8)0 && v4_pf_1->tft_ipsec_spi != v4_pf_2->tft_ipsec_spi) || ((valid_bits & (U8)NAS_TFT_ID_IPv4_SRC_ADDR_MASK) != (U8)0 && memcmp(&v4_pf_1->tft_ipv4_src_addr_mask, &v4_pf_2->tft_ipv4_src_addr_mask, sizeof(T_NAS_tft_ipv4_src_addr_mask)) != 0)) { return FALSE; } } else if (tft1->ctrl_tft_pf_entry == NAS_is_tft_pf_ipv6) { T_NAS_tft_pf_ipv6 *v6_pf_1 = &tft1->tft_pf_entry.tft_pf_ipv6; T_NAS_tft_pf_ipv6 *v6_pf_2 = &tft2->tft_pf_entry.tft_pf_ipv6; if (((valid_bits & (U8)NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR) != (U8)0 && v6_pf_1->tft_next_hdr != v6_pf_2->tft_next_hdr) || ((valid_bits & (U8)NAS_TFT_ID_TOS_AND_MASK) != (U8)0 && v6_pf_1->tft_tos_and_mask.tos_value != v6_pf_2->tft_tos_and_mask.tos_value && v6_pf_1->tft_tos_and_mask.tos_mask != v6_pf_2->tft_tos_and_mask.tos_mask) || ((valid_bits & (U8)NAS_TFT_ID_DEST_PORT_RANGE) != (U8)0 && memcmp(&v6_pf_1->tft_dest_port_range, &v6_pf_2->tft_dest_port_range, sizeof(T_NAS_tft_dest_port_range)) != 0) || ((valid_bits & (U8)NAS_TFT_ID_SRC_PORT_RANGE) != (U8)0 && memcmp(&v6_pf_1->tft_src_port_range, &v6_pf_2->tft_src_port_range, sizeof(T_NAS_tft_src_port_range)) != 0) || ((valid_bits & (U8)NAS_TFT_ID_IPSEC_SPI) != (U8)0 && v6_pf_1->tft_ipsec_spi != v6_pf_2->tft_ipsec_spi) || ((valid_bits & (U8)NAS_TFT_ID_FLOW_LABEL) != (U8)0 && v6_pf_1->tft_flow_label != v6_pf_2->tft_flow_label) || ((valid_bits & (U8)NAS_TFT_ID_IPv6_SRC_ADDR_MASK) != (U8)0 && memcmp(&v6_pf_1->tft_ipv6_src_addr_mask, &v6_pf_2->tft_ipv6_src_addr_mask, sizeof(T_NAS_tft_ipv6_src_addr_mask)) != 0)) { return FALSE; } } else { (void)TRACE_EVENT_P1("ERROR: Invalid union controller %d in ctrl_tft_pf_entry!", tft1->ctrl_tft_pf_entry); } return TRUE; } /* +------------------------------------------------------------------------------ | Function : sm_tft_copy_ipv4_pf +------------------------------------------------------------------------------ | Description : Copies an IPv4 TFT filter from src_tft to dst_tft AIM struct. | | Parameters : dst_tft - destination aim TFT structs | src_tft - source TFT structs | valid_flag - valid flags for filter components +------------------------------------------------------------------------------ */ static void sm_tft_copy_ipsec_spi(/*@out@*/T_M_SM_tft_ipsec_spi *dst_spi, U32 spi) { M_SM_BUF_ipsec_spi_value *dst = &dst_spi->ipsec_spi_value; #ifdef TFT_DEBUG (void)TRACE_EVENT_P1("tft_copy: Copying IPSEC SPI filter (SPI 0x%08x)", spi); #endif dst->l_ipsec_spi_value = (U16)32; dst->o_ipsec_spi_value = (U16)0; dst->b_ipsec_spi_value[0] = (U8)((spi >> 24) & 255); dst->b_ipsec_spi_value[1] = (U8)((spi >> 16) & 255); dst->b_ipsec_spi_value[2] = (U8)((spi >> 8) & 255); dst->b_ipsec_spi_value[3] = (U8)( spi & 255); } static void sm_tft_copy_ipv4_pf(/*@out@*/ T_M_SM_tft_filter_entry *dst, T_NAS_tft_pf_ipv4 *src, U8 valid_flag) { /* Copy IPv4 address, if present */ if ((valid_flag & NAS_TFT_ID_IPv4_SRC_ADDR_MASK) != (U8)0) { dst->v_tft_ipv4_addr_mask = (U8)TRUE; memcpy(dst->tft_ipv4_addr_mask.src_addr, src->tft_ipv4_src_addr_mask.tft_ipv4_addr, (size_t)NAS_SIZE_IPv4_ADDR); memcpy(dst->tft_ipv4_addr_mask.addr_mask, src->tft_ipv4_src_addr_mask.tft_ipv4_mask, (size_t)NAS_SIZE_IPv4_ADDR); #ifdef TFT_DEBUG { U8 *addr, *mask; addr = dst->tft_ipv4_addr_mask.src_addr; mask = dst->tft_ipv4_addr_mask.addr_mask; (void)TRACE_EVENT_P8("tft_copy: Copy IPv4 src addr/mask filter: " "%u.%u.%u.%u/%u.%u.%u.%u", addr[0], addr[1], addr[2], addr[3], mask[0], mask[1], mask[2], mask[3]); } #endif } else { dst->v_tft_ipv4_addr_mask = (U8)FALSE; } /* NAS_TFT_ID_IPv4_SRC_ADDR_MASK */ /* IPv6 addr/mask never invluded in IPv4 packet filter */ dst->v_tft_ipv6_addr_mask = (U8)FALSE; /* Copy IPv4 protocol number field */ if ((valid_flag & NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR) != (U8)0) { dst->v_tft_protocol = (U8)TRUE; dst->tft_protocol.tft_protocol_val = src->tft_protocol; #ifdef TFT_DEBUG (void)TRACE_EVENT_P1("tft_copy: Copy IPv4 protocol: 0x%02x", src->tft_protocol); #endif } else { dst->v_tft_protocol = (U8)FALSE; } /* NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR */ /* Copy destination single port/port range parameter */ if ((valid_flag & NAS_TFT_ID_DEST_PORT_RANGE) != (U8)0) { T_NAS_tft_dest_port_range *port_range = &src->tft_dest_port_range; if (sm_tft_is_port_range(port_range->low_limit, port_range->high_limit)) { dst->v_tft_dest_port_range = (U8)TRUE; dst->v_tft_dest_port = (U8)FALSE; dst->tft_dest_port_range.low_limit = port_range->low_limit; dst->tft_dest_port_range.high_limit = port_range->high_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P2("tft_copy: Copying destination port range filter (ports %d-%d)", port_range->low_limit, port_range->high_limit); #endif } else { dst->v_tft_dest_port_range = (U8)FALSE; dst->v_tft_dest_port = (U8)TRUE; dst->tft_dest_port.low_limit = port_range->low_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P1("tft_copy: Copying single destination port filter (port %d)", port_range->low_limit); #endif } } else { dst->v_tft_dest_port_range = (U8)FALSE; dst->v_tft_dest_port = (U8)FALSE; } /* NAS_TFT_ID_DEST_PORT_RANGE */ /* Copy source single port/port range parameter */ if ((valid_flag & NAS_TFT_ID_SRC_PORT_RANGE) != (U8)0) { T_NAS_tft_src_port_range *port_range = &src->tft_src_port_range; if (sm_tft_is_port_range(port_range->low_limit, port_range->high_limit)) { dst->v_tft_src_port_range = (U8)TRUE; dst->v_tft_src_port = (U8)FALSE; dst->tft_src_port_range.low_limit = port_range->low_limit; dst->tft_src_port_range.high_limit = port_range->high_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P2("tft_copy: Copying source port range filter (ports %d-%d)", port_range->low_limit, port_range->high_limit); #endif } else { dst->v_tft_src_port_range = (U8)FALSE; dst->v_tft_src_port = (U8)TRUE; dst->tft_src_port.low_limit = port_range->low_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P1("tft_copy: Copying single source port filter (port %d)", port_range->low_limit); #endif } } else { dst->v_tft_src_port_range = (U8)FALSE; dst->v_tft_src_port = (U8)FALSE; } /* NAS_TFT_ID_SRC_PORT_RANGE */ if ((valid_flag & NAS_TFT_ID_IPSEC_SPI) != (U8)0) { dst->v_tft_ipsec_spi = (U8)TRUE; sm_tft_copy_ipsec_spi(&dst->tft_ipsec_spi, src->tft_ipsec_spi); } else { dst->v_tft_ipsec_spi = (U8)FALSE; }/* NAS_TFT_ID_IPSEC_SPI */ if ((valid_flag & NAS_TFT_ID_TOS_AND_MASK) != (U8)0) { dst->v_tft_tos_and_mask = (U8)TRUE; dst->tft_tos_and_mask.tos_value = src->tft_tos_and_mask.tos_value; dst->tft_tos_and_mask.tos_mask = src->tft_tos_and_mask.tos_mask; } else { dst->v_tft_tos_and_mask = (U8)FALSE; } /* NAS_TFT_ID_TOS_AND_MASK */ if ((valid_flag & NAS_TFT_ID_FLOW_LABEL) != (U8)0) { (void)TRACE_ERROR("tft_copy: Found flow label in IPv4 packet filter - Discarded..."); } /* NAS_TFT_ID_FLOW_LABEL */ dst->v_tft_flow_label = (U8)FALSE; } /* +------------------------------------------------------------------------------ | Function : sm_tft_copy_ipv6_pf +------------------------------------------------------------------------------ | Description : Copies an IPv6 TFT filter from src_tft to dst_tft AIM struct. | | Parameters : dst_tft - destination aim TFT structs | src_tft - source TFT structs | valid_flag - valid flags for filter components +------------------------------------------------------------------------------ */ static void sm_tft_copy_ipv6_pf(/*@out@*/ T_M_SM_tft_filter_entry *dst, T_NAS_tft_pf_ipv6 *src, U8 valid_flag) { /* IPv4 addr/mask never invluded in IPv4 packet filter */ dst->v_tft_ipv4_addr_mask = (U8)FALSE; /* Copy IPv6 address, if present */ if ((valid_flag & NAS_TFT_ID_IPv6_SRC_ADDR_MASK) != (U8)0) { dst->v_tft_ipv6_addr_mask = (U8)TRUE; memcpy(dst->tft_ipv6_addr_mask.src_addr, src->tft_ipv6_src_addr_mask.tft_ipv6_addr, (size_t)NAS_SIZE_IPv6_ADDR); memcpy(dst->tft_ipv6_addr_mask.addr_mask, src->tft_ipv6_src_addr_mask.tft_ipv6_mask, (size_t)NAS_SIZE_IPv6_ADDR); #ifdef TFT_DEBUG /* Dump address/mask */ { char addr[SM_SIZE_FORMATTED_IPv6_ADDR], mask[SM_SIZE_FORMATTED_IPv6_ADDR]; (void)TRACE_EVENT_P2("tft_copy: Copy IPv6 src addr/mask filter: %s/%s", sm_format_ipv6_addr(dst->tft_ipv6_addr_mask.src_addr, addr), sm_format_ipv6_addr(dst->tft_ipv6_addr_mask.addr_mask, mask)); } #endif } else { dst->v_tft_ipv6_addr_mask = (U8)FALSE; } /* NAS_TFT_ID_IPv6_SRC_ADDR_MASK */ /* Copy IPv6 next header field */ if ((valid_flag & NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR) != (U8)0) { dst->v_tft_protocol = (U8)TRUE; dst->tft_protocol.tft_protocol_val = src->tft_next_hdr; #ifdef TFT_DEBUG (void)TRACE_EVENT_P1("tft_copy: Copy IPv6 next header field: 0x%02x", src->tft_next_hdr); #endif } else { dst->v_tft_protocol = (U8)FALSE; } /* NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR */ /* Copy destination single port/port range parameter */ if ((valid_flag & NAS_TFT_ID_DEST_PORT_RANGE) != (U8)0) { T_NAS_tft_dest_port_range *port_range = &src->tft_dest_port_range; if (sm_tft_is_port_range(port_range->low_limit, port_range->high_limit)) { dst->v_tft_dest_port_range = (U8)TRUE; dst->v_tft_dest_port = (U8)FALSE; dst->tft_dest_port_range.low_limit = port_range->low_limit; dst->tft_dest_port_range.high_limit = port_range->high_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P2("tft_copy: Copying destination port range filter (ports %d-%d)", port_range->low_limit, port_range->high_limit); #endif } else { dst->v_tft_dest_port_range = (U8)FALSE; dst->v_tft_dest_port = (U8)TRUE; dst->tft_dest_port.low_limit = port_range->low_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P1("tft_copy: Copying single destination port filter (port %d)", port_range->low_limit); #endif } } else { dst->v_tft_dest_port_range = (U8)FALSE; dst->v_tft_dest_port = (U8)FALSE; } /* NAS_TFT_ID_DEST_PORT_RANGE */ /* Copy source single port/port range parameter */ if ((valid_flag & NAS_TFT_ID_SRC_PORT_RANGE) != (U8)0) { T_NAS_tft_src_port_range *port_range = &src->tft_src_port_range; if (sm_tft_is_port_range(port_range->low_limit, port_range->high_limit)) { dst->v_tft_src_port_range = (U8)TRUE; dst->v_tft_src_port = (U8)FALSE; dst->tft_src_port_range.low_limit = port_range->low_limit; dst->tft_src_port_range.high_limit = port_range->high_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P2("tft_copy: Copying source port range filter (ports %d-%d)", port_range->low_limit, port_range->high_limit); #endif } else { dst->v_tft_src_port_range = (U8)FALSE; dst->v_tft_src_port = (U8)TRUE; dst->tft_src_port.low_limit = port_range->low_limit; #ifdef TFT_DEBUG (void)TRACE_EVENT_P1("tft_copy: Copying single source port filter (port %d)", port_range->low_limit); #endif } } else { dst->v_tft_src_port_range = (U8)FALSE; dst->v_tft_src_port = (U8)FALSE; } /* NAS_TFT_ID_SRC_PORT_RANGE */ if ((valid_flag & NAS_TFT_ID_IPSEC_SPI) != (U8)0) { dst->v_tft_ipsec_spi = (U8)TRUE; sm_tft_copy_ipsec_spi(&dst->tft_ipsec_spi, src->tft_ipsec_spi); } else { dst->v_tft_ipsec_spi = (U8)FALSE; } /* NAS_TFT_ID_IPSEC_SPI */ if ((valid_flag & NAS_TFT_ID_TOS_AND_MASK) != (U8)0) { dst->v_tft_tos_and_mask = (U8)TRUE; dst->tft_tos_and_mask.tos_value = src->tft_tos_and_mask.tos_value; dst->tft_tos_and_mask.tos_mask = src->tft_tos_and_mask.tos_mask; } else { dst->v_tft_tos_and_mask = (U8)FALSE; } /* NAS_TFT_ID_TOS_AND_MASK */ if ((valid_flag & NAS_TFT_ID_FLOW_LABEL) != (U8)0) { dst->v_tft_flow_label = (U8)TRUE; dst->tft_flow_label.flow_label_value = src->tft_flow_label; } else { dst->v_tft_flow_label = (U8)FALSE; } /* NAS_TFT_ID_FLOW_LABEL */ } /* +------------------------------------------------------------------------------ | Function : sm_tft_copy_filters +------------------------------------------------------------------------------ | Description : Copies TFT filters from src_tft to dst_tft AIM structs. | | Parameters : dst_tft - destination aim TFT structs | src_tft - source TFT structs | tft_mask - TFT mask (determines which TFTs to consider) +------------------------------------------------------------------------------ */ static U8 sm_tft_copy_filters(/*@special@*/T_M_SM_tft *dst_tft, /*@in@*/ T_NAS_tft_pf *src_tft, U8 max_count, U8 tft_mask) { int i, count; T_M_SM_tft_filter *dst; U16 size, total_size = 0; U8 change_mask = (U8)0; dst_tft->v_tft_filter = (U8)TRUE; /* Initialize pointer to air interface TFT */ dst = dst_tft->tft_filter; for (i = 0, count = 0; i < (int)max_count; i++) { if (sm_tft_is_tft_in_mask(src_tft->tft_pf_id, tft_mask)) { size = sm_tft_pf_size(src_tft); /* Only include packet filter, if it fits in air interface message */ if (total_size + size > (U16)255) { break; } dst->tft_filter_id = src_tft->tft_pf_id; dst->tft_filter_prio = src_tft->tft_pf_precedence; if (src_tft->ctrl_tft_pf_entry == NAS_is_tft_pf_ipv4) { sm_tft_copy_ipv4_pf(&dst->tft_filter_entry, &src_tft->tft_pf_entry.tft_pf_ipv4, src_tft->tft_pf_valid_bits); } else if (src_tft->ctrl_tft_pf_entry == NAS_is_tft_pf_ipv6) { sm_tft_copy_ipv6_pf(&dst->tft_filter_entry, &src_tft->tft_pf_entry.tft_pf_ipv6, src_tft->tft_pf_valid_bits); } else { (void)TRACE_EVENT_P1("tft_copy: ERROR! Wrong union controller (%d) " "for tft_pf_entry; discarded...", src_tft->ctrl_tft_pf_entry); } /* Update change mask and total TFT size */ change_mask |= (U8)(1UL << dst->tft_filter_id); total_size += size; /* Advance to next destination TFT */ dst++; count++; } /* if (sm_tft_is_tft_in_mask()) */ /* Skip to next input TFT */ src_tft++; } dst_tft->c_tft_filter = (U8)count; return change_mask; } /* +------------------------------------------------------------------------------ | Function : sm_tft_copy_filter_numbers +------------------------------------------------------------------------------ | Description : Copies filter IDs to dst_tft AIM struct (derived from tft_mask) | | Parameters : dst_tft - destination aim TFT structs | tft_mask - TFT mask (determines which TFTs to consider) +------------------------------------------------------------------------------ */ static void sm_tft_copy_filter_numbers(/*@special@*/T_M_SM_tft *dst_tft, U8 tft_mask) { int index, dst_idx; dst_tft->v_tft_filter_id = (U8)TRUE; for (index = 0, dst_idx = 0; index < (int)NAS_SIZE_TFT_FILTER; index++) { if (sm_tft_is_tft_in_mask((U8)index, tft_mask)) { dst_tft->tft_filter_id[dst_idx] = (U8)index; dst_idx++; } } /* for */ /* Set counter to the number of filters numbers inserted */ dst_tft->c_tft_filter_id = (U8)dst_idx; } /* +------------------------------------------------------------------------------ | Function : sm_tft_update_active_tft +------------------------------------------------------------------------------ | Description : Update context data structure with new active TFT as it would | be would the modification succeed. | | Parameters : context - context data | tft_mask - TFT mask (determines which TFTs to consider) +------------------------------------------------------------------------------ */ static void sm_tft_update_active_tft(/*@special@*/struct T_SM_CONTEXT_DATA *context, U8 change_mask) { T_NAS_tft_pf *req_tft, *act_tft; U16 index; U8 req_mask, act_mask, add_mask, delete_mask; req_mask = context->requested_tft.tft_precence_mask; act_mask = context->active_tft.tft_precence_mask; add_mask = req_mask & change_mask; delete_mask = (U8)(0xffUL ^ req_mask) & change_mask; if (req_mask == (U8)0) { sm_nw_free_active_tft(context); return; } TRACE_ASSERT(context->requested_tft.ptr_tft_pf != NULL); /* Allocate active TFT memory, if required */ if (act_mask == (U8)0 && /*req_mask != (U8)0 &&*/ /*commented out because of previous return*/ context->active_tft.ptr_tft_pf == NULL) { sm_nw_allocate_active_tft(context); TRACE_ASSERT(context->active_tft.ptr_tft_pf != NULL); } /* Loop over TFTs, in order to find any TFTs to delete */ for (index = 0; index < (U16)NAS_SIZE_TFT_FILTER; index++) { if (sm_tft_is_tft_in_mask((U8)index, delete_mask)) { /* Was filter removed ? If so, clear filter from mask and store */ act_mask &= (U8)(0xffUL ^ 1UL << index); act_tft = sm_tft_get_active_tft_by_id(context, (U8)index); memset(act_tft, 0, sizeof(T_NAS_tft_pf)); } } for (index = 0, req_tft = context->requested_tft.ptr_tft_pf; index < (U16)context->requested_tft.c_tft_pf; index++, req_tft++) { U8 pf_id = req_tft->tft_pf_id; if (sm_tft_is_tft_in_mask(pf_id, add_mask)) { /* Copy any remaining requested TFTs into active TFT */ act_mask |= (U8)(1UL << pf_id); act_tft = sm_tft_get_active_tft_by_id(context, pf_id); memcpy(act_tft, req_tft, sizeof(T_NAS_tft_pf)); } } /* for */ context->active_tft.tft_precence_mask = act_mask; context->active_tft.c_tft_pf = sm_tft_count_tfts_in_mask(act_mask); } /* +------------------------------------------------------------------------------ | Function : sm_tft_next_action +------------------------------------------------------------------------------ | Description : Determines the next action to perform (opcode) on the TFTs | for a context, and the filters affected. | (8 upper bits is change mask; 8 lower bits is opcode) | | Parameters : context - context data +------------------------------------------------------------------------------ */ static U16 sm_tft_next_action(struct T_SM_CONTEXT_DATA *context) { U8 req_mask, act_mask, missing_mask, surplus_mask, replace_mask; U16 index; req_mask = context->requested_tft.tft_precence_mask; act_mask = context->active_tft.tft_precence_mask; /* If requested TFT contains 0 filters, remove TFT altogether */ if (context->requested_tft.c_tft_pf == (U8)0) { return (U16)M_SM_TFT_OPCODE_DELETE_TFT; } TRACE_ASSERT(context->requested_tft.ptr_tft_pf != NULL); /* If there are no activate TFT filters, and requested != 0, create new TFT */ if (act_mask == (U8)0 && req_mask != (U8)0) { return (U16)M_SM_TFT_OPCODE_CREATE_TFT | (U16)req_mask << 8; } /* Add filters, if requested filter count > active filter count or * requested filters exist, that are not active. */ missing_mask = req_mask & (0xff ^ act_mask); if (context->requested_tft.c_tft_pf > context->active_tft.c_tft_pf || missing_mask != (U8)0) { return (U16)M_SM_TFT_OPCODE_ADD_FILTERS | (U16)missing_mask << 8; } /* Delete filters, if requested filter count < active filter count or * active filters exist, that are not requested. */ surplus_mask = act_mask & (0xff ^ req_mask); if (context->requested_tft.c_tft_pf < context->active_tft.c_tft_pf || surplus_mask != (U8)0) { return (U16)M_SM_TFT_OPCODE_DELETE_FILTERS | (U16)surplus_mask << 8; } /* Now, requested and active TFTs have the same filter *numbers* active; * We then need to check, whether the *contents* of the filters that * have the same number also match. */ for (index = 0, replace_mask = (U8)0; index < (U16)context->requested_tft.c_tft_pf; index++) { T_NAS_tft_pf *req_tft = &context->requested_tft.ptr_tft_pf[index]; T_NAS_tft_pf *act_tft = sm_tft_get_active_tft_by_id(context, req_tft->tft_pf_id); if (!sm_tft_are_equal(req_tft, act_tft)) { replace_mask |= (U8)(1UL << req_tft->tft_pf_id); } } if (replace_mask != (U8)0) { return (U16)M_SM_TFT_OPCODE_REPLACE_FILTERS | (U16)replace_mask << 8; } /* Error. Nothing to change, or invalid configuration */ return (U16)M_SM_TFT_OPCODE_SPARE; } /*==== PUBLIC FUNCTIONS =====================================================*/ U8 sm_tft_precence_mask(T_NAS_tft_pf *tft, U8 count) { U16 index; U8 precence_mask = (U8)0; for (index = 0; index < (U16)count; index++) { precence_mask |= (1UL << tft[index].tft_pf_id); } return precence_mask; } void sm_tft_convert_to_aim(struct T_SM_CONTEXT_DATA *context, /*@out@*/ T_M_SM_tft *dst_tft) { U8 opcode, filter_mask, change_mask, max_count; U16 opcode_and_mask; T_NAS_tft_pf *src_tft = context->requested_tft.ptr_tft_pf; max_count = context->requested_tft.c_tft_pf; if (src_tft == NULL) { return; } opcode_and_mask = sm_tft_next_action(context); opcode = (U8)(opcode_and_mask & 0xff); filter_mask = (U8)(opcode_and_mask >> 8); dst_tft->tft_opcode = opcode; switch (opcode) { case M_SM_TFT_OPCODE_CREATE_TFT: case M_SM_TFT_OPCODE_ADD_FILTERS: case M_SM_TFT_OPCODE_REPLACE_FILTERS: TRACE_ASSERT(src_tft != NULL); /* Copy filter count to air interface message TFT struct */ change_mask = sm_tft_copy_filters(dst_tft, src_tft, max_count, filter_mask); sm_tft_update_active_tft(context, change_mask); dst_tft->tft_filter_count = sm_tft_count_tfts_in_mask(change_mask); break; case M_SM_TFT_OPCODE_DELETE_TFT: /* * DELETE TFT can have no fields other than TFT opcode and * filter count (== 0), and is thus complete. */ context->requested_tft.tft_precence_mask = (U8)0; sm_tft_update_active_tft(context, (U8)0xff); dst_tft->tft_filter_count = (U8)0; break; case M_SM_TFT_OPCODE_DELETE_FILTERS: TRACE_ASSERT(src_tft != NULL); /* Copy filter count to air interface message TFT struct */ sm_tft_copy_filter_numbers(dst_tft, filter_mask); sm_tft_update_active_tft(context, filter_mask); dst_tft->tft_filter_count = sm_tft_count_tfts_in_mask(filter_mask); break; default: (void)TRACE_EVENT_P1("tft_convert_to_aim: ERROR!" "Invalid opcode (%d) - TFT skipped!", opcode); break; } } BOOL sm_tft_more_to_modify(struct T_SM_CONTEXT_DATA *context) { int filter; (void)TRACE_FUNCTION("sm_tft_more_to_modify"); if (context->requested_tft.c_tft_pf != context->active_tft.c_tft_pf || context->requested_tft.tft_precence_mask != context->active_tft.tft_precence_mask) { return TRUE; } if (context->requested_tft.c_tft_pf > (U8)0 && context->requested_tft.ptr_tft_pf != NULL && context->active_tft.ptr_tft_pf != NULL) { for (filter = 0; filter < (int)context->requested_tft.c_tft_pf; filter++) { if (!sm_tft_are_equal(&context->requested_tft.ptr_tft_pf[filter], sm_tft_get_active_tft_by_id(context, context->requested_tft.ptr_tft_pf[filter].tft_pf_id))) { return TRUE; } } /* for */ } /* if (c_tft_pf > 0) */ return FALSE; }