/* * (C) 2012 by Pablo Neira Ayuso * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published * by the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This code has been sponsored by Sophos Astaro */ #include #include #include #include #include #include #include #include #include #include #include #include #include "internal.h" #ifdef JSON_PARSING static int nft_data_reg_verdict_json_parse(union nft_data_reg *reg, json_t *data, struct nft_parse_err *err) { int verdict; const char *verdict_str; const char *chain; verdict_str = nft_jansson_parse_str(data, "verdict", err); if (verdict_str == NULL) return DATA_NONE; if (nft_str2verdict(verdict_str, &verdict) != 0) { err->node_name = "verdict"; err->error = NFT_PARSE_EBADTYPE; errno = EINVAL; return -1; } reg->verdict = (uint32_t)verdict; if (nft_jansson_node_exist(data, "chain")) { chain = nft_jansson_parse_str(data, "chain", err); if (chain == NULL) return DATA_NONE; reg->chain = strdup(chain); } return DATA_VERDICT; } static int nft_data_reg_value_json_parse(union nft_data_reg *reg, json_t *data, struct nft_parse_err *err) { int i; char node_name[6]; if (nft_jansson_parse_val(data, "len", NFT_TYPE_U8, ®->len, err) < 0) return DATA_NONE; for (i = 0; i < div_round_up(reg->len, sizeof(uint32_t)); i++) { sprintf(node_name, "data%d", i); if (nft_jansson_str2num(data, node_name, BASE_HEX, ®->val[i], NFT_TYPE_U32, err) != 0) return DATA_NONE; } return DATA_VALUE; } int nft_data_reg_json_parse(union nft_data_reg *reg, json_t *data, struct nft_parse_err *err) { const char *type; type = nft_jansson_parse_str(data, "type", err); if (type == NULL) return -1; /* Select what type of parsing is needed */ if (strcmp(type, "value") == 0) return nft_data_reg_value_json_parse(reg, data, err); else if (strcmp(type, "verdict") == 0) return nft_data_reg_verdict_json_parse(reg, data, err); return DATA_NONE; } #endif #ifdef XML_PARSING static int nft_data_reg_verdict_xml_parse(union nft_data_reg *reg, mxml_node_t *tree, struct nft_parse_err *err) { int verdict; const char *verdict_str; const char *chain; verdict_str = nft_mxml_str_parse(tree, "verdict", MXML_DESCEND_FIRST, NFT_XML_MAND, err); if (verdict_str == NULL) return DATA_NONE; if (nft_str2verdict(verdict_str, &verdict) != 0) { err->node_name = "verdict"; err->error = NFT_PARSE_EBADTYPE; errno = EINVAL; return DATA_NONE; } reg->verdict = (uint32_t)verdict; chain = nft_mxml_str_parse(tree, "chain", MXML_DESCEND_FIRST, NFT_XML_OPT, err); if (chain != NULL) { if (reg->chain) xfree(reg->chain); reg->chain = strdup(chain); } return DATA_VERDICT; } static int nft_data_reg_value_xml_parse(union nft_data_reg *reg, mxml_node_t *tree, struct nft_parse_err *err) { int i; char node_name[6]; if (nft_mxml_num_parse(tree, "len", MXML_DESCEND_FIRST, BASE_DEC, ®->len, NFT_TYPE_U8, NFT_XML_MAND, err) != 0) return DATA_NONE; for (i = 0; i < div_round_up(reg->len, sizeof(uint32_t)); i++) { sprintf(node_name, "data%d", i); if (nft_mxml_num_parse(tree, node_name, MXML_DESCEND_FIRST, BASE_HEX, ®->val[i], NFT_TYPE_U32, NFT_XML_MAND, err) != 0) return DATA_NONE; } return DATA_VALUE; } int nft_data_reg_xml_parse(union nft_data_reg *reg, mxml_node_t *tree, struct nft_parse_err *err) { const char *type; mxml_node_t *node; node = mxmlFindElement(tree, tree, "reg", "type", NULL, MXML_DESCEND_FIRST); if (node == NULL) goto err; type = mxmlElementGetAttr(node, "type"); if (type == NULL) goto err; if (strcmp(type, "value") == 0) return nft_data_reg_value_xml_parse(reg, node, err); else if (strcmp(type, "verdict") == 0) return nft_data_reg_verdict_xml_parse(reg, node, err); return DATA_NONE; err: errno = EINVAL; err->node_name = "reg"; err->error = NFT_PARSE_EMISSINGNODE; return DATA_NONE; } #endif static int nft_data_reg_value_snprintf_json(char *buf, size_t size, union nft_data_reg *reg, uint32_t flags) { int len = size, offset = 0, ret, i, j; uint32_t utemp; uint8_t *tmp; ret = snprintf(buf, len, "\"reg\":{\"type\":\"value\","); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); ret = snprintf(buf+offset, len, "\"len\":%u,", reg->len); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); for (i = 0; i < div_round_up(reg->len, sizeof(uint32_t)); i++) { ret = snprintf(buf+offset, len, "\"data%d\":\"0x", i); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); utemp = htonl(reg->val[i]); tmp = (uint8_t *)&utemp; for (j = 0; j"); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); ret = snprintf(buf+offset, len, "%u", reg->len); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); for (i = 0; i < div_round_up(reg->len, sizeof(uint32_t)); i++) { ret = snprintf(buf+offset, len, "0x", i); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); be = htonl(reg->val[i]); tmp = (uint8_t *)&be; for (j = 0; j < sizeof(uint32_t); j++) { ret = snprintf(buf+offset, len, "%.02x", tmp[j]); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); } ret = snprintf(buf+offset, len, "", i); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); } ret = snprintf(buf+offset, len, ""); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); return offset; } static int nft_data_reg_value_snprintf_default(char *buf, size_t size, union nft_data_reg *reg, uint32_t flags) { int len = size, offset = 0, ret, i; for (i = 0; i < div_round_up(reg->len, sizeof(uint32_t)); i++) { ret = snprintf(buf+offset, len, "0x%.8x ", reg->val[i]); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); } return offset; } static int nft_data_reg_verdict_snprintf_def(char *buf, size_t size, union nft_data_reg *reg, uint32_t flags) { int len = size, offset = 0, ret = 0; ret = snprintf(buf, size, "%s ", nft_verdict2str(reg->verdict)); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); if (reg->chain != NULL) { ret = snprintf(buf+offset, len, "-> %s ", reg->chain); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); } return offset; } static int nft_data_reg_verdict_snprintf_xml(char *buf, size_t size, union nft_data_reg *reg, uint32_t flags) { int len = size, offset = 0, ret = 0; ret = snprintf(buf, size, "" "%s", nft_verdict2str(reg->verdict)); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); if (reg->chain != NULL) { ret = snprintf(buf+offset, len, "%s", reg->chain); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); } ret = snprintf(buf+offset, len, ""); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); return offset; } static int nft_data_reg_verdict_snprintf_json(char *buf, size_t size, union nft_data_reg *reg, uint32_t flags) { int len = size, offset = 0, ret = 0; ret = snprintf(buf, size, "\"reg\":{\"type\":\"verdict\"," "\"verdict\":\"%s\"", nft_verdict2str(reg->verdict)); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); if (reg->chain != NULL) { ret = snprintf(buf+offset, len, ",\"chain\":\"%s\"", reg->chain); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); } ret = snprintf(buf+offset, len, "}"); SNPRINTF_BUFFER_SIZE(ret, size, len, offset); return offset; } int nft_data_reg_snprintf(char *buf, size_t size, union nft_data_reg *reg, uint32_t output_format, uint32_t flags, int reg_type) { switch(reg_type) { case DATA_VALUE: switch(output_format) { case NFT_OUTPUT_DEFAULT: return nft_data_reg_value_snprintf_default(buf, size, reg, flags); case NFT_OUTPUT_XML: return nft_data_reg_value_snprintf_xml(buf, size, reg, flags); case NFT_OUTPUT_JSON: return nft_data_reg_value_snprintf_json(buf, size, reg, flags); default: break; } case DATA_VERDICT: case DATA_CHAIN: switch(output_format) { case NFT_OUTPUT_DEFAULT: return nft_data_reg_verdict_snprintf_def(buf, size, reg, flags); case NFT_OUTPUT_XML: return nft_data_reg_verdict_snprintf_xml(buf, size, reg, flags); case NFT_OUTPUT_JSON: return nft_data_reg_verdict_snprintf_json(buf, size, reg, flags); default: break; } default: break; } return -1; } static int nft_data_parse_cb(const struct nlattr *attr, void *data) { const struct nlattr **tb = data; int type = mnl_attr_get_type(attr); if (mnl_attr_type_valid(attr, NFTA_DATA_MAX) < 0) return MNL_CB_OK; switch(type) { case NFTA_DATA_VALUE: if (mnl_attr_validate(attr, MNL_TYPE_BINARY) < 0) abi_breakage(); break; case NFTA_DATA_VERDICT: if (mnl_attr_validate(attr, MNL_TYPE_NESTED) < 0) abi_breakage(); break; } tb[type] = attr; return MNL_CB_OK; } static int nft_verdict_parse_cb(const struct nlattr *attr, void *data) { const struct nlattr **tb = data; int type = mnl_attr_get_type(attr); if (mnl_attr_type_valid(attr, NFTA_VERDICT_MAX) < 0) return MNL_CB_OK; switch(type) { case NFTA_VERDICT_CODE: if (mnl_attr_validate(attr, MNL_TYPE_U32) < 0) abi_breakage(); break; case NFTA_VERDICT_CHAIN: if (mnl_attr_validate(attr, MNL_TYPE_STRING) < 0) abi_breakage(); break; } tb[type] = attr; return MNL_CB_OK; } static int nft_parse_verdict(union nft_data_reg *data, const struct nlattr *attr, int *type) { struct nlattr *tb[NFTA_VERDICT_MAX+1]; if (mnl_attr_parse_nested(attr, nft_verdict_parse_cb, tb) < 0) { perror("mnl_attr_parse_nested"); return -1; } if (!tb[NFTA_VERDICT_CODE]) return -1; data->verdict = ntohl(mnl_attr_get_u32(tb[NFTA_VERDICT_CODE])); switch(data->verdict) { case NF_ACCEPT: case NF_DROP: case NF_QUEUE: case NFT_CONTINUE: case NFT_BREAK: case NFT_RETURN: if (type) *type = DATA_VERDICT; data->len = sizeof(data->verdict); break; case NFT_JUMP: case NFT_GOTO: if (!tb[NFTA_VERDICT_CHAIN]) return -1; data->chain = strdup(mnl_attr_get_str(tb[NFTA_VERDICT_CHAIN])); if (type) *type = DATA_CHAIN; break; default: return -1; } return 0; } static int __nft_parse_data(union nft_data_reg *data, const struct nlattr *attr) { void *orig = mnl_attr_get_payload(attr); uint32_t data_len = mnl_attr_get_payload_len(attr); if (data_len == 0) return -1; if (data_len > sizeof(uint32_t) * 4) return -1; memcpy(data->val, orig, data_len); data->len = data_len; return 0; } int nft_parse_data(union nft_data_reg *data, struct nlattr *attr, int *type) { struct nlattr *tb[NFTA_DATA_MAX+1] = {}; int ret = 0; if (mnl_attr_parse_nested(attr, nft_data_parse_cb, tb) < 0) { perror("mnl_attr_parse_nested"); return -1; } if (tb[NFTA_DATA_VALUE]) { if (type) *type = DATA_VALUE; ret = __nft_parse_data(data, tb[NFTA_DATA_VALUE]); if (ret < 0) return ret; } if (tb[NFTA_DATA_VERDICT]) ret = nft_parse_verdict(data, tb[NFTA_DATA_VERDICT], type); return ret; }