/* Generated by `lib9p/idl.gen lib9p/idl/2002-9P2000.9p lib9p/idl/2003-9P2000.p9p.9p lib9p/idl/2005-9P2000.u.9p lib9p/idl/2010-9P2000.L.9p lib9p/idl/2012-9P2000.e.9p`. DO NOT EDIT! */ #include #include /* for size_t */ #include /* for PRI* macros */ #include /* for memset() */ #include #include #include "internal.h" /* utilities ******************************************************************/ #if CONFIG_9P_ENABLE_9P2000 #define _is_ver_9P2000(v) (v == LIB9P_VER_9P2000) #else #define _is_ver_9P2000(v) false #endif #if CONFIG_9P_ENABLE_9P2000_L #define _is_ver_9P2000_L(v) (v == LIB9P_VER_9P2000_L) #else #define _is_ver_9P2000_L(v) false #endif #if CONFIG_9P_ENABLE_9P2000_e #define _is_ver_9P2000_e(v) (v == LIB9P_VER_9P2000_e) #else #define _is_ver_9P2000_e(v) false #endif #if CONFIG_9P_ENABLE_9P2000_p9p #define _is_ver_9P2000_p9p(v) (v == LIB9P_VER_9P2000_p9p) #else #define _is_ver_9P2000_p9p(v) false #endif #if CONFIG_9P_ENABLE_9P2000_u #define _is_ver_9P2000_u(v) (v == LIB9P_VER_9P2000_u) #else #define _is_ver_9P2000_u(v) false #endif /** * is_ver(ctx, ver) is essentially `(ctx->ctx->version == LIB9P_VER_##ver)`, * but compiles correctly (to `false`) even if `LIB9P_VER_##ver` isn't defined * (because `!CONFIG_9P_ENABLE_##ver`). This is useful when `||`ing * several version checks together. */ #define is_ver(CTX, ver) _is_ver_##ver(CTX->ctx->version) /* strings ********************************************************************/ const char *_lib9p_table_ver_name[LIB9P_VER_NUM] = { [LIB9P_VER_unknown] = "unknown", #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = "9P2000", #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = "9P2000.L", #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = "9P2000.e", #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = "9P2000.p9p", #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = "9P2000.u", #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; #define _MSG_NAME(typ) [LIB9P_TYP_##typ] = #typ const char * _lib9p_table_msg_name[LIB9P_VER_NUM][0x100] = { [LIB9P_VER_unknown] = { _MSG_NAME(Tversion), _MSG_NAME(Rversion), _MSG_NAME(Rerror), }, #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = { _MSG_NAME(Tversion), _MSG_NAME(Rversion), _MSG_NAME(Tauth), _MSG_NAME(Rauth), _MSG_NAME(Tattach), _MSG_NAME(Rattach), _MSG_NAME(Rerror), _MSG_NAME(Tflush), _MSG_NAME(Rflush), _MSG_NAME(Twalk), _MSG_NAME(Rwalk), _MSG_NAME(Topen), _MSG_NAME(Ropen), _MSG_NAME(Tcreate), _MSG_NAME(Rcreate), _MSG_NAME(Tread), _MSG_NAME(Rread), _MSG_NAME(Twrite), _MSG_NAME(Rwrite), _MSG_NAME(Tclunk), _MSG_NAME(Rclunk), _MSG_NAME(Tremove), _MSG_NAME(Rremove), _MSG_NAME(Tstat), _MSG_NAME(Rstat), _MSG_NAME(Twstat), _MSG_NAME(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = { _MSG_NAME(Rlerror), _MSG_NAME(Tstatfs), _MSG_NAME(Rstatfs), _MSG_NAME(Tlopen), _MSG_NAME(Rlopen), _MSG_NAME(Tlcreate), _MSG_NAME(Rlcreate), _MSG_NAME(Tsymlink), _MSG_NAME(Rsymlink), _MSG_NAME(Tmknod), _MSG_NAME(Rmknod), _MSG_NAME(Trename), _MSG_NAME(Rrename), _MSG_NAME(Treadlink), _MSG_NAME(Rreadlink), _MSG_NAME(Tgetattr), _MSG_NAME(Rgetattr), _MSG_NAME(Tsetattr), _MSG_NAME(Rsetattr), _MSG_NAME(Txattrwalk), _MSG_NAME(Rxattrwalk), _MSG_NAME(Txattrcreate), _MSG_NAME(Rxattrcreate), _MSG_NAME(Treaddir), _MSG_NAME(Rreaddir), _MSG_NAME(Tfsync), _MSG_NAME(Rfsync), _MSG_NAME(Tlock), _MSG_NAME(Rlock), _MSG_NAME(Tgetlock), _MSG_NAME(Rgetlock), _MSG_NAME(Tlink), _MSG_NAME(Rlink), _MSG_NAME(Tmkdir), _MSG_NAME(Rmkdir), _MSG_NAME(Trenameat), _MSG_NAME(Rrenameat), _MSG_NAME(Tunlinkat), _MSG_NAME(Runlinkat), _MSG_NAME(Tversion), _MSG_NAME(Rversion), _MSG_NAME(Tauth), _MSG_NAME(Rauth), _MSG_NAME(Tattach), _MSG_NAME(Rattach), _MSG_NAME(Rerror), _MSG_NAME(Tflush), _MSG_NAME(Rflush), _MSG_NAME(Twalk), _MSG_NAME(Rwalk), _MSG_NAME(Tread), _MSG_NAME(Rread), _MSG_NAME(Twrite), _MSG_NAME(Rwrite), _MSG_NAME(Tclunk), _MSG_NAME(Rclunk), _MSG_NAME(Tremove), _MSG_NAME(Rremove), }, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = { _MSG_NAME(Tversion), _MSG_NAME(Rversion), _MSG_NAME(Tauth), _MSG_NAME(Rauth), _MSG_NAME(Tattach), _MSG_NAME(Rattach), _MSG_NAME(Rerror), _MSG_NAME(Tflush), _MSG_NAME(Rflush), _MSG_NAME(Twalk), _MSG_NAME(Rwalk), _MSG_NAME(Topen), _MSG_NAME(Ropen), _MSG_NAME(Tcreate), _MSG_NAME(Rcreate), _MSG_NAME(Tread), _MSG_NAME(Rread), _MSG_NAME(Twrite), _MSG_NAME(Rwrite), _MSG_NAME(Tclunk), _MSG_NAME(Rclunk), _MSG_NAME(Tremove), _MSG_NAME(Rremove), _MSG_NAME(Tstat), _MSG_NAME(Rstat), _MSG_NAME(Twstat), _MSG_NAME(Rwstat), _MSG_NAME(Tsession), _MSG_NAME(Rsession), _MSG_NAME(Tsread), _MSG_NAME(Rsread), _MSG_NAME(Tswrite), _MSG_NAME(Rswrite), }, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = { _MSG_NAME(Topenfd), _MSG_NAME(Ropenfd), _MSG_NAME(Tversion), _MSG_NAME(Rversion), _MSG_NAME(Tauth), _MSG_NAME(Rauth), _MSG_NAME(Tattach), _MSG_NAME(Rattach), _MSG_NAME(Rerror), _MSG_NAME(Tflush), _MSG_NAME(Rflush), _MSG_NAME(Twalk), _MSG_NAME(Rwalk), _MSG_NAME(Topen), _MSG_NAME(Ropen), _MSG_NAME(Tcreate), _MSG_NAME(Rcreate), _MSG_NAME(Tread), _MSG_NAME(Rread), _MSG_NAME(Twrite), _MSG_NAME(Rwrite), _MSG_NAME(Tclunk), _MSG_NAME(Rclunk), _MSG_NAME(Tremove), _MSG_NAME(Rremove), _MSG_NAME(Tstat), _MSG_NAME(Rstat), _MSG_NAME(Twstat), _MSG_NAME(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = { _MSG_NAME(Tversion), _MSG_NAME(Rversion), _MSG_NAME(Tauth), _MSG_NAME(Rauth), _MSG_NAME(Tattach), _MSG_NAME(Rattach), _MSG_NAME(Rerror), _MSG_NAME(Tflush), _MSG_NAME(Rflush), _MSG_NAME(Twalk), _MSG_NAME(Rwalk), _MSG_NAME(Topen), _MSG_NAME(Ropen), _MSG_NAME(Tcreate), _MSG_NAME(Rcreate), _MSG_NAME(Tread), _MSG_NAME(Rread), _MSG_NAME(Twrite), _MSG_NAME(Rwrite), _MSG_NAME(Tclunk), _MSG_NAME(Rclunk), _MSG_NAME(Tremove), _MSG_NAME(Rremove), _MSG_NAME(Tstat), _MSG_NAME(Rstat), _MSG_NAME(Twstat), _MSG_NAME(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; /* bitmasks *******************************************************************/ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u static const lib9p_dm_t dm_masks[LIB9P_VER_NUM] = { #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = 0b11101100000000000000000111111111, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = 0b11101100000000000000000111111111, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = 0b11101100000000000000000111111111, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = 0b11101100101111000000000111111111, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u static const lib9p_qt_t qt_masks[LIB9P_VER_NUM] = { #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = 0b11101100, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = 0b11101100, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = 0b11101100, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = 0b11101100, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = 0b11101110, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u static const lib9p_o_t o_masks[LIB9P_VER_NUM] = { #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = 0b01010011, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = 0b00000000, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = 0b01010011, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = 0b01010011, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = 0b01010011, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L static const lib9p_getattr_t getattr_masks[LIB9P_VER_NUM] = { #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = 0b0000000000000000000000000000000000000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000 */ [LIB9P_VER_9P2000_L] = 0b0000000000000000000000000000000000000000000000000011111111111111, #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = 0b0000000000000000000000000000000000000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = 0b0000000000000000000000000000000000000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = 0b0000000000000000000000000000000000000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; static const lib9p_setattr_t setattr_masks[LIB9P_VER_NUM] = { #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000 */ [LIB9P_VER_9P2000_L] = 0b00000000000000000000000111111111, #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; static const lib9p_lock_flags_t lock_flags_masks[LIB9P_VER_NUM] = { #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000 */ [LIB9P_VER_9P2000_L] = 0b00000000000000000000000000000011, #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = 0b00000000000000000000000000000000, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; #endif /* CONFIG_9P_ENABLE_9P2000_L */ /* validate_* *****************************************************************/ LM_ALWAYS_INLINE static bool _validate_size_net(struct _validate_ctx *ctx, uint32_t n) { if (__builtin_add_overflow(ctx->net_offset, n, &ctx->net_offset)) /* If needed-net-size overflowed uint32_t, then * there's no way that actual-net-size will live up to * that. */ return lib9p_error(ctx->ctx, LINUX_EBADMSG, "message is too short for content"); if (ctx->net_offset > ctx->net_size) return lib9p_error(ctx->ctx, LINUX_EBADMSG, "message is too short for content"); return false; } LM_ALWAYS_INLINE static bool _validate_size_host(struct _validate_ctx *ctx, size_t n) { if (__builtin_add_overflow(ctx->host_extra, n, &ctx->host_extra)) /* If needed-host-size overflowed size_t, then there's * no way that actual-net-size will live up to * that. */ return lib9p_error(ctx->ctx, LINUX_EBADMSG, "message is too short for content"); return false; } LM_ALWAYS_INLINE static bool _validate_list(struct _validate_ctx *ctx, size_t cnt, _validate_fn_t item_fn, size_t item_host_size) { for (size_t i = 0; i < cnt; i++) if (_validate_size_host(ctx, item_host_size) || item_fn(ctx)) return true; return false; } LM_ALWAYS_INLINE static bool validate_1(struct _validate_ctx *ctx) { return _validate_size_net(ctx, 1); } LM_ALWAYS_INLINE static bool validate_2(struct _validate_ctx *ctx) { return _validate_size_net(ctx, 2); } LM_ALWAYS_INLINE static bool validate_4(struct _validate_ctx *ctx) { return _validate_size_net(ctx, 4); } LM_ALWAYS_INLINE static bool validate_8(struct _validate_ctx *ctx) { return _validate_size_net(ctx, 8); } #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool validate_tag(struct _validate_ctx *ctx) { return validate_2(ctx); } LM_ALWAYS_INLINE static bool validate_fid(struct _validate_ctx *ctx) { return validate_4(ctx); } LM_ALWAYS_INLINE static bool validate_s(struct _validate_ctx *ctx) { uint16_t len; return false || (validate_2(ctx) || ({ len = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || _validate_list(ctx, len, validate_1, sizeof(uint8_t)) || ({ (!is_valid_utf8_without_nul(&ctx->net_bytes[ctx->net_offset-len], len)) && lib9p_error(ctx->ctx, LINUX_EBADMSG, "message contains invalid UTF-8"); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool validate_dm(struct _validate_ctx *ctx) { if (validate_4(ctx)) return true; lib9p_dm_t mask = dm_masks[ctx->ctx->version]; lib9p_dm_t val = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); if (val & ~mask) return lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "unknown bits in dm bitfield: %#04"PRIx32, val & ~mask); return false; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool validate_qt(struct _validate_ctx *ctx) { if (validate_1(ctx)) return true; lib9p_qt_t mask = qt_masks[ctx->ctx->version]; lib9p_qt_t val = ctx->net_bytes[ctx->net_offset-1]; if (val & ~mask) return lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "unknown bits in qt bitfield: %#01"PRIx8, val & ~mask); return false; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool validate_nuid(struct _validate_ctx *ctx) { return validate_4(ctx); } #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool validate_o(struct _validate_ctx *ctx) { if (validate_1(ctx)) return true; lib9p_o_t mask = o_masks[ctx->ctx->version]; lib9p_o_t val = ctx->net_bytes[ctx->net_offset-1]; if (val & ~mask) return lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "unknown bits in o bitfield: %#01"PRIx8, val & ~mask); return false; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_ALWAYS_INLINE static bool validate_getattr(struct _validate_ctx *ctx) { if (validate_8(ctx)) return true; lib9p_getattr_t mask = getattr_masks[ctx->ctx->version]; lib9p_getattr_t val = uint64le_decode(&ctx->net_bytes[ctx->net_offset-8]); if (val & ~mask) return lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "unknown bits in getattr bitfield: %#08"PRIx64, val & ~mask); return false; } LM_ALWAYS_INLINE static bool validate_setattr(struct _validate_ctx *ctx) { if (validate_4(ctx)) return true; lib9p_setattr_t mask = setattr_masks[ctx->ctx->version]; lib9p_setattr_t val = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); if (val & ~mask) return lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "unknown bits in setattr bitfield: %#04"PRIx32, val & ~mask); return false; } LM_ALWAYS_INLINE static bool validate_lock_type(struct _validate_ctx *ctx) { return validate_1(ctx); } LM_ALWAYS_INLINE static bool validate_lock_flags(struct _validate_ctx *ctx) { if (validate_4(ctx)) return true; lib9p_lock_flags_t mask = lock_flags_masks[ctx->ctx->version]; lib9p_lock_flags_t val = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); if (val & ~mask) return lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "unknown bits in lock_flags bitfield: %#04"PRIx32, val & ~mask); return false; } LM_ALWAYS_INLINE static bool validate_lock_status(struct _validate_ctx *ctx) { return validate_1(ctx); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Tflush(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_2(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 108; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rflush(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 109; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rread(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t count; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || (validate_4(ctx) || ({ count = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || _validate_list(ctx, count, validate_1, sizeof(uint8_t)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 117; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint32_t max = INT32_MAX; (((uint32_t)count) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "count value is too large (%"PRIu32" > %"PRIu32")", count, max); }) ; } LM_FLATTEN static bool validate_Rwrite(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t count; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || (validate_4(ctx) || ({ count = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 119; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint32_t max = INT32_MAX; (((uint32_t)count) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "count value is too large (%"PRIu32" > %"PRIu32")", count, max); }) ; } LM_FLATTEN static bool validate_Rclunk(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 121; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rremove(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 123; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Rwstat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 127; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool validate_Rlerror(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 7; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rstatfs(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_4(ctx) || validate_4(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 9; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rrename(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 21; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rsetattr(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 27; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rxattrwalk(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_8(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 31; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rxattrcreate(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 33; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rreaddir(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t count; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || (validate_4(ctx) || ({ count = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || _validate_list(ctx, count, validate_1, sizeof(uint8_t)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 41; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rfsync(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 51; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rlink(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 71; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rrenameat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 75; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Runlinkat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 77; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e LM_FLATTEN static bool validate_Tsession(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_8(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 150; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rsession(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 151; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rsread(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t count; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || (validate_4(ctx) || ({ count = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || _validate_list(ctx, count, validate_1, sizeof(uint8_t)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 153; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rswrite(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 155; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Tread(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint64_t offset; uint32_t count; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || (validate_8(ctx) || ({ offset = uint64le_decode(&ctx->net_bytes[ctx->net_offset-8]); false; })) || (validate_4(ctx) || ({ count = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 116; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint64_t max = INT64_MAX; (((uint64_t)offset) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "offset value is too large (%"PRIu64" > %"PRIu64")", offset, max); }) || ({ uint32_t max = INT32_MAX; (((uint32_t)count) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "count value is too large (%"PRIu32" > %"PRIu32")", count, max); }) ; } LM_FLATTEN static bool validate_Twrite(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint64_t offset; uint32_t count; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || (validate_8(ctx) || ({ offset = uint64le_decode(&ctx->net_bytes[ctx->net_offset-8]); false; })) || (validate_4(ctx) || ({ count = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || _validate_list(ctx, count, validate_1, sizeof(uint8_t)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 118; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint64_t max = INT64_MAX; (((uint64_t)offset) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "offset value is too large (%"PRIu64" > %"PRIu64")", offset, max); }) || ({ uint32_t max = INT32_MAX; (((uint32_t)count) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "count value is too large (%"PRIu32" > %"PRIu32")", count, max); }) ; } LM_FLATTEN static bool validate_Tclunk(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 120; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tremove(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 122; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Tstat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 124; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool validate_Tstatfs(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 8; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tlopen(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 12; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Treadlink(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 22; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Treaddir(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_8(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 40; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tfsync(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 50; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Tversion(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_4(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 100; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rversion(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_4(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 101; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rerror(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_s(ctx) #if CONFIG_9P_ENABLE_9P2000_u || ( is_ver(ctx, 9P2000_u) && validate_4(ctx) ) #endif /* CONFIG_9P_ENABLE_9P2000_u */ || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 107; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Twalk(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint16_t nwname; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_fid(ctx) || (validate_2(ctx) || ({ nwname = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || _validate_list(ctx, nwname, validate_s, sizeof(struct lib9p_s)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 110; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint16_t max = 16; (((uint16_t)nwname) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "nwname value is too large (%"PRIu16" > %"PRIu16")", nwname, max); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool validate_Trename(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_fid(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 20; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rreadlink(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 23; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Txattrwalk(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_fid(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 30; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Txattrcreate(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_8(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 32; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tgetlock(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_1(ctx) || validate_8(ctx) || validate_8(ctx) || validate_4(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 54; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rgetlock(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_1(ctx) || validate_8(ctx) || validate_8(ctx) || validate_4(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 55; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tlink(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_fid(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 70; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Trenameat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_fid(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 74; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tunlinkat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 76; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e LM_FLATTEN static bool validate_Tsread(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint16_t nwname; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_4(ctx) || (validate_2(ctx) || ({ nwname = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || _validate_list(ctx, nwname, validate_s, sizeof(struct lib9p_s)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 152; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tswrite(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint16_t nwname; uint32_t count; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_4(ctx) || (validate_2(ctx) || ({ nwname = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || _validate_list(ctx, nwname, validate_s, sizeof(struct lib9p_s)) || (validate_4(ctx) || ({ count = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || _validate_list(ctx, count, validate_1, sizeof(uint8_t)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 154; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool validate_qid(struct _validate_ctx *ctx) { return false || validate_qt(ctx) || validate_4(ctx) || validate_8(ctx) ; } LM_FLATTEN static bool validate_Tauth(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_s(ctx) #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u || ( ( is_ver(ctx, 9P2000_L) || is_ver(ctx, 9P2000_u) ) && validate_nuid(ctx) ) #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 102; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tattach(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_s(ctx) #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u || ( ( is_ver(ctx, 9P2000_L) || is_ver(ctx, 9P2000_u) ) && validate_nuid(ctx) ) #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 104; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool validate_Tlcreate(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_4(ctx) || validate_4(ctx) || validate_nuid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 14; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tsymlink(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_s(ctx) || validate_nuid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 16; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tmknod(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_4(ctx) || validate_4(ctx) || validate_4(ctx) || validate_nuid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 18; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tmkdir(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_4(ctx) || validate_nuid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 72; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Topen(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_o(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 112; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tcreate(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_s(ctx) || validate_dm(ctx) || validate_o(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 114; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_p9p LM_FLATTEN static bool validate_Topenfd(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_o(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 98; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool validate_Tgetattr(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_getattr(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 24; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tsetattr(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_setattr(ctx) || validate_4(ctx) || validate_nuid(ctx) || validate_nuid(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 26; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Tlock(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || validate_lock_type(ctx) || validate_lock_flags(ctx) || validate_8(ctx) || validate_8(ctx) || validate_4(ctx) || validate_s(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 52; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rlock(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_lock_status(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 53; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool validate_stat(struct _validate_ctx *ctx) { uint16_t stat_size; uint32_t _kern_type_offset; return false || (validate_2(ctx) || ({ stat_size = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || ({ _kern_type_offset = ctx->net_offset; validate_2(ctx); }) || validate_4(ctx) || validate_qid(ctx) || validate_dm(ctx) || validate_4(ctx) || validate_4(ctx) || validate_8(ctx) || validate_s(ctx) || validate_s(ctx) || validate_s(ctx) || validate_s(ctx) #if CONFIG_9P_ENABLE_9P2000_u || ( is_ver(ctx, 9P2000_u) && validate_s(ctx) ) || ( is_ver(ctx, 9P2000_u) && validate_nuid(ctx) ) || ( is_ver(ctx, 9P2000_u) && validate_nuid(ctx) ) || ( is_ver(ctx, 9P2000_u) && validate_nuid(ctx) ) #endif /* CONFIG_9P_ENABLE_9P2000_u */ || ({ uint16_t exp = ctx->net_offset - _kern_type_offset; (((uint16_t)stat_size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "stat_size value is wrong (actual:%"PRIu16" != correct:%"PRIu16")", (uint16_t)stat_size, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Rauth(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 103; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rattach(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 105; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rwalk(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint16_t nwqid; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || (validate_2(ctx) || ({ nwqid = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || _validate_list(ctx, nwqid, validate_qid, sizeof(struct lib9p_qid)) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 111; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint16_t max = 16; (((uint16_t)nwqid) > max) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "nwqid value is too large (%"PRIu16" > %"PRIu16")", nwqid, max); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Ropen(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 113; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rcreate(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 115; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_p9p LM_FLATTEN static bool validate_Ropenfd(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || validate_4(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 99; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool validate_Rlopen(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 13; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rlcreate(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || validate_4(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 15; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rsymlink(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 17; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rmknod(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 19; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rgetattr(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_8(ctx) || validate_qid(ctx) || validate_4(ctx) || validate_nuid(ctx) || validate_nuid(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || validate_8(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 25; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } LM_FLATTEN static bool validate_Rmkdir(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint32_t _size_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_qid(ctx) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 73; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool validate_Rstat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint16_t nstat; uint32_t _size_offset; uint32_t _stat_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || (validate_2(ctx) || ({ nstat = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || ({ _stat_offset = ctx->net_offset; validate_stat(ctx); }) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 125; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint16_t exp = ctx->net_offset - _stat_offset; (((uint16_t)nstat) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "nstat value is wrong (actual:%"PRIu16" != correct:%"PRIu16")", (uint16_t)nstat, exp); }) ; } LM_FLATTEN static bool validate_Twstat(struct _validate_ctx *ctx) { uint32_t size; uint8_t typ; uint16_t nstat; uint32_t _size_offset; uint32_t _stat_offset; return false || (({ _size_offset = ctx->net_offset; validate_4(ctx); }) || ({ size = uint32le_decode(&ctx->net_bytes[ctx->net_offset-4]); false; })) || (validate_1(ctx) || ({ typ = ctx->net_bytes[ctx->net_offset-1]; false; })) || validate_tag(ctx) || validate_fid(ctx) || (validate_2(ctx) || ({ nstat = uint16le_decode(&ctx->net_bytes[ctx->net_offset-2]); false; })) || ({ _stat_offset = ctx->net_offset; validate_stat(ctx); }) || ({ uint32_t exp = ctx->net_offset - _size_offset; (((uint32_t)size) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "size value is wrong (actual:%"PRIu32" != correct:%"PRIu32")", (uint32_t)size, exp); }) || ({ uint8_t exp = 126; (((uint8_t)typ) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "typ value is wrong (actual:%"PRIu8" != correct:%"PRIu8")", (uint8_t)typ, exp); }) || ({ uint16_t exp = ctx->net_offset - _stat_offset; (((uint16_t)nstat) != exp) && lib9p_errorf(ctx->ctx, LINUX_EBADMSG, "nstat value is wrong (actual:%"PRIu16" != correct:%"PRIu16")", (uint16_t)nstat, exp); }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ /* unmarshal_* ****************************************************************/ LM_ALWAYS_INLINE static void unmarshal_1(struct _unmarshal_ctx *ctx, uint8_t *out) { *out = ctx->net_bytes[ctx->net_offset]; ctx->net_offset += 1; } LM_ALWAYS_INLINE static void unmarshal_2(struct _unmarshal_ctx *ctx, uint16_t *out) { *out = uint16le_decode(&ctx->net_bytes[ctx->net_offset]); ctx->net_offset += 2; } LM_ALWAYS_INLINE static void unmarshal_4(struct _unmarshal_ctx *ctx, uint32_t *out) { *out = uint32le_decode(&ctx->net_bytes[ctx->net_offset]); ctx->net_offset += 4; } LM_ALWAYS_INLINE static void unmarshal_8(struct _unmarshal_ctx *ctx, uint64_t *out) { *out = uint64le_decode(&ctx->net_bytes[ctx->net_offset]); ctx->net_offset += 8; } #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static void unmarshal_tag(struct _unmarshal_ctx *ctx, lib9p_tag_t *out) { unmarshal_2(ctx, (uint16_t *)out); } LM_ALWAYS_INLINE static void unmarshal_fid(struct _unmarshal_ctx *ctx, lib9p_fid_t *out) { unmarshal_4(ctx, (uint32_t *)out); } LM_ALWAYS_INLINE static void unmarshal_s(struct _unmarshal_ctx *ctx, struct lib9p_s *out) { memset(out, 0, sizeof(*out)); unmarshal_2(ctx, &out->len); out->utf8 = ctx->extra; ctx->extra += sizeof(out->utf8[0]) * out->len; for (typeof(out->len) i = 0; i < out->len; i++) unmarshal_1(ctx, (uint8_t *)&out->utf8[i]); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static void unmarshal_dm(struct _unmarshal_ctx *ctx, lib9p_dm_t *out) { unmarshal_4(ctx, (uint32_t *)out); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static void unmarshal_qt(struct _unmarshal_ctx *ctx, lib9p_qt_t *out) { unmarshal_1(ctx, (uint8_t *)out); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static void unmarshal_nuid(struct _unmarshal_ctx *ctx, lib9p_nuid_t *out) { unmarshal_4(ctx, (uint32_t *)out); } #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static void unmarshal_o(struct _unmarshal_ctx *ctx, lib9p_o_t *out) { unmarshal_1(ctx, (uint8_t *)out); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_ALWAYS_INLINE static void unmarshal_getattr(struct _unmarshal_ctx *ctx, lib9p_getattr_t *out) { unmarshal_8(ctx, (uint64_t *)out); } LM_ALWAYS_INLINE static void unmarshal_setattr(struct _unmarshal_ctx *ctx, lib9p_setattr_t *out) { unmarshal_4(ctx, (uint32_t *)out); } LM_ALWAYS_INLINE static void unmarshal_lock_type(struct _unmarshal_ctx *ctx, lib9p_lock_type_t *out) { unmarshal_1(ctx, (uint8_t *)out); } LM_ALWAYS_INLINE static void unmarshal_lock_flags(struct _unmarshal_ctx *ctx, lib9p_lock_flags_t *out) { unmarshal_4(ctx, (uint32_t *)out); } LM_ALWAYS_INLINE static void unmarshal_lock_status(struct _unmarshal_ctx *ctx, lib9p_lock_status_t *out) { unmarshal_1(ctx, (uint8_t *)out); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Tflush(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tflush *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_2(ctx, &out->oldtag); } LM_FLATTEN static void unmarshal_Rflush(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rflush *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rread(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rread *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->count); out->data = ctx->extra; ctx->extra += sizeof(out->data[0]) * out->count; for (typeof(out->count) i = 0; i < out->count; i++) unmarshal_1(ctx, (uint8_t *)&out->data[i]); } LM_FLATTEN static void unmarshal_Rwrite(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rwrite *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->count); } LM_FLATTEN static void unmarshal_Rclunk(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rclunk *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rremove(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rremove *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Rwstat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rwstat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static void unmarshal_Rlerror(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rlerror *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->ecode); } LM_FLATTEN static void unmarshal_Rstatfs(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rstatfs *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->type); unmarshal_4(ctx, &out->bsize); unmarshal_8(ctx, &out->blocks); unmarshal_8(ctx, &out->bfree); unmarshal_8(ctx, &out->bavail); unmarshal_8(ctx, &out->files); unmarshal_8(ctx, &out->ffree); unmarshal_8(ctx, &out->fsid); unmarshal_4(ctx, &out->namelen); } LM_FLATTEN static void unmarshal_Rrename(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rrename *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rsetattr(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rsetattr *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rxattrwalk(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rxattrwalk *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_8(ctx, &out->attr_size); } LM_FLATTEN static void unmarshal_Rxattrcreate(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rxattrcreate *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rreaddir(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rreaddir *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->count); out->data = ctx->extra; ctx->extra += sizeof(out->data[0]) * out->count; for (typeof(out->count) i = 0; i < out->count; i++) unmarshal_1(ctx, (uint8_t *)&out->data[i]); } LM_FLATTEN static void unmarshal_Rfsync(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rfsync *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rlink(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rlink *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rrenameat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rrenameat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Runlinkat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Runlinkat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e LM_FLATTEN static void unmarshal_Tsession(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tsession *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_8(ctx, &out->key); } LM_FLATTEN static void unmarshal_Rsession(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rsession *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); } LM_FLATTEN static void unmarshal_Rsread(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rsread *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->count); out->data = ctx->extra; ctx->extra += sizeof(out->data[0]) * out->count; for (typeof(out->count) i = 0; i < out->count; i++) unmarshal_1(ctx, (uint8_t *)&out->data[i]); } LM_FLATTEN static void unmarshal_Rswrite(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rswrite *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->count); } #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Tread(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tread *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_8(ctx, &out->offset); unmarshal_4(ctx, &out->count); } LM_FLATTEN static void unmarshal_Twrite(struct _unmarshal_ctx *ctx, struct lib9p_msg_Twrite *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_8(ctx, &out->offset); unmarshal_4(ctx, &out->count); out->data = ctx->extra; ctx->extra += sizeof(out->data[0]) * out->count; for (typeof(out->count) i = 0; i < out->count; i++) unmarshal_1(ctx, (uint8_t *)&out->data[i]); } LM_FLATTEN static void unmarshal_Tclunk(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tclunk *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); } LM_FLATTEN static void unmarshal_Tremove(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tremove *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Tstat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tstat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static void unmarshal_Tstatfs(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tstatfs *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); } LM_FLATTEN static void unmarshal_Tlopen(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tlopen *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_4(ctx, &out->flags); } LM_FLATTEN static void unmarshal_Treadlink(struct _unmarshal_ctx *ctx, struct lib9p_msg_Treadlink *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); } LM_FLATTEN static void unmarshal_Treaddir(struct _unmarshal_ctx *ctx, struct lib9p_msg_Treaddir *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_8(ctx, &out->offset); unmarshal_4(ctx, &out->count); } LM_FLATTEN static void unmarshal_Tfsync(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tfsync *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_4(ctx, &out->datasync); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Tversion(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tversion *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->max_msg_size); unmarshal_s(ctx, &out->version); } LM_FLATTEN static void unmarshal_Rversion(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rversion *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->max_msg_size); unmarshal_s(ctx, &out->version); } LM_FLATTEN static void unmarshal_Rerror(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rerror *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_s(ctx, &out->ename); #if CONFIG_9P_ENABLE_9P2000_u if ( is_ver(ctx, 9P2000_u) ) unmarshal_4(ctx, &out->errno); #endif /* CONFIG_9P_ENABLE_9P2000_u */ } LM_FLATTEN static void unmarshal_Twalk(struct _unmarshal_ctx *ctx, struct lib9p_msg_Twalk *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_fid(ctx, &out->newfid); unmarshal_2(ctx, &out->nwname); out->wname = ctx->extra; ctx->extra += sizeof(out->wname[0]) * out->nwname; for (typeof(out->nwname) i = 0; i < out->nwname; i++) unmarshal_s(ctx, &out->wname[i]); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static void unmarshal_Trename(struct _unmarshal_ctx *ctx, struct lib9p_msg_Trename *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_fid(ctx, &out->dfid); unmarshal_s(ctx, &out->name); } LM_FLATTEN static void unmarshal_Rreadlink(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rreadlink *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_s(ctx, &out->target); } LM_FLATTEN static void unmarshal_Txattrwalk(struct _unmarshal_ctx *ctx, struct lib9p_msg_Txattrwalk *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_fid(ctx, &out->newfid); unmarshal_s(ctx, &out->name); } LM_FLATTEN static void unmarshal_Txattrcreate(struct _unmarshal_ctx *ctx, struct lib9p_msg_Txattrcreate *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_s(ctx, &out->name); unmarshal_8(ctx, &out->attr_size); unmarshal_4(ctx, &out->flags); } LM_FLATTEN static void unmarshal_Tgetlock(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tgetlock *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_1(ctx, &out->type); unmarshal_8(ctx, &out->start); unmarshal_8(ctx, &out->length); unmarshal_4(ctx, &out->proc_id); unmarshal_s(ctx, &out->client_id); } LM_FLATTEN static void unmarshal_Rgetlock(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rgetlock *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_1(ctx, &out->type); unmarshal_8(ctx, &out->start); unmarshal_8(ctx, &out->length); unmarshal_4(ctx, &out->proc_id); unmarshal_s(ctx, &out->client_id); } LM_FLATTEN static void unmarshal_Tlink(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tlink *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->dfid); unmarshal_fid(ctx, &out->fid); unmarshal_s(ctx, &out->name); } LM_FLATTEN static void unmarshal_Trenameat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Trenameat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->olddirfid); unmarshal_s(ctx, &out->oldname); unmarshal_fid(ctx, &out->newdirfid); unmarshal_s(ctx, &out->newname); } LM_FLATTEN static void unmarshal_Tunlinkat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tunlinkat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->dirfd); unmarshal_s(ctx, &out->name); unmarshal_4(ctx, &out->flags); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e LM_FLATTEN static void unmarshal_Tsread(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tsread *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->fid); unmarshal_2(ctx, &out->nwname); out->wname = ctx->extra; ctx->extra += sizeof(out->wname[0]) * out->nwname; for (typeof(out->nwname) i = 0; i < out->nwname; i++) unmarshal_s(ctx, &out->wname[i]); } LM_FLATTEN static void unmarshal_Tswrite(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tswrite *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_4(ctx, &out->fid); unmarshal_2(ctx, &out->nwname); out->wname = ctx->extra; ctx->extra += sizeof(out->wname[0]) * out->nwname; for (typeof(out->nwname) i = 0; i < out->nwname; i++) unmarshal_s(ctx, &out->wname[i]); unmarshal_4(ctx, &out->count); out->data = ctx->extra; ctx->extra += sizeof(out->data[0]) * out->count; for (typeof(out->count) i = 0; i < out->count; i++) unmarshal_1(ctx, (uint8_t *)&out->data[i]); } #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static void unmarshal_qid(struct _unmarshal_ctx *ctx, struct lib9p_qid *out) { memset(out, 0, sizeof(*out)); unmarshal_qt(ctx, &out->type); unmarshal_4(ctx, &out->vers); unmarshal_8(ctx, &out->path); } LM_FLATTEN static void unmarshal_Tauth(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tauth *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->afid); unmarshal_s(ctx, &out->uname); unmarshal_s(ctx, &out->aname); #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u if ( ( is_ver(ctx, 9P2000_L) || is_ver(ctx, 9P2000_u) ) ) unmarshal_nuid(ctx, &out->n_uid); #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ } LM_FLATTEN static void unmarshal_Tattach(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tattach *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_fid(ctx, &out->afid); unmarshal_s(ctx, &out->uname); unmarshal_s(ctx, &out->aname); #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u if ( ( is_ver(ctx, 9P2000_L) || is_ver(ctx, 9P2000_u) ) ) unmarshal_nuid(ctx, &out->n_uid); #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static void unmarshal_Tlcreate(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tlcreate *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_s(ctx, &out->name); unmarshal_4(ctx, &out->flags); unmarshal_4(ctx, &out->mode); unmarshal_nuid(ctx, &out->gid); } LM_FLATTEN static void unmarshal_Tsymlink(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tsymlink *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_s(ctx, &out->name); unmarshal_s(ctx, &out->symtgt); unmarshal_nuid(ctx, &out->gid); } LM_FLATTEN static void unmarshal_Tmknod(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tmknod *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->dfid); unmarshal_s(ctx, &out->name); unmarshal_4(ctx, &out->mode); unmarshal_4(ctx, &out->major); unmarshal_4(ctx, &out->minor); unmarshal_nuid(ctx, &out->gid); } LM_FLATTEN static void unmarshal_Tmkdir(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tmkdir *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->dfid); unmarshal_s(ctx, &out->name); unmarshal_4(ctx, &out->mode); unmarshal_nuid(ctx, &out->gid); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Topen(struct _unmarshal_ctx *ctx, struct lib9p_msg_Topen *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_o(ctx, &out->mode); } LM_FLATTEN static void unmarshal_Tcreate(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tcreate *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_s(ctx, &out->name); unmarshal_dm(ctx, &out->perm); unmarshal_o(ctx, &out->mode); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_p9p LM_FLATTEN static void unmarshal_Topenfd(struct _unmarshal_ctx *ctx, struct lib9p_msg_Topenfd *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_o(ctx, &out->mode); } #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static void unmarshal_Tgetattr(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tgetattr *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_getattr(ctx, &out->request_mask); } LM_FLATTEN static void unmarshal_Tsetattr(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tsetattr *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_setattr(ctx, &out->valid); unmarshal_4(ctx, &out->mode); unmarshal_nuid(ctx, &out->uid); unmarshal_nuid(ctx, &out->gid); unmarshal_8(ctx, &out->filesize); unmarshal_8(ctx, &out->atime_sec); unmarshal_8(ctx, &out->atime_nsec); unmarshal_8(ctx, &out->mtime_sec); unmarshal_8(ctx, &out->mtime_nsec); } LM_FLATTEN static void unmarshal_Tlock(struct _unmarshal_ctx *ctx, struct lib9p_msg_Tlock *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); unmarshal_lock_type(ctx, &out->type); unmarshal_lock_flags(ctx, &out->flags); unmarshal_8(ctx, &out->start); unmarshal_8(ctx, &out->length); unmarshal_4(ctx, &out->proc_id); unmarshal_s(ctx, &out->client_id); } LM_FLATTEN static void unmarshal_Rlock(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rlock *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_lock_status(ctx, &out->status); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static void unmarshal_stat(struct _unmarshal_ctx *ctx, struct lib9p_stat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 2; unmarshal_2(ctx, &out->kern_type); unmarshal_4(ctx, &out->kern_dev); unmarshal_qid(ctx, &out->file_qid); unmarshal_dm(ctx, &out->file_mode); unmarshal_4(ctx, &out->file_atime); unmarshal_4(ctx, &out->file_mtime); unmarshal_8(ctx, &out->file_size); unmarshal_s(ctx, &out->file_name); unmarshal_s(ctx, &out->file_owner_uid); unmarshal_s(ctx, &out->file_owner_gid); unmarshal_s(ctx, &out->file_last_modified_uid); #if CONFIG_9P_ENABLE_9P2000_u if ( is_ver(ctx, 9P2000_u) ) unmarshal_s(ctx, &out->file_extension); if ( is_ver(ctx, 9P2000_u) ) unmarshal_nuid(ctx, &out->file_owner_n_uid); if ( is_ver(ctx, 9P2000_u) ) unmarshal_nuid(ctx, &out->file_owner_n_gid); if ( is_ver(ctx, 9P2000_u) ) unmarshal_nuid(ctx, &out->file_last_modified_n_uid); #endif /* CONFIG_9P_ENABLE_9P2000_u */ } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Rauth(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rauth *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->aqid); } LM_FLATTEN static void unmarshal_Rattach(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rattach *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); } LM_FLATTEN static void unmarshal_Rwalk(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rwalk *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_2(ctx, &out->nwqid); out->wqid = ctx->extra; ctx->extra += sizeof(out->wqid[0]) * out->nwqid; for (typeof(out->nwqid) i = 0; i < out->nwqid; i++) unmarshal_qid(ctx, &out->wqid[i]); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Ropen(struct _unmarshal_ctx *ctx, struct lib9p_msg_Ropen *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); unmarshal_4(ctx, &out->iounit); } LM_FLATTEN static void unmarshal_Rcreate(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rcreate *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); unmarshal_4(ctx, &out->iounit); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_p9p LM_FLATTEN static void unmarshal_Ropenfd(struct _unmarshal_ctx *ctx, struct lib9p_msg_Ropenfd *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); unmarshal_4(ctx, &out->iounit); unmarshal_4(ctx, &out->unixfd); } #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static void unmarshal_Rlopen(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rlopen *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); unmarshal_4(ctx, &out->iounit); } LM_FLATTEN static void unmarshal_Rlcreate(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rlcreate *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); unmarshal_4(ctx, &out->iounit); } LM_FLATTEN static void unmarshal_Rsymlink(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rsymlink *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); } LM_FLATTEN static void unmarshal_Rmknod(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rmknod *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); } LM_FLATTEN static void unmarshal_Rgetattr(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rgetattr *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_8(ctx, &out->valid); unmarshal_qid(ctx, &out->qid); unmarshal_4(ctx, &out->mode); unmarshal_nuid(ctx, &out->uid); unmarshal_nuid(ctx, &out->gid); unmarshal_8(ctx, &out->nlink); unmarshal_8(ctx, &out->rdev); unmarshal_8(ctx, &out->filesize); unmarshal_8(ctx, &out->blksize); unmarshal_8(ctx, &out->blocks); unmarshal_8(ctx, &out->atime_sec); unmarshal_8(ctx, &out->atime_nsec); unmarshal_8(ctx, &out->mtime_sec); unmarshal_8(ctx, &out->mtime_nsec); unmarshal_8(ctx, &out->ctime_sec); unmarshal_8(ctx, &out->ctime_nsec); unmarshal_8(ctx, &out->btime_sec); unmarshal_8(ctx, &out->btime_nsec); unmarshal_8(ctx, &out->gen); unmarshal_8(ctx, &out->data_version); } LM_FLATTEN static void unmarshal_Rmkdir(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rmkdir *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_qid(ctx, &out->qid); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static void unmarshal_Rstat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Rstat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); ctx->net_offset += 2; unmarshal_stat(ctx, &out->stat); } LM_FLATTEN static void unmarshal_Twstat(struct _unmarshal_ctx *ctx, struct lib9p_msg_Twstat *out) { memset(out, 0, sizeof(*out)); ctx->net_offset += 4; ctx->net_offset += 1; unmarshal_tag(ctx, &out->tag); unmarshal_fid(ctx, &out->fid); ctx->net_offset += 2; unmarshal_stat(ctx, &out->stat); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ /* marshal_* ******************************************************************/ LM_ALWAYS_INLINE static bool _marshal_too_large(struct _marshal_ctx *ctx) { lib9p_errorf(ctx->ctx, LINUX_ERANGE, "%s too large to marshal into %s limit (limit=%"PRIu32")", (ctx->net_bytes[4] % 2 == 0) ? "T-message" : "R-message", ctx->ctx->version ? "negotiated" : ((ctx->net_bytes[4] % 2 == 0) ? "client" : "server"), ctx->ctx->max_msg_size); return true; } LM_ALWAYS_INLINE static bool marshal_1(struct _marshal_ctx *ctx, uint8_t *val) { if (ctx->net_offset + 1 > ctx->ctx->max_msg_size) return _marshal_too_large(ctx); ctx->net_bytes[ctx->net_offset] = *val; ctx->net_offset += 1; return false; } LM_ALWAYS_INLINE static bool marshal_2(struct _marshal_ctx *ctx, uint16_t *val) { if (ctx->net_offset + 2 > ctx->ctx->max_msg_size) return _marshal_too_large(ctx); uint16le_encode(&ctx->net_bytes[ctx->net_offset], *val); ctx->net_offset += 2; return false; } LM_ALWAYS_INLINE static bool marshal_4(struct _marshal_ctx *ctx, uint32_t *val) { if (ctx->net_offset + 4 > ctx->ctx->max_msg_size) return true; uint32le_encode(&ctx->net_bytes[ctx->net_offset], *val); ctx->net_offset += 4; return false; } LM_ALWAYS_INLINE static bool marshal_8(struct _marshal_ctx *ctx, uint64_t *val) { if (ctx->net_offset + 8 > ctx->ctx->max_msg_size) return true; uint64le_encode(&ctx->net_bytes[ctx->net_offset], *val); ctx->net_offset += 8; return false; } #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool marshal_tag(struct _marshal_ctx *ctx, lib9p_tag_t *val) { return marshal_2(ctx, (uint16_t *)val); } LM_ALWAYS_INLINE static bool marshal_fid(struct _marshal_ctx *ctx, lib9p_fid_t *val) { return marshal_4(ctx, (uint32_t *)val); } LM_ALWAYS_INLINE static bool marshal_s(struct _marshal_ctx *ctx, struct lib9p_s *val) { return false || marshal_2(ctx, &val->len) || ({ bool err = false; for (typeof(val->len) i = 0; i < val->len && !err; i++) err = marshal_1(ctx, (uint8_t *)&val->utf8[i]); err; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool marshal_dm(struct _marshal_ctx *ctx, lib9p_dm_t *val) { lib9p_dm_t masked_val = *val & dm_masks[ctx->ctx->version]; return marshal_4(ctx, (uint32_t *)&masked_val); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool marshal_qt(struct _marshal_ctx *ctx, lib9p_qt_t *val) { lib9p_qt_t masked_val = *val & qt_masks[ctx->ctx->version]; return marshal_1(ctx, (uint8_t *)&masked_val); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool marshal_nuid(struct _marshal_ctx *ctx, lib9p_nuid_t *val) { return marshal_4(ctx, (uint32_t *)val); } #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool marshal_o(struct _marshal_ctx *ctx, lib9p_o_t *val) { lib9p_o_t masked_val = *val & o_masks[ctx->ctx->version]; return marshal_1(ctx, (uint8_t *)&masked_val); } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_ALWAYS_INLINE static bool marshal_getattr(struct _marshal_ctx *ctx, lib9p_getattr_t *val) { lib9p_getattr_t masked_val = *val & getattr_masks[ctx->ctx->version]; return marshal_8(ctx, (uint64_t *)&masked_val); } LM_ALWAYS_INLINE static bool marshal_setattr(struct _marshal_ctx *ctx, lib9p_setattr_t *val) { lib9p_setattr_t masked_val = *val & setattr_masks[ctx->ctx->version]; return marshal_4(ctx, (uint32_t *)&masked_val); } LM_ALWAYS_INLINE static bool marshal_lock_type(struct _marshal_ctx *ctx, lib9p_lock_type_t *val) { return marshal_1(ctx, (uint8_t *)val); } LM_ALWAYS_INLINE static bool marshal_lock_flags(struct _marshal_ctx *ctx, lib9p_lock_flags_t *val) { lib9p_lock_flags_t masked_val = *val & lock_flags_masks[ctx->ctx->version]; return marshal_4(ctx, (uint32_t *)&masked_val); } LM_ALWAYS_INLINE static bool marshal_lock_status(struct _marshal_ctx *ctx, lib9p_lock_status_t *val) { return marshal_1(ctx, (uint8_t *)val); } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Tflush(struct _marshal_ctx *ctx, struct lib9p_msg_Tflush *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_2(ctx, &val->oldtag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 108; false; }) ; } LM_FLATTEN static bool marshal_Rflush(struct _marshal_ctx *ctx, struct lib9p_msg_Rflush *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 109; false; }) ; } LM_FLATTEN static bool marshal_Rread(struct _marshal_ctx *ctx, struct lib9p_msg_Rread *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->count) || ({ bool err = false; for (typeof(val->count) i = 0; i < val->count && !err; i++) err = marshal_1(ctx, (uint8_t *)&val->data[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 117; false; }) ; } LM_FLATTEN static bool marshal_Rwrite(struct _marshal_ctx *ctx, struct lib9p_msg_Rwrite *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->count) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 119; false; }) ; } LM_FLATTEN static bool marshal_Rclunk(struct _marshal_ctx *ctx, struct lib9p_msg_Rclunk *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 121; false; }) ; } LM_FLATTEN static bool marshal_Rremove(struct _marshal_ctx *ctx, struct lib9p_msg_Rremove *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 123; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Rwstat(struct _marshal_ctx *ctx, struct lib9p_msg_Rwstat *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 127; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool marshal_Rlerror(struct _marshal_ctx *ctx, struct lib9p_msg_Rlerror *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->ecode) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 7; false; }) ; } LM_FLATTEN static bool marshal_Rstatfs(struct _marshal_ctx *ctx, struct lib9p_msg_Rstatfs *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->type) || marshal_4(ctx, &val->bsize) || marshal_8(ctx, &val->blocks) || marshal_8(ctx, &val->bfree) || marshal_8(ctx, &val->bavail) || marshal_8(ctx, &val->files) || marshal_8(ctx, &val->ffree) || marshal_8(ctx, &val->fsid) || marshal_4(ctx, &val->namelen) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 9; false; }) ; } LM_FLATTEN static bool marshal_Rrename(struct _marshal_ctx *ctx, struct lib9p_msg_Rrename *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 21; false; }) ; } LM_FLATTEN static bool marshal_Rsetattr(struct _marshal_ctx *ctx, struct lib9p_msg_Rsetattr *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 27; false; }) ; } LM_FLATTEN static bool marshal_Rxattrwalk(struct _marshal_ctx *ctx, struct lib9p_msg_Rxattrwalk *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_8(ctx, &val->attr_size) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 31; false; }) ; } LM_FLATTEN static bool marshal_Rxattrcreate(struct _marshal_ctx *ctx, struct lib9p_msg_Rxattrcreate *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 33; false; }) ; } LM_FLATTEN static bool marshal_Rreaddir(struct _marshal_ctx *ctx, struct lib9p_msg_Rreaddir *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->count) || ({ bool err = false; for (typeof(val->count) i = 0; i < val->count && !err; i++) err = marshal_1(ctx, (uint8_t *)&val->data[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 41; false; }) ; } LM_FLATTEN static bool marshal_Rfsync(struct _marshal_ctx *ctx, struct lib9p_msg_Rfsync *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 51; false; }) ; } LM_FLATTEN static bool marshal_Rlink(struct _marshal_ctx *ctx, struct lib9p_msg_Rlink *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 71; false; }) ; } LM_FLATTEN static bool marshal_Rrenameat(struct _marshal_ctx *ctx, struct lib9p_msg_Rrenameat *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 75; false; }) ; } LM_FLATTEN static bool marshal_Runlinkat(struct _marshal_ctx *ctx, struct lib9p_msg_Runlinkat *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 77; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e LM_FLATTEN static bool marshal_Tsession(struct _marshal_ctx *ctx, struct lib9p_msg_Tsession *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_8(ctx, &val->key) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 150; false; }) ; } LM_FLATTEN static bool marshal_Rsession(struct _marshal_ctx *ctx, struct lib9p_msg_Rsession *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 151; false; }) ; } LM_FLATTEN static bool marshal_Rsread(struct _marshal_ctx *ctx, struct lib9p_msg_Rsread *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->count) || ({ bool err = false; for (typeof(val->count) i = 0; i < val->count && !err; i++) err = marshal_1(ctx, (uint8_t *)&val->data[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 153; false; }) ; } LM_FLATTEN static bool marshal_Rswrite(struct _marshal_ctx *ctx, struct lib9p_msg_Rswrite *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->count) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 155; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Tread(struct _marshal_ctx *ctx, struct lib9p_msg_Tread *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_8(ctx, &val->offset) || marshal_4(ctx, &val->count) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 116; false; }) ; } LM_FLATTEN static bool marshal_Twrite(struct _marshal_ctx *ctx, struct lib9p_msg_Twrite *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_8(ctx, &val->offset) || marshal_4(ctx, &val->count) || ({ bool err = false; for (typeof(val->count) i = 0; i < val->count && !err; i++) err = marshal_1(ctx, (uint8_t *)&val->data[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 118; false; }) ; } LM_FLATTEN static bool marshal_Tclunk(struct _marshal_ctx *ctx, struct lib9p_msg_Tclunk *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 120; false; }) ; } LM_FLATTEN static bool marshal_Tremove(struct _marshal_ctx *ctx, struct lib9p_msg_Tremove *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 122; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Tstat(struct _marshal_ctx *ctx, struct lib9p_msg_Tstat *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 124; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool marshal_Tstatfs(struct _marshal_ctx *ctx, struct lib9p_msg_Tstatfs *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 8; false; }) ; } LM_FLATTEN static bool marshal_Tlopen(struct _marshal_ctx *ctx, struct lib9p_msg_Tlopen *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_4(ctx, &val->flags) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 12; false; }) ; } LM_FLATTEN static bool marshal_Treadlink(struct _marshal_ctx *ctx, struct lib9p_msg_Treadlink *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 22; false; }) ; } LM_FLATTEN static bool marshal_Treaddir(struct _marshal_ctx *ctx, struct lib9p_msg_Treaddir *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_8(ctx, &val->offset) || marshal_4(ctx, &val->count) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 40; false; }) ; } LM_FLATTEN static bool marshal_Tfsync(struct _marshal_ctx *ctx, struct lib9p_msg_Tfsync *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_4(ctx, &val->datasync) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 50; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Tversion(struct _marshal_ctx *ctx, struct lib9p_msg_Tversion *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->max_msg_size) || marshal_s(ctx, &val->version) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 100; false; }) ; } LM_FLATTEN static bool marshal_Rversion(struct _marshal_ctx *ctx, struct lib9p_msg_Rversion *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->max_msg_size) || marshal_s(ctx, &val->version) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 101; false; }) ; } LM_FLATTEN static bool marshal_Rerror(struct _marshal_ctx *ctx, struct lib9p_msg_Rerror *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_s(ctx, &val->ename) #if CONFIG_9P_ENABLE_9P2000_u || ( is_ver(ctx, 9P2000_u) && marshal_4(ctx, &val->errno) ) #endif /* CONFIG_9P_ENABLE_9P2000_u */ || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 107; false; }) ; } LM_FLATTEN static bool marshal_Twalk(struct _marshal_ctx *ctx, struct lib9p_msg_Twalk *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_fid(ctx, &val->newfid) || marshal_2(ctx, &val->nwname) || ({ bool err = false; for (typeof(val->nwname) i = 0; i < val->nwname && !err; i++) err = marshal_s(ctx, &val->wname[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 110; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool marshal_Trename(struct _marshal_ctx *ctx, struct lib9p_msg_Trename *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_fid(ctx, &val->dfid) || marshal_s(ctx, &val->name) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 20; false; }) ; } LM_FLATTEN static bool marshal_Rreadlink(struct _marshal_ctx *ctx, struct lib9p_msg_Rreadlink *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_s(ctx, &val->target) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 23; false; }) ; } LM_FLATTEN static bool marshal_Txattrwalk(struct _marshal_ctx *ctx, struct lib9p_msg_Txattrwalk *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_fid(ctx, &val->newfid) || marshal_s(ctx, &val->name) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 30; false; }) ; } LM_FLATTEN static bool marshal_Txattrcreate(struct _marshal_ctx *ctx, struct lib9p_msg_Txattrcreate *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_s(ctx, &val->name) || marshal_8(ctx, &val->attr_size) || marshal_4(ctx, &val->flags) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 32; false; }) ; } LM_FLATTEN static bool marshal_Tgetlock(struct _marshal_ctx *ctx, struct lib9p_msg_Tgetlock *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_1(ctx, &val->type) || marshal_8(ctx, &val->start) || marshal_8(ctx, &val->length) || marshal_4(ctx, &val->proc_id) || marshal_s(ctx, &val->client_id) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 54; false; }) ; } LM_FLATTEN static bool marshal_Rgetlock(struct _marshal_ctx *ctx, struct lib9p_msg_Rgetlock *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_1(ctx, &val->type) || marshal_8(ctx, &val->start) || marshal_8(ctx, &val->length) || marshal_4(ctx, &val->proc_id) || marshal_s(ctx, &val->client_id) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 55; false; }) ; } LM_FLATTEN static bool marshal_Tlink(struct _marshal_ctx *ctx, struct lib9p_msg_Tlink *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->dfid) || marshal_fid(ctx, &val->fid) || marshal_s(ctx, &val->name) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 70; false; }) ; } LM_FLATTEN static bool marshal_Trenameat(struct _marshal_ctx *ctx, struct lib9p_msg_Trenameat *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->olddirfid) || marshal_s(ctx, &val->oldname) || marshal_fid(ctx, &val->newdirfid) || marshal_s(ctx, &val->newname) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 74; false; }) ; } LM_FLATTEN static bool marshal_Tunlinkat(struct _marshal_ctx *ctx, struct lib9p_msg_Tunlinkat *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->dirfd) || marshal_s(ctx, &val->name) || marshal_4(ctx, &val->flags) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 76; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e LM_FLATTEN static bool marshal_Tsread(struct _marshal_ctx *ctx, struct lib9p_msg_Tsread *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->fid) || marshal_2(ctx, &val->nwname) || ({ bool err = false; for (typeof(val->nwname) i = 0; i < val->nwname && !err; i++) err = marshal_s(ctx, &val->wname[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 152; false; }) ; } LM_FLATTEN static bool marshal_Tswrite(struct _marshal_ctx *ctx, struct lib9p_msg_Tswrite *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_4(ctx, &val->fid) || marshal_2(ctx, &val->nwname) || ({ bool err = false; for (typeof(val->nwname) i = 0; i < val->nwname && !err; i++) err = marshal_s(ctx, &val->wname[i]); err; }) || marshal_4(ctx, &val->count) || ({ bool err = false; for (typeof(val->count) i = 0; i < val->count && !err; i++) err = marshal_1(ctx, (uint8_t *)&val->data[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 154; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool marshal_qid(struct _marshal_ctx *ctx, struct lib9p_qid *val) { return false || marshal_qt(ctx, &val->type) || marshal_4(ctx, &val->vers) || marshal_8(ctx, &val->path) ; } LM_FLATTEN static bool marshal_Tauth(struct _marshal_ctx *ctx, struct lib9p_msg_Tauth *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->afid) || marshal_s(ctx, &val->uname) || marshal_s(ctx, &val->aname) #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u || ( ( is_ver(ctx, 9P2000_L) || is_ver(ctx, 9P2000_u) ) && marshal_nuid(ctx, &val->n_uid) ) #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 102; false; }) ; } LM_FLATTEN static bool marshal_Tattach(struct _marshal_ctx *ctx, struct lib9p_msg_Tattach *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_fid(ctx, &val->afid) || marshal_s(ctx, &val->uname) || marshal_s(ctx, &val->aname) #if CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u || ( ( is_ver(ctx, 9P2000_L) || is_ver(ctx, 9P2000_u) ) && marshal_nuid(ctx, &val->n_uid) ) #endif /* CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_u */ || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 104; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool marshal_Tlcreate(struct _marshal_ctx *ctx, struct lib9p_msg_Tlcreate *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_s(ctx, &val->name) || marshal_4(ctx, &val->flags) || marshal_4(ctx, &val->mode) || marshal_nuid(ctx, &val->gid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 14; false; }) ; } LM_FLATTEN static bool marshal_Tsymlink(struct _marshal_ctx *ctx, struct lib9p_msg_Tsymlink *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_s(ctx, &val->name) || marshal_s(ctx, &val->symtgt) || marshal_nuid(ctx, &val->gid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 16; false; }) ; } LM_FLATTEN static bool marshal_Tmknod(struct _marshal_ctx *ctx, struct lib9p_msg_Tmknod *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->dfid) || marshal_s(ctx, &val->name) || marshal_4(ctx, &val->mode) || marshal_4(ctx, &val->major) || marshal_4(ctx, &val->minor) || marshal_nuid(ctx, &val->gid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 18; false; }) ; } LM_FLATTEN static bool marshal_Tmkdir(struct _marshal_ctx *ctx, struct lib9p_msg_Tmkdir *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->dfid) || marshal_s(ctx, &val->name) || marshal_4(ctx, &val->mode) || marshal_nuid(ctx, &val->gid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 72; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Topen(struct _marshal_ctx *ctx, struct lib9p_msg_Topen *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_o(ctx, &val->mode) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 112; false; }) ; } LM_FLATTEN static bool marshal_Tcreate(struct _marshal_ctx *ctx, struct lib9p_msg_Tcreate *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_s(ctx, &val->name) || marshal_dm(ctx, &val->perm) || marshal_o(ctx, &val->mode) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 114; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_p9p LM_FLATTEN static bool marshal_Topenfd(struct _marshal_ctx *ctx, struct lib9p_msg_Topenfd *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_o(ctx, &val->mode) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 98; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool marshal_Tgetattr(struct _marshal_ctx *ctx, struct lib9p_msg_Tgetattr *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_getattr(ctx, &val->request_mask) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 24; false; }) ; } LM_FLATTEN static bool marshal_Tsetattr(struct _marshal_ctx *ctx, struct lib9p_msg_Tsetattr *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_setattr(ctx, &val->valid) || marshal_4(ctx, &val->mode) || marshal_nuid(ctx, &val->uid) || marshal_nuid(ctx, &val->gid) || marshal_8(ctx, &val->filesize) || marshal_8(ctx, &val->atime_sec) || marshal_8(ctx, &val->atime_nsec) || marshal_8(ctx, &val->mtime_sec) || marshal_8(ctx, &val->mtime_nsec) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 26; false; }) ; } LM_FLATTEN static bool marshal_Tlock(struct _marshal_ctx *ctx, struct lib9p_msg_Tlock *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || marshal_lock_type(ctx, &val->type) || marshal_lock_flags(ctx, &val->flags) || marshal_8(ctx, &val->start) || marshal_8(ctx, &val->length) || marshal_4(ctx, &val->proc_id) || marshal_s(ctx, &val->client_id) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 52; false; }) ; } LM_FLATTEN static bool marshal_Rlock(struct _marshal_ctx *ctx, struct lib9p_msg_Rlock *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_lock_status(ctx, &val->status) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 53; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_ALWAYS_INLINE static bool marshal_stat(struct _marshal_ctx *ctx, struct lib9p_stat *val) { uint32_t _stat_size_offset; uint32_t _kern_type_offset; return false || ({ _stat_size_offset = ctx->net_offset; ({ ctx->net_offset += 2; false; }); }) || ({ _kern_type_offset = ctx->net_offset; marshal_2(ctx, &val->kern_type); }) || marshal_4(ctx, &val->kern_dev) || marshal_qid(ctx, &val->file_qid) || marshal_dm(ctx, &val->file_mode) || marshal_4(ctx, &val->file_atime) || marshal_4(ctx, &val->file_mtime) || marshal_8(ctx, &val->file_size) || marshal_s(ctx, &val->file_name) || marshal_s(ctx, &val->file_owner_uid) || marshal_s(ctx, &val->file_owner_gid) || marshal_s(ctx, &val->file_last_modified_uid) #if CONFIG_9P_ENABLE_9P2000_u || ( is_ver(ctx, 9P2000_u) && marshal_s(ctx, &val->file_extension) ) || ( is_ver(ctx, 9P2000_u) && marshal_nuid(ctx, &val->file_owner_n_uid) ) || ( is_ver(ctx, 9P2000_u) && marshal_nuid(ctx, &val->file_owner_n_gid) ) || ( is_ver(ctx, 9P2000_u) && marshal_nuid(ctx, &val->file_last_modified_n_uid) ) #endif /* CONFIG_9P_ENABLE_9P2000_u */ || ({ uint16le_encode(&ctx->net_bytes[_stat_size_offset], ctx->net_offset - _kern_type_offset); false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Rauth(struct _marshal_ctx *ctx, struct lib9p_msg_Rauth *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->aqid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 103; false; }) ; } LM_FLATTEN static bool marshal_Rattach(struct _marshal_ctx *ctx, struct lib9p_msg_Rattach *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 105; false; }) ; } LM_FLATTEN static bool marshal_Rwalk(struct _marshal_ctx *ctx, struct lib9p_msg_Rwalk *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_2(ctx, &val->nwqid) || ({ bool err = false; for (typeof(val->nwqid) i = 0; i < val->nwqid && !err; i++) err = marshal_qid(ctx, &val->wqid[i]); err; }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 111; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_L || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Ropen(struct _marshal_ctx *ctx, struct lib9p_msg_Ropen *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || marshal_4(ctx, &val->iounit) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 113; false; }) ; } LM_FLATTEN static bool marshal_Rcreate(struct _marshal_ctx *ctx, struct lib9p_msg_Rcreate *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || marshal_4(ctx, &val->iounit) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 115; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ #if CONFIG_9P_ENABLE_9P2000_p9p LM_FLATTEN static bool marshal_Ropenfd(struct _marshal_ctx *ctx, struct lib9p_msg_Ropenfd *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || marshal_4(ctx, &val->iounit) || marshal_4(ctx, &val->unixfd) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 99; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_L LM_FLATTEN static bool marshal_Rlopen(struct _marshal_ctx *ctx, struct lib9p_msg_Rlopen *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || marshal_4(ctx, &val->iounit) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 13; false; }) ; } LM_FLATTEN static bool marshal_Rlcreate(struct _marshal_ctx *ctx, struct lib9p_msg_Rlcreate *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || marshal_4(ctx, &val->iounit) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 15; false; }) ; } LM_FLATTEN static bool marshal_Rsymlink(struct _marshal_ctx *ctx, struct lib9p_msg_Rsymlink *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 17; false; }) ; } LM_FLATTEN static bool marshal_Rmknod(struct _marshal_ctx *ctx, struct lib9p_msg_Rmknod *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 19; false; }) ; } LM_FLATTEN static bool marshal_Rgetattr(struct _marshal_ctx *ctx, struct lib9p_msg_Rgetattr *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_8(ctx, &val->valid) || marshal_qid(ctx, &val->qid) || marshal_4(ctx, &val->mode) || marshal_nuid(ctx, &val->uid) || marshal_nuid(ctx, &val->gid) || marshal_8(ctx, &val->nlink) || marshal_8(ctx, &val->rdev) || marshal_8(ctx, &val->filesize) || marshal_8(ctx, &val->blksize) || marshal_8(ctx, &val->blocks) || marshal_8(ctx, &val->atime_sec) || marshal_8(ctx, &val->atime_nsec) || marshal_8(ctx, &val->mtime_sec) || marshal_8(ctx, &val->mtime_nsec) || marshal_8(ctx, &val->ctime_sec) || marshal_8(ctx, &val->ctime_nsec) || marshal_8(ctx, &val->btime_sec) || marshal_8(ctx, &val->btime_nsec) || marshal_8(ctx, &val->gen) || marshal_8(ctx, &val->data_version) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 25; false; }) ; } LM_FLATTEN static bool marshal_Rmkdir(struct _marshal_ctx *ctx, struct lib9p_msg_Rmkdir *val) { uint32_t _size_offset; uint32_t _typ_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_qid(ctx, &val->qid) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 73; false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u LM_FLATTEN static bool marshal_Rstat(struct _marshal_ctx *ctx, struct lib9p_msg_Rstat *val) { uint32_t _size_offset; uint32_t _typ_offset; uint32_t _nstat_offset; uint32_t _stat_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || ({ _nstat_offset = ctx->net_offset; ({ ctx->net_offset += 2; false; }); }) || ({ _stat_offset = ctx->net_offset; marshal_stat(ctx, &val->stat); }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 125; false; }) || ({ uint16le_encode(&ctx->net_bytes[_nstat_offset], ctx->net_offset - _stat_offset); false; }) ; } LM_FLATTEN static bool marshal_Twstat(struct _marshal_ctx *ctx, struct lib9p_msg_Twstat *val) { uint32_t _size_offset; uint32_t _typ_offset; uint32_t _nstat_offset; uint32_t _stat_offset; return false || ({ _size_offset = ctx->net_offset; ({ ctx->net_offset += 4; false; }); }) || ({ _typ_offset = ctx->net_offset; ({ ctx->net_offset += 1; false; }); }) || marshal_tag(ctx, &val->tag) || marshal_fid(ctx, &val->fid) || ({ _nstat_offset = ctx->net_offset; ({ ctx->net_offset += 2; false; }); }) || ({ _stat_offset = ctx->net_offset; marshal_stat(ctx, &val->stat); }) || ({ uint32le_encode(&ctx->net_bytes[_size_offset], ctx->net_offset - _size_offset); false; }) || ({ ctx->net_bytes[_typ_offset] = 126; false; }) || ({ uint16le_encode(&ctx->net_bytes[_nstat_offset], ctx->net_offset - _stat_offset); false; }) ; } #endif /* CONFIG_9P_ENABLE_9P2000 || CONFIG_9P_ENABLE_9P2000_e || CONFIG_9P_ENABLE_9P2000_p9p || CONFIG_9P_ENABLE_9P2000_u */ /* function tables ************************************************************/ #define _MSG_RECV(typ) [LIB9P_TYP_##typ/2] = { \ .basesize = sizeof(struct lib9p_msg_##typ), \ .validate = validate_##typ, \ .unmarshal = (_unmarshal_fn_t)unmarshal_##typ, \ } #define _MSG_SEND(typ) [LIB9P_TYP_##typ/2] = { \ .marshal = (_marshal_fn_t)marshal_##typ, \ } const struct _lib9p_recv_tentry _lib9p_table_Tmsg_recv[LIB9P_VER_NUM][0x80] = { [LIB9P_VER_unknown] = { _MSG_RECV(Tversion), }, #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = { _MSG_RECV(Tversion), _MSG_RECV(Tauth), _MSG_RECV(Tattach), _MSG_RECV(Tflush), _MSG_RECV(Twalk), _MSG_RECV(Topen), _MSG_RECV(Tcreate), _MSG_RECV(Tread), _MSG_RECV(Twrite), _MSG_RECV(Tclunk), _MSG_RECV(Tremove), _MSG_RECV(Tstat), _MSG_RECV(Twstat), }, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = { _MSG_RECV(Tstatfs), _MSG_RECV(Tlopen), _MSG_RECV(Tlcreate), _MSG_RECV(Tsymlink), _MSG_RECV(Tmknod), _MSG_RECV(Trename), _MSG_RECV(Treadlink), _MSG_RECV(Tgetattr), _MSG_RECV(Tsetattr), _MSG_RECV(Txattrwalk), _MSG_RECV(Txattrcreate), _MSG_RECV(Treaddir), _MSG_RECV(Tfsync), _MSG_RECV(Tlock), _MSG_RECV(Tgetlock), _MSG_RECV(Tlink), _MSG_RECV(Tmkdir), _MSG_RECV(Trenameat), _MSG_RECV(Tunlinkat), _MSG_RECV(Tversion), _MSG_RECV(Tauth), _MSG_RECV(Tattach), _MSG_RECV(Tflush), _MSG_RECV(Twalk), _MSG_RECV(Tread), _MSG_RECV(Twrite), _MSG_RECV(Tclunk), _MSG_RECV(Tremove), }, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = { _MSG_RECV(Tversion), _MSG_RECV(Tauth), _MSG_RECV(Tattach), _MSG_RECV(Tflush), _MSG_RECV(Twalk), _MSG_RECV(Topen), _MSG_RECV(Tcreate), _MSG_RECV(Tread), _MSG_RECV(Twrite), _MSG_RECV(Tclunk), _MSG_RECV(Tremove), _MSG_RECV(Tstat), _MSG_RECV(Twstat), _MSG_RECV(Tsession), _MSG_RECV(Tsread), _MSG_RECV(Tswrite), }, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = { _MSG_RECV(Topenfd), _MSG_RECV(Tversion), _MSG_RECV(Tauth), _MSG_RECV(Tattach), _MSG_RECV(Tflush), _MSG_RECV(Twalk), _MSG_RECV(Topen), _MSG_RECV(Tcreate), _MSG_RECV(Tread), _MSG_RECV(Twrite), _MSG_RECV(Tclunk), _MSG_RECV(Tremove), _MSG_RECV(Tstat), _MSG_RECV(Twstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = { _MSG_RECV(Tversion), _MSG_RECV(Tauth), _MSG_RECV(Tattach), _MSG_RECV(Tflush), _MSG_RECV(Twalk), _MSG_RECV(Topen), _MSG_RECV(Tcreate), _MSG_RECV(Tread), _MSG_RECV(Twrite), _MSG_RECV(Tclunk), _MSG_RECV(Tremove), _MSG_RECV(Tstat), _MSG_RECV(Twstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; const struct _lib9p_recv_tentry _lib9p_table_Rmsg_recv[LIB9P_VER_NUM][0x80] = { [LIB9P_VER_unknown] = { _MSG_RECV(Rversion), _MSG_RECV(Rerror), }, #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = { _MSG_RECV(Rversion), _MSG_RECV(Rauth), _MSG_RECV(Rattach), _MSG_RECV(Rerror), _MSG_RECV(Rflush), _MSG_RECV(Rwalk), _MSG_RECV(Ropen), _MSG_RECV(Rcreate), _MSG_RECV(Rread), _MSG_RECV(Rwrite), _MSG_RECV(Rclunk), _MSG_RECV(Rremove), _MSG_RECV(Rstat), _MSG_RECV(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = { _MSG_RECV(Rlerror), _MSG_RECV(Rstatfs), _MSG_RECV(Rlopen), _MSG_RECV(Rlcreate), _MSG_RECV(Rsymlink), _MSG_RECV(Rmknod), _MSG_RECV(Rrename), _MSG_RECV(Rreadlink), _MSG_RECV(Rgetattr), _MSG_RECV(Rsetattr), _MSG_RECV(Rxattrwalk), _MSG_RECV(Rxattrcreate), _MSG_RECV(Rreaddir), _MSG_RECV(Rfsync), _MSG_RECV(Rlock), _MSG_RECV(Rgetlock), _MSG_RECV(Rlink), _MSG_RECV(Rmkdir), _MSG_RECV(Rrenameat), _MSG_RECV(Runlinkat), _MSG_RECV(Rversion), _MSG_RECV(Rauth), _MSG_RECV(Rattach), _MSG_RECV(Rerror), _MSG_RECV(Rflush), _MSG_RECV(Rwalk), _MSG_RECV(Rread), _MSG_RECV(Rwrite), _MSG_RECV(Rclunk), _MSG_RECV(Rremove), }, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = { _MSG_RECV(Rversion), _MSG_RECV(Rauth), _MSG_RECV(Rattach), _MSG_RECV(Rerror), _MSG_RECV(Rflush), _MSG_RECV(Rwalk), _MSG_RECV(Ropen), _MSG_RECV(Rcreate), _MSG_RECV(Rread), _MSG_RECV(Rwrite), _MSG_RECV(Rclunk), _MSG_RECV(Rremove), _MSG_RECV(Rstat), _MSG_RECV(Rwstat), _MSG_RECV(Rsession), _MSG_RECV(Rsread), _MSG_RECV(Rswrite), }, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = { _MSG_RECV(Ropenfd), _MSG_RECV(Rversion), _MSG_RECV(Rauth), _MSG_RECV(Rattach), _MSG_RECV(Rerror), _MSG_RECV(Rflush), _MSG_RECV(Rwalk), _MSG_RECV(Ropen), _MSG_RECV(Rcreate), _MSG_RECV(Rread), _MSG_RECV(Rwrite), _MSG_RECV(Rclunk), _MSG_RECV(Rremove), _MSG_RECV(Rstat), _MSG_RECV(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = { _MSG_RECV(Rversion), _MSG_RECV(Rauth), _MSG_RECV(Rattach), _MSG_RECV(Rerror), _MSG_RECV(Rflush), _MSG_RECV(Rwalk), _MSG_RECV(Ropen), _MSG_RECV(Rcreate), _MSG_RECV(Rread), _MSG_RECV(Rwrite), _MSG_RECV(Rclunk), _MSG_RECV(Rremove), _MSG_RECV(Rstat), _MSG_RECV(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; const struct _lib9p_send_tentry _lib9p_table_Tmsg_send[LIB9P_VER_NUM][0x80] = { [LIB9P_VER_unknown] = { _MSG_SEND(Tversion), }, #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = { _MSG_SEND(Tversion), _MSG_SEND(Tauth), _MSG_SEND(Tattach), _MSG_SEND(Tflush), _MSG_SEND(Twalk), _MSG_SEND(Topen), _MSG_SEND(Tcreate), _MSG_SEND(Tread), _MSG_SEND(Twrite), _MSG_SEND(Tclunk), _MSG_SEND(Tremove), _MSG_SEND(Tstat), _MSG_SEND(Twstat), }, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = { _MSG_SEND(Tstatfs), _MSG_SEND(Tlopen), _MSG_SEND(Tlcreate), _MSG_SEND(Tsymlink), _MSG_SEND(Tmknod), _MSG_SEND(Trename), _MSG_SEND(Treadlink), _MSG_SEND(Tgetattr), _MSG_SEND(Tsetattr), _MSG_SEND(Txattrwalk), _MSG_SEND(Txattrcreate), _MSG_SEND(Treaddir), _MSG_SEND(Tfsync), _MSG_SEND(Tlock), _MSG_SEND(Tgetlock), _MSG_SEND(Tlink), _MSG_SEND(Tmkdir), _MSG_SEND(Trenameat), _MSG_SEND(Tunlinkat), _MSG_SEND(Tversion), _MSG_SEND(Tauth), _MSG_SEND(Tattach), _MSG_SEND(Tflush), _MSG_SEND(Twalk), _MSG_SEND(Tread), _MSG_SEND(Twrite), _MSG_SEND(Tclunk), _MSG_SEND(Tremove), }, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = { _MSG_SEND(Tversion), _MSG_SEND(Tauth), _MSG_SEND(Tattach), _MSG_SEND(Tflush), _MSG_SEND(Twalk), _MSG_SEND(Topen), _MSG_SEND(Tcreate), _MSG_SEND(Tread), _MSG_SEND(Twrite), _MSG_SEND(Tclunk), _MSG_SEND(Tremove), _MSG_SEND(Tstat), _MSG_SEND(Twstat), _MSG_SEND(Tsession), _MSG_SEND(Tsread), _MSG_SEND(Tswrite), }, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = { _MSG_SEND(Topenfd), _MSG_SEND(Tversion), _MSG_SEND(Tauth), _MSG_SEND(Tattach), _MSG_SEND(Tflush), _MSG_SEND(Twalk), _MSG_SEND(Topen), _MSG_SEND(Tcreate), _MSG_SEND(Tread), _MSG_SEND(Twrite), _MSG_SEND(Tclunk), _MSG_SEND(Tremove), _MSG_SEND(Tstat), _MSG_SEND(Twstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = { _MSG_SEND(Tversion), _MSG_SEND(Tauth), _MSG_SEND(Tattach), _MSG_SEND(Tflush), _MSG_SEND(Twalk), _MSG_SEND(Topen), _MSG_SEND(Tcreate), _MSG_SEND(Tread), _MSG_SEND(Twrite), _MSG_SEND(Tclunk), _MSG_SEND(Tremove), _MSG_SEND(Tstat), _MSG_SEND(Twstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; const struct _lib9p_send_tentry _lib9p_table_Rmsg_send[LIB9P_VER_NUM][0x80] = { [LIB9P_VER_unknown] = { _MSG_SEND(Rversion), _MSG_SEND(Rerror), }, #if CONFIG_9P_ENABLE_9P2000 [LIB9P_VER_9P2000] = { _MSG_SEND(Rversion), _MSG_SEND(Rauth), _MSG_SEND(Rattach), _MSG_SEND(Rerror), _MSG_SEND(Rflush), _MSG_SEND(Rwalk), _MSG_SEND(Ropen), _MSG_SEND(Rcreate), _MSG_SEND(Rread), _MSG_SEND(Rwrite), _MSG_SEND(Rclunk), _MSG_SEND(Rremove), _MSG_SEND(Rstat), _MSG_SEND(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000 */ #if CONFIG_9P_ENABLE_9P2000_L [LIB9P_VER_9P2000_L] = { _MSG_SEND(Rlerror), _MSG_SEND(Rstatfs), _MSG_SEND(Rlopen), _MSG_SEND(Rlcreate), _MSG_SEND(Rsymlink), _MSG_SEND(Rmknod), _MSG_SEND(Rrename), _MSG_SEND(Rreadlink), _MSG_SEND(Rgetattr), _MSG_SEND(Rsetattr), _MSG_SEND(Rxattrwalk), _MSG_SEND(Rxattrcreate), _MSG_SEND(Rreaddir), _MSG_SEND(Rfsync), _MSG_SEND(Rlock), _MSG_SEND(Rgetlock), _MSG_SEND(Rlink), _MSG_SEND(Rmkdir), _MSG_SEND(Rrenameat), _MSG_SEND(Runlinkat), _MSG_SEND(Rversion), _MSG_SEND(Rauth), _MSG_SEND(Rattach), _MSG_SEND(Rerror), _MSG_SEND(Rflush), _MSG_SEND(Rwalk), _MSG_SEND(Rread), _MSG_SEND(Rwrite), _MSG_SEND(Rclunk), _MSG_SEND(Rremove), }, #endif /* CONFIG_9P_ENABLE_9P2000_L */ #if CONFIG_9P_ENABLE_9P2000_e [LIB9P_VER_9P2000_e] = { _MSG_SEND(Rversion), _MSG_SEND(Rauth), _MSG_SEND(Rattach), _MSG_SEND(Rerror), _MSG_SEND(Rflush), _MSG_SEND(Rwalk), _MSG_SEND(Ropen), _MSG_SEND(Rcreate), _MSG_SEND(Rread), _MSG_SEND(Rwrite), _MSG_SEND(Rclunk), _MSG_SEND(Rremove), _MSG_SEND(Rstat), _MSG_SEND(Rwstat), _MSG_SEND(Rsession), _MSG_SEND(Rsread), _MSG_SEND(Rswrite), }, #endif /* CONFIG_9P_ENABLE_9P2000_e */ #if CONFIG_9P_ENABLE_9P2000_p9p [LIB9P_VER_9P2000_p9p] = { _MSG_SEND(Ropenfd), _MSG_SEND(Rversion), _MSG_SEND(Rauth), _MSG_SEND(Rattach), _MSG_SEND(Rerror), _MSG_SEND(Rflush), _MSG_SEND(Rwalk), _MSG_SEND(Ropen), _MSG_SEND(Rcreate), _MSG_SEND(Rread), _MSG_SEND(Rwrite), _MSG_SEND(Rclunk), _MSG_SEND(Rremove), _MSG_SEND(Rstat), _MSG_SEND(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_p9p */ #if CONFIG_9P_ENABLE_9P2000_u [LIB9P_VER_9P2000_u] = { _MSG_SEND(Rversion), _MSG_SEND(Rauth), _MSG_SEND(Rattach), _MSG_SEND(Rerror), _MSG_SEND(Rflush), _MSG_SEND(Rwalk), _MSG_SEND(Ropen), _MSG_SEND(Rcreate), _MSG_SEND(Rread), _MSG_SEND(Rwrite), _MSG_SEND(Rclunk), _MSG_SEND(Rremove), _MSG_SEND(Rstat), _MSG_SEND(Rwstat), }, #endif /* CONFIG_9P_ENABLE_9P2000_u */ }; LM_FLATTEN bool _lib9p_stat_validate(struct _validate_ctx *ctx) { return validate_stat(ctx); } LM_FLATTEN void _lib9p_stat_unmarshal(struct _unmarshal_ctx *ctx, struct lib9p_stat *out) { unmarshal_stat(ctx, out); } LM_FLATTEN bool _lib9p_stat_marshal(struct _marshal_ctx *ctx, struct lib9p_stat *val) { return marshal_stat(ctx, val); }