* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
-#include <errno.h>
-#include <stdio.h>
-#include <helper.h>
-#include <lttng/ust-events.h>
-#include <stdint.h>
-#include <errno.h>
-#include <string.h>
-#include <inttypes.h>
-#include <limits.h>
-#include "filter-bytecode.h"
-
-#define DEBUG //TEST
-
-#define NR_REG 2
-
-#ifndef min_t
-#define min_t(type, a, b) \
- ((type) (a) < (type) (b) ? (type) (a) : (type) (b))
-#endif
-
-#ifndef likely
-#define likely(x) __builtin_expect(!!(x), 1)
-#endif
-
-#ifndef unlikely
-#define unlikely(x) __builtin_expect(!!(x), 0)
-#endif
-
-#ifdef DEBUG
-#define dbg_printf(fmt, args...) printf("[debug bytecode] " fmt, ## args)
-#else
-#define dbg_printf(fmt, args...) \
-do { \
- /* do nothing but check printf format */ \
- if (0) \
- printf("[debug bytecode] " fmt, ## args); \
-} while (0)
-#endif
-
-/* Linked bytecode */
-struct bytecode_runtime {
- uint16_t len;
- char data[0];
-};
-
-struct reg {
- enum {
- REG_S64,
- REG_DOUBLE,
- REG_STRING,
- } type;
- int64_t v;
- double d;
-
- const char *str;
- size_t seq_len;
- int literal; /* is string literal ? */
-};
+#include "lttng-filter.h"
static const char *opnames[] = {
[ FILTER_OP_UNKNOWN ] = "UNKNOWN",
[ FILTER_OP_BIN_AND ] = "BIN_AND",
[ FILTER_OP_BIN_OR ] = "BIN_OR",
[ FILTER_OP_BIN_XOR ] = "BIN_XOR",
+
+ /* binary comparators */
[ FILTER_OP_EQ ] = "EQ",
[ FILTER_OP_NE ] = "NE",
[ FILTER_OP_GT ] = "GT",
[ FILTER_OP_GE ] = "GE",
[ FILTER_OP_LE ] = "LE",
+ /* string binary comparators */
+ [ FILTER_OP_EQ_STRING ] = "EQ_STRING",
+ [ FILTER_OP_NE_STRING ] = "NE_STRING",
+ [ FILTER_OP_GT_STRING ] = "GT_STRING",
+ [ FILTER_OP_LT_STRING ] = "LT_STRING",
+ [ FILTER_OP_GE_STRING ] = "GE_STRING",
+ [ FILTER_OP_LE_STRING ] = "LE_STRING",
+
+ /* s64 binary comparators */
+ [ FILTER_OP_EQ_S64 ] = "EQ_S64",
+ [ FILTER_OP_NE_S64 ] = "NE_S64",
+ [ FILTER_OP_GT_S64 ] = "GT_S64",
+ [ FILTER_OP_LT_S64 ] = "LT_S64",
+ [ FILTER_OP_GE_S64 ] = "GE_S64",
+ [ FILTER_OP_LE_S64 ] = "LE_S64",
+
+ /* double binary comparators */
+ [ FILTER_OP_EQ_DOUBLE ] = "EQ_DOUBLE",
+ [ FILTER_OP_NE_DOUBLE ] = "NE_DOUBLE",
+ [ FILTER_OP_GT_DOUBLE ] = "GT_DOUBLE",
+ [ FILTER_OP_LT_DOUBLE ] = "LT_DOUBLE",
+ [ FILTER_OP_GE_DOUBLE ] = "GE_DOUBLE",
+ [ FILTER_OP_LE_DOUBLE ] = "LE_DOUBLE",
+
+ /* Mixed S64-double binary comparators */
+ [ FILTER_OP_EQ_DOUBLE_S64 ] = "EQ_DOUBLE_S64",
+ [ FILTER_OP_NE_DOUBLE_S64 ] = "NE_DOUBLE_S64",
+ [ FILTER_OP_GT_DOUBLE_S64 ] = "GT_DOUBLE_S64",
+ [ FILTER_OP_LT_DOUBLE_S64 ] = "LT_DOUBLE_S64",
+ [ FILTER_OP_GE_DOUBLE_S64 ] = "GE_DOUBLE_S64",
+ [ FILTER_OP_LE_DOUBLE_S64 ] = "LE_DOUBLE_S64",
+
+ [ FILTER_OP_EQ_S64_DOUBLE ] = "EQ_S64_DOUBLE",
+ [ FILTER_OP_NE_S64_DOUBLE ] = "NE_S64_DOUBLE",
+ [ FILTER_OP_GT_S64_DOUBLE ] = "GT_S64_DOUBLE",
+ [ FILTER_OP_LT_S64_DOUBLE ] = "LT_S64_DOUBLE",
+ [ FILTER_OP_GE_S64_DOUBLE ] = "GE_S64_DOUBLE",
+ [ FILTER_OP_LE_S64_DOUBLE ] = "LE_S64_DOUBLE",
+
/* unary */
[ FILTER_OP_UNARY_PLUS ] = "UNARY_PLUS",
[ FILTER_OP_UNARY_MINUS ] = "UNARY_MINUS",
[ FILTER_OP_UNARY_NOT ] = "UNARY_NOT",
+ [ FILTER_OP_UNARY_PLUS_S64 ] = "UNARY_PLUS_S64",
+ [ FILTER_OP_UNARY_MINUS_S64 ] = "UNARY_MINUS_S64",
+ [ FILTER_OP_UNARY_NOT_S64 ] = "UNARY_NOT_S64",
+ [ FILTER_OP_UNARY_PLUS_DOUBLE ] = "UNARY_PLUS_DOUBLE",
+ [ FILTER_OP_UNARY_MINUS_DOUBLE ] = "UNARY_MINUS_DOUBLE",
+ [ FILTER_OP_UNARY_NOT_DOUBLE ] = "UNARY_NOT_DOUBLE",
/* logical */
[ FILTER_OP_AND ] = "AND",
/* load */
[ FILTER_OP_LOAD_FIELD_REF ] = "LOAD_FIELD_REF",
+ [ FILTER_OP_LOAD_FIELD_REF_STRING ] = "LOAD_FIELD_REF_STRING",
+ [ FILTER_OP_LOAD_FIELD_REF_SEQUENCE ] = "LOAD_FIELD_REF_SEQUENCE",
+ [ FILTER_OP_LOAD_FIELD_REF_S64 ] = "LOAD_FIELD_REF_S64",
+ [ FILTER_OP_LOAD_FIELD_REF_DOUBLE ] = "LOAD_FIELD_REF_DOUBLE",
+
[ FILTER_OP_LOAD_STRING ] = "LOAD_STRING",
[ FILTER_OP_LOAD_S64 ] = "LOAD_S64",
[ FILTER_OP_LOAD_DOUBLE ] = "LOAD_DOUBLE",
+
+ /* cast */
+ [ FILTER_OP_CAST_TO_S64 ] = "CAST_TO_S64",
+ [ FILTER_OP_CAST_DOUBLE_TO_S64 ] = "CAST_DOUBLE_TO_S64",
+ [ FILTER_OP_CAST_NOP ] = "CAST_NOP",
};
-static
const char *print_op(enum filter_op op)
{
if (op >= NR_FILTER_OPS)
return opnames[op];
}
-/*
- * -1: wildcard found.
- * -2: unknown escape char.
- * 0: normal char.
- */
-
-static
-int parse_char(const char **p)
-{
- switch (**p) {
- case '\\':
- (*p)++;
- switch (**p) {
- case '\\':
- case '*':
- return 0;
- default:
- return -2;
- }
- case '*':
- return -1;
- default:
- return 0;
- }
-}
-
-static
-int reg_strcmp(struct reg reg[NR_REG], const char *cmp_type)
-{
- const char *p = reg[REG_R0].str, *q = reg[REG_R1].str;
- int ret;
- int diff;
-
- for (;;) {
- int escaped_r0 = 0;
-
- if (unlikely(p - reg[REG_R0].str > reg[REG_R0].seq_len || *p == '\0')) {
- if (q - reg[REG_R1].str > reg[REG_R1].seq_len || *q == '\0')
- diff = 0;
- else
- diff = -1;
- break;
- }
- if (unlikely(q - reg[REG_R1].str > reg[REG_R1].seq_len || *q == '\0')) {
- if (p - reg[REG_R0].str > reg[REG_R0].seq_len || *p == '\0')
- diff = 0;
- else
- diff = 1;
- break;
- }
- if (reg[REG_R0].literal) {
- ret = parse_char(&p);
- if (ret == -1) {
- return 0;
- } else if (ret == -2) {
- escaped_r0 = 1;
- }
- /* else compare both char */
- }
- if (reg[REG_R1].literal) {
- ret = parse_char(&q);
- if (ret == -1) {
- return 0;
- } else if (ret == -2) {
- if (!escaped_r0)
- return -1;
- } else {
- if (escaped_r0)
- return 1;
- }
- } else {
- if (escaped_r0)
- return 1;
- }
- diff = *p - *q;
- if (diff != 0)
- break;
- p++;
- q++;
- }
- return diff;
-}
-
-static
-int lttng_filter_false(void *filter_data,
- const char *filter_stack_data)
-{
- return 0;
-}
-
-static
-int lttng_filter_interpret_bytecode(void *filter_data,
- const char *filter_stack_data)
-{
- struct bytecode_runtime *bytecode = filter_data;
- void *pc, *next_pc, *start_pc;
- int ret = -EINVAL;
- int retval = 0;
- struct reg reg[NR_REG];
- int i;
-
- for (i = 0; i < NR_REG; i++) {
- reg[i].type = REG_S64;
- reg[i].v = 0;
- reg[i].d = 0.0;
- reg[i].str = NULL;
- reg[i].seq_len = 0;
- reg[i].literal = 0;
- }
-
- start_pc = &bytecode->data[0];
- for (pc = next_pc = start_pc; pc - start_pc < bytecode->len;
- pc = next_pc) {
- if (unlikely(pc >= start_pc + bytecode->len)) {
- fprintf(stderr, "[error] filter bytecode overflow\n");
- ret = -EINVAL;
- goto end;
- }
- dbg_printf("Executing op %s (%u)\n",
- print_op((unsigned int) *(filter_opcode_t *) pc),
- (unsigned int) *(filter_opcode_t *) pc);
- switch (*(filter_opcode_t *) pc) {
- case FILTER_OP_UNKNOWN:
- default:
- fprintf(stderr, "[error] unknown bytecode op %u\n",
- (unsigned int) *(filter_opcode_t *) pc);
- ret = -EINVAL;
- goto end;
-
- case FILTER_OP_RETURN:
- retval = !!reg[0].v;
- ret = 0;
- goto end;
-
- /* binary */
- case FILTER_OP_MUL:
- case FILTER_OP_DIV:
- case FILTER_OP_MOD:
- case FILTER_OP_PLUS:
- case FILTER_OP_MINUS:
- case FILTER_OP_RSHIFT:
- case FILTER_OP_LSHIFT:
- case FILTER_OP_BIN_AND:
- case FILTER_OP_BIN_OR:
- case FILTER_OP_BIN_XOR:
- fprintf(stderr, "[error] unsupported bytecode op %u\n",
- (unsigned int) *(filter_opcode_t *) pc);
- ret = -EINVAL;
- goto end;
-
- case FILTER_OP_EQ:
- {
- if (unlikely((reg[REG_R0].type == REG_STRING && reg[REG_R1].type != REG_STRING)
- || (reg[REG_R0].type != REG_STRING && reg[REG_R1].type == REG_STRING))) {
- fprintf(stderr, "[error] type mismatch for '==' binary operator\n");
- ret = -EINVAL;
- goto end;
- }
- switch (reg[REG_R0].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- reg[REG_R0].v = (reg_strcmp(reg, "==") == 0);
- break;
- case REG_S64:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].v == reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].v == reg[REG_R1].d);
- break;
- }
- break;
- case REG_DOUBLE:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].d == reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].d == reg[REG_R1].d);
- break;
- }
- break;
- }
- reg[REG_R0].type = REG_S64;
- next_pc += sizeof(struct binary_op);
- break;
- }
- case FILTER_OP_NE:
- {
- if (unlikely((reg[REG_R0].type == REG_STRING && reg[REG_R1].type != REG_STRING)
- || (reg[REG_R0].type != REG_STRING && reg[REG_R1].type == REG_STRING))) {
- fprintf(stderr, "[error] type mismatch for '!=' binary operator\n");
- ret = -EINVAL;
- goto end;
- }
- switch (reg[REG_R0].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- reg[REG_R0].v = (reg_strcmp(reg, "!=") != 0);
- break;
- case REG_S64:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].v != reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].v != reg[REG_R1].d);
- break;
- }
- break;
- case REG_DOUBLE:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].d != reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].d != reg[REG_R1].d);
- break;
- }
- break;
- }
- reg[REG_R0].type = REG_S64;
- next_pc += sizeof(struct binary_op);
- break;
- }
- case FILTER_OP_GT:
- {
- if (unlikely((reg[REG_R0].type == REG_STRING && reg[REG_R1].type != REG_STRING)
- || (reg[REG_R0].type != REG_STRING && reg[REG_R1].type == REG_STRING))) {
- fprintf(stderr, "[error] type mismatch for '>' binary operator\n");
- ret = -EINVAL;
- goto end;
- }
- switch (reg[REG_R0].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- reg[REG_R0].v = (reg_strcmp(reg, ">") > 0);
- break;
- case REG_S64:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].v > reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].v > reg[REG_R1].d);
- break;
- }
- break;
- case REG_DOUBLE:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].d > reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].d > reg[REG_R1].d);
- break;
- }
- break;
- }
- reg[REG_R0].type = REG_S64;
- next_pc += sizeof(struct binary_op);
- break;
- }
- case FILTER_OP_LT:
- {
- if (unlikely((reg[REG_R0].type == REG_STRING && reg[REG_R1].type != REG_STRING)
- || (reg[REG_R0].type != REG_STRING && reg[REG_R1].type == REG_STRING))) {
- fprintf(stderr, "[error] type mismatch for '<' binary operator\n");
- ret = -EINVAL;
- goto end;
- }
- switch (reg[REG_R0].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- reg[REG_R0].v = (reg_strcmp(reg, "<") < 0);
- break;
- case REG_S64:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].v < reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].v < reg[REG_R1].d);
- break;
- }
- break;
- case REG_DOUBLE:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].d < reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].d < reg[REG_R1].d);
- break;
- }
- break;
- }
- reg[REG_R0].type = REG_S64;
- next_pc += sizeof(struct binary_op);
- break;
- }
- case FILTER_OP_GE:
- {
- if (unlikely((reg[REG_R0].type == REG_STRING && reg[REG_R1].type != REG_STRING)
- || (reg[REG_R0].type != REG_STRING && reg[REG_R1].type == REG_STRING))) {
- fprintf(stderr, "[error] type mismatch for '>=' binary operator\n");
- ret = -EINVAL;
- goto end;
- }
- switch (reg[REG_R0].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- reg[REG_R0].v = (reg_strcmp(reg, ">=") >= 0);
- break;
- case REG_S64:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].v >= reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].v >= reg[REG_R1].d);
- break;
- }
- break;
- case REG_DOUBLE:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].d >= reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].d >= reg[REG_R1].d);
- break;
- }
- break;
- }
- reg[REG_R0].type = REG_S64;
- next_pc += sizeof(struct binary_op);
- break;
- }
- case FILTER_OP_LE:
- {
- if (unlikely((reg[REG_R0].type == REG_STRING && reg[REG_R1].type != REG_STRING)
- || (reg[REG_R0].type != REG_STRING && reg[REG_R1].type == REG_STRING))) {
- fprintf(stderr, "[error] type mismatch for '<=' binary operator\n");
- ret = -EINVAL;
- goto end;
- }
- switch (reg[REG_R0].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- reg[REG_R0].v = (reg_strcmp(reg, "<=") <= 0);
- break;
- case REG_S64:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].v <= reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].v <= reg[REG_R1].d);
- break;
- }
- break;
- case REG_DOUBLE:
- switch (reg[REG_R1].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_S64:
- reg[REG_R0].v = (reg[REG_R0].d <= reg[REG_R1].v);
- break;
- case REG_DOUBLE:
- reg[REG_R0].v = (reg[REG_R0].d <= reg[REG_R1].d);
- break;
- }
- break;
- }
- reg[REG_R0].type = REG_S64;
- next_pc += sizeof(struct binary_op);
- break;
- }
-
- /* unary */
- case FILTER_OP_UNARY_PLUS:
- {
- struct unary_op *insn = (struct unary_op *) pc;
-
- if (unlikely(insn->reg >= REG_ERROR)) {
- fprintf(stderr, "[error] invalid register %u\n",
- (unsigned int) insn->reg);
- ret = -EINVAL;
- goto end;
- }
- switch (reg[insn->reg].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- fprintf(stderr, "[error] Unary plus can only be applied to numeric or floating point registers\n");
- ret = -EINVAL;
- goto end;
- case REG_S64:
- break;
- case REG_DOUBLE:
- break;
- }
- next_pc += sizeof(struct unary_op);
- break;
- }
- case FILTER_OP_UNARY_MINUS:
- {
- struct unary_op *insn = (struct unary_op *) pc;
-
- if (unlikely(insn->reg >= REG_ERROR)) {
- fprintf(stderr, "[error] invalid register %u\n",
- (unsigned int) insn->reg);
- ret = -EINVAL;
- goto end;
- }
- switch (reg[insn->reg].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- fprintf(stderr, "[error] Unary minus can only be applied to numeric or floating point registers\n");
- ret = -EINVAL;
- goto end;
- case REG_S64:
- reg[insn->reg].v = -reg[insn->reg].v;
- break;
- case REG_DOUBLE:
- reg[insn->reg].d = -reg[insn->reg].d;
- break;
- }
- next_pc += sizeof(struct unary_op);
- break;
- }
- case FILTER_OP_UNARY_NOT:
- {
- struct unary_op *insn = (struct unary_op *) pc;
-
- if (unlikely(insn->reg >= REG_ERROR)) {
- fprintf(stderr, "[error] invalid register %u\n",
- (unsigned int) insn->reg);
- ret = -EINVAL;
- goto end;
- }
- switch (reg[insn->reg].type) {
- default:
- fprintf(stderr, "[error] unknown register type\n");
- ret = -EINVAL;
- goto end;
-
- case REG_STRING:
- fprintf(stderr, "[error] Unary not can only be applied to numeric or floating point registers\n");
- ret = -EINVAL;
- goto end;
- case REG_S64:
- reg[insn->reg].v = !reg[insn->reg].v;
- break;
- case REG_DOUBLE:
- reg[insn->reg].d = !reg[insn->reg].d;
- break;
- }
- if (unlikely(reg[insn->reg].type != REG_S64)) {
- fprintf(stderr, "[error] Unary not can only be applied to numeric register\n");
- ret = -EINVAL;
- goto end;
- }
- reg[insn->reg].v = !reg[insn->reg].v;
- next_pc += sizeof(struct unary_op);
- break;
- }
- /* logical */
- case FILTER_OP_AND:
- {
- struct logical_op *insn = (struct logical_op *) pc;
-
- if (unlikely(reg[REG_R0].type == REG_STRING)) {
- fprintf(stderr, "[error] Logical operator 'and' can only be applied to numeric and floating point registers\n");
- ret = -EINVAL;
- goto end;
- }
-
- /* If REG_R0 is 0, skip and evaluate to 0 */
- if ((reg[REG_R0].type == REG_S64 && reg[REG_R0].v == 0)
- || (reg[REG_R0].type == REG_DOUBLE && reg[REG_R0].d == 0.0)) {
- dbg_printf("Jumping to bytecode offset %u\n",
- (unsigned int) insn->skip_offset);
- next_pc = start_pc + insn->skip_offset;
- if (unlikely(next_pc <= pc)) {
- fprintf(stderr, "[error] Loops are not allowed in bytecode\n");
- ret = -EINVAL;
- goto end;
- }
- } else {
- next_pc += sizeof(struct logical_op);
- }
- break;
- }
- case FILTER_OP_OR:
- {
- struct logical_op *insn = (struct logical_op *) pc;
-
- if (unlikely(reg[REG_R0].type == REG_STRING)) {
- fprintf(stderr, "[error] Logical operator 'or' can only be applied to numeric and floating point registers\n");
- ret = -EINVAL;
- goto end;
- }
-
- /* If REG_R0 is nonzero, skip and evaluate to 1 */
-
- if ((reg[REG_R0].type == REG_S64 && reg[REG_R0].v != 0)
- || (reg[REG_R0].type == REG_DOUBLE && reg[REG_R0].d != 0.0)) {
- reg[REG_R0].v = 1;
- dbg_printf("Jumping to bytecode offset %u\n",
- (unsigned int) insn->skip_offset);
- next_pc = start_pc + insn->skip_offset;
- if (unlikely(next_pc <= pc)) {
- fprintf(stderr, "[error] Loops are not allowed in bytecode\n");
- ret = -EINVAL;
- goto end;
- }
- } else {
- next_pc += sizeof(struct logical_op);
- }
- break;
- }
-
- /* load */
- case FILTER_OP_LOAD_FIELD_REF:
- {
- struct load_op *insn = (struct load_op *) pc;
- struct field_ref *ref = (struct field_ref *) insn->data;
-
- if (unlikely(insn->reg >= REG_ERROR)) {
- fprintf(stderr, "[error] invalid register %u\n",
- (unsigned int) insn->reg);
- ret = -EINVAL;
- goto end;
- }
- dbg_printf("load field ref offset %u type %u\n",
- ref->offset, ref->type);
- switch (ref->type) {
- case FIELD_REF_UNKNOWN:
- default:
- fprintf(stderr, "[error] unknown field ref type\n");
- ret = -EINVAL;
- goto end;
-
- case FIELD_REF_STRING:
- reg[insn->reg].str =
- *(const char * const *) &filter_stack_data[ref->offset];
- reg[insn->reg].type = REG_STRING;
- reg[insn->reg].seq_len = UINT_MAX;
- reg[insn->reg].literal = 0;
- dbg_printf("ref load string %s\n", reg[insn->reg].str);
- break;
- case FIELD_REF_SEQUENCE:
- reg[insn->reg].seq_len =
- *(unsigned long *) &filter_stack_data[ref->offset];
- reg[insn->reg].str =
- *(const char **) (&filter_stack_data[ref->offset
- + sizeof(unsigned long)]);
- reg[insn->reg].type = REG_STRING;
- reg[insn->reg].literal = 0;
- break;
- case FIELD_REF_S64:
- memcpy(®[insn->reg].v, &filter_stack_data[ref->offset],
- sizeof(struct literal_numeric));
- reg[insn->reg].type = REG_S64;
- reg[insn->reg].literal = 0;
- dbg_printf("ref load s64 %" PRIi64 "\n", reg[insn->reg].v);
- break;
- case FIELD_REF_DOUBLE:
- memcpy(®[insn->reg].d, &filter_stack_data[ref->offset],
- sizeof(struct literal_double));
- reg[insn->reg].type = REG_DOUBLE;
- reg[insn->reg].literal = 0;
- dbg_printf("ref load double %g\n", reg[insn->reg].d);
- break;
- }
-
- next_pc += sizeof(struct load_op) + sizeof(struct field_ref);
- break;
- }
-
- case FILTER_OP_LOAD_STRING:
- {
- struct load_op *insn = (struct load_op *) pc;
-
- if (unlikely(insn->reg >= REG_ERROR)) {
- fprintf(stderr, "[error] invalid register %u\n",
- (unsigned int) insn->reg);
- ret = -EINVAL;
- goto end;
- }
- dbg_printf("load string %s\n", insn->data);
- reg[insn->reg].str = insn->data;
- reg[insn->reg].type = REG_STRING;
- reg[insn->reg].seq_len = UINT_MAX;
- reg[insn->reg].literal = 1;
- next_pc += sizeof(struct load_op) + strlen(insn->data) + 1;
- break;
- }
-
- case FILTER_OP_LOAD_S64:
- {
- struct load_op *insn = (struct load_op *) pc;
-
- if (unlikely(insn->reg >= REG_ERROR)) {
- fprintf(stderr, "[error] invalid register %u\n",
- (unsigned int) insn->reg);
- ret = -EINVAL;
- goto end;
- }
- memcpy(®[insn->reg].v, insn->data,
- sizeof(struct literal_numeric));
- dbg_printf("load s64 %" PRIi64 "\n", reg[insn->reg].v);
- reg[insn->reg].type = REG_S64;
- next_pc += sizeof(struct load_op)
- + sizeof(struct literal_numeric);
- break;
- }
-
- case FILTER_OP_LOAD_DOUBLE:
- {
- struct load_op *insn = (struct load_op *) pc;
-
- if (unlikely(insn->reg >= REG_ERROR)) {
- fprintf(stderr, "[error] invalid register %u\n",
- (unsigned int) insn->reg);
- ret = -EINVAL;
- goto end;
- }
- memcpy(®[insn->reg].d, insn->data,
- sizeof(struct literal_double));
- dbg_printf("load s64 %g\n", reg[insn->reg].d);
- reg[insn->reg].type = REG_DOUBLE;
- next_pc += sizeof(struct load_op)
- + sizeof(struct literal_double);
- break;
- }
- }
- }
-end:
- /* return 0 (discard) on error */
- if (ret)
- return 0;
- return retval;
-}
-
static
int apply_field_reloc(struct ltt_event *event,
struct bytecode_runtime *runtime,
const struct lttng_event_field *fields, *field = NULL;
unsigned int nr_fields, i;
struct field_ref *field_ref;
+ struct load_op *op;
uint32_t field_offset = 0;
dbg_printf("Apply reloc: %u %s\n", reloc_offset, field_name);
return -EINVAL;
/* set type */
- field_ref = (struct field_ref *) &runtime->data[reloc_offset];
+ op = (struct load_op *) &runtime->data[reloc_offset];
+ field_ref = (struct field_ref *) op->data;
switch (field->type.atype) {
case atype_integer:
case atype_enum:
- field_ref->type = FIELD_REF_S64;
- field_ref->type = FIELD_REF_S64;
+ op->op = FILTER_OP_LOAD_FIELD_REF_S64;
break;
case atype_array:
case atype_sequence:
- field_ref->type = FIELD_REF_SEQUENCE;
+ op->op = FILTER_OP_LOAD_FIELD_REF_SEQUENCE;
break;
case atype_string:
- field_ref->type = FIELD_REF_STRING;
+ op->op = FILTER_OP_LOAD_FIELD_REF_STRING;
break;
case atype_float:
- field_ref->type = FIELD_REF_DOUBLE;
+ op->op = FILTER_OP_LOAD_FIELD_REF_DOUBLE;
break;
default:
return -EINVAL;
}
next_offset = offset + sizeof(uint16_t) + strlen(field_name) + 1;
}
+ /* Validate bytecode */
+ ret = lttng_filter_validate_bytecode(runtime);
+ if (ret) {
+ goto link_error;
+ }
+ /* Specialize bytecode */
+ ret = lttng_filter_specialize_bytecode(runtime);
+ if (ret) {
+ goto link_error;
+ }
event->filter_data = runtime;
event->filter = lttng_filter_interpret_bytecode;
return 0;