tools/perf/util/expr.y - linux - Git at Google

 /* Simple expression parser */
 %{
 #define YYDEBUG 1
 #include <assert.h>
 #include <math.h>
 #include <stdlib.h>
 #include "util/debug.h"
 #define IN_EXPR_Y 1
 #include "expr.h"
 %}

 %define api.pure full

 %parse-param { double *final_val }
 %parse-param { struct expr_parse_ctx *ctx }
 %parse-param { bool compute_ids }
 %parse-param {void *scanner}
 %lex-param {void* scanner}

 %union {
 	double	 num;
 	char	*str;
 	struct ids {
 		/*
 		 * When creating ids, holds the working set of event ids. NULL
 		 * implies the set is empty.
 		 */
 		struct hashmap *ids;
 		/*
 		 * The metric value. When not creating ids this is the value
 		 * read from a counter, a constant or some computed value. When
 		 * creating ids the value is either a constant or BOTTOM. NAN is
 		 * used as the special BOTTOM value, representing a "set of all
 		 * values" case.
 		 */
 		double val;
 	} ids;
 }

 %token ID NUMBER MIN MAX IF ELSE LITERAL D_RATIO SOURCE_COUNT EXPR_ERROR
 %left MIN MAX IF
 %left '|'
 %left '^'
 %left '&'
 %left '<' '>'
 %left '-' '+'
 %left '*' '/' '%'
 %left NEG NOT
 %type <num> NUMBER LITERAL
 %type <str> ID
 %destructor { free ($$); } <str>
 %type <ids> expr if_expr
 %destructor { ids__free($$.ids); } <ids>

 %{
 static void expr_error(double *final_val __maybe_unused,
 		       struct expr_parse_ctx *ctx __maybe_unused,
 		       bool compute_ids __maybe_unused,
 		       void *scanner,
 		       const char *s)
 {
 	pr_debug("%s\n", s);
 }

 /*
  * During compute ids, the special "bottom" value uses NAN to represent the set
  * of all values. NAN is selected as it isn't a useful constant value.
  */
 #define BOTTOM NAN

 /* During computing ids, does val represent a constant (non-BOTTOM) value? */
 static bool is_const(double val)
 {
 	return isfinite(val);
 }

 static struct ids union_expr(struct ids ids1, struct ids ids2)
 {
 	struct ids result = {
 		.val = BOTTOM,
 		.ids = ids__union(ids1.ids, ids2.ids),
 	};
 	return result;
 }

 static struct ids handle_id(struct expr_parse_ctx *ctx, char *id,
 			    bool compute_ids, bool source_count)
 {
 	struct ids result;

 	if (!compute_ids) {
 		/*
 		 * Compute the event's value from ID. If the ID isn't known then
 		 * it isn't used to compute the formula so set to NAN.
 		 */
 		struct expr_id_data *data;

 		result.val = NAN;
 		if (expr__resolve_id(ctx, id, &data) == 0) {
 			result.val = source_count
 				? expr_id_data__source_count(data)
 				: expr_id_data__value(data);
 		}
 		result.ids = NULL;
 		free(id);
 	} else {
 		/*
 		 * Set the value to BOTTOM to show that any value is possible
 		 * when the event is computed. Create a set of just the ID.
 		 */
 		result.val = BOTTOM;
 		result.ids = ids__new();
 		if (!result.ids || ids__insert(result.ids, id)) {
 			pr_err("Error creating IDs for '%s'", id);
 			free(id);
 		}
 	}
 	return result;
 }

 /*
  * If we're not computing ids or $1 and $3 are constants, compute the new
  * constant value using OP. Its invariant that there are no ids.  If computing
  * ids for non-constants union the set of IDs that must be computed.
  */
 #define BINARY_LONG_OP(RESULT, OP, LHS, RHS)				\
 	if (!compute_ids || (is_const(LHS.val) && is_const(RHS.val))) { \
 		assert(LHS.ids == NULL);				\
 		assert(RHS.ids == NULL);				\
 		RESULT.val = (long)LHS.val OP (long)RHS.val;		\
 		RESULT.ids = NULL;					\
 	} else {							\
 	        RESULT = union_expr(LHS, RHS);				\
 	}

 #define BINARY_OP(RESULT, OP, LHS, RHS)					\
 	if (!compute_ids || (is_const(LHS.val) && is_const(RHS.val))) { \
 		assert(LHS.ids == NULL);				\
 		assert(RHS.ids == NULL);				\
 		RESULT.val = LHS.val OP RHS.val;			\
 		RESULT.ids = NULL;					\
 	} else {							\
 	        RESULT = union_expr(LHS, RHS);				\
 	}

 %}
 %%

 start: if_expr
 {
 	if (compute_ids)
 		ctx->ids = ids__union($1.ids, ctx->ids);

 	if (final_val)
 		*final_val = $1.val;
 }
 ;

 if_expr: expr IF expr ELSE expr
 {
 	if (fpclassify($3.val) == FP_ZERO) {
 		/*
 		 * The IF expression evaluated to 0 so treat as false, take the
 		 * ELSE and discard everything else.
 		 */
 		$$.val = $5.val;
 		$$.ids = $5.ids;
 		ids__free($1.ids);
 		ids__free($3.ids);
 	} else if (!compute_ids || is_const($3.val)) {
 		/*
 		 * If ids aren't computed then treat the expression as true. If
 		 * ids are being computed and the IF expr is a non-zero
 		 * constant, then also evaluate the true case.
 		 */
 		$$.val = $1.val;
 		$$.ids = $1.ids;
 		ids__free($3.ids);
 		ids__free($5.ids);
 	} else if ($1.val == $5.val) {
 		/*
 		 * LHS == RHS, so both are an identical constant. No need to
 		 * evaluate any events.
 		 */
 		$$.val = $1.val;
 		$$.ids = NULL;
 		ids__free($1.ids);
 		ids__free($3.ids);
 		ids__free($5.ids);
 	} else {
 		/*
 		 * Value is either the LHS or RHS and we need the IF expression
 		 * to compute it.
 		 */
 		$$ = union_expr($1, union_expr($3, $5));
 	}
 }
 | expr
 ;

 expr: NUMBER
 {
 	$$.val = $1;
 	$$.ids = NULL;
 }
 | ID				{ $$ = handle_id(ctx, $1, compute_ids, /*source_count=*/false); }
 | SOURCE_COUNT '(' ID ')'	{ $$ = handle_id(ctx, $3, compute_ids, /*source_count=*/true); }
 | expr '|' expr { BINARY_LONG_OP($$, |, $1, $3); }
 | expr '&' expr { BINARY_LONG_OP($$, &, $1, $3); }
 | expr '^' expr { BINARY_LONG_OP($$, ^, $1, $3); }
 | expr '<' expr { BINARY_OP($$, <, $1, $3); }
 | expr '>' expr { BINARY_OP($$, >, $1, $3); }
 | expr '+' expr { BINARY_OP($$, +, $1, $3); }
 | expr '-' expr { BINARY_OP($$, -, $1, $3); }
 | expr '*' expr { BINARY_OP($$, *, $1, $3); }
 | expr '/' expr
 {
 	if (fpclassify($3.val) == FP_ZERO) {
 		pr_debug("division by zero\n");
 		YYABORT;
 	} else if (!compute_ids || (is_const($1.val) && is_const($3.val))) {
 		assert($1.ids == NULL);
 		assert($3.ids == NULL);
 		$$.val = $1.val / $3.val;
 		$$.ids = NULL;
 	} else {
 		/* LHS and/or RHS need computing from event IDs so union. */
 		$$ = union_expr($1, $3);
 	}
 }
 | expr '%' expr
 {
 	if (fpclassify($3.val) == FP_ZERO) {
 		pr_debug("division by zero\n");
 		YYABORT;
 	} else if (!compute_ids || (is_const($1.val) && is_const($3.val))) {
 		assert($1.ids == NULL);
 		assert($3.ids == NULL);
 		$$.val = (long)$1.val % (long)$3.val;
 		$$.ids = NULL;
 	} else {
 		/* LHS and/or RHS need computing from event IDs so union. */
 		$$ = union_expr($1, $3);
 	}
 }
 | D_RATIO '(' expr ',' expr ')'
 {
 	if (fpclassify($5.val) == FP_ZERO) {
 		/*
 		 * Division by constant zero always yields zero and no events
 		 * are necessary.
 		 */
 		assert($5.ids == NULL);
 		$$.val = 0.0;
 		$$.ids = NULL;
 		ids__free($3.ids);
 	} else if (!compute_ids || (is_const($3.val) && is_const($5.val))) {
 		assert($3.ids == NULL);
 		assert($5.ids == NULL);
 		$$.val = $3.val / $5.val;
 		$$.ids = NULL;
 	} else {
 		/* LHS and/or RHS need computing from event IDs so union. */
 		$$ = union_expr($3, $5);
 	}
 }
 | '-' expr %prec NEG
 {
 	$$.val = -$2.val;
 	$$.ids = $2.ids;
 }
 | '(' if_expr ')'
 {
 	$$ = $2;
 }
 | MIN '(' expr ',' expr ')'
 {
 	if (!compute_ids) {
 		$$.val = $3.val < $5.val ? $3.val : $5.val;
 		$$.ids = NULL;
 	} else {
 		$$ = union_expr($3, $5);
 	}
 }
 | MAX '(' expr ',' expr ')'
 {
 	if (!compute_ids) {
 		$$.val = $3.val > $5.val ? $3.val : $5.val;
 		$$.ids = NULL;
 	} else {
 		$$ = union_expr($3, $5);
 	}
 }
 | LITERAL
 {
 	$$.val = $1;
 	$$.ids = NULL;
 }
 ;

 %%
	/* Simple expression parser */
	%{
	#define YYDEBUG 1
	#include <assert.h>
	#include <math.h>
	#include <stdlib.h>
	#include "util/debug.h"
	#define IN_EXPR_Y 1
	#include "expr.h"
	%}

	%define api.pure full

	%parse-param { double *final_val }
	%parse-param { struct expr_parse_ctx *ctx }
	%parse-param { bool compute_ids }
	%parse-param {void *scanner}
	%lex-param {void* scanner}

	%union {
	double num;
	char *str;
	struct ids {
	/*
	* When creating ids, holds the working set of event ids. NULL
	* implies the set is empty.
	*/
	struct hashmap *ids;
	/*
	* The metric value. When not creating ids this is the value
	* read from a counter, a constant or some computed value. When
	* creating ids the value is either a constant or BOTTOM. NAN is
	* used as the special BOTTOM value, representing a "set of all
	* values" case.
	*/
	double val;
	} ids;
	}

	%token ID NUMBER MIN MAX IF ELSE LITERAL D_RATIO SOURCE_COUNT EXPR_ERROR
	%left MIN MAX IF
	%left '\|'
	%left '^'
	%left '&'
	%left '<' '>'
	%left '-' '+'
	%left '*' '/' '%'
	%left NEG NOT
	%type <num> NUMBER LITERAL
	%type <str> ID
	%destructor { free ($$); } <str>
	%type <ids> expr if_expr
	%destructor { ids__free($$.ids); } <ids>

	%{
	static void expr_error(double *final_val __maybe_unused,
	struct expr_parse_ctx *ctx __maybe_unused,
	bool compute_ids __maybe_unused,
	void *scanner,
	const char *s)
	{
	pr_debug("%s\n", s);
	}

	/*
	* During compute ids, the special "bottom" value uses NAN to represent the set
	* of all values. NAN is selected as it isn't a useful constant value.
	*/
	#define BOTTOM NAN

	/* During computing ids, does val represent a constant (non-BOTTOM) value? */
	static bool is_const(double val)
	{
	return isfinite(val);
	}

	static struct ids union_expr(struct ids ids1, struct ids ids2)
	{
	struct ids result = {
	.val = BOTTOM,
	.ids = ids__union(ids1.ids, ids2.ids),
	};
	return result;
	}

	static struct ids handle_id(struct expr_parse_ctx ctx, char id,
	bool compute_ids, bool source_count)
	{
	struct ids result;

	if (!compute_ids) {
	/*
	* Compute the event's value from ID. If the ID isn't known then
	* it isn't used to compute the formula so set to NAN.
	*/
	struct expr_id_data *data;

	result.val = NAN;
	if (expr__resolve_id(ctx, id, &data) == 0) {
	result.val = source_count
	? expr_id_data__source_count(data)
	: expr_id_data__value(data);
	}
	result.ids = NULL;
	free(id);
	} else {
	/*
	* Set the value to BOTTOM to show that any value is possible
	* when the event is computed. Create a set of just the ID.
	*/
	result.val = BOTTOM;
	result.ids = ids__new();
	if (!result.ids \|\| ids__insert(result.ids, id)) {
	pr_err("Error creating IDs for '%s'", id);
	free(id);
	}
	}
	return result;
	}

	/*
	* If we're not computing ids or $1 and $3 are constants, compute the new
	* constant value using OP. Its invariant that there are no ids. If computing
	* ids for non-constants union the set of IDs that must be computed.
	*/
	#define BINARY_LONG_OP(RESULT, OP, LHS, RHS) \
	if (!compute_ids \|\| (is_const(LHS.val) && is_const(RHS.val))) { \
	assert(LHS.ids == NULL); \
	assert(RHS.ids == NULL); \
	RESULT.val = (long)LHS.val OP (long)RHS.val; \
	RESULT.ids = NULL; \
	} else { \
	RESULT = union_expr(LHS, RHS); \
	}

	#define BINARY_OP(RESULT, OP, LHS, RHS) \
	if (!compute_ids \|\| (is_const(LHS.val) && is_const(RHS.val))) { \
	assert(LHS.ids == NULL); \
	assert(RHS.ids == NULL); \
	RESULT.val = LHS.val OP RHS.val; \
	RESULT.ids = NULL; \
	} else { \
	RESULT = union_expr(LHS, RHS); \
	}

	%}
	%%

	start: if_expr
	{
	if (compute_ids)
	ctx->ids = ids__union($1.ids, ctx->ids);

	if (final_val)
	*final_val = $1.val;
	}
	;

	if_expr: expr IF expr ELSE expr
	{
	if (fpclassify($3.val) == FP_ZERO) {
	/*
	* The IF expression evaluated to 0 so treat as false, take the
	* ELSE and discard everything else.
	*/
	$$.val = $5.val;
	$$.ids = $5.ids;
	ids__free($1.ids);
	ids__free($3.ids);
	} else if (!compute_ids \|\| is_const($3.val)) {
	/*
	* If ids aren't computed then treat the expression as true. If
	* ids are being computed and the IF expr is a non-zero
	* constant, then also evaluate the true case.
	*/
	$$.val = $1.val;
	$$.ids = $1.ids;
	ids__free($3.ids);
	ids__free($5.ids);
	} else if ($1.val == $5.val) {
	/*
	* LHS == RHS, so both are an identical constant. No need to
	* evaluate any events.
	*/
	$$.val = $1.val;
	$$.ids = NULL;
	ids__free($1.ids);
	ids__free($3.ids);
	ids__free($5.ids);
	} else {
	/*
	* Value is either the LHS or RHS and we need the IF expression
	* to compute it.
	*/
	$$ = union_expr($1, union_expr($3, $5));
	}
	}
	\| expr
	;

	expr: NUMBER
	{
	$$.val = $1;
	$$.ids = NULL;
	}
	\| ID { $$ = handle_id(ctx, $1, compute_ids, /source_count=/false); }
	\| SOURCE_COUNT '(' ID ')' { $$ = handle_id(ctx, $3, compute_ids, /source_count=/true); }
	\| expr '\|' expr { BINARY_LONG_OP($$, \|, $1, $3); }
	\| expr '&' expr { BINARY_LONG_OP($$, &, $1, $3); }
	\| expr '^' expr { BINARY_LONG_OP($$, ^, $1, $3); }
	\| expr '<' expr { BINARY_OP($$, <, $1, $3); }
	\| expr '>' expr { BINARY_OP($$, >, $1, $3); }
	\| expr '+' expr { BINARY_OP($$, +, $1, $3); }
	\| expr '-' expr { BINARY_OP($$, -, $1, $3); }
	\| expr '' expr { BINARY_OP($$, , $1, $3); }
	\| expr '/' expr
	{
	if (fpclassify($3.val) == FP_ZERO) {
	pr_debug("division by zero\n");
	YYABORT;
	} else if (!compute_ids \|\| (is_const($1.val) && is_const($3.val))) {
	assert($1.ids == NULL);
	assert($3.ids == NULL);
	$$.val = $1.val / $3.val;
	$$.ids = NULL;
	} else {
	/* LHS and/or RHS need computing from event IDs so union. */
	$$ = union_expr($1, $3);
	}
	}
	\| expr '%' expr
	{
	if (fpclassify($3.val) == FP_ZERO) {
	pr_debug("division by zero\n");
	YYABORT;
	} else if (!compute_ids \|\| (is_const($1.val) && is_const($3.val))) {
	assert($1.ids == NULL);
	assert($3.ids == NULL);
	$$.val = (long)$1.val % (long)$3.val;
	$$.ids = NULL;
	} else {
	/* LHS and/or RHS need computing from event IDs so union. */
	$$ = union_expr($1, $3);
	}
	}
	\| D_RATIO '(' expr ',' expr ')'
	{
	if (fpclassify($5.val) == FP_ZERO) {
	/*
	* Division by constant zero always yields zero and no events
	* are necessary.
	*/
	assert($5.ids == NULL);
	$$.val = 0.0;
	$$.ids = NULL;
	ids__free($3.ids);
	} else if (!compute_ids \|\| (is_const($3.val) && is_const($5.val))) {
	assert($3.ids == NULL);
	assert($5.ids == NULL);
	$$.val = $3.val / $5.val;
	$$.ids = NULL;
	} else {
	/* LHS and/or RHS need computing from event IDs so union. */
	$$ = union_expr($3, $5);
	}
	}
	\| '-' expr %prec NEG
	{
	$$.val = -$2.val;
	$$.ids = $2.ids;
	}
	\| '(' if_expr ')'
	{
	$$ = $2;
	}
	\| MIN '(' expr ',' expr ')'
	{
	if (!compute_ids) {
	$$.val = $3.val < $5.val ? $3.val : $5.val;
	$$.ids = NULL;
	} else {
	$$ = union_expr($3, $5);
	}
	}
	\| MAX '(' expr ',' expr ')'
	{
	if (!compute_ids) {
	$$.val = $3.val > $5.val ? $3.val : $5.val;
	$$.ids = NULL;
	} else {
	$$ = union_expr($3, $5);
	}
	}
	\| LITERAL
	{
	$$.val = $1;
	$$.ids = NULL;
	}
	;

	%%