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@ -14,19 +14,20 @@
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#endif
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/*
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* The sorted array sorts the last N executions by execution time
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* The buffer array acts as a circular buffer of indices into the sorted array
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* The by_duration array sorts the last N executions by execution time
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* The by_termination array acts as a circular buffer that maps to indices in the by_duration array
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*
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* This provides a sorted circular buffer
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* by_termination ensures that the when the circular buffer is full, the oldest data in both arrays is
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* overwritten, providing a sorted circular buffer
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*/
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struct execution_node {
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uint32_t execution_time;
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uint16_t buffer_idx; /* Reverse Index back to the sorted bin equal to this index */
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uint16_t by_termination_idx; /* Reverse idx of the associated by_termination bin. Used for swaps! */
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};
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struct perf_window {
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struct execution_node sorted[PERF_WINDOW_BUFFER_SIZE];
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uint16_t buffer[PERF_WINDOW_BUFFER_SIZE];
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struct execution_node by_duration[PERF_WINDOW_BUFFER_SIZE];
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uint16_t by_termination[PERF_WINDOW_BUFFER_SIZE];
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uint64_t count;
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lock_t lock;
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};
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@ -42,47 +43,50 @@ perf_window_initialize(struct perf_window *self)
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LOCK_INIT(&self->lock);
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self->count = 0;
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memset(&self->sorted, 0, sizeof(struct execution_node) * PERF_WINDOW_BUFFER_SIZE);
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memset(&self->buffer, 0, sizeof(uint16_t) * PERF_WINDOW_BUFFER_SIZE);
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memset(&self->by_duration, 0, sizeof(struct execution_node) * PERF_WINDOW_BUFFER_SIZE);
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memset(&self->by_termination, 0, sizeof(uint16_t) * PERF_WINDOW_BUFFER_SIZE);
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}
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/**
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* Swaps two execution nodes in the sorted array, including updating the indices in the circular buffer
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* Swaps two execution nodes in the by_duration array, including updating the indices in the by_termination circular
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* buffer
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* @param self
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* @param first_sorted_idx
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* @param second_sorted_idx
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* @param first_by_duration_idx
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* @param second_by_duration_idx
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*/
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static inline void
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perf_window_swap(struct perf_window *self, uint16_t first_sorted_idx, uint16_t second_sorted_idx)
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perf_window_swap(struct perf_window *self, uint16_t first_by_duration_idx, uint16_t second_by_duration_idx)
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{
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assert(LOCK_IS_LOCKED(&self->lock));
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assert(self != NULL);
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assert(first_sorted_idx >= 0 && first_sorted_idx < PERF_WINDOW_BUFFER_SIZE);
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assert(second_sorted_idx >= 0 && second_sorted_idx < PERF_WINDOW_BUFFER_SIZE);
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assert(first_by_duration_idx >= 0 && first_by_duration_idx < PERF_WINDOW_BUFFER_SIZE);
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assert(second_by_duration_idx >= 0 && second_by_duration_idx < PERF_WINDOW_BUFFER_SIZE);
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uint16_t first_buffer_idx = self->sorted[first_sorted_idx].buffer_idx;
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uint16_t second_buffer_idx = self->sorted[second_sorted_idx].buffer_idx;
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uint16_t first_by_termination_idx = self->by_duration[first_by_duration_idx].by_termination_idx;
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uint16_t second_by_termination_idx = self->by_duration[second_by_duration_idx].by_termination_idx;
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/* The execution node's buffer_idx points to a buffer cell equal to its own sorted index */
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assert(self->buffer[first_buffer_idx] == first_sorted_idx);
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assert(self->buffer[second_buffer_idx] == second_sorted_idx);
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/* The execution node's by_termination_idx points to a by_termination cell equal to its own by_duration index */
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assert(self->by_termination[first_by_termination_idx] == first_by_duration_idx);
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assert(self->by_termination[second_by_termination_idx] == second_by_duration_idx);
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uint32_t first_execution_time = self->sorted[first_sorted_idx].execution_time;
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uint32_t second_execution_time = self->sorted[second_sorted_idx].execution_time;
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uint32_t first_execution_time = self->by_duration[first_by_duration_idx].execution_time;
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uint32_t second_execution_time = self->by_duration[second_by_duration_idx].execution_time;
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/* Swap Indices in Buffer*/
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self->buffer[first_buffer_idx] = second_sorted_idx;
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self->buffer[second_buffer_idx] = first_sorted_idx;
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/* Swap buffer_idx */
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struct execution_node tmp_node = self->sorted[first_sorted_idx];
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self->sorted[first_sorted_idx] = self->sorted[second_sorted_idx];
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self->sorted[second_sorted_idx] = tmp_node;
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/* The circular buffer indices should always point to the same execution times across all swaps */
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assert(self->sorted[self->buffer[first_buffer_idx]].execution_time == first_execution_time);
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assert(self->sorted[self->buffer[second_buffer_idx]].execution_time == second_execution_time);
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self->by_termination[first_by_termination_idx] = second_by_duration_idx;
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self->by_termination[second_by_termination_idx] = first_by_duration_idx;
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/* Swap by_termination_idx */
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struct execution_node tmp_node = self->by_duration[first_by_duration_idx];
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self->by_duration[first_by_duration_idx] = self->by_duration[second_by_duration_idx];
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self->by_duration[second_by_duration_idx] = tmp_node;
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/* The circular by_termination indices should always point to the same execution times across all swaps */
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assert(self->by_duration[self->by_termination[first_by_termination_idx]].execution_time
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== first_execution_time);
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assert(self->by_duration[self->by_termination[second_by_termination_idx]].execution_time
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== second_execution_time);
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}
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/**
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@ -104,39 +108,41 @@ perf_window_add(struct perf_window *self, uint32_t value)
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/* If count is 0, then fill entire array with initial execution times */
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if (self->count == 0) {
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for (int i = 0; i < PERF_WINDOW_BUFFER_SIZE; i++) {
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self->buffer[i] = i;
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self->sorted[i] = (struct execution_node){ .execution_time = value, .buffer_idx = i };
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self->by_termination[i] = i;
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self->by_duration[i] = (struct execution_node){ .execution_time = value,
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.by_termination_idx = i };
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}
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self->count = PERF_WINDOW_BUFFER_SIZE;
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goto done;
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}
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/* Otherwise, replace the oldest value, and then sort */
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uint16_t idx_of_oldest = self->buffer[self->count % PERF_WINDOW_BUFFER_SIZE];
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bool check_up = value > self->sorted[idx_of_oldest].execution_time;
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uint16_t idx_of_oldest = self->by_termination[self->count % PERF_WINDOW_BUFFER_SIZE];
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bool check_up = value > self->by_duration[idx_of_oldest].execution_time;
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self->sorted[idx_of_oldest].execution_time = value;
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self->by_duration[idx_of_oldest].execution_time = value;
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if (check_up) {
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for (uint16_t i = idx_of_oldest; i + 1 < PERF_WINDOW_BUFFER_SIZE
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&& self->sorted[i + 1].execution_time < self->sorted[i].execution_time;
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for (uint16_t i = idx_of_oldest;
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i + 1 < PERF_WINDOW_BUFFER_SIZE
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&& self->by_duration[i + 1].execution_time < self->by_duration[i].execution_time;
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i++) {
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perf_window_swap(self, i, i + 1);
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}
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} else {
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for (uint16_t i = idx_of_oldest;
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i - 1 >= 0 && self->sorted[i - 1].execution_time > self->sorted[i].execution_time; i--) {
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for (int i = idx_of_oldest;
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i - 1 >= 0 && self->by_duration[i - 1].execution_time > self->by_duration[i].execution_time; i--) {
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perf_window_swap(self, i, i - 1);
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}
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}
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/* The idx that we replaces should still point to the same value */
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assert(self->sorted[self->buffer[self->count % PERF_WINDOW_BUFFER_SIZE]].execution_time == value);
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assert(self->by_duration[self->by_termination[self->count % PERF_WINDOW_BUFFER_SIZE]].execution_time == value);
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/* The sorted array should be ordered by execution time */
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/* The by_duration array should be ordered by execution time */
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#ifndef NDEBUG
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for (int i = 1; i < PERF_WINDOW_BUFFER_SIZE; i++) {
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assert(self->sorted[i - 1].execution_time <= self->sorted[i].execution_time);
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assert(self->by_duration[i - 1].execution_time <= self->by_duration[i].execution_time);
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}
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#endif
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@ -150,7 +156,7 @@ done:
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* Returns pXX execution time
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* @param self
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* @param percentile represented by double between 0 and 1
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* @returns execution time or -1 if buffer is empty
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* @returns execution time or -1 if by_termination is empty
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*/
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static inline uint32_t
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perf_window_get_percentile(struct perf_window *self, double percentile)
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@ -160,7 +166,7 @@ perf_window_get_percentile(struct perf_window *self, double percentile)
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if (self->count == 0) return -1;
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return self->sorted[(int)(PERF_WINDOW_BUFFER_SIZE * percentile)].execution_time;
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return self->by_duration[(int)(PERF_WINDOW_BUFFER_SIZE * percentile)].execution_time;
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}
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/**
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Sean McBride
4 years ago