memory: tegra: Rework update_clock_tree_delay()

Further streamline this function by moving the delay post-processing
to the callers, leaving it only with the task of returning the measured
delay values.

Signed-off-by: Diogo Ivo <diogo.ivo@tecnico.ulisboa.pt>
Link: https://lore.kernel.org/r/20240704-tegra210_emcfreq-v4-7-3e450503c555@tecnico.ulisboa.pt
Signed-off-by: Krzysztof Kozlowski <krzysztof.kozlowski@linaro.org>

1 files changed, 48 insertions, 74 deletions

diff --git a/drivers/memory/tegra/tegra210-emc-cc-r21021.c b/drivers/memory/tegra/tegra210-emc-cc-r21021.c
index a8a217502f0c..a30a646ec468 100644
--- a/drivers/memory/tegra/tegra210-emc-cc-r21021.c
+++ b/drivers/memory/tegra/tegra210-emc-cc-r21021.c
@@ -105,7 +105,7 @@ enum {
 			  next->ptfv_list[w])) /			\
 			(next->ptfv_list[w] + 1);			\
 									\
-		emc_dbg(emc, EMA_UPDATES, "%s: (s=%lu) EMA: %u\n",	\
+		emc_dbg(emc, EMA_UPDATES, "%s: (s=%u) EMA: %u\n",	\
 			__stringify(dev), nval, next->ptfv_list[dqs]);	\
 	} while (0)
 
@@ -130,93 +130,53 @@ static bool tegra210_emc_compare_update_delay(struct tegra210_emc_timing *timing
 	return false;
 }
 
-static bool update_clock_tree_delay(struct tegra210_emc *emc, int type)
+static void tegra210_emc_get_clktree_delay(struct tegra210_emc *emc,
+					   u32 delay[DRAM_CLKTREE_NUM])
 {
-	bool periodic_training_update = type == PERIODIC_TRAINING_UPDATE;
-	struct tegra210_emc_timing *last = emc->last;
-	struct tegra210_emc_timing *next = emc->next;
-	u32 last_timing_rate_mhz = last->rate / 1000;
-	bool dvfs_update = type == DVFS_UPDATE;
-	bool dvfs_pt1 = type == DVFS_PT1;
-	u32 temp[2][2], value, delay_us;
-	unsigned long cval = 0;
+	struct tegra210_emc_timing *curr = emc->last;
+	u32 rate_mhz = curr->rate / 1000;
+	u32 msb, lsb, dqsosc, delay_us;
 	unsigned int c, d, idx;
-	bool over = false;
+	unsigned long clocks;
 
-	if (dvfs_pt1 || periodic_training_update) {
-		delay_us = tegra210_emc_actual_osc_clocks(last->run_clocks);
-		delay_us *= 1000;
-		delay_us = 2 + (delay_us / last->rate);
+	clocks = tegra210_emc_actual_osc_clocks(curr->run_clocks);
+	delay_us = 2 + (clocks / rate_mhz);
 
-		tegra210_emc_start_periodic_compensation(emc);
-		udelay(delay_us);
-	}
+	tegra210_emc_start_periodic_compensation(emc);
+	udelay(delay_us);
 
 	for (d = 0; d < emc->num_devices; d++) {
-		if (dvfs_pt1 || periodic_training_update) {
-			/* Dev[d] MSB */
-			value = tegra210_emc_mrr_read(emc, 2 - d, 19);
-
-			for (c = 0; c < emc->num_channels; c++) {
-				temp[c][0] = (value & 0x00ff) << 8;
-				temp[c][1] = (value & 0xff00) << 0;
-				value >>= 16;
-			}
-
-			/* Dev[d] LSB */
-			value = tegra210_emc_mrr_read(emc, 2 - d, 18);
-
-			for (c = 0; c < emc->num_channels; c++) {
-				temp[c][0] |= (value & 0x00ff) >> 0;
-				temp[c][1] |= (value & 0xff00) >> 8;
-				value >>= 16;
-			}
-		}
+		/* Read DQSOSC from MRR18/19 */
+		msb = tegra210_emc_mrr_read(emc, 2 - d, 19);
+		lsb = tegra210_emc_mrr_read(emc, 2 - d, 18);
 
 		for (c = 0; c < emc->num_channels; c++) {
 			/* C[c]D[d]U[0] */
 			idx = c * 4 + d * 2;
 
-			if (dvfs_pt1 || periodic_training_update) {
-				cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
-				cval *= 1000000;
-				cval /= last_timing_rate_mhz * 2 * temp[c][0];
-			}
-
-			if (dvfs_pt1)
-				__INCREMENT_PTFV(idx, cval);
-			else if (dvfs_update)
-				__AVERAGE_PTFV(idx);
-			else if (periodic_training_update)
-				__WEIGHTED_UPDATE_PTFV(idx, cval);
+			dqsosc = (msb & 0x00ff) << 8;
+			dqsosc |= (lsb & 0x00ff) >> 0;
 
-			if (dvfs_update || periodic_training_update)
-				over |= tegra210_emc_compare_update_delay(next,
-							__MOVAVG_AC(next, idx), idx);
+			/* Check for unpopulated channels */
+			if (dqsosc)
+				delay[idx] = (clocks * 1000000) /
+					     (rate_mhz * 2 * dqsosc);
 
 			/* C[c]D[d]U[1] */
 			idx++;
 
-			if (dvfs_pt1 || periodic_training_update) {
-				cval = tegra210_emc_actual_osc_clocks(last->run_clocks);
-				cval *= 1000000;
-				cval /= last_timing_rate_mhz * 2 * temp[c][1];
-			}
+			dqsosc = (msb & 0xff00) << 0;
+			dqsosc |= (lsb & 0xff00) >> 8;
 
-			if (dvfs_pt1)
-				__INCREMENT_PTFV(idx, cval);
-			else if (dvfs_update)
-				__AVERAGE_PTFV(idx);
-			else if (periodic_training_update)
-				__WEIGHTED_UPDATE_PTFV(idx, cval);
+			/* Check for unpopulated channels */
+			if (dqsosc)
+				delay[idx] = (clocks * 1000000) /
+					     (rate_mhz * 2 * dqsosc);
 
-			if (dvfs_update || periodic_training_update)
-				over |= tegra210_emc_compare_update_delay(next,
-							__MOVAVG_AC(next, idx), idx);
+			msb >>= 16;
+			lsb >>= 16;
 		}
 	}
-
-	return over;
 }
 
 static bool periodic_compensation_handler(struct tegra210_emc *emc, u32 type,
@@ -228,8 +188,8 @@ static bool periodic_compensation_handler(struct tegra210_emc *emc, u32 type,
 	   (nt)->ptfv_list[PTFV_DVFS_SAMPLES_INDEX]; })
 
 	u32 i, samples = next->ptfv_list[PTFV_DVFS_SAMPLES_INDEX];
+	u32 delay[DRAM_CLKTREE_NUM], idx;
 	bool over = false;
-	u32 idx;
 
 	if (!next->periodic_training)
 		return 0;
@@ -252,16 +212,30 @@ static bool periodic_compensation_handler(struct tegra210_emc *emc, u32 type,
 
 			for (i = 0; i < samples; i++) {
 				/* Generate next sample of data. */
-				update_clock_tree_delay(emc, DVFS_PT1);
+				tegra210_emc_get_clktree_delay(emc, delay);
+
+				for (idx = 0; idx < DRAM_CLKTREE_NUM; idx++)
+					__INCREMENT_PTFV(idx, delay[idx]);
 			}
 		}
 
-		/* Do the division part of the moving average */
-		over = update_clock_tree_delay(emc, DVFS_UPDATE);
+		for (idx = 0; idx < DRAM_CLKTREE_NUM; idx++) {
+			/* Do the division part of the moving average */
+			__AVERAGE_PTFV(idx);
+			over |= tegra210_emc_compare_update_delay(next,
+						__MOVAVG_AC(next, idx), idx);
+		}
 	}
 
-	if (type == PERIODIC_TRAINING_SEQUENCE)
-		over = update_clock_tree_delay(emc, PERIODIC_TRAINING_UPDATE);
+	if (type == PERIODIC_TRAINING_SEQUENCE) {
+		tegra210_emc_get_clktree_delay(emc, delay);
+
+		for (idx = 0; idx < DRAM_CLKTREE_NUM; idx++) {
+			__WEIGHTED_UPDATE_PTFV(idx, delay[idx]);
+			over |= tegra210_emc_compare_update_delay(next,
+						__MOVAVG_AC(next, idx), idx);
+		}
+	}
 
 	return over;
 }