@@ -403,6 +403,14 @@ static unsigned long tegra210_input_freq[] = {
#define PLLRE_BASE_DEFAULT_MASK 0x1c000000
#define PLLRE_MISC0_WRITE_MASK 0x67ffffff
+/* PLLE */
+#define PLLE_MISC_IDDQ_SW_CTRL (1 << 14)
+#define PLLE_AUX_USE_LOCKDET (1 << 3)
+#define PLLE_AUX_SS_SEQ_INCLUDE (1 << 31)
+#define PLLE_AUX_ENABLE_SWCTL (1 << 4)
+#define PLLE_AUX_SS_SWCTL (1 << 6)
+#define PLLE_AUX_SEQ_ENABLE (1 << 24)
+
/* PLLX */
#define PLLX_USE_DYN_RAMP 1
#define PLLX_BASE_LOCK (1 << 27)
@@ -489,6 +497,49 @@ static unsigned long tegra210_input_freq[] = {
#define PLLU_MISC0_WRITE_MASK 0xbfffffff
#define PLLU_MISC1_WRITE_MASK 0x00000007
+bool tegra210_plle_hw_sequence_is_enabled(void)
+{
+ u32 value;
+
+ value = readl_relaxed(clk_base + PLLE_AUX);
+ if (value & PLLE_AUX_SEQ_ENABLE)
+ return true;
+
+ return false;
+}
+EXPORT_SYMBOL_GPL(tegra210_plle_hw_sequence_is_enabled);
+
+int tegra210_plle_hw_sequence_start(void)
+{
+ u32 value;
+
+ if (tegra210_plle_hw_sequence_is_enabled())
+ return 0;
+
+ /* skip if PLLE is not enabled yet */
+ value = readl_relaxed(clk_base + PLLE_MISC0);
+ if (!(value & PLLE_MISC_LOCK))
+ return -EIO;
+
+ value &= ~PLLE_MISC_IDDQ_SW_CTRL;
+ writel_relaxed(value, clk_base + PLLE_MISC0);
+
+ value = readl_relaxed(clk_base + PLLE_AUX);
+ value |= (PLLE_AUX_USE_LOCKDET | PLLE_AUX_SS_SEQ_INCLUDE);
+ value &= ~(PLLE_AUX_ENABLE_SWCTL | PLLE_AUX_SS_SWCTL);
+ writel_relaxed(value, clk_base + PLLE_AUX);
+
+ fence_udelay(1, clk_base);
+
+ value |= PLLE_AUX_SEQ_ENABLE;
+ writel_relaxed(value, clk_base + PLLE_AUX);
+
+ fence_udelay(1, clk_base);
+
+ return 0;
+}
+EXPORT_SYMBOL_GPL(tegra210_plle_hw_sequence_start);
+
void tegra210_xusb_pll_hw_control_enable(void)
{
u32 val;
@@ -123,6 +123,8 @@ static inline void tegra_cpu_clock_resume(void)
}
#endif
+extern int tegra210_plle_hw_sequence_start(void);
+extern bool tegra210_plle_hw_sequence_is_enabled(void);
extern void tegra210_xusb_pll_hw_control_enable(void);
extern void tegra210_xusb_pll_hw_sequence_start(void);
extern void tegra210_sata_pll_hw_control_enable(void);
PLLE has a hardware power sequencer logic which is a state machine that can power on/off PLLE without any software intervention. The sequencer has two inputs, one from XUSB UPHY PLL and the other from SATA UPHY PLL. PLLE provides reference clock to XUSB and SATA UPHY PLLs. When both of the downstream PLLs are powered-off, PLLE hardware power sequencer will automatically power off PLLE for power saving. XUSB and SATA UPHY PLLs also have their own hardware power sequencer logic. XUSB UPHY PLL is shared between XUSB SuperSpeed ports and PCIE controllers. The XUSB UPHY PLL hardware power sequencer has inputs from XUSB and PCIE. When all of the XUSB SuperSpeed ports and PCIE controllers are in low power state, XUSB UPHY PLL hardware power sequencer automatically power off PLL and flags idle to PLLE hardware power sequencer. Similar applies to SATA UPHY PLL. PLLE hardware power sequencer has to be enabled after both downstream sequencers are enabled. This commit adds two helper functions: 1. tegra210_plle_hw_sequence_start() for XUSB PADCTL driver to enable PLLE hardware sequencer at proper time. 2. tegra210_plle_hw_sequence_is_enabled() for XUSB PADCTL driver to check whether PLLE hardware sequencer has been enabled or not. Signed-off-by: JC Kuo <jckuo@nvidia.com> --- v3: rename 'val' with 'value drivers/clk/tegra/clk-tegra210.c | 51 ++++++++++++++++++++++++++++++++ include/linux/clk/tegra.h | 2 ++ 2 files changed, 53 insertions(+)