Stephen Warren | 0c5403f | 2016-05-25 14:38:51 -0600 | [diff] [blame^] | 1 | NVIDIA Tegra186 GPIO controllers |
| 2 | |
| 3 | Tegra186 contains two GPIO controllers; a main controller and an "AON" |
| 4 | controller. This binding document applies to both controllers. The register |
| 5 | layouts for the controllers share many similarities, but also some significant |
| 6 | differences. Hence, this document describes closely related but different |
| 7 | bindings and compatible values. |
| 8 | |
| 9 | The Tegra186 GPIO controller allows software to set the IO direction of, and |
| 10 | read/write the value of, numerous GPIO signals. Routing of GPIO signals to |
| 11 | package balls is under the control of a separate pin controller HW block. Two |
| 12 | major sets of registers exist: |
| 13 | |
| 14 | a) Security registers, which allow configuration of allowed access to the GPIO |
| 15 | register set. These registers exist in a single contiguous block of physical |
| 16 | address space. The size of this block, and the security features available, |
| 17 | varies between the different GPIO controllers. |
| 18 | |
| 19 | Access to this set of registers is not necessary in all circumstances. Code |
| 20 | that wishes to configure access to the GPIO registers needs access to these |
| 21 | registers to do so. Code which simply wishes to read or write GPIO data does not |
| 22 | need access to these registers. |
| 23 | |
| 24 | b) GPIO registers, which allow manipulation of the GPIO signals. In some GPIO |
| 25 | controllers, these registers are exposed via multiple "physical aliases" in |
| 26 | address space, each of which access the same underlying state. See the hardware |
| 27 | documentation for rationale. Any particular GPIO client is expected to access |
| 28 | just one of these physical aliases. |
| 29 | |
| 30 | Tegra HW documentation describes a unified naming convention for all GPIOs |
| 31 | implemented by the SoC. Each GPIO is assigned to a port, and a port may control |
| 32 | a number of GPIOs. Thus, each GPIO is named according to an alphabetical port |
| 33 | name and an integer GPIO name within the port. For example, GPIO_PA0, GPIO_PN6, |
| 34 | or GPIO_PCC3. |
| 35 | |
| 36 | The number of ports implemented by each GPIO controller varies. The number of |
| 37 | implemented GPIOs within each port varies. GPIO registers within a controller |
| 38 | are grouped and laid out according to the port they affect. |
| 39 | |
| 40 | The mapping from port name to the GPIO controller that implements that port, and |
| 41 | the mapping from port name to register offset within a controller, are both |
| 42 | extremely non-linear. The header file <dt-bindings/gpio/tegra186-gpio.h> |
| 43 | describes the port-level mapping. In that file, the naming convention for ports |
| 44 | matches the HW documentation. The values chosen for the names are alphabetically |
| 45 | sorted within a particular controller. Drivers need to map between the DT GPIO |
| 46 | IDs and HW register offsets using a lookup table. |
| 47 | |
| 48 | Each GPIO controller can generate a number of interrupt signals. Each signal |
| 49 | represents the aggregate status for all GPIOs within a set of ports. Thus, the |
| 50 | number of interrupt signals generated by a controller varies as a rough function |
| 51 | of the number of ports it implements. Note that the HW documentation refers to |
| 52 | both the overall controller HW module and the sets-of-ports as "controllers". |
| 53 | |
| 54 | Each GPIO controller in fact generates multiple interrupts signals for each set |
| 55 | of ports. Each GPIO may be configured to feed into a specific one of the |
| 56 | interrupt signals generated by a set-of-ports. The intent is for each generated |
| 57 | signal to be routed to a different CPU, thus allowing different CPUs to each |
| 58 | handle subsets of the interrupts within a port. The status of each of these |
| 59 | per-port-set signals is reported via a separate register. Thus, a driver needs |
| 60 | to know which status register to observe. This binding currently defines no |
| 61 | configuration mechanism for this. By default, drivers should use register |
| 62 | GPIO_${port}_INTERRUPT_STATUS_G1_0. Future revisions to the binding could |
| 63 | define a property to configure this. |
| 64 | |
| 65 | Required properties: |
| 66 | - compatible |
| 67 | Array of strings. |
| 68 | One of: |
| 69 | - "nvidia,tegra186-gpio". |
| 70 | - "nvidia,tegra186-gpio-aon". |
| 71 | - reg-names |
| 72 | Array of strings. |
| 73 | Contains a list of names for the register spaces described by the reg |
| 74 | property. May contain the following entries, in any order: |
| 75 | - "gpio": Mandatory. GPIO control registers. This may cover either: |
| 76 | a) The single physical alias that this OS should use. |
| 77 | b) All physical aliases that exist in the controller. This is |
| 78 | appropriate when the OS is responsible for managing assignment of |
| 79 | the physical aliases. |
| 80 | - "security": Optional. Security configuration registers. |
| 81 | Users of this binding MUST look up entries in the reg property by name, |
| 82 | using this reg-names property to do so. |
| 83 | - reg |
| 84 | Array of (physical base address, length) tuples. |
| 85 | Must contain one entry per entry in the reg-names property, in a matching |
| 86 | order. |
| 87 | - interrupts |
| 88 | Array of interrupt specifiers. |
| 89 | The interrupt outputs from the HW block, one per set of ports, in the |
| 90 | order the HW manual describes them. The number of entries required varies |
| 91 | depending on compatible value: |
| 92 | - "nvidia,tegra186-gpio": 6 entries. |
| 93 | - "nvidia,tegra186-gpio-aon": 1 entry. |
| 94 | - gpio-controller |
| 95 | Boolean. |
| 96 | Marks the device node as a GPIO controller/provider. |
| 97 | - #gpio-cells |
| 98 | Single-cell integer. |
| 99 | Must be <2>. |
| 100 | Indicates how many cells are used in a consumer's GPIO specifier. |
| 101 | In the specifier: |
| 102 | - The first cell is the pin number. |
| 103 | See <dt-bindings/gpio/tegra186-gpio.h>. |
| 104 | - The second cell contains flags: |
| 105 | - Bit 0 specifies polarity |
| 106 | - 0: Active-high (normal). |
| 107 | - 1: Active-low (inverted). |
| 108 | - interrupt-controller |
| 109 | Boolean. |
| 110 | Marks the device node as an interrupt controller/provider. |
| 111 | - #interrupt-cells |
| 112 | Single-cell integer. |
| 113 | Must be <2>. |
| 114 | Indicates how many cells are used in a consumer's interrupt specifier. |
| 115 | In the specifier: |
| 116 | - The first cell is the GPIO number. |
| 117 | See <dt-bindings/gpio/tegra186-gpio.h>. |
| 118 | - The second cell is contains flags: |
| 119 | - Bits [3:0] indicate trigger type and level: |
| 120 | - 1: Low-to-high edge triggered. |
| 121 | - 2: High-to-low edge triggered. |
| 122 | - 4: Active high level-sensitive. |
| 123 | - 8: Active low level-sensitive. |
| 124 | Valid combinations are 1, 2, 3, 4, 8. |
| 125 | |
| 126 | Example: |
| 127 | |
| 128 | #include <dt-bindings/interrupt-controller/irq.h> |
| 129 | |
| 130 | gpio@2200000 { |
| 131 | compatible = "nvidia,tegra186-gpio"; |
| 132 | reg-names = "security", "gpio"; |
| 133 | reg = |
| 134 | <0x0 0x2200000 0x0 0x10000>, |
| 135 | <0x0 0x2210000 0x0 0x10000>; |
| 136 | interrupts = |
| 137 | <0 47 IRQ_TYPE_LEVEL_HIGH>, |
| 138 | <0 50 IRQ_TYPE_LEVEL_HIGH>, |
| 139 | <0 53 IRQ_TYPE_LEVEL_HIGH>, |
| 140 | <0 56 IRQ_TYPE_LEVEL_HIGH>, |
| 141 | <0 59 IRQ_TYPE_LEVEL_HIGH>, |
| 142 | <0 180 IRQ_TYPE_LEVEL_HIGH>; |
| 143 | gpio-controller; |
| 144 | #gpio-cells = <2>; |
| 145 | interrupt-controller; |
| 146 | #interrupt-cells = <2>; |
| 147 | }; |
| 148 | |
| 149 | gpio@c2f0000 { |
| 150 | compatible = "nvidia,tegra186-gpio-aon"; |
| 151 | reg-names = "security", "gpio"; |
| 152 | reg = |
| 153 | <0x0 0xc2f0000 0x0 0x1000>, |
| 154 | <0x0 0xc2f1000 0x0 0x1000>; |
| 155 | interrupts = |
| 156 | <0 60 IRQ_TYPE_LEVEL_HIGH>; |
| 157 | gpio-controller; |
| 158 | #gpio-cells = <2>; |
| 159 | interrupt-controller; |
| 160 | #interrupt-cells = <2>; |
| 161 | }; |