xref: /linux/Documentation/devicetree/bindings/pci/snps,dw-pcie-common.yaml (revision c532de5a67a70f8533d495f8f2aaa9a0491c3ad0)
1# SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
2%YAML 1.2
3---
4$id: http://devicetree.org/schemas/pci/snps,dw-pcie-common.yaml#
5$schema: http://devicetree.org/meta-schemas/core.yaml#
6
7title: Synopsys DWC PCIe RP/EP controller
8
9maintainers:
10  - Jingoo Han <jingoohan1@gmail.com>
11  - Gustavo Pimentel <gustavo.pimentel@synopsys.com>
12
13description:
14  Generic Synopsys DesignWare PCIe Root Port and Endpoint controller
15  properties.
16
17select: false
18
19properties:
20  reg:
21    description:
22      DWC PCIe CSR space is normally accessed over the dedicated Data Bus
23      Interface - DBI. In accordance with the reference manual the register
24      configuration space belongs to the Configuration-Dependent Module (CDM)
25      and is split up into several sub-parts Standard PCIe configuration
26      space, Port Logic Registers (PL), Shadow Config-space Registers,
27      iATU/eDMA registers. The particular sub-space is selected by the
28      CDM/ELBI (dbi_cs) and CS2 (dbi_cs2) signals (selector bits). Such
29      configuration provides a flexible interface for the system engineers to
30      either map the particular space at a desired MMIO address or just leave
31      them in a contiguous memory space if pure Native or AXI Bridge DBI access
32      is selected. Note the PCIe CFG-space, PL and Shadow registers are
33      specific for each activated function, while the rest of the sub-spaces
34      are common for all of them (if there are more than one).
35    minItems: 2
36    maxItems: 7
37
38  reg-names:
39    minItems: 2
40    maxItems: 7
41
42  interrupts:
43    description:
44      There are two main sub-blocks which are normally capable of
45      generating interrupts. It's System Information Interface and MSI
46      interface. While the former one has some common for the Host and
47      Endpoint controllers IRQ-signals, the later interface is obviously
48      Root Complex specific since it's responsible for the incoming MSI
49      messages signalling. The System Information IRQ signals are mainly
50      responsible for reporting the generic PCIe hierarchy and Root
51      Complex events like VPD IO request, general AER, PME, Hot-plug, link
52      bandwidth change, link equalization request, INTx asserted/deasserted
53      Message detection, embedded DMA Tx/Rx/Error.
54    minItems: 1
55    maxItems: 26
56
57  interrupt-names:
58    minItems: 1
59    maxItems: 26
60
61  clocks:
62    description:
63      DWC PCIe reference manual explicitly defines a set of the clocks required
64      to get the controller working correctly. In general all of them can
65      be divided into two groups':' application and core clocks. Note the
66      platforms may have some of the clock sources unspecified in case if the
67      corresponding domains are fed up from a common clock source.
68    minItems: 1
69    maxItems: 7
70
71  clock-names:
72    minItems: 1
73    maxItems: 7
74    items:
75      oneOf:
76        - description:
77            Data Bus Interface (DBI) clock. Clock signal for the AXI-bus
78            interface of the Configuration-Dependent Module, which is
79            basically the set of the controller CSRs.
80          const: dbi
81        - description:
82            Application AXI-bus Master interface clock. Basically this is
83            a clock for the controller DMA interface (PCI-to-CPU).
84          const: mstr
85        - description:
86            Application AXI-bus Slave interface clock. This is a clock for
87            the CPU-to-PCI memory IO interface.
88          const: slv
89        - description:
90            Controller Core-PCS PIPE interface clock. It's normally
91            supplied by an external PCS-PHY.
92          const: pipe
93        - description:
94            Controller Primary clock. It's assumed that all controller input
95            signals (except resets) are synchronous to this clock.
96          const: core
97        - description:
98            Auxiliary clock for the controller PMC domain. The controller
99            partitioning implies having some parts to operate with this
100            clock in some power management states.
101          const: aux
102        - description:
103            Generic reference clock. In case if there are several
104            interfaces fed up with a common clock source it's advisable to
105            define it with this name (for instance pipe, core and aux can
106            be connected to a single source of the periodic signal).
107          const: ref
108        - description:
109            Clock for the PHY registers interface. Originally this is
110            a PHY-viewport-based interface, but some platform may have
111            specifically designed one.
112          const: phy_reg
113        - description:
114            Vendor-specific clock names. Consider using the generic names
115            above for new bindings.
116          oneOf:
117            - description: See native 'dbi' clock for details
118              enum: [ pcie, pcie_apb_sys, aclk_dbi ]
119            - description: See native 'mstr/slv' clock for details
120              enum: [ pcie_bus, pcie_inbound_axi, pcie_aclk, aclk_mst, aclk_slv ]
121            - description: See native 'pipe' clock for details
122              enum: [ pcie_phy, pcie_phy_ref, link ]
123            - description: See native 'aux' clock for details
124              enum: [ pcie_aux ]
125            - description: See native 'ref' clock for details.
126              enum: [ gio ]
127            - description: See nativs 'phy_reg' clock for details
128              enum: [ pcie_apb_phy, pclk ]
129
130  resets:
131    description:
132      DWC PCIe reference manual explicitly defines a set of the reset
133      signals required to be de-asserted to properly activate the controller
134      sub-parts. All of these signals can be divided into two sub-groups':'
135      application and core resets with respect to the main sub-domains they
136      are supposed to reset. Note the platforms may have some of these signals
137      unspecified in case if they are automatically handled or aggregated into
138      a comprehensive control module.
139    minItems: 1
140    maxItems: 10
141
142  reset-names:
143    minItems: 1
144    maxItems: 10
145    items:
146      oneOf:
147        - description: Data Bus Interface (DBI) domain reset
148          const: dbi
149        - description: AXI-bus Master interface reset
150          const: mstr
151        - description: AXI-bus Slave interface reset
152          const: slv
153        - description: Application-dependent interface reset
154          const: app
155        - description: Controller Non-sticky CSR flags reset
156          const: non-sticky
157        - description: Controller sticky CSR flags reset
158          const: sticky
159        - description: PIPE-interface (Core-PCS) logic reset
160          const: pipe
161        - description:
162            Controller primary reset (resets everything except PMC module)
163          const: core
164        - description: PCS/PHY block reset
165          const: phy
166        - description: PMC hot reset signal
167          const: hot
168        - description: Cold reset signal
169          const: pwr
170        - description:
171            Vendor-specific reset names. Consider using the generic names
172            above for new bindings.
173          oneOf:
174            - description: See native 'app' reset for details
175              enum: [ apps, gio, apb ]
176            - description: See native 'phy' reset for details
177              enum: [ pciephy, link ]
178            - description: See native 'pwr' reset for details
179              enum: [ turnoff ]
180
181  phys:
182    description:
183      There can be up to the number of possible lanes PHYs specified placed in
184      the phandle array in the line-based order. Obviously each the specified
185      PHYs are supposed to be able to work in the PCIe mode with a speed
186      implied by the DWC PCIe controller they are attached to.
187    minItems: 1
188    maxItems: 16
189
190  phy-names:
191    minItems: 1
192    maxItems: 16
193    oneOf:
194      - description: Generic PHY names
195        items:
196          pattern: '^pcie[0-9]+$'
197      - description:
198          Vendor-specific PHY names. Consider using the generic
199          names above for new bindings.
200        items:
201          oneOf:
202            - pattern: '^pcie(-?phy[0-9]*)?$'
203            - pattern: '^p2u-[0-7]$'
204
205  reset-gpio:
206    deprecated: true
207    description:
208      Reference to the GPIO-controlled PERST# signal. It is used to reset all
209      the peripheral devices available on the PCIe bus.
210    maxItems: 1
211
212  reset-gpios:
213    description:
214      Reference to the GPIO-controlled PERST# signal. It is used to reset all
215      the peripheral devices available on the PCIe bus.
216    maxItems: 1
217
218  max-link-speed:
219    maximum: 5
220
221  num-lanes:
222    description:
223      Number of PCIe link lanes to use. Can be omitted if the already brought
224      up link is supposed to be preserved.
225    maximum: 16
226
227  num-ob-windows:
228    $ref: /schemas/types.yaml#/definitions/uint32
229    deprecated: true
230    description:
231      Number of outbound address translation windows. This parameter can be
232      auto-detected based on the iATU memory writability. So there is no
233      point in having a dedicated DT-property for it.
234    maximum: 256
235
236  num-ib-windows:
237    $ref: /schemas/types.yaml#/definitions/uint32
238    deprecated: true
239    description:
240      Number of inbound address translation windows. In the same way as
241      for the outbound AT windows, this parameter can be auto-detected based
242      on the iATU memory writability. There is no point having a dedicated
243      DT-property for it either.
244    maximum: 256
245
246  num-viewport:
247    $ref: /schemas/types.yaml#/definitions/uint32
248    deprecated: true
249    description:
250      Number of outbound view ports configured in hardware. It's the same as
251      the number of outbound AT windows.
252    maximum: 256
253
254  snps,enable-cdm-check:
255    $ref: /schemas/types.yaml#/definitions/flag
256    description:
257      Enable automatic checking of CDM (Configuration Dependent Module)
258      registers for data corruption. CDM registers include standard PCIe
259      configuration space registers, Port Logic registers, DMA and iATU
260      registers. This feature has been available since DWC PCIe v4.80a.
261
262  dma-coherent: true
263
264additionalProperties: true
265
266...
267