summaryrefslogtreecommitdiffstats
path: root/Documentation/powerpc/dts-bindings/xilinx.txt
blob: ea68046bb9cb1381db127087280822bc04e49a6d (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
   d) Xilinx IP cores

   The Xilinx EDK toolchain ships with a set of IP cores (devices) for use
   in Xilinx Spartan and Virtex FPGAs.  The devices cover the whole range
   of standard device types (network, serial, etc.) and miscellaneous
   devices (gpio, LCD, spi, etc).  Also, since these devices are
   implemented within the fpga fabric every instance of the device can be
   synthesised with different options that change the behaviour.

   Each IP-core has a set of parameters which the FPGA designer can use to
   control how the core is synthesized.  Historically, the EDK tool would
   extract the device parameters relevant to device drivers and copy them
   into an 'xparameters.h' in the form of #define symbols.  This tells the
   device drivers how the IP cores are configured, but it requres the kernel
   to be recompiled every time the FPGA bitstream is resynthesized.

   The new approach is to export the parameters into the device tree and
   generate a new device tree each time the FPGA bitstream changes.  The
   parameters which used to be exported as #defines will now become
   properties of the device node.  In general, device nodes for IP-cores
   will take the following form:

	(name): (generic-name)@(base-address) {
		compatible = "xlnx,(ip-core-name)-(HW_VER)"
			     [, (list of compatible devices), ...];
		reg = <(baseaddr) (size)>;
		interrupt-parent = <&interrupt-controller-phandle>;
		interrupts = < ... >;
		xlnx,(parameter1) = "(string-value)";
		xlnx,(parameter2) = <(int-value)>;
	};

	(generic-name):   an open firmware-style name that describes the
			generic class of device.  Preferably, this is one word, such
			as 'serial' or 'ethernet'.
	(ip-core-name):	the name of the ip block (given after the BEGIN
			directive in system.mhs).  Should be in lowercase
			and all underscores '_' converted to dashes '-'.
	(name):		is derived from the "PARAMETER INSTANCE" value.
	(parameter#):	C_* parameters from system.mhs.  The C_ prefix is
			dropped from the parameter name, the name is converted
			to lowercase and all underscore '_' characters are
			converted to dashes '-'.
	(baseaddr):	the baseaddr parameter value (often named C_BASEADDR).
	(HW_VER):	from the HW_VER parameter.
	(size):		the address range size (often C_HIGHADDR - C_BASEADDR + 1).

   Typically, the compatible list will include the exact IP core version
   followed by an older IP core version which implements the same
   interface or any other device with the same interface.

   'reg', 'interrupt-parent' and 'interrupts' are all optional properties.

   For example, the following block from system.mhs:

	BEGIN opb_uartlite
		PARAMETER INSTANCE = opb_uartlite_0
		PARAMETER HW_VER = 1.00.b
		PARAMETER C_BAUDRATE = 115200
		PARAMETER C_DATA_BITS = 8
		PARAMETER C_ODD_PARITY = 0
		PARAMETER C_USE_PARITY = 0
		PARAMETER C_CLK_FREQ = 50000000
		PARAMETER C_BASEADDR = 0xEC100000
		PARAMETER C_HIGHADDR = 0xEC10FFFF
		BUS_INTERFACE SOPB = opb_7
		PORT OPB_Clk = CLK_50MHz
		PORT Interrupt = opb_uartlite_0_Interrupt
		PORT RX = opb_uartlite_0_RX
		PORT TX = opb_uartlite_0_TX
		PORT OPB_Rst = sys_bus_reset_0
	END

   becomes the following device tree node:

	opb_uartlite_0: serial@ec100000 {
		device_type = "serial";
		compatible = "xlnx,opb-uartlite-1.00.b";
		reg = <ec100000 10000>;
		interrupt-parent = <&opb_intc_0>;
		interrupts = <1 0>; // got this from the opb_intc parameters
		current-speed = <d#115200>;	// standard serial device prop
		clock-frequency = <d#50000000>;	// standard serial device prop
		xlnx,data-bits = <8>;
		xlnx,odd-parity = <0>;
		xlnx,use-parity = <0>;
	};

   Some IP cores actually implement 2 or more logical devices.  In
   this case, the device should still describe the whole IP core with
   a single node and add a child node for each logical device.  The
   ranges property can be used to translate from parent IP-core to the
   registers of each device.  In addition, the parent node should be
   compatible with the bus type 'xlnx,compound', and should contain
   #address-cells and #size-cells, as with any other bus.  (Note: this
   makes the assumption that both logical devices have the same bus
   binding.  If this is not true, then separate nodes should be used
   for each logical device).  The 'cell-index' property can be used to
   enumerate logical devices within an IP core.  For example, the
   following is the system.mhs entry for the dual ps2 controller found
   on the ml403 reference design.

	BEGIN opb_ps2_dual_ref
		PARAMETER INSTANCE = opb_ps2_dual_ref_0
		PARAMETER HW_VER = 1.00.a
		PARAMETER C_BASEADDR = 0xA9000000
		PARAMETER C_HIGHADDR = 0xA9001FFF
		BUS_INTERFACE SOPB = opb_v20_0
		PORT Sys_Intr1 = ps2_1_intr
		PORT Sys_Intr2 = ps2_2_intr
		PORT Clkin1 = ps2_clk_rx_1
		PORT Clkin2 = ps2_clk_rx_2
		PORT Clkpd1 = ps2_clk_tx_1
		PORT Clkpd2 = ps2_clk_tx_2
		PORT Rx1 = ps2_d_rx_1
		PORT Rx2 = ps2_d_rx_2
		PORT Txpd1 = ps2_d_tx_1
		PORT Txpd2 = ps2_d_tx_2
	END

   It would result in the following device tree nodes:

	opb_ps2_dual_ref_0: opb-ps2-dual-ref@a9000000 {
		#address-cells = <1>;
		#size-cells = <1>;
		compatible = "xlnx,compound";
		ranges = <0 a9000000 2000>;
		// If this device had extra parameters, then they would
		// go here.
		ps2@0 {
			compatible = "xlnx,opb-ps2-dual-ref-1.00.a";
			reg = <0 40>;
			interrupt-parent = <&opb_intc_0>;
			interrupts = <3 0>;
			cell-index = <0>;
		};
		ps2@1000 {
			compatible = "xlnx,opb-ps2-dual-ref-1.00.a";
			reg = <1000 40>;
			interrupt-parent = <&opb_intc_0>;
			interrupts = <3 0>;
			cell-index = <0>;
		};
	};

   Also, the system.mhs file defines bus attachments from the processor
   to the devices.  The device tree structure should reflect the bus
   attachments.  Again an example; this system.mhs fragment:

	BEGIN ppc405_virtex4
		PARAMETER INSTANCE = ppc405_0
		PARAMETER HW_VER = 1.01.a
		BUS_INTERFACE DPLB = plb_v34_0
		BUS_INTERFACE IPLB = plb_v34_0
	END

	BEGIN opb_intc
		PARAMETER INSTANCE = opb_intc_0
		PARAMETER HW_VER = 1.00.c
		PARAMETER C_BASEADDR = 0xD1000FC0
		PARAMETER C_HIGHADDR = 0xD1000FDF
		BUS_INTERFACE SOPB = opb_v20_0
	END

	BEGIN opb_uart16550
		PARAMETER INSTANCE = opb_uart16550_0
		PARAMETER HW_VER = 1.00.d
		PARAMETER C_BASEADDR = 0xa0000000
		PARAMETER C_HIGHADDR = 0xa0001FFF
		BUS_INTERFACE SOPB = opb_v20_0
	END

	BEGIN plb_v34
		PARAMETER INSTANCE = plb_v34_0
		PARAMETER HW_VER = 1.02.a
	END

	BEGIN plb_bram_if_cntlr
		PARAMETER INSTANCE = plb_bram_if_cntlr_0
		PARAMETER HW_VER = 1.00.b
		PARAMETER C_BASEADDR = 0xFFFF0000
		PARAMETER C_HIGHADDR = 0xFFFFFFFF
		BUS_INTERFACE SPLB = plb_v34_0
	END

	BEGIN plb2opb_bridge
		PARAMETER INSTANCE = plb2opb_bridge_0
		PARAMETER HW_VER = 1.01.a
		PARAMETER C_RNG0_BASEADDR = 0x20000000
		PARAMETER C_RNG0_HIGHADDR = 0x3FFFFFFF
		PARAMETER C_RNG1_BASEADDR = 0x60000000
		PARAMETER C_RNG1_HIGHADDR = 0x7FFFFFFF
		PARAMETER C_RNG2_BASEADDR = 0x80000000
		PARAMETER C_RNG2_HIGHADDR = 0xBFFFFFFF
		PARAMETER C_RNG3_BASEADDR = 0xC0000000
		PARAMETER C_RNG3_HIGHADDR = 0xDFFFFFFF
		BUS_INTERFACE SPLB = plb_v34_0
		BUS_INTERFACE MOPB = opb_v20_0
	END

   Gives this device tree (some properties removed for clarity):

	plb@0 {
		#address-cells = <1>;
		#size-cells = <1>;
		compatible = "xlnx,plb-v34-1.02.a";
		device_type = "ibm,plb";
		ranges; // 1:1 translation

		plb_bram_if_cntrl_0: bram@ffff0000 {
			reg = <ffff0000 10000>;
		}

		opb@20000000 {
			#address-cells = <1>;
			#size-cells = <1>;
			ranges = <20000000 20000000 20000000
				  60000000 60000000 20000000
				  80000000 80000000 40000000
				  c0000000 c0000000 20000000>;

			opb_uart16550_0: serial@a0000000 {
				reg = <a00000000 2000>;
			};

			opb_intc_0: interrupt-controller@d1000fc0 {
				reg = <d1000fc0 20>;
			};
		};
	};

   That covers the general approach to binding xilinx IP cores into the
   device tree.  The following are bindings for specific devices:

      i) Xilinx ML300 Framebuffer

      Simple framebuffer device from the ML300 reference design (also on the
      ML403 reference design as well as others).

      Optional properties:
       - resolution = <xres yres> : pixel resolution of framebuffer.  Some
                                    implementations use a different resolution.
                                    Default is <d#640 d#480>
       - virt-resolution = <xvirt yvirt> : Size of framebuffer in memory.
                                           Default is <d#1024 d#480>.
       - rotate-display (empty) : rotate display 180 degrees.

      ii) Xilinx SystemACE

      The Xilinx SystemACE device is used to program FPGAs from an FPGA
      bitstream stored on a CF card.  It can also be used as a generic CF
      interface device.

      Optional properties:
       - 8-bit (empty) : Set this property for SystemACE in 8 bit mode

      iii) Xilinx EMAC and Xilinx TEMAC

      Xilinx Ethernet devices.  In addition to general xilinx properties
      listed above, nodes for these devices should include a phy-handle
      property, and may include other common network device properties
      like local-mac-address.

      iv) Xilinx Uartlite

      Xilinx uartlite devices are simple fixed speed serial ports.

      Required properties:
       - current-speed : Baud rate of uartlite

      v) Xilinx hwicap

		Xilinx hwicap devices provide access to the configuration logic
		of the FPGA through the Internal Configuration Access Port
		(ICAP).  The ICAP enables partial reconfiguration of the FPGA,
		readback of the configuration information, and some control over
		'warm boots' of the FPGA fabric.

		Required properties:
		- xlnx,family : The family of the FPGA, necessary since the
                      capabilities of the underlying ICAP hardware
                      differ between different families.  May be
                      'virtex2p', 'virtex4', or 'virtex5'.

      vi) Xilinx Uart 16550

      Xilinx UART 16550 devices are very similar to the NS16550 but with
      different register spacing and an offset from the base address.

      Required properties:
       - clock-frequency : Frequency of the clock input
       - reg-offset : A value of 3 is required
       - reg-shift : A value of 2 is required

      vii) Xilinx USB Host controller

      The Xilinx USB host controller is EHCI compatible but with a different
      base address for the EHCI registers, and it is always a big-endian
      USB Host controller. The hardware can be configured as high speed only,
      or high speed/full speed hybrid.

      Required properties:
      - xlnx,support-usb-fs: A value 0 means the core is built as high speed
                             only. A value 1 means the core also supports
                             full speed devices.

OpenPOWER on IntegriCloud