1 /* $Id: bbc.h,v 1.2 2001/03/26 23:47:18 davem Exp $
2  * bbc.h: Defines for BootBus Controller found on UltraSPARC-III
3  *        systems.
4  *
5  * Copyright (C) 2000 David S. Miller (davem@redhat.com)
6  */
7 
8 #ifndef _SPARC64_BBC_H
9 #define _SPARC64_BBC_H
10 
11 /* Register sizes are indicated by "B" (Byte, 1-byte),
12  * "H" (Half-word, 2 bytes), "W" (Word, 4 bytes) or
13  * "Q" (Quad, 8 bytes) inside brackets.
14  */
15 
16 #define BBC_AID		0x00	/* [B] Agent ID			*/
17 #define BBC_DEVP	0x01	/* [B] Device Present		*/
18 #define BBC_ARB		0x02	/* [B] Arbitration		*/
19 #define BBC_QUIESCE	0x03	/* [B] Quiesce			*/
20 #define BBC_WDACTION	0x04	/* [B] Watchdog Action		*/
21 #define BBC_SPG		0x06	/* [B] Soft POR Gen		*/
22 #define BBC_SXG		0x07	/* [B] Soft XIR Gen		*/
23 #define BBC_PSRC	0x08	/* [W] POR Source		*/
24 #define BBC_XSRC	0x0c	/* [B] XIR Source		*/
25 #define BBC_CSC		0x0d	/* [B] Clock Synthesizers Control*/
26 #define BBC_ES_CTRL	0x0e	/* [H] Energy Star Control	*/
27 #define BBC_ES_ACT	0x10	/* [W] E* Assert Change Time	*/
28 #define BBC_ES_DACT	0x14	/* [B] E* De-Assert Change Time	*/
29 #define BBC_ES_DABT	0x15	/* [B] E* De-Assert Bypass Time	*/
30 #define BBC_ES_ABT	0x16	/* [H] E* Assert Bypass Time	*/
31 #define BBC_ES_PST	0x18	/* [W] E* PLL Settle Time	*/
32 #define BBC_ES_FSL	0x1c	/* [W] E* Frequency Switch Latency*/
33 #define BBC_EBUST	0x20	/* [Q] EBUS Timing		*/
34 #define BBC_JTAG_CMD	0x28	/* [W] JTAG+ Command		*/
35 #define BBC_JTAG_CTRL	0x2c	/* [B] JTAG+ Control		*/
36 #define BBC_I2C_SEL	0x2d	/* [B] I2C Selection		*/
37 #define BBC_I2C_0_S1	0x2e	/* [B] I2C ctrlr-0 reg S1	*/
38 #define BBC_I2C_0_S0	0x2f	/* [B] I2C ctrlr-0 regs S0,S0',S2,S3*/
39 #define BBC_I2C_1_S1	0x30	/* [B] I2C ctrlr-1 reg S1	*/
40 #define BBC_I2C_1_S0	0x31	/* [B] I2C ctrlr-1 regs S0,S0',S2,S3*/
41 #define BBC_KBD_BEEP	0x32	/* [B] Keyboard Beep		*/
42 #define BBC_KBD_BCNT	0x34	/* [W] Keyboard Beep Counter	*/
43 
44 #define BBC_REGS_SIZE	0x40
45 
46 /* There is a 2K scratch ram area at offset 0x80000 but I doubt
47  * we will use it for anything.
48  */
49 
50 /* Agent ID register.  This register shows the Safari Agent ID
51  * for the processors.  The value returned depends upon which
52  * cpu is reading the register.
53  */
54 #define BBC_AID_ID	0x07	/* Safari ID		*/
55 #define BBC_AID_RESV	0xf8	/* Reserved		*/
56 
57 /* Device Present register.  One can determine which cpus are actually
58  * present in the machine by interrogating this register.
59  */
60 #define BBC_DEVP_CPU0	0x01	/* Processor 0 present	*/
61 #define BBC_DEVP_CPU1	0x02	/* Processor 1 present	*/
62 #define BBC_DEVP_CPU2	0x04	/* Processor 2 present	*/
63 #define BBC_DEVP_CPU3	0x08	/* Processor 3 present	*/
64 #define BBC_DEVP_RESV	0xf0	/* Reserved		*/
65 
66 /* Arbitration register.  This register is used to block access to
67  * the BBC from a particular cpu.
68  */
69 #define BBC_ARB_CPU0	0x01	/* Enable cpu 0 BBC arbitratrion */
70 #define BBC_ARB_CPU1	0x02	/* Enable cpu 1 BBC arbitratrion */
71 #define BBC_ARB_CPU2	0x04	/* Enable cpu 2 BBC arbitratrion */
72 #define BBC_ARB_CPU3	0x08	/* Enable cpu 3 BBC arbitratrion */
73 #define BBC_ARB_RESV	0xf0	/* Reserved			 */
74 
75 /* Quiesce register.  Bus and BBC segments for cpus can be disabled
76  * with this register, ie. for hot plugging.
77  */
78 #define BBC_QUIESCE_S02	0x01	/* Quiesce Safari segment for cpu 0 and 2 */
79 #define BBC_QUIESCE_S13	0x02	/* Quiesce Safari segment for cpu 1 and 3 */
80 #define BBC_QUIESCE_B02	0x04	/* Quiesce BBC segment for cpu 0 and 2    */
81 #define BBC_QUIESCE_B13	0x08	/* Quiesce BBC segment for cpu 1 and 3    */
82 #define BBC_QUIESCE_FD0 0x10	/* Disable Fatal_Error[0] reporting	  */
83 #define BBC_QUIESCE_FD1 0x20	/* Disable Fatal_Error[1] reporting	  */
84 #define BBC_QUIESCE_FD2 0x40	/* Disable Fatal_Error[2] reporting	  */
85 #define BBC_QUIESCE_FD3 0x80	/* Disable Fatal_Error[3] reporting	  */
86 
87 /* Watchdog Action register.  When the watchdog device timer expires
88  * a line is enabled to the BBC.  The action BBC takes when this line
89  * is asserted can be controlled by this regiser.
90  */
91 #define BBC_WDACTION_RST  0x01	/* When set, watchdog causes system reset.
92 				 * When clear, BBC ignores watchdog signal.
93 				 */
94 #define BBC_WDACTION_RESV 0xfe	/* Reserved */
95 
96 /* Soft_POR_GEN register.  The POR (Power On Reset) signal may be asserted
97  * for specific processors or all processors via this register.
98  */
99 #define BBC_SPG_CPU0	0x01 /* Assert POR for processor 0	*/
100 #define BBC_SPG_CPU1	0x02 /* Assert POR for processor 1	*/
101 #define BBC_SPG_CPU2	0x04 /* Assert POR for processor 2	*/
102 #define BBC_SPG_CPU3	0x08 /* Assert POR for processor 3	*/
103 #define BBC_SPG_CPUALL	0x10 /* Reset all processors and reset
104 			      * the entire system.
105 			      */
106 #define BBC_SPG_RESV	0xe0 /* Reserved			*/
107 
108 /* Soft_XIR_GEN register.  The XIR (eXternally Initiated Reset) signal
109  * may be asserted to specific processors via this register.
110  */
111 #define BBC_SXG_CPU0	0x01 /* Assert XIR for processor 0	*/
112 #define BBC_SXG_CPU1	0x02 /* Assert XIR for processor 1	*/
113 #define BBC_SXG_CPU2	0x04 /* Assert XIR for processor 2	*/
114 #define BBC_SXG_CPU3	0x08 /* Assert XIR for processor 3	*/
115 #define BBC_SXG_RESV	0xf0 /* Reserved			*/
116 
117 /* POR Source register.  One may identify the cause of the most recent
118  * reset by reading this register.
119  */
120 #define BBC_PSRC_SPG0	0x0001 /* CPU 0 reset via BBC_SPG register	*/
121 #define BBC_PSRC_SPG1	0x0002 /* CPU 1 reset via BBC_SPG register	*/
122 #define BBC_PSRC_SPG2	0x0004 /* CPU 2 reset via BBC_SPG register	*/
123 #define BBC_PSRC_SPG3	0x0008 /* CPU 3 reset via BBC_SPG register	*/
124 #define BBC_PSRC_SPGSYS	0x0010 /* System reset via BBC_SPG register	*/
125 #define BBC_PSRC_JTAG	0x0020 /* System reset via JTAG+		*/
126 #define BBC_PSRC_BUTTON	0x0040 /* System reset via push-button dongle	*/
127 #define BBC_PSRC_PWRUP	0x0080 /* System reset via power-up		*/
128 #define BBC_PSRC_FE0	0x0100 /* CPU 0 reported Fatal_Error		*/
129 #define BBC_PSRC_FE1	0x0200 /* CPU 1 reported Fatal_Error		*/
130 #define BBC_PSRC_FE2	0x0400 /* CPU 2 reported Fatal_Error		*/
131 #define BBC_PSRC_FE3	0x0800 /* CPU 3 reported Fatal_Error		*/
132 #define BBC_PSRC_FE4	0x1000 /* Schizo reported Fatal_Error		*/
133 #define BBC_PSRC_FE5	0x2000 /* Safari device 5 reported Fatal_Error	*/
134 #define BBC_PSRC_FE6	0x4000 /* CPMS reported Fatal_Error		*/
135 #define BBC_PSRC_SYNTH	0x8000 /* System reset when on-board clock synthesizers
136 				* were updated.
137 				*/
138 #define BBC_PSRC_WDT   0x10000 /* System reset via Super I/O watchdog	*/
139 #define BBC_PSRC_RSC   0x20000 /* System reset via RSC remote monitoring
140 				* device
141 				*/
142 
143 /* XIR Source register.  The source of an XIR event sent to a processor may
144  * be determined via this register.
145  */
146 #define BBC_XSRC_SXG0	0x01	/* CPU 0 received XIR via Soft_XIR_GEN reg */
147 #define BBC_XSRC_SXG1	0x02	/* CPU 1 received XIR via Soft_XIR_GEN reg */
148 #define BBC_XSRC_SXG2	0x04	/* CPU 2 received XIR via Soft_XIR_GEN reg */
149 #define BBC_XSRC_SXG3	0x08	/* CPU 3 received XIR via Soft_XIR_GEN reg */
150 #define BBC_XSRC_JTAG	0x10	/* All CPUs received XIR via JTAG+         */
151 #define BBC_XSRC_W_OR_B	0x20	/* All CPUs received XIR either because:
152 				 * a) Super I/O watchdog fired, or
153 				 * b) XIR push button was activated
154 				 */
155 #define BBC_XSRC_RESV	0xc0	/* Reserved				   */
156 
157 /* Clock Synthesizers Control register.  This register provides the big-bang
158  * programming interface to the two clock synthesizers of the machine.
159  */
160 #define BBC_CSC_SLOAD	0x01	/* Directly connected to S_LOAD pins	*/
161 #define BBC_CSC_SDATA	0x02	/* Directly connected to S_DATA pins	*/
162 #define BBC_CSC_SCLOCK	0x04	/* Directly connected to S_CLOCK pins	*/
163 #define BBC_CSC_RESV	0x78	/* Reserved				*/
164 #define BBC_CSC_RST	0x80	/* Generate system reset when S_LOAD==1	*/
165 
166 /* Energy Star Control register.  This register is used to generate the
167  * clock frequency change trigger to the main system devices (Schizo and
168  * the processors).  The transition occurs when bits in this register
169  * go from 0 to 1, only one bit must be set at once else no action
170  * occurs.  Basically the sequence of events is:
171  * a) Choose new frequency: full, 1/2 or 1/32
172  * b) Program this desired frequency into the cpus and Schizo.
173  * c) Set the same value in this register.
174  * d) 16 system clocks later, clear this register.
175  */
176 #define BBC_ES_CTRL_1_1		0x01	/* Full frequency	*/
177 #define BBC_ES_CTRL_1_2		0x02	/* 1/2 frequency	*/
178 #define BBC_ES_CTRL_1_32	0x20	/* 1/32 frequency	*/
179 #define BBC_ES_RESV		0xdc	/* Reserved		*/
180 
181 /* Energy Star Assert Change Time register.  This determines the number
182  * of BBC clock cycles (which is half the system frequency) between
183  * the detection of FREEZE_ACK being asserted and the assertion of
184  * the CLK_CHANGE_L[2:0] signals.
185  */
186 #define BBC_ES_ACT_VAL	0xff
187 
188 /* Energy Star Assert Bypass Time register.  This determines the number
189  * of BBC clock cycles (which is half the system frequency) between
190  * the assertion of the CLK_CHANGE_L[2:0] signals and the assertion of
191  * the ESTAR_PLL_BYPASS signal.
192  */
193 #define BBC_ES_ABT_VAL	0xffff
194 
195 /* Energy Star PLL Settle Time register.  This determines the number of
196  * BBC clock cycles (which is half the system frequency) between the
197  * de-assertion of CLK_CHANGE_L[2:0] and the de-assertion of the FREEZE_L
198  * signal.
199  */
200 #define BBC_ES_PST_VAL	0xffffffff
201 
202 /* Energy Star Frequency Switch Latency register.  This is the number of
203  * BBC clocks between the de-assertion of CLK_CHANGE_L[2:0] and the first
204  * edge of the Safari clock at the new frequency.
205  */
206 #define BBC_ES_FSL_VAL	0xffffffff
207 
208 /* Keyboard Beep control register.  This is a simple enabler for the audio
209  * beep sound.
210  */
211 #define BBC_KBD_BEEP_ENABLE	0x01 /* Enable beep	*/
212 #define BBC_KBD_BEEP_RESV	0xfe /* Reserved	*/
213 
214 /* Keyboard Beep Counter register.  There is a free-running counter inside
215  * the BBC which runs at half the system clock.  The bit set in this register
216  * determines when the audio sound is generated.  So for example if bit
217  * 10 is set, the audio beep will oscillate at 1/(2**12).  The keyboard beep
218  * generator automatically selects a different bit to use if the system clock
219  * is changed via Energy Star.
220  */
221 #define BBC_KBD_BCNT_BITS	0x0007fc00
222 #define BBC_KBC_BCNT_RESV	0xfff803ff
223 
224 #endif /* _SPARC64_BBC_H */
225 
226