/* * QUICC Engine (QE) Internal Memory Map. * The Internal Memory Map for devices with QE on them. This * is the superset of all QE devices (8360, etc.). * Copyright (C) 2006. Freescale Semiconductor, Inc. All rights reserved. * * Authors: Shlomi Gridish <gridish@freescale.com> * Li Yang <leoli@freescale.com> * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. */ #ifndef _ASM_POWERPC_IMMAP_QE_H #define _ASM_POWERPC_IMMAP_QE_H #ifdef __KERNEL__ #include <linux/kernel.h> #include <asm/io.h> #define QE_IMMAP_SIZE (1024 * 1024) /* 1MB from 1MB+IMMR */ /* QE I-RAM */ struct qe_iram { __be32 iadd; /* I-RAM Address Register */ __be32 idata; /* I-RAM Data Register */ u8 res0[0x04]; __be32 iready; /* I-RAM Ready Register */ u8 res1[0x70]; } __attribute__ ((packed)); /* QE Interrupt Controller */ struct qe_ic_regs { __be32 qicr; __be32 qivec; __be32 qripnr; __be32 qipnr; __be32 qipxcc; __be32 qipycc; __be32 qipwcc; __be32 qipzcc; __be32 qimr; __be32 qrimr; __be32 qicnr; u8 res0[0x4]; __be32 qiprta; __be32 qiprtb; u8 res1[0x4]; __be32 qricr; u8 res2[0x20]; __be32 qhivec; u8 res3[0x1C]; } __attribute__ ((packed)); /* Communications Processor */ struct cp_qe { __be32 cecr; /* QE command register */ __be32 ceccr; /* QE controller configuration register */ __be32 cecdr; /* QE command data register */ u8 res0[0xA]; __be16 ceter; /* QE timer event register */ u8 res1[0x2]; __be16 cetmr; /* QE timers mask register */ __be32 cetscr; /* QE time-stamp timer control register */ __be32 cetsr1; /* QE time-stamp register 1 */ __be32 cetsr2; /* QE time-stamp register 2 */ u8 res2[0x8]; __be32 cevter; /* QE virtual tasks event register */ __be32 cevtmr; /* QE virtual tasks mask register */ __be16 cercr; /* QE RAM control register */ u8 res3[0x2]; u8 res4[0x24]; __be16 ceexe1; /* QE external request 1 event register */ u8 res5[0x2]; __be16 ceexm1; /* QE external request 1 mask register */ u8 res6[0x2]; __be16 ceexe2; /* QE external request 2 event register */ u8 res7[0x2]; __be16 ceexm2; /* QE external request 2 mask register */ u8 res8[0x2]; __be16 ceexe3; /* QE external request 3 event register */ u8 res9[0x2]; __be16 ceexm3; /* QE external request 3 mask register */ u8 res10[0x2]; __be16 ceexe4; /* QE external request 4 event register */ u8 res11[0x2]; __be16 ceexm4; /* QE external request 4 mask register */ u8 res12[0x3A]; __be32 ceurnr; /* QE microcode revision number register */ u8 res13[0x244]; } __attribute__ ((packed)); /* QE Multiplexer */ struct qe_mux { __be32 cmxgcr; /* CMX general clock route register */ __be32 cmxsi1cr_l; /* CMX SI1 clock route low register */ __be32 cmxsi1cr_h; /* CMX SI1 clock route high register */ __be32 cmxsi1syr; /* CMX SI1 SYNC route register */ __be32 cmxucr[4]; /* CMX UCCx clock route registers */ __be32 cmxupcr; /* CMX UPC clock route register */ u8 res0[0x1C]; } __attribute__ ((packed)); /* QE Timers */ struct qe_timers { u8 gtcfr1; /* Timer 1 and Timer 2 global config register*/ u8 res0[0x3]; u8 gtcfr2; /* Timer 3 and timer 4 global config register*/ u8 res1[0xB]; __be16 gtmdr1; /* Timer 1 mode register */ __be16 gtmdr2; /* Timer 2 mode register */ __be16 gtrfr1; /* Timer 1 reference register */ __be16 gtrfr2; /* Timer 2 reference register */ __be16 gtcpr1; /* Timer 1 capture register */ __be16 gtcpr2; /* Timer 2 capture register */ __be16 gtcnr1; /* Timer 1 counter */ __be16 gtcnr2; /* Timer 2 counter */ __be16 gtmdr3; /* Timer 3 mode register */ __be16 gtmdr4; /* Timer 4 mode register */ __be16 gtrfr3; /* Timer 3 reference register */ __be16 gtrfr4; /* Timer 4 reference register */ __be16 gtcpr3; /* Timer 3 capture register */ __be16 gtcpr4; /* Timer 4 capture register */ __be16 gtcnr3; /* Timer 3 counter */ __be16 gtcnr4; /* Timer 4 counter */ __be16 gtevr1; /* Timer 1 event register */ __be16 gtevr2; /* Timer 2 event register */ __be16 gtevr3; /* Timer 3 event register */ __be16 gtevr4; /* Timer 4 event register */ __be16 gtps; /* Timer 1 prescale register */ u8 res2[0x46]; } __attribute__ ((packed)); /* BRG */ struct qe_brg { __be32 brgc[16]; /* BRG configuration registers */ u8 res0[0x40]; } __attribute__ ((packed)); /* SPI */ struct spi { u8 res0[0x20]; __be32 spmode; /* SPI mode register */ u8 res1[0x2]; u8 spie; /* SPI event register */ u8 res2[0x1]; u8 res3[0x2]; u8 spim; /* SPI mask register */ u8 res4[0x1]; u8 res5[0x1]; u8 spcom; /* SPI command register */ u8 res6[0x2]; __be32 spitd; /* SPI transmit data register (cpu mode) */ __be32 spird; /* SPI receive data register (cpu mode) */ u8 res7[0x8]; } __attribute__ ((packed)); /* SI */ struct si1 { __be16 siamr1; /* SI1 TDMA mode register */ __be16 sibmr1; /* SI1 TDMB mode register */ __be16 sicmr1; /* SI1 TDMC mode register */ __be16 sidmr1; /* SI1 TDMD mode register */ u8 siglmr1_h; /* SI1 global mode register high */ u8 res0[0x1]; u8 sicmdr1_h; /* SI1 command register high */ u8 res2[0x1]; u8 sistr1_h; /* SI1 status register high */ u8 res3[0x1]; __be16 sirsr1_h; /* SI1 RAM shadow address register high */ u8 sitarc1; /* SI1 RAM counter Tx TDMA */ u8 sitbrc1; /* SI1 RAM counter Tx TDMB */ u8 sitcrc1; /* SI1 RAM counter Tx TDMC */ u8 sitdrc1; /* SI1 RAM counter Tx TDMD */ u8 sirarc1; /* SI1 RAM counter Rx TDMA */ u8 sirbrc1; /* SI1 RAM counter Rx TDMB */ u8 sircrc1; /* SI1 RAM counter Rx TDMC */ u8 sirdrc1; /* SI1 RAM counter Rx TDMD */ u8 res4[0x8]; __be16 siemr1; /* SI1 TDME mode register 16 bits */ __be16 sifmr1; /* SI1 TDMF mode register 16 bits */ __be16 sigmr1; /* SI1 TDMG mode register 16 bits */ __be16 sihmr1; /* SI1 TDMH mode register 16 bits */ u8 siglmg1_l; /* SI1 global mode register low 8 bits */ u8 res5[0x1]; u8 sicmdr1_l; /* SI1 command register low 8 bits */ u8 res6[0x1]; u8 sistr1_l; /* SI1 status register low 8 bits */ u8 res7[0x1]; __be16 sirsr1_l; /* SI1 RAM shadow address register low 16 bits*/ u8 siterc1; /* SI1 RAM counter Tx TDME 8 bits */ u8 sitfrc1; /* SI1 RAM counter Tx TDMF 8 bits */ u8 sitgrc1; /* SI1 RAM counter Tx TDMG 8 bits */ u8 sithrc1; /* SI1 RAM counter Tx TDMH 8 bits */ u8 sirerc1; /* SI1 RAM counter Rx TDME 8 bits */ u8 sirfrc1; /* SI1 RAM counter Rx TDMF 8 bits */ u8 sirgrc1; /* SI1 RAM counter Rx TDMG 8 bits */ u8 sirhrc1; /* SI1 RAM counter Rx TDMH 8 bits */ u8 res8[0x8]; __be32 siml1; /* SI1 multiframe limit register */ u8 siedm1; /* SI1 extended diagnostic mode register */ u8 res9[0xBB]; } __attribute__ ((packed)); /* SI Routing Tables */ struct sir { u8 tx[0x400]; u8 rx[0x400]; u8 res0[0x800]; } __attribute__ ((packed)); /* USB Controller */ struct qe_usb_ctlr { u8 usb_usmod; u8 usb_usadr; u8 usb_uscom; u8 res1[1]; __be16 usb_usep[4]; u8 res2[4]; __be16 usb_usber; u8 res3[2]; __be16 usb_usbmr; u8 res4[1]; u8 usb_usbs; __be16 usb_ussft; u8 res5[2]; __be16 usb_usfrn; u8 res6[0x22]; } __attribute__ ((packed)); /* MCC */ struct qe_mcc { __be32 mcce; /* MCC event register */ __be32 mccm; /* MCC mask register */ __be32 mccf; /* MCC configuration register */ __be32 merl; /* MCC emergency request level register */ u8 res0[0xF0]; } __attribute__ ((packed)); /* QE UCC Slow */ struct ucc_slow { __be32 gumr_l; /* UCCx general mode register (low) */ __be32 gumr_h; /* UCCx general mode register (high) */ __be16 upsmr; /* UCCx protocol-specific mode register */ u8 res0[0x2]; __be16 utodr; /* UCCx transmit on demand register */ __be16 udsr; /* UCCx data synchronization register */ __be16 ucce; /* UCCx event register */ u8 res1[0x2]; __be16 uccm; /* UCCx mask register */ u8 res2[0x1]; u8 uccs; /* UCCx status register */ u8 res3[0x24]; __be16 utpt; u8 res4[0x52]; u8 guemr; /* UCC general extended mode register */ } __attribute__ ((packed)); /* QE UCC Fast */ struct ucc_fast { __be32 gumr; /* UCCx general mode register */ __be32 upsmr; /* UCCx protocol-specific mode register */ __be16 utodr; /* UCCx transmit on demand register */ u8 res0[0x2]; __be16 udsr; /* UCCx data synchronization register */ u8 res1[0x2]; __be32 ucce; /* UCCx event register */ __be32 uccm; /* UCCx mask register */ u8 uccs; /* UCCx status register */ u8 res2[0x7]; __be32 urfb; /* UCC receive FIFO base */ __be16 urfs; /* UCC receive FIFO size */ u8 res3[0x2]; __be16 urfet; /* UCC receive FIFO emergency threshold */ __be16 urfset; /* UCC receive FIFO special emergency threshold */ __be32 utfb; /* UCC transmit FIFO base */ __be16 utfs; /* UCC transmit FIFO size */ u8 res4[0x2]; __be16 utfet; /* UCC transmit FIFO emergency threshold */ u8 res5[0x2]; __be16 utftt; /* UCC transmit FIFO transmit threshold */ u8 res6[0x2]; __be16 utpt; /* UCC transmit polling timer */ u8 res7[0x2]; __be32 urtry; /* UCC retry counter register */ u8 res8[0x4C]; u8 guemr; /* UCC general extended mode register */ } __attribute__ ((packed)); struct ucc { union { struct ucc_slow slow; struct ucc_fast fast; u8 res[0x200]; /* UCC blocks are 512 bytes each */ }; } __attribute__ ((packed)); /* MultiPHY UTOPIA POS Controllers (UPC) */ struct upc { __be32 upgcr; /* UTOPIA/POS general configuration register */ __be32 uplpa; /* UTOPIA/POS last PHY address */ __be32 uphec; /* ATM HEC register */ __be32 upuc; /* UTOPIA/POS UCC configuration */ __be32 updc1; /* UTOPIA/POS device 1 configuration */ __be32 updc2; /* UTOPIA/POS device 2 configuration */ __be32 updc3; /* UTOPIA/POS device 3 configuration */ __be32 updc4; /* UTOPIA/POS device 4 configuration */ __be32 upstpa; /* UTOPIA/POS STPA threshold */ u8 res0[0xC]; __be32 updrs1_h; /* UTOPIA/POS device 1 rate select */ __be32 updrs1_l; /* UTOPIA/POS device 1 rate select */ __be32 updrs2_h; /* UTOPIA/POS device 2 rate select */ __be32 updrs2_l; /* UTOPIA/POS device 2 rate select */ __be32 updrs3_h; /* UTOPIA/POS device 3 rate select */ __be32 updrs3_l; /* UTOPIA/POS device 3 rate select */ __be32 updrs4_h; /* UTOPIA/POS device 4 rate select */ __be32 updrs4_l; /* UTOPIA/POS device 4 rate select */ __be32 updrp1; /* UTOPIA/POS device 1 receive priority low */ __be32 updrp2; /* UTOPIA/POS device 2 receive priority low */ __be32 updrp3; /* UTOPIA/POS device 3 receive priority low */ __be32 updrp4; /* UTOPIA/POS device 4 receive priority low */ __be32 upde1; /* UTOPIA/POS device 1 event */ __be32 upde2; /* UTOPIA/POS device 2 event */ __be32 upde3; /* UTOPIA/POS device 3 event */ __be32 upde4; /* UTOPIA/POS device 4 event */ __be16 uprp1; __be16 uprp2; __be16 uprp3; __be16 uprp4; u8 res1[0x8]; __be16 uptirr1_0; /* Device 1 transmit internal rate 0 */ __be16 uptirr1_1; /* Device 1 transmit internal rate 1 */ __be16 uptirr1_2; /* Device 1 transmit internal rate 2 */ __be16 uptirr1_3; /* Device 1 transmit internal rate 3 */ __be16 uptirr2_0; /* Device 2 transmit internal rate 0 */ __be16 uptirr2_1; /* Device 2 transmit internal rate 1 */ __be16 uptirr2_2; /* Device 2 transmit internal rate 2 */ __be16 uptirr2_3; /* Device 2 transmit internal rate 3 */ __be16 uptirr3_0; /* Device 3 transmit internal rate 0 */ __be16 uptirr3_1; /* Device 3 transmit internal rate 1 */ __be16 uptirr3_2; /* Device 3 transmit internal rate 2 */ __be16 uptirr3_3; /* Device 3 transmit internal rate 3 */ __be16 uptirr4_0; /* Device 4 transmit internal rate 0 */ __be16 uptirr4_1; /* Device 4 transmit internal rate 1 */ __be16 uptirr4_2; /* Device 4 transmit internal rate 2 */ __be16 uptirr4_3; /* Device 4 transmit internal rate 3 */ __be32 uper1; /* Device 1 port enable register */ __be32 uper2; /* Device 2 port enable register */ __be32 uper3; /* Device 3 port enable register */ __be32 uper4; /* Device 4 port enable register */ u8 res2[0x150]; } __attribute__ ((packed)); /* SDMA */ struct sdma { __be32 sdsr; /* Serial DMA status register */ __be32 sdmr; /* Serial DMA mode register */ __be32 sdtr1; /* SDMA system bus threshold register */ __be32 sdtr2; /* SDMA secondary bus threshold register */ __be32 sdhy1; /* SDMA system bus hysteresis register */ __be32 sdhy2; /* SDMA secondary bus hysteresis register */ __be32 sdta1; /* SDMA system bus address register */ __be32 sdta2; /* SDMA secondary bus address register */ __be32 sdtm1; /* SDMA system bus MSNUM register */ __be32 sdtm2; /* SDMA secondary bus MSNUM register */ u8 res0[0x10]; __be32 sdaqr; /* SDMA address bus qualify register */ __be32 sdaqmr; /* SDMA address bus qualify mask register */ u8 res1[0x4]; __be32 sdebcr; /* SDMA CAM entries base register */ u8 res2[0x38]; } __attribute__ ((packed)); /* Debug Space */ struct dbg { __be32 bpdcr; /* Breakpoint debug command register */ __be32 bpdsr; /* Breakpoint debug status register */ __be32 bpdmr; /* Breakpoint debug mask register */ __be32 bprmrr0; /* Breakpoint request mode risc register 0 */ __be32 bprmrr1; /* Breakpoint request mode risc register 1 */ u8 res0[0x8]; __be32 bprmtr0; /* Breakpoint request mode trb register 0 */ __be32 bprmtr1; /* Breakpoint request mode trb register 1 */ u8 res1[0x8]; __be32 bprmir; /* Breakpoint request mode immediate register */ __be32 bprmsr; /* Breakpoint request mode serial register */ __be32 bpemr; /* Breakpoint exit mode register */ u8 res2[0x48]; } __attribute__ ((packed)); /* * RISC Special Registers (Trap and Breakpoint). These are described in * the QE Developer's Handbook. */ struct rsp { __be32 tibcr[16]; /* Trap/instruction breakpoint control regs */ u8 res0[64]; __be32 ibcr0; __be32 ibs0; __be32 ibcnr0; u8 res1[4]; __be32 ibcr1; __be32 ibs1; __be32 ibcnr1; __be32 npcr; __be32 dbcr; __be32 dbar; __be32 dbamr; __be32 dbsr; __be32 dbcnr; u8 res2[12]; __be32 dbdr_h; __be32 dbdr_l; __be32 dbdmr_h; __be32 dbdmr_l; __be32 bsr; __be32 bor; __be32 bior; u8 res3[4]; __be32 iatr[4]; __be32 eccr; /* Exception control configuration register */ __be32 eicr; u8 res4[0x100-0xf8]; } __attribute__ ((packed)); struct qe_immap { struct qe_iram iram; /* I-RAM */ struct qe_ic_regs ic; /* Interrupt Controller */ struct cp_qe cp; /* Communications Processor */ struct qe_mux qmx; /* QE Multiplexer */ struct qe_timers qet; /* QE Timers */ struct spi spi[0x2]; /* spi */ struct qe_mcc mcc; /* mcc */ struct qe_brg brg; /* brg */ struct qe_usb_ctlr usb; /* USB */ struct si1 si1; /* SI */ u8 res11[0x800]; struct sir sir; /* SI Routing Tables */ struct ucc ucc1; /* ucc1 */ struct ucc ucc3; /* ucc3 */ struct ucc ucc5; /* ucc5 */ struct ucc ucc7; /* ucc7 */ u8 res12[0x600]; struct upc upc1; /* MultiPHY UTOPIA POS Ctrlr 1*/ struct ucc ucc2; /* ucc2 */ struct ucc ucc4; /* ucc4 */ struct ucc ucc6; /* ucc6 */ struct ucc ucc8; /* ucc8 */ u8 res13[0x600]; struct upc upc2; /* MultiPHY UTOPIA POS Ctrlr 2*/ struct sdma sdma; /* SDMA */ struct dbg dbg; /* 0x104080 - 0x1040FF Debug Space */ struct rsp rsp[0x2]; /* 0x104100 - 0x1042FF RISC Special Registers (Trap and Breakpoint) */ u8 res14[0x300]; /* 0x104300 - 0x1045FF */ u8 res15[0x3A00]; /* 0x104600 - 0x107FFF */ u8 res16[0x8000]; /* 0x108000 - 0x110000 */ u8 muram[0xC000]; /* 0x110000 - 0x11C000 Multi-user RAM */ u8 res17[0x24000]; /* 0x11C000 - 0x140000 */ u8 res18[0xC0000]; /* 0x140000 - 0x200000 */ } __attribute__ ((packed)); extern struct qe_immap __iomem *qe_immr; extern phys_addr_t get_qe_base(void); /* * Returns the offset within the QE address space of the given pointer. * * Note that the QE does not support 36-bit physical addresses, so if * get_qe_base() returns a number above 4GB, the caller will probably fail. */ static inline phys_addr_t immrbar_virt_to_phys(void *address) { void *q = (void *)qe_immr; /* Is it a MURAM address? */ if ((address >= q) && (address < (q + QE_IMMAP_SIZE))) return get_qe_base() + (address - q); /* It's an address returned by kmalloc */ return virt_to_phys(address); } #endif /* __KERNEL__ */ #endif /* _ASM_POWERPC_IMMAP_QE_H */