/* * Private header for the MPC52xx processor BestComm driver * * By private, we mean that driver should not use it directly. It's meant * to be used by the BestComm engine driver itself and by the intermediate * layer between the core and the drivers. * * Copyright (C) 2006 Sylvain Munaut <tnt@246tNt.com> * Copyright (C) 2005 Varma Electronics Oy, * ( by Andrey Volkov <avolkov@varma-el.com> ) * Copyright (C) 2003-2004 MontaVista, Software, Inc. * ( by Dale Farnsworth <dfarnsworth@mvista.com> ) * * This file is licensed under the terms of the GNU General Public License * version 2. This program is licensed "as is" without any warranty of any * kind, whether express or implied. */ #ifndef __BESTCOMM_PRIV_H__ #define __BESTCOMM_PRIV_H__ #include <linux/spinlock.h> #include <linux/of.h> #include <asm/io.h> #include <asm/mpc52xx.h> #include "sram.h" /* ======================================================================== */ /* Engine related stuff */ /* ======================================================================== */ /* Zones sizes and needed alignments */ #define BCOM_MAX_TASKS 16 #define BCOM_MAX_VAR 24 #define BCOM_MAX_INC 8 #define BCOM_MAX_FDT 64 #define BCOM_MAX_CTX 20 #define BCOM_CTX_SIZE (BCOM_MAX_CTX * sizeof(u32)) #define BCOM_CTX_ALIGN 0x100 #define BCOM_VAR_SIZE (BCOM_MAX_VAR * sizeof(u32)) #define BCOM_INC_SIZE (BCOM_MAX_INC * sizeof(u32)) #define BCOM_VAR_ALIGN 0x80 #define BCOM_FDT_SIZE (BCOM_MAX_FDT * sizeof(u32)) #define BCOM_FDT_ALIGN 0x100 /** * struct bcom_tdt - Task Descriptor Table Entry * */ struct bcom_tdt { u32 start; u32 stop; u32 var; u32 fdt; u32 exec_status; /* used internally by BestComm engine */ u32 mvtp; /* used internally by BestComm engine */ u32 context; u32 litbase; }; /** * struct bcom_engine * * This holds all info needed globaly to handle the engine */ struct bcom_engine { struct device_node *ofnode; struct mpc52xx_sdma __iomem *regs; phys_addr_t regs_base; struct bcom_tdt *tdt; u32 *ctx; u32 *var; u32 *fdt; spinlock_t lock; }; extern struct bcom_engine *bcom_eng; /* ======================================================================== */ /* Tasks related stuff */ /* ======================================================================== */ /* Tasks image header */ #define BCOM_TASK_MAGIC 0x4243544B /* 'BCTK' */ struct bcom_task_header { u32 magic; u8 desc_size; /* the size fields */ u8 var_size; /* are given in number */ u8 inc_size; /* of 32-bits words */ u8 first_var; u8 reserved[8]; }; /* Descriptors structure & co */ #define BCOM_DESC_NOP 0x000001f8 #define BCOM_LCD_MASK 0x80000000 #define BCOM_DRD_EXTENDED 0x40000000 #define BCOM_DRD_INITIATOR_SHIFT 21 /* Tasks pragma */ #define BCOM_PRAGMA_BIT_RSV 7 /* reserved pragma bit */ #define BCOM_PRAGMA_BIT_PRECISE_INC 6 /* increment 0=when possible, */ /* 1=iter end */ #define BCOM_PRAGMA_BIT_RST_ERROR_NO 5 /* don't reset errors on */ /* task enable */ #define BCOM_PRAGMA_BIT_PACK 4 /* pack data enable */ #define BCOM_PRAGMA_BIT_INTEGER 3 /* data alignment */ /* 0=frac(msb), 1=int(lsb) */ #define BCOM_PRAGMA_BIT_SPECREAD 2 /* XLB speculative read */ #define BCOM_PRAGMA_BIT_CW 1 /* write line buffer enable */ #define BCOM_PRAGMA_BIT_RL 0 /* read line buffer enable */ /* Looks like XLB speculative read generates XLB errors when a buffer * is at the end of the physical memory. i.e. when accessing the * lasts words, the engine tries to prefetch the next but there is no * next ... */ #define BCOM_STD_PRAGMA ((0 << BCOM_PRAGMA_BIT_RSV) | \ (0 << BCOM_PRAGMA_BIT_PRECISE_INC) | \ (0 << BCOM_PRAGMA_BIT_RST_ERROR_NO) | \ (0 << BCOM_PRAGMA_BIT_PACK) | \ (0 << BCOM_PRAGMA_BIT_INTEGER) | \ (0 << BCOM_PRAGMA_BIT_SPECREAD) | \ (1 << BCOM_PRAGMA_BIT_CW) | \ (1 << BCOM_PRAGMA_BIT_RL)) #define BCOM_PCI_PRAGMA ((0 << BCOM_PRAGMA_BIT_RSV) | \ (0 << BCOM_PRAGMA_BIT_PRECISE_INC) | \ (0 << BCOM_PRAGMA_BIT_RST_ERROR_NO) | \ (0 << BCOM_PRAGMA_BIT_PACK) | \ (1 << BCOM_PRAGMA_BIT_INTEGER) | \ (0 << BCOM_PRAGMA_BIT_SPECREAD) | \ (1 << BCOM_PRAGMA_BIT_CW) | \ (1 << BCOM_PRAGMA_BIT_RL)) #define BCOM_ATA_PRAGMA BCOM_STD_PRAGMA #define BCOM_CRC16_DP_0_PRAGMA BCOM_STD_PRAGMA #define BCOM_CRC16_DP_1_PRAGMA BCOM_STD_PRAGMA #define BCOM_FEC_RX_BD_PRAGMA BCOM_STD_PRAGMA #define BCOM_FEC_TX_BD_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_DP_0_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_DP_1_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_DP_2_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_DP_3_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_DP_BD_0_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_DP_BD_1_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_RX_BD_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_TX_BD_PRAGMA BCOM_STD_PRAGMA #define BCOM_GEN_LPC_PRAGMA BCOM_STD_PRAGMA #define BCOM_PCI_RX_PRAGMA BCOM_PCI_PRAGMA #define BCOM_PCI_TX_PRAGMA BCOM_PCI_PRAGMA /* Initiators number */ #define BCOM_INITIATOR_ALWAYS 0 #define BCOM_INITIATOR_SCTMR_0 1 #define BCOM_INITIATOR_SCTMR_1 2 #define BCOM_INITIATOR_FEC_RX 3 #define BCOM_INITIATOR_FEC_TX 4 #define BCOM_INITIATOR_ATA_RX 5 #define BCOM_INITIATOR_ATA_TX 6 #define BCOM_INITIATOR_SCPCI_RX 7 #define BCOM_INITIATOR_SCPCI_TX 8 #define BCOM_INITIATOR_PSC3_RX 9 #define BCOM_INITIATOR_PSC3_TX 10 #define BCOM_INITIATOR_PSC2_RX 11 #define BCOM_INITIATOR_PSC2_TX 12 #define BCOM_INITIATOR_PSC1_RX 13 #define BCOM_INITIATOR_PSC1_TX 14 #define BCOM_INITIATOR_SCTMR_2 15 #define BCOM_INITIATOR_SCLPC 16 #define BCOM_INITIATOR_PSC5_RX 17 #define BCOM_INITIATOR_PSC5_TX 18 #define BCOM_INITIATOR_PSC4_RX 19 #define BCOM_INITIATOR_PSC4_TX 20 #define BCOM_INITIATOR_I2C2_RX 21 #define BCOM_INITIATOR_I2C2_TX 22 #define BCOM_INITIATOR_I2C1_RX 23 #define BCOM_INITIATOR_I2C1_TX 24 #define BCOM_INITIATOR_PSC6_RX 25 #define BCOM_INITIATOR_PSC6_TX 26 #define BCOM_INITIATOR_IRDA_RX 25 #define BCOM_INITIATOR_IRDA_TX 26 #define BCOM_INITIATOR_SCTMR_3 27 #define BCOM_INITIATOR_SCTMR_4 28 #define BCOM_INITIATOR_SCTMR_5 29 #define BCOM_INITIATOR_SCTMR_6 30 #define BCOM_INITIATOR_SCTMR_7 31 /* Initiators priorities */ #define BCOM_IPR_ALWAYS 7 #define BCOM_IPR_SCTMR_0 2 #define BCOM_IPR_SCTMR_1 2 #define BCOM_IPR_FEC_RX 6 #define BCOM_IPR_FEC_TX 5 #define BCOM_IPR_ATA_RX 7 #define BCOM_IPR_ATA_TX 7 #define BCOM_IPR_SCPCI_RX 2 #define BCOM_IPR_SCPCI_TX 2 #define BCOM_IPR_PSC3_RX 2 #define BCOM_IPR_PSC3_TX 2 #define BCOM_IPR_PSC2_RX 2 #define BCOM_IPR_PSC2_TX 2 #define BCOM_IPR_PSC1_RX 2 #define BCOM_IPR_PSC1_TX 2 #define BCOM_IPR_SCTMR_2 2 #define BCOM_IPR_SCLPC 2 #define BCOM_IPR_PSC5_RX 2 #define BCOM_IPR_PSC5_TX 2 #define BCOM_IPR_PSC4_RX 2 #define BCOM_IPR_PSC4_TX 2 #define BCOM_IPR_I2C2_RX 2 #define BCOM_IPR_I2C2_TX 2 #define BCOM_IPR_I2C1_RX 2 #define BCOM_IPR_I2C1_TX 2 #define BCOM_IPR_PSC6_RX 2 #define BCOM_IPR_PSC6_TX 2 #define BCOM_IPR_IRDA_RX 2 #define BCOM_IPR_IRDA_TX 2 #define BCOM_IPR_SCTMR_3 2 #define BCOM_IPR_SCTMR_4 2 #define BCOM_IPR_SCTMR_5 2 #define BCOM_IPR_SCTMR_6 2 #define BCOM_IPR_SCTMR_7 2 /* ======================================================================== */ /* API */ /* ======================================================================== */ extern struct bcom_task *bcom_task_alloc(int bd_count, int bd_size, int priv_size); extern void bcom_task_free(struct bcom_task *tsk); extern int bcom_load_image(int task, u32 *task_image); extern void bcom_set_initiator(int task, int initiator); #define TASK_ENABLE 0x8000 /** * bcom_disable_prefetch - Hook to disable bus prefetching * * ATA DMA and the original MPC5200 need this due to silicon bugs. At the * moment disabling prefetch is a one-way street. There is no mechanism * in place to turn prefetch back on after it has been disabled. There is * no reason it couldn't be done, it would just be more complex to implement. */ static inline void bcom_disable_prefetch(void) { u16 regval; regval = in_be16(&bcom_eng->regs->PtdCntrl); out_be16(&bcom_eng->regs->PtdCntrl, regval | 1); }; static inline void bcom_enable_task(int task) { u16 reg; reg = in_be16(&bcom_eng->regs->tcr[task]); out_be16(&bcom_eng->regs->tcr[task], reg | TASK_ENABLE); } static inline void bcom_disable_task(int task) { u16 reg = in_be16(&bcom_eng->regs->tcr[task]); out_be16(&bcom_eng->regs->tcr[task], reg & ~TASK_ENABLE); } static inline u32 * bcom_task_desc(int task) { return bcom_sram_pa2va(bcom_eng->tdt[task].start); } static inline int bcom_task_num_descs(int task) { return (bcom_eng->tdt[task].stop - bcom_eng->tdt[task].start)/sizeof(u32) + 1; } static inline u32 * bcom_task_var(int task) { return bcom_sram_pa2va(bcom_eng->tdt[task].var); } static inline u32 * bcom_task_inc(int task) { return &bcom_task_var(task)[BCOM_MAX_VAR]; } static inline int bcom_drd_is_extended(u32 desc) { return (desc) & BCOM_DRD_EXTENDED; } static inline int bcom_desc_is_drd(u32 desc) { return !(desc & BCOM_LCD_MASK) && desc != BCOM_DESC_NOP; } static inline int bcom_desc_initiator(u32 desc) { return (desc >> BCOM_DRD_INITIATOR_SHIFT) & 0x1f; } static inline void bcom_set_desc_initiator(u32 *desc, int initiator) { *desc = (*desc & ~(0x1f << BCOM_DRD_INITIATOR_SHIFT)) | ((initiator & 0x1f) << BCOM_DRD_INITIATOR_SHIFT); } static inline void bcom_set_task_pragma(int task, int pragma) { u32 *fdt = &bcom_eng->tdt[task].fdt; *fdt = (*fdt & ~0xff) | pragma; } static inline void bcom_set_task_auto_start(int task, int next_task) { u16 __iomem *tcr = &bcom_eng->regs->tcr[task]; out_be16(tcr, (in_be16(tcr) & ~0xff) | 0x00c0 | next_task); } static inline void bcom_set_tcr_initiator(int task, int initiator) { u16 __iomem *tcr = &bcom_eng->regs->tcr[task]; out_be16(tcr, (in_be16(tcr) & ~0x1f00) | ((initiator & 0x1f) << 8)); } #endif /* __BESTCOMM_PRIV_H__ */