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/* SPDX-License-Identifier: GPL-2.0 */
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/*
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 * include/asm-m68k/dma.h
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 *
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 * Copyright 1995 (C) David S. Miller ([email protected])
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 *
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 * Hacked to fit Sun3x needs by Thomas Bogendoerfer
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 */
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#ifndef __M68K_DVMA_H
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#define __M68K_DVMA_H
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#define DVMA_PAGE_SHIFT	13
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#define DVMA_PAGE_SIZE	(1UL << DVMA_PAGE_SHIFT)
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#define DVMA_PAGE_MASK	(~(DVMA_PAGE_SIZE-1))
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#define DVMA_PAGE_ALIGN(addr)	ALIGN(addr, DVMA_PAGE_SIZE)
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extern void dvma_init(void);
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extern int dvma_map_iommu(unsigned long kaddr, unsigned long baddr,
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			  int len);
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#define dvma_malloc(x) dvma_malloc_align(x, 0)
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#define dvma_map(x, y) dvma_map_align(x, y, 0)
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#define dvma_map_vme(x, y) (dvma_map(x, y) & 0xfffff)
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#define dvma_map_align_vme(x, y, z) (dvma_map_align (x, y, z) & 0xfffff)
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extern unsigned long dvma_map_align(unsigned long kaddr, int len,
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			    int align);
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extern void *dvma_malloc_align(unsigned long len, unsigned long align);
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extern void dvma_unmap(void *baddr);
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extern void dvma_free(void *vaddr);
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#ifdef CONFIG_SUN3
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/* sun3 dvma page support */
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/* memory and pmegs potentially reserved for dvma */
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#define DVMA_PMEG_START 10
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#define DVMA_PMEG_END 16
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#define DVMA_START 0xf00000
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#define DVMA_END 0xfe0000
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#define DVMA_SIZE (DVMA_END-DVMA_START)
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#define IOMMU_TOTAL_ENTRIES 128
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#define IOMMU_ENTRIES 120
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/* empirical kludge -- dvma regions only seem to work right on 0x10000
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   byte boundaries */
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#define DVMA_REGION_SIZE 0x10000
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#define DVMA_ALIGN(addr) (((addr)+DVMA_REGION_SIZE-1) & \
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                         ~(DVMA_REGION_SIZE-1))
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/* virt <-> phys conversions */
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#define dvma_vtop(x) ((unsigned long)(x) & 0xffffff)
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#define dvma_ptov(x) ((unsigned long)(x) | 0xf000000)
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#define dvma_vtovme(x) ((unsigned long)(x) & 0x00fffff)
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#define dvma_vmetov(x) ((unsigned long)(x) | 0xff00000)
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#define dvma_vtob(x) dvma_vtop(x)
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#define dvma_btov(x) dvma_ptov(x)
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void sun3_dvma_init(void);
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static inline int dvma_map_cpu(unsigned long kaddr, unsigned long vaddr,
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			       int len)
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{
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	return 0;
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}
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static inline void dvma_unmap_iommu(unsigned long baddr, int len) { }
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#else /* Sun3x */
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/* sun3x dvma page support */
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#define DVMA_START 0x0
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#define DVMA_END 0xf00000
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#define DVMA_SIZE (DVMA_END-DVMA_START)
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#define IOMMU_TOTAL_ENTRIES	   2048
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/* the prom takes the top meg */
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#define IOMMU_ENTRIES              (IOMMU_TOTAL_ENTRIES - 0x80)
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#define dvma_vtob(x) ((unsigned long)(x) & 0x00ffffff)
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#define dvma_btov(x) ((unsigned long)(x) | 0xff000000)
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static inline void sun3_dvma_init(void) { }
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int dvma_map_cpu(unsigned long kaddr, unsigned long vaddr, int len);
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void dvma_unmap_iommu(unsigned long baddr, int len);
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/* everything below this line is specific to dma used for the onboard
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   ESP scsi on sun3x */
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/* Structure to describe the current status of DMA registers on the Sparc */
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struct sparc_dma_registers {
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  __volatile__ unsigned long cond_reg;	/* DMA condition register */
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  __volatile__ unsigned long st_addr;	/* Start address of this transfer */
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  __volatile__ unsigned long  cnt;	/* How many bytes to transfer */
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  __volatile__ unsigned long dma_test;	/* DMA test register */
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};
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/* DVMA chip revisions */
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enum dvma_rev {
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	dvmarev0,
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	dvmaesc1,
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	dvmarev1,
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	dvmarev2,
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	dvmarev3,
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	dvmarevplus,
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	dvmahme
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};
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#define DMA_HASCOUNT(rev)  ((rev)==dvmaesc1)
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/* Linux DMA information structure, filled during probe. */
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struct Linux_SBus_DMA {
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	struct Linux_SBus_DMA *next;
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	struct linux_sbus_device *SBus_dev;
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	struct sparc_dma_registers *regs;
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	/* Status, misc info */
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	int node;                /* Prom node for this DMA device */
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	int running;             /* Are we doing DMA now? */
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	int allocated;           /* Are we "owned" by anyone yet? */
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	/* Transfer information. */
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	unsigned long addr;      /* Start address of current transfer */
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	int nbytes;              /* Size of current transfer */
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	int realbytes;           /* For splitting up large transfers, etc. */
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	/* DMA revision */
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	enum dvma_rev revision;
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};
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extern struct Linux_SBus_DMA *dma_chain;
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/* Broken hardware... */
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#define DMA_ISBROKEN(dma)    ((dma)->revision == dvmarev1)
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#define DMA_ISESC1(dma)      ((dma)->revision == dvmaesc1)
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/* Fields in the cond_reg register */
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/* First, the version identification bits */
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#define DMA_DEVICE_ID    0xf0000000        /* Device identification bits */
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#define DMA_VERS0        0x00000000        /* Sunray DMA version */
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#define DMA_ESCV1        0x40000000        /* DMA ESC Version 1 */
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#define DMA_VERS1        0x80000000        /* DMA rev 1 */
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#define DMA_VERS2        0xa0000000        /* DMA rev 2 */
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#define DMA_VERHME       0xb0000000        /* DMA hme gate array */
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#define DMA_VERSPLUS     0x90000000        /* DMA rev 1 PLUS */
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#define DMA_HNDL_INTR    0x00000001        /* An IRQ needs to be handled */
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#define DMA_HNDL_ERROR   0x00000002        /* We need to take an error */
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#define DMA_FIFO_ISDRAIN 0x0000000c        /* The DMA FIFO is draining */
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#define DMA_INT_ENAB     0x00000010        /* Turn on interrupts */
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#define DMA_FIFO_INV     0x00000020        /* Invalidate the FIFO */
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#define DMA_ACC_SZ_ERR   0x00000040        /* The access size was bad */
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#define DMA_FIFO_STDRAIN 0x00000040        /* DMA_VERS1 Drain the FIFO */
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#define DMA_RST_SCSI     0x00000080        /* Reset the SCSI controller */
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#define DMA_RST_ENET     DMA_RST_SCSI      /* Reset the ENET controller */
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#define DMA_ST_WRITE     0x00000100        /* write from device to memory */
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#define DMA_ENABLE       0x00000200        /* Fire up DMA, handle requests */
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#define DMA_PEND_READ    0x00000400        /* DMA_VERS1/0/PLUS Pending Read */
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#define DMA_ESC_BURST    0x00000800        /* 1=16byte 0=32byte */
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#define DMA_READ_AHEAD   0x00001800        /* DMA read ahead partial longword */
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#define DMA_DSBL_RD_DRN  0x00001000        /* No EC drain on slave reads */
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#define DMA_BCNT_ENAB    0x00002000        /* If on, use the byte counter */
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#define DMA_TERM_CNTR    0x00004000        /* Terminal counter */
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#define DMA_CSR_DISAB    0x00010000        /* No FIFO drains during csr */
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#define DMA_SCSI_DISAB   0x00020000        /* No FIFO drains during reg */
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#define DMA_DSBL_WR_INV  0x00020000        /* No EC inval. on slave writes */
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#define DMA_ADD_ENABLE   0x00040000        /* Special ESC DVMA optimization */
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#define DMA_E_BURST8	 0x00040000	   /* ENET: SBUS r/w burst size */
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#define DMA_BRST_SZ      0x000c0000        /* SCSI: SBUS r/w burst size */
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#define DMA_BRST64       0x00080000        /* SCSI: 64byte bursts (HME on UltraSparc only) */
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#define DMA_BRST32       0x00040000        /* SCSI: 32byte bursts */
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#define DMA_BRST16       0x00000000        /* SCSI: 16byte bursts */
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#define DMA_BRST0        0x00080000        /* SCSI: no bursts (non-HME gate arrays) */
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#define DMA_ADDR_DISAB   0x00100000        /* No FIFO drains during addr */
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#define DMA_2CLKS        0x00200000        /* Each transfer = 2 clock ticks */
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#define DMA_3CLKS        0x00400000        /* Each transfer = 3 clock ticks */
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#define DMA_EN_ENETAUI   DMA_3CLKS         /* Put lance into AUI-cable mode */
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#define DMA_CNTR_DISAB   0x00800000        /* No IRQ when DMA_TERM_CNTR set */
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#define DMA_AUTO_NADDR   0x01000000        /* Use "auto nxt addr" feature */
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#define DMA_SCSI_ON      0x02000000        /* Enable SCSI dma */
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#define DMA_PARITY_OFF   0x02000000        /* HME: disable parity checking */
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#define DMA_LOADED_ADDR  0x04000000        /* Address has been loaded */
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#define DMA_LOADED_NADDR 0x08000000        /* Next address has been loaded */
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/* Values describing the burst-size property from the PROM */
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#define DMA_BURST1       0x01
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#define DMA_BURST2       0x02
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#define DMA_BURST4       0x04
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#define DMA_BURST8       0x08
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#define DMA_BURST16      0x10
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#define DMA_BURST32      0x20
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#define DMA_BURST64      0x40
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#define DMA_BURSTBITS    0x7f
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/* Determine highest possible final transfer address given a base */
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#define DMA_MAXEND(addr) (0x01000000UL-(((unsigned long)(addr))&0x00ffffffUL))
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/* Yes, I hack a lot of elisp in my spare time... */
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#define DMA_ERROR_P(regs)  ((((regs)->cond_reg) & DMA_HNDL_ERROR))
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#define DMA_IRQ_P(regs)    ((((regs)->cond_reg) & (DMA_HNDL_INTR | DMA_HNDL_ERROR)))
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#define DMA_WRITE_P(regs)  ((((regs)->cond_reg) & DMA_ST_WRITE))
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#define DMA_OFF(regs)      ((((regs)->cond_reg) &= (~DMA_ENABLE)))
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#define DMA_INTSOFF(regs)  ((((regs)->cond_reg) &= (~DMA_INT_ENAB)))
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#define DMA_INTSON(regs)   ((((regs)->cond_reg) |= (DMA_INT_ENAB)))
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#define DMA_PUNTFIFO(regs) ((((regs)->cond_reg) |= DMA_FIFO_INV))
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#define DMA_SETSTART(regs, addr)  ((((regs)->st_addr) = (char *) addr))
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#define DMA_BEGINDMA_W(regs) \
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        ((((regs)->cond_reg |= (DMA_ST_WRITE|DMA_ENABLE|DMA_INT_ENAB))))
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#define DMA_BEGINDMA_R(regs) \
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        ((((regs)->cond_reg |= ((DMA_ENABLE|DMA_INT_ENAB)&(~DMA_ST_WRITE)))))
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/* For certain DMA chips, we need to disable ints upon irq entry
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 * and turn them back on when we are done.  So in any ESP interrupt
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 * handler you *must* call DMA_IRQ_ENTRY upon entry and DMA_IRQ_EXIT
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 * when leaving the handler.  You have been warned...
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 */
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#define DMA_IRQ_ENTRY(dma, dregs) do { \
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        if(DMA_ISBROKEN(dma)) DMA_INTSOFF(dregs); \
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   } while (0)
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#define DMA_IRQ_EXIT(dma, dregs) do { \
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	if(DMA_ISBROKEN(dma)) DMA_INTSON(dregs); \
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   } while(0)
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/* Reset the friggin' thing... */
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#define DMA_RESET(dma) do { \
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	struct sparc_dma_registers *regs = dma->regs;                      \
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	/* Let the current FIFO drain itself */                            \
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	sparc_dma_pause(regs, (DMA_FIFO_ISDRAIN));                         \
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	/* Reset the logic */                                              \
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	regs->cond_reg |= (DMA_RST_SCSI);     /* assert */                 \
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	__delay(400);                         /* let the bits set ;) */    \
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	regs->cond_reg &= ~(DMA_RST_SCSI);    /* de-assert */              \
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	sparc_dma_enable_interrupts(regs);    /* Re-enable interrupts */   \
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	/* Enable FAST transfers if available */                           \
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	if(dma->revision>dvmarev1) regs->cond_reg |= DMA_3CLKS;            \
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	dma->running = 0;                                                  \
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} while(0)
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#endif /* !CONFIG_SUN3 */
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#endif /* !(__M68K_DVMA_H) */
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