Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Atsushi Nemoto | 975 | 99.19% | 1 | 25.00% |
Dan J Williams | 4 | 0.41% | 1 | 25.00% |
Thomas Gleixner | 2 | 0.20% | 1 | 25.00% |
Ralf Baechle | 2 | 0.20% | 1 | 25.00% |
Total | 983 | 4 |
/* SPDX-License-Identifier: GPL-2.0-only */ /* * Driver for the TXx9 SoC DMA Controller * * Copyright (C) 2009 Atsushi Nemoto */ #ifndef TXX9DMAC_H #define TXX9DMAC_H #include <linux/dmaengine.h> #include <asm/txx9/dmac.h> /* * Design Notes: * * This DMAC have four channels and one FIFO buffer. Each channel can * be configured for memory-memory or device-memory transfer, but only * one channel can do alignment-free memory-memory transfer at a time * while the channel should occupy the FIFO buffer for effective * transfers. * * Instead of dynamically assign the FIFO buffer to channels, I chose * make one dedicated channel for memory-memory transfer. The * dedicated channel is public. Other channels are private and used * for slave transfer. Some devices in the SoC are wired to certain * DMA channel. */ #ifdef CONFIG_MACH_TX49XX static inline bool txx9_dma_have_SMPCHN(void) { return true; } #define TXX9_DMA_USE_SIMPLE_CHAIN #else static inline bool txx9_dma_have_SMPCHN(void) { return false; } #endif #ifdef __LITTLE_ENDIAN #ifdef CONFIG_MACH_TX49XX #define CCR_LE TXX9_DMA_CCR_LE #define MCR_LE 0 #else #define CCR_LE 0 #define MCR_LE TXX9_DMA_MCR_LE #endif #else #define CCR_LE 0 #define MCR_LE 0 #endif /* * Redefine this macro to handle differences between 32- and 64-bit * addressing, big vs. little endian, etc. */ #ifdef __BIG_ENDIAN #define TXX9_DMA_REG32(name) u32 __pad_##name; u32 name #else #define TXX9_DMA_REG32(name) u32 name; u32 __pad_##name #endif /* Hardware register definitions. */ struct txx9dmac_cregs { #if defined(CONFIG_32BIT) && !defined(CONFIG_PHYS_ADDR_T_64BIT) TXX9_DMA_REG32(CHAR); /* Chain Address Register */ #else u64 CHAR; /* Chain Address Register */ #endif u64 SAR; /* Source Address Register */ u64 DAR; /* Destination Address Register */ TXX9_DMA_REG32(CNTR); /* Count Register */ TXX9_DMA_REG32(SAIR); /* Source Address Increment Register */ TXX9_DMA_REG32(DAIR); /* Destination Address Increment Register */ TXX9_DMA_REG32(CCR); /* Channel Control Register */ TXX9_DMA_REG32(CSR); /* Channel Status Register */ }; struct txx9dmac_cregs32 { u32 CHAR; u32 SAR; u32 DAR; u32 CNTR; u32 SAIR; u32 DAIR; u32 CCR; u32 CSR; }; struct txx9dmac_regs { /* per-channel registers */ struct txx9dmac_cregs CHAN[TXX9_DMA_MAX_NR_CHANNELS]; u64 __pad[9]; u64 MFDR; /* Memory Fill Data Register */ TXX9_DMA_REG32(MCR); /* Master Control Register */ }; struct txx9dmac_regs32 { struct txx9dmac_cregs32 CHAN[TXX9_DMA_MAX_NR_CHANNELS]; u32 __pad[9]; u32 MFDR; u32 MCR; }; /* bits for MCR */ #define TXX9_DMA_MCR_EIS(ch) (0x10000000<<(ch)) #define TXX9_DMA_MCR_DIS(ch) (0x01000000<<(ch)) #define TXX9_DMA_MCR_RSFIF 0x00000080 #define TXX9_DMA_MCR_FIFUM(ch) (0x00000008<<(ch)) #define TXX9_DMA_MCR_LE 0x00000004 #define TXX9_DMA_MCR_RPRT 0x00000002 #define TXX9_DMA_MCR_MSTEN 0x00000001 /* bits for CCRn */ #define TXX9_DMA_CCR_IMMCHN 0x20000000 #define TXX9_DMA_CCR_USEXFSZ 0x10000000 #define TXX9_DMA_CCR_LE 0x08000000 #define TXX9_DMA_CCR_DBINH 0x04000000 #define TXX9_DMA_CCR_SBINH 0x02000000 #define TXX9_DMA_CCR_CHRST 0x01000000 #define TXX9_DMA_CCR_RVBYTE 0x00800000 #define TXX9_DMA_CCR_ACKPOL 0x00400000 #define TXX9_DMA_CCR_REQPL 0x00200000 #define TXX9_DMA_CCR_EGREQ 0x00100000 #define TXX9_DMA_CCR_CHDN 0x00080000 #define TXX9_DMA_CCR_DNCTL 0x00060000 #define TXX9_DMA_CCR_EXTRQ 0x00010000 #define TXX9_DMA_CCR_INTRQD 0x0000e000 #define TXX9_DMA_CCR_INTENE 0x00001000 #define TXX9_DMA_CCR_INTENC 0x00000800 #define TXX9_DMA_CCR_INTENT 0x00000400 #define TXX9_DMA_CCR_CHNEN 0x00000200 #define TXX9_DMA_CCR_XFACT 0x00000100 #define TXX9_DMA_CCR_SMPCHN 0x00000020 #define TXX9_DMA_CCR_XFSZ(order) (((order) << 2) & 0x0000001c) #define TXX9_DMA_CCR_XFSZ_1 TXX9_DMA_CCR_XFSZ(0) #define TXX9_DMA_CCR_XFSZ_2 TXX9_DMA_CCR_XFSZ(1) #define TXX9_DMA_CCR_XFSZ_4 TXX9_DMA_CCR_XFSZ(2) #define TXX9_DMA_CCR_XFSZ_8 TXX9_DMA_CCR_XFSZ(3) #define TXX9_DMA_CCR_XFSZ_X4 TXX9_DMA_CCR_XFSZ(4) #define TXX9_DMA_CCR_XFSZ_X8 TXX9_DMA_CCR_XFSZ(5) #define TXX9_DMA_CCR_XFSZ_X16 TXX9_DMA_CCR_XFSZ(6) #define TXX9_DMA_CCR_XFSZ_X32 TXX9_DMA_CCR_XFSZ(7) #define TXX9_DMA_CCR_MEMIO 0x00000002 #define TXX9_DMA_CCR_SNGAD 0x00000001 /* bits for CSRn */ #define TXX9_DMA_CSR_CHNEN 0x00000400 #define TXX9_DMA_CSR_STLXFER 0x00000200 #define TXX9_DMA_CSR_XFACT 0x00000100 #define TXX9_DMA_CSR_ABCHC 0x00000080 #define TXX9_DMA_CSR_NCHNC 0x00000040 #define TXX9_DMA_CSR_NTRNFC 0x00000020 #define TXX9_DMA_CSR_EXTDN 0x00000010 #define TXX9_DMA_CSR_CFERR 0x00000008 #define TXX9_DMA_CSR_CHERR 0x00000004 #define TXX9_DMA_CSR_DESERR 0x00000002 #define TXX9_DMA_CSR_SORERR 0x00000001 struct txx9dmac_chan { struct dma_chan chan; struct dma_device dma; struct txx9dmac_dev *ddev; void __iomem *ch_regs; struct tasklet_struct tasklet; int irq; u32 ccr; spinlock_t lock; /* these other elements are all protected by lock */ struct list_head active_list; struct list_head queue; struct list_head free_list; unsigned int descs_allocated; }; struct txx9dmac_dev { void __iomem *regs; struct tasklet_struct tasklet; int irq; struct txx9dmac_chan *chan[TXX9_DMA_MAX_NR_CHANNELS]; bool have_64bit_regs; unsigned int descsize; }; static inline bool __is_dmac64(const struct txx9dmac_dev *ddev) { return ddev->have_64bit_regs; } static inline bool is_dmac64(const struct txx9dmac_chan *dc) { return __is_dmac64(dc->ddev); } #ifdef TXX9_DMA_USE_SIMPLE_CHAIN /* Hardware descriptor definition. (for simple-chain) */ struct txx9dmac_hwdesc { #if defined(CONFIG_32BIT) && !defined(CONFIG_PHYS_ADDR_T_64BIT) TXX9_DMA_REG32(CHAR); #else u64 CHAR; #endif u64 SAR; u64 DAR; TXX9_DMA_REG32(CNTR); }; struct txx9dmac_hwdesc32 { u32 CHAR; u32 SAR; u32 DAR; u32 CNTR; }; #else #define txx9dmac_hwdesc txx9dmac_cregs #define txx9dmac_hwdesc32 txx9dmac_cregs32 #endif struct txx9dmac_desc { /* FIRST values the hardware uses */ union { struct txx9dmac_hwdesc hwdesc; struct txx9dmac_hwdesc32 hwdesc32; }; /* THEN values for driver housekeeping */ struct list_head desc_node ____cacheline_aligned; struct list_head tx_list; struct dma_async_tx_descriptor txd; size_t len; }; #ifdef TXX9_DMA_USE_SIMPLE_CHAIN static inline bool txx9dmac_chan_INTENT(struct txx9dmac_chan *dc) { return (dc->ccr & TXX9_DMA_CCR_INTENT) != 0; } static inline void txx9dmac_chan_set_INTENT(struct txx9dmac_chan *dc) { dc->ccr |= TXX9_DMA_CCR_INTENT; } static inline void txx9dmac_desc_set_INTENT(struct txx9dmac_dev *ddev, struct txx9dmac_desc *desc) { } static inline void txx9dmac_chan_set_SMPCHN(struct txx9dmac_chan *dc) { dc->ccr |= TXX9_DMA_CCR_SMPCHN; } static inline void txx9dmac_desc_set_nosimple(struct txx9dmac_dev *ddev, struct txx9dmac_desc *desc, u32 sair, u32 dair, u32 ccr) { } #else /* TXX9_DMA_USE_SIMPLE_CHAIN */ static inline bool txx9dmac_chan_INTENT(struct txx9dmac_chan *dc) { return true; } static void txx9dmac_chan_set_INTENT(struct txx9dmac_chan *dc) { } static inline void txx9dmac_desc_set_INTENT(struct txx9dmac_dev *ddev, struct txx9dmac_desc *desc) { if (__is_dmac64(ddev)) desc->hwdesc.CCR |= TXX9_DMA_CCR_INTENT; else desc->hwdesc32.CCR |= TXX9_DMA_CCR_INTENT; } static inline void txx9dmac_chan_set_SMPCHN(struct txx9dmac_chan *dc) { } static inline void txx9dmac_desc_set_nosimple(struct txx9dmac_dev *ddev, struct txx9dmac_desc *desc, u32 sai, u32 dai, u32 ccr) { if (__is_dmac64(ddev)) { desc->hwdesc.SAIR = sai; desc->hwdesc.DAIR = dai; desc->hwdesc.CCR = ccr; } else { desc->hwdesc32.SAIR = sai; desc->hwdesc32.DAIR = dai; desc->hwdesc32.CCR = ccr; } } #endif /* TXX9_DMA_USE_SIMPLE_CHAIN */ #endif /* TXX9DMAC_H */
Information contained on this website is for historical information purposes only and does not indicate or represent copyright ownership.
Created with Cregit http://github.com/cregit/cregit
Version 2.0-RC1