Tom Rini | 10e4779 | 2018-05-06 17:58:06 -0400 | [diff] [blame] | 1 | /* SPDX-License-Identifier: GPL-2.0+ */ |
Prabhakar Kushwaha | cfd9fbf | 2015-03-19 09:20:45 -0700 | [diff] [blame] | 2 | /* |
| 3 | * Copyright (C) 2014 Freescale Semiconductor |
Prabhakar Kushwaha | cfd9fbf | 2015-03-19 09:20:45 -0700 | [diff] [blame] | 4 | */ |
| 5 | |
| 6 | #ifndef _FSL_QBMAN_BASE_H |
| 7 | #define _FSL_QBMAN_BASE_H |
| 8 | |
| 9 | /* Descriptor for a QBMan instance on the SoC. On partitions/targets that do not |
| 10 | * control this QBMan instance, these values may simply be place-holders. The |
| 11 | * idea is simply that we be able to distinguish between them, eg. so that SWP |
| 12 | * descriptors can identify which QBMan instance they belong to. */ |
| 13 | struct qbman_block_desc { |
| 14 | void *ccsr_reg_bar; /* CCSR register map */ |
| 15 | int irq_rerr; /* Recoverable error interrupt line */ |
| 16 | int irq_nrerr; /* Non-recoverable error interrupt line */ |
| 17 | }; |
| 18 | |
| 19 | /* Descriptor for a QBMan software portal, expressed in terms that make sense to |
| 20 | * the user context. Ie. on MC, this information is likely to be true-physical, |
| 21 | * and instantiated statically at compile-time. On GPP, this information is |
| 22 | * likely to be obtained via "discovery" over a partition's "layerscape bus" |
| 23 | * (ie. in response to a MC portal command), and would take into account any |
| 24 | * virtualisation of the GPP user's address space and/or interrupt numbering. */ |
| 25 | struct qbman_swp_desc { |
| 26 | const struct qbman_block_desc *block; /* The QBMan instance */ |
| 27 | void *cena_bar; /* Cache-enabled portal register map */ |
| 28 | void *cinh_bar; /* Cache-inhibited portal register map */ |
| 29 | }; |
| 30 | |
| 31 | /* Driver object for managing a QBMan portal */ |
| 32 | struct qbman_swp; |
| 33 | |
| 34 | /* Place-holder for FDs, we represent it via the simplest form that we need for |
| 35 | * now. Different overlays may be needed to support different options, etc. (It |
| 36 | * is impractical to define One True Struct, because the resulting encoding |
| 37 | * routines (lots of read-modify-writes) would be worst-case performance whether |
| 38 | * or not circumstances required them.) |
| 39 | * |
| 40 | * Note, as with all data-structures exchanged between software and hardware (be |
| 41 | * they located in the portal register map or DMA'd to and from main-memory), |
| 42 | * the driver ensures that the caller of the driver API sees the data-structures |
| 43 | * in host-endianness. "struct qbman_fd" is no exception. The 32-bit words |
| 44 | * contained within this structure are represented in host-endianness, even if |
| 45 | * hardware always treats them as little-endian. As such, if any of these fields |
| 46 | * are interpreted in a binary (rather than numerical) fashion by hardware |
| 47 | * blocks (eg. accelerators), then the user should be careful. We illustrate |
| 48 | * with an example; |
| 49 | * |
| 50 | * Suppose the desired behaviour of an accelerator is controlled by the "frc" |
| 51 | * field of the FDs that are sent to it. Suppose also that the behaviour desired |
| 52 | * by the user corresponds to an "frc" value which is expressed as the literal |
| 53 | * sequence of bytes 0xfe, 0xed, 0xab, and 0xba. So "frc" should be the 32-bit |
| 54 | * value in which 0xfe is the first byte and 0xba is the last byte, and as |
| 55 | * hardware is little-endian, this amounts to a 32-bit "value" of 0xbaabedfe. If |
| 56 | * the software is little-endian also, this can simply be achieved by setting |
| 57 | * frc=0xbaabedfe. On the other hand, if software is big-endian, it should set |
| 58 | * frc=0xfeedabba! The best away of avoiding trouble with this sort of thing is |
| 59 | * to treat the 32-bit words as numerical values, in which the offset of a field |
| 60 | * from the beginning of the first byte (as required or generated by hardware) |
| 61 | * is numerically encoded by a left-shift (ie. by raising the field to a |
| 62 | * corresponding power of 2). Ie. in the current example, software could set |
| 63 | * "frc" in the following way, and it would work correctly on both little-endian |
| 64 | * and big-endian operation; |
| 65 | * fd.frc = (0xfe << 0) | (0xed << 8) | (0xab << 16) | (0xba << 24); |
| 66 | */ |
| 67 | struct qbman_fd { |
| 68 | union { |
| 69 | uint32_t words[8]; |
| 70 | struct qbman_fd_simple { |
| 71 | uint32_t addr_lo; |
| 72 | uint32_t addr_hi; |
| 73 | uint32_t len; |
| 74 | /* offset in the MS 16 bits, BPID in the LS 16 bits */ |
| 75 | uint32_t bpid_offset; |
| 76 | uint32_t frc; /* frame context */ |
| 77 | /* "err", "va", "cbmt", "asal", [...] */ |
| 78 | uint32_t ctrl; |
| 79 | /* flow context */ |
| 80 | uint32_t flc_lo; |
| 81 | uint32_t flc_hi; |
| 82 | } simple; |
| 83 | }; |
| 84 | }; |
| 85 | |
| 86 | #endif /* !_FSL_QBMAN_BASE_H */ |