drivers/net/ethernet/netronome/nfp/nfpcore/nfp_target.c - hafnium/third_party/linux - Git at Google

 // SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
 /* Copyright (C) 2015-2018 Netronome Systems, Inc. */

 /*
  * nfp_target.c
  * CPP Access Width Decoder
  * Authors: Jakub Kicinski <jakub.kicinski@netronome.com>
  *          Jason McMullan <jason.mcmullan@netronome.com>
  *          Francois H. Theron <francois.theron@netronome.com>
  */

 #define pr_fmt(fmt)       "NFP target: " fmt

 #include <linux/bitops.h>
 #include <linux/kernel.h>
 #include <linux/printk.h>

 #include "nfp_cpp.h"

 #include "nfp6000/nfp6000.h"

 #define P32 1
 #define P64 2

 /* This structure ONLY includes items that can be done with a read or write of
  * 32-bit or 64-bit words. All others are not listed.
  */

 #define AT(_action, _token, _pull, _push)				\
 	case NFP_CPP_ID(0, (_action), (_token)):			\
 		return PUSHPULL((_pull), (_push))

 static int target_rw(u32 cpp_id, int pp, int start, int len)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 0,  0, pp);
 	AT(1, 0, pp,  0);
 	AT(NFP_CPP_ACTION_RW, 0, pp, pp);
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp6000_nbi_dma(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 0,   0, P64);	/* ReadNbiDma */
 	AT(1, 0,   P64, 0);	/* WriteNbiDma */
 	AT(NFP_CPP_ACTION_RW, 0, P64, P64);
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp6000_nbi_stats(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 0,   0, P32);	/* ReadNbiStats */
 	AT(1, 0,   P32, 0);	/* WriteNbiStats */
 	AT(NFP_CPP_ACTION_RW, 0, P32, P32);
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp6000_nbi_tm(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 0,   0, P64);	/* ReadNbiTM */
 	AT(1, 0,   P64, 0);	/* WriteNbiTM */
 	AT(NFP_CPP_ACTION_RW, 0, P64, P64);
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp6000_nbi_ppc(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 0,   0, P64);	/* ReadNbiPreclassifier */
 	AT(1, 0,   P64, 0);	/* WriteNbiPreclassifier */
 	AT(NFP_CPP_ACTION_RW, 0, P64, P64);
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp6000_nbi(u32 cpp_id, u64 address)
 {
 	u64 rel_addr = address & 0x3fFFFF;

 	if (rel_addr < (1 << 20))
 		return nfp6000_nbi_dma(cpp_id);
 	if (rel_addr < (2 << 20))
 		return nfp6000_nbi_stats(cpp_id);
 	if (rel_addr < (3 << 20))
 		return nfp6000_nbi_tm(cpp_id);
 	return nfp6000_nbi_ppc(cpp_id);
 }

 /* This structure ONLY includes items that can be done with a read or write of
  * 32-bit or 64-bit words. All others are not listed.
  */
 static int nfp6000_mu_common(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(NFP_CPP_ACTION_RW, 0, P64, P64);	/* read_be/write_be */
 	AT(NFP_CPP_ACTION_RW, 1, P64, P64);	/* read_le/write_le */
 	AT(NFP_CPP_ACTION_RW, 2, P64, P64);	/* read_swap_be/write_swap_be */
 	AT(NFP_CPP_ACTION_RW, 3, P64, P64);	/* read_swap_le/write_swap_le */
 	AT(0, 0,   0, P64);	/* read_be */
 	AT(0, 1,   0, P64);	/* read_le */
 	AT(0, 2,   0, P64);	/* read_swap_be */
 	AT(0, 3,   0, P64);	/* read_swap_le */
 	AT(1, 0, P64,   0);	/* write_be */
 	AT(1, 1, P64,   0);	/* write_le */
 	AT(1, 2, P64,   0);	/* write_swap_be */
 	AT(1, 3, P64,   0);	/* write_swap_le */
 	AT(3, 0,   0, P32);	/* atomic_read */
 	AT(3, 2, P32,   0);	/* mask_compare_write */
 	AT(4, 0, P32,   0);	/* atomic_write */
 	AT(4, 2,   0,   0);	/* atomic_write_imm */
 	AT(4, 3,   0, P32);	/* swap_imm */
 	AT(5, 0, P32,   0);	/* set */
 	AT(5, 3,   0, P32);	/* test_set_imm */
 	AT(6, 0, P32,   0);	/* clr */
 	AT(6, 3,   0, P32);	/* test_clr_imm */
 	AT(7, 0, P32,   0);	/* add */
 	AT(7, 3,   0, P32);	/* test_add_imm */
 	AT(8, 0, P32,   0);	/* addsat */
 	AT(8, 3,   0, P32);	/* test_subsat_imm */
 	AT(9, 0, P32,   0);	/* sub */
 	AT(9, 3,   0, P32);	/* test_sub_imm */
 	AT(10, 0, P32,   0);	/* subsat */
 	AT(10, 3,   0, P32);	/* test_subsat_imm */
 	AT(13, 0,   0, P32);	/* microq128_get */
 	AT(13, 1,   0, P32);	/* microq128_pop */
 	AT(13, 2, P32,   0);	/* microq128_put */
 	AT(15, 0, P32,   0);	/* xor */
 	AT(15, 3,   0, P32);	/* test_xor_imm */
 	AT(28, 0,   0, P32);	/* read32_be */
 	AT(28, 1,   0, P32);	/* read32_le */
 	AT(28, 2,   0, P32);	/* read32_swap_be */
 	AT(28, 3,   0, P32);	/* read32_swap_le */
 	AT(31, 0, P32,   0);	/* write32_be */
 	AT(31, 1, P32,   0);	/* write32_le */
 	AT(31, 2, P32,   0);	/* write32_swap_be */
 	AT(31, 3, P32,   0);	/* write32_swap_le */
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp6000_mu_ctm(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(16, 1,   0, P32);	/* packet_read_packet_status */
 	AT(17, 1,   0, P32);	/* packet_credit_get */
 	AT(17, 3,   0, P64);	/* packet_add_thread */
 	AT(18, 2,   0, P64);	/* packet_free_and_return_pointer */
 	AT(18, 3,   0, P64);	/* packet_return_pointer */
 	AT(21, 0,   0, P64);	/* pe_dma_to_memory_indirect */
 	AT(21, 1,   0, P64);	/* pe_dma_to_memory_indirect_swap */
 	AT(21, 2,   0, P64);	/* pe_dma_to_memory_indirect_free */
 	AT(21, 3,   0, P64);	/* pe_dma_to_memory_indirect_free_swap */
 	default:
 		return nfp6000_mu_common(cpp_id);
 	}
 }

 static int nfp6000_mu_emu(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(18, 0,   0, P32);	/* read_queue */
 	AT(18, 1,   0, P32);	/* read_queue_ring */
 	AT(18, 2, P32,   0);	/* write_queue */
 	AT(18, 3, P32,   0);	/* write_queue_ring */
 	AT(20, 2, P32,   0);	/* journal */
 	AT(21, 0,   0, P32);	/* get */
 	AT(21, 1,   0, P32);	/* get_eop */
 	AT(21, 2,   0, P32);	/* get_freely */
 	AT(22, 0,   0, P32);	/* pop */
 	AT(22, 1,   0, P32);	/* pop_eop */
 	AT(22, 2,   0, P32);	/* pop_freely */
 	default:
 		return nfp6000_mu_common(cpp_id);
 	}
 }

 static int nfp6000_mu_imu(u32 cpp_id)
 {
 	return nfp6000_mu_common(cpp_id);
 }

 static int nfp6000_mu(u32 cpp_id, u64 address)
 {
 	int pp;

 	if (address < 0x2000000000ULL)
 		pp = nfp6000_mu_ctm(cpp_id);
 	else if (address < 0x8000000000ULL)
 		pp = nfp6000_mu_emu(cpp_id);
 	else if (address < 0x9800000000ULL)
 		pp = nfp6000_mu_ctm(cpp_id);
 	else if (address < 0x9C00000000ULL)
 		pp = nfp6000_mu_emu(cpp_id);
 	else if (address < 0xA000000000ULL)
 		pp = nfp6000_mu_imu(cpp_id);
 	else
 		pp = nfp6000_mu_ctm(cpp_id);

 	return pp;
 }

 static int nfp6000_ila(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 1,   0, P32);	/* read_check_error */
 	AT(2, 0,   0, P32);	/* read_int */
 	AT(3, 0, P32,   0);	/* write_int */
 	default:
 		return target_rw(cpp_id, P32, 48, 4);
 	}
 }

 static int nfp6000_pci(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(2, 0,   0, P32);
 	AT(3, 0, P32,   0);
 	default:
 		return target_rw(cpp_id, P32, 4, 4);
 	}
 }

 static int nfp6000_crypto(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(2, 0, P64,   0);
 	default:
 		return target_rw(cpp_id, P64, 12, 4);
 	}
 }

 static int nfp6000_cap_xpb(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 1,   0, P32); /* RingGet */
 	AT(0, 2, P32,   0); /* Interthread Signal */
 	AT(1, 1, P32,   0); /* RingPut */
 	AT(1, 2, P32,   0); /* CTNNWr */
 	AT(2, 0,   0, P32); /* ReflectRd, signal none */
 	AT(2, 1,   0, P32); /* ReflectRd, signal self */
 	AT(2, 2,   0, P32); /* ReflectRd, signal remote */
 	AT(2, 3,   0, P32); /* ReflectRd, signal both */
 	AT(3, 0, P32,   0); /* ReflectWr, signal none */
 	AT(3, 1, P32,   0); /* ReflectWr, signal self */
 	AT(3, 2, P32,   0); /* ReflectWr, signal remote */
 	AT(3, 3, P32,   0); /* ReflectWr, signal both */
 	AT(NFP_CPP_ACTION_RW, 1, P32, P32);
 	default:
 		return target_rw(cpp_id, P32, 1, 63);
 	}
 }

 static int nfp6000_cls(u32 cpp_id)
 {
 	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
 	AT(0, 3, P32,  0); /* xor */
 	AT(2, 0, P32,  0); /* set */
 	AT(2, 1, P32,  0); /* clr */
 	AT(4, 0, P32,  0); /* add */
 	AT(4, 1, P32,  0); /* add64 */
 	AT(6, 0, P32,  0); /* sub */
 	AT(6, 1, P32,  0); /* sub64 */
 	AT(6, 2, P32,  0); /* subsat */
 	AT(8, 2, P32,  0); /* hash_mask */
 	AT(8, 3, P32,  0); /* hash_clear */
 	AT(9, 0,  0, P32); /* ring_get */
 	AT(9, 1,  0, P32); /* ring_pop */
 	AT(9, 2,  0, P32); /* ring_get_freely */
 	AT(9, 3,  0, P32); /* ring_pop_freely */
 	AT(10, 0, P32,  0); /* ring_put */
 	AT(10, 2, P32,  0); /* ring_journal */
 	AT(14, 0,  P32, 0); /* reflect_write_sig_local */
 	AT(15, 1,  0, P32); /* reflect_read_sig_local */
 	AT(17, 2, P32,  0); /* statisic */
 	AT(24, 0,  0, P32); /* ring_read */
 	AT(24, 1, P32,  0); /* ring_write */
 	AT(25, 0,  0, P32); /* ring_workq_add_thread */
 	AT(25, 1, P32,  0); /* ring_workq_add_work */
 	default:
 		return target_rw(cpp_id, P32, 0, 64);
 	}
 }

 int nfp_target_pushpull(u32 cpp_id, u64 address)
 {
 	switch (NFP_CPP_ID_TARGET_of(cpp_id)) {
 	case NFP_CPP_TARGET_NBI:
 		return nfp6000_nbi(cpp_id, address);
 	case NFP_CPP_TARGET_QDR:
 		return target_rw(cpp_id, P32, 24, 4);
 	case NFP_CPP_TARGET_ILA:
 		return nfp6000_ila(cpp_id);
 	case NFP_CPP_TARGET_MU:
 		return nfp6000_mu(cpp_id, address);
 	case NFP_CPP_TARGET_PCIE:
 		return nfp6000_pci(cpp_id);
 	case NFP_CPP_TARGET_ARM:
 		if (address < 0x10000)
 			return target_rw(cpp_id, P64, 1, 1);
 		else
 			return target_rw(cpp_id, P32, 1, 1);
 	case NFP_CPP_TARGET_CRYPTO:
 		return nfp6000_crypto(cpp_id);
 	case NFP_CPP_TARGET_CT_XPB:
 		return nfp6000_cap_xpb(cpp_id);
 	case NFP_CPP_TARGET_CLS:
 		return nfp6000_cls(cpp_id);
 	case 0:
 		return target_rw(cpp_id, P32, 4, 4);
 	default:
 		return -EINVAL;
 	}
 }

 #undef AT
 #undef P32
 #undef P64

 /* All magic NFP-6xxx IMB 'mode' numbers here are from:
  * Databook (1 August 2013)
  * - System Overview and Connectivity
  * -- Internal Connectivity
  * --- Distributed Switch Fabric - Command Push/Pull (DSF-CPP) Bus
  * ---- CPP addressing
  * ----- Table 3.6. CPP Address Translation Mode Commands
  */

 #define _NIC_NFP6000_MU_LOCALITY_DIRECT     2

 static int nfp_decode_basic(u64 addr, int *dest_island, int cpp_tgt,
 			    int mode, bool addr40, int isld1, int isld0)
 {
 	int iid_lsb, idx_lsb;

 	/* This function doesn't handle MU or CTXBP */
 	if (cpp_tgt == NFP_CPP_TARGET_MU || cpp_tgt == NFP_CPP_TARGET_CT_XPB)
 		return -EINVAL;

 	switch (mode) {
 	case 0:
 		/* For VQDR, in this mode for 32-bit addressing
 		 * it would be islands 0, 16, 32 and 48 depending on channel
 		 * and upper address bits.
 		 * Since those are not all valid islands, most decode
 		 * cases would result in bad island IDs, but we do them
 		 * anyway since this is decoding an address that is already
 		 * assumed to be used as-is to get to sram.
 		 */
 		iid_lsb = addr40 ? 34 : 26;
 		*dest_island = (addr >> iid_lsb) & 0x3F;
 		return 0;
 	case 1:
 		/* For VQDR 32-bit, this would decode as:
 		 * Channel 0: island#0
 		 * Channel 1: island#0
 		 * Channel 2: island#1
 		 * Channel 3: island#1
 		 * That would be valid as long as both islands
 		 * have VQDR. Let's allow this.
 		 */
 		idx_lsb = addr40 ? 39 : 31;
 		if (addr & BIT_ULL(idx_lsb))
 			*dest_island = isld1;
 		else
 			*dest_island = isld0;

 		return 0;
 	case 2:
 		/* For VQDR 32-bit:
 		 * Channel 0: (island#0 | 0)
 		 * Channel 1: (island#0 | 1)
 		 * Channel 2: (island#1 | 0)
 		 * Channel 3: (island#1 | 1)
 		 *
 		 * Make sure we compare against isldN values
 		 * by clearing the LSB.
 		 * This is what the silicon does.
 		 */
 		isld0 &= ~1;
 		isld1 &= ~1;

 		idx_lsb = addr40 ? 39 : 31;
 		iid_lsb = idx_lsb - 1;

 		if (addr & BIT_ULL(idx_lsb))
 			*dest_island = isld1 | (int)((addr >> iid_lsb) & 1);
 		else
 			*dest_island = isld0 | (int)((addr >> iid_lsb) & 1);

 		return 0;
 	case 3:
 		/* In this mode the data address starts to affect the island ID
 		 * so rather not allow it. In some really specific case
 		 * one could use this to send the upper half of the
 		 * VQDR channel to another MU, but this is getting very
 		 * specific.
 		 * However, as above for mode 0, this is the decoder
 		 * and the caller should validate the resulting IID.
 		 * This blindly does what the silicon would do.
 		 */
 		isld0 &= ~3;
 		isld1 &= ~3;

 		idx_lsb = addr40 ? 39 : 31;
 		iid_lsb = idx_lsb - 2;

 		if (addr & BIT_ULL(idx_lsb))
 			*dest_island = isld1 | (int)((addr >> iid_lsb) & 3);
 		else
 			*dest_island = isld0 | (int)((addr >> iid_lsb) & 3);

 		return 0;
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp_encode_basic_qdr(u64 addr, int dest_island, int cpp_tgt,
 				int mode, bool addr40, int isld1, int isld0)
 {
 	int v, ret;

 	/* Full Island ID and channel bits overlap? */
 	ret = nfp_decode_basic(addr, &v, cpp_tgt, mode, addr40, isld1, isld0);
 	if (ret)
 		return ret;

 	/* The current address won't go where expected? */
 	if (dest_island != -1 && dest_island != v)
 		return -EINVAL;

 	/* If dest_island was -1, we don't care where it goes. */
 	return 0;
 }

 /* Try each option, take first one that fits.
  * Not sure if we would want to do some smarter
  * searching and prefer 0 or non-0 island IDs.
  */
 static int nfp_encode_basic_search(u64 *addr, int dest_island, int *isld,
 				   int iid_lsb, int idx_lsb, int v_max)
 {
 	int i, v;

 	for (i = 0; i < 2; i++)
 		for (v = 0; v < v_max; v++) {
 			if (dest_island != (isld[i] | v))
 				continue;

 			*addr &= ~GENMASK_ULL(idx_lsb, iid_lsb);
 			*addr |= ((u64)i << idx_lsb);
 			*addr |= ((u64)v << iid_lsb);
 			return 0;
 		}

 	return -ENODEV;
 }

 /* For VQDR, we may not modify the Channel bits, which might overlap
  *  with the Index bit. When it does, we need to ensure that isld0 == isld1.
  */
 static int nfp_encode_basic(u64 *addr, int dest_island, int cpp_tgt,
 			    int mode, bool addr40, int isld1, int isld0)
 {
 	int iid_lsb, idx_lsb;
 	int isld[2];
 	u64 v64;

 	isld[0] = isld0;
 	isld[1] = isld1;

 	/* This function doesn't handle MU or CTXBP */
 	if (cpp_tgt == NFP_CPP_TARGET_MU || cpp_tgt == NFP_CPP_TARGET_CT_XPB)
 		return -EINVAL;

 	switch (mode) {
 	case 0:
 		if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
 			/* In this specific mode we'd rather not modify
 			 * the address but we can verify if the existing
 			 * contents will point to a valid island.
 			 */
 			return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
 						    mode, addr40, isld1, isld0);

 		iid_lsb = addr40 ? 34 : 26;
 		/* <39:34> or <31:26> */
 		v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
 		*addr &= ~v64;
 		*addr |= ((u64)dest_island << iid_lsb) & v64;
 		return 0;
 	case 1:
 		if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
 			return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
 						    mode, addr40, isld1, isld0);

 		idx_lsb = addr40 ? 39 : 31;
 		if (dest_island == isld0) {
 			/* Only need to clear the Index bit */
 			*addr &= ~BIT_ULL(idx_lsb);
 			return 0;
 		}

 		if (dest_island == isld1) {
 			/* Only need to set the Index bit */
 			*addr |= BIT_ULL(idx_lsb);
 			return 0;
 		}

 		return -ENODEV;
 	case 2:
 		/* iid<0> = addr<30> = channel<0>
 		 * channel<1> = addr<31> = Index
 		 */
 		if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
 			/* Special case where we allow channel bits to
 			 * be set before hand and with them select an island.
 			 * So we need to confirm that it's at least plausible.
 			 */
 			return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
 						    mode, addr40, isld1, isld0);

 		/* Make sure we compare against isldN values
 		 * by clearing the LSB.
 		 * This is what the silicon does.
 		 */
 		isld[0] &= ~1;
 		isld[1] &= ~1;

 		idx_lsb = addr40 ? 39 : 31;
 		iid_lsb = idx_lsb - 1;

 		return nfp_encode_basic_search(addr, dest_island, isld,
 					       iid_lsb, idx_lsb, 2);
 	case 3:
 		if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
 			/* iid<0> = addr<29> = data
 			 * iid<1> = addr<30> = channel<0>
 			 * channel<1> = addr<31> = Index
 			 */
 			return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
 						    mode, addr40, isld1, isld0);

 		isld[0] &= ~3;
 		isld[1] &= ~3;

 		idx_lsb = addr40 ? 39 : 31;
 		iid_lsb = idx_lsb - 2;

 		return nfp_encode_basic_search(addr, dest_island, isld,
 					       iid_lsb, idx_lsb, 4);
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp_encode_mu(u64 *addr, int dest_island, int mode,
 			 bool addr40, int isld1, int isld0)
 {
 	int iid_lsb, idx_lsb, locality_lsb;
 	int isld[2];
 	u64 v64;
 	int da;

 	isld[0] = isld0;
 	isld[1] = isld1;
 	locality_lsb = nfp_cppat_mu_locality_lsb(mode, addr40);

 	if (((*addr >> locality_lsb) & 3) == _NIC_NFP6000_MU_LOCALITY_DIRECT)
 		da = 1;
 	else
 		da = 0;

 	switch (mode) {
 	case 0:
 		iid_lsb = addr40 ? 32 : 24;
 		v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
 		*addr &= ~v64;
 		*addr |= (((u64)dest_island) << iid_lsb) & v64;
 		return 0;
 	case 1:
 		if (da) {
 			iid_lsb = addr40 ? 32 : 24;
 			v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
 			*addr &= ~v64;
 			*addr |= (((u64)dest_island) << iid_lsb) & v64;
 			return 0;
 		}

 		idx_lsb = addr40 ? 37 : 29;
 		if (dest_island == isld0) {
 			*addr &= ~BIT_ULL(idx_lsb);
 			return 0;
 		}

 		if (dest_island == isld1) {
 			*addr |= BIT_ULL(idx_lsb);
 			return 0;
 		}

 		return -ENODEV;
 	case 2:
 		if (da) {
 			iid_lsb = addr40 ? 32 : 24;
 			v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
 			*addr &= ~v64;
 			*addr |= (((u64)dest_island) << iid_lsb) & v64;
 			return 0;
 		}

 		/* Make sure we compare against isldN values
 		 * by clearing the LSB.
 		 * This is what the silicon does.
 		 */
 		isld[0] &= ~1;
 		isld[1] &= ~1;

 		idx_lsb = addr40 ? 37 : 29;
 		iid_lsb = idx_lsb - 1;

 		return nfp_encode_basic_search(addr, dest_island, isld,
 					       iid_lsb, idx_lsb, 2);
 	case 3:
 		/* Only the EMU will use 40 bit addressing. Silently
 		 * set the direct locality bit for everyone else.
 		 * The SDK toolchain uses dest_island <= 0 to test
 		 * for atypical address encodings to support access
 		 * to local-island CTM with a 32-but address (high-locality
 		 * is effewctively ignored and just used for
 		 * routing to island #0).
 		 */
 		if (dest_island > 0 && (dest_island < 24 || dest_island > 26)) {
 			*addr |= ((u64)_NIC_NFP6000_MU_LOCALITY_DIRECT)
 							<< locality_lsb;
 			da = 1;
 		}

 		if (da) {
 			iid_lsb = addr40 ? 32 : 24;
 			v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
 			*addr &= ~v64;
 			*addr |= (((u64)dest_island) << iid_lsb) & v64;
 			return 0;
 		}

 		isld[0] &= ~3;
 		isld[1] &= ~3;

 		idx_lsb = addr40 ? 37 : 29;
 		iid_lsb = idx_lsb - 2;

 		return nfp_encode_basic_search(addr, dest_island, isld,
 					       iid_lsb, idx_lsb, 4);
 	default:
 		return -EINVAL;
 	}
 }

 static int nfp_cppat_addr_encode(u64 *addr, int dest_island, int cpp_tgt,
 				 int mode, bool addr40, int isld1, int isld0)
 {
 	switch (cpp_tgt) {
 	case NFP_CPP_TARGET_NBI:
 	case NFP_CPP_TARGET_QDR:
 	case NFP_CPP_TARGET_ILA:
 	case NFP_CPP_TARGET_PCIE:
 	case NFP_CPP_TARGET_ARM:
 	case NFP_CPP_TARGET_CRYPTO:
 	case NFP_CPP_TARGET_CLS:
 		return nfp_encode_basic(addr, dest_island, cpp_tgt, mode,
 					addr40, isld1, isld0);

 	case NFP_CPP_TARGET_MU:
 		return nfp_encode_mu(addr, dest_island, mode,
 				     addr40, isld1, isld0);

 	case NFP_CPP_TARGET_CT_XPB:
 		if (mode != 1 || addr40)
 			return -EINVAL;
 		*addr &= ~GENMASK_ULL(29, 24);
 		*addr |= ((u64)dest_island << 24) & GENMASK_ULL(29, 24);
 		return 0;
 	default:
 		return -EINVAL;
 	}
 }

 int nfp_target_cpp(u32 cpp_island_id, u64 cpp_island_address,
 		   u32 *cpp_target_id, u64 *cpp_target_address,
 		   const u32 *imb_table)
 {
 	const int island = NFP_CPP_ID_ISLAND_of(cpp_island_id);
 	const int target = NFP_CPP_ID_TARGET_of(cpp_island_id);
 	u32 imb;
 	int err;

 	if (target < 0 || target >= 16) {
 		pr_err("Invalid CPP target: %d\n", target);
 		return -EINVAL;
 	}

 	if (island == 0) {
 		/* Already translated */
 		*cpp_target_id = cpp_island_id;
 		*cpp_target_address = cpp_island_address;
 		return 0;
 	}

 	/* CPP + Island only allowed on systems with IMB tables */
 	if (!imb_table)
 		return -EINVAL;

 	imb = imb_table[target];

 	*cpp_target_address = cpp_island_address;
 	err = nfp_cppat_addr_encode(cpp_target_address, island, target,
 				    ((imb >> 13) & 7), ((imb >> 12) & 1),
 				    ((imb >> 6)  & 0x3f), ((imb >> 0)  & 0x3f));
 	if (err) {
 		pr_err("Can't encode CPP address: %d\n", err);
 		return err;
 	}

 	*cpp_target_id = NFP_CPP_ID(target,
 				    NFP_CPP_ID_ACTION_of(cpp_island_id),
 				    NFP_CPP_ID_TOKEN_of(cpp_island_id));

 	return 0;
 }
	// SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
	/* Copyright (C) 2015-2018 Netronome Systems, Inc. */

	/*
	* nfp_target.c
	* CPP Access Width Decoder
	* Authors: Jakub Kicinski <jakub.kicinski@netronome.com>
	* Jason McMullan <jason.mcmullan@netronome.com>
	* Francois H. Theron <francois.theron@netronome.com>
	*/

	#define pr_fmt(fmt) "NFP target: " fmt

	#include <linux/bitops.h>
	#include <linux/kernel.h>
	#include <linux/printk.h>

	#include "nfp_cpp.h"

	#include "nfp6000/nfp6000.h"

	#define P32 1
	#define P64 2

	/* This structure ONLY includes items that can be done with a read or write of
	* 32-bit or 64-bit words. All others are not listed.
	*/

	#define AT(_action, _token, _pull, _push) \
	case NFP_CPP_ID(0, (_action), (_token)): \
	return PUSHPULL((_pull), (_push))

	static int target_rw(u32 cpp_id, int pp, int start, int len)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 0, 0, pp);
	AT(1, 0, pp, 0);
	AT(NFP_CPP_ACTION_RW, 0, pp, pp);
	default:
	return -EINVAL;
	}
	}

	static int nfp6000_nbi_dma(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 0, 0, P64); /* ReadNbiDma */
	AT(1, 0, P64, 0); /* WriteNbiDma */
	AT(NFP_CPP_ACTION_RW, 0, P64, P64);
	default:
	return -EINVAL;
	}
	}

	static int nfp6000_nbi_stats(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 0, 0, P32); /* ReadNbiStats */
	AT(1, 0, P32, 0); /* WriteNbiStats */
	AT(NFP_CPP_ACTION_RW, 0, P32, P32);
	default:
	return -EINVAL;
	}
	}

	static int nfp6000_nbi_tm(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 0, 0, P64); /* ReadNbiTM */
	AT(1, 0, P64, 0); /* WriteNbiTM */
	AT(NFP_CPP_ACTION_RW, 0, P64, P64);
	default:
	return -EINVAL;
	}
	}

	static int nfp6000_nbi_ppc(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 0, 0, P64); /* ReadNbiPreclassifier */
	AT(1, 0, P64, 0); /* WriteNbiPreclassifier */
	AT(NFP_CPP_ACTION_RW, 0, P64, P64);
	default:
	return -EINVAL;
	}
	}

	static int nfp6000_nbi(u32 cpp_id, u64 address)
	{
	u64 rel_addr = address & 0x3fFFFF;

	if (rel_addr < (1 << 20))
	return nfp6000_nbi_dma(cpp_id);
	if (rel_addr < (2 << 20))
	return nfp6000_nbi_stats(cpp_id);
	if (rel_addr < (3 << 20))
	return nfp6000_nbi_tm(cpp_id);
	return nfp6000_nbi_ppc(cpp_id);
	}

	/* This structure ONLY includes items that can be done with a read or write of
	* 32-bit or 64-bit words. All others are not listed.
	*/
	static int nfp6000_mu_common(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(NFP_CPP_ACTION_RW, 0, P64, P64); /* read_be/write_be */
	AT(NFP_CPP_ACTION_RW, 1, P64, P64); /* read_le/write_le */
	AT(NFP_CPP_ACTION_RW, 2, P64, P64); /* read_swap_be/write_swap_be */
	AT(NFP_CPP_ACTION_RW, 3, P64, P64); /* read_swap_le/write_swap_le */
	AT(0, 0, 0, P64); /* read_be */
	AT(0, 1, 0, P64); /* read_le */
	AT(0, 2, 0, P64); /* read_swap_be */
	AT(0, 3, 0, P64); /* read_swap_le */
	AT(1, 0, P64, 0); /* write_be */
	AT(1, 1, P64, 0); /* write_le */
	AT(1, 2, P64, 0); /* write_swap_be */
	AT(1, 3, P64, 0); /* write_swap_le */
	AT(3, 0, 0, P32); /* atomic_read */
	AT(3, 2, P32, 0); /* mask_compare_write */
	AT(4, 0, P32, 0); /* atomic_write */
	AT(4, 2, 0, 0); /* atomic_write_imm */
	AT(4, 3, 0, P32); /* swap_imm */
	AT(5, 0, P32, 0); /* set */
	AT(5, 3, 0, P32); /* test_set_imm */
	AT(6, 0, P32, 0); /* clr */
	AT(6, 3, 0, P32); /* test_clr_imm */
	AT(7, 0, P32, 0); /* add */
	AT(7, 3, 0, P32); /* test_add_imm */
	AT(8, 0, P32, 0); /* addsat */
	AT(8, 3, 0, P32); /* test_subsat_imm */
	AT(9, 0, P32, 0); /* sub */
	AT(9, 3, 0, P32); /* test_sub_imm */
	AT(10, 0, P32, 0); /* subsat */
	AT(10, 3, 0, P32); /* test_subsat_imm */
	AT(13, 0, 0, P32); /* microq128_get */
	AT(13, 1, 0, P32); /* microq128_pop */
	AT(13, 2, P32, 0); /* microq128_put */
	AT(15, 0, P32, 0); /* xor */
	AT(15, 3, 0, P32); /* test_xor_imm */
	AT(28, 0, 0, P32); /* read32_be */
	AT(28, 1, 0, P32); /* read32_le */
	AT(28, 2, 0, P32); /* read32_swap_be */
	AT(28, 3, 0, P32); /* read32_swap_le */
	AT(31, 0, P32, 0); /* write32_be */
	AT(31, 1, P32, 0); /* write32_le */
	AT(31, 2, P32, 0); /* write32_swap_be */
	AT(31, 3, P32, 0); /* write32_swap_le */
	default:
	return -EINVAL;
	}
	}

	static int nfp6000_mu_ctm(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(16, 1, 0, P32); /* packet_read_packet_status */
	AT(17, 1, 0, P32); /* packet_credit_get */
	AT(17, 3, 0, P64); /* packet_add_thread */
	AT(18, 2, 0, P64); /* packet_free_and_return_pointer */
	AT(18, 3, 0, P64); /* packet_return_pointer */
	AT(21, 0, 0, P64); /* pe_dma_to_memory_indirect */
	AT(21, 1, 0, P64); /* pe_dma_to_memory_indirect_swap */
	AT(21, 2, 0, P64); /* pe_dma_to_memory_indirect_free */
	AT(21, 3, 0, P64); /* pe_dma_to_memory_indirect_free_swap */
	default:
	return nfp6000_mu_common(cpp_id);
	}
	}

	static int nfp6000_mu_emu(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(18, 0, 0, P32); /* read_queue */
	AT(18, 1, 0, P32); /* read_queue_ring */
	AT(18, 2, P32, 0); /* write_queue */
	AT(18, 3, P32, 0); /* write_queue_ring */
	AT(20, 2, P32, 0); /* journal */
	AT(21, 0, 0, P32); /* get */
	AT(21, 1, 0, P32); /* get_eop */
	AT(21, 2, 0, P32); /* get_freely */
	AT(22, 0, 0, P32); /* pop */
	AT(22, 1, 0, P32); /* pop_eop */
	AT(22, 2, 0, P32); /* pop_freely */
	default:
	return nfp6000_mu_common(cpp_id);
	}
	}

	static int nfp6000_mu_imu(u32 cpp_id)
	{
	return nfp6000_mu_common(cpp_id);
	}

	static int nfp6000_mu(u32 cpp_id, u64 address)
	{
	int pp;

	if (address < 0x2000000000ULL)
	pp = nfp6000_mu_ctm(cpp_id);
	else if (address < 0x8000000000ULL)
	pp = nfp6000_mu_emu(cpp_id);
	else if (address < 0x9800000000ULL)
	pp = nfp6000_mu_ctm(cpp_id);
	else if (address < 0x9C00000000ULL)
	pp = nfp6000_mu_emu(cpp_id);
	else if (address < 0xA000000000ULL)
	pp = nfp6000_mu_imu(cpp_id);
	else
	pp = nfp6000_mu_ctm(cpp_id);

	return pp;
	}

	static int nfp6000_ila(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 1, 0, P32); /* read_check_error */
	AT(2, 0, 0, P32); /* read_int */
	AT(3, 0, P32, 0); /* write_int */
	default:
	return target_rw(cpp_id, P32, 48, 4);
	}
	}

	static int nfp6000_pci(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(2, 0, 0, P32);
	AT(3, 0, P32, 0);
	default:
	return target_rw(cpp_id, P32, 4, 4);
	}
	}

	static int nfp6000_crypto(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(2, 0, P64, 0);
	default:
	return target_rw(cpp_id, P64, 12, 4);
	}
	}

	static int nfp6000_cap_xpb(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 1, 0, P32); /* RingGet */
	AT(0, 2, P32, 0); /* Interthread Signal */
	AT(1, 1, P32, 0); /* RingPut */
	AT(1, 2, P32, 0); /* CTNNWr */
	AT(2, 0, 0, P32); /* ReflectRd, signal none */
	AT(2, 1, 0, P32); /* ReflectRd, signal self */
	AT(2, 2, 0, P32); /* ReflectRd, signal remote */
	AT(2, 3, 0, P32); /* ReflectRd, signal both */
	AT(3, 0, P32, 0); /* ReflectWr, signal none */
	AT(3, 1, P32, 0); /* ReflectWr, signal self */
	AT(3, 2, P32, 0); /* ReflectWr, signal remote */
	AT(3, 3, P32, 0); /* ReflectWr, signal both */
	AT(NFP_CPP_ACTION_RW, 1, P32, P32);
	default:
	return target_rw(cpp_id, P32, 1, 63);
	}
	}

	static int nfp6000_cls(u32 cpp_id)
	{
	switch (cpp_id & NFP_CPP_ID(0, ~0, ~0)) {
	AT(0, 3, P32, 0); /* xor */
	AT(2, 0, P32, 0); /* set */
	AT(2, 1, P32, 0); /* clr */
	AT(4, 0, P32, 0); /* add */
	AT(4, 1, P32, 0); /* add64 */
	AT(6, 0, P32, 0); /* sub */
	AT(6, 1, P32, 0); /* sub64 */
	AT(6, 2, P32, 0); /* subsat */
	AT(8, 2, P32, 0); /* hash_mask */
	AT(8, 3, P32, 0); /* hash_clear */
	AT(9, 0, 0, P32); /* ring_get */
	AT(9, 1, 0, P32); /* ring_pop */
	AT(9, 2, 0, P32); /* ring_get_freely */
	AT(9, 3, 0, P32); /* ring_pop_freely */
	AT(10, 0, P32, 0); /* ring_put */
	AT(10, 2, P32, 0); /* ring_journal */
	AT(14, 0, P32, 0); /* reflect_write_sig_local */
	AT(15, 1, 0, P32); /* reflect_read_sig_local */
	AT(17, 2, P32, 0); /* statisic */
	AT(24, 0, 0, P32); /* ring_read */
	AT(24, 1, P32, 0); /* ring_write */
	AT(25, 0, 0, P32); /* ring_workq_add_thread */
	AT(25, 1, P32, 0); /* ring_workq_add_work */
	default:
	return target_rw(cpp_id, P32, 0, 64);
	}
	}

	int nfp_target_pushpull(u32 cpp_id, u64 address)
	{
	switch (NFP_CPP_ID_TARGET_of(cpp_id)) {
	case NFP_CPP_TARGET_NBI:
	return nfp6000_nbi(cpp_id, address);
	case NFP_CPP_TARGET_QDR:
	return target_rw(cpp_id, P32, 24, 4);
	case NFP_CPP_TARGET_ILA:
	return nfp6000_ila(cpp_id);
	case NFP_CPP_TARGET_MU:
	return nfp6000_mu(cpp_id, address);
	case NFP_CPP_TARGET_PCIE:
	return nfp6000_pci(cpp_id);
	case NFP_CPP_TARGET_ARM:
	if (address < 0x10000)
	return target_rw(cpp_id, P64, 1, 1);
	else
	return target_rw(cpp_id, P32, 1, 1);
	case NFP_CPP_TARGET_CRYPTO:
	return nfp6000_crypto(cpp_id);
	case NFP_CPP_TARGET_CT_XPB:
	return nfp6000_cap_xpb(cpp_id);
	case NFP_CPP_TARGET_CLS:
	return nfp6000_cls(cpp_id);
	case 0:
	return target_rw(cpp_id, P32, 4, 4);
	default:
	return -EINVAL;
	}
	}

	#undef AT
	#undef P32
	#undef P64

	/* All magic NFP-6xxx IMB 'mode' numbers here are from:
	* Databook (1 August 2013)
	* - System Overview and Connectivity
	* -- Internal Connectivity
	* --- Distributed Switch Fabric - Command Push/Pull (DSF-CPP) Bus
	* ---- CPP addressing
	* ----- Table 3.6. CPP Address Translation Mode Commands
	*/

	#define _NIC_NFP6000_MU_LOCALITY_DIRECT 2

	static int nfp_decode_basic(u64 addr, int *dest_island, int cpp_tgt,
	int mode, bool addr40, int isld1, int isld0)
	{
	int iid_lsb, idx_lsb;

	/* This function doesn't handle MU or CTXBP */
	if (cpp_tgt == NFP_CPP_TARGET_MU \|\| cpp_tgt == NFP_CPP_TARGET_CT_XPB)
	return -EINVAL;

	switch (mode) {
	case 0:
	/* For VQDR, in this mode for 32-bit addressing
	* it would be islands 0, 16, 32 and 48 depending on channel
	* and upper address bits.
	* Since those are not all valid islands, most decode
	* cases would result in bad island IDs, but we do them
	* anyway since this is decoding an address that is already
	* assumed to be used as-is to get to sram.
	*/
	iid_lsb = addr40 ? 34 : 26;
	*dest_island = (addr >> iid_lsb) & 0x3F;
	return 0;
	case 1:
	/* For VQDR 32-bit, this would decode as:
	* Channel 0: island#0
	* Channel 1: island#0
	* Channel 2: island#1
	* Channel 3: island#1
	* That would be valid as long as both islands
	* have VQDR. Let's allow this.
	*/
	idx_lsb = addr40 ? 39 : 31;
	if (addr & BIT_ULL(idx_lsb))
	*dest_island = isld1;
	else
	*dest_island = isld0;

	return 0;
	case 2:
	/* For VQDR 32-bit:
	* Channel 0: (island#0 \| 0)
	* Channel 1: (island#0 \| 1)
	* Channel 2: (island#1 \| 0)
	* Channel 3: (island#1 \| 1)
	*
	* Make sure we compare against isldN values
	* by clearing the LSB.
	* This is what the silicon does.
	*/
	isld0 &= ~1;
	isld1 &= ~1;

	idx_lsb = addr40 ? 39 : 31;
	iid_lsb = idx_lsb - 1;

	if (addr & BIT_ULL(idx_lsb))
	*dest_island = isld1 \| (int)((addr >> iid_lsb) & 1);
	else
	*dest_island = isld0 \| (int)((addr >> iid_lsb) & 1);

	return 0;
	case 3:
	/* In this mode the data address starts to affect the island ID
	* so rather not allow it. In some really specific case
	* one could use this to send the upper half of the
	* VQDR channel to another MU, but this is getting very
	* specific.
	* However, as above for mode 0, this is the decoder
	* and the caller should validate the resulting IID.
	* This blindly does what the silicon would do.
	*/
	isld0 &= ~3;
	isld1 &= ~3;

	idx_lsb = addr40 ? 39 : 31;
	iid_lsb = idx_lsb - 2;

	if (addr & BIT_ULL(idx_lsb))
	*dest_island = isld1 \| (int)((addr >> iid_lsb) & 3);
	else
	*dest_island = isld0 \| (int)((addr >> iid_lsb) & 3);

	return 0;
	default:
	return -EINVAL;
	}
	}

	static int nfp_encode_basic_qdr(u64 addr, int dest_island, int cpp_tgt,
	int mode, bool addr40, int isld1, int isld0)
	{
	int v, ret;

	/* Full Island ID and channel bits overlap? */
	ret = nfp_decode_basic(addr, &v, cpp_tgt, mode, addr40, isld1, isld0);
	if (ret)
	return ret;

	/* The current address won't go where expected? */
	if (dest_island != -1 && dest_island != v)
	return -EINVAL;

	/* If dest_island was -1, we don't care where it goes. */
	return 0;
	}

	/* Try each option, take first one that fits.
	* Not sure if we would want to do some smarter
	* searching and prefer 0 or non-0 island IDs.
	*/
	static int nfp_encode_basic_search(u64 addr, int dest_island, int isld,
	int iid_lsb, int idx_lsb, int v_max)
	{
	int i, v;

	for (i = 0; i < 2; i++)
	for (v = 0; v < v_max; v++) {
	if (dest_island != (isld[i] \| v))
	continue;

	*addr &= ~GENMASK_ULL(idx_lsb, iid_lsb);
	*addr \|= ((u64)i << idx_lsb);
	*addr \|= ((u64)v << iid_lsb);
	return 0;
	}

	return -ENODEV;
	}

	/* For VQDR, we may not modify the Channel bits, which might overlap
	* with the Index bit. When it does, we need to ensure that isld0 == isld1.
	*/
	static int nfp_encode_basic(u64 *addr, int dest_island, int cpp_tgt,
	int mode, bool addr40, int isld1, int isld0)
	{
	int iid_lsb, idx_lsb;
	int isld[2];
	u64 v64;

	isld[0] = isld0;
	isld[1] = isld1;

	/* This function doesn't handle MU or CTXBP */
	if (cpp_tgt == NFP_CPP_TARGET_MU \|\| cpp_tgt == NFP_CPP_TARGET_CT_XPB)
	return -EINVAL;

	switch (mode) {
	case 0:
	if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
	/* In this specific mode we'd rather not modify
	* the address but we can verify if the existing
	* contents will point to a valid island.
	*/
	return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
	mode, addr40, isld1, isld0);

	iid_lsb = addr40 ? 34 : 26;
	/* <39:34> or <31:26> */
	v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
	*addr &= ~v64;
	*addr \|= ((u64)dest_island << iid_lsb) & v64;
	return 0;
	case 1:
	if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
	return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
	mode, addr40, isld1, isld0);

	idx_lsb = addr40 ? 39 : 31;
	if (dest_island == isld0) {
	/* Only need to clear the Index bit */
	*addr &= ~BIT_ULL(idx_lsb);
	return 0;
	}

	if (dest_island == isld1) {
	/* Only need to set the Index bit */
	*addr \|= BIT_ULL(idx_lsb);
	return 0;
	}

	return -ENODEV;
	case 2:
	/* iid<0> = addr<30> = channel<0>
	* channel<1> = addr<31> = Index
	*/
	if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
	/* Special case where we allow channel bits to
	* be set before hand and with them select an island.
	* So we need to confirm that it's at least plausible.
	*/
	return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
	mode, addr40, isld1, isld0);

	/* Make sure we compare against isldN values
	* by clearing the LSB.
	* This is what the silicon does.
	*/
	isld[0] &= ~1;
	isld[1] &= ~1;

	idx_lsb = addr40 ? 39 : 31;
	iid_lsb = idx_lsb - 1;

	return nfp_encode_basic_search(addr, dest_island, isld,
	iid_lsb, idx_lsb, 2);
	case 3:
	if (cpp_tgt == NFP_CPP_TARGET_QDR && !addr40)
	/* iid<0> = addr<29> = data
	* iid<1> = addr<30> = channel<0>
	* channel<1> = addr<31> = Index
	*/
	return nfp_encode_basic_qdr(*addr, cpp_tgt, dest_island,
	mode, addr40, isld1, isld0);

	isld[0] &= ~3;
	isld[1] &= ~3;

	idx_lsb = addr40 ? 39 : 31;
	iid_lsb = idx_lsb - 2;

	return nfp_encode_basic_search(addr, dest_island, isld,
	iid_lsb, idx_lsb, 4);
	default:
	return -EINVAL;
	}
	}

	static int nfp_encode_mu(u64 *addr, int dest_island, int mode,
	bool addr40, int isld1, int isld0)
	{
	int iid_lsb, idx_lsb, locality_lsb;
	int isld[2];
	u64 v64;
	int da;

	isld[0] = isld0;
	isld[1] = isld1;
	locality_lsb = nfp_cppat_mu_locality_lsb(mode, addr40);

	if (((*addr >> locality_lsb) & 3) == _NIC_NFP6000_MU_LOCALITY_DIRECT)
	da = 1;
	else
	da = 0;

	switch (mode) {
	case 0:
	iid_lsb = addr40 ? 32 : 24;
	v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
	*addr &= ~v64;
	*addr \|= (((u64)dest_island) << iid_lsb) & v64;
	return 0;
	case 1:
	if (da) {
	iid_lsb = addr40 ? 32 : 24;
	v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
	*addr &= ~v64;
	*addr \|= (((u64)dest_island) << iid_lsb) & v64;
	return 0;
	}

	idx_lsb = addr40 ? 37 : 29;
	if (dest_island == isld0) {
	*addr &= ~BIT_ULL(idx_lsb);
	return 0;
	}

	if (dest_island == isld1) {
	*addr \|= BIT_ULL(idx_lsb);
	return 0;
	}

	return -ENODEV;
	case 2:
	if (da) {
	iid_lsb = addr40 ? 32 : 24;
	v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
	*addr &= ~v64;
	*addr \|= (((u64)dest_island) << iid_lsb) & v64;
	return 0;
	}

	/* Make sure we compare against isldN values
	* by clearing the LSB.
	* This is what the silicon does.
	*/
	isld[0] &= ~1;
	isld[1] &= ~1;

	idx_lsb = addr40 ? 37 : 29;
	iid_lsb = idx_lsb - 1;

	return nfp_encode_basic_search(addr, dest_island, isld,
	iid_lsb, idx_lsb, 2);
	case 3:
	/* Only the EMU will use 40 bit addressing. Silently
	* set the direct locality bit for everyone else.
	* The SDK toolchain uses dest_island <= 0 to test
	* for atypical address encodings to support access
	* to local-island CTM with a 32-but address (high-locality
	* is effewctively ignored and just used for
	* routing to island #0).
	*/
	if (dest_island > 0 && (dest_island < 24 \|\| dest_island > 26)) {
	*addr \|= ((u64)_NIC_NFP6000_MU_LOCALITY_DIRECT)
	<< locality_lsb;
	da = 1;
	}

	if (da) {
	iid_lsb = addr40 ? 32 : 24;
	v64 = GENMASK_ULL(iid_lsb + 5, iid_lsb);
	*addr &= ~v64;
	*addr \|= (((u64)dest_island) << iid_lsb) & v64;
	return 0;
	}

	isld[0] &= ~3;
	isld[1] &= ~3;

	idx_lsb = addr40 ? 37 : 29;
	iid_lsb = idx_lsb - 2;

	return nfp_encode_basic_search(addr, dest_island, isld,
	iid_lsb, idx_lsb, 4);
	default:
	return -EINVAL;
	}
	}

	static int nfp_cppat_addr_encode(u64 *addr, int dest_island, int cpp_tgt,
	int mode, bool addr40, int isld1, int isld0)
	{
	switch (cpp_tgt) {
	case NFP_CPP_TARGET_NBI:
	case NFP_CPP_TARGET_QDR:
	case NFP_CPP_TARGET_ILA:
	case NFP_CPP_TARGET_PCIE:
	case NFP_CPP_TARGET_ARM:
	case NFP_CPP_TARGET_CRYPTO:
	case NFP_CPP_TARGET_CLS:
	return nfp_encode_basic(addr, dest_island, cpp_tgt, mode,
	addr40, isld1, isld0);

	case NFP_CPP_TARGET_MU:
	return nfp_encode_mu(addr, dest_island, mode,
	addr40, isld1, isld0);

	case NFP_CPP_TARGET_CT_XPB:
	if (mode != 1 \|\| addr40)
	return -EINVAL;
	*addr &= ~GENMASK_ULL(29, 24);
	*addr \|= ((u64)dest_island << 24) & GENMASK_ULL(29, 24);
	return 0;
	default:
	return -EINVAL;
	}
	}

	int nfp_target_cpp(u32 cpp_island_id, u64 cpp_island_address,
	u32 cpp_target_id, u64 cpp_target_address,
	const u32 *imb_table)
	{
	const int island = NFP_CPP_ID_ISLAND_of(cpp_island_id);
	const int target = NFP_CPP_ID_TARGET_of(cpp_island_id);
	u32 imb;
	int err;

	if (target < 0 \|\| target >= 16) {
	pr_err("Invalid CPP target: %d\n", target);
	return -EINVAL;
	}

	if (island == 0) {
	/* Already translated */
	*cpp_target_id = cpp_island_id;
	*cpp_target_address = cpp_island_address;
	return 0;
	}

	/* CPP + Island only allowed on systems with IMB tables */
	if (!imb_table)
	return -EINVAL;

	imb = imb_table[target];

	*cpp_target_address = cpp_island_address;
	err = nfp_cppat_addr_encode(cpp_target_address, island, target,
	((imb >> 13) & 7), ((imb >> 12) & 1),
	((imb >> 6) & 0x3f), ((imb >> 0) & 0x3f));
	if (err) {
	pr_err("Can't encode CPP address: %d\n", err);
	return err;
	}

	*cpp_target_id = NFP_CPP_ID(target,
	NFP_CPP_ID_ACTION_of(cpp_island_id),
	NFP_CPP_ID_TOKEN_of(cpp_island_id));

	return 0;
	}