1 files changed, 473 insertions, 0 deletions
diff --git a/arch/arm/common/uengine.c b/arch/arm/common/uengine.c
new file mode 100644
index 000000000000..a1310b71004e
--- /dev/null
+++ b/arch/arm/common/uengine.c
@@ -0,0 +1,473 @@
+/*
+ * Generic library functions for the microengines found on the Intel
+ * IXP2000 series of network processors.
+ *
+ * Copyright (C) 2004, 2005 Lennert Buytenhek <buytenh@wantstofly.org>
+ * Dedicated to Marija Kulikova.
+ *
+ * This program is free software; you can redistribute it and/or modify
+ * it under the terms of the GNU Lesser General Public License as
+ * published by the Free Software Foundation; either version 2.1 of the
+ * License, or (at your option) any later version.
+ */
+#include <linux/config.h>
+#include <linux/kernel.h>
+#include <linux/init.h>
+#include <linux/slab.h>
+#include <linux/module.h>
+#include <linux/string.h>
+#include <asm/hardware.h>
+#include <asm/arch/ixp2000-regs.h>
+#include <asm/hardware/uengine.h>
+#include <asm/io.h>
+#define USTORE_ADDRESS                  0x000
+#define USTORE_DATA_LOWER               0x004
+#define USTORE_DATA_UPPER               0x008
+#define CTX_ENABLES                     0x018
+#define CC_ENABLE                       0x01c
+#define CSR_CTX_POINTER                 0x020
+#define INDIRECT_CTX_STS                0x040
+#define ACTIVE_CTX_STS                  0x044
+#define INDIRECT_CTX_SIG_EVENTS         0x048
+#define INDIRECT_CTX_WAKEUP_EVENTS      0x050
+#define NN_PUT                          0x080
+#define NN_GET                          0x084
+#define TIMESTAMP_LOW                   0x0c0
+#define TIMESTAMP_HIGH                  0x0c4
+#define T_INDEX_BYTE_INDEX              0x0f4
+#define LOCAL_CSR_STATUS                0x180
+u32 ixp2000_uengine_mask;
+static void *ixp2000_uengine_csr_area(int uengine)
+{
+        return ((void *)IXP2000_UENGINE_CSR_VIRT_BASE) + (uengine << 10);
+}
+/*
+ * LOCAL_CSR_STATUS=1 after a read or write to a microengine's CSR
+ * space means that the microengine we tried to access was also trying
+ * to access its own CSR space on the same clock cycle as we did.  When
+ * this happens, we lose the arbitration process by default, and the
+ * read or write we tried to do was not actually performed, so we try
+ * again until it succeeds.
+ */
+u32 ixp2000_uengine_csr_read(int uengine, int offset)
+{
+        void *uebase;
+        u32 *local_csr_status;
+        u32 *reg;
+        u32 value;
+        uebase = ixp2000_uengine_csr_area(uengine);
+        local_csr_status = (u32 *)(uebase + LOCAL_CSR_STATUS);
+        reg = (u32 *)(uebase + offset);
+        do {
+                value = ixp2000_reg_read(reg);
+        } while (ixp2000_reg_read(local_csr_status) & 1);
+        return value;
+}
+EXPORT_SYMBOL(ixp2000_uengine_csr_read);
+void ixp2000_uengine_csr_write(int uengine, int offset, u32 value)
+{
+        void *uebase;
+        u32 *local_csr_status;
+        u32 *reg;
+        uebase = ixp2000_uengine_csr_area(uengine);
+        local_csr_status = (u32 *)(uebase + LOCAL_CSR_STATUS);
+        reg = (u32 *)(uebase + offset);
+        do {
+                ixp2000_reg_write(reg, value);
+        } while (ixp2000_reg_read(local_csr_status) & 1);
+}
+EXPORT_SYMBOL(ixp2000_uengine_csr_write);
+void ixp2000_uengine_reset(u32 uengine_mask)
+{
+        ixp2000_reg_wrb(IXP2000_RESET1, uengine_mask & ixp2000_uengine_mask);
+        ixp2000_reg_wrb(IXP2000_RESET1, 0);
+}
+EXPORT_SYMBOL(ixp2000_uengine_reset);
+void ixp2000_uengine_set_mode(int uengine, u32 mode)
+{
+        /*
+         * CTL_STR_PAR_EN: unconditionally enable parity checking on
+         * control store.
+         */
+        mode |= 0x10000000;
+        ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mode);
+        /*
+         * Enable updating of condition codes.
+         */
+        ixp2000_uengine_csr_write(uengine, CC_ENABLE, 0x00002000);
+        /*
+         * Initialise other per-microengine registers.
+         */
+        ixp2000_uengine_csr_write(uengine, NN_PUT, 0x00);
+        ixp2000_uengine_csr_write(uengine, NN_GET, 0x00);
+        ixp2000_uengine_csr_write(uengine, T_INDEX_BYTE_INDEX, 0);
+}
+EXPORT_SYMBOL(ixp2000_uengine_set_mode);
+static int make_even_parity(u32 x)
+{
+        return hweight32(x) & 1;
+}
+static void ustore_write(int uengine, u64 insn)
+{
+        /*
+         * Generate even parity for top and bottom 20 bits.
+         */
+        insn |= (u64)make_even_parity((insn >> 20) & 0x000fffff) << 41;
+        insn |= (u64)make_even_parity(insn & 0x000fffff) << 40;
+        /*
+         * Write to microstore.  The second write auto-increments
+         * the USTORE_ADDRESS index register.
+         */
+        ixp2000_uengine_csr_write(uengine, USTORE_DATA_LOWER, (u32)insn);
+        ixp2000_uengine_csr_write(uengine, USTORE_DATA_UPPER, (u32)(insn >> 32));
+}
+void ixp2000_uengine_load_microcode(int uengine, u8 *ucode, int insns)
+{
+        int i;
+        /*
+         * Start writing to microstore at address 0.
+         */
+        ixp2000_uengine_csr_write(uengine, USTORE_ADDRESS, 0x80000000);
+        for (i = 0; i < insns; i++) {
+                u64 insn;
+                insn = (((u64)ucode[0]) << 32) |
+                        (((u64)ucode[1]) << 24) |
+                        (((u64)ucode[2]) << 16) |
+                        (((u64)ucode[3]) << 8) |
+                        ((u64)ucode[4]);
+                ucode += 5;
+                ustore_write(uengine, insn);
+        }
+        /*
+         * Pad with a few NOPs at the end (to avoid the microengine
+         * aborting as it prefetches beyond the last instruction), unless
+         * we run off the end of the instruction store first, at which
+         * point the address register will wrap back to zero.
+         */
+        for (i = 0; i < 4; i++) {
+                u32 addr;
+                addr = ixp2000_uengine_csr_read(uengine, USTORE_ADDRESS);
+                if (addr == 0x80000000)
+                        break;
+                ustore_write(uengine, 0xf0000c0300ULL);
+        }
+        /*
+         * End programming.
+         */
+        ixp2000_uengine_csr_write(uengine, USTORE_ADDRESS, 0x00000000);
+}
+EXPORT_SYMBOL(ixp2000_uengine_load_microcode);
+void ixp2000_uengine_init_context(int uengine, int context, int pc)
+{
+        /*
+         * Select the right context for indirect access.
+         */
+        ixp2000_uengine_csr_write(uengine, CSR_CTX_POINTER, context);
+        /*
+         * Initialise signal masks to immediately go to Ready state.
+         */
+        ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_SIG_EVENTS, 1);
+        ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_WAKEUP_EVENTS, 1);
+        /*
+         * Set program counter.
+         */
+        ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_STS, pc);
+}
+EXPORT_SYMBOL(ixp2000_uengine_init_context);
+void ixp2000_uengine_start_contexts(int uengine, u8 ctx_mask)
+{
+        u32 mask;
+        /*
+         * Enable the specified context to go to Executing state.
+         */
+        mask = ixp2000_uengine_csr_read(uengine, CTX_ENABLES);
+        mask |= ctx_mask << 8;
+        ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mask);
+}
+EXPORT_SYMBOL(ixp2000_uengine_start_contexts);
+void ixp2000_uengine_stop_contexts(int uengine, u8 ctx_mask)
+{
+        u32 mask;
+        /*
+         * Disable the Ready->Executing transition.  Note that this
+         * does not stop the context until it voluntarily yields.
+         */
+        mask = ixp2000_uengine_csr_read(uengine, CTX_ENABLES);
+        mask &= ~(ctx_mask << 8);
+        ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mask);
+}
+EXPORT_SYMBOL(ixp2000_uengine_stop_contexts);
+static int check_ixp_type(struct ixp2000_uengine_code *c)
+{
+        u32 product_id;
+        u32 rev;
+        product_id = ixp2000_reg_read(IXP2000_PRODUCT_ID);
+        if (((product_id >> 16) & 0x1f) != 0)
+                return 0;
+        switch ((product_id >> 8) & 0xff) {
+        case 0:         /* IXP2800 */
+                if (!(c->cpu_model_bitmask & 4))
+                        return 0;
+                break;
+        case 1:         /* IXP2850 */
+                if (!(c->cpu_model_bitmask & 8))
+                        return 0;
+                break;
+        case 2:         /* IXP2400 */
+                if (!(c->cpu_model_bitmask & 2))
+                        return 0;
+                break;
+        default:
+                return 0;
+        }
+        rev = product_id & 0xff;
+        if (rev < c->cpu_min_revision || rev > c->cpu_max_revision)
+                return 0;
+        return 1;
+}
+static void generate_ucode(u8 *ucode, u32 *gpr_a, u32 *gpr_b)
+{
+        int offset;
+        int i;
+        offset = 0;
+        for (i = 0; i < 128; i++) {
+                u8 b3;
+                u8 b2;
+                u8 b1;
+                u8 b0;
+                b3 = (gpr_a[i] >> 24) & 0xff;
+                b2 = (gpr_a[i] >> 16) & 0xff;
+                b1 = (gpr_a[i] >> 8) & 0xff;
+                b0 = gpr_a[i] & 0xff;
+                // immed[@ai, (b1 << 8) | b0]
+                // 11110000 0000VVVV VVVV11VV VVVVVV00 1IIIIIII
+                ucode[offset++] = 0xf0;
+                ucode[offset++] = (b1 >> 4);
+                ucode[offset++] = (b1 << 4) | 0x0c | (b0 >> 6);
+                ucode[offset++] = (b0 << 2);
+                ucode[offset++] = 0x80 | i;
+                // immed_w1[@ai, (b3 << 8) | b2]
+                // 11110100 0100VVVV VVVV11VV VVVVVV00 1IIIIIII
+                ucode[offset++] = 0xf4;
+                ucode[offset++] = 0x40 | (b3 >> 4);
+                ucode[offset++] = (b3 << 4) | 0x0c | (b2 >> 6);
+                ucode[offset++] = (b2 << 2);
+                ucode[offset++] = 0x80 | i;
+        }
+        for (i = 0; i < 128; i++) {
+                u8 b3;
+                u8 b2;
+                u8 b1;
+                u8 b0;
+                b3 = (gpr_b[i] >> 24) & 0xff;
+                b2 = (gpr_b[i] >> 16) & 0xff;
+                b1 = (gpr_b[i] >> 8) & 0xff;
+                b0 = gpr_b[i] & 0xff;
+                // immed[@bi, (b1 << 8) | b0]
+                // 11110000 0000VVVV VVVV001I IIIIII11 VVVVVVVV
+                ucode[offset++] = 0xf0;
+                ucode[offset++] = (b1 >> 4);
+                ucode[offset++] = (b1 << 4) | 0x02 | (i >> 6);
+                ucode[offset++] = (i << 2) | 0x03;
+                ucode[offset++] = b0;
+                // immed_w1[@bi, (b3 << 8) | b2]
+                // 11110100 0100VVVV VVVV001I IIIIII11 VVVVVVVV
+                ucode[offset++] = 0xf4;
+                ucode[offset++] = 0x40 | (b3 >> 4);
+                ucode[offset++] = (b3 << 4) | 0x02 | (i >> 6);
+                ucode[offset++] = (i << 2) | 0x03;
+                ucode[offset++] = b2;
+        }
+        // ctx_arb[kill]
+        ucode[offset++] = 0xe0;
+        ucode[offset++] = 0x00;
+        ucode[offset++] = 0x01;
+        ucode[offset++] = 0x00;
+        ucode[offset++] = 0x00;
+}
+static int set_initial_registers(int uengine, struct ixp2000_uengine_code *c)
+{
+        int per_ctx_regs;
+        u32 *gpr_a;
+        u32 *gpr_b;
+        u8 *ucode;
+        int i;
+        gpr_a = kmalloc(128 * sizeof(u32), GFP_KERNEL);
+        gpr_b = kmalloc(128 * sizeof(u32), GFP_KERNEL);
+        ucode = kmalloc(513 * 5, GFP_KERNEL);
+        if (gpr_a == NULL || gpr_b == NULL || ucode == NULL) {
+                kfree(ucode);
+                kfree(gpr_b);
+                kfree(gpr_a);
+                return 1;
+        }
+        per_ctx_regs = 16;
+        if (c->uengine_parameters & IXP2000_UENGINE_4_CONTEXTS)
+                per_ctx_regs = 32;
+        memset(gpr_a, 0, sizeof(gpr_a));
+        memset(gpr_b, 0, sizeof(gpr_b));
+        for (i = 0; i < 256; i++) {
+                struct ixp2000_reg_value *r = c->initial_reg_values + i;
+                u32 *bank;
+                int inc;
+                int j;
+                if (r->reg == -1)
+                        break;
+                bank = (r->reg & 0x400) ? gpr_b : gpr_a;
+                inc = (r->reg & 0x80) ? 128 : per_ctx_regs;
+                j = r->reg & 0x7f;
+                while (j < 128) {
+                        bank[j] = r->value;
+                        j += inc;
+                }
+        }
+        generate_ucode(ucode, gpr_a, gpr_b);
+        ixp2000_uengine_load_microcode(uengine, ucode, 513);
+        ixp2000_uengine_init_context(uengine, 0, 0);
+        ixp2000_uengine_start_contexts(uengine, 0x01);
+        for (i = 0; i < 100; i++) {
+                u32 status;
+                status = ixp2000_uengine_csr_read(uengine, ACTIVE_CTX_STS);
+                if (!(status & 0x80000000))
+                        break;
+        }
+        ixp2000_uengine_stop_contexts(uengine, 0x01);
+        kfree(ucode);
+        kfree(gpr_b);
+        kfree(gpr_a);
+        return !!(i == 100);
+}
+int ixp2000_uengine_load(int uengine, struct ixp2000_uengine_code *c)
+{
+        int ctx;
+        if (!check_ixp_type(c))
+                return 1;
+        if (!(ixp2000_uengine_mask & (1 << uengine)))
+                return 1;
+        ixp2000_uengine_reset(1 << uengine);
+        ixp2000_uengine_set_mode(uengine, c->uengine_parameters);
+        if (set_initial_registers(uengine, c))
+                return 1;
+        ixp2000_uengine_load_microcode(uengine, c->insns, c->num_insns);
+        for (ctx = 0; ctx < 8; ctx++)
+                ixp2000_uengine_init_context(uengine, ctx, 0);
+        return 0;
+}
+EXPORT_SYMBOL(ixp2000_uengine_load);
+static int __init ixp2000_uengine_init(void)
+{
+        int uengine;
+        u32 value;
+        /*
+         * Determine number of microengines present.
+         */
+        switch ((ixp2000_reg_read(IXP2000_PRODUCT_ID) >> 8) & 0x1fff) {
+        case 0:         /* IXP2800 */
+        case 1:         /* IXP2850 */
+                ixp2000_uengine_mask = 0x00ff00ff;
+                break;
+        case 2:         /* IXP2400 */
+                ixp2000_uengine_mask = 0x000f000f;
+                break;
+        default:
+                printk(KERN_INFO "Detected unknown IXP2000 model (%.8x)\n",
+                        (unsigned int)ixp2000_reg_read(IXP2000_PRODUCT_ID));
+                ixp2000_uengine_mask = 0x00000000;
+                break;
+        }
+        /*
+         * Reset microengines.
+         */
+        ixp2000_uengine_reset(ixp2000_uengine_mask);
+        /*
+         * Synchronise timestamp counters across all microengines.
+         */
+        value = ixp2000_reg_read(IXP2000_MISC_CONTROL);
+        ixp2000_reg_wrb(IXP2000_MISC_CONTROL, value & ~0x80);
+        for (uengine = 0; uengine < 32; uengine++) {
+                if (ixp2000_uengine_mask & (1 << uengine)) {
+                        ixp2000_uengine_csr_write(uengine, TIMESTAMP_LOW, 0);
+                        ixp2000_uengine_csr_write(uengine, TIMESTAMP_HIGH, 0);
+                }
+        }
+        ixp2000_reg_wrb(IXP2000_MISC_CONTROL, value | 0x80);
+        return 0;
+}
+subsys_initcall(ixp2000_uengine_init);

diff --git a/arch/arm/common/uengine.c b/arch/arm/common/uengine.c new file mode 100644 index 000000000000..a1310b71004e --- /dev/null +++ b/arch/arm/common/uengine.c
@@ -0,0 +1,473 @@
	1	/*
	2	* Generic library functions for the microengines found on the Intel
	3	* IXP2000 series of network processors.
	4	*
	5	* Copyright (C) 2004, 2005 Lennert Buytenhek <buytenh@wantstofly.org>
	6	* Dedicated to Marija Kulikova.
	7	*
	8	* This program is free software; you can redistribute it and/or modify
	9	* it under the terms of the GNU Lesser General Public License as
	10	* published by the Free Software Foundation; either version 2.1 of the
	11	* License, or (at your option) any later version.
	12	*/
	13
	14	#include <linux/config.h>
	15	#include <linux/kernel.h>
	16	#include <linux/init.h>
	17	#include <linux/slab.h>
	18	#include <linux/module.h>
	19	#include <linux/string.h>
	20	#include <asm/hardware.h>
	21	#include <asm/arch/ixp2000-regs.h>
	22	#include <asm/hardware/uengine.h>
	23	#include <asm/io.h>
	24
	25	#define USTORE_ADDRESS 0x000
	26	#define USTORE_DATA_LOWER 0x004
	27	#define USTORE_DATA_UPPER 0x008
	28	#define CTX_ENABLES 0x018
	29	#define CC_ENABLE 0x01c
	30	#define CSR_CTX_POINTER 0x020
	31	#define INDIRECT_CTX_STS 0x040
	32	#define ACTIVE_CTX_STS 0x044
	33	#define INDIRECT_CTX_SIG_EVENTS 0x048
	34	#define INDIRECT_CTX_WAKEUP_EVENTS 0x050
	35	#define NN_PUT 0x080
	36	#define NN_GET 0x084
	37	#define TIMESTAMP_LOW 0x0c0
	38	#define TIMESTAMP_HIGH 0x0c4
	39	#define T_INDEX_BYTE_INDEX 0x0f4
	40	#define LOCAL_CSR_STATUS 0x180
	41
	42	u32 ixp2000_uengine_mask;
	43
	44	static void *ixp2000_uengine_csr_area(int uengine)
	45	{
	46	return ((void *)IXP2000_UENGINE_CSR_VIRT_BASE) + (uengine << 10);
	47	}
	48
	49	/*
	50	* LOCAL_CSR_STATUS=1 after a read or write to a microengine's CSR
	51	* space means that the microengine we tried to access was also trying
	52	* to access its own CSR space on the same clock cycle as we did. When
	53	* this happens, we lose the arbitration process by default, and the
	54	* read or write we tried to do was not actually performed, so we try
	55	* again until it succeeds.
	56	*/
	57	u32 ixp2000_uengine_csr_read(int uengine, int offset)
	58	{
	59	void *uebase;
	60	u32 *local_csr_status;
	61	u32 *reg;
	62	u32 value;
	63
	64	uebase = ixp2000_uengine_csr_area(uengine);
	65
	66	local_csr_status = (u32 *)(uebase + LOCAL_CSR_STATUS);
	67	reg = (u32 *)(uebase + offset);
	68	do {
	69	value = ixp2000_reg_read(reg);
	70	} while (ixp2000_reg_read(local_csr_status) & 1);
	71
	72	return value;
	73	}
	74	EXPORT_SYMBOL(ixp2000_uengine_csr_read);
	75
	76	void ixp2000_uengine_csr_write(int uengine, int offset, u32 value)
	77	{
	78	void *uebase;
	79	u32 *local_csr_status;
	80	u32 *reg;
	81
	82	uebase = ixp2000_uengine_csr_area(uengine);
	83
	84	local_csr_status = (u32 *)(uebase + LOCAL_CSR_STATUS);
	85	reg = (u32 *)(uebase + offset);
	86	do {
	87	ixp2000_reg_write(reg, value);
	88	} while (ixp2000_reg_read(local_csr_status) & 1);
	89	}
	90	EXPORT_SYMBOL(ixp2000_uengine_csr_write);
	91
	92	void ixp2000_uengine_reset(u32 uengine_mask)
	93	{
	94	ixp2000_reg_wrb(IXP2000_RESET1, uengine_mask & ixp2000_uengine_mask);
	95	ixp2000_reg_wrb(IXP2000_RESET1, 0);
	96	}
	97	EXPORT_SYMBOL(ixp2000_uengine_reset);
	98
	99	void ixp2000_uengine_set_mode(int uengine, u32 mode)
	100	{
	101	/*
	102	* CTL_STR_PAR_EN: unconditionally enable parity checking on
	103	* control store.
	104	*/
	105	mode \|= 0x10000000;
	106	ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mode);
	107
	108	/*
	109	* Enable updating of condition codes.
	110	*/
	111	ixp2000_uengine_csr_write(uengine, CC_ENABLE, 0x00002000);
	112
	113	/*
	114	* Initialise other per-microengine registers.
	115	*/
	116	ixp2000_uengine_csr_write(uengine, NN_PUT, 0x00);
	117	ixp2000_uengine_csr_write(uengine, NN_GET, 0x00);
	118	ixp2000_uengine_csr_write(uengine, T_INDEX_BYTE_INDEX, 0);
	119	}
	120	EXPORT_SYMBOL(ixp2000_uengine_set_mode);
	121
	122	static int make_even_parity(u32 x)
	123	{
	124	return hweight32(x) & 1;
	125	}
	126
	127	static void ustore_write(int uengine, u64 insn)
	128	{
	129	/*
	130	* Generate even parity for top and bottom 20 bits.
	131	*/
	132	insn \|= (u64)make_even_parity((insn >> 20) & 0x000fffff) << 41;
	133	insn \|= (u64)make_even_parity(insn & 0x000fffff) << 40;
	134
	135	/*
	136	* Write to microstore. The second write auto-increments
	137	* the USTORE_ADDRESS index register.
	138	*/
	139	ixp2000_uengine_csr_write(uengine, USTORE_DATA_LOWER, (u32)insn);
	140	ixp2000_uengine_csr_write(uengine, USTORE_DATA_UPPER, (u32)(insn >> 32));
	141	}
	142
	143	void ixp2000_uengine_load_microcode(int uengine, u8 *ucode, int insns)
	144	{
	145	int i;
	146
	147	/*
	148	* Start writing to microstore at address 0.
	149	*/
	150	ixp2000_uengine_csr_write(uengine, USTORE_ADDRESS, 0x80000000);
	151	for (i = 0; i < insns; i++) {
	152	u64 insn;
	153
	154	insn = (((u64)ucode[0]) << 32) \|
	155	(((u64)ucode[1]) << 24) \|
	156	(((u64)ucode[2]) << 16) \|
	157	(((u64)ucode[3]) << 8) \|
	158	((u64)ucode[4]);
	159	ucode += 5;
	160
	161	ustore_write(uengine, insn);
	162	}
	163
	164	/*
	165	* Pad with a few NOPs at the end (to avoid the microengine
	166	* aborting as it prefetches beyond the last instruction), unless
	167	* we run off the end of the instruction store first, at which
	168	* point the address register will wrap back to zero.
	169	*/
	170	for (i = 0; i < 4; i++) {
	171	u32 addr;
	172
	173	addr = ixp2000_uengine_csr_read(uengine, USTORE_ADDRESS);
	174	if (addr == 0x80000000)
	175	break;
	176	ustore_write(uengine, 0xf0000c0300ULL);
	177	}
	178
	179	/*
	180	* End programming.
	181	*/
	182	ixp2000_uengine_csr_write(uengine, USTORE_ADDRESS, 0x00000000);
	183	}
	184	EXPORT_SYMBOL(ixp2000_uengine_load_microcode);
	185
	186	void ixp2000_uengine_init_context(int uengine, int context, int pc)
	187	{
	188	/*
	189	* Select the right context for indirect access.
	190	*/
	191	ixp2000_uengine_csr_write(uengine, CSR_CTX_POINTER, context);
	192
	193	/*
	194	* Initialise signal masks to immediately go to Ready state.
	195	*/
	196	ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_SIG_EVENTS, 1);
	197	ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_WAKEUP_EVENTS, 1);
	198
	199	/*
	200	* Set program counter.
	201	*/
	202	ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_STS, pc);
	203	}
	204	EXPORT_SYMBOL(ixp2000_uengine_init_context);
	205
	206	void ixp2000_uengine_start_contexts(int uengine, u8 ctx_mask)
	207	{
	208	u32 mask;
	209
	210	/*
	211	* Enable the specified context to go to Executing state.
	212	*/
	213	mask = ixp2000_uengine_csr_read(uengine, CTX_ENABLES);
	214	mask \|= ctx_mask << 8;
	215	ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mask);
	216	}
	217	EXPORT_SYMBOL(ixp2000_uengine_start_contexts);
	218
	219	void ixp2000_uengine_stop_contexts(int uengine, u8 ctx_mask)
	220	{
	221	u32 mask;
	222
	223	/*
	224	* Disable the Ready->Executing transition. Note that this
	225	* does not stop the context until it voluntarily yields.
	226	*/
	227	mask = ixp2000_uengine_csr_read(uengine, CTX_ENABLES);
	228	mask &= ~(ctx_mask << 8);
	229	ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mask);
	230	}
	231	EXPORT_SYMBOL(ixp2000_uengine_stop_contexts);
	232
	233	static int check_ixp_type(struct ixp2000_uengine_code *c)
	234	{
	235	u32 product_id;
	236	u32 rev;
	237
	238	product_id = ixp2000_reg_read(IXP2000_PRODUCT_ID);
	239	if (((product_id >> 16) & 0x1f) != 0)
	240	return 0;
	241
	242	switch ((product_id >> 8) & 0xff) {
	243	case 0: /* IXP2800 */
	244	if (!(c->cpu_model_bitmask & 4))
	245	return 0;
	246	break;
	247
	248	case 1: /* IXP2850 */
	249	if (!(c->cpu_model_bitmask & 8))
	250	return 0;
	251	break;
	252
	253	case 2: /* IXP2400 */
	254	if (!(c->cpu_model_bitmask & 2))
	255	return 0;
	256	break;
	257
	258	default:
	259	return 0;
	260	}
	261
	262	rev = product_id & 0xff;
	263	if (rev < c->cpu_min_revision \|\| rev > c->cpu_max_revision)
	264	return 0;
	265
	266	return 1;
	267	}
	268
	269	static void generate_ucode(u8 ucode, u32 gpr_a, u32 *gpr_b)
	270	{
	271	int offset;
	272	int i;
	273
	274	offset = 0;
	275
	276	for (i = 0; i < 128; i++) {
	277	u8 b3;
	278	u8 b2;
	279	u8 b1;
	280	u8 b0;
	281
	282	b3 = (gpr_a[i] >> 24) & 0xff;
	283	b2 = (gpr_a[i] >> 16) & 0xff;
	284	b1 = (gpr_a[i] >> 8) & 0xff;
	285	b0 = gpr_a[i] & 0xff;
	286
	287	// immed[@ai, (b1 << 8) \| b0]
	288	// 11110000 0000VVVV VVVV11VV VVVVVV00 1IIIIIII
	289	ucode[offset++] = 0xf0;
	290	ucode[offset++] = (b1 >> 4);
	291	ucode[offset++] = (b1 << 4) \| 0x0c \| (b0 >> 6);
	292	ucode[offset++] = (b0 << 2);
	293	ucode[offset++] = 0x80 \| i;
	294
	295	// immed_w1[@ai, (b3 << 8) \| b2]
	296	// 11110100 0100VVVV VVVV11VV VVVVVV00 1IIIIIII
	297	ucode[offset++] = 0xf4;
	298	ucode[offset++] = 0x40 \| (b3 >> 4);
	299	ucode[offset++] = (b3 << 4) \| 0x0c \| (b2 >> 6);
	300	ucode[offset++] = (b2 << 2);
	301	ucode[offset++] = 0x80 \| i;
	302	}
	303
	304	for (i = 0; i < 128; i++) {
	305	u8 b3;
	306	u8 b2;
	307	u8 b1;
	308	u8 b0;
	309
	310	b3 = (gpr_b[i] >> 24) & 0xff;
	311	b2 = (gpr_b[i] >> 16) & 0xff;
	312	b1 = (gpr_b[i] >> 8) & 0xff;
	313	b0 = gpr_b[i] & 0xff;
	314
	315	// immed[@bi, (b1 << 8) \| b0]
	316	// 11110000 0000VVVV VVVV001I IIIIII11 VVVVVVVV
	317	ucode[offset++] = 0xf0;
	318	ucode[offset++] = (b1 >> 4);
	319	ucode[offset++] = (b1 << 4) \| 0x02 \| (i >> 6);
	320	ucode[offset++] = (i << 2) \| 0x03;
	321	ucode[offset++] = b0;
	322
	323	// immed_w1[@bi, (b3 << 8) \| b2]
	324	// 11110100 0100VVVV VVVV001I IIIIII11 VVVVVVVV
	325	ucode[offset++] = 0xf4;
	326	ucode[offset++] = 0x40 \| (b3 >> 4);
	327	ucode[offset++] = (b3 << 4) \| 0x02 \| (i >> 6);
	328	ucode[offset++] = (i << 2) \| 0x03;
	329	ucode[offset++] = b2;
	330	}
	331
	332	// ctx_arb[kill]
	333	ucode[offset++] = 0xe0;
	334	ucode[offset++] = 0x00;
	335	ucode[offset++] = 0x01;
	336	ucode[offset++] = 0x00;
	337	ucode[offset++] = 0x00;
	338	}
	339
	340	static int set_initial_registers(int uengine, struct ixp2000_uengine_code *c)
	341	{
	342	int per_ctx_regs;
	343	u32 *gpr_a;
	344	u32 *gpr_b;
	345	u8 *ucode;
	346	int i;
	347
	348	gpr_a = kmalloc(128 * sizeof(u32), GFP_KERNEL);
	349	gpr_b = kmalloc(128 * sizeof(u32), GFP_KERNEL);
	350	ucode = kmalloc(513 * 5, GFP_KERNEL);
	351	if (gpr_a == NULL \|\| gpr_b == NULL \|\| ucode == NULL) {
	352	kfree(ucode);
	353	kfree(gpr_b);
	354	kfree(gpr_a);
	355	return 1;
	356	}
	357
	358	per_ctx_regs = 16;
	359	if (c->uengine_parameters & IXP2000_UENGINE_4_CONTEXTS)
	360	per_ctx_regs = 32;
	361
	362	memset(gpr_a, 0, sizeof(gpr_a));
	363	memset(gpr_b, 0, sizeof(gpr_b));
	364	for (i = 0; i < 256; i++) {
	365	struct ixp2000_reg_value *r = c->initial_reg_values + i;
	366	u32 *bank;
	367	int inc;
	368	int j;
	369
	370	if (r->reg == -1)
	371	break;
	372
	373	bank = (r->reg & 0x400) ? gpr_b : gpr_a;
	374	inc = (r->reg & 0x80) ? 128 : per_ctx_regs;
	375
	376	j = r->reg & 0x7f;
	377	while (j < 128) {
	378	bank[j] = r->value;
	379	j += inc;
	380	}
	381	}
	382
	383	generate_ucode(ucode, gpr_a, gpr_b);
	384	ixp2000_uengine_load_microcode(uengine, ucode, 513);
	385	ixp2000_uengine_init_context(uengine, 0, 0);
	386	ixp2000_uengine_start_contexts(uengine, 0x01);
	387	for (i = 0; i < 100; i++) {
	388	u32 status;
	389
	390	status = ixp2000_uengine_csr_read(uengine, ACTIVE_CTX_STS);
	391	if (!(status & 0x80000000))
	392	break;
	393	}
	394	ixp2000_uengine_stop_contexts(uengine, 0x01);
	395
	396	kfree(ucode);
	397	kfree(gpr_b);
	398	kfree(gpr_a);
	399
	400	return !!(i == 100);
	401	}
	402
	403	int ixp2000_uengine_load(int uengine, struct ixp2000_uengine_code *c)
	404	{
	405	int ctx;
	406
	407	if (!check_ixp_type(c))
	408	return 1;
	409
	410	if (!(ixp2000_uengine_mask & (1 << uengine)))
	411	return 1;
	412
	413	ixp2000_uengine_reset(1 << uengine);
	414	ixp2000_uengine_set_mode(uengine, c->uengine_parameters);
	415	if (set_initial_registers(uengine, c))
	416	return 1;
	417	ixp2000_uengine_load_microcode(uengine, c->insns, c->num_insns);
	418
	419	for (ctx = 0; ctx < 8; ctx++)
	420	ixp2000_uengine_init_context(uengine, ctx, 0);
	421
	422	return 0;
	423	}
	424	EXPORT_SYMBOL(ixp2000_uengine_load);
	425
	426
	427	static int __init ixp2000_uengine_init(void)
	428	{
	429	int uengine;
	430	u32 value;
	431
	432	/*
	433	* Determine number of microengines present.
	434	*/
	435	switch ((ixp2000_reg_read(IXP2000_PRODUCT_ID) >> 8) & 0x1fff) {
	436	case 0: /* IXP2800 */
	437	case 1: /* IXP2850 */
	438	ixp2000_uengine_mask = 0x00ff00ff;
	439	break;
	440
	441	case 2: /* IXP2400 */
	442	ixp2000_uengine_mask = 0x000f000f;
	443	break;
	444
	445	default:
	446	printk(KERN_INFO "Detected unknown IXP2000 model (%.8x)\n",
	447	(unsigned int)ixp2000_reg_read(IXP2000_PRODUCT_ID));
	448	ixp2000_uengine_mask = 0x00000000;
	449	break;
	450	}
	451
	452	/*
	453	* Reset microengines.
	454	*/
	455	ixp2000_uengine_reset(ixp2000_uengine_mask);
	456
	457	/*
	458	* Synchronise timestamp counters across all microengines.
	459	*/
	460	value = ixp2000_reg_read(IXP2000_MISC_CONTROL);
	461	ixp2000_reg_wrb(IXP2000_MISC_CONTROL, value & ~0x80);
	462	for (uengine = 0; uengine < 32; uengine++) {
	463	if (ixp2000_uengine_mask & (1 << uengine)) {
	464	ixp2000_uengine_csr_write(uengine, TIMESTAMP_LOW, 0);
	465	ixp2000_uengine_csr_write(uengine, TIMESTAMP_HIGH, 0);
	466	}
	467	}
	468	ixp2000_reg_wrb(IXP2000_MISC_CONTROL, value \| 0x80);
	469
	470	return 0;
	471	}
	472
	473	subsys_initcall(ixp2000_uengine_init);