Revision 18f5ed365d3f188a91149d528c853000330a4a58 authored by Takashi Sakamoto on 05 August 2015, 00:21:05 UTC, committed by Takashi Iwai on 05 August 2015, 05:52:39 UTC
Fireworks uses TSB43CB43(IceLynx-Micro) as its IEC 61883-1/6 interface. This chip includes ARM7 core, and loads and runs program. The firmware is stored in on-board memory and loaded every powering-on from it. Echo Audio ships several versions of firmwares for each model. These firmwares have each quirk and the quirk changes a sequence of packets. As long as I investigated, AudioFire2/AudioFire4/AudioFirePre8 have a quirk to transfer a first packet with 0x02 in its dbc field. This causes ALSA Fireworks driver to detect discontinuity. In this case, firmware version 5.7.0, 5.7.3 and 5.8.0 are used. Payload CIP CIP quadlets header1 header2 02 00050002 90ffffff <- 42 0005000a 90013000 42 00050012 90014400 42 0005001a 90015800 02 0005001a 90ffffff 42 00050022 90019000 42 0005002a 9001a400 42 00050032 9001b800 02 00050032 90ffffff 42 0005003a 9001d000 42 00050042 9001e400 42 0005004a 9001f800 02 0005004a 90ffffff (AudioFire2 with firmware version 5.7.) $ dmesg snd-fireworks fw1.0: Detect discontinuity of CIP: 00 02 These models, AudioFire8 (since Jul 2009 ) and Gibson Robot Interface Pack series uses the same ARM binary as their firmware. Thus, this quirk may be observed among them. This commit adds a new member for AMDTP structure. This member represents the value of dbc field in a first AMDTP packet. Drivers can set it with a preferred value according to model's quirk. Tested-by: Johannes Oertei <johannes.oertel@uni-due.de> Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Cc: <stable@vger.kernel.org> Signed-off-by: Takashi Iwai <tiwai@suse.de>
1 parent c85523d
sys_eb64p.c
/*
* linux/arch/alpha/kernel/sys_eb64p.c
*
* Copyright (C) 1995 David A Rusling
* Copyright (C) 1996 Jay A Estabrook
* Copyright (C) 1998, 1999 Richard Henderson
*
* Code supporting the EB64+ and EB66.
*/
#include <linux/kernel.h>
#include <linux/types.h>
#include <linux/mm.h>
#include <linux/sched.h>
#include <linux/pci.h>
#include <linux/init.h>
#include <linux/bitops.h>
#include <asm/ptrace.h>
#include <asm/dma.h>
#include <asm/irq.h>
#include <asm/mmu_context.h>
#include <asm/io.h>
#include <asm/pgtable.h>
#include <asm/core_apecs.h>
#include <asm/core_lca.h>
#include <asm/hwrpb.h>
#include <asm/tlbflush.h>
#include "proto.h"
#include "irq_impl.h"
#include "pci_impl.h"
#include "machvec_impl.h"
/* Note mask bit is true for DISABLED irqs. */
static unsigned int cached_irq_mask = -1;
static inline void
eb64p_update_irq_hw(unsigned int irq, unsigned long mask)
{
outb(mask >> (irq >= 24 ? 24 : 16), (irq >= 24 ? 0x27 : 0x26));
}
static inline void
eb64p_enable_irq(struct irq_data *d)
{
eb64p_update_irq_hw(d->irq, cached_irq_mask &= ~(1 << d->irq));
}
static void
eb64p_disable_irq(struct irq_data *d)
{
eb64p_update_irq_hw(d->irq, cached_irq_mask |= 1 << d->irq);
}
static struct irq_chip eb64p_irq_type = {
.name = "EB64P",
.irq_unmask = eb64p_enable_irq,
.irq_mask = eb64p_disable_irq,
.irq_mask_ack = eb64p_disable_irq,
};
static void
eb64p_device_interrupt(unsigned long vector)
{
unsigned long pld;
unsigned int i;
/* Read the interrupt summary registers */
pld = inb(0x26) | (inb(0x27) << 8);
/*
* Now, for every possible bit set, work through
* them and call the appropriate interrupt handler.
*/
while (pld) {
i = ffz(~pld);
pld &= pld - 1; /* clear least bit set */
if (i == 5) {
isa_device_interrupt(vector);
} else {
handle_irq(16 + i);
}
}
}
static void __init
eb64p_init_irq(void)
{
long i;
#if defined(CONFIG_ALPHA_GENERIC) || defined(CONFIG_ALPHA_CABRIOLET)
/*
* CABRIO SRM may not set variation correctly, so here we test
* the high word of the interrupt summary register for the RAZ
* bits, and hope that a true EB64+ would read all ones...
*/
if (inw(0x806) != 0xffff) {
extern struct alpha_machine_vector cabriolet_mv;
printk("Detected Cabriolet: correcting HWRPB.\n");
hwrpb->sys_variation |= 2L << 10;
hwrpb_update_checksum(hwrpb);
alpha_mv = cabriolet_mv;
alpha_mv.init_irq();
return;
}
#endif /* GENERIC */
outb(0xff, 0x26);
outb(0xff, 0x27);
init_i8259a_irqs();
for (i = 16; i < 32; ++i) {
irq_set_chip_and_handler(i, &eb64p_irq_type, handle_level_irq);
irq_set_status_flags(i, IRQ_LEVEL);
}
common_init_isa_dma();
setup_irq(16+5, &isa_cascade_irqaction);
}
/*
* PCI Fixup configuration.
*
* There are two 8 bit external summary registers as follows:
*
* Summary @ 0x26:
* Bit Meaning
* 0 Interrupt Line A from slot 0
* 1 Interrupt Line A from slot 1
* 2 Interrupt Line B from slot 0
* 3 Interrupt Line B from slot 1
* 4 Interrupt Line C from slot 0
* 5 Interrupt line from the two ISA PICs
* 6 Tulip
* 7 NCR SCSI
*
* Summary @ 0x27
* Bit Meaning
* 0 Interrupt Line C from slot 1
* 1 Interrupt Line D from slot 0
* 2 Interrupt Line D from slot 1
* 3 RAZ
* 4 RAZ
* 5 RAZ
* 6 RAZ
* 7 RAZ
*
* The device to slot mapping looks like:
*
* Slot Device
* 5 NCR SCSI controller
* 6 PCI on board slot 0
* 7 PCI on board slot 1
* 8 Intel SIO PCI-ISA bridge chip
* 9 Tulip - DECchip 21040 Ethernet controller
*
*
* This two layered interrupt approach means that we allocate IRQ 16 and
* above for PCI interrupts. The IRQ relates to which bit the interrupt
* comes in on. This makes interrupt processing much easier.
*/
static int __init
eb64p_map_irq(const struct pci_dev *dev, u8 slot, u8 pin)
{
static char irq_tab[5][5] __initdata = {
/*INT INTA INTB INTC INTD */
{16+7, 16+7, 16+7, 16+7, 16+7}, /* IdSel 5, slot ?, ?? */
{16+0, 16+0, 16+2, 16+4, 16+9}, /* IdSel 6, slot ?, ?? */
{16+1, 16+1, 16+3, 16+8, 16+10}, /* IdSel 7, slot ?, ?? */
{ -1, -1, -1, -1, -1}, /* IdSel 8, SIO */
{16+6, 16+6, 16+6, 16+6, 16+6}, /* IdSel 9, TULIP */
};
const long min_idsel = 5, max_idsel = 9, irqs_per_slot = 5;
return COMMON_TABLE_LOOKUP;
}
/*
* The System Vector
*/
#if defined(CONFIG_ALPHA_GENERIC) || defined(CONFIG_ALPHA_EB64P)
struct alpha_machine_vector eb64p_mv __initmv = {
.vector_name = "EB64+",
DO_EV4_MMU,
DO_DEFAULT_RTC,
DO_APECS_IO,
.machine_check = apecs_machine_check,
.max_isa_dma_address = ALPHA_MAX_ISA_DMA_ADDRESS,
.min_io_address = DEFAULT_IO_BASE,
.min_mem_address = APECS_AND_LCA_DEFAULT_MEM_BASE,
.nr_irqs = 32,
.device_interrupt = eb64p_device_interrupt,
.init_arch = apecs_init_arch,
.init_irq = eb64p_init_irq,
.init_rtc = common_init_rtc,
.init_pci = common_init_pci,
.kill_arch = NULL,
.pci_map_irq = eb64p_map_irq,
.pci_swizzle = common_swizzle,
};
ALIAS_MV(eb64p)
#endif
#if defined(CONFIG_ALPHA_GENERIC) || defined(CONFIG_ALPHA_EB66)
struct alpha_machine_vector eb66_mv __initmv = {
.vector_name = "EB66",
DO_EV4_MMU,
DO_DEFAULT_RTC,
DO_LCA_IO,
.machine_check = lca_machine_check,
.max_isa_dma_address = ALPHA_MAX_ISA_DMA_ADDRESS,
.min_io_address = DEFAULT_IO_BASE,
.min_mem_address = APECS_AND_LCA_DEFAULT_MEM_BASE,
.nr_irqs = 32,
.device_interrupt = eb64p_device_interrupt,
.init_arch = lca_init_arch,
.init_irq = eb64p_init_irq,
.init_rtc = common_init_rtc,
.init_pci = common_init_pci,
.pci_map_irq = eb64p_map_irq,
.pci_swizzle = common_swizzle,
};
ALIAS_MV(eb66)
#endif
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