Merge branch 'master' into d3d12

This commit is contained in:
Triang3l 2018-11-24 16:26:27 +03:00
commit 5c1efe7b9a
48 changed files with 10195 additions and 5730 deletions

View File

@ -4,8 +4,11 @@ Xenia - Xbox 360 Emulator Research Project
Xenia is an experimental emulator for the Xbox 360. For more information see the
[main xenia website](https://xenia.jp/).
**Interested in supporting the core contributors?
[Xenia Project on Patreon](https://www.patreon.com/xenia_project).**
Come chat with us about **emulator-related topics** on [Discord](https://discord.gg/Q9mxZf9).
For developer chat join `#dev` but stay on topic. Lurking is fine.
For developer chat join `#dev` but stay on topic. Lurking is not only fine, but encouraged!
Please check the [frequently asked questions](https://xenia.jp/faq/) page before
asking questions. We've got jobs/lives/etc, so don't expect instant answers.

428
assets/icon/LICENSE Normal file
View File

@ -0,0 +1,428 @@
Attribution-ShareAlike 4.0 International
=======================================================================
Creative Commons Corporation ("Creative Commons") is not a law firm and
does not provide legal services or legal advice. Distribution of
Creative Commons public licenses does not create a lawyer-client or
other relationship. Creative Commons makes its licenses and related
information available on an "as-is" basis. Creative Commons gives no
warranties regarding its licenses, any material licensed under their
terms and conditions, or any related information. Creative Commons
disclaims all liability for damages resulting from their use to the
fullest extent possible.
Using Creative Commons Public Licenses
Creative Commons public licenses provide a standard set of terms and
conditions that creators and other rights holders may use to share
original works of authorship and other material subject to copyright
and certain other rights specified in the public license below. The
following considerations are for informational purposes only, are not
exhaustive, and do not form part of our licenses.
Considerations for licensors: Our public licenses are
intended for use by those authorized to give the public
permission to use material in ways otherwise restricted by
copyright and certain other rights. Our licenses are
irrevocable. Licensors should read and understand the terms
and conditions of the license they choose before applying it.
Licensors should also secure all rights necessary before
applying our licenses so that the public can reuse the
material as expected. Licensors should clearly mark any
material not subject to the license. This includes other CC-
licensed material, or material used under an exception or
limitation to copyright. More considerations for licensors:
wiki.creativecommons.org/Considerations_for_licensors
Considerations for the public: By using one of our public
licenses, a licensor grants the public permission to use the
licensed material under specified terms and conditions. If
the licensor's permission is not necessary for any reason--for
example, because of any applicable exception or limitation to
copyright--then that use is not regulated by the license. Our
licenses grant only permissions under copyright and certain
other rights that a licensor has authority to grant. Use of
the licensed material may still be restricted for other
reasons, including because others have copyright or other
rights in the material. A licensor may make special requests,
such as asking that all changes be marked or described.
Although not required by our licenses, you are encouraged to
respect those requests where reasonable. More considerations
for the public:
wiki.creativecommons.org/Considerations_for_licensees
=======================================================================
Creative Commons Attribution-ShareAlike 4.0 International Public
License
By exercising the Licensed Rights (defined below), You accept and agree
to be bound by the terms and conditions of this Creative Commons
Attribution-ShareAlike 4.0 International Public License ("Public
License"). To the extent this Public License may be interpreted as a
contract, You are granted the Licensed Rights in consideration of Your
acceptance of these terms and conditions, and the Licensor grants You
such rights in consideration of benefits the Licensor receives from
making the Licensed Material available under these terms and
conditions.
Section 1 -- Definitions.
a. Adapted Material means material subject to Copyright and Similar
Rights that is derived from or based upon the Licensed Material
and in which the Licensed Material is translated, altered,
arranged, transformed, or otherwise modified in a manner requiring
permission under the Copyright and Similar Rights held by the
Licensor. For purposes of this Public License, where the Licensed
Material is a musical work, performance, or sound recording,
Adapted Material is always produced where the Licensed Material is
synched in timed relation with a moving image.
b. Adapter's License means the license You apply to Your Copyright
and Similar Rights in Your contributions to Adapted Material in
accordance with the terms and conditions of this Public License.
c. BY-SA Compatible License means a license listed at
creativecommons.org/compatiblelicenses, approved by Creative
Commons as essentially the equivalent of this Public License.
d. Copyright and Similar Rights means copyright and/or similar rights
closely related to copyright including, without limitation,
performance, broadcast, sound recording, and Sui Generis Database
Rights, without regard to how the rights are labeled or
categorized. For purposes of this Public License, the rights
specified in Section 2(b)(1)-(2) are not Copyright and Similar
Rights.
e. Effective Technological Measures means those measures that, in the
absence of proper authority, may not be circumvented under laws
fulfilling obligations under Article 11 of the WIPO Copyright
Treaty adopted on December 20, 1996, and/or similar international
agreements.
f. Exceptions and Limitations means fair use, fair dealing, and/or
any other exception or limitation to Copyright and Similar Rights
that applies to Your use of the Licensed Material.
g. License Elements means the license attributes listed in the name
of a Creative Commons Public License. The License Elements of this
Public License are Attribution and ShareAlike.
h. Licensed Material means the artistic or literary work, database,
or other material to which the Licensor applied this Public
License.
i. Licensed Rights means the rights granted to You subject to the
terms and conditions of this Public License, which are limited to
all Copyright and Similar Rights that apply to Your use of the
Licensed Material and that the Licensor has authority to license.
j. Licensor means the individual(s) or entity(ies) granting rights
under this Public License.
k. Share means to provide material to the public by any means or
process that requires permission under the Licensed Rights, such
as reproduction, public display, public performance, distribution,
dissemination, communication, or importation, and to make material
available to the public including in ways that members of the
public may access the material from a place and at a time
individually chosen by them.
l. Sui Generis Database Rights means rights other than copyright
resulting from Directive 96/9/EC of the European Parliament and of
the Council of 11 March 1996 on the legal protection of databases,
as amended and/or succeeded, as well as other essentially
equivalent rights anywhere in the world.
m. You means the individual or entity exercising the Licensed Rights
under this Public License. Your has a corresponding meaning.
Section 2 -- Scope.
a. License grant.
1. Subject to the terms and conditions of this Public License,
the Licensor hereby grants You a worldwide, royalty-free,
non-sublicensable, non-exclusive, irrevocable license to
exercise the Licensed Rights in the Licensed Material to:
a. reproduce and Share the Licensed Material, in whole or
in part; and
b. produce, reproduce, and Share Adapted Material.
2. Exceptions and Limitations. For the avoidance of doubt, where
Exceptions and Limitations apply to Your use, this Public
License does not apply, and You do not need to comply with
its terms and conditions.
3. Term. The term of this Public License is specified in Section
6(a).
4. Media and formats; technical modifications allowed. The
Licensor authorizes You to exercise the Licensed Rights in
all media and formats whether now known or hereafter created,
and to make technical modifications necessary to do so. The
Licensor waives and/or agrees not to assert any right or
authority to forbid You from making technical modifications
necessary to exercise the Licensed Rights, including
technical modifications necessary to circumvent Effective
Technological Measures. For purposes of this Public License,
simply making modifications authorized by this Section 2(a)
(4) never produces Adapted Material.
5. Downstream recipients.
a. Offer from the Licensor -- Licensed Material. Every
recipient of the Licensed Material automatically
receives an offer from the Licensor to exercise the
Licensed Rights under the terms and conditions of this
Public License.
b. Additional offer from the Licensor -- Adapted Material.
Every recipient of Adapted Material from You
automatically receives an offer from the Licensor to
exercise the Licensed Rights in the Adapted Material
under the conditions of the Adapter's License You apply.
c. No downstream restrictions. You may not offer or impose
any additional or different terms or conditions on, or
apply any Effective Technological Measures to, the
Licensed Material if doing so restricts exercise of the
Licensed Rights by any recipient of the Licensed
Material.
6. No endorsement. Nothing in this Public License constitutes or
may be construed as permission to assert or imply that You
are, or that Your use of the Licensed Material is, connected
with, or sponsored, endorsed, or granted official status by,
the Licensor or others designated to receive attribution as
provided in Section 3(a)(1)(A)(i).
b. Other rights.
1. Moral rights, such as the right of integrity, are not
licensed under this Public License, nor are publicity,
privacy, and/or other similar personality rights; however, to
the extent possible, the Licensor waives and/or agrees not to
assert any such rights held by the Licensor to the limited
extent necessary to allow You to exercise the Licensed
Rights, but not otherwise.
2. Patent and trademark rights are not licensed under this
Public License.
3. To the extent possible, the Licensor waives any right to
collect royalties from You for the exercise of the Licensed
Rights, whether directly or through a collecting society
under any voluntary or waivable statutory or compulsory
licensing scheme. In all other cases the Licensor expressly
reserves any right to collect such royalties.
Section 3 -- License Conditions.
Your exercise of the Licensed Rights is expressly made subject to the
following conditions.
a. Attribution.
1. If You Share the Licensed Material (including in modified
form), You must:
a. retain the following if it is supplied by the Licensor
with the Licensed Material:
i. identification of the creator(s) of the Licensed
Material and any others designated to receive
attribution, in any reasonable manner requested by
the Licensor (including by pseudonym if
designated);
ii. a copyright notice;
iii. a notice that refers to this Public License;
iv. a notice that refers to the disclaimer of
warranties;
v. a URI or hyperlink to the Licensed Material to the
extent reasonably practicable;
b. indicate if You modified the Licensed Material and
retain an indication of any previous modifications; and
c. indicate the Licensed Material is licensed under this
Public License, and include the text of, or the URI or
hyperlink to, this Public License.
2. You may satisfy the conditions in Section 3(a)(1) in any
reasonable manner based on the medium, means, and context in
which You Share the Licensed Material. For example, it may be
reasonable to satisfy the conditions by providing a URI or
hyperlink to a resource that includes the required
information.
3. If requested by the Licensor, You must remove any of the
information required by Section 3(a)(1)(A) to the extent
reasonably practicable.
b. ShareAlike.
In addition to the conditions in Section 3(a), if You Share
Adapted Material You produce, the following conditions also apply.
1. The Adapter's License You apply must be a Creative Commons
license with the same License Elements, this version or
later, or a BY-SA Compatible License.
2. You must include the text of, or the URI or hyperlink to, the
Adapter's License You apply. You may satisfy this condition
in any reasonable manner based on the medium, means, and
context in which You Share Adapted Material.
3. You may not offer or impose any additional or different terms
or conditions on, or apply any Effective Technological
Measures to, Adapted Material that restrict exercise of the
rights granted under the Adapter's License You apply.
Section 4 -- Sui Generis Database Rights.
Where the Licensed Rights include Sui Generis Database Rights that
apply to Your use of the Licensed Material:
a. for the avoidance of doubt, Section 2(a)(1) grants You the right
to extract, reuse, reproduce, and Share all or a substantial
portion of the contents of the database;
b. if You include all or a substantial portion of the database
contents in a database in which You have Sui Generis Database
Rights, then the database in which You have Sui Generis Database
Rights (but not its individual contents) is Adapted Material,
including for purposes of Section 3(b); and
c. You must comply with the conditions in Section 3(a) if You Share
all or a substantial portion of the contents of the database.
For the avoidance of doubt, this Section 4 supplements and does not
replace Your obligations under this Public License where the Licensed
Rights include other Copyright and Similar Rights.
Section 5 -- Disclaimer of Warranties and Limitation of Liability.
a. UNLESS OTHERWISE SEPARATELY UNDERTAKEN BY THE LICENSOR, TO THE
EXTENT POSSIBLE, THE LICENSOR OFFERS THE LICENSED MATERIAL AS-IS
AND AS-AVAILABLE, AND MAKES NO REPRESENTATIONS OR WARRANTIES OF
ANY KIND CONCERNING THE LICENSED MATERIAL, WHETHER EXPRESS,
IMPLIED, STATUTORY, OR OTHER. THIS INCLUDES, WITHOUT LIMITATION,
WARRANTIES OF TITLE, MERCHANTABILITY, FITNESS FOR A PARTICULAR
PURPOSE, NON-INFRINGEMENT, ABSENCE OF LATENT OR OTHER DEFECTS,
ACCURACY, OR THE PRESENCE OR ABSENCE OF ERRORS, WHETHER OR NOT
KNOWN OR DISCOVERABLE. WHERE DISCLAIMERS OF WARRANTIES ARE NOT
ALLOWED IN FULL OR IN PART, THIS DISCLAIMER MAY NOT APPLY TO YOU.
b. TO THE EXTENT POSSIBLE, IN NO EVENT WILL THE LICENSOR BE LIABLE
TO YOU ON ANY LEGAL THEORY (INCLUDING, WITHOUT LIMITATION,
NEGLIGENCE) OR OTHERWISE FOR ANY DIRECT, SPECIAL, INDIRECT,
INCIDENTAL, CONSEQUENTIAL, PUNITIVE, EXEMPLARY, OR OTHER LOSSES,
COSTS, EXPENSES, OR DAMAGES ARISING OUT OF THIS PUBLIC LICENSE OR
USE OF THE LICENSED MATERIAL, EVEN IF THE LICENSOR HAS BEEN
ADVISED OF THE POSSIBILITY OF SUCH LOSSES, COSTS, EXPENSES, OR
DAMAGES. WHERE A LIMITATION OF LIABILITY IS NOT ALLOWED IN FULL OR
IN PART, THIS LIMITATION MAY NOT APPLY TO YOU.
c. The disclaimer of warranties and limitation of liability provided
above shall be interpreted in a manner that, to the extent
possible, most closely approximates an absolute disclaimer and
waiver of all liability.
Section 6 -- Term and Termination.
a. This Public License applies for the term of the Copyright and
Similar Rights licensed here. However, if You fail to comply with
this Public License, then Your rights under this Public License
terminate automatically.
b. Where Your right to use the Licensed Material has terminated under
Section 6(a), it reinstates:
1. automatically as of the date the violation is cured, provided
it is cured within 30 days of Your discovery of the
violation; or
2. upon express reinstatement by the Licensor.
For the avoidance of doubt, this Section 6(b) does not affect any
right the Licensor may have to seek remedies for Your violations
of this Public License.
c. For the avoidance of doubt, the Licensor may also offer the
Licensed Material under separate terms or conditions or stop
distributing the Licensed Material at any time; however, doing so
will not terminate this Public License.
d. Sections 1, 5, 6, 7, and 8 survive termination of this Public
License.
Section 7 -- Other Terms and Conditions.
a. The Licensor shall not be bound by any additional or different
terms or conditions communicated by You unless expressly agreed.
b. Any arrangements, understandings, or agreements regarding the
Licensed Material not stated herein are separate from and
independent of the terms and conditions of this Public License.
Section 8 -- Interpretation.
a. For the avoidance of doubt, this Public License does not, and
shall not be interpreted to, reduce, limit, restrict, or impose
conditions on any use of the Licensed Material that could lawfully
be made without permission under this Public License.
b. To the extent possible, if any provision of this Public License is
deemed unenforceable, it shall be automatically reformed to the
minimum extent necessary to make it enforceable. If the provision
cannot be reformed, it shall be severed from this Public License
without affecting the enforceability of the remaining terms and
conditions.
c. No term or condition of this Public License will be waived and no
failure to comply consented to unless expressly agreed to by the
Licensor.
d. Nothing in this Public License constitutes or may be interpreted
as a limitation upon, or waiver of, any privileges and immunities
that apply to the Licensor or You, including from the legal
processes of any jurisdiction or authority.
=======================================================================
Creative Commons is not a party to its public
licenses. Notwithstanding, Creative Commons may elect to apply one of
its public licenses to material it publishes and in those instances
will be considered the “Licensor.” The text of the Creative Commons
public licenses is dedicated to the public domain under the CC0 Public
Domain Dedication. Except for the limited purpose of indicating that
material is shared under a Creative Commons public license or as
otherwise permitted by the Creative Commons policies published at
creativecommons.org/policies, Creative Commons does not authorize the
use of the trademark "Creative Commons" or any other trademark or logo
of Creative Commons without its prior written consent including,
without limitation, in connection with any unauthorized modifications
to any of its public licenses or any other arrangements,
understandings, or agreements concerning use of licensed material. For
the avoidance of doubt, this paragraph does not form part of the
public licenses.
Creative Commons may be contacted at creativecommons.org.

Binary file not shown.

Before

Width:  |  Height:  |  Size: 99 KiB

After

Width:  |  Height:  |  Size: 102 KiB

View File

@ -233,6 +233,7 @@ solution("xenia")
include("third_party/glslang-spirv.lua")
include("third_party/imgui.lua")
include("third_party/libav.lua")
include("third_party/mspack.lua")
include("third_party/snappy.lua")
include("third_party/spirv-tools.lua")
include("third_party/volk.lua")

View File

@ -16,6 +16,7 @@ project("xenia-app")
"imgui",
"libavcodec",
"libavutil",
"mspack",
"snappy",
"spirv-tools",
"volk",

View File

@ -42,6 +42,15 @@ class X64ThunkEmitter : public X64Emitter {
HostToGuestThunk EmitHostToGuestThunk();
GuestToHostThunk EmitGuestToHostThunk();
ResolveFunctionThunk EmitResolveFunctionThunk();
private:
// The following four functions provide save/load functionality for registers.
// They assume at least StackLayout::THUNK_STACK_SIZE bytes have been
// allocated on the stack.
void EmitSaveVolatileRegs();
void EmitLoadVolatileRegs();
void EmitSaveNonvolatileRegs();
void EmitLoadNonvolatileRegs();
};
X64Backend::X64Backend() : Backend(), code_cache_(nullptr) {
@ -73,8 +82,6 @@ bool X64Backend::Initialize(Processor* processor) {
return false;
}
RegisterSequences();
// Need movbe to do advanced LOAD/STORE tricks.
if (FLAGS_enable_haswell_instructions) {
machine_info_.supports_extended_load_store =
@ -406,6 +413,117 @@ HostToGuestThunk X64ThunkEmitter::EmitHostToGuestThunk() {
mov(qword[rsp + 8 * 1], rcx);
sub(rsp, stack_size);
// Save nonvolatile registers.
EmitSaveNonvolatileRegs();
mov(rax, rcx);
mov(rsi, rdx); // context
mov(rcx, r8); // return address
call(rax);
EmitLoadNonvolatileRegs();
add(rsp, stack_size);
mov(rcx, qword[rsp + 8 * 1]);
mov(rdx, qword[rsp + 8 * 2]);
mov(r8, qword[rsp + 8 * 3]);
ret();
void* fn = Emplace(stack_size);
return (HostToGuestThunk)fn;
}
GuestToHostThunk X64ThunkEmitter::EmitGuestToHostThunk() {
// rcx = target function
// rdx = arg0
// r8 = arg1
// r9 = arg2
const size_t stack_size = StackLayout::THUNK_STACK_SIZE;
// rsp + 0 = return address
sub(rsp, stack_size);
// Save off volatile registers.
EmitSaveVolatileRegs();
mov(rax, rcx); // function
mov(rcx, GetContextReg()); // context
call(rax);
EmitLoadVolatileRegs();
add(rsp, stack_size);
ret();
void* fn = Emplace(stack_size);
return (GuestToHostThunk)fn;
}
// X64Emitter handles actually resolving functions.
extern "C" uint64_t ResolveFunction(void* raw_context, uint32_t target_address);
ResolveFunctionThunk X64ThunkEmitter::EmitResolveFunctionThunk() {
// ebx = target PPC address
// rcx = context
const size_t stack_size = StackLayout::THUNK_STACK_SIZE;
// rsp + 0 = return address
sub(rsp, stack_size);
// Save volatile registers
EmitSaveVolatileRegs();
mov(rcx, rsi); // context
mov(rdx, rbx);
mov(rax, uint64_t(&ResolveFunction));
call(rax);
EmitLoadVolatileRegs();
add(rsp, stack_size);
jmp(rax);
void* fn = Emplace(stack_size);
return (ResolveFunctionThunk)fn;
}
void X64ThunkEmitter::EmitSaveVolatileRegs() {
// Save off volatile registers.
// mov(qword[rsp + offsetof(StackLayout::Thunk, r[0])], rax);
mov(qword[rsp + offsetof(StackLayout::Thunk, r[1])], rcx);
mov(qword[rsp + offsetof(StackLayout::Thunk, r[2])], rdx);
mov(qword[rsp + offsetof(StackLayout::Thunk, r[3])], r8);
mov(qword[rsp + offsetof(StackLayout::Thunk, r[4])], r9);
mov(qword[rsp + offsetof(StackLayout::Thunk, r[5])], r10);
mov(qword[rsp + offsetof(StackLayout::Thunk, r[6])], r11);
// movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[0])], xmm0);
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[1])], xmm1);
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[2])], xmm2);
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[3])], xmm3);
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[4])], xmm4);
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[5])], xmm5);
}
void X64ThunkEmitter::EmitLoadVolatileRegs() {
// Load volatile registers from our stack frame.
// movaps(xmm0, qword[rsp + offsetof(StackLayout::Thunk, xmm[0])]);
movaps(xmm1, qword[rsp + offsetof(StackLayout::Thunk, xmm[1])]);
movaps(xmm2, qword[rsp + offsetof(StackLayout::Thunk, xmm[2])]);
movaps(xmm3, qword[rsp + offsetof(StackLayout::Thunk, xmm[3])]);
movaps(xmm4, qword[rsp + offsetof(StackLayout::Thunk, xmm[4])]);
movaps(xmm5, qword[rsp + offsetof(StackLayout::Thunk, xmm[5])]);
// mov(rax, qword[rsp + offsetof(StackLayout::Thunk, r[0])]);
mov(rcx, qword[rsp + offsetof(StackLayout::Thunk, r[1])]);
mov(rdx, qword[rsp + offsetof(StackLayout::Thunk, r[2])]);
mov(r8, qword[rsp + offsetof(StackLayout::Thunk, r[3])]);
mov(r9, qword[rsp + offsetof(StackLayout::Thunk, r[4])]);
mov(r10, qword[rsp + offsetof(StackLayout::Thunk, r[5])]);
mov(r11, qword[rsp + offsetof(StackLayout::Thunk, r[6])]);
}
void X64ThunkEmitter::EmitSaveNonvolatileRegs() {
// Preserve nonvolatile registers.
mov(qword[rsp + offsetof(StackLayout::Thunk, r[0])], rbx);
mov(qword[rsp + offsetof(StackLayout::Thunk, r[1])], rcx);
@ -427,12 +545,9 @@ HostToGuestThunk X64ThunkEmitter::EmitHostToGuestThunk() {
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[7])], xmm13);
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[8])], xmm14);
movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[9])], xmm15);
}
mov(rax, rcx);
mov(rsi, rdx); // context
mov(rcx, r8); // return address
call(rax);
void X64ThunkEmitter::EmitLoadNonvolatileRegs() {
movaps(xmm6, qword[rsp + offsetof(StackLayout::Thunk, xmm[0])]);
movaps(xmm7, qword[rsp + offsetof(StackLayout::Thunk, xmm[1])]);
movaps(xmm8, qword[rsp + offsetof(StackLayout::Thunk, xmm[2])]);
@ -453,100 +568,6 @@ HostToGuestThunk X64ThunkEmitter::EmitHostToGuestThunk() {
mov(r13, qword[rsp + offsetof(StackLayout::Thunk, r[6])]);
mov(r14, qword[rsp + offsetof(StackLayout::Thunk, r[7])]);
mov(r15, qword[rsp + offsetof(StackLayout::Thunk, r[8])]);
add(rsp, stack_size);
mov(rcx, qword[rsp + 8 * 1]);
mov(rdx, qword[rsp + 8 * 2]);
mov(r8, qword[rsp + 8 * 3]);
ret();
void* fn = Emplace(stack_size);
return (HostToGuestThunk)fn;
}
GuestToHostThunk X64ThunkEmitter::EmitGuestToHostThunk() {
// rcx = context
// rdx = target function
// r8 = arg0
// r9 = arg1
// r10 = arg2
const size_t stack_size = StackLayout::THUNK_STACK_SIZE;
// rsp + 0 = return address
mov(qword[rsp + 8 * 2], rdx);
mov(qword[rsp + 8 * 1], rcx);
sub(rsp, stack_size);
// Save off volatile registers.
// TODO(DrChat): Enable this when we actually need this.
// mov(qword[rsp + offsetof(StackLayout::Thunk, r[0])], rcx);
// mov(qword[rsp + offsetof(StackLayout::Thunk, r[1])], rdx);
// mov(qword[rsp + offsetof(StackLayout::Thunk, r[2])], r8);
// mov(qword[rsp + offsetof(StackLayout::Thunk, r[3])], r9);
// mov(qword[rsp + offsetof(StackLayout::Thunk, r[4])], r10);
// mov(qword[rsp + offsetof(StackLayout::Thunk, r[5])], r11);
// movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[1])], xmm1);
// movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[2])], xmm2);
// movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[3])], xmm3);
// movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[4])], xmm4);
// movaps(qword[rsp + offsetof(StackLayout::Thunk, xmm[5])], xmm5);
mov(rax, rdx);
mov(rcx, rsi); // context
mov(rdx, r8);
mov(r8, r9);
mov(r9, r10);
call(rax);
// movaps(xmm1, qword[rsp + offsetof(StackLayout::Thunk, xmm[1])]);
// movaps(xmm2, qword[rsp + offsetof(StackLayout::Thunk, xmm[2])]);
// movaps(xmm3, qword[rsp + offsetof(StackLayout::Thunk, xmm[3])]);
// movaps(xmm4, qword[rsp + offsetof(StackLayout::Thunk, xmm[4])]);
// movaps(xmm5, qword[rsp + offsetof(StackLayout::Thunk, xmm[5])]);
// mov(rcx, qword[rsp + offsetof(StackLayout::Thunk, r[0])]);
// mov(rdx, qword[rsp + offsetof(StackLayout::Thunk, r[1])]);
// mov(r8, qword[rsp + offsetof(StackLayout::Thunk, r[2])]);
// mov(r9, qword[rsp + offsetof(StackLayout::Thunk, r[3])]);
// mov(r10, qword[rsp + offsetof(StackLayout::Thunk, r[4])]);
// mov(r11, qword[rsp + offsetof(StackLayout::Thunk, r[5])]);
add(rsp, stack_size);
mov(rcx, qword[rsp + 8 * 1]);
mov(rdx, qword[rsp + 8 * 2]);
ret();
void* fn = Emplace(stack_size);
return (GuestToHostThunk)fn;
}
// X64Emitter handles actually resolving functions.
extern "C" uint64_t ResolveFunction(void* raw_context, uint32_t target_address);
ResolveFunctionThunk X64ThunkEmitter::EmitResolveFunctionThunk() {
// ebx = target PPC address
// rcx = context
uint32_t stack_size = 0x18;
// rsp + 0 = return address
mov(qword[rsp + 8 * 2], rdx);
mov(qword[rsp + 8 * 1], rcx);
sub(rsp, stack_size);
mov(rcx, rsi); // context
mov(rdx, rbx);
mov(rax, uint64_t(&ResolveFunction));
call(rax);
add(rsp, stack_size);
mov(rcx, qword[rsp + 8 * 1]);
mov(rdx, qword[rsp + 8 * 2]);
jmp(rax);
void* fn = Emplace(stack_size);
return (ResolveFunctionThunk)fn;
}
} // namespace x64

View File

@ -174,15 +174,17 @@ void* X64CodeCache::PlaceGuestCode(uint32_t guest_address, void* machine_code,
// If we are going above the high water mark of committed memory, commit
// some more. It's ok if multiple threads do this, as redundant commits
// aren't harmful.
size_t old_commit_mark = generated_code_commit_mark_;
if (high_mark > old_commit_mark) {
size_t new_commit_mark = old_commit_mark + 16 * 1024 * 1024;
size_t old_commit_mark, new_commit_mark;
do {
old_commit_mark = generated_code_commit_mark_;
if (high_mark <= old_commit_mark) break;
new_commit_mark = old_commit_mark + 16 * 1024 * 1024;
xe::memory::AllocFixed(generated_code_base_, new_commit_mark,
xe::memory::AllocationType::kCommit,
xe::memory::PageAccess::kExecuteReadWrite);
generated_code_commit_mark_.compare_exchange_strong(old_commit_mark,
new_commit_mark);
}
} while (generated_code_commit_mark_.compare_exchange_weak(
old_commit_mark, new_commit_mark));
// Copy code.
std::memcpy(code_address, machine_code, code_size);
@ -248,15 +250,17 @@ uint32_t X64CodeCache::PlaceData(const void* data, size_t length) {
// If we are going above the high water mark of committed memory, commit some
// more. It's ok if multiple threads do this, as redundant commits aren't
// harmful.
size_t old_commit_mark = generated_code_commit_mark_;
if (high_mark > old_commit_mark) {
size_t new_commit_mark = old_commit_mark + 16 * 1024 * 1024;
size_t old_commit_mark, new_commit_mark;
do {
old_commit_mark = generated_code_commit_mark_;
if (high_mark <= old_commit_mark) break;
new_commit_mark = old_commit_mark + 16 * 1024 * 1024;
xe::memory::AllocFixed(generated_code_base_, new_commit_mark,
xe::memory::AllocationType::kCommit,
xe::memory::PageAccess::kExecuteReadWrite);
generated_code_commit_mark_.compare_exchange_strong(old_commit_mark,
new_commit_mark);
}
} while (generated_code_commit_mark_.compare_exchange_weak(old_commit_mark,
new_commit_mark));
// Copy code.
std::memcpy(data_address, data, length);

View File

@ -56,12 +56,13 @@ static const size_t kStashOffset = 32;
// static const size_t kStashOffsetHigh = 32 + 32;
const uint32_t X64Emitter::gpr_reg_map_[X64Emitter::GPR_COUNT] = {
Xbyak::Operand::RBX, Xbyak::Operand::R12, Xbyak::Operand::R13,
Xbyak::Operand::R14, Xbyak::Operand::R15,
Xbyak::Operand::RBX, Xbyak::Operand::R10, Xbyak::Operand::R11,
Xbyak::Operand::R12, Xbyak::Operand::R13, Xbyak::Operand::R14,
Xbyak::Operand::R15,
};
const uint32_t X64Emitter::xmm_reg_map_[X64Emitter::XMM_COUNT] = {
6, 7, 8, 9, 10, 11, 12, 13, 14, 15,
4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15,
};
X64Emitter::X64Emitter(X64Backend* backend, XbyakAllocator* allocator)
@ -148,11 +149,13 @@ bool X64Emitter::Emit(HIRBuilder* builder, size_t* out_stack_size) {
for (auto it = locals.begin(); it != locals.end(); ++it) {
auto slot = *it;
size_t type_size = GetTypeSize(slot->type);
// Align to natural size.
stack_offset = xe::align(stack_offset, type_size);
slot->set_constant((uint32_t)stack_offset);
stack_offset += type_size;
}
// Ensure 16b alignment.
stack_offset -= StackLayout::GUEST_STACK_SIZE;
stack_offset = xe::align(stack_offset, static_cast<size_t>(16));
@ -160,7 +163,7 @@ bool X64Emitter::Emit(HIRBuilder* builder, size_t* out_stack_size) {
// Function prolog.
// Must be 16b aligned.
// Windows is very strict about the form of this and the epilog:
// https://msdn.microsoft.com/en-us/library/tawsa7cb.aspx
// https://docs.microsoft.com/en-us/cpp/build/prolog-and-epilog?view=vs-2017
// IMPORTANT: any changes to the prolog must be kept in sync with
// X64CodeCache, which dynamically generates exception information.
// Adding or changing anything here must be matched!
@ -168,6 +171,7 @@ bool X64Emitter::Emit(HIRBuilder* builder, size_t* out_stack_size) {
assert_true((stack_size + 8) % 16 == 0);
*out_stack_size = stack_size;
stack_size_ = stack_size;
sub(rsp, (uint32_t)stack_size);
mov(qword[rsp + StackLayout::GUEST_CTX_HOME], GetContextReg());
mov(qword[rsp + StackLayout::GUEST_RET_ADDR], rcx);
@ -221,6 +225,8 @@ bool X64Emitter::Emit(HIRBuilder* builder, size_t* out_stack_size) {
const Instr* new_tail = instr;
if (!SelectSequence(this, instr, &new_tail)) {
// No sequence found!
// NOTE: If you encounter this after adding a new instruction, do a full
// rebuild!
assert_always();
XELOGE("Unable to process HIR opcode %s", instr->opcode->name);
break;
@ -340,13 +346,14 @@ void X64Emitter::UnimplementedInstr(const hir::Instr* i) {
// This is used by the X64ThunkEmitter's ResolveFunctionThunk.
extern "C" uint64_t ResolveFunction(void* raw_context,
uint32_t target_address) {
uint64_t target_address) {
auto thread_state = *reinterpret_cast<ThreadState**>(raw_context);
// TODO(benvanik): required?
assert_not_zero(target_address);
auto fn = thread_state->processor()->ResolveFunction(target_address);
auto fn =
thread_state->processor()->ResolveFunction((uint32_t)target_address);
assert_not_null(fn);
auto x64_fn = static_cast<X64Function*>(fn);
uint64_t addr = reinterpret_cast<uint64_t>(x64_fn->machine_code());
@ -373,10 +380,7 @@ void X64Emitter::Call(const hir::Instr* instr, GuestFunction* function) {
// Old-style resolve.
// Not too important because indirection table is almost always available.
// TODO: Overwrite the call-site with a straight call.
mov(rax, reinterpret_cast<uint64_t>(ResolveFunction));
mov(rcx, GetContextReg());
mov(rdx, function->address());
call(rax);
CallNative(&ResolveFunction, function->address());
}
// Actually jump/call to rax.
@ -457,16 +461,15 @@ void X64Emitter::CallExtern(const hir::Instr* instr, const Function* function) {
auto builtin_function = static_cast<const BuiltinFunction*>(function);
if (builtin_function->handler()) {
undefined = false;
// rcx = context
// rdx = target host function
// r8 = arg0
// r9 = arg1
mov(rcx, GetContextReg());
mov(rdx, reinterpret_cast<uint64_t>(builtin_function->handler()));
mov(r8, reinterpret_cast<uint64_t>(builtin_function->arg0()));
mov(r9, reinterpret_cast<uint64_t>(builtin_function->arg1()));
// rcx = target function
// rdx = arg0
// r8 = arg1
// r9 = arg2
auto thunk = backend()->guest_to_host_thunk();
mov(rax, reinterpret_cast<uint64_t>(thunk));
mov(rcx, reinterpret_cast<uint64_t>(builtin_function->handler()));
mov(rdx, reinterpret_cast<uint64_t>(builtin_function->arg0()));
mov(r8, reinterpret_cast<uint64_t>(builtin_function->arg1()));
call(rax);
// rax = host return
}
@ -474,13 +477,15 @@ void X64Emitter::CallExtern(const hir::Instr* instr, const Function* function) {
auto extern_function = static_cast<const GuestFunction*>(function);
if (extern_function->extern_handler()) {
undefined = false;
// rcx = context
// rdx = target host function
mov(rcx, GetContextReg());
mov(rdx, reinterpret_cast<uint64_t>(extern_function->extern_handler()));
mov(r8, qword[GetContextReg() + offsetof(ppc::PPCContext, kernel_state)]);
// rcx = target function
// rdx = arg0
// r8 = arg1
// r9 = arg2
auto thunk = backend()->guest_to_host_thunk();
mov(rax, reinterpret_cast<uint64_t>(thunk));
mov(rcx, reinterpret_cast<uint64_t>(extern_function->extern_handler()));
mov(rdx,
qword[GetContextReg() + offsetof(ppc::PPCContext, kernel_state)]);
call(rax);
// rax = host return
}
@ -490,42 +495,30 @@ void X64Emitter::CallExtern(const hir::Instr* instr, const Function* function) {
}
}
void X64Emitter::CallNative(void* fn) {
mov(rax, reinterpret_cast<uint64_t>(fn));
mov(rcx, GetContextReg());
call(rax);
}
void X64Emitter::CallNative(void* fn) { CallNativeSafe(fn); }
void X64Emitter::CallNative(uint64_t (*fn)(void* raw_context)) {
mov(rax, reinterpret_cast<uint64_t>(fn));
mov(rcx, GetContextReg());
call(rax);
CallNativeSafe(reinterpret_cast<void*>(fn));
}
void X64Emitter::CallNative(uint64_t (*fn)(void* raw_context, uint64_t arg0)) {
mov(rax, reinterpret_cast<uint64_t>(fn));
mov(rcx, GetContextReg());
call(rax);
CallNativeSafe(reinterpret_cast<void*>(fn));
}
void X64Emitter::CallNative(uint64_t (*fn)(void* raw_context, uint64_t arg0),
uint64_t arg0) {
mov(rax, reinterpret_cast<uint64_t>(fn));
mov(rcx, GetContextReg());
mov(rdx, arg0);
call(rax);
mov(GetNativeParam(0), arg0);
CallNativeSafe(reinterpret_cast<void*>(fn));
}
void X64Emitter::CallNativeSafe(void* fn) {
// rcx = context
// rdx = target function
// r8 = arg0
// r9 = arg1
// r10 = arg2
// rcx = target function
// rdx = arg0
// r8 = arg1
// r9 = arg2
auto thunk = backend()->guest_to_host_thunk();
mov(rax, reinterpret_cast<uint64_t>(thunk));
mov(rcx, GetContextReg());
mov(rdx, reinterpret_cast<uint64_t>(fn));
mov(rcx, reinterpret_cast<uint64_t>(fn));
call(rax);
// rax = host return
}
@ -535,6 +528,18 @@ void X64Emitter::SetReturnAddress(uint64_t value) {
mov(qword[rsp + StackLayout::GUEST_CALL_RET_ADDR], rax);
}
Xbyak::Reg64 X64Emitter::GetNativeParam(uint32_t param) {
if (param == 0)
return rdx;
else if (param == 1)
return r8;
else if (param == 2)
return r9;
assert_always();
return r9;
}
// Important: If you change these, you must update the thunks in x64_backend.cc!
Xbyak::Reg64 X64Emitter::GetContextReg() { return rsi; }
Xbyak::Reg64 X64Emitter::GetMembaseReg() { return rdi; }

View File

@ -139,13 +139,13 @@ class X64Emitter : public Xbyak::CodeGenerator {
std::vector<SourceMapEntry>* out_source_map);
public:
// Reserved: rsp
// Reserved: rsp, rsi, rdi
// Scratch: rax/rcx/rdx
// xmm0-2
// Available: rbx, r12-r15 (save to get r8-r11, rbp, rsi, rdi?)
// xmm6-xmm15 (save to get xmm3-xmm5)
static const int GPR_COUNT = 5;
static const int XMM_COUNT = 10;
// Available: rbx, r10-r15
// xmm4-xmm15 (save to get xmm3)
static const int GPR_COUNT = 7;
static const int XMM_COUNT = 12;
static void SetupReg(const hir::Value* v, Xbyak::Reg8& r) {
auto idx = gpr_reg_map_[v->reg.index];
@ -187,6 +187,8 @@ class X64Emitter : public Xbyak::CodeGenerator {
void CallNativeSafe(void* fn);
void SetReturnAddress(uint64_t value);
Xbyak::Reg64 GetNativeParam(uint32_t param);
Xbyak::Reg64 GetContextReg();
Xbyak::Reg64 GetMembaseReg();
void ReloadContext();

View File

@ -0,0 +1,629 @@
/**
******************************************************************************
* Xenia : Xbox 360 Emulator Research Project *
******************************************************************************
* Copyright 2018 Xenia Developers. All rights reserved. *
* Released under the BSD license - see LICENSE in the root for more details. *
******************************************************************************
*/
#ifndef XENIA_CPU_BACKEND_X64_X64_OP_H_
#define XENIA_CPU_BACKEND_X64_X64_OP_H_
#include "xenia/cpu/backend/x64/x64_emitter.h"
#include "xenia/cpu/hir/instr.h"
namespace xe {
namespace cpu {
namespace backend {
namespace x64 {
// TODO(benvanik): direct usings.
using namespace xe::cpu;
using namespace xe::cpu::hir;
using namespace Xbyak;
// Selects the right byte/word/etc from a vector. We need to flip logical
// indices (0,1,2,3,4,5,6,7,...) = (3,2,1,0,7,6,5,4,...)
#define VEC128_B(n) ((n) ^ 0x3)
#define VEC128_W(n) ((n) ^ 0x1)
#define VEC128_D(n) (n)
#define VEC128_F(n) (n)
enum KeyType {
KEY_TYPE_X = OPCODE_SIG_TYPE_X,
KEY_TYPE_L = OPCODE_SIG_TYPE_L,
KEY_TYPE_O = OPCODE_SIG_TYPE_O,
KEY_TYPE_S = OPCODE_SIG_TYPE_S,
KEY_TYPE_V_I8 = OPCODE_SIG_TYPE_V + INT8_TYPE,
KEY_TYPE_V_I16 = OPCODE_SIG_TYPE_V + INT16_TYPE,
KEY_TYPE_V_I32 = OPCODE_SIG_TYPE_V + INT32_TYPE,
KEY_TYPE_V_I64 = OPCODE_SIG_TYPE_V + INT64_TYPE,
KEY_TYPE_V_F32 = OPCODE_SIG_TYPE_V + FLOAT32_TYPE,
KEY_TYPE_V_F64 = OPCODE_SIG_TYPE_V + FLOAT64_TYPE,
KEY_TYPE_V_V128 = OPCODE_SIG_TYPE_V + VEC128_TYPE,
};
#pragma pack(push, 1)
union InstrKey {
struct {
uint32_t opcode : 8;
uint32_t dest : 5;
uint32_t src1 : 5;
uint32_t src2 : 5;
uint32_t src3 : 5;
uint32_t reserved : 4;
};
uint32_t value;
operator uint32_t() const { return value; }
InstrKey() : value(0) {}
InstrKey(uint32_t v) : value(v) {}
InstrKey(const Instr* i) : value(0) {
opcode = i->opcode->num;
uint32_t sig = i->opcode->signature;
dest =
GET_OPCODE_SIG_TYPE_DEST(sig) ? OPCODE_SIG_TYPE_V + i->dest->type : 0;
src1 = GET_OPCODE_SIG_TYPE_SRC1(sig);
if (src1 == OPCODE_SIG_TYPE_V) {
src1 += i->src1.value->type;
}
src2 = GET_OPCODE_SIG_TYPE_SRC2(sig);
if (src2 == OPCODE_SIG_TYPE_V) {
src2 += i->src2.value->type;
}
src3 = GET_OPCODE_SIG_TYPE_SRC3(sig);
if (src3 == OPCODE_SIG_TYPE_V) {
src3 += i->src3.value->type;
}
}
template <Opcode OPCODE, KeyType DEST = KEY_TYPE_X, KeyType SRC1 = KEY_TYPE_X,
KeyType SRC2 = KEY_TYPE_X, KeyType SRC3 = KEY_TYPE_X>
struct Construct {
static const uint32_t value =
(OPCODE) | (DEST << 8) | (SRC1 << 13) | (SRC2 << 18) | (SRC3 << 23);
};
};
#pragma pack(pop)
static_assert(sizeof(InstrKey) <= 4, "Key must be 4 bytes");
template <typename... Ts>
struct CombinedStruct;
template <>
struct CombinedStruct<> {};
template <typename T, typename... Ts>
struct CombinedStruct<T, Ts...> : T, CombinedStruct<Ts...> {};
struct OpBase {};
template <typename T, KeyType KEY_TYPE>
struct Op : OpBase {
static const KeyType key_type = KEY_TYPE;
};
struct VoidOp : Op<VoidOp, KEY_TYPE_X> {
protected:
template <typename T, KeyType KEY_TYPE>
friend struct Op;
template <hir::Opcode OPCODE, typename... Ts>
friend struct I;
void Load(const Instr::Op& op) {}
};
struct OffsetOp : Op<OffsetOp, KEY_TYPE_O> {
uint64_t value;
protected:
template <typename T, KeyType KEY_TYPE>
friend struct Op;
template <hir::Opcode OPCODE, typename... Ts>
friend struct I;
void Load(const Instr::Op& op) { this->value = op.offset; }
};
struct SymbolOp : Op<SymbolOp, KEY_TYPE_S> {
Function* value;
protected:
template <typename T, KeyType KEY_TYPE>
friend struct Op;
template <hir::Opcode OPCODE, typename... Ts>
friend struct I;
bool Load(const Instr::Op& op) {
this->value = op.symbol;
return true;
}
};
struct LabelOp : Op<LabelOp, KEY_TYPE_L> {
hir::Label* value;
protected:
template <typename T, KeyType KEY_TYPE>
friend struct Op;
template <hir::Opcode OPCODE, typename... Ts>
friend struct I;
void Load(const Instr::Op& op) { this->value = op.label; }
};
template <typename T, KeyType KEY_TYPE, typename REG_TYPE, typename CONST_TYPE>
struct ValueOp : Op<ValueOp<T, KEY_TYPE, REG_TYPE, CONST_TYPE>, KEY_TYPE> {
typedef REG_TYPE reg_type;
const Value* value;
bool is_constant;
virtual bool ConstantFitsIn32Reg() const { return true; }
const REG_TYPE& reg() const {
assert_true(!is_constant);
return reg_;
}
operator const REG_TYPE&() const { return reg(); }
bool IsEqual(const T& b) const {
if (is_constant && b.is_constant) {
return reinterpret_cast<const T*>(this)->constant() == b.constant();
} else if (!is_constant && !b.is_constant) {
return reg_.getIdx() == b.reg_.getIdx();
} else {
return false;
}
}
bool IsEqual(const Xbyak::Reg& b) const {
if (is_constant) {
return false;
} else if (!is_constant) {
return reg_.getIdx() == b.getIdx();
} else {
return false;
}
}
bool operator==(const T& b) const { return IsEqual(b); }
bool operator!=(const T& b) const { return !IsEqual(b); }
bool operator==(const Xbyak::Reg& b) const { return IsEqual(b); }
bool operator!=(const Xbyak::Reg& b) const { return !IsEqual(b); }
void Load(const Instr::Op& op) {
value = op.value;
is_constant = value->IsConstant();
if (!is_constant) {
X64Emitter::SetupReg(value, reg_);
}
}
protected:
REG_TYPE reg_;
};
struct I8Op : ValueOp<I8Op, KEY_TYPE_V_I8, Reg8, int8_t> {
typedef ValueOp<I8Op, KEY_TYPE_V_I8, Reg8, int8_t> BASE;
const int8_t constant() const {
assert_true(BASE::is_constant);
return BASE::value->constant.i8;
}
};
struct I16Op : ValueOp<I16Op, KEY_TYPE_V_I16, Reg16, int16_t> {
typedef ValueOp<I16Op, KEY_TYPE_V_I16, Reg16, int16_t> BASE;
const int16_t constant() const {
assert_true(BASE::is_constant);
return BASE::value->constant.i16;
}
};
struct I32Op : ValueOp<I32Op, KEY_TYPE_V_I32, Reg32, int32_t> {
typedef ValueOp<I32Op, KEY_TYPE_V_I32, Reg32, int32_t> BASE;
const int32_t constant() const {
assert_true(BASE::is_constant);
return BASE::value->constant.i32;
}
};
struct I64Op : ValueOp<I64Op, KEY_TYPE_V_I64, Reg64, int64_t> {
typedef ValueOp<I64Op, KEY_TYPE_V_I64, Reg64, int64_t> BASE;
const int64_t constant() const {
assert_true(BASE::is_constant);
return BASE::value->constant.i64;
}
bool ConstantFitsIn32Reg() const override {
int64_t v = BASE::value->constant.i64;
if ((v & ~0x7FFFFFFF) == 0) {
// Fits under 31 bits, so just load using normal mov.
return true;
} else if ((v & ~0x7FFFFFFF) == ~0x7FFFFFFF) {
// Negative number that fits in 32bits.
return true;
}
return false;
}
};
struct F32Op : ValueOp<F32Op, KEY_TYPE_V_F32, Xmm, float> {
typedef ValueOp<F32Op, KEY_TYPE_V_F32, Xmm, float> BASE;
const float constant() const {
assert_true(BASE::is_constant);
return BASE::value->constant.f32;
}
};
struct F64Op : ValueOp<F64Op, KEY_TYPE_V_F64, Xmm, double> {
typedef ValueOp<F64Op, KEY_TYPE_V_F64, Xmm, double> BASE;
const double constant() const {
assert_true(BASE::is_constant);
return BASE::value->constant.f64;
}
};
struct V128Op : ValueOp<V128Op, KEY_TYPE_V_V128, Xmm, vec128_t> {
typedef ValueOp<V128Op, KEY_TYPE_V_V128, Xmm, vec128_t> BASE;
const vec128_t& constant() const {
assert_true(BASE::is_constant);
return BASE::value->constant.v128;
}
};
template <typename DEST, typename... Tf>
struct DestField;
template <typename DEST>
struct DestField<DEST> {
DEST dest;
protected:
bool LoadDest(const Instr* i) {
Instr::Op op;
op.value = i->dest;
dest.Load(op);
return true;
}
};
template <>
struct DestField<VoidOp> {
protected:
bool LoadDest(const Instr* i) { return true; }
};
template <hir::Opcode OPCODE, typename... Ts>
struct I;
template <hir::Opcode OPCODE, typename DEST>
struct I<OPCODE, DEST> : DestField<DEST> {
typedef DestField<DEST> BASE;
static const hir::Opcode opcode = OPCODE;
static const uint32_t key =
InstrKey::Construct<OPCODE, DEST::key_type>::value;
static const KeyType dest_type = DEST::key_type;
const Instr* instr;
protected:
template <typename SEQ, typename T>
friend struct Sequence;
bool Load(const Instr* i) {
if (InstrKey(i).value == key && BASE::LoadDest(i)) {
instr = i;
return true;
}
return false;
}
};
template <hir::Opcode OPCODE, typename DEST, typename SRC1>
struct I<OPCODE, DEST, SRC1> : DestField<DEST> {
typedef DestField<DEST> BASE;
static const hir::Opcode opcode = OPCODE;
static const uint32_t key =
InstrKey::Construct<OPCODE, DEST::key_type, SRC1::key_type>::value;
static const KeyType dest_type = DEST::key_type;
static const KeyType src1_type = SRC1::key_type;
const Instr* instr;
SRC1 src1;
protected:
template <typename SEQ, typename T>
friend struct Sequence;
bool Load(const Instr* i) {
if (InstrKey(i).value == key && BASE::LoadDest(i)) {
instr = i;
src1.Load(i->src1);
return true;
}
return false;
}
};
template <hir::Opcode OPCODE, typename DEST, typename SRC1, typename SRC2>
struct I<OPCODE, DEST, SRC1, SRC2> : DestField<DEST> {
typedef DestField<DEST> BASE;
static const hir::Opcode opcode = OPCODE;
static const uint32_t key =
InstrKey::Construct<OPCODE, DEST::key_type, SRC1::key_type,
SRC2::key_type>::value;
static const KeyType dest_type = DEST::key_type;
static const KeyType src1_type = SRC1::key_type;
static const KeyType src2_type = SRC2::key_type;
const Instr* instr;
SRC1 src1;
SRC2 src2;
protected:
template <typename SEQ, typename T>
friend struct Sequence;
bool Load(const Instr* i) {
if (InstrKey(i).value == key && BASE::LoadDest(i)) {
instr = i;
src1.Load(i->src1);
src2.Load(i->src2);
return true;
}
return false;
}
};
template <hir::Opcode OPCODE, typename DEST, typename SRC1, typename SRC2,
typename SRC3>
struct I<OPCODE, DEST, SRC1, SRC2, SRC3> : DestField<DEST> {
typedef DestField<DEST> BASE;
static const hir::Opcode opcode = OPCODE;
static const uint32_t key =
InstrKey::Construct<OPCODE, DEST::key_type, SRC1::key_type,
SRC2::key_type, SRC3::key_type>::value;
static const KeyType dest_type = DEST::key_type;
static const KeyType src1_type = SRC1::key_type;
static const KeyType src2_type = SRC2::key_type;
static const KeyType src3_type = SRC3::key_type;
const Instr* instr;
SRC1 src1;
SRC2 src2;
SRC3 src3;
protected:
template <typename SEQ, typename T>
friend struct Sequence;
bool Load(const Instr* i) {
if (InstrKey(i).value == key && BASE::LoadDest(i)) {
instr = i;
src1.Load(i->src1);
src2.Load(i->src2);
src3.Load(i->src3);
return true;
}
return false;
}
};
template <typename T>
static const T GetTempReg(X64Emitter& e);
template <>
const Reg8 GetTempReg<Reg8>(X64Emitter& e) {
return e.al;
}
template <>
const Reg16 GetTempReg<Reg16>(X64Emitter& e) {
return e.ax;
}
template <>
const Reg32 GetTempReg<Reg32>(X64Emitter& e) {
return e.eax;
}
template <>
const Reg64 GetTempReg<Reg64>(X64Emitter& e) {
return e.rax;
}
template <typename SEQ, typename T>
struct Sequence {
typedef T EmitArgType;
static constexpr uint32_t head_key() { return T::key; }
static bool Select(X64Emitter& e, const Instr* i) {
T args;
if (!args.Load(i)) {
return false;
}
SEQ::Emit(e, args);
return true;
}
template <typename REG_FN>
static void EmitUnaryOp(X64Emitter& e, const EmitArgType& i,
const REG_FN& reg_fn) {
if (i.src1.is_constant) {
e.mov(i.dest, i.src1.constant());
reg_fn(e, i.dest);
} else {
if (i.dest != i.src1) {
e.mov(i.dest, i.src1);
}
reg_fn(e, i.dest);
}
}
template <typename REG_REG_FN, typename REG_CONST_FN>
static void EmitCommutativeBinaryOp(X64Emitter& e, const EmitArgType& i,
const REG_REG_FN& reg_reg_fn,
const REG_CONST_FN& reg_const_fn) {
if (i.src1.is_constant) {
if (i.src2.is_constant) {
// Both constants.
if (i.src1.ConstantFitsIn32Reg()) {
e.mov(i.dest, i.src2.constant());
reg_const_fn(e, i.dest, static_cast<int32_t>(i.src1.constant()));
} else if (i.src2.ConstantFitsIn32Reg()) {
e.mov(i.dest, i.src1.constant());
reg_const_fn(e, i.dest, static_cast<int32_t>(i.src2.constant()));
} else {
e.mov(i.dest, i.src1.constant());
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2.constant());
reg_reg_fn(e, i.dest, temp);
}
} else {
// src1 constant.
if (i.dest == i.src2) {
if (i.src1.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.dest, static_cast<int32_t>(i.src1.constant()));
} else {
auto temp = GetTempReg<typename decltype(i.src1)::reg_type>(e);
e.mov(temp, i.src1.constant());
reg_reg_fn(e, i.dest, temp);
}
} else {
e.mov(i.dest, i.src1.constant());
reg_reg_fn(e, i.dest, i.src2);
}
}
} else if (i.src2.is_constant) {
if (i.dest == i.src1) {
if (i.src2.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.dest, static_cast<int32_t>(i.src2.constant()));
} else {
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2.constant());
reg_reg_fn(e, i.dest, temp);
}
} else {
e.mov(i.dest, i.src2.constant());
reg_reg_fn(e, i.dest, i.src1);
}
} else {
if (i.dest == i.src1) {
reg_reg_fn(e, i.dest, i.src2);
} else if (i.dest == i.src2) {
reg_reg_fn(e, i.dest, i.src1);
} else {
e.mov(i.dest, i.src1);
reg_reg_fn(e, i.dest, i.src2);
}
}
}
template <typename REG_REG_FN, typename REG_CONST_FN>
static void EmitAssociativeBinaryOp(X64Emitter& e, const EmitArgType& i,
const REG_REG_FN& reg_reg_fn,
const REG_CONST_FN& reg_const_fn) {
if (i.src1.is_constant) {
assert_true(!i.src2.is_constant);
if (i.dest == i.src2) {
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2);
e.mov(i.dest, i.src1.constant());
reg_reg_fn(e, i.dest, temp);
} else {
e.mov(i.dest, i.src1.constant());
reg_reg_fn(e, i.dest, i.src2);
}
} else if (i.src2.is_constant) {
if (i.dest == i.src1) {
if (i.src2.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.dest, static_cast<int32_t>(i.src2.constant()));
} else {
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2.constant());
reg_reg_fn(e, i.dest, temp);
}
} else {
e.mov(i.dest, i.src1);
if (i.src2.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.dest, static_cast<int32_t>(i.src2.constant()));
} else {
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2.constant());
reg_reg_fn(e, i.dest, temp);
}
}
} else {
if (i.dest == i.src1) {
reg_reg_fn(e, i.dest, i.src2);
} else if (i.dest == i.src2) {
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2);
e.mov(i.dest, i.src1);
reg_reg_fn(e, i.dest, temp);
} else {
e.mov(i.dest, i.src1);
reg_reg_fn(e, i.dest, i.src2);
}
}
}
template <typename FN>
static void EmitCommutativeBinaryXmmOp(X64Emitter& e, const EmitArgType& i,
const FN& fn) {
if (i.src1.is_constant) {
assert_true(!i.src2.is_constant);
e.LoadConstantXmm(e.xmm0, i.src1.constant());
fn(e, i.dest, e.xmm0, i.src2);
} else if (i.src2.is_constant) {
assert_true(!i.src1.is_constant);
e.LoadConstantXmm(e.xmm0, i.src2.constant());
fn(e, i.dest, i.src1, e.xmm0);
} else {
fn(e, i.dest, i.src1, i.src2);
}
}
template <typename FN>
static void EmitAssociativeBinaryXmmOp(X64Emitter& e, const EmitArgType& i,
const FN& fn) {
if (i.src1.is_constant) {
assert_true(!i.src2.is_constant);
e.LoadConstantXmm(e.xmm0, i.src1.constant());
fn(e, i.dest, e.xmm0, i.src2);
} else if (i.src2.is_constant) {
assert_true(!i.src1.is_constant);
e.LoadConstantXmm(e.xmm0, i.src2.constant());
fn(e, i.dest, i.src1, e.xmm0);
} else {
fn(e, i.dest, i.src1, i.src2);
}
}
template <typename REG_REG_FN, typename REG_CONST_FN>
static void EmitCommutativeCompareOp(X64Emitter& e, const EmitArgType& i,
const REG_REG_FN& reg_reg_fn,
const REG_CONST_FN& reg_const_fn) {
if (i.src1.is_constant) {
assert_true(!i.src2.is_constant);
if (i.src1.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.src2, static_cast<int32_t>(i.src1.constant()));
} else {
auto temp = GetTempReg<typename decltype(i.src1)::reg_type>(e);
e.mov(temp, i.src1.constant());
reg_reg_fn(e, i.src2, temp);
}
} else if (i.src2.is_constant) {
assert_true(!i.src1.is_constant);
if (i.src2.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.src1, static_cast<int32_t>(i.src2.constant()));
} else {
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2.constant());
reg_reg_fn(e, i.src1, temp);
}
} else {
reg_reg_fn(e, i.src1, i.src2);
}
}
template <typename REG_REG_FN, typename REG_CONST_FN>
static void EmitAssociativeCompareOp(X64Emitter& e, const EmitArgType& i,
const REG_REG_FN& reg_reg_fn,
const REG_CONST_FN& reg_const_fn) {
if (i.src1.is_constant) {
assert_true(!i.src2.is_constant);
if (i.src1.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.dest, i.src2, static_cast<int32_t>(i.src1.constant()),
true);
} else {
auto temp = GetTempReg<typename decltype(i.src1)::reg_type>(e);
e.mov(temp, i.src1.constant());
reg_reg_fn(e, i.dest, i.src2, temp, true);
}
} else if (i.src2.is_constant) {
assert_true(!i.src1.is_constant);
if (i.src2.ConstantFitsIn32Reg()) {
reg_const_fn(e, i.dest, i.src1, static_cast<int32_t>(i.src2.constant()),
false);
} else {
auto temp = GetTempReg<typename decltype(i.src2)::reg_type>(e);
e.mov(temp, i.src2.constant());
reg_reg_fn(e, i.dest, i.src1, temp, false);
}
} else {
reg_reg_fn(e, i.dest, i.src1, i.src2, false);
}
}
};
} // namespace x64
} // namespace backend
} // namespace cpu
} // namespace xe
#endif // XENIA_CPU_BACKEND_X64_X64_OP_H_

View File

@ -0,0 +1,553 @@
/**
******************************************************************************
* Xenia : Xbox 360 Emulator Research Project *
******************************************************************************
* Copyright 2018 Xenia Developers. All rights reserved. *
* Released under the BSD license - see LICENSE in the root for more details. *
******************************************************************************
*/
#include "xenia/cpu/backend/x64/x64_sequences.h"
#include <algorithm>
#include <cstring>
#include "xenia/cpu/backend/x64/x64_op.h"
namespace xe {
namespace cpu {
namespace backend {
namespace x64 {
volatile int anchor_control = 0;
// ============================================================================
// OPCODE_DEBUG_BREAK
// ============================================================================
struct DEBUG_BREAK : Sequence<DEBUG_BREAK, I<OPCODE_DEBUG_BREAK, VoidOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) { e.DebugBreak(); }
};
EMITTER_OPCODE_TABLE(OPCODE_DEBUG_BREAK, DEBUG_BREAK);
// ============================================================================
// OPCODE_DEBUG_BREAK_TRUE
// ============================================================================
struct DEBUG_BREAK_TRUE_I8
: Sequence<DEBUG_BREAK_TRUE_I8, I<OPCODE_DEBUG_BREAK_TRUE, VoidOp, I8Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.DebugBreak();
e.L(skip);
}
};
struct DEBUG_BREAK_TRUE_I16
: Sequence<DEBUG_BREAK_TRUE_I16,
I<OPCODE_DEBUG_BREAK_TRUE, VoidOp, I16Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.DebugBreak();
e.L(skip);
}
};
struct DEBUG_BREAK_TRUE_I32
: Sequence<DEBUG_BREAK_TRUE_I32,
I<OPCODE_DEBUG_BREAK_TRUE, VoidOp, I32Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.DebugBreak();
e.L(skip);
}
};
struct DEBUG_BREAK_TRUE_I64
: Sequence<DEBUG_BREAK_TRUE_I64,
I<OPCODE_DEBUG_BREAK_TRUE, VoidOp, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.DebugBreak();
e.L(skip);
}
};
struct DEBUG_BREAK_TRUE_F32
: Sequence<DEBUG_BREAK_TRUE_F32,
I<OPCODE_DEBUG_BREAK_TRUE, VoidOp, F32Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.DebugBreak();
e.L(skip);
}
};
struct DEBUG_BREAK_TRUE_F64
: Sequence<DEBUG_BREAK_TRUE_F64,
I<OPCODE_DEBUG_BREAK_TRUE, VoidOp, F64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.DebugBreak();
e.L(skip);
}
};
EMITTER_OPCODE_TABLE(OPCODE_DEBUG_BREAK_TRUE, DEBUG_BREAK_TRUE_I8,
DEBUG_BREAK_TRUE_I16, DEBUG_BREAK_TRUE_I32,
DEBUG_BREAK_TRUE_I64, DEBUG_BREAK_TRUE_F32,
DEBUG_BREAK_TRUE_F64);
// ============================================================================
// OPCODE_TRAP
// ============================================================================
struct TRAP : Sequence<TRAP, I<OPCODE_TRAP, VoidOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.Trap(i.instr->flags);
}
};
EMITTER_OPCODE_TABLE(OPCODE_TRAP, TRAP);
// ============================================================================
// OPCODE_TRAP_TRUE
// ============================================================================
struct TRAP_TRUE_I8
: Sequence<TRAP_TRUE_I8, I<OPCODE_TRAP_TRUE, VoidOp, I8Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Trap(i.instr->flags);
e.L(skip);
}
};
struct TRAP_TRUE_I16
: Sequence<TRAP_TRUE_I16, I<OPCODE_TRAP_TRUE, VoidOp, I16Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Trap(i.instr->flags);
e.L(skip);
}
};
struct TRAP_TRUE_I32
: Sequence<TRAP_TRUE_I32, I<OPCODE_TRAP_TRUE, VoidOp, I32Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Trap(i.instr->flags);
e.L(skip);
}
};
struct TRAP_TRUE_I64
: Sequence<TRAP_TRUE_I64, I<OPCODE_TRAP_TRUE, VoidOp, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Trap(i.instr->flags);
e.L(skip);
}
};
struct TRAP_TRUE_F32
: Sequence<TRAP_TRUE_F32, I<OPCODE_TRAP_TRUE, VoidOp, F32Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Trap(i.instr->flags);
e.L(skip);
}
};
struct TRAP_TRUE_F64
: Sequence<TRAP_TRUE_F64, I<OPCODE_TRAP_TRUE, VoidOp, F64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Trap(i.instr->flags);
e.L(skip);
}
};
EMITTER_OPCODE_TABLE(OPCODE_TRAP_TRUE, TRAP_TRUE_I8, TRAP_TRUE_I16,
TRAP_TRUE_I32, TRAP_TRUE_I64, TRAP_TRUE_F32,
TRAP_TRUE_F64);
// ============================================================================
// OPCODE_CALL
// ============================================================================
struct CALL : Sequence<CALL, I<OPCODE_CALL, VoidOp, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
assert_true(i.src1.value->is_guest());
e.Call(i.instr, static_cast<GuestFunction*>(i.src1.value));
}
};
EMITTER_OPCODE_TABLE(OPCODE_CALL, CALL);
// ============================================================================
// OPCODE_CALL_TRUE
// ============================================================================
struct CALL_TRUE_I8
: Sequence<CALL_TRUE_I8, I<OPCODE_CALL_TRUE, VoidOp, I8Op, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
assert_true(i.src2.value->is_guest());
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Call(i.instr, static_cast<GuestFunction*>(i.src2.value));
e.L(skip);
}
};
struct CALL_TRUE_I16
: Sequence<CALL_TRUE_I16, I<OPCODE_CALL_TRUE, VoidOp, I16Op, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
assert_true(i.src2.value->is_guest());
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Call(i.instr, static_cast<GuestFunction*>(i.src2.value));
e.L(skip);
}
};
struct CALL_TRUE_I32
: Sequence<CALL_TRUE_I32, I<OPCODE_CALL_TRUE, VoidOp, I32Op, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
assert_true(i.src2.value->is_guest());
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Call(i.instr, static_cast<GuestFunction*>(i.src2.value));
e.L(skip);
}
};
struct CALL_TRUE_I64
: Sequence<CALL_TRUE_I64, I<OPCODE_CALL_TRUE, VoidOp, I64Op, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
assert_true(i.src2.value->is_guest());
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Call(i.instr, static_cast<GuestFunction*>(i.src2.value));
e.L(skip);
}
};
struct CALL_TRUE_F32
: Sequence<CALL_TRUE_F32, I<OPCODE_CALL_TRUE, VoidOp, F32Op, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
assert_true(i.src2.value->is_guest());
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Call(i.instr, static_cast<GuestFunction*>(i.src2.value));
e.L(skip);
}
};
struct CALL_TRUE_F64
: Sequence<CALL_TRUE_F64, I<OPCODE_CALL_TRUE, VoidOp, F64Op, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
assert_true(i.src2.value->is_guest());
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip);
e.Call(i.instr, static_cast<GuestFunction*>(i.src2.value));
e.L(skip);
}
};
EMITTER_OPCODE_TABLE(OPCODE_CALL_TRUE, CALL_TRUE_I8, CALL_TRUE_I16,
CALL_TRUE_I32, CALL_TRUE_I64, CALL_TRUE_F32,
CALL_TRUE_F64);
// ============================================================================
// OPCODE_CALL_INDIRECT
// ============================================================================
struct CALL_INDIRECT
: Sequence<CALL_INDIRECT, I<OPCODE_CALL_INDIRECT, VoidOp, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.CallIndirect(i.instr, i.src1);
}
};
EMITTER_OPCODE_TABLE(OPCODE_CALL_INDIRECT, CALL_INDIRECT);
// ============================================================================
// OPCODE_CALL_INDIRECT_TRUE
// ============================================================================
struct CALL_INDIRECT_TRUE_I8
: Sequence<CALL_INDIRECT_TRUE_I8,
I<OPCODE_CALL_INDIRECT_TRUE, VoidOp, I8Op, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip, CodeGenerator::T_NEAR);
e.CallIndirect(i.instr, i.src2);
e.L(skip);
}
};
struct CALL_INDIRECT_TRUE_I16
: Sequence<CALL_INDIRECT_TRUE_I16,
I<OPCODE_CALL_INDIRECT_TRUE, VoidOp, I16Op, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip, CodeGenerator::T_NEAR);
e.CallIndirect(i.instr, i.src2);
e.L(skip);
}
};
struct CALL_INDIRECT_TRUE_I32
: Sequence<CALL_INDIRECT_TRUE_I32,
I<OPCODE_CALL_INDIRECT_TRUE, VoidOp, I32Op, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip, CodeGenerator::T_NEAR);
e.CallIndirect(i.instr, i.src2);
e.L(skip);
}
};
struct CALL_INDIRECT_TRUE_I64
: Sequence<CALL_INDIRECT_TRUE_I64,
I<OPCODE_CALL_INDIRECT_TRUE, VoidOp, I64Op, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip, CodeGenerator::T_NEAR);
e.CallIndirect(i.instr, i.src2);
e.L(skip);
}
};
struct CALL_INDIRECT_TRUE_F32
: Sequence<CALL_INDIRECT_TRUE_F32,
I<OPCODE_CALL_INDIRECT_TRUE, VoidOp, F32Op, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip, CodeGenerator::T_NEAR);
e.CallIndirect(i.instr, i.src2);
e.L(skip);
}
};
struct CALL_INDIRECT_TRUE_F64
: Sequence<CALL_INDIRECT_TRUE_F64,
I<OPCODE_CALL_INDIRECT_TRUE, VoidOp, F64Op, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
Xbyak::Label skip;
e.jz(skip, CodeGenerator::T_NEAR);
e.CallIndirect(i.instr, i.src2);
e.L(skip);
}
};
EMITTER_OPCODE_TABLE(OPCODE_CALL_INDIRECT_TRUE, CALL_INDIRECT_TRUE_I8,
CALL_INDIRECT_TRUE_I16, CALL_INDIRECT_TRUE_I32,
CALL_INDIRECT_TRUE_I64, CALL_INDIRECT_TRUE_F32,
CALL_INDIRECT_TRUE_F64);
// ============================================================================
// OPCODE_CALL_EXTERN
// ============================================================================
struct CALL_EXTERN
: Sequence<CALL_EXTERN, I<OPCODE_CALL_EXTERN, VoidOp, SymbolOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.CallExtern(i.instr, i.src1.value);
}
};
EMITTER_OPCODE_TABLE(OPCODE_CALL_EXTERN, CALL_EXTERN);
// ============================================================================
// OPCODE_RETURN
// ============================================================================
struct RETURN : Sequence<RETURN, I<OPCODE_RETURN, VoidOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
// If this is the last instruction in the last block, just let us
// fall through.
if (i.instr->next || i.instr->block->next) {
e.jmp(e.epilog_label(), CodeGenerator::T_NEAR);
}
}
};
EMITTER_OPCODE_TABLE(OPCODE_RETURN, RETURN);
// ============================================================================
// OPCODE_RETURN_TRUE
// ============================================================================
struct RETURN_TRUE_I8
: Sequence<RETURN_TRUE_I8, I<OPCODE_RETURN_TRUE, VoidOp, I8Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(e.epilog_label(), CodeGenerator::T_NEAR);
}
};
struct RETURN_TRUE_I16
: Sequence<RETURN_TRUE_I16, I<OPCODE_RETURN_TRUE, VoidOp, I16Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(e.epilog_label(), CodeGenerator::T_NEAR);
}
};
struct RETURN_TRUE_I32
: Sequence<RETURN_TRUE_I32, I<OPCODE_RETURN_TRUE, VoidOp, I32Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(e.epilog_label(), CodeGenerator::T_NEAR);
}
};
struct RETURN_TRUE_I64
: Sequence<RETURN_TRUE_I64, I<OPCODE_RETURN_TRUE, VoidOp, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(e.epilog_label(), CodeGenerator::T_NEAR);
}
};
struct RETURN_TRUE_F32
: Sequence<RETURN_TRUE_F32, I<OPCODE_RETURN_TRUE, VoidOp, F32Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
e.jnz(e.epilog_label(), CodeGenerator::T_NEAR);
}
};
struct RETURN_TRUE_F64
: Sequence<RETURN_TRUE_F64, I<OPCODE_RETURN_TRUE, VoidOp, F64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
e.jnz(e.epilog_label(), CodeGenerator::T_NEAR);
}
};
EMITTER_OPCODE_TABLE(OPCODE_RETURN_TRUE, RETURN_TRUE_I8, RETURN_TRUE_I16,
RETURN_TRUE_I32, RETURN_TRUE_I64, RETURN_TRUE_F32,
RETURN_TRUE_F64);
// ============================================================================
// OPCODE_SET_RETURN_ADDRESS
// ============================================================================
struct SET_RETURN_ADDRESS
: Sequence<SET_RETURN_ADDRESS,
I<OPCODE_SET_RETURN_ADDRESS, VoidOp, I64Op>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.SetReturnAddress(i.src1.constant());
}
};
EMITTER_OPCODE_TABLE(OPCODE_SET_RETURN_ADDRESS, SET_RETURN_ADDRESS);
// ============================================================================
// OPCODE_BRANCH
// ============================================================================
struct BRANCH : Sequence<BRANCH, I<OPCODE_BRANCH, VoidOp, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.jmp(i.src1.value->name, e.T_NEAR);
}
};
EMITTER_OPCODE_TABLE(OPCODE_BRANCH, BRANCH);
// ============================================================================
// OPCODE_BRANCH_TRUE
// ============================================================================
struct BRANCH_TRUE_I8
: Sequence<BRANCH_TRUE_I8, I<OPCODE_BRANCH_TRUE, VoidOp, I8Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_TRUE_I16
: Sequence<BRANCH_TRUE_I16, I<OPCODE_BRANCH_TRUE, VoidOp, I16Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_TRUE_I32
: Sequence<BRANCH_TRUE_I32, I<OPCODE_BRANCH_TRUE, VoidOp, I32Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_TRUE_I64
: Sequence<BRANCH_TRUE_I64, I<OPCODE_BRANCH_TRUE, VoidOp, I64Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jnz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_TRUE_F32
: Sequence<BRANCH_TRUE_F32, I<OPCODE_BRANCH_TRUE, VoidOp, F32Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
e.jnz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_TRUE_F64
: Sequence<BRANCH_TRUE_F64, I<OPCODE_BRANCH_TRUE, VoidOp, F64Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
e.jnz(i.src2.value->name, e.T_NEAR);
}
};
EMITTER_OPCODE_TABLE(OPCODE_BRANCH_TRUE, BRANCH_TRUE_I8, BRANCH_TRUE_I16,
BRANCH_TRUE_I32, BRANCH_TRUE_I64, BRANCH_TRUE_F32,
BRANCH_TRUE_F64);
// ============================================================================
// OPCODE_BRANCH_FALSE
// ============================================================================
struct BRANCH_FALSE_I8
: Sequence<BRANCH_FALSE_I8, I<OPCODE_BRANCH_FALSE, VoidOp, I8Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_FALSE_I16
: Sequence<BRANCH_FALSE_I16,
I<OPCODE_BRANCH_FALSE, VoidOp, I16Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_FALSE_I32
: Sequence<BRANCH_FALSE_I32,
I<OPCODE_BRANCH_FALSE, VoidOp, I32Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_FALSE_I64
: Sequence<BRANCH_FALSE_I64,
I<OPCODE_BRANCH_FALSE, VoidOp, I64Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.test(i.src1, i.src1);
e.jz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_FALSE_F32
: Sequence<BRANCH_FALSE_F32,
I<OPCODE_BRANCH_FALSE, VoidOp, F32Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
e.jz(i.src2.value->name, e.T_NEAR);
}
};
struct BRANCH_FALSE_F64
: Sequence<BRANCH_FALSE_F64,
I<OPCODE_BRANCH_FALSE, VoidOp, F64Op, LabelOp>> {
static void Emit(X64Emitter& e, const EmitArgType& i) {
e.vptest(i.src1, i.src1);
e.jz(i.src2.value->name, e.T_NEAR);
}
};
EMITTER_OPCODE_TABLE(OPCODE_BRANCH_FALSE, BRANCH_FALSE_I8, BRANCH_FALSE_I16,
BRANCH_FALSE_I32, BRANCH_FALSE_I64, BRANCH_FALSE_F32,
BRANCH_FALSE_F64);
} // namespace x64
} // namespace backend
} // namespace cpu
} // namespace xe

File diff suppressed because it is too large Load Diff

File diff suppressed because it is too large Load Diff

File diff suppressed because it is too large Load Diff

View File

@ -12,6 +12,8 @@
#include "xenia/cpu/hir/instr.h"
#include <unordered_map>
namespace xe {
namespace cpu {
namespace backend {
@ -19,7 +21,25 @@ namespace x64 {
class X64Emitter;
void RegisterSequences();
typedef bool (*SequenceSelectFn)(X64Emitter&, const hir::Instr*);
extern std::unordered_map<uint32_t, SequenceSelectFn> sequence_table;
template <typename T>
bool Register() {
sequence_table.insert({T::head_key(), T::Select});
return true;
}
template <typename T, typename Tn, typename... Ts>
static bool Register() {
bool b = true;
b = b && Register<T>(); // Call the above function
b = b && Register<Tn, Ts...>(); // Call ourself again (recursively)
return b;
}
#define EMITTER_OPCODE_TABLE(name, ...) \
const auto X64_INSTR_##name = Register<__VA_ARGS__>();
bool SelectSequence(X64Emitter* e, const hir::Instr* i,
const hir::Instr** new_tail);

View File

@ -10,6 +10,8 @@
#ifndef XENIA_CPU_COMPILER_COMPILER_PASSES_H_
#define XENIA_CPU_COMPILER_COMPILER_PASSES_H_
#include "xenia/cpu/compiler/passes/conditional_group_pass.h"
#include "xenia/cpu/compiler/passes/conditional_group_subpass.h"
#include "xenia/cpu/compiler/passes/constant_propagation_pass.h"
#include "xenia/cpu/compiler/passes/context_promotion_pass.h"
#include "xenia/cpu/compiler/passes/control_flow_analysis_pass.h"

View File

@ -0,0 +1,85 @@
/**
******************************************************************************
* Xenia : Xbox 360 Emulator Research Project *
******************************************************************************
* Copyright 2013 Ben Vanik. All rights reserved. *
* Released under the BSD license - see LICENSE in the root for more details. *
******************************************************************************
*/
#include "xenia/cpu/compiler/passes/conditional_group_pass.h"
#include <gflags/gflags.h>
#include "xenia/base/profiling.h"
#include "xenia/cpu/compiler/compiler.h"
#include "xenia/cpu/ppc/ppc_context.h"
#include "xenia/cpu/processor.h"
namespace xe {
namespace cpu {
namespace compiler {
namespace passes {
// TODO(benvanik): remove when enums redefined.
using namespace xe::cpu::hir;
using xe::cpu::hir::Block;
using xe::cpu::hir::HIRBuilder;
using xe::cpu::hir::Instr;
using xe::cpu::hir::Value;
ConditionalGroupPass::ConditionalGroupPass() : CompilerPass() {}
ConditionalGroupPass::~ConditionalGroupPass() {}
bool ConditionalGroupPass::Initialize(Compiler* compiler) {
if (!CompilerPass::Initialize(compiler)) {
return false;
}
for (size_t i = 0; i < passes_.size(); ++i) {
auto& pass = passes_[i];
if (!pass->Initialize(compiler)) {
return false;
}
}
return true;
}
bool ConditionalGroupPass::Run(HIRBuilder* builder) {
bool dirty;
int loops = 0;
do {
assert_true(loops < 20); // arbitrary number
dirty = false;
for (size_t i = 0; i < passes_.size(); ++i) {
scratch_arena()->Reset();
auto& pass = passes_[i];
auto subpass = dynamic_cast<ConditionalGroupSubpass*>(pass.get());
if (!subpass) {
if (!pass->Run(builder)) {
return false;
}
} else {
bool result = false;
if (!subpass->Run(builder, result)) {
return false;
}
dirty |= result;
}
}
loops++;
} while (dirty);
return true;
}
void ConditionalGroupPass::AddPass(std::unique_ptr<CompilerPass> pass) {
passes_.push_back(std::move(pass));
}
} // namespace passes
} // namespace compiler
} // namespace cpu
} // namespace xe

View File

@ -0,0 +1,45 @@
/**
******************************************************************************
* Xenia : Xbox 360 Emulator Research Project *
******************************************************************************
* Copyright 2013 Ben Vanik. All rights reserved. *
* Released under the BSD license - see LICENSE in the root for more details. *
******************************************************************************
*/
#ifndef XENIA_CPU_COMPILER_PASSES_CONDITIONAL_GROUP_PASS_H_
#define XENIA_CPU_COMPILER_PASSES_CONDITIONAL_GROUP_PASS_H_
#include <cmath>
#include <vector>
#include "xenia/base/platform.h"
#include "xenia/cpu/compiler/compiler_pass.h"
#include "xenia/cpu/compiler/passes/conditional_group_subpass.h"
namespace xe {
namespace cpu {
namespace compiler {
namespace passes {
class ConditionalGroupPass : public CompilerPass {
public:
ConditionalGroupPass();
virtual ~ConditionalGroupPass() override;
bool Initialize(Compiler* compiler) override;
bool Run(hir::HIRBuilder* builder) override;
void AddPass(std::unique_ptr<CompilerPass> pass);
private:
std::vector<std::unique_ptr<CompilerPass>> passes_;
};
} // namespace passes
} // namespace compiler
} // namespace cpu
} // namespace xe
#endif // XENIA_CPU_COMPILER_PASSES_CONDITIONAL_GROUP_PASS_H_

View File

@ -0,0 +1,26 @@
/**
******************************************************************************
* Xenia : Xbox 360 Emulator Research Project *
******************************************************************************
* Copyright 2013 Ben Vanik. All rights reserved. *
* Released under the BSD license - see LICENSE in the root for more details. *
******************************************************************************
*/
#include "xenia/cpu/compiler/passes/conditional_group_subpass.h"
#include "xenia/cpu/compiler/compiler.h"
namespace xe {
namespace cpu {
namespace compiler {
namespace passes {
ConditionalGroupSubpass::ConditionalGroupSubpass() : CompilerPass() {}
ConditionalGroupSubpass::~ConditionalGroupSubpass() = default;
} // namespace passes
} // namespace compiler
} // namespace cpu
} // namespace xe

View File

@ -0,0 +1,47 @@
/**
******************************************************************************
* Xenia : Xbox 360 Emulator Research Project *
******************************************************************************
* Copyright 2013 Ben Vanik. All rights reserved. *
* Released under the BSD license - see LICENSE in the root for more details. *
******************************************************************************
*/
#ifndef XENIA_CPU_COMPILER_PASSES_CONDITIONAL_GROUP_SUBPASS_H_
#define XENIA_CPU_COMPILER_PASSES_CONDITIONAL_GROUP_SUBPASS_H_
#include "xenia/base/arena.h"
#include "xenia/cpu/compiler/compiler_pass.h"
#include "xenia/cpu/hir/hir_builder.h"
namespace xe {
namespace cpu {
class Processor;
} // namespace cpu
} // namespace xe
namespace xe {
namespace cpu {
namespace compiler {
class Compiler;
namespace passes {
class ConditionalGroupSubpass : public CompilerPass {
public:
ConditionalGroupSubpass();
virtual ~ConditionalGroupSubpass();
bool Run(hir::HIRBuilder* builder) override {
bool dummy;
return Run(builder, dummy);
}
virtual bool Run(hir::HIRBuilder* builder, bool& result) = 0;
};
} // namespace passes
} // namespace compiler
} // namespace cpu
} // namespace xe
#endif // XENIA_CPU_COMPILER_PASSES_CONDITIONAL_GROUP_SUBPASS_H_

View File

@ -31,11 +31,12 @@ using xe::cpu::hir::HIRBuilder;
using xe::cpu::hir::TypeName;
using xe::cpu::hir::Value;
ConstantPropagationPass::ConstantPropagationPass() : CompilerPass() {}
ConstantPropagationPass::ConstantPropagationPass()
: ConditionalGroupSubpass() {}
ConstantPropagationPass::~ConstantPropagationPass() {}
bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool ConstantPropagationPass::Run(HIRBuilder* builder, bool& result) {
// Once ContextPromotion has run there will likely be a whole slew of
// constants that can be pushed through the function.
// Example:
@ -63,6 +64,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
// v1 = 19
// v2 = 0
result = false;
auto block = builder->first_block();
while (block) {
auto i = block->instr_head;
@ -76,6 +78,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
} else {
i->Remove();
}
result = true;
}
break;
@ -86,6 +89,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
} else {
i->Remove();
}
result = true;
}
break;
@ -98,6 +102,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
} else {
i->Remove();
}
result = true;
}
break;
case OPCODE_CALL_INDIRECT:
@ -109,6 +114,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
}
i->Replace(&OPCODE_CALL_info, i->flags);
i->src1.symbol = function;
result = true;
}
break;
case OPCODE_CALL_INDIRECT_TRUE:
@ -120,6 +126,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
} else {
i->Remove();
}
result = true;
}
break;
@ -132,6 +139,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
} else {
i->Remove();
}
result = true;
}
break;
case OPCODE_BRANCH_FALSE:
@ -143,6 +151,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
} else {
i->Remove();
}
result = true;
}
break;
@ -152,6 +161,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Cast(target_type);
i->Remove();
result = true;
}
break;
case OPCODE_CONVERT:
@ -160,6 +170,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Convert(target_type, RoundMode(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_ROUND:
@ -167,6 +178,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Round(RoundMode(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_ZERO_EXTEND:
@ -175,6 +187,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->ZeroExtend(target_type);
i->Remove();
result = true;
}
break;
case OPCODE_SIGN_EXTEND:
@ -183,6 +196,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->SignExtend(target_type);
i->Remove();
result = true;
}
break;
case OPCODE_TRUNCATE:
@ -191,6 +205,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Truncate(target_type);
i->Remove();
result = true;
}
break;
@ -210,6 +225,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
i->Replace(&OPCODE_LOAD_MMIO_info, 0);
i->src1.offset = reinterpret_cast<uint64_t>(mmio_range);
i->src2.offset = address;
result = true;
} else {
auto heap = memory->LookupHeap(address);
uint32_t protect;
@ -222,18 +238,22 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
case INT8_TYPE:
v->set_constant(xe::load<uint8_t>(host_addr));
i->Remove();
result = true;
break;
case INT16_TYPE:
v->set_constant(xe::load<uint16_t>(host_addr));
i->Remove();
result = true;
break;
case INT32_TYPE:
v->set_constant(xe::load<uint32_t>(host_addr));
i->Remove();
result = true;
break;
case INT64_TYPE:
v->set_constant(xe::load<uint64_t>(host_addr));
i->Remove();
result = true;
break;
case VEC128_TYPE:
vec128_t val;
@ -241,6 +261,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
val.high = xe::load<uint64_t>(host_addr + 8);
v->set_constant(val);
i->Remove();
result = true;
break;
default:
assert_unhandled_case(v->type);
@ -270,6 +291,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
i->src1.offset = reinterpret_cast<uint64_t>(mmio_range);
i->src2.offset = address;
i->set_src3(value);
result = true;
}
}
break;
@ -281,10 +303,12 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
auto src2 = i->src2.value;
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(src2);
result = true;
} else if (i->src1.value->IsConstantFalse()) {
auto src3 = i->src3.value;
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(src3);
result = true;
} else if (i->src2.value->IsConstant() &&
i->src3.value->IsConstant()) {
// TODO: Select
@ -305,6 +329,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_constant(uint8_t(0));
}
i->Remove();
result = true;
}
break;
case OPCODE_IS_FALSE:
@ -315,6 +340,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_constant(uint8_t(0));
}
i->Remove();
result = true;
}
break;
case OPCODE_IS_NAN:
@ -329,6 +355,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_constant(uint8_t(0));
}
i->Remove();
result = true;
}
break;
@ -338,6 +365,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantEQ(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_NE:
@ -345,6 +373,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantNE(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_SLT:
@ -352,6 +381,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantSLT(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_SLE:
@ -359,6 +389,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantSLE(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_SGT:
@ -366,6 +397,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantSGT(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_SGE:
@ -373,6 +405,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantSGE(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_ULT:
@ -380,6 +413,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantULT(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_ULE:
@ -387,6 +421,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantULE(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_UGT:
@ -394,6 +429,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantUGT(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
case OPCODE_COMPARE_UGE:
@ -401,6 +437,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
bool value = i->src1.value->IsConstantUGE(i->src2.value);
i->dest->set_constant(uint8_t(value));
i->Remove();
result = true;
}
break;
@ -413,6 +450,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Add(i->src2.value);
i->Remove();
result = true;
}
break;
case OPCODE_ADD_CARRY:
@ -433,6 +471,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
i->set_src1(ca);
}
}
result = true;
}
break;
case OPCODE_SUB:
@ -440,6 +479,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Sub(i->src2.value);
i->Remove();
result = true;
}
break;
case OPCODE_MUL:
@ -447,6 +487,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Mul(i->src2.value);
i->Remove();
result = true;
} else if (i->src1.value->IsConstant() ||
i->src2.value->IsConstant()) {
// Reorder the sources to make things simpler.
@ -460,12 +501,14 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
if (s2->type != VEC128_TYPE && s2->IsConstantOne()) {
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(s1);
result = true;
} else if (s2->type == VEC128_TYPE) {
auto& c = s2->constant;
if (c.v128.f32[0] == 1.f && c.v128.f32[1] == 1.f &&
c.v128.f32[2] == 1.f && c.v128.f32[3] == 1.f) {
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(s1);
result = true;
}
}
}
@ -475,6 +518,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->MulHi(i->src2.value, (i->flags & ARITHMETIC_UNSIGNED) != 0);
i->Remove();
result = true;
}
break;
case OPCODE_DIV:
@ -482,6 +526,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Div(i->src2.value, (i->flags & ARITHMETIC_UNSIGNED) != 0);
i->Remove();
result = true;
} else if (i->src2.value->IsConstant()) {
// Division by one = no-op.
Value* src1 = i->src1.value;
@ -489,12 +534,14 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
i->src2.value->IsConstantOne()) {
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(src1);
result = true;
} else if (i->src2.value->type == VEC128_TYPE) {
auto& c = i->src2.value->constant;
if (c.v128.f32[0] == 1.f && c.v128.f32[1] == 1.f &&
c.v128.f32[2] == 1.f && c.v128.f32[3] == 1.f) {
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(src1);
result = true;
}
}
}
@ -505,6 +552,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
Value::MulAdd(v, i->src1.value, i->src2.value, i->src3.value);
i->Remove();
result = true;
} else {
// Multiply part is constant.
Value* mul = builder->AllocValue();
@ -515,6 +563,8 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
i->Replace(&OPCODE_ADD_info, 0);
i->set_src1(mul);
i->set_src2(add);
result = true;
}
}
break;
@ -525,6 +575,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
Value::MulSub(v, i->src1.value, i->src2.value, i->src3.value);
i->Remove();
result = true;
} else {
// Multiply part is constant.
Value* mul = builder->AllocValue();
@ -535,6 +586,8 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
i->Replace(&OPCODE_SUB_info, 0);
i->set_src1(mul);
i->set_src2(add);
result = true;
}
}
break;
@ -543,6 +596,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Max(i->src2.value);
i->Remove();
result = true;
}
break;
case OPCODE_NEG:
@ -550,6 +604,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Neg();
i->Remove();
result = true;
}
break;
case OPCODE_ABS:
@ -557,6 +612,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Abs();
i->Remove();
result = true;
}
break;
case OPCODE_SQRT:
@ -564,6 +620,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Sqrt();
i->Remove();
result = true;
}
break;
case OPCODE_RSQRT:
@ -571,6 +628,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->RSqrt();
i->Remove();
result = true;
}
break;
case OPCODE_RECIP:
@ -578,6 +636,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Recip();
i->Remove();
result = true;
}
break;
case OPCODE_AND:
@ -585,6 +644,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->And(i->src2.value);
i->Remove();
result = true;
}
break;
case OPCODE_OR:
@ -592,6 +652,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Or(i->src2.value);
i->Remove();
result = true;
}
break;
case OPCODE_XOR:
@ -599,11 +660,13 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Xor(i->src2.value);
i->Remove();
result = true;
} else if (!i->src1.value->IsConstant() &&
!i->src2.value->IsConstant() &&
i->src1.value == i->src2.value) {
v->set_zero(v->type);
i->Remove();
result = true;
}
break;
case OPCODE_NOT:
@ -611,6 +674,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Not();
i->Remove();
result = true;
}
break;
case OPCODE_SHL:
@ -618,10 +682,12 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Shl(i->src2.value);
i->Remove();
result = true;
} else if (i->src2.value->IsConstantZero()) {
auto src1 = i->src1.value;
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(src1);
result = true;
}
break;
case OPCODE_SHR:
@ -629,10 +695,12 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Shr(i->src2.value);
i->Remove();
result = true;
} else if (i->src2.value->IsConstantZero()) {
auto src1 = i->src1.value;
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(src1);
result = true;
}
break;
case OPCODE_SHA:
@ -640,6 +708,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->Sha(i->src2.value);
i->Remove();
result = true;
}
break;
// TODO(benvanik): ROTATE_LEFT
@ -648,6 +717,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->ByteSwap();
i->Remove();
result = true;
}
break;
case OPCODE_CNTLZ:
@ -655,6 +725,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_zero(v->type);
v->CountLeadingZeros(i->src1.value);
i->Remove();
result = true;
}
break;
// TODO(benvanik): INSERT/EXTRACT
@ -664,6 +735,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_zero(v->type);
v->Extract(i->src1.value, i->src2.value);
i->Remove();
result = true;
}
break;
case OPCODE_SPLAT:
@ -671,6 +743,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_zero(v->type);
v->Splat(i->src1.value);
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_COMPARE_EQ:
@ -678,6 +751,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorCompareEQ(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_COMPARE_SGT:
@ -685,6 +759,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorCompareSGT(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_COMPARE_SGE:
@ -692,6 +767,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorCompareSGE(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_COMPARE_UGT:
@ -699,6 +775,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorCompareUGT(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_COMPARE_UGE:
@ -706,6 +783,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorCompareUGE(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_CONVERT_F2I:
@ -714,6 +792,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->VectorConvertF2I(i->src1.value,
!!(i->flags & ARITHMETIC_UNSIGNED));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_CONVERT_I2F:
@ -722,6 +801,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->VectorConvertI2F(i->src1.value,
!!(i->flags & ARITHMETIC_UNSIGNED));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_SHL:
@ -729,6 +809,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorShl(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_SHR:
@ -736,6 +817,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorShr(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_ROTATE_LEFT:
@ -743,6 +825,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->VectorRol(i->src2.value, hir::TypeName(i->flags));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_ADD:
@ -753,6 +836,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
!!(arith_flags & ARITHMETIC_UNSIGNED),
!!(arith_flags & ARITHMETIC_SATURATE));
i->Remove();
result = true;
}
break;
case OPCODE_VECTOR_SUB:
@ -763,6 +847,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
!!(arith_flags & ARITHMETIC_UNSIGNED),
!!(arith_flags & ARITHMETIC_SATURATE));
i->Remove();
result = true;
}
break;
@ -771,6 +856,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->DotProduct3(i->src2.value);
i->Remove();
result = true;
}
break;
@ -779,6 +865,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
v->set_from(i->src1.value);
v->DotProduct4(i->src2.value);
i->Remove();
result = true;
}
break;
@ -790,6 +877,7 @@ bool ConstantPropagationPass::Run(HIRBuilder* builder) {
!!(arith_flags & ARITHMETIC_UNSIGNED),
!!(arith_flags & ARITHMETIC_SATURATE));
i->Remove();
result = true;
}
break;

View File

@ -10,19 +10,19 @@
#ifndef XENIA_CPU_COMPILER_PASSES_CONSTANT_PROPAGATION_PASS_H_
#define XENIA_CPU_COMPILER_PASSES_CONSTANT_PROPAGATION_PASS_H_
#include "xenia/cpu/compiler/compiler_pass.h"
#include "xenia/cpu/compiler/passes/conditional_group_subpass.h"
namespace xe {
namespace cpu {
namespace compiler {
namespace passes {
class ConstantPropagationPass : public CompilerPass {
class ConstantPropagationPass : public ConditionalGroupSubpass {
public:
ConstantPropagationPass();
~ConstantPropagationPass() override;
bool Run(hir::HIRBuilder* builder) override;
bool Run(hir::HIRBuilder* builder, bool& result) override;
private:
};

View File

@ -23,17 +23,18 @@ using xe::cpu::hir::HIRBuilder;
using xe::cpu::hir::Instr;
using xe::cpu::hir::Value;
SimplificationPass::SimplificationPass() : CompilerPass() {}
SimplificationPass::SimplificationPass() : ConditionalGroupSubpass() {}
SimplificationPass::~SimplificationPass() {}
bool SimplificationPass::Run(HIRBuilder* builder) {
EliminateConversions(builder);
SimplifyAssignments(builder);
bool SimplificationPass::Run(HIRBuilder* builder, bool& result) {
result = false;
result |= EliminateConversions(builder);
result |= SimplifyAssignments(builder);
return true;
}
void SimplificationPass::EliminateConversions(HIRBuilder* builder) {
bool SimplificationPass::EliminateConversions(HIRBuilder* builder) {
// First, we check for truncates/extensions that can be skipped.
// This generates some assignments which then the second step will clean up.
// Both zero/sign extends can be skipped:
@ -43,6 +44,7 @@ void SimplificationPass::EliminateConversions(HIRBuilder* builder) {
// v1.i64 = zero/sign_extend v0.i32 (may be dead code removed later)
// v2.i32 = v0.i32
bool result = false;
auto block = builder->first_block();
while (block) {
auto i = block->instr_head;
@ -51,20 +53,21 @@ void SimplificationPass::EliminateConversions(HIRBuilder* builder) {
// back to definition).
if (i->opcode == &OPCODE_TRUNCATE_info) {
// Matches zero/sign_extend + truncate.
CheckTruncate(i);
result |= CheckTruncate(i);
} else if (i->opcode == &OPCODE_BYTE_SWAP_info) {
// Matches byte swap + byte swap.
// This is pretty rare within the same basic block, but is in the
// memcpy hot path and (probably) worth it. Maybe.
CheckByteSwap(i);
result |= CheckByteSwap(i);
}
i = i->next;
}
block = block->next;
}
return result;
}
void SimplificationPass::CheckTruncate(Instr* i) {
bool SimplificationPass::CheckTruncate(Instr* i) {
// Walk backward up src's chain looking for an extend. We may have
// assigns, so skip those.
auto src = i->src1.value;
@ -80,6 +83,7 @@ void SimplificationPass::CheckTruncate(Instr* i) {
// Types match, use original by turning this into an assign.
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(def->src1.value);
return true;
}
} else if (def->opcode == &OPCODE_ZERO_EXTEND_info) {
// Value comes from a zero extend.
@ -87,12 +91,14 @@ void SimplificationPass::CheckTruncate(Instr* i) {
// Types match, use original by turning this into an assign.
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(def->src1.value);
return true;
}
}
}
return false;
}
void SimplificationPass::CheckByteSwap(Instr* i) {
bool SimplificationPass::CheckByteSwap(Instr* i) {
// Walk backward up src's chain looking for a byte swap. We may have
// assigns, so skip those.
auto src = i->src1.value;
@ -107,11 +113,13 @@ void SimplificationPass::CheckByteSwap(Instr* i) {
// Types match, use original by turning this into an assign.
i->Replace(&OPCODE_ASSIGN_info, 0);
i->set_src1(def->src1.value);
return true;
}
}
return false;
}
void SimplificationPass::SimplifyAssignments(HIRBuilder* builder) {
bool SimplificationPass::SimplifyAssignments(HIRBuilder* builder) {
// Run over the instructions and rename assigned variables:
// v1 = v0
// v2 = v1
@ -129,27 +137,35 @@ void SimplificationPass::SimplifyAssignments(HIRBuilder* builder) {
// of that instr. Because we may have chains, we do this recursively until
// we find a non-assign def.
bool result = false;
auto block = builder->first_block();
while (block) {
auto i = block->instr_head;
while (i) {
uint32_t signature = i->opcode->signature;
if (GET_OPCODE_SIG_TYPE_SRC1(signature) == OPCODE_SIG_TYPE_V) {
i->set_src1(CheckValue(i->src1.value));
bool modified = false;
i->set_src1(CheckValue(i->src1.value, modified));
result |= modified;
}
if (GET_OPCODE_SIG_TYPE_SRC2(signature) == OPCODE_SIG_TYPE_V) {
i->set_src2(CheckValue(i->src2.value));
bool modified = false;
i->set_src2(CheckValue(i->src2.value, modified));
result |= modified;
}
if (GET_OPCODE_SIG_TYPE_SRC3(signature) == OPCODE_SIG_TYPE_V) {
i->set_src3(CheckValue(i->src3.value));
bool modified = false;
i->set_src3(CheckValue(i->src3.value, modified));
result |= modified;
}
i = i->next;
}
block = block->next;
}
return result;
}
Value* SimplificationPass::CheckValue(Value* value) {
Value* SimplificationPass::CheckValue(Value* value, bool& result) {
auto def = value->def;
if (def && def->opcode == &OPCODE_ASSIGN_info) {
// Value comes from an assignment - recursively find if it comes from
@ -162,8 +178,10 @@ Value* SimplificationPass::CheckValue(Value* value) {
}
replacement = def->src1.value;
}
result = true;
return replacement;
}
result = false;
return value;
}

View File

@ -10,27 +10,27 @@
#ifndef XENIA_CPU_COMPILER_PASSES_SIMPLIFICATION_PASS_H_
#define XENIA_CPU_COMPILER_PASSES_SIMPLIFICATION_PASS_H_
#include "xenia/cpu/compiler/compiler_pass.h"
#include "xenia/cpu/compiler/passes/conditional_group_subpass.h"
namespace xe {
namespace cpu {
namespace compiler {
namespace passes {
class SimplificationPass : public CompilerPass {
class SimplificationPass : public ConditionalGroupSubpass {
public:
SimplificationPass();
~SimplificationPass() override;
bool Run(hir::HIRBuilder* builder) override;
bool Run(hir::HIRBuilder* builder, bool& result) override;
private:
void EliminateConversions(hir::HIRBuilder* builder);
void CheckTruncate(hir::Instr* i);
void CheckByteSwap(hir::Instr* i);
bool EliminateConversions(hir::HIRBuilder* builder);
bool CheckTruncate(hir::Instr* i);
bool CheckByteSwap(hir::Instr* i);
void SimplifyAssignments(hir::HIRBuilder* builder);
hir::Value* CheckValue(hir::Value* value);
bool SimplifyAssignments(hir::HIRBuilder* builder);
hir::Value* CheckValue(hir::Value* value, bool& result);
};
} // namespace passes

View File

@ -170,6 +170,7 @@ class Value {
constant.v128 = value;
}
void set_from(const Value* other) {
assert_true(other->IsConstant());
type = other->type;
flags = other->flags;
constant.v128 = other->constant.v128;

View File

@ -53,15 +53,16 @@ PPCTranslator::PPCTranslator(PPCFrontend* frontend) : frontend_(frontend) {
if (validate) compiler_->AddPass(std::make_unique<passes::ValidationPass>());
compiler_->AddPass(std::make_unique<passes::ContextPromotionPass>());
if (validate) compiler_->AddPass(std::make_unique<passes::ValidationPass>());
// TODO(gibbed): loop until these passes stop making changes?
for (int i = 0; i < 5; ++i) {
compiler_->AddPass(std::make_unique<passes::SimplificationPass>());
if (validate)
compiler_->AddPass(std::make_unique<passes::ValidationPass>());
compiler_->AddPass(std::make_unique<passes::ConstantPropagationPass>());
if (validate)
compiler_->AddPass(std::make_unique<passes::ValidationPass>());
}
// Grouped simplification + constant propagation.
// Loops until no changes are made.
auto sap = std::make_unique<passes::ConditionalGroupPass>();
sap->AddPass(std::make_unique<passes::SimplificationPass>());
if (validate) sap->AddPass(std::make_unique<passes::ValidationPass>());
sap->AddPass(std::make_unique<passes::ConstantPropagationPass>());
if (validate) sap->AddPass(std::make_unique<passes::ValidationPass>());
compiler_->AddPass(std::move(sap));
if (backend->machine_info()->supports_extended_load_store) {
// Backend supports the advanced LOAD/STORE instructions.
// These will save us a lot of HIR opcodes.

View File

@ -13,6 +13,7 @@ project("xenia-cpu-ppc-tests")
"xenia-base",
"gflags",
"capstone", -- cpu-backend-x64
"mspack",
})
files({
"ppc_testing_main.cc",

View File

@ -8,6 +8,7 @@ project("xenia-cpu")
language("C++")
links({
"xenia-base",
"mspack",
})
includedirs({
project_root.."/third_party/llvm/include",

View File

@ -25,7 +25,6 @@
#include "third_party/crypto/rijndael-alg-fst.c"
#include "third_party/crypto/rijndael-alg-fst.h"
#include "third_party/mspack/lzx.h"
#include "third_party/mspack/lzxd.c"
#include "third_party/mspack/mspack.h"
#include "third_party/pe/pe_image.h"
@ -120,7 +119,7 @@ int lzx_decompress(const void* lzx_data, size_t lzx_len, void* dest,
mspack_memory_file* lzxdst = mspack_memory_open(sys, dest, dest_len);
lzxd_stream* lzxd =
lzxd_init(sys, (struct mspack_file*)lzxsrc, (struct mspack_file*)lzxdst,
window_bits, 0, 0x8000, (off_t)dest_len);
window_bits, 0, 0x8000, (off_t)dest_len, 0);
if (lzxd) {
if (window_data) {
@ -1120,23 +1119,23 @@ bool XexModule::LoadContinue() {
processor_->backend()->CommitExecutableRange(low_address_, high_address_);
// Add all imports (variables/functions).
xex2_opt_import_libraries* opt_import_header = nullptr;
GetOptHeader(XEX_HEADER_IMPORT_LIBRARIES, &opt_import_header);
xex2_opt_import_libraries* opt_import_libraries = nullptr;
GetOptHeader(XEX_HEADER_IMPORT_LIBRARIES, &opt_import_libraries);
if (opt_import_header) {
if (opt_import_libraries) {
// FIXME: Don't know if 32 is the actual limit, but haven't seen more than
// 2.
const char* string_table[32];
std::memset(string_table, 0, sizeof(string_table));
size_t max_string_table_index = 0;
// Parse the string table
for (size_t i = 0; i < opt_import_header->string_table_size;
++max_string_table_index) {
assert_true(max_string_table_index < xe::countof(string_table));
const char* str = opt_import_header->string_table + i;
for (size_t i = 0, o = 0; i < opt_import_libraries->string_table.size &&
o < opt_import_libraries->string_table.count;
++o) {
assert_true(o < xe::countof(string_table));
const char* str = &opt_import_libraries->string_table.data[i];
string_table[max_string_table_index] = str;
string_table[o] = str;
i += std::strlen(str) + 1;
// Padding
@ -1145,15 +1144,19 @@ bool XexModule::LoadContinue() {
}
}
auto libraries_ptr = reinterpret_cast<uint8_t*>(opt_import_header) +
opt_import_header->string_table_size + 12;
auto library_data = reinterpret_cast<uint8_t*>(opt_import_libraries) +
opt_import_libraries->string_table.size + 12;
uint32_t library_offset = 0;
uint32_t library_count = opt_import_header->library_count;
for (uint32_t i = 0; i < library_count; i++) {
auto library = reinterpret_cast<xex2_import_library*>(libraries_ptr +
library_offset);
while (library_offset < opt_import_libraries->size) {
auto library =
reinterpret_cast<xex2_import_library*>(library_data + library_offset);
if (!library->size) {
break;
}
size_t library_name_index = library->name_index & 0xFF;
assert_true(library_name_index < max_string_table_index);
assert_true(library_name_index <
opt_import_libraries->string_table.count);
assert_not_null(string_table[library_name_index]);
SetupLibraryImports(string_table[library_name_index], library);
library_offset += library->size;
}
@ -1313,10 +1316,12 @@ bool XexModule::SetupLibraryImports(const char* name,
var_info->set_status(Symbol::Status::kDefined);
} else if (record_type == 1) {
// Thunk.
assert_true(library_info.imports.size() > 0);
auto& prev_import = library_info.imports[library_info.imports.size() - 1];
assert_true(prev_import.ordinal == ordinal);
prev_import.thunk_address = record_addr;
if (library_info.imports.size() > 0) {
auto& prev_import =
library_info.imports[library_info.imports.size() - 1];
assert_true(prev_import.ordinal == ordinal);
prev_import.thunk_address = record_addr;
}
if (kernel_export) {
import_name.AppendFormat("%s", kernel_export->name);

View File

@ -38,6 +38,7 @@ project("xenia-gpu-vulkan-trace-viewer")
"imgui",
"libavcodec",
"libavutil",
"mspack",
"snappy",
"spirv-tools",
"volk",
@ -110,6 +111,7 @@ project("xenia-gpu-vulkan-trace-dump")
"imgui",
"libavcodec",
"libavutil",
"mspack",
"snappy",
"spirv-tools",
"volk",

View File

@ -486,29 +486,33 @@ void UserModule::Dump() {
std::memset(string_table, 0, sizeof(string_table));
// Parse the string table
for (size_t l = 0, j = 0; l < opt_import_libraries->string_table_size;
j++) {
assert_true(j < xe::countof(string_table));
const char* str = opt_import_libraries->string_table + l;
for (size_t j = 0, o = 0; j < opt_import_libraries->string_table.size &&
o < opt_import_libraries->string_table.count;
o++) {
assert_true(o < xe::countof(string_table));
const char* str = &opt_import_libraries->string_table.data[j];
string_table[j] = str;
l += std::strlen(str) + 1;
string_table[o] = str;
j += std::strlen(str) + 1;
// Padding
if ((l % 4) != 0) {
l += 4 - (l % 4);
if ((j % 4) != 0) {
j += 4 - (j % 4);
}
}
auto libraries =
auto library_data =
reinterpret_cast<const uint8_t*>(opt_import_libraries) +
opt_import_libraries->string_table_size + 12;
opt_import_libraries->string_table.size + 12;
uint32_t library_offset = 0;
uint32_t library_count = opt_import_libraries->library_count;
for (uint32_t l = 0; l < library_count; l++) {
while (library_offset < opt_import_libraries->size) {
auto library = reinterpret_cast<const xex2_import_library*>(
libraries + library_offset);
library_data + library_offset);
if (!library->size) {
break;
}
auto name = string_table[library->name_index & 0xFF];
assert_not_null(name);
sb.AppendFormat(" %s - %d imports\n", name,
(uint16_t)library->count);
@ -786,11 +790,11 @@ void UserModule::Dump() {
}
if (kernel_export &&
kernel_export->type == cpu::Export::Type::kVariable) {
sb.AppendFormat(" V %.8X %.3X (%3d) %s %s\n",
sb.AppendFormat(" V %.8X %.3X (%4d) %s %s\n",
info->value_address, info->ordinal, info->ordinal,
implemented ? " " : "!!", name);
} else if (info->thunk_address) {
sb.AppendFormat(" F %.8X %.8X %.3X (%3d) %s %s\n",
sb.AppendFormat(" F %.8X %.8X %.3X (%4d) %s %s\n",
info->value_address, info->thunk_address,
info->ordinal, info->ordinal,
implemented ? " " : "!!", name);

View File

@ -474,10 +474,12 @@ struct xex2_opt_execution_info {
static_assert_size(xex2_opt_execution_info, 0x18);
struct xex2_opt_import_libraries {
xe::be<uint32_t> section_size; // 0x0
xe::be<uint32_t> string_table_size; // 0x4
xe::be<uint32_t> library_count; // 0x8
char string_table[1]; // 0xC string_table_size bytes
xe::be<uint32_t> size; // 0x0
struct {
xe::be<uint32_t> size; // 0x4
xe::be<uint32_t> count; // 0x8
char data[1]; // 0xC string_table_size bytes
} string_table;
};
struct xex2_import_library {

View File

@ -23,7 +23,7 @@ struct DeviceInfo {
uint32_t device_type;
uint64_t total_bytes;
uint64_t free_bytes;
std::wstring name;
wchar_t name[28];
};
static const DeviceInfo dummy_device_info_ = {
0xF00D0000,
@ -57,7 +57,7 @@ dword_result_t XamContentGetDeviceName(dword_t device_id,
return X_ERROR_DEVICE_NOT_CONNECTED;
}
if (name_capacity < dummy_device_info_.name.size() + 1) {
if (name_capacity < wcslen(dummy_device_info_.name) + 1) {
return X_ERROR_INSUFFICIENT_BUFFER;
}
@ -174,6 +174,35 @@ dword_result_t XamContentCreateEnumerator(dword_t user_index, dword_t device_id,
}
DECLARE_XAM_EXPORT1(XamContentCreateEnumerator, kContent, kImplemented);
dword_result_t XamContentCreateDeviceEnumerator(dword_t content_type,
dword_t content_flags,
dword_t max_count,
lpdword_t buffer_size_ptr,
lpdword_t handle_out) {
assert_not_null(handle_out);
if (buffer_size_ptr) {
*buffer_size_ptr = sizeof(DeviceInfo) * max_count;
}
auto e = new XStaticEnumerator(kernel_state(), max_count, sizeof(DeviceInfo));
e->Initialize();
// Copy our dummy device into the enumerator
DeviceInfo* dev = (DeviceInfo*)e->AppendItem();
if (dev) {
xe::store_and_swap(&dev->device_id, dummy_device_info_.device_id);
xe::store_and_swap(&dev->device_type, dummy_device_info_.device_type);
xe::store_and_swap(&dev->total_bytes, dummy_device_info_.total_bytes);
xe::store_and_swap(&dev->free_bytes, dummy_device_info_.free_bytes);
xe::copy_and_swap(dev->name, dummy_device_info_.name, 28);
}
*handle_out = e->handle();
return X_ERROR_SUCCESS;
}
DECLARE_XAM_EXPORT1(XamContentCreateDeviceEnumerator, kNone, kImplemented);
dword_result_t XamContentCreateEx(dword_t user_index, lpstring_t root_name,
lpvoid_t content_data_ptr, dword_t flags,
lpdword_t disposition_ptr,

View File

@ -17,6 +17,10 @@
#include "xenia/kernel/xthread.h"
#include "xenia/xbox.h"
#if XE_PLATFORM_WIN32
#include "xenia/base/platform_win.h"
#endif
namespace xe {
namespace kernel {
namespace xam {
@ -24,6 +28,152 @@ namespace xam {
constexpr uint32_t X_LANGUAGE_ENGLISH = 1;
constexpr uint32_t X_LANGUAGE_JAPANESE = 2;
dword_result_t XamGetOnlineSchema() {
static uint32_t schema_guest = 0;
static uint32_t schema_ptr_guest = 0;
if (!schema_guest) {
// create a dummy schema, 8 bytes of 0 seems to work fine
// (with another 8 bytes for schema ptr/schema size)
schema_guest = kernel_state()->memory()->SystemHeapAlloc(16);
schema_ptr_guest = schema_guest + 8;
auto schema = kernel_state()->memory()->TranslateVirtual(schema_guest);
memset(schema, 0, 16);
// store schema ptr + size
xe::store_and_swap<uint32_t>(schema + 0x8, schema_guest);
xe::store_and_swap<uint32_t>(schema + 0xC, 0x8);
}
// return pointer to the schema ptr/schema size struct
return schema_ptr_guest;
}
DECLARE_XAM_EXPORT2(XamGetOnlineSchema, kNone, kImplemented, kSketchy);
void XamFormatDateString(dword_t unk, qword_t filetime, lpvoid_t buffer,
dword_t buffer_length) {
std::memset(buffer, 0, buffer_length * 2);
// TODO: implement this for other platforms
#if XE_PLATFORM_WIN32
FILETIME t;
t.dwHighDateTime = filetime >> 32;
t.dwLowDateTime = (uint32_t)filetime;
SYSTEMTIME st;
SYSTEMTIME stLocal;
FileTimeToSystemTime(&t, &st);
SystemTimeToTzSpecificLocalTime(NULL, &st, &stLocal);
wchar_t buf[256];
// TODO: format this depending on users locale?
swprintf(buf, 256, L"%02d/%02d/%d", stLocal.wMonth, stLocal.wDay,
stLocal.wYear);
xe::copy_and_swap((wchar_t*)buffer.host_address(), buf, buffer_length);
#else
assert_always();
#endif
}
DECLARE_XAM_EXPORT1(XamFormatDateString, kNone, kImplemented);
void XamFormatTimeString(dword_t unk, qword_t filetime, lpvoid_t buffer,
dword_t buffer_length) {
std::memset(buffer, 0, buffer_length * 2);
// TODO: implement this for other platforms
#if XE_PLATFORM_WIN32
FILETIME t;
t.dwHighDateTime = filetime >> 32;
t.dwLowDateTime = (uint32_t)filetime;
SYSTEMTIME st;
SYSTEMTIME stLocal;
FileTimeToSystemTime(&t, &st);
SystemTimeToTzSpecificLocalTime(NULL, &st, &stLocal);
wchar_t buf[256];
swprintf(buf, 256, L"%02d:%02d", stLocal.wHour, stLocal.wMinute);
xe::copy_and_swap((wchar_t*)buffer.host_address(), buf, buffer_length);
#else
assert_always();
#endif
}
DECLARE_XAM_EXPORT1(XamFormatTimeString, kNone, kImplemented);
dword_result_t keXamBuildResourceLocator(uint64_t module,
const wchar_t* container,
const wchar_t* resource,
lpvoid_t buffer,
uint32_t buffer_length) {
wchar_t buf[256];
if (!module) {
swprintf(buf, 256, L"file://media:/%s.xzp#%s", container, resource);
XELOGD(
"XamBuildResourceLocator(%ws) returning locator to local file %ws.xzp",
container, container);
} else {
swprintf(buf, 256, L"section://%X,%s#%s", (uint32_t)module, container,
resource);
}
xe::copy_and_swap((wchar_t*)buffer.host_address(), buf, buffer_length);
return 0;
}
dword_result_t XamBuildResourceLocator(qword_t module, lpwstring_t container,
lpwstring_t resource, lpvoid_t buffer,
dword_t buffer_length) {
return keXamBuildResourceLocator(module, container.value().c_str(),
resource.value().c_str(), buffer,
buffer_length);
}
DECLARE_XAM_EXPORT1(XamBuildResourceLocator, kNone, kImplemented);
dword_result_t XamBuildGamercardResourceLocator(lpwstring_t filename,
lpvoid_t buffer,
dword_t buffer_length) {
// On an actual xbox these funcs would return a locator to xam.xex resources,
// but for Xenia we can return a locator to the resources as local files. (big
// thanks to MS for letting XamBuildResourceLocator return local file
// locators!)
// If you're running an app that'll need them, make sure to extract xam.xex
// resources with xextool ("xextool -d . xam.xex") and add a .xzp extension.
return keXamBuildResourceLocator(0, L"gamercrd", filename.value().c_str(),
buffer, buffer_length);
}
DECLARE_XAM_EXPORT1(XamBuildGamercardResourceLocator, kNone, kImplemented);
dword_result_t XamBuildSharedSystemResourceLocator(lpwstring_t filename,
lpvoid_t buffer,
dword_t buffer_length) {
// see notes inside XamBuildGamercardResourceLocator above
return keXamBuildResourceLocator(0, L"shrdres", filename.value().c_str(),
buffer, buffer_length);
}
DECLARE_XAM_EXPORT1(XamBuildSharedSystemResourceLocator, kNone, kImplemented);
dword_result_t XamBuildLegacySystemResourceLocator(lpwstring_t filename,
lpvoid_t buffer,
dword_t buffer_length) {
return XamBuildSharedSystemResourceLocator(filename, buffer, buffer_length);
}
DECLARE_XAM_EXPORT1(XamBuildLegacySystemResourceLocator, kNone, kImplemented);
dword_result_t XamBuildXamResourceLocator(lpwstring_t filename, lpvoid_t buffer,
dword_t buffer_length) {
return keXamBuildResourceLocator(0, L"xam", filename.value().c_str(), buffer,
buffer_length);
}
DECLARE_XAM_EXPORT1(XamBuildXamResourceLocator, kNone, kImplemented);
dword_result_t XamGetSystemVersion() {
// eh, just picking one. If we go too low we may break new games, but
// this value seems to be used for conditionally loading symbols and if

View File

@ -18,7 +18,8 @@ namespace xe {
namespace kernel {
namespace xam {
dword_result_t XamNotifyCreateListener(qword_t mask, dword_t one) {
dword_result_t XamNotifyCreateListenerInternal(qword_t mask, dword_t unk,
dword_t one) {
// r4=1 may indicate user process?
auto listener =
@ -30,6 +31,12 @@ dword_result_t XamNotifyCreateListener(qword_t mask, dword_t one) {
return handle;
}
DECLARE_XAM_EXPORT2(XamNotifyCreateListenerInternal, kNone, kImplemented,
kSketchy);
dword_result_t XamNotifyCreateListener(qword_t mask, dword_t one) {
return XamNotifyCreateListenerInternal(mask, 0, one);
}
DECLARE_XAM_EXPORT1(XamNotifyCreateListener, kNone, kImplemented);
// https://github.com/CodeAsm/ffplay360/blob/master/Common/AtgSignIn.cpp

View File

@ -588,7 +588,7 @@ XE_EXPORT(xam, 0x00000318, XamVoiceGetMicArrayStatus,
XE_EXPORT(xam, 0x00000319, XamVoiceSetAudioCaptureRoutine, kFunction),
XE_EXPORT(xam, 0x0000031A, XamVoiceGetDirectionalData, kFunction),
XE_EXPORT(xam, 0x0000031B, XamBuildResourceLocator, kFunction),
XE_EXPORT(xam, 0x0000031C, XamBuildSharedSystemResourceLocator_, kFunction),
XE_EXPORT(xam, 0x0000031C, XamBuildLegacySystemResourceLocator, kFunction),
XE_EXPORT(xam, 0x0000031D, XamBuildGamercardResourceLocator, kFunction),
XE_EXPORT(xam, 0x0000031E, XamBuildDynamicResourceLocator, kFunction),
XE_EXPORT(xam, 0x0000031F, XamBuildXamResourceLocator, kFunction),

View File

@ -159,6 +159,14 @@ XboxkrnlModule::XboxkrnlModule(Emulator* emulator, KernelState* kernel_state)
xe::store_and_swap<uint8_t>(lpXboxHardwareInfo + 4, 0x06); // cpu count
// Remaining 11b are zeroes?
// ExConsoleGameRegion, probably same values as keyvault region uses?
// Just return all 0xFF, should satisfy anything that checks it
uint32_t pExConsoleGameRegion = memory_->SystemHeapAlloc(4);
auto lpExConsoleGameRegion = memory_->TranslateVirtual(pExConsoleGameRegion);
export_resolver_->SetVariableMapping(
"xboxkrnl.exe", ordinals::ExConsoleGameRegion, pExConsoleGameRegion);
xe::store<uint32_t>(lpExConsoleGameRegion, 0xFFFFFFFF);
// XexExecutableModuleHandle (?**)
// Games try to dereference this to get a pointer to some module struct.
// So far it seems like it's just in loader code, and only used to look up

View File

@ -1009,6 +1009,46 @@ SHIM_CALL _vsnprintf_shim(PPCContext* ppc_context, KernelState* kernel_state) {
SHIM_SET_RETURN_32(count);
}
// https://msdn.microsoft.com/en-us/library/1kt27hek.aspx
SHIM_CALL _vsnwprintf_shim(PPCContext* ppc_context, KernelState* kernel_state) {
uint32_t buffer_ptr = SHIM_GET_ARG_32(0);
int32_t buffer_count = SHIM_GET_ARG_32(1);
uint32_t format_ptr = SHIM_GET_ARG_32(2);
uint32_t arg_ptr = SHIM_GET_ARG_32(3);
XELOGD("_vsnwprintf(%08X, %i, %08X, %08X)", buffer_ptr, buffer_count,
format_ptr, arg_ptr);
if (buffer_ptr == 0 || buffer_count <= 0 || format_ptr == 0) {
SHIM_SET_RETURN_32(-1);
return;
}
auto buffer = (uint16_t*)SHIM_MEM_ADDR(buffer_ptr);
auto format = (const uint16_t*)SHIM_MEM_ADDR(format_ptr);
ArrayArgList args(ppc_context, arg_ptr);
WideStringFormatData data(format);
int32_t count = format_core(ppc_context, data, args, true);
if (count < 0) {
// Error.
if (buffer_count > 0) {
buffer[0] = '\0'; // write a null, just to be safe
}
} else if (count <= buffer_count) {
// Fit within the buffer.
xe::copy_and_swap(buffer, (uint16_t*)data.wstr().c_str(), count);
if (count < buffer_count) {
buffer[count] = '\0';
}
} else {
// Overflowed buffer. We still return the count we would have written.
xe::copy_and_swap(buffer, (uint16_t*)data.wstr().c_str(), buffer_count);
}
SHIM_SET_RETURN_32(count);
}
// https://msdn.microsoft.com/en-us/library/28d5ce15.aspx
SHIM_CALL vsprintf_shim(PPCContext* ppc_context, KernelState* kernel_state) {
uint32_t buffer_ptr = SHIM_GET_ARG_32(0);
@ -1100,6 +1140,7 @@ void RegisterStringExports(xe::cpu::ExportResolver* export_resolver,
SHIM_SET_MAPPING("xboxkrnl.exe", vsprintf, state);
SHIM_SET_MAPPING("xboxkrnl.exe", _vscwprintf, state);
SHIM_SET_MAPPING("xboxkrnl.exe", vswprintf, state);
SHIM_SET_MAPPING("xboxkrnl.exe", _vsnwprintf, state);
}
} // namespace xboxkrnl

33
third_party/mspack.lua vendored Normal file
View File

@ -0,0 +1,33 @@
group("third_party")
project("mspack")
uuid("0881692A-75A1-4E7B-87D8-BB9108CEDEA4")
kind("StaticLib")
language("C")
defines({
"_LIB",
"HAVE_CONFIG_H",
})
removedefines({
"_UNICODE",
"UNICODE",
})
includedirs({
"mspack",
})
files({
"mspack/lzx.h",
"mspack/lzxd.c",
"mspack/mspack.h",
"mspack/readbits.h",
"mspack/readhuff.h",
"mspack/system.c",
"mspack/system.h",
})
filter("platforms:Windows")
defines({
})
filter("platforms:Linux")
defines({
})

504
third_party/mspack/COPYING.LIB vendored Normal file
View File

@ -0,0 +1,504 @@
GNU LESSER GENERAL PUBLIC LICENSE
Version 2.1, February 1999
Copyright (C) 1991, 1999 Free Software Foundation, Inc.
59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
Everyone is permitted to copy and distribute verbatim copies
of this license document, but changing it is not allowed.
[This is the first released version of the Lesser GPL. It also counts
as the successor of the GNU Library Public License, version 2, hence
the version number 2.1.]
Preamble
The licenses for most software are designed to take away your
freedom to share and change it. By contrast, the GNU General Public
Licenses are intended to guarantee your freedom to share and change
free software--to make sure the software is free for all its users.
This license, the Lesser General Public License, applies to some
specially designated software packages--typically libraries--of the
Free Software Foundation and other authors who decide to use it. You
can use it too, but we suggest you first think carefully about whether
this license or the ordinary General Public License is the better
strategy to use in any particular case, based on the explanations below.
When we speak of free software, we are referring to freedom of use,
not price. Our General Public Licenses are designed to make sure that
you have the freedom to distribute copies of free software (and charge
for this service if you wish); that you receive source code or can get
it if you want it; that you can change the software and use pieces of
it in new free programs; and that you are informed that you can do
these things.
To protect your rights, we need to make restrictions that forbid
distributors to deny you these rights or to ask you to surrender these
rights. These restrictions translate to certain responsibilities for
you if you distribute copies of the library or if you modify it.
For example, if you distribute copies of the library, whether gratis
or for a fee, you must give the recipients all the rights that we gave
you. You must make sure that they, too, receive or can get the source
code. If you link other code with the library, you must provide
complete object files to the recipients, so that they can relink them
with the library after making changes to the library and recompiling
it. And you must show them these terms so they know their rights.
We protect your rights with a two-step method: (1) we copyright the
library, and (2) we offer you this license, which gives you legal
permission to copy, distribute and/or modify the library.
To protect each distributor, we want to make it very clear that
there is no warranty for the free library. Also, if the library is
modified by someone else and passed on, the recipients should know
that what they have is not the original version, so that the original
author's reputation will not be affected by problems that might be
introduced by others.
Finally, software patents pose a constant threat to the existence of
any free program. We wish to make sure that a company cannot
effectively restrict the users of a free program by obtaining a
restrictive license from a patent holder. Therefore, we insist that
any patent license obtained for a version of the library must be
consistent with the full freedom of use specified in this license.
Most GNU software, including some libraries, is covered by the
ordinary GNU General Public License. This license, the GNU Lesser
General Public License, applies to certain designated libraries, and
is quite different from the ordinary General Public License. We use
this license for certain libraries in order to permit linking those
libraries into non-free programs.
When a program is linked with a library, whether statically or using
a shared library, the combination of the two is legally speaking a
combined work, a derivative of the original library. The ordinary
General Public License therefore permits such linking only if the
entire combination fits its criteria of freedom. The Lesser General
Public License permits more lax criteria for linking other code with
the library.
We call this license the "Lesser" General Public License because it
does Less to protect the user's freedom than the ordinary General
Public License. It also provides other free software developers Less
of an advantage over competing non-free programs. These disadvantages
are the reason we use the ordinary General Public License for many
libraries. However, the Lesser license provides advantages in certain
special circumstances.
For example, on rare occasions, there may be a special need to
encourage the widest possible use of a certain library, so that it becomes
a de-facto standard. To achieve this, non-free programs must be
allowed to use the library. A more frequent case is that a free
library does the same job as widely used non-free libraries. In this
case, there is little to gain by limiting the free library to free
software only, so we use the Lesser General Public License.
In other cases, permission to use a particular library in non-free
programs enables a greater number of people to use a large body of
free software. For example, permission to use the GNU C Library in
non-free programs enables many more people to use the whole GNU
operating system, as well as its variant, the GNU/Linux operating
system.
Although the Lesser General Public License is Less protective of the
users' freedom, it does ensure that the user of a program that is
linked with the Library has the freedom and the wherewithal to run
that program using a modified version of the Library.
The precise terms and conditions for copying, distribution and
modification follow. Pay close attention to the difference between a
"work based on the library" and a "work that uses the library". The
former contains code derived from the library, whereas the latter must
be combined with the library in order to run.
GNU LESSER GENERAL PUBLIC LICENSE
TERMS AND CONDITIONS FOR COPYING, DISTRIBUTION AND MODIFICATION
0. This License Agreement applies to any software library or other
program which contains a notice placed by the copyright holder or
other authorized party saying it may be distributed under the terms of
this Lesser General Public License (also called "this License").
Each licensee is addressed as "you".
A "library" means a collection of software functions and/or data
prepared so as to be conveniently linked with application programs
(which use some of those functions and data) to form executables.
The "Library", below, refers to any such software library or work
which has been distributed under these terms. A "work based on the
Library" means either the Library or any derivative work under
copyright law: that is to say, a work containing the Library or a
portion of it, either verbatim or with modifications and/or translated
straightforwardly into another language. (Hereinafter, translation is
included without limitation in the term "modification".)
"Source code" for a work means the preferred form of the work for
making modifications to it. For a library, complete source code means
all the source code for all modules it contains, plus any associated
interface definition files, plus the scripts used to control compilation
and installation of the library.
Activities other than copying, distribution and modification are not
covered by this License; they are outside its scope. The act of
running a program using the Library is not restricted, and output from
such a program is covered only if its contents constitute a work based
on the Library (independent of the use of the Library in a tool for
writing it). Whether that is true depends on what the Library does
and what the program that uses the Library does.
1. You may copy and distribute verbatim copies of the Library's
complete source code as you receive it, in any medium, provided that
you conspicuously and appropriately publish on each copy an
appropriate copyright notice and disclaimer of warranty; keep intact
all the notices that refer to this License and to the absence of any
warranty; and distribute a copy of this License along with the
Library.
You may charge a fee for the physical act of transferring a copy,
and you may at your option offer warranty protection in exchange for a
fee.
2. You may modify your copy or copies of the Library or any portion
of it, thus forming a work based on the Library, and copy and
distribute such modifications or work under the terms of Section 1
above, provided that you also meet all of these conditions:
a) The modified work must itself be a software library.
b) You must cause the files modified to carry prominent notices
stating that you changed the files and the date of any change.
c) You must cause the whole of the work to be licensed at no
charge to all third parties under the terms of this License.
d) If a facility in the modified Library refers to a function or a
table of data to be supplied by an application program that uses
the facility, other than as an argument passed when the facility
is invoked, then you must make a good faith effort to ensure that,
in the event an application does not supply such function or
table, the facility still operates, and performs whatever part of
its purpose remains meaningful.
(For example, a function in a library to compute square roots has
a purpose that is entirely well-defined independent of the
application. Therefore, Subsection 2d requires that any
application-supplied function or table used by this function must
be optional: if the application does not supply it, the square
root function must still compute square roots.)
These requirements apply to the modified work as a whole. If
identifiable sections of that work are not derived from the Library,
and can be reasonably considered independent and separate works in
themselves, then this License, and its terms, do not apply to those
sections when you distribute them as separate works. But when you
distribute the same sections as part of a whole which is a work based
on the Library, the distribution of the whole must be on the terms of
this License, whose permissions for other licensees extend to the
entire whole, and thus to each and every part regardless of who wrote
it.
Thus, it is not the intent of this section to claim rights or contest
your rights to work written entirely by you; rather, the intent is to
exercise the right to control the distribution of derivative or
collective works based on the Library.
In addition, mere aggregation of another work not based on the Library
with the Library (or with a work based on the Library) on a volume of
a storage or distribution medium does not bring the other work under
the scope of this License.
3. You may opt to apply the terms of the ordinary GNU General Public
License instead of this License to a given copy of the Library. To do
this, you must alter all the notices that refer to this License, so
that they refer to the ordinary GNU General Public License, version 2,
instead of to this License. (If a newer version than version 2 of the
ordinary GNU General Public License has appeared, then you can specify
that version instead if you wish.) Do not make any other change in
these notices.
Once this change is made in a given copy, it is irreversible for
that copy, so the ordinary GNU General Public License applies to all
subsequent copies and derivative works made from that copy.
This option is useful when you wish to copy part of the code of
the Library into a program that is not a library.
4. You may copy and distribute the Library (or a portion or
derivative of it, under Section 2) in object code or executable form
under the terms of Sections 1 and 2 above provided that you accompany
it with the complete corresponding machine-readable source code, which
must be distributed under the terms of Sections 1 and 2 above on a
medium customarily used for software interchange.
If distribution of object code is made by offering access to copy
from a designated place, then offering equivalent access to copy the
source code from the same place satisfies the requirement to
distribute the source code, even though third parties are not
compelled to copy the source along with the object code.
5. A program that contains no derivative of any portion of the
Library, but is designed to work with the Library by being compiled or
linked with it, is called a "work that uses the Library". Such a
work, in isolation, is not a derivative work of the Library, and
therefore falls outside the scope of this License.
However, linking a "work that uses the Library" with the Library
creates an executable that is a derivative of the Library (because it
contains portions of the Library), rather than a "work that uses the
library". The executable is therefore covered by this License.
Section 6 states terms for distribution of such executables.
When a "work that uses the Library" uses material from a header file
that is part of the Library, the object code for the work may be a
derivative work of the Library even though the source code is not.
Whether this is true is especially significant if the work can be
linked without the Library, or if the work is itself a library. The
threshold for this to be true is not precisely defined by law.
If such an object file uses only numerical parameters, data
structure layouts and accessors, and small macros and small inline
functions (ten lines or less in length), then the use of the object
file is unrestricted, regardless of whether it is legally a derivative
work. (Executables containing this object code plus portions of the
Library will still fall under Section 6.)
Otherwise, if the work is a derivative of the Library, you may
distribute the object code for the work under the terms of Section 6.
Any executables containing that work also fall under Section 6,
whether or not they are linked directly with the Library itself.
6. As an exception to the Sections above, you may also combine or
link a "work that uses the Library" with the Library to produce a
work containing portions of the Library, and distribute that work
under terms of your choice, provided that the terms permit
modification of the work for the customer's own use and reverse
engineering for debugging such modifications.
You must give prominent notice with each copy of the work that the
Library is used in it and that the Library and its use are covered by
this License. You must supply a copy of this License. If the work
during execution displays copyright notices, you must include the
copyright notice for the Library among them, as well as a reference
directing the user to the copy of this License. Also, you must do one
of these things:
a) Accompany the work with the complete corresponding
machine-readable source code for the Library including whatever
changes were used in the work (which must be distributed under
Sections 1 and 2 above); and, if the work is an executable linked
with the Library, with the complete machine-readable "work that
uses the Library", as object code and/or source code, so that the
user can modify the Library and then relink to produce a modified
executable containing the modified Library. (It is understood
that the user who changes the contents of definitions files in the
Library will not necessarily be able to recompile the application
to use the modified definitions.)
b) Use a suitable shared library mechanism for linking with the
Library. A suitable mechanism is one that (1) uses at run time a
copy of the library already present on the user's computer system,
rather than copying library functions into the executable, and (2)
will operate properly with a modified version of the library, if
the user installs one, as long as the modified version is
interface-compatible with the version that the work was made with.
c) Accompany the work with a written offer, valid for at
least three years, to give the same user the materials
specified in Subsection 6a, above, for a charge no more
than the cost of performing this distribution.
d) If distribution of the work is made by offering access to copy
from a designated place, offer equivalent access to copy the above
specified materials from the same place.
e) Verify that the user has already received a copy of these
materials or that you have already sent this user a copy.
For an executable, the required form of the "work that uses the
Library" must include any data and utility programs needed for
reproducing the executable from it. However, as a special exception,
the materials to be distributed need not include anything that is
normally distributed (in either source or binary form) with the major
components (compiler, kernel, and so on) of the operating system on
which the executable runs, unless that component itself accompanies
the executable.
It may happen that this requirement contradicts the license
restrictions of other proprietary libraries that do not normally
accompany the operating system. Such a contradiction means you cannot
use both them and the Library together in an executable that you
distribute.
7. You may place library facilities that are a work based on the
Library side-by-side in a single library together with other library
facilities not covered by this License, and distribute such a combined
library, provided that the separate distribution of the work based on
the Library and of the other library facilities is otherwise
permitted, and provided that you do these two things:
a) Accompany the combined library with a copy of the same work
based on the Library, uncombined with any other library
facilities. This must be distributed under the terms of the
Sections above.
b) Give prominent notice with the combined library of the fact
that part of it is a work based on the Library, and explaining
where to find the accompanying uncombined form of the same work.
8. You may not copy, modify, sublicense, link with, or distribute
the Library except as expressly provided under this License. Any
attempt otherwise to copy, modify, sublicense, link with, or
distribute the Library is void, and will automatically terminate your
rights under this License. However, parties who have received copies,
or rights, from you under this License will not have their licenses
terminated so long as such parties remain in full compliance.
9. You are not required to accept this License, since you have not
signed it. However, nothing else grants you permission to modify or
distribute the Library or its derivative works. These actions are
prohibited by law if you do not accept this License. Therefore, by
modifying or distributing the Library (or any work based on the
Library), you indicate your acceptance of this License to do so, and
all its terms and conditions for copying, distributing or modifying
the Library or works based on it.
10. Each time you redistribute the Library (or any work based on the
Library), the recipient automatically receives a license from the
original licensor to copy, distribute, link with or modify the Library
subject to these terms and conditions. You may not impose any further
restrictions on the recipients' exercise of the rights granted herein.
You are not responsible for enforcing compliance by third parties with
this License.
11. If, as a consequence of a court judgment or allegation of patent
infringement or for any other reason (not limited to patent issues),
conditions are imposed on you (whether by court order, agreement or
otherwise) that contradict the conditions of this License, they do not
excuse you from the conditions of this License. If you cannot
distribute so as to satisfy simultaneously your obligations under this
License and any other pertinent obligations, then as a consequence you
may not distribute the Library at all. For example, if a patent
license would not permit royalty-free redistribution of the Library by
all those who receive copies directly or indirectly through you, then
the only way you could satisfy both it and this License would be to
refrain entirely from distribution of the Library.
If any portion of this section is held invalid or unenforceable under any
particular circumstance, the balance of the section is intended to apply,
and the section as a whole is intended to apply in other circumstances.
It is not the purpose of this section to induce you to infringe any
patents or other property right claims or to contest validity of any
such claims; this section has the sole purpose of protecting the
integrity of the free software distribution system which is
implemented by public license practices. Many people have made
generous contributions to the wide range of software distributed
through that system in reliance on consistent application of that
system; it is up to the author/donor to decide if he or she is willing
to distribute software through any other system and a licensee cannot
impose that choice.
This section is intended to make thoroughly clear what is believed to
be a consequence of the rest of this License.
12. If the distribution and/or use of the Library is restricted in
certain countries either by patents or by copyrighted interfaces, the
original copyright holder who places the Library under this License may add
an explicit geographical distribution limitation excluding those countries,
so that distribution is permitted only in or among countries not thus
excluded. In such case, this License incorporates the limitation as if
written in the body of this License.
13. The Free Software Foundation may publish revised and/or new
versions of the Lesser General Public License from time to time.
Such new versions will be similar in spirit to the present version,
but may differ in detail to address new problems or concerns.
Each version is given a distinguishing version number. If the Library
specifies a version number of this License which applies to it and
"any later version", you have the option of following the terms and
conditions either of that version or of any later version published by
the Free Software Foundation. If the Library does not specify a
license version number, you may choose any version ever published by
the Free Software Foundation.
14. If you wish to incorporate parts of the Library into other free
programs whose distribution conditions are incompatible with these,
write to the author to ask for permission. For software which is
copyrighted by the Free Software Foundation, write to the Free
Software Foundation; we sometimes make exceptions for this. Our
decision will be guided by the two goals of preserving the free status
of all derivatives of our free software and of promoting the sharing
and reuse of software generally.
NO WARRANTY
15. BECAUSE THE LIBRARY IS LICENSED FREE OF CHARGE, THERE IS NO
WARRANTY FOR THE LIBRARY, TO THE EXTENT PERMITTED BY APPLICABLE LAW.
EXCEPT WHEN OTHERWISE STATED IN WRITING THE COPYRIGHT HOLDERS AND/OR
OTHER PARTIES PROVIDE THE LIBRARY "AS IS" WITHOUT WARRANTY OF ANY
KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
PURPOSE. THE ENTIRE RISK AS TO THE QUALITY AND PERFORMANCE OF THE
LIBRARY IS WITH YOU. SHOULD THE LIBRARY PROVE DEFECTIVE, YOU ASSUME
THE COST OF ALL NECESSARY SERVICING, REPAIR OR CORRECTION.
16. IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN
WRITING WILL ANY COPYRIGHT HOLDER, OR ANY OTHER PARTY WHO MAY MODIFY
AND/OR REDISTRIBUTE THE LIBRARY AS PERMITTED ABOVE, BE LIABLE TO YOU
FOR DAMAGES, INCLUDING ANY GENERAL, SPECIAL, INCIDENTAL OR
CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OR INABILITY TO USE THE
LIBRARY (INCLUDING BUT NOT LIMITED TO LOSS OF DATA OR DATA BEING
RENDERED INACCURATE OR LOSSES SUSTAINED BY YOU OR THIRD PARTIES OR A
FAILURE OF THE LIBRARY TO OPERATE WITH ANY OTHER SOFTWARE), EVEN IF
SUCH HOLDER OR OTHER PARTY HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
DAMAGES.
END OF TERMS AND CONDITIONS
How to Apply These Terms to Your New Libraries
If you develop a new library, and you want it to be of the greatest
possible use to the public, we recommend making it free software that
everyone can redistribute and change. You can do so by permitting
redistribution under these terms (or, alternatively, under the terms of the
ordinary General Public License).
To apply these terms, attach the following notices to the library. It is
safest to attach them to the start of each source file to most effectively
convey the exclusion of warranty; and each file should have at least the
"copyright" line and a pointer to where the full notice is found.
<one line to give the library's name and a brief idea of what it does.>
Copyright (C) <year> <name of author>
This library 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.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
Also add information on how to contact you by electronic and paper mail.
You should also get your employer (if you work as a programmer) or your
school, if any, to sign a "copyright disclaimer" for the library, if
necessary. Here is a sample; alter the names:
Yoyodyne, Inc., hereby disclaims all copyright interest in the
library `Frob' (a library for tweaking knobs) written by James Random Hacker.
<signature of Ty Coon>, 1 April 1990
Ty Coon, President of Vice
That's all there is to it!

114
third_party/mspack/config.h vendored Normal file
View File

@ -0,0 +1,114 @@
/* config.h.in. Generated from configure.ac by autoheader. */
/* Turn debugging mode on? */
#undef DEBUG
/* Define to 1 if you have the <dlfcn.h> header file. */
#undef HAVE_DLFCN_H
/* Define to 1 if fseeko (and presumably ftello) exists and is declared. */
#undef HAVE_FSEEKO
/* Define to 1 if you have the <inttypes.h> header file. */
#define HAVE_INTTYPES_H 1
/* Define to 1 if you have the <memory.h> header file. */
#undef HAVE_MEMORY_H
/* Define to 1 if you have the `mkdir' function. */
#undef HAVE_MKDIR
/* Define to 1 if you have the <stdint.h> header file. */
#define HAVE_STDINT_H 1
/* Define to 1 if you have the <stdlib.h> header file. */
#define HAVE_STDLIB_H 1
/* Define to 1 if you have the <strings.h> header file. */
#undef HAVE_STRINGS_H
/* Define to 1 if you have the <string.h> header file. */
#define HAVE_STRING_H 1
/* Define to 1 if you have the <sys/stat.h> header file. */
#undef HAVE_SYS_STAT_H
/* Define to 1 if you have the <sys/types.h> header file. */
#undef HAVE_SYS_TYPES_H
/* Define to 1 if you have the `towlower' function. */
#undef HAVE_TOWLOWER
/* Define to 1 if you have the <unistd.h> header file. */
#undef HAVE_UNISTD_H
/* Define to 1 if you have the `_mkdir' function. */
#undef HAVE__MKDIR
/* Define to the sub-directory where libtool stores uninstalled libraries. */
#undef LT_OBJDIR
/* Define if mkdir takes only one argument. */
#undef MKDIR_TAKES_ONE_ARG
/* Name of package */
#undef PACKAGE
/* Define to the address where bug reports for this package should be sent. */
#undef PACKAGE_BUGREPORT
/* Define to the full name of this package. */
#undef PACKAGE_NAME
/* Define to the full name and version of this package. */
#undef PACKAGE_STRING
/* Define to the one symbol short name of this package. */
#undef PACKAGE_TARNAME
/* Define to the home page for this package. */
#undef PACKAGE_URL
/* Define to the version of this package. */
#undef PACKAGE_VERSION
/* The size of `off_t', as computed by sizeof. */
#undef SIZEOF_OFF_T
/* Define to 1 if you have the ANSI C header files. */
#undef STDC_HEADERS
/* Version number of package */
#undef VERSION
/* Enable large inode numbers on Mac OS X 10.5. */
#ifndef _DARWIN_USE_64_BIT_INODE
# define _DARWIN_USE_64_BIT_INODE 1
#endif
/* Number of bits in a file offset, on hosts where this is settable. */
#undef _FILE_OFFSET_BITS
/* Define to 1 to make fseeko visible on some hosts (e.g. glibc 2.2). */
#undef _LARGEFILE_SOURCE
/* Define for large files, on AIX-style hosts. */
#undef _LARGE_FILES
/* Define to empty if `const' does not conform to ANSI C. */
#undef const
/* Define to `__inline__' or `__inline' if that's what the C compiler
calls it, or to nothing if 'inline' is not supported under any name. */
#ifndef __cplusplus
#undef inline
#endif
/* Define to `int' if <sys/types.h> does not define. */
#undef mode_t
/* Define to `long int' if <sys/types.h> does not define. */
#undef off_t
/* Define to `unsigned int' if <sys/types.h> does not define. */
#undef size_t

View File

@ -1,5 +1,5 @@
/* This file is part of libmspack.
* (C) 2003-2004 Stuart Caie.
* (C) 2003-2013 Stuart Caie.
*
* The LZX method was created by Jonathan Forbes and Tomi Poutanen, adapted
* by Microsoft Corporation.
@ -13,6 +13,10 @@
#ifndef MSPACK_LZX_H
#define MSPACK_LZX_H 1
#ifdef __cplusplus
extern "C" {
#endif
/* LZX compression / decompression definitions */
/* some constants defined by the LZX specification */
@ -31,7 +35,7 @@
/* LZX huffman defines: tweak tablebits as desired */
#define LZX_PRETREE_MAXSYMBOLS (LZX_PRETREE_NUM_ELEMENTS)
#define LZX_PRETREE_TABLEBITS (6)
#define LZX_MAINTREE_MAXSYMBOLS (LZX_NUM_CHARS + 50*8)
#define LZX_MAINTREE_MAXSYMBOLS (LZX_NUM_CHARS + 290*8)
#define LZX_MAINTREE_TABLEBITS (12)
#define LZX_LENGTH_MAXSYMBOLS (LZX_NUM_SECONDARY_LENGTHS+1)
#define LZX_LENGTH_TABLEBITS (12)
@ -51,6 +55,8 @@ struct lzxd_stream {
unsigned char *window; /* decoding window */
unsigned int window_size; /* window size */
unsigned int ref_data_size; /* LZX DELTA reference data size */
unsigned int num_offsets; /* number of match_offset entries in table */
unsigned int window_posn; /* decompression offset within window */
unsigned int frame_posn; /* current frame offset within in window */
unsigned int frame; /* the number of 32kb frames processed */
@ -66,8 +72,8 @@ struct lzxd_stream {
unsigned char intel_started; /* has intel E8 decoding started? */
unsigned char block_type; /* type of the current block */
unsigned char header_read; /* have we started decoding at all yet? */
unsigned char posn_slots; /* how many posn slots in stream? */
unsigned char input_end; /* have we reached the end of input? */
unsigned char is_delta; /* does stream follow LZX DELTA spec? */
int error;
@ -83,85 +89,133 @@ struct lzxd_stream {
/* huffman decoding tables */
unsigned short PRETREE_table [(1 << LZX_PRETREE_TABLEBITS) +
(LZX_PRETREE_MAXSYMBOLS * 2)];
(LZX_PRETREE_MAXSYMBOLS * 2)];
unsigned short MAINTREE_table[(1 << LZX_MAINTREE_TABLEBITS) +
(LZX_MAINTREE_MAXSYMBOLS * 2)];
(LZX_MAINTREE_MAXSYMBOLS * 2)];
unsigned short LENGTH_table [(1 << LZX_LENGTH_TABLEBITS) +
(LZX_LENGTH_MAXSYMBOLS * 2)];
(LZX_LENGTH_MAXSYMBOLS * 2)];
unsigned short ALIGNED_table [(1 << LZX_ALIGNED_TABLEBITS) +
(LZX_ALIGNED_MAXSYMBOLS * 2)];
(LZX_ALIGNED_MAXSYMBOLS * 2)];
unsigned char LENGTH_empty;
/* this is used purely for doing the intel E8 transform */
unsigned char e8_buf[LZX_FRAME_SIZE];
};
/* allocates LZX decompression state for decoding the given stream.
/**
* Allocates and initialises LZX decompression state for decoding an LZX
* stream.
*
* - returns NULL if window_bits is outwith the range 15 to 21 (inclusive).
* This routine uses system->alloc() to allocate memory. If memory
* allocation fails, or the parameters to this function are invalid,
* NULL is returned.
*
* - uses system->alloc() to allocate memory
*
* - returns NULL if not enough memory
*
* - window_bits is the size of the LZX window, from 32Kb (15) to 2Mb (21).
*
* - reset_interval is how often the bitstream is reset, measured in
* multiples of 32Kb bytes output. For CAB LZX streams, this is always 0
* (does not occur).
*
* - input_buffer_size is how many bytes to use as an input bitstream buffer
*
* - output_length is the length in bytes of the entirely decompressed
* output stream, if known in advance. It is used to correctly perform
* the Intel E8 transformation, which must stop 6 bytes before the very
* end of the decompressed stream. It is not otherwise used or adhered
* to. If the full decompressed length is known in advance, set it here.
* If it is NOT known, use the value 0, and call lzxd_set_output_length()
* once it is known. If never set, 4 of the final 6 bytes of the output
* stream may be incorrect.
* @param system an mspack_system structure used to read from
* the input stream and write to the output
* stream, also to allocate and free memory.
* @param input an input stream with the LZX data.
* @param output an output stream to write the decoded data to.
* @param window_bits the size of the decoding window, which must be
* between 15 and 21 inclusive for regular LZX
* data, or between 17 and 25 inclusive for
* LZX DELTA data.
* @param reset_interval the interval at which the LZX bitstream is
* reset, in multiples of LZX frames (32678
* bytes), e.g. a value of 2 indicates the input
* stream resets after every 65536 output bytes.
* A value of 0 indicates that the bitstream never
* resets, such as in CAB LZX streams.
* @param input_buffer_size the number of bytes to use as an input
* bitstream buffer.
* @param output_length the length in bytes of the entirely
* decompressed output stream, if known in
* advance. It is used to correctly perform the
* Intel E8 transformation, which must stop 6
* bytes before the very end of the
* decompressed stream. It is not otherwise used
* or adhered to. If the full decompressed
* length is known in advance, set it here.
* If it is NOT known, use the value 0, and call
* lzxd_set_output_length() once it is
* known. If never set, 4 of the final 6 bytes
* of the output stream may be incorrect.
* @param is_delta should be zero for all regular LZX data,
* non-zero for LZX DELTA encoded data.
* @return a pointer to an initialised lzxd_stream structure, or NULL if
* there was not enough memory or parameters to the function were wrong.
*/
extern struct lzxd_stream *lzxd_init(struct mspack_system *system,
struct mspack_file *input,
struct mspack_file *output,
int window_bits,
int reset_interval,
int input_buffer_size,
off_t output_length);
struct mspack_file *input,
struct mspack_file *output,
int window_bits,
int reset_interval,
int input_buffer_size,
off_t output_length,
char is_delta);
/* see description of output_length in lzxd_init() */
extern void lzxd_set_output_length(struct lzxd_stream *lzx,
off_t output_length);
off_t output_length);
/* decompresses, or decompresses more of, an LZX stream.
/**
* Reads LZX DELTA reference data into the window and allows
* lzxd_decompress() to reference it.
*
* - out_bytes of data will be decompressed and the function will return
* with an MSPACK_ERR_OK return code.
* Call this before the first call to lzxd_decompress().
* @param lzx the LZX stream to apply this reference data to
* @param system an mspack_system implementation to use with the
* input param. Only read() will be called.
* @param input an input file handle to read reference data using
* system->read().
* @param length the length of the reference data. Cannot be longer
* than the LZX window size.
* @return an error code, or MSPACK_ERR_OK if successful
*/
extern int lzxd_set_reference_data(struct lzxd_stream *lzx,
struct mspack_system *system,
struct mspack_file *input,
unsigned int length);
/**
* Decompresses entire or partial LZX streams.
*
* - decompressing will stop as soon as out_bytes is reached. if the true
* amount of bytes decoded spills over that amount, they will be kept for
* a later invocation of lzxd_decompress().
* The number of bytes of data that should be decompressed is given as the
* out_bytes parameter. If more bytes are decoded than are needed, they
* will be kept over for a later invocation.
*
* - the output bytes will be passed to the system->write() function given in
* lzxd_init(), using the output file handle given in lzxd_init(). More
* than one call may be made to system->write().
* The output bytes will be passed to the system->write() function given in
* lzxd_init(), using the output file handle given in lzxd_init(). More than
* one call may be made to system->write().
* Input bytes will be read in as necessary using the system->read()
* function given in lzxd_init(), using the input file handle given in
* lzxd_init(). This will continue until system->read() returns 0 bytes,
* or an error. Errors will be passed out of the function as
* MSPACK_ERR_READ errors. Input streams should convey an "end of input
* stream" by refusing to supply all the bytes that LZX asks for when they
* reach the end of the stream, rather than return an error code.
*
* - LZX will read input bytes as necessary using the system->read() function
* given in lzxd_init(), using the input file handle given in lzxd_init().
* This will continue until system->read() returns 0 bytes, or an error.
* input streams should convey an "end of input stream" by refusing to
* supply all the bytes that LZX asks for when they reach the end of the
* stream, rather than return an error code.
* If any error code other than MSPACK_ERR_OK is returned, the stream
* should be considered unusable and lzxd_decompress() should not be
* called again on this stream.
*
* - if an error code other than MSPACK_ERR_OK is returned, the stream should
* be considered unusable and lzxd_decompress() should not be called again
* on this stream.
* @param lzx LZX decompression state, as allocated by lzxd_init().
* @param out_bytes the number of bytes of data to decompress.
* @return an error code, or MSPACK_ERR_OK if successful
*/
extern int lzxd_decompress(struct lzxd_stream *lzx, off_t out_bytes);
/* frees all state associated with an LZX data stream
/**
* Frees all state associated with an LZX data stream. This will call
* system->free() using the system pointer given in lzxd_init().
*
* - calls system->free() using the system pointer given in lzxd_init()
* @param lzx LZX decompression state to free.
*/
void lzxd_free(struct lzxd_stream *lzx);
#ifdef __cplusplus
}
#endif
#endif

File diff suppressed because it is too large Load Diff

File diff suppressed because it is too large Load Diff

207
third_party/mspack/readbits.h vendored Normal file
View File

@ -0,0 +1,207 @@
/* This file is part of libmspack.
* (C) 2003-2010 Stuart Caie.
*
* libmspack is free software; you can redistribute it and/or modify it under
* the terms of the GNU Lesser General Public License (LGPL) version 2.1
*
* For further details, see the file COPYING.LIB distributed with libmspack
*/
#ifndef MSPACK_READBITS_H
#define MSPACK_READBITS_H 1
/* this header defines macros that read data streams by
* the individual bits
*
* INIT_BITS initialises bitstream state in state structure
* STORE_BITS stores bitstream state in state structure
* RESTORE_BITS restores bitstream state from state structure
* ENSURE_BITS(n) ensure there are at least N bits in the bit buffer
* READ_BITS(var,n) takes N bits from the buffer and puts them in var
* PEEK_BITS(n) extracts without removing N bits from the bit buffer
* REMOVE_BITS(n) removes N bits from the bit buffer
*
* READ_BITS simply calls ENSURE_BITS, PEEK_BITS and REMOVE_BITS,
* which means it's limited to reading the number of bits you can
* ensure at any one time. It also fails if asked to read zero bits.
* If you need to read zero bits, or more bits than can be ensured in
* one go, use READ_MANY_BITS instead.
*
* These macros have variable names baked into them, so to use them
* you have to define some macros:
* - BITS_TYPE: the type name of your state structure
* - BITS_VAR: the variable that points to your state structure
* - define BITS_ORDER_MSB if bits are read from the MSB, or
* define BITS_ORDER_LSB if bits are read from the LSB
* - READ_BYTES: some code that reads more data into the bit buffer,
* it should use READ_IF_NEEDED (calls read_input if the byte buffer
* is empty), then INJECT_BITS(data,n) to put data from the byte
* buffer into the bit buffer.
*
* You also need to define some variables and structure members:
* - unsigned char *i_ptr; // current position in the byte buffer
* - unsigned char *i_end; // end of the byte buffer
* - unsigned int bit_buffer; // the bit buffer itself
* - unsigned int bits_left; // number of bits remaining
*
* If you use read_input() and READ_IF_NEEDED, they also expect these
* structure members:
* - struct mspack_system *sys; // to access sys->read()
* - unsigned int error; // to record/return read errors
* - unsigned char input_end; // to mark reaching the EOF
* - unsigned char *inbuf; // the input byte buffer
* - unsigned int inbuf_size; // the size of the input byte buffer
*
* Your READ_BYTES implementation should read data from *i_ptr and
* put them in the bit buffer. READ_IF_NEEDED will call read_input()
* if i_ptr reaches i_end, and will fill up inbuf and set i_ptr to
* the start of inbuf and i_end to the end of inbuf.
*
* If you're reading in MSB order, the routines work by using the area
* beyond the MSB and the LSB of the bit buffer as a free source of
* zeroes when shifting. This avoids having to mask any bits. So we
* have to know the bit width of the bit buffer variable. We use
* <limits.h> and CHAR_BIT to find the size of the bit buffer in bits.
*
* If you are reading in LSB order, bits need to be masked. Normally
* this is done by computing the mask: N bits are masked by the value
* (1<<N)-1). However, you can define BITS_LSB_TABLE to use a lookup
* table instead of computing this. This adds two new macros,
* PEEK_BITS_T and READ_BITS_T which work the same way as PEEK_BITS
* and READ_BITS, except they use this lookup table. This is useful if
* you need to look up a number of bits that are only known at
* runtime, so the bit mask can't be turned into a constant by the
* compiler.
* The bit buffer datatype should be at least 32 bits wide: it must be
* possible to ENSURE_BITS(17), so it must be possible to add 16 new bits
* to the bit buffer when the bit buffer already has 1 to 15 bits left.
*/
#ifndef BITS_VAR
# error "define BITS_VAR as the state structure poiner variable name"
#endif
#ifndef BITS_TYPE
# error "define BITS_TYPE as the state structure type"
#endif
#if defined(BITS_ORDER_MSB) && defined(BITS_ORDER_LSB)
# error "you must define either BITS_ORDER_MSB or BITS_ORDER_LSB"
#else
# if !(defined(BITS_ORDER_MSB) || defined(BITS_ORDER_LSB))
# error "you must define BITS_ORDER_MSB or BITS_ORDER_LSB"
# endif
#endif
#if HAVE_LIMITS_H
# include <limits.h>
#endif
#ifndef CHAR_BIT
# define CHAR_BIT (8)
#endif
#define BITBUF_WIDTH (sizeof(bit_buffer) * CHAR_BIT)
#define INIT_BITS do { \
BITS_VAR->i_ptr = &BITS_VAR->inbuf[0]; \
BITS_VAR->i_end = &BITS_VAR->inbuf[0]; \
BITS_VAR->bit_buffer = 0; \
BITS_VAR->bits_left = 0; \
BITS_VAR->input_end = 0; \
} while (0)
#define STORE_BITS do { \
BITS_VAR->i_ptr = i_ptr; \
BITS_VAR->i_end = i_end; \
BITS_VAR->bit_buffer = bit_buffer; \
BITS_VAR->bits_left = bits_left; \
} while (0)
#define RESTORE_BITS do { \
i_ptr = BITS_VAR->i_ptr; \
i_end = BITS_VAR->i_end; \
bit_buffer = BITS_VAR->bit_buffer; \
bits_left = BITS_VAR->bits_left; \
} while (0)
#define ENSURE_BITS(nbits) do { \
while (bits_left < (nbits)) READ_BYTES; \
} while (0)
#define READ_BITS(val, nbits) do { \
ENSURE_BITS(nbits); \
(val) = PEEK_BITS(nbits); \
REMOVE_BITS(nbits); \
} while (0)
#define READ_MANY_BITS(val, bits) do { \
unsigned char needed = (bits), bitrun; \
(val) = 0; \
while (needed > 0) { \
if (bits_left <= (BITBUF_WIDTH - 16)) READ_BYTES; \
bitrun = (bits_left < needed) ? bits_left : needed; \
(val) = ((val) << bitrun) | PEEK_BITS(bitrun); \
REMOVE_BITS(bitrun); \
needed -= bitrun; \
} \
} while (0)
#ifdef BITS_ORDER_MSB
# define PEEK_BITS(nbits) (bit_buffer >> (BITBUF_WIDTH - (nbits)))
# define REMOVE_BITS(nbits) ((bit_buffer <<= (nbits)), (bits_left -= (nbits)))
# define INJECT_BITS(bitdata,nbits) ((bit_buffer |= \
(bitdata) << (BITBUF_WIDTH - (nbits) - bits_left)), (bits_left += (nbits)))
#else /* BITS_ORDER_LSB */
# define PEEK_BITS(nbits) (bit_buffer & ((1 << (nbits))-1))
# define REMOVE_BITS(nbits) ((bit_buffer >>= (nbits)), (bits_left -= (nbits)))
# define INJECT_BITS(bitdata,nbits) ((bit_buffer |= \
(bitdata) << bits_left), (bits_left += (nbits)))
#endif
#ifdef BITS_LSB_TABLE
/* lsb_bit_mask[n] = (1 << n) - 1 */
static const unsigned short lsb_bit_mask[17] = {
0x0000, 0x0001, 0x0003, 0x0007, 0x000f, 0x001f, 0x003f, 0x007f, 0x00ff,
0x01ff, 0x03ff, 0x07ff, 0x0fff, 0x1fff, 0x3fff, 0x7fff, 0xffff
};
# define PEEK_BITS_T(nbits) (bit_buffer & lsb_bit_mask[(nbits)])
# define READ_BITS_T(val, nbits) do { \
ENSURE_BITS(nbits); \
(val) = PEEK_BITS_T(nbits); \
REMOVE_BITS(nbits); \
} while (0)
#endif
#ifndef BITS_NO_READ_INPUT
# define READ_IF_NEEDED do { \
if (i_ptr >= i_end) { \
if (read_input(BITS_VAR)) \
return BITS_VAR->error; \
i_ptr = BITS_VAR->i_ptr; \
i_end = BITS_VAR->i_end; \
} \
} while (0)
static int read_input(BITS_TYPE *p) {
int read = p->sys->read(p->input, &p->inbuf[0], (int)p->inbuf_size);
if (read < 0) return p->error = MSPACK_ERR_READ;
/* we might overrun the input stream by asking for bits we don't use,
* so fake 2 more bytes at the end of input */
if (read == 0) {
if (p->input_end) {
D(("out of input bytes"))
return p->error = MSPACK_ERR_READ;
}
else {
read = 2;
p->inbuf[0] = p->inbuf[1] = 0;
p->input_end = 1;
}
}
/* update i_ptr and i_end */
p->i_ptr = &p->inbuf[0];
p->i_end = &p->inbuf[read];
return MSPACK_ERR_OK;
}
#endif
#endif

172
third_party/mspack/readhuff.h vendored Normal file
View File

@ -0,0 +1,172 @@
/* This file is part of libmspack.
* (C) 2003-2014 Stuart Caie.
*
* libmspack is free software; you can redistribute it and/or modify it under
* the terms of the GNU Lesser General Public License (LGPL) version 2.1
*
* For further details, see the file COPYING.LIB distributed with libmspack
*/
#ifndef MSPACK_READHUFF_H
#define MSPACK_READHUFF_H 1
/* This implements a fast Huffman tree decoding system. */
#if !(defined(BITS_ORDER_MSB) || defined(BITS_ORDER_LSB))
# error "readhuff.h is used in conjunction with readbits.h, include that first"
#endif
#if !(defined(TABLEBITS) && defined(MAXSYMBOLS))
# error "define TABLEBITS(tbl) and MAXSYMBOLS(tbl) before using readhuff.h"
#endif
#if !(defined(HUFF_TABLE) && defined(HUFF_LEN))
# error "define HUFF_TABLE(tbl) and HUFF_LEN(tbl) before using readhuff.h"
#endif
#ifndef HUFF_ERROR
# error "define HUFF_ERROR before using readhuff.h"
#endif
#ifndef HUFF_MAXBITS
# define HUFF_MAXBITS 16
#endif
/* Decodes the next huffman symbol from the input bitstream into var.
* Do not use this macro on a table unless build_decode_table() succeeded.
*/
#define READ_HUFFSYM(tbl, var) do { \
ENSURE_BITS(HUFF_MAXBITS); \
sym = HUFF_TABLE(tbl, PEEK_BITS(TABLEBITS(tbl))); \
if (sym >= MAXSYMBOLS(tbl)) HUFF_TRAVERSE(tbl); \
(var) = sym; \
i = HUFF_LEN(tbl, sym); \
REMOVE_BITS(i); \
} while (0)
#ifdef BITS_ORDER_LSB
# define HUFF_TRAVERSE(tbl) do { \
i = TABLEBITS(tbl) - 1; \
do { \
if (i++ > HUFF_MAXBITS) HUFF_ERROR; \
sym = HUFF_TABLE(tbl, \
(sym << 1) | ((bit_buffer >> i) & 1)); \
} while (sym >= MAXSYMBOLS(tbl)); \
} while (0)
#else
#define HUFF_TRAVERSE(tbl) do { \
i = 1 << (BITBUF_WIDTH - TABLEBITS(tbl)); \
do { \
if ((i >>= 1) == 0) HUFF_ERROR; \
sym = HUFF_TABLE(tbl, \
(sym << 1) | ((bit_buffer & i) ? 1 : 0)); \
} while (sym >= MAXSYMBOLS(tbl)); \
} while (0)
#endif
/* make_decode_table(nsyms, nbits, length[], table[])
*
* This function was originally coded by David Tritscher.
* It builds a fast huffman decoding table from
* a canonical huffman code lengths table.
*
* nsyms = total number of symbols in this huffman tree.
* nbits = any symbols with a code length of nbits or less can be decoded
* in one lookup of the table.
* length = A table to get code lengths from [0 to nsyms-1]
* table = The table to fill up with decoded symbols and pointers.
* Should be ((1<<nbits) + (nsyms*2)) in length.
*
* Returns 0 for OK or 1 for error
*/
static int make_decode_table(unsigned int nsyms, unsigned int nbits,
unsigned char *length, unsigned short *table)
{
register unsigned short sym, next_symbol;
register unsigned int leaf, fill;
#ifdef BITS_ORDER_LSB
register unsigned int reverse;
#endif
register unsigned char bit_num;
unsigned int pos = 0; /* the current position in the decode table */
unsigned int table_mask = 1 << nbits;
unsigned int bit_mask = table_mask >> 1; /* don't do 0 length codes */
/* fill entries for codes short enough for a direct mapping */
for (bit_num = 1; bit_num <= nbits; bit_num++) {
for (sym = 0; sym < nsyms; sym++) {
if (length[sym] != bit_num) continue;
#ifdef BITS_ORDER_MSB
leaf = pos;
#else
/* reverse the significant bits */
fill = length[sym]; reverse = pos >> (nbits - fill); leaf = 0;
do {leaf <<= 1; leaf |= reverse & 1; reverse >>= 1;} while (--fill);
#endif
if((pos += bit_mask) > table_mask) return 1; /* table overrun */
/* fill all possible lookups of this symbol with the symbol itself */
#ifdef BITS_ORDER_MSB
for (fill = bit_mask; fill-- > 0;) table[leaf++] = sym;
#else
fill = bit_mask; next_symbol = 1 << bit_num;
do { table[leaf] = sym; leaf += next_symbol; } while (--fill);
#endif
}
bit_mask >>= 1;
}
/* exit with success if table is now complete */
if (pos == table_mask) return 0;
/* mark all remaining table entries as unused */
for (sym = pos; sym < table_mask; sym++) {
#ifdef BITS_ORDER_MSB
table[sym] = 0xFFFF;
#else
reverse = sym; leaf = 0; fill = nbits;
do { leaf <<= 1; leaf |= reverse & 1; reverse >>= 1; } while (--fill);
table[leaf] = 0xFFFF;
#endif
}
/* next_symbol = base of allocation for long codes */
next_symbol = ((table_mask >> 1) < nsyms) ? nsyms : (table_mask >> 1);
/* give ourselves room for codes to grow by up to 16 more bits.
* codes now start at bit nbits+16 and end at (nbits+16-codelength) */
pos <<= 16;
table_mask <<= 16;
bit_mask = 1 << 15;
for (bit_num = nbits+1; bit_num <= HUFF_MAXBITS; bit_num++) {
for (sym = 0; sym < nsyms; sym++) {
if (length[sym] != bit_num) continue;
if (pos >= table_mask) return 1; /* table overflow */
#ifdef BITS_ORDER_MSB
leaf = pos >> 16;
#else
/* leaf = the first nbits of the code, reversed */
reverse = pos >> 16; leaf = 0; fill = nbits;
do {leaf <<= 1; leaf |= reverse & 1; reverse >>= 1;} while (--fill);
#endif
for (fill = 0; fill < (bit_num - nbits); fill++) {
/* if this path hasn't been taken yet, 'allocate' two entries */
if (table[leaf] == 0xFFFF) {
table[(next_symbol << 1) ] = 0xFFFF;
table[(next_symbol << 1) + 1 ] = 0xFFFF;
table[leaf] = next_symbol++;
}
/* follow the path and select either left or right for next bit */
leaf = table[leaf] << 1;
if ((pos >> (15-fill)) & 1) leaf++;
}
table[leaf] = sym;
pos += bit_mask;
}
bit_mask >>= 1;
}
/* full table? */
return (pos == table_mask) ? 0 : 1;
}
#endif

242
third_party/mspack/system.c vendored Normal file
View File

@ -0,0 +1,242 @@
/* This file is part of libmspack.
* (C) 2003-2004 Stuart Caie.
*
* libmspack is free software; you can redistribute it and/or modify it under
* the terms of the GNU Lesser General Public License (LGPL) version 2.1
*
* For further details, see the file COPYING.LIB distributed with libmspack
*/
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include <system.h>
#if !LARGEFILE_SUPPORT
const char *largefile_msg = "library not compiled to support large files.";
#endif
int mspack_version(int entity) {
switch (entity) {
/* CHM decoder version 1 -> 2 changes:
* - added mschmd_sec_mscompressed::spaninfo
* - added mschmd_header::first_pmgl
* - added mschmd_header::last_pmgl
* - added mschmd_header::chunk_cache;
*/
case MSPACK_VER_MSCHMD:
/* CAB decoder version 1 -> 2 changes:
* - added MSCABD_PARAM_SALVAGE
*/
case MSPACK_VER_MSCABD:
return 2;
case MSPACK_VER_LIBRARY:
case MSPACK_VER_SYSTEM:
case MSPACK_VER_MSSZDDD:
case MSPACK_VER_MSKWAJD:
case MSPACK_VER_MSOABD:
return 1;
case MSPACK_VER_MSCABC:
case MSPACK_VER_MSCHMC:
case MSPACK_VER_MSLITD:
case MSPACK_VER_MSLITC:
case MSPACK_VER_MSHLPD:
case MSPACK_VER_MSHLPC:
case MSPACK_VER_MSSZDDC:
case MSPACK_VER_MSKWAJC:
case MSPACK_VER_MSOABC:
return 0;
}
return -1;
}
int mspack_sys_selftest_internal(int offt_size) {
return (sizeof(off_t) == offt_size) ? MSPACK_ERR_OK : MSPACK_ERR_SEEK;
}
/* validates a system structure */
int mspack_valid_system(struct mspack_system *sys) {
return (sys != NULL) && (sys->open != NULL) && (sys->close != NULL) &&
(sys->read != NULL) && (sys->write != NULL) && (sys->seek != NULL) &&
(sys->tell != NULL) && (sys->message != NULL) && (sys->alloc != NULL) &&
(sys->free != NULL) && (sys->copy != NULL) && (sys->null_ptr == NULL);
}
/* returns the length of a file opened for reading */
int mspack_sys_filelen(struct mspack_system *system,
struct mspack_file *file, off_t *length)
{
off_t current;
if (!system || !file || !length) return MSPACK_ERR_OPEN;
/* get current offset */
current = system->tell(file);
/* seek to end of file */
if (system->seek(file, (off_t) 0, MSPACK_SYS_SEEK_END)) {
return MSPACK_ERR_SEEK;
}
/* get offset of end of file */
*length = system->tell(file);
/* seek back to original offset */
if (system->seek(file, current, MSPACK_SYS_SEEK_START)) {
return MSPACK_ERR_SEEK;
}
return MSPACK_ERR_OK;
}
/* definition of mspack_default_system -- if the library is compiled with
* MSPACK_NO_DEFAULT_SYSTEM, no default system will be provided. Otherwise,
* an appropriate default system (e.g. the standard C library, or some native
* API calls)
*/
#ifdef MSPACK_NO_DEFAULT_SYSTEM
struct mspack_system *mspack_default_system = NULL;
#else
/* implementation of mspack_default_system for standard C library */
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdarg.h>
struct mspack_file_p {
FILE *fh;
const char *name;
};
static struct mspack_file *msp_open(struct mspack_system *self,
const char *filename, int mode)
{
struct mspack_file_p *fh;
const char *fmode;
switch (mode) {
case MSPACK_SYS_OPEN_READ: fmode = "rb"; break;
case MSPACK_SYS_OPEN_WRITE: fmode = "wb"; break;
case MSPACK_SYS_OPEN_UPDATE: fmode = "r+b"; break;
case MSPACK_SYS_OPEN_APPEND: fmode = "ab"; break;
default: return NULL;
}
if ((fh = (struct mspack_file_p *) malloc(sizeof(struct mspack_file_p)))) {
fh->name = filename;
if ((fh->fh = fopen(filename, fmode))) return (struct mspack_file *) fh;
free(fh);
}
return NULL;
}
static void msp_close(struct mspack_file *file) {
struct mspack_file_p *self = (struct mspack_file_p *) file;
if (self) {
fclose(self->fh);
free(self);
}
}
static int msp_read(struct mspack_file *file, void *buffer, int bytes) {
struct mspack_file_p *self = (struct mspack_file_p *) file;
if (self && buffer && bytes >= 0) {
size_t count = fread(buffer, 1, (size_t) bytes, self->fh);
if (!ferror(self->fh)) return (int) count;
}
return -1;
}
static int msp_write(struct mspack_file *file, void *buffer, int bytes) {
struct mspack_file_p *self = (struct mspack_file_p *) file;
if (self && buffer && bytes >= 0) {
size_t count = fwrite(buffer, 1, (size_t) bytes, self->fh);
if (!ferror(self->fh)) return (int) count;
}
return -1;
}
static int msp_seek(struct mspack_file *file, off_t offset, int mode) {
struct mspack_file_p *self = (struct mspack_file_p *) file;
if (self) {
switch (mode) {
case MSPACK_SYS_SEEK_START: mode = SEEK_SET; break;
case MSPACK_SYS_SEEK_CUR: mode = SEEK_CUR; break;
case MSPACK_SYS_SEEK_END: mode = SEEK_END; break;
default: return -1;
}
#if HAVE_FSEEKO
return fseeko(self->fh, offset, mode);
#else
return fseek(self->fh, offset, mode);
#endif
}
return -1;
}
static off_t msp_tell(struct mspack_file *file) {
struct mspack_file_p *self = (struct mspack_file_p *) file;
#if HAVE_FSEEKO
return (self) ? (off_t) ftello(self->fh) : 0;
#else
return (self) ? (off_t) ftell(self->fh) : 0;
#endif
}
static void msp_msg(struct mspack_file *file, const char *format, ...) {
va_list ap;
if (file) fprintf(stderr, "%s: ", ((struct mspack_file_p *) file)->name);
va_start(ap, format);
vfprintf(stderr, format, ap);
va_end(ap);
fputc((int) '\n', stderr);
fflush(stderr);
}
static void *msp_alloc(struct mspack_system *self, size_t bytes) {
#if DEBUG
/* make uninitialised data obvious */
char *buf = malloc(bytes + 8);
if (buf) memset(buf, 0xDC, bytes);
*((size_t *)buf) = bytes;
return &buf[8];
#else
return malloc(bytes);
#endif
}
static void msp_free(void *buffer) {
#if DEBUG
char *buf = buffer;
size_t bytes;
if (buf) {
buf -= 8;
bytes = *((size_t *)buf);
/* make freed data obvious */
memset(buf, 0xED, bytes);
free(buf);
}
#else
free(buffer);
#endif
}
static void msp_copy(void *src, void *dest, size_t bytes) {
memcpy(dest, src, bytes);
}
static struct mspack_system msp_system = {
&msp_open, &msp_close, &msp_read, &msp_write, &msp_seek,
&msp_tell, &msp_msg, &msp_alloc, &msp_free, &msp_copy, NULL
};
struct mspack_system *mspack_default_system = &msp_system;
#endif

113
third_party/mspack/system.h vendored Normal file
View File

@ -0,0 +1,113 @@
/* This file is part of libmspack.
* (C) 2003-2018 Stuart Caie.
*
* libmspack is free software; you can redistribute it and/or modify it under
* the terms of the GNU Lesser General Public License (LGPL) version 2.1
*
* For further details, see the file COPYING.LIB distributed with libmspack
*/
#ifndef MSPACK_SYSTEM_H
#define MSPACK_SYSTEM_H 1
#ifdef __cplusplus
extern "C" {
#endif
/* ensure config.h is read before mspack.h */
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include <mspack.h>
/* assume <string.h> exists */
#include <string.h>
/* fix for problem with GCC 4 and glibc (thanks to Ville Skytta)
* http://bugzilla.redhat.com/bugzilla/show_bug.cgi?id=150429
*/
#ifdef read
# undef read
#endif
/* Old GCCs don't have __func__, but __FUNCTION__:
* http://gcc.gnu.org/onlinedocs/gcc/Function-Names.html
*/
#if __STDC_VERSION__ < 199901L
# if __GNUC__ >= 2
# define __func__ __FUNCTION__
# else
# define __func__ "<unknown>"
# endif
#endif
#if DEBUG
# include <stdio.h>
# define D(x) do { printf("%s:%d (%s) ",__FILE__, __LINE__, __func__); \
printf x ; fputc('\n', stdout); fflush(stdout);} while (0);
#else
# define D(x)
#endif
/* CAB supports searching through files over 4GB in size, and the CHM file
* format actively uses 64-bit offsets. These can only be fully supported
* if the system the code runs on supports large files. If not, the library
* will work as normal using only 32-bit arithmetic, but if an offset
* greater than 2GB is detected, an error message indicating the library
* can't support the file should be printed.
*/
#if HAVE_INTTYPES_H
# include <inttypes.h>
#else
# define PRId64 "lld"
# define PRIu64 "llu"
# define PRId32 "ld"
# define PRIu32 "lu"
#endif
#include <limits.h>
#if ((defined(_FILE_OFFSET_BITS) && _FILE_OFFSET_BITS >= 64) || \
(defined(FILESIZEBITS) && FILESIZEBITS >= 64) || \
defined(_LARGEFILE_SOURCE) || defined(_LARGEFILE64_SOURCE) || \
SIZEOF_OFF_T >= 8)
# define LARGEFILE_SUPPORT 1
# define LD PRId64
# define LU PRIu64
#else
extern const char *largefile_msg;
# define LD PRId32
# define LU PRIu32
#endif
/* endian-neutral reading of little-endian data */
#define __egi32(a,n) ( ((((unsigned char *) a)[n+3]) << 24) | \
((((unsigned char *) a)[n+2]) << 16) | \
((((unsigned char *) a)[n+1]) << 8) | \
((((unsigned char *) a)[n+0])))
#define EndGetI64(a) ((((unsigned long long int) __egi32(a,4)) << 32) | \
((unsigned int) __egi32(a,0)))
#define EndGetI32(a) __egi32(a,0)
#define EndGetI16(a) ((((a)[1])<<8)|((a)[0]))
/* endian-neutral reading of big-endian data */
#define EndGetM32(a) (((((unsigned char *) a)[0]) << 24) | \
((((unsigned char *) a)[1]) << 16) | \
((((unsigned char *) a)[2]) << 8) | \
((((unsigned char *) a)[3])))
#define EndGetM16(a) ((((a)[0])<<8)|((a)[1]))
extern struct mspack_system *mspack_default_system;
/* returns the length of a file opened for reading */
extern int mspack_sys_filelen(struct mspack_system *system,
struct mspack_file *file, off_t *length);
/* validates a system structure */
extern int mspack_valid_system(struct mspack_system *sys);
#ifdef __cplusplus
}
#endif
#endif